Your search keyword '"acyl coenzyme A"' showing total 155 results

1. Fatty acids and inflammatory stimuli induce expression of long-chain acyl-CoA synthetase 1 to promote lipid remodeling in diabetic kidney disease.

Author

Chih-Hong Wang, Surbhi, Goraya, Sayhaan, Byun, Jaeman, and Pennathur, Subramaniam

Subjects

*DIABETIC nephropathies, *FATTY acids, *GENE expression, *KIDNEY cortex, *ACYL coenzyme A, *GLUTAMINE synthetase, *LIPIDS

Abstract

Fatty acid handling and complex lipid synthesis are altered in the kidney cortex of diabetic patients. We recently showed that inhibition of the renin-angiotensin system without changes in glycemia can reverse diabetic kidney disease (DKD) and restore the lipid metabolic network in the kidney cortex of diabetic (db/db) mice, raising the possibility that lipid remodeling may play a central role in DKD. However, the roles of specific enzymes involved in lipid remodeling in DKD have not been elucidated. In the present study, we used this diabetic mouse model and a proximal tubule epithelial cell line (HK2) to investigate the potential relationship between long-chain acyl-CoA synthetase 1 (ACSL1) and lipid metabolism in response to fatty acid exposure and inflammatory signals. We found ACSL1 expression was significantly increased in the kidney cortex of db/db mice, and exposure to palmitate or tumor necrosis factor-α significantly increased Acsl1 mRNA expression in HK-2 cells. In addition, palmitate treatment significantly increased the levels of long-chain acylcarnitines and fatty acyl CoAs in HK2 cells, and these increases were abolished in HK2 cell lines with specific deletion of Acsl1(Acsl1KO cells), suggesting a key role for ACSL1 in fatty acid β-oxidation. In contrast, tumor necrosis factor-α treatment significantly increased the levels of short-chain acylcarnitines and long-chain fatty acyl CoAs in HK2 cells but not in Acsl1KO cells, consistent with fatty acid channeling to complex lipids. Taken together, our data demonstrate a key role for ACSL1 in regulating lipid metabolism, fatty acid partitioning, and inflammation. [ABSTRACT FROM AUTHOR]

Published

2024

2. A short-chain acyl-CoA synthetase that supports branched-chain fatty acid synthesis in Staphylococcus aureus.

Author

Whaley, Sarah G., Frank, Matthew W., and Rock, Charles O.

Subjects

*FATTY acids, *STAPHYLOCOCCUS aureus, *ACYL coenzyme A, *CARRIER proteins, *DICARBOXYLIC acids, *ACYLTRANSFERASES, *POLYKETIDE synthases

Abstract

Staphylococcus aureus controls its membrane biophysical properties using branched-chain fatty acids (BCFAs). The branched-chain acyl-CoA precursors, utilized to initiate fatty acid synthesis, are derived from branched-chain ketoacid dehydrogenase (Bkd), a multiprotein complex that converts a-keto acids to their corresponding acyl-CoAs; however, Bkd KO strains still contain BCFAs. Here, we show that commonly used rich medias contain substantial concentrations of short-chain acids, like 2-methylbutyric and isobutyric acids, that are incorporated into membrane BCFAs. Bkd-deficient strains cannot grow in defined medium unless it is supplemented with either 2-methylbutyric or isobutyric acid. We performed a screen of candidate KO strains and identified the methylbutyryl-CoA synthetase (mbcS gene; SAUSA300_2542) as required for the incorporation of 2-methylbutyric and isobutyric acids into phosphatidylglycerol. Our mass tracing experiments show that isobutyric acid is converted to isobutyryl-CoA that flows into the even-chain acyl-acyl carrier protein intermediates in the type II fatty acid biosynthesis elongation cycle. Furthermore, purified MbcS is an ATP-dependent acyl-CoA synthetase that selectively catalyzes the activation of 2-methylbutyrate and isobutyrate. We found that butyrate and isovalerate are poor MbcS substrates and activity was not detected with acetate or short-chain dicarboxylic acids. Thus, MbcS functions to convert extracellular 2-methylbutyric and isobutyric acids to their respective acyl-CoAs that are used by 3-ketoacyl-ACP synthase III (FabH) to initiate BCFA biosynthesis. [ABSTRACT FROM AUTHOR]

Published

2023

3. Fitm2 is required for ER homeostasis and normal function of murine liver.

Author

Bond, Laura M., Ibrahim, Ayon, Zon W. Lai, Walzem, Rosemary L., Bronson, Roderick T., Ilkayeva, Olga R., Walther, Tobias C., and Farese Jr, Robert V.

Subjects

*HOMEOSTASIS, *MEMBRANE proteins, *FATTY acid oxidation, *LIVER, *HIGH-fat diet, *ACYL coenzyme A, *MEMBRANE lipids, *ACYLTRANSFERASES

Abstract

The endoplasmic reticulum (ER)-resident protein fat storage-inducing transmembrane protein 2 (FIT2) catalyzes acyl-CoA cleavage in vitro and is required for ER homeostasis and normal lipid storage in cells. The gene encoding FIT2 is essential for the viability of mice and worms. Whether FIT2 acts as an acyl-CoA diphosphatase in vivo and how this activity affects the liver, where the protein was discovered, are unknown. Here, we report that hepatocyte-specific Fitm2 knockout (FIT2-LKO) mice fed a chow diet exhibited elevated acyl-CoA levels, ER stress, and signs of liver injury. These mice also had more triglycerides in their livers than control littermates due, in part, to impaired secretion of triglyceride-rich lipoproteins and reduced capacity for fatty acid oxidation. We found that challenging FIT2-LKO mice with a high-fat diet worsened hepatic ER stress and liver injury but unexpectedly reversed the steatosis phenotype, similar to what is observed in FIT2-deficient cells loaded with fatty acids. Our findings support the model that FIT2 acts as an acyl-CoA diphosphatase in vivo and is crucial for normal hepatocyte function and ER homeostasis in the murine liver. [ABSTRACT FROM AUTHOR]

Published

2023

4. Hedgehog acyltransferase catalyzes a random sequential reaction and utilizes multiple fatty acyl-CoA substrates.

Author

Schonbrun, Adina R. and Resh, Marilyn D.

Subjects

*SATURATED fatty acids, *ACYLTRANSFERASES, *ACYL coenzyme A, *FATTY acids, *EMBRYOLOGY

Abstract

Sonic hedgehog (Shh) signaling is a key component of embryonic development and is a driving force in several cancers. Hedgehog acyltransferase (Hhat), a member of the membrane-bound O-acyltransferase family of enzymes, catalyzes the attachment of palmitate to the N-terminal cysteine of Shh, a posttranslation modification critical for Shh signaling. The activity of Hhat has been assayed in cells and in vitro, and cryo-EM structures of Hhat have been reported, yet several unanswered questions remain regarding the enzyme's reaction mechanism, substrate specificity, and the impact of the latter on Shh signaling. Here, we present an in vitro acylation assay with purified Hhat that directly monitors attachment of a fluorescently tagged fatty acyl chain to Shh. Our kinetic analyses revealed that the reaction catalyzed by Hhat proceeds through a random sequential mechanism. We also determined that Hhat can utilize multiple fatty acyl-CoA substrates for fatty acid transfer to Shh, with comparable affinities and turnover rates for myristoyl-CoA, palmitoyl-CoA, palmitoleoyl-CoA, and oleoyl-CoA. Furthermore, we investigated the functional consequence of differential fatty acylation of Shh in a luciferase-based Shh reporter system. We found that the potency of the signaling response in cells was higher for Shh acylated with saturated fatty acids compared to mono-unsaturated fatty acids. These findings demonstrate that Hhat can attach fatty acids other than palmitate to Shh and suggest that heterogeneous fatty acylation has the potential to impact Shh signaling in the developing embryo and/or cancer cells. [ABSTRACT FROM AUTHOR]

Published

2022

5. Biochemical characterization of the first step in sulfonolipid biosynthesis in Alistipes finegoldii.

Author

Radka, Christopher D., Miller, Darcie J., Frank, Matthew W., and Rock, Charles O.

Subjects

*CARRIER proteins, *VITAMIN B6, *GRAM-negative bacteria, *BIOSYNTHESIS, *ACYL coenzyme A, *CRYSTAL structure

Abstract

Sulfonolipids are unusual lipids found in the outer membranes of Gram-negative bacteria in the phylum Bacteroidetes. Sulfonolipid and its deacylated derivative, capnine, are sulfur analogs of ceramide-1-phosphate and sphingosine-1-phosphate, respectively; thus, sulfonolipid biosynthesis is postulated to be similar to the sphingolipid biosynthetic pathway. Here, we identify the first enzyme in sulfonolipid synthesis in Alistipes finegoldii as the product of the alfi_1224 gene, cysteate acyl-acyl carrier protein (ACP) transferase (SulA). We show SulA catalyzes the condensation of acyl-ACP and cysteate (3-sulfo-alanine) to form 3-ketocapnine. Acyl-CoA is a poor substrate. We show SulA has a bound pyridoxal phosphate (PLP) cofactor that undergoes a spectral redshift in the presence of cysteate, consistent with the transition of the lysine-aldimine complex to a substrate-aldimine complex. Furthermore, the SulA crystal structure shows the same prototypical fold found in bacterial serine palmitoyltransferases (Spts), enveloping the PLP cofactor bound to Lys251. We observed the SulA and Spt active sites are identical except for Lys281 in SulA, which is an alanine in Spt. Additionally, SulA(K281A) is catalytically inactive but binds cysteate and forms the external aldimine normally, highlighting the structural role of the Lys281 side chain in walling off the active site from bulk solvent. Finally, the electropositive groove on the protein surface adjacent to the active site entrance provides a landing pad for the electronegative acyl-ACP surface. Taken together, these data identify the substrates, products, and mechanism of SulA, the PLP-dependent condensing enzyme that catalyzes the first step in sulfonolipid synthesis in a gut commensal bacterium. [ABSTRACT FROM AUTHOR]

Published

2022

6. Fatty acid transport protein 2 interacts with ceramide synthase 2 to promote ceramide synthesis.

Author

Jiyoon L. Kim, Mestre, Beatriz, Malitsky, Sergey, Itkin, Maxim, Kupervaser, Meital, and Futerman, Anthony H.

Subjects

*FATTY acid-binding proteins, *CERAMIDES, *CARRIER proteins, *MOIETIES (Chemistry), *ACYL coenzyme A, *ACETYLCOENZYME A

Abstract

Dihydroceramide is a lipid molecule generated via the action of (dihydro)ceramide synthases (CerSs), which use two substrates, namely sphinganine and fatty acyl-CoAs. Sphinganine is generated via the sequential activity of two integral membrane proteins located in the endoplasmic reticulum. Less is known about the source of the fatty acyl-CoAs, although a number of cytosolic proteins in the pathways of acyl-CoA generation modulate ceramide synthesis via direct or indirect interaction with the CerSs. In this study, we demonstrate, by proteomic analysis of immunoprecipitated proteins, that fatty acid transporter protein 2 (FATP2) (also known as very long-chain acyl-CoA synthetase) directly interacts with CerS2 in mouse liver. Studies in cultured cells demonstrated that other members of the FATP family can also interact with CerS2, with the interaction dependent on both proteins being catalytically active. In addition, transfection of cells with FATP1, FATP2, or FATP4 increased ceramide levels although only FATP2 and 4 increased dihydroceramide levels, consistent with their known intracellular locations. Finally, we show that lipofermata, an FATP2 inhibitor which is believed to directly impact tumor cell growth via modulation of FATP2, decreased de novo dihydroceramide synthesis, suggesting that some of the proposed therapeutic effects of lipofermata may be mediated via (dihydro)ceramide rather than directly via acyl-CoA generation. In summary, our study reinforces the idea that manipulating the pathway of fatty acyl-CoA generation will impact a wide variety of down-stream lipids, not least the sphingolipids, which utilize two acyl-CoA moieties in the initial steps of their synthesis. [ABSTRACT FROM AUTHOR]

Published

2022

7. Metallo-β-lactamase domain-containing protein 2 is S-palmitoylated and exhibits acyl-CoA hydrolase activity.

Author

Malgapo, Martin Ian P., Safadi, Jenelle M., and Linder, Maurine E.

Subjects

*ACYL coenzyme A, *SMALL molecules, *PROTEINS, *THIOESTERASE, *CELL metabolism, *BETA lactam antibiotics, *ZINC-finger proteins

Abstract

Members of the metallo-ß-lactamase (MBL) superfamily of enzymes harbor a highly conserved aßßa MBL-fold domain and were first described as inactivators of common ß-lactam antibiotics. In humans, these enzymes have been shown to exhibit diverse functions, including hydrolase activity toward amides, esters, and thioesters. An uncharacterized member of the human MBL family, MBLAC2, was detected in multiple palmitoylproteomes, identified as a zDHHC20 S-acyltransferase interactor, and annotated as a potential thioesterase. In this study, we confirmed that MBLAC2 is palmitoylated and identified the likely S-palmitoylation site as Cys254. S-palmitoylation of MBLAC2 is increased in cells when expressed with zDHHC20, and MBLAC2 is a substrate for purified zDHHC20 in vitro. To determine its biochemical function, we tested the ability of MBLAC2 to hydrolyze a variety of small molecules and acylprotein substrates. MBLAC2 has acyl-CoA thioesterase activity with kinetic parameters and acyl-CoA selectivity comparable with acyl-CoA thioesterase 1 (ACOT1). Two predicted zinc-binding residues, Asp87 and His88, are required for MBLAC2 hydrolase activity. Consistent with a role in fatty acid metabolism in cells, MBLAC2 was cross-linked to a photoactivatable fatty acid in a manner that was independent of its S-fatty acylation at Cys254. Our study adds to previous investigations demonstrating the versatility of the MBL-fold domain in supporting a variety of enzymatic reactions. [ABSTRACT FROM AUTHOR]

Published

2021

8. Multiple mitochondrial thioesterases have distinct tissue and substrate specificity and CoA regulation, suggesting unique functional roles.

Author

Bekeova, Carmen, Anderson-Pullinger, Lauren, Boye, Kevin, Boos, Felix, Sharpadskaya, Yana, Herrmann, Johannes M., and Seifert, Erin L.

Subjects

*BROWN adipose tissue, *LIVER mitochondria, *TISSUES, *ACYL coenzyme A, *SKELETAL muscle

Abstract

Acyl-CoA thioesterases (Acots) hydrolyze fatty acyl-CoA esters. Acots in the mitochondrial matrix are poised to mitigate α-oxidation overload and maintain CoA availability. Several Acots associate with mitochondria, but whether they all localize to the matrix, are redundant, or have different roles is unresolved. Here, we compared the suborganellar localization, activity, expression, and regulation among mitochondrial Acots (Acot2, -7, -9, and -13) in mitochondria from multiple mouse tissues and from a model of Acot2 depletion. Acot7, -9, and -13 localized to the matrix, joining Acot2 that was previously shown to localize there. Mitochondria from heart, skeletal muscle, brown adipose tissue, and kidney robustly expressed Acot2, -9, and -13; Acot9 levels were substantially higher in brown adipose tissue and kidney mitochondria, as was activity for C4:0-CoA, a unique Acot9 substrate. In all tissues, Acot2 accounted for about half of the thioesterase activity for C14:0-CoA and C16:0-CoA. In contrast, liver mitochondria from fed and fasted mice expressed little Acot activity, which was confined to long-chain CoAs and due mainly to Acot7 and Acot13 activities. Matrix Acots occupied different functional niches, based on substrate specificity (Acot9 versus Acot2 and -13) and strong CoA inhibition (Acot7, -9, and -13, but not Acot2). Interpreted in the context of α-oxidation, CoA inhibition would prevent Acotmediated suppression of α-oxidation, while providing a release valve when CoA is limiting. In contrast, CoA-insensitive Acot2 could provide a constitutive siphon for long-chain fatty acyl-CoAs. These results reveal how the family of matrix Acots can mitigate α-oxidation overload and prevent CoA limitation. [ABSTRACT FROM AUTHOR]

Published

2019

9. Acyl-CoA synthetase 6 enriches seminiferous tubules with the ω-3 fatty acid docosahexaenoic acid and is required for male fertility in the mouse.

Author

Hale, Benjamin J., Fernandez, Regina F., Kim, Sora Q., Diaz, Victoria D., Jackson, Shelley N., Lei Liu, Brenna, X. J. Thomas, Hermann, Brian P., Geyer, Christopher B., and Ellis, Jessica M.

Subjects

*SPERMATOGENESIS, *SEMINIFEROUS tubules, *DOCOSAHEXAENOIC acid, *FATTY acids, *UNSATURATED fatty acids, *ACYL coenzyme A, *PHOSPHOLIPIDS, *FISH oils

Abstract

Docosahexaenoic acid (DHA) is an ω-3 dietary-derived polyunsaturated fatty acid of marine origin enriched in testes and necessary for normal fertility, yet the mechanisms regulating the enrichment of DHA in the testes remain unclear. Long-chain ACSL6 (acyl-CoA synthetase isoform 6) activates fatty acids for cellular anabolic and catabolic metabolism by ligating a CoA to a fatty acid, is highly expressed in testes, and has high preference for DHA. Here, we investigated the role of ACSL6 for DHA enrichment in the testes and its requirement for male fertility. Acsl6-/- males were severely subfertile with smaller testes, reduced cauda epididymal sperm counts, germ cell loss, and disorganization of the seminiferous epithelium. Total fatty acid profiling of Acsl6-/- testes revealed reduced DHA and increased ω-6 arachidonic acid, a fatty acid profile also reflected in phospholipid composition. Strikingly, lipid imaging demonstrated spatial redistribution of phospholipids in Acsl6-/- testes. Arachidonic acid--containing phospholipids were predominantly interstitial in control testes but diffusely localized across Acsl6-/- testes. In control testes, DHA-containing phospholipids were predominantly within seminiferous tubules, which contain Sertoli cells and spermatogenic cells but relocalized to the interstitium in Acsl6-/- testes. Taken together, these data demonstrate that ACSL6 is an initial driving force for germ cell DHA enrichment and is required for normal spermatogenesis and male fertility. [ABSTRACT FROM AUTHOR]

Published

2019

10. Synthesis of oxidized phospholipids by sn-1 acyltransferase using 2-15-HETE lysophospholipids.

Author

Gao-Yuan Liu, Sung Ho Moon, Jenkins, Christopher M., Sims, Harold F., Shaoping Guan, and Gross, Richard W.

Subjects

*PHOSPHOLIPASES, *ACYLTRANSFERASES, *PHOSPHOLIPIDS, *LYSOPHOSPHOLIPIDS, *ARACHIDONIC acid, *ACYL coenzyme A, *ESTERIFICATION

Abstract

Recently, oxidized phospholipid species have emerged as important signaling lipids in activated immune cells and platelets. The canonical pathway for the synthesis of oxidized phospholipids is through the release of arachidonic acid by cytosolic phospholipase A2α (cPLA2α) followed by its enzymatic oxidation, activation of the carboxylate anion by acyl-CoA synthetase(s), and re-esterification to the sn-2 position by sn-2 acyltransferase activity (i.e. the Lands cycle). However, recent studies have demonstrated the unanticipated significance of sn-1 hydrolysis of arachidonoyl-containing choline and ethanolamine glycerophospholipids by other phospholipases to generate the corresponding 2-arachidonoyl-lysolipids. Herein, we identified a pathway for oxidized phospholipid synthesis comprising sequential sn-1 hydrolysis by a phospholipase A1 (e.g. by patatin-like phospholipase domain-containing 8 (PNPLA8)), direct enzymatic oxidation of the resultant 2-arachidonoyl-lysophospholipids, and the esterification of oxidized 2-arachidonoyl-lysophospholipids by acyl-CoA-dependent sn-1 acyltransferase(s). To circumvent ambiguities associated with acyl migration or hydrolysis, we developed a synthesis for optically active (D- and L-enantiomers) nonhydrolyzable analogs of 2-arachidonoyl-lysophosphatidylcholine (2-AA-LPC). sn-1 acyltransferase activity in murine liver microsomes stereospecifically and preferentially utilized the naturally occurring L-enantiomer of the ether analog of lysophosphatidylcholine. Next, we demonstrated the high selectivity of the sn-1 acyltransferase activity for saturated acyl-CoA species. Importantly, we established that 2-15-hydroxyeicosatetraenoic acid (HETE) ether-LPC sn-1 esterification is markedly activated by thrombin treatment of murine platelets to generate oxidized PC. Collectively, these findings demonstrate the enantiomeric specificity and saturated acyl-CoA selectivity of microsomal sn-1 acyltransferase(s) and reveal its participation in a previously uncharacterized pathway for the synthesis of oxidized phospholipids with cell-signaling properties. [ABSTRACT FROM AUTHOR]

Published

2019

11. Defective fatty acid oxidation in mice with muscle-specific acyl-CoA synthetase 1 deficiency increases amino acid use and impairs muscle function.

Author

Liyang Zhao, Pascual, Florencia, Bacudio, Lawrence, Suchanek, Amanda L., Young, Pamela A., Lei O. Li, Martin, Sarah A., Camporez, Joao-Paulo, Perry, Rachel J., Shulman, Gerald I., Klett, Eric L., and Coleman, Rosalind A.

Subjects

*FATTY acid oxidation, *ACYL coenzyme A, *MUSCLE proteins, *SKELETAL muscle, *AMINO acids, *MUSCLE strength

Abstract

Loss of long-chain acyl-CoA synthetase isoform-1 (ACSL1) in mouse skeletal muscle (Acsl1M-/-) severely reduces acyl-CoA synthetase activity and fatty acid oxidation. However, the effects of decreased fatty acid oxidation on skeletal muscle function, histology, use of alternative fuels, and mitochondrial function and morphology are unclear. We observed that Acsl1M-/- mice have impaired voluntary running capacity and muscle grip strength and that their gastrocnemius muscle contains myocytes with central nuclei, indicating muscle regeneration. We also found that plasma creatine kinase and aspartate aminotransferase levels in Acsl1M-/- mice are 3.4- and 1.5-fold greater, respectively, than in control mice (Acsl1flox/flox), indicating muscle damage, even without exercise, in the Acsl1M-/- mice. Moreover, caspase-3 protein expression exclusively in Acsl1M-/- skeletal muscle and the presence of cleaved caspase-3 suggested myocyte apoptosis. Mitochondria in Acsl1M-/- skeletal muscle were swollen with abnormal cristae, and mitochondrial biogenesis was increased. Glucose uptake did not increase in Acsl1M-/- skeletal muscle, and pyruvate oxidation was similar in gastrocnemius homogenates from Acsl1M-/- and control mice. The rate of protein synthesis in Acsl1M-/- glycolytic muscle was 2.1-fold greater 30 min after exercise than in the controls, suggesting resynthesis of proteins catabolized for fuel during the exercise. At this time, mTOR complex 1 was activated, and autophagy was blocked. These results suggest that fatty acid oxidation is critical for normal skeletal muscle homeostasis during both rest and exercise. We conclude that ACSL1 deficiency produces an overall defect in muscle fuel metabolism that increases protein catabolism, resulting in exercise intolerance, muscle weakness, and myocyte apoptosis. [ABSTRACT FROM AUTHOR]

Published

2019

12. Structural basis for substrate specificity of methylsuccinyl-CoA dehydrogenase, an unusual member of the acyl-CoA dehydrogenase family.

Author

Schwander, Thomas, McLean, Richard, Zarzycki, Jan, and Erb, Tobias J.

Subjects

*ACYLTRANSFERASES, *ACYL coenzyme A, *DICARBOXYLIC acids, *CARBOXYL group, *CARBON metabolism, *CRYSTAL structure

Abstract

(2S)-methylsuccinyl-CoA dehydrogenase (MCD) belongs to the family of FAD-dependent acyl-CoA dehydrogenase (ACD) and is a key enzyme of the ethylmalonyl-CoA pathway for acetate assimilation. It catalyzes the oxidation of (2S)-methylsuccinyl- CoA to &3945;,β-unsaturated mesaconyl-CoA and shows only about 0.5% activity with succinyl-CoA. Here we report the crystal structure ofMCDat a resolution of 1.37 Å. The enzyme forms a homodimer of two 60-kDa subunits. Compared with other ACDs, MCD contains an ~ 170-residue-long N-terminal extension that structurally mimics a dimer-dimer interface of these enzymes that are canonically organized as tetramers. MCD catalyzes the unprecedented oxidation of an α-methyl branched dicarboxylic acid CoA thioester. Substrate specificity is achieved by a cluster of three arginines that accommodates the terminal carboxyl group and a dedicated cavity that facilitates binding of the C2 methyl branch. MCD apparently evolved toward preventing the nonspecific oxidation of succinyl-CoA, which is a close structural homolog of (2S)-methylsuccinyl-CoA and an essential intermediate in central carbon metabolism. For different metabolic engineering and biotechnological applications, however, an enzyme that can oxidize succinyl-CoA to fumaryl-CoA is sought after. Based on the MCD structure, we were able to shift substrate specificity of MCD toward succinyl- CoA through active-site mutagenesis. [ABSTRACT FROM AUTHOR]

Published

2018

13. An N-terminal di-proline motif is essential for fatty acid-dependent degradation of ∆9-desaturase in Drosophila.

Author

Akira Murakami, Kohjiro Nagao, Naoto Juni, Yuji Hara, and Masato Umeda

Subjects

*PROLINE, *FATTY acids, *DESATURASES, *ACYL coenzyme A, *GENE expression, *DROSOPHILA as laboratory animals

Abstract

The ∆9-fatty acid desaturase introduces a double bond at the ∆9 position of the acyl moiety of acyl-CoA and regulates the cellular levels of unsaturated fatty acids. However, it is unclear how ∆9-desaturase expression is regulated in response to changes in the levels of fatty acid desaturation. In this study, we found that the degradation of DESAT1, the sole ∆9-desaturase in the Drosophila cell line S2, was significantly enhanced when the amounts of unsaturated acyl chains of membrane phospholipids were increased by supplementation with unsaturated fatty acids, such as oleic and linoleic acids. In contrast, inhibition of DESAT1 activity remarkably suppressed its degradation. Of note, removal of the DESAT1 N-terminal domain abolished the responsiveness of DESAT1 degradation to the level of fatty acid unsaturation. Further truncation and amino acid replacement analyses revealed that two sequential prolines, the second and third residues of DESAT1, were responsible for the unsaturated fatty acid-dependent degradation. Although degradation of mouse stearoyl-CoA desaturase 1 (SCD1) was unaffected by changes in fatty acid unsaturation, introduction of the N-terminal sequential proline residues into SCD1 conferred responsiveness to unsaturated fatty acid-dependent degradation. Furthermore, we also found that the Ca2+-dependent cysteine protease calpain is involved in the sequential proline-dependent degradation of DESAT1. In light of these findings, we designated the sequential prolines at the second and third positions of DESAT1 as a "di-proline motif," which plays a crucial role in the regulation of ∆9-desaturase expression in response to changes in the level of cellular unsaturated fatty acids. [ABSTRACT FROM AUTHOR]

Published

2017

14. Myeloid Acyl-CoA:Cholesterol Acyltransferase 1 Deficiency Reduces Lesion Macrophage Content and Suppresses Atherosclerosis Progression.

Author

Li-Hao Huang, Melton, Elaina M., Haibo Li, Sohn, Paul, Rogers, Maximillian A., Mulligan-Kehoe, Mary Jo, Fiering, Steven N., Hickey, William F., Chang, Catherine C. Y., and Ta-Yuan Chang

Subjects

*ACYL coenzyme A, *MACROPHAGES, *ATHEROSCLEROSIS, *DISEASE progression, *CHOLESTEROL, *ACYLTRANSFERASES, *PATIENTS

Abstract

Acyl-CoA:cholesterol acyltransferase 1 (Acat1) converts cellular cholesterol to cholesteryl esters and is considered a drug target for treating atherosclerosis. However, in mouse models for atherosclerosis, global Acat1 knockout (Acat1-/-) did not prevent lesion development. Acat1-/- increased apoptosis within lesions and led to several additional undesirable phenotypes, including hair loss, dry eye, leukocytosis, xanthomatosis, and a reduced life span. To determine the roles of Acat1 in monocytes/macrophages in atherosclerosis, we produced a myeloid-specific Acat1 knockout (Acat1-M/-M) mouse and showed that, in the Apoe knockout (Apoe-/-) mouse model for atherosclerosis, Acat1-M/-M decreased the plaque area and reduced lesion size without causing leukocytosis, dry eye, hair loss, or a reduced life span. Acat1-M/-M enhanced xanthomatosis in apoe-/- mice, a skin disease that is not associated with diet-induced atherosclerosis in humans. Analyses of atherosclerotic lesions showed that Acat1-M/-M reduced macrophage numbers and diminished the cholesterol and cholesteryl ester load without causing detectable apoptotic cell death. Leukocyte migration analysis in vivo showed that Acat1-M/-M caused much fewer leukocytes to appear at the activated endothelium. Studies in inflammatory (Ly6Chi-positive) monocytes and in cultured macrophages showed that inhibiting ACAT1 by gene knockout or by pharmacological inhibition caused a significant decrease in integrin β 1 (CD29) expression in activated monocytes/macrophages. The sparse presence of lesion macrophages without Acat1 can therefore, in part, be attributed to decreased interaction between inflammatory monocytes/macrophages lacking Acat1 and the activated endothelium. We conclude that targeting ACAT1 in a myeloid cell lineage suppresses atherosclerosis progression while avoiding many of the undesirable side effects caused by global Acat1 inhibition. [ABSTRACT FROM AUTHOR]

Published

2016

15. Coordinative Modulation of Chlorothricin Biosynthesis by Binding of the Glycosylated Intermediates and End Product to a Responsive Regulator ChlF1.

Author

Yue Li, Jingjing Li, Zhenhua Tian, Yu Xu, Jihui Zhang, Wen Liu, and Huarong Tan

Subjects

*BIOSYNTHESIS, *GLYCOSYLATION, *ACYL coenzyme A, *CHEMICAL structure, *ANTIBACTERIAL agents

Abstract

Chlorothricin, isolated from Streptomyces antibioticus, is a parent member of spirotetronate family of antibiotics that have long been appreciated for their remarkable biological activities. ChlF1 plays bifunctional roles in chlorothricin biosynthesis by binding to its target genes (chlJ, chlF1, chlG, and chlK). The dissociation constants of ChlF1 to these genes are ~102-140 nM. A consensus sequence, 5'-GTAANNATTTAC-3', was found in these binding sites. ChlF1 represses the transcription of chlF1, chlG, and chlK but activates chlJ, which encodes a key enzyme acyl-CoA carboxyl transferase involved in the chlorothricin biosynthesis. We demonstrate that the end product chlorothricin and likewise its biosynthetic intermediates (demethylsalicycloyl chlorothricin and deschloro-chlorothricin) can act as signaling molecules to modulate the binding of ChlF1 to its target genes. Intriguingly, a correlation between the antibacterial activity and binding ability of signaling molecules to the regulator ChlF1 is clearly observed. These features of the signaling molecules are associated with the glycosylation of spirotetronate macrolide aglycone. The findings provide new insights into the TetR family regulators responding to special structure of signaling molecules, and we reveal the regulatory mini-network mediated by ChlF1 in chlorothricin biosynthesis for the first time. [ABSTRACT FROM AUTHOR]

Published

2016

16. Dysregulation of Plasmalogen Homeostasis Impairs Cholesterol Biosynthesis.

Author

Masanori Honsho, Yuichi Abe, and Yukio Fujiki

Subjects

*PLASMALOGENS, *HOMEOSTASIS, *CHOLESTEROL, *BIOSYNTHESIS, *ACYL coenzyme A, *REDUCTASES, *ISOPRENYLATION

Abstract

Plasmalogen biosynthesis is regulated by modulating fatty acyl-CoA reductase 1 stability in a manner dependent on cellular plasmalogen level. However, physiological significance of the regulation of plasmalogen biosynthesis remains unknown. Here we show that elevation of the cellular plasmalogen level reduces cholesterol biosynthesis without affecting the isoprenylation of proteins such as Rab and Pex19p. Analysis of intermediate metabolites in cholesterol biosynthesis suggests that the first oxidative step in cholesterol biosynthesis catalyzed by squalene monooxygenase (SQLE), an important regulator downstream HMG-CoA reductase in cholesterol synthesis, is reduced by degradation of SQLE upon elevation of cellular plasmalogen level. By contrast, the defect of plasmalogen synthesis causes elevation of SQLE expression, resulting in the reduction of 2,3- epoxysqualene required for cholesterol synthesis, hence implying a novel physiological consequence of the regulation of plasmalogen biosynthesis. [ABSTRACT FROM AUTHOR]

Published

2015

17. Increased Glucose Metabolism and Glycerolipid Formation by Fatty Acids and GPR40 Receptor Signaling Underlies the Fatty Acid Potentiation of Insulin Secretion.

Author

El-Azzouny, Mahmoud, Evans, Charles R., Treutelaar, Mary K., Kennedy, Robert T., and Burant, Charles F.

Subjects

*FATTY acids, *METABOLOMICS, *GLUCOSE, *ACYL coenzyme A, *GLYCEROLIPIDS, *GLYCOLYSIS

Abstract

Acute fatty acid (FA) exposure potentiates glucose-stimulated insulin secretion in β cells through metabolic and receptor-mediated effects. We assessed the effect of fatty acids on the dynamics of the metabolome in INS-1 cells following exposure to [U-13C]glucose to assess flux through metabolic pathways. Metabolite profiling showed a fatty acid-induced increase in long chain acyl-CoAs that were rapidly esterified with glucose-derived glycerol-3-phosphate to form lysophosphatidic acid, mono- and diacylglycerols, and other glycerolipids, some implicated in augmenting insulin secretion. Glucose utilization and glycolytic flux increased, along with a reduction in the NADH/ NAD+ ratio, presumably by an increase in conversion of dihydroxyacetone phosphate to glycerol-3-phosphate. The fatty acid-induced increase in glycolysis also resulted in increases in tricarboxylic cycle flux and oxygen consumption. Inhibition of fatty acid activation of FFAR1/GPR40 by an antagonist decreased glycerolipid formation, attenuated fatty acid increases in glucose oxidation, and increased mitochondrial FA flux, as evidenced by increased acylcarnitine levels. Conversely, FFAR1/ GPR40 activation in the presence of low FA increased flux into glycerolipids and enhanced glucose oxidation. These results suggest that, by remodeling glucose and lipid metabolism, fatty acid significantly increases the formation of both lipid- and TCA cycle-derived intermediates that augment insulin secretion, increasing our understanding of mechanisms underlying β cell insulin secretion. [ABSTRACT FROM AUTHOR]

Published

2014

18. Eleven residues determine the acyl chain specificity of ceramide synthases

Author

Rotem Tidhar, Alfred H. Merrill, Shifra Ben-Dor, Anthony H. Futerman, Giora Volpert, Samuel Kelly, and Iris D. Zelnik

Subjects

0301 basic medicine, Ceramide, Sequence Homology, Sequence (biology), Ceramides, Biochemistry, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Humans, Editors' Picks, Amino Acid Sequence, Molecular Biology, Peptide sequence, Ceramide synthase, Sphingolipids, Base Sequence, Mutagenesis, Cell Biology, Fusion protein, Sphingolipid, carbohydrates (lipids), Transmembrane domain, 030104 developmental biology, chemistry, 030220 oncology & carcinogenesis, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A, CRISPR-Cas Systems, Oxidoreductases

Abstract

Lipids display large structural complexity, with ∼40,000 different lipids identified to date, ∼4000 of which are sphingolipids. A critical factor determining the biological activities of the sphingolipid, ceramide, and of more complex sphingolipids is their N-acyl chain length, which in mammals is determined by a family of six ceramide synthases (CerS). Little information is available about the CerS regions that determine specificity toward different acyl-CoA substrates. We previously demonstrated that substrate specificity resides in a region of ∼150 residues in the Tram-Lag-CLN8 domain. Using site-directed mutagenesis and biochemical analyses, we now narrow specificity down to an 11-residue sequence in a loop located between the last two putative transmembrane domains (TMDs) of the CerS. The specificity of a chimeric protein, CerS5(299–309→CerS2), based on the backbone of CerS5 (which generates C16-ceramide), but containing 11 residues from CerS2 (which generates C22–C24-ceramides), was altered such that it generated C22–C24 and other ceramides. Moreover, a chimeric protein, CerS4(291–301→CerS2), based on CerS4 (which normally generates C18–C22 ceramides) displayed significant activity toward C24:1-CoA. Additional data supported the notion that substitutions of these 11 residues alter the specificities of the CerS toward their cognate acyl-CoAs. Our findings may suggest that this short loop may restrict adjacent TMDs, leading to a more open conformation in the membrane, and that the CerS acting on shorter acyl-CoAs may have a longer, more flexible loop, permitting TMD flexibility. In summary, we have identified an 11-residue region that determines the acyl-CoA specificity of CerS.

Published

2018

19. Thioesterase SuperfamilyMember 2/Acyl-CoA Thioesterase 13 (Them2/Acot13) Regulates Adaptive Thermogenesis in Mice.

Author

Hye Won Kang, Ozdemir, Cafer, Yuki Kawano, LeClair, Katherine B., Vernochet, Cecile, Kahn, C. Ronald, Hagen, Susan J., and Cohen, David E.

Subjects

*THIOESTERASE, *ESTERASES, *ACYL coenzyme A, *COENZYMES, *BODY temperature regulation

Abstract

Members of the acyl-CoA thioesterase (Acot) gene family hydrolyze fatty acyl-CoAs, but their biological functions remain incompletely understood. Thioesterase superfamily member 2 (Them2; synonym Acot13) is enriched in oxidative tissues, associated with mitochondria, and relatively specific for long chain fatty/ acyl-CoA substrates. Using Them2-/- mice, we have demonstrated key roles for Them2 in regulating hepatic glucose and lipid metabolism. However, reduced body weights and decreased adiposity in Them2-/- mice observed despite increased food consumption were not well explained. To explore a role in thermogenesis, mice were exposed to ambient temperatures ranging from thermoneutrality (30 °C) to cold (4 °C). In response to short term/ (24-h) exposures to decreasing ambient temperatures, Them2-/- mice exhibited increased adaptive responses in physical activity, food consumption, and energy expenditure when compared/ with Them2+/+ mice. By contrast, genotype-dependent differences were not observed in mice that were equilibrated (96 h) at each ambient temperature. In brown adipose tissue, the absence of Them2 was associated with reduced lipid droplets, alterations in the ultrastructure of mitochondria, and increased expression of thermogenic genes. Indicative of a direct regulatory role for Them2 in heat production, cultured primary brown adipocytes/ from Them2-/- mice exhibited increased norepinephrine-mediated triglyceride hydrolysis and increased rates of O2 consumption, together with elevated expression of thermogenic genes. At least in part by regulating intracellular fatty acid channeling, Them2 functions in brown adipose tissue to suppress adaptive increases in energy expenditure. [ABSTRACT FROM AUTHOR]

Published

2013

20. The pathogen-related yeast protein Pry1, a member of the CAP protein superfamily, is a fatty acid-binding protein

Author

David Gfeller, Rabih Darwiche, Laurent Mène-Saffrané, Roger Schneiter, and Oluwatoyin A. Asojo

Subjects

0301 basic medicine, Saccharomyces cerevisiae Proteins, Protein domain, Saccharomyces cerevisiae, Fatty Acid-Binding Proteins, Biochemistry, Fatty acid-binding protein, 03 medical and health sciences, Protein Domains, Fatty acid binding, Coenzyme A Ligases, Computer Simulation, Molecular Biology, chemistry.chemical_classification, biology, Microfilament Proteins, Fatty acid, Cell Biology, biology.organism_classification, Yeast, Metabolism, 030104 developmental biology, chemistry, Mutagenesis, Site-Directed, Free fatty acid receptor, biology.protein, Acyl Coenzyme A, Catabolite activator protein

Abstract

Members of the CAP superfamily (cysteine-rich secretory proteins, antigen 5, and pathogenesis-related 1 proteins), also known as SCP superfamily (sperm-coating proteins), have been implicated in many physiological processes, including immune defenses, venom toxicity, and sperm maturation. Their mode of action, however, remains poorly understood. Three proteins of the CAP superfamily, Pry1, -2, and -3 (pathogen related in yeast), are encoded in the Saccharomyces cerevisiae genome. We have shown previously that Pry1 binds cholesterol in vitro and that Pry function is required for sterol secretion in yeast cells, indicating that members of this superfamily may generally bind sterols or related small hydrophobic compounds. On the other hand, tablysin-15, a CAP protein from the horsefly Tabanus yao, has been shown to bind leukotrienes and free fatty acids in vitro. Therefore, here we assessed whether the yeast Pry1 protein binds fatty acids. Computational modeling and site-directed mutagenesis indicated that the mode of fatty acid binding is conserved between tablysin-15 and Pry1. Pry1 bound fatty acids with micromolar affinity in vitro, and its function was essential for fatty acid export in cells lacking the acyl-CoA synthetases Faa1 and Faa4. Fatty acid binding of Pry1 is independent of its capacity to bind sterols, and the two sterol- and fatty acid-binding sites are nonoverlapping. These results indicate that some CAP family members, such as Pry1, can bind different lipids, particularly sterols and fatty acids, at distinct binding sites, suggesting that the CAP domain may serve as a stable, secreted protein domain that can accommodate multiple ligand-binding sites.

Published

2017

21. Deficiency of a Retinal Dystrophy Protein, Acyl-CoA Binding Domain-containing 5 (ACBD5), Impairs Peroxisomal β-Oxidation of Very-long-chain Fatty Acids

Author

Fowzan S. Alkuraya, Mohammed Al-Owain, Yuichi Abe, Yuichi Yagita, Yukio Fujiki, Keiko Nakagawa, and Kyoko Shinohara

Subjects

0301 basic medicine, Biological Transport, Active, Biology, Biochemistry, 03 medical and health sciences, Acyl-CoA, chemistry.chemical_compound, Cytosol, 0302 clinical medicine, Protein Domains, Retinal Dystrophies, Peroxisomal disorder, Acyl-CoA-binding protein, Peroxisomes, medicine, Animals, Humans, Molecular Biology, Peroxisomal targeting signal, Adaptor Proteins, Signal Transducing, Fatty Acids, Membrane Proteins, Molecular Bases of Disease, Cell Biology, Peroxisome, medicine.disease, Cell biology, 030104 developmental biology, chemistry, Membrane protein, Acyl Coenzyme A, Rabbits, Oxidation-Reduction, 030217 neurology & neurosurgery, HeLa Cells, Binding domain

Abstract

Acyl-CoA binding domain-containing 5 (ACBD5) is a peroxisomal protein that carries an acyl-CoA binding domain (ACBD) at its N-terminal region. The recent identification of a mutation in the ACBD5 gene in patients with a syndromic form of retinal dystrophy highlights the physiological importance of ACBD5 in humans. However, the underlying pathogenic mechanisms and the precise function of ACBD5 remain unclear. We herein report that ACBD5 is a peroxisomal tail-anchored membrane protein exposing its ACBD to the cytosol. Using patient-derived fibroblasts and ACBD5 knock-out HeLa cells generated via genome editing, we demonstrate that ACBD5 deficiency causes a moderate but significant defect in peroxisomal β-oxidation of very-long-chain fatty acids (VLCFAs) and elevates the level of cellular phospholipids containing VLCFAs without affecting peroxisome biogenesis, including the import of membrane and matrix proteins. Both the N-terminal ACBD and peroxisomal localization of ACBD5 are prerequisite for efficient VLCFA β-oxidation in peroxisomes. Furthermore, ACBD5 preferentially binds very-long-chain fatty acyl-CoAs (VLC-CoAs). Together, these results suggest a direct role of ACBD5 in peroxisomal VLCFA β-oxidation. Based on our findings, we propose that ACBD5 captures VLC-CoAs on the cytosolic side of the peroxisomal membrane so that the transport of VLC-CoAs into peroxisomes and subsequent β-oxidation thereof can proceed efficiently. Our study reclassifies ACBD5-related phenotype as a novel peroxisomal disorder.

Published

2017

22. Substrate Trapping in Crystals of the Thiolase OleA Identifies Three Channels That Enable Long Chain Olefin Biosynthesis

Author

Carrie M. Wilmot, Fatuma A. Mohamed, Brandon R. Goblirsch, Matthew R. Jensen, and Lawrence P. Wackett

Subjects

Models, Molecular, 0301 basic medicine, Protein Conformation, Stereochemistry, Alkenes, Crystallography, X-Ray, Xanthomonas campestris, Biochemistry, Catalysis, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Residue (chemistry), Bacterial Proteins, Catalytic Domain, Transferase, Coenzyme A, Cysteine, Acetyl-CoA C-Acetyltransferase, Molecular Biology, Binding Sites, 030102 biochemistry & molecular biology, biology, Thiolase, Chemistry, Active site, Substrate (chemistry), Cell Biology, biology.organism_classification, 030104 developmental biology, Olea, Covalent bond, Mutation, Enzymology, biology.protein, Mutant Proteins, Acyl Coenzyme A, Crystallization, Acyl group

Abstract

Phylogenetically diverse microbes that produce long chain, olefinic hydrocarbons have received much attention as possible sources of renewable energy biocatalysts. One enzyme that is critical for this process is OleA, a thiolase superfamily enzyme that condenses two fatty acyl-CoA substrates to produce a β-ketoacid product and initiates the biosynthesis of long chain olefins in bacteria. Thiolases typically utilize a ping-pong mechanism centered on an active site cysteine residue. Reaction with the first substrate produces a covalent cysteine-thioester tethered acyl group that is transferred to the second substrate through formation of a carbon-carbon bond. Although the basics of thiolase chemistry are precedented, the mechanism by which OleA accommodates two substrates with extended carbon chains and a coenzyme moiety—unusual for a thiolase—are unknown. Gaining insights into this process could enable manipulation of the system for large scale olefin production with hydrocarbon chains lengths equivalent to those of fossil fuels. In this study, mutagenesis of the active site cysteine in Xanthomonas campestris OleA (Cys143) enabled trapping of two catalytically relevant species in crystals. In the resulting structures, long chain alkyl groups (C12 and C14) and phosphopantetheinate define three substrate channels in a T-shaped configuration, explaining how OleA coordinates its two substrates and product. The C143A OleA co-crystal structure possesses a single bound acyl-CoA representing the Michaelis complex with the first substrate, whereas the C143S co-crystal structure contains both acyl-CoA and fatty acid, defining how a second substrate binds to the acyl-enzyme intermediate. An active site glutamate (Gluβ117) is positioned to deprotonate bound acyl-CoA and initiate carbon-carbon bond formation.

Published

2016

23. Cloning of Glycerophosphocholine Acyltransferase (GPCAT) from Fungi and Plants

Author

Jana Patton-Vogt, Mirela Beganovic, Mengshu Hao, Antoni Banaś, Sten Stymne, Bartosz Głąb, Sanket Anaokar, Allan G. Rasmusson, and Ida Lager

Subjects

0301 basic medicine, glycerophospholipid, Saccharomyces cerevisiae Proteins, Acylation, Saccharomyces cerevisiae, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Biosynthesis, Acyl binding, acyltransferase, lipid metabolism, phosphatidylcholine, Molecular Biology, Plant Proteins, biology, Lysophosphatidylethanolamine, Cell Biology, Plants, biology.organism_classification, Lipids, Yeast, 030104 developmental biology, chemistry, Acyltransferases, plant biochemistry, Acyltransferase, Phosphatidylcholines, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A

Abstract

Glycero-3-phosphocholine (GPC), the product of the complete deacylation of phosphatidylcholine (PC), was long thought to not be a substrate for reacylation. However, it was recently shown that cell-free extracts from yeast and plants could acylate GPC with acyl groups from acyl-CoA. By screening enzyme activities of extracts derived from a yeast knock-out collection, we were able to identify and clone the yeast gene (GPC1) encoding the enzyme, named glycerophosphocholine acyltransferase (GPCAT). By homology search, we also identified and cloned GPCAT genes from three plant species. All enzymes utilize acyl-CoA to acylate GPC, forming lyso-PC, and they show broad acyl specificities in both yeast and plants. In addition to acyl-CoA, GPCAT efficiently utilizes LPC and lysophosphatidylethanolamine as acyl donors in the acylation of GPC. GPCAT homologues were found in the major eukaryotic organism groups but not in prokaryotes or chordates. The enzyme forms its own protein family and does not contain any of the acyl binding or lipase motifs that are present in other studied acyltransferases and transacylases. In vivo labeling studies confirm a role for Gpc1p in PC biosynthesis in yeast. It is postulated that GPCATs contribute to the maintenance of PC homeostasis and also have specific functions in acyl editing of PC (e.g. in transferring acyl groups modified at the sn-2 position of PC to the sn-1 position of this molecule in plant cells).

Published

2016

24. Allosteric Regulation of Mammalian Pantothenate Kinase

Author

Suzanne Jackowski, Mi-Kyung Yun, Lalit Kumar Sharma, Richard E. Lee, Stephen W. White, Jiangwei Yao, Charles O. Rock, and Chitra Subramanian

Subjects

0301 basic medicine, Conformational change, Stereochemistry, Allosteric regulation, Mutation, Missense, Cooperativity, Protomer, Biochemistry, Protein Structure, Secondary, 03 medical and health sciences, 0302 clinical medicine, Allosteric Regulation, Protein Domains, Humans, Transferase, Molecular Biology, biology, Active site, Cell Biology, Phosphotransferases (Alcohol Group Acceptor), 030104 developmental biology, Amino Acid Substitution, Cyclic nucleotide-binding domain, Protein Structure and Folding, biology.protein, Pantothenate kinase, Acyl Coenzyme A, 030217 neurology & neurosurgery

Abstract

Pantothenate kinase is the master regulator of CoA biosynthesis and is feedback-inhibited by acetyl-CoA. Comparison of the human PANK3·acetyl-CoA complex to the structures of PANK3 in four catalytically relevant complexes, 5′-adenylyl-β,γ-imidodiphosphate (AMPPNP)·Mg2+, AMPPNP·Mg2+·pantothenate, ADP·Mg2+·phosphopantothenate, and AMP phosphoramidate (AMPPN)·Mg2+, revealed a large conformational change in the dimeric enzyme. The amino-terminal nucleotide binding domain rotates to close the active site, and this allows the P-loop to engage ATP and facilitates required substrate/product interactions at the active site. Biochemical analyses showed that the transition between the inactive and active conformations, as assessed by the binding of either ATP·Mg2+ or acyl-CoA to PANK3, is highly cooperative indicating that both protomers move in concert. PANK3(G19V) cannot bind ATP, and biochemical analyses of an engineered PANK3/PANK3(G19V) heterodimer confirmed that the two active sites are functionally coupled. The communication between the two protomers is mediated by an α-helix that interacts with the ATP-binding site at its amino terminus and with the substrate/inhibitor-binding site of the opposite protomer at its carboxyl terminus. The two α-helices within the dimer together with the bound ligands create a ring that stabilizes the assembly in either the active closed conformation or the inactive open conformation. Thus, both active sites of the dimeric mammalian pantothenate kinases coordinately switch between the on and off states in response to intracellular concentrations of ATP and its key negative regulators, acetyl(acyl)-CoA.

Published

2016

25. Aspergillus oryzae CsyB Catalyzes the Condensation of Two β-Ketoacyl-CoAs to Form 3-Acetyl-4-hydroxy-6-alkyl-α-pyrone

Author

Makoto Hashimoto, Katsuhiko Kitamoto, Isao Fujii, Tsukasa Koen, Hiroaki Takahashi, and Chihiro Suda

Subjects

Stereochemistry, Aspergillus oryzae, Genes, Fungal, Dehydroacetic acid, Thioester, Models, Biological, Biochemistry, Catalysis, Substrate Specificity, Enzyme catalysis, Fungal Proteins, chemistry.chemical_compound, Polyketide, Acyl-CoA, Organic chemistry, Molecular Biology, chemistry.chemical_classification, Fungal protein, Molecular Structure, biology, fungi, Cell Biology, biology.organism_classification, Recombinant Proteins, Pyrone, Kinetics, chemistry, Pyrones, Enzymology, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A, Polyketide Synthases

Abstract

The type III polyketide synthases from fungi produce a variety of secondary metabolites including pyrones, resorcinols, and resorcylic acids. We previously reported that CsyB from Aspergillus oryzae forms α-pyrone csypyrone B compounds when expressed in A. oryzae. Feeding experiments of labeled acetates indicated that a fatty acyl starter is involved in the reaction catalyzed by CsyB. Here we report the in vivo and in vitro reconstitution analysis of CsyB. When CsyB was expressed in Escherichia coli, we observed the production of 3-acetyl-4-hydroxy-α-pyrones with saturated or unsaturated straight aliphatic chains of C9-C17 in length at the 6 position. Subsequent in vitro analysis using recombinant CsyB revealed that CsyB could accept butyryl-CoA as a starter substrate and malonyl-CoA and acetoacetyl-CoA as extender substrates to form 3-acetyl-4-hydroxy-6-propyl-α-pyrone. CsyB also afforded dehydroacetic acid from two molecules of acetoacetyl-CoA. Furthermore, synthetic N-acetylcysteamine thioester of β-ketohexanoic acid was converted to 3-butanoyl-4-hydroxy-6-propyl-α-pyrone by CsyB. These results therefore confirmed that CsyB catalyzed the synthesis of β-ketoacyl-CoA from the reaction of the starter fatty acyl CoA thioesters with malonyl-CoA as the extender through decarboxylative condensation and further coupling with acetoacetyl-CoA to form 3-acetyl-4-hydroxy-6-alkyl-α-pyrone. CsyB is the first type III polyketide synthase that synthesizes 3-acetyl-4-hydroxy-6-alkyl-α-pyrone by catalyzed the coupling of two β-ketoacyl-CoAs.

Published

2014

26. Candida albicans Utilizes a Modified β-Oxidation Pathway for the Degradation of Toxic Propionyl-CoA

Author

Christian Otzen, Markus Nett, Matthias Brock, Bettina Bardl, and Ilse D. Jacobsen

Subjects

Dehydrogenase, complex mixtures, Biochemistry, Microbiology, Fungal Proteins, Serine, Mice, chemistry.chemical_compound, Candida albicans, Animals, Molecular Biology, Beta oxidation, chemistry.chemical_classification, Mice, Inbred BALB C, biology, Fatty acid metabolism, Catabolism, Fatty Acids, Candidiasis, Cell Biology, Metabolic intermediate, biology.organism_classification, Metabolism, chemistry, Mutation, Propionate, lipids (amino acids, peptides, and proteins), Female, Acyl Coenzyme A, Propionates, Oxidation-Reduction, Metabolic Networks and Pathways

Abstract

Propionyl-CoA arises as a metabolic intermediate from the degradation of propionate, odd-chain fatty acids, and some amino acids. Thus, pathways for catabolism of this intermediate have evolved in all kingdoms of life, preventing the accumulation of toxic propionyl-CoA concentrations. Previous studies have shown that fungi generally use the methyl citrate cycle for propionyl-CoA degradation. Here, we show that this is not the case for the pathogenic fungus Candida albicans despite its ability to use propionate and valerate as carbon sources. Comparative proteome analyses suggested the presence of a modified β-oxidation pathway with the key intermediate 3-hydroxypropionate. Gene deletion analyses confirmed that the enoyl-CoA hydratase/dehydrogenase Fox2p, the putative 3-hydroxypropionyl-CoA hydrolase Ehd3p, the 3-hydroxypropionate dehydrogenase Hpd1p, and the putative malonate semialdehyde dehydrogenase Ald6p essentially contribute to propionyl-CoA degradation and its conversion to acetyl-CoA. The function of Hpd1p was further supported by the detection of accumulating 3-hydroxypropionate in the hpd1 mutant on propionyl-CoA-generating nutrients. Substrate specificity of Hpd1p was determined from recombinant purified enzyme, which revealed a preference for 3-hydroxypropionate, although serine and 3-hydroxyisobutyrate could also serve as substrates. Finally, virulence studies in a murine sepsis model revealed attenuated virulence of the hpd1 mutant, which indicates generation of propionyl-CoA from host-provided nutrients during infection.

Published

2014

27. Identification of Amino Acids Conferring Chain Length Substrate Specificities on Fatty Alcohol-forming Reductases FAR5 and FAR8 from Arabidopsis thaliana

Author

Owen Rowland, Ian P. Pulsifer, Frances Tran, Micaëla G. Chacón, Ashley E. Fournier, Frédéric Domergue, and Franziska Dittrich-Domergue

Subjects

Protein Folding, Stereochemistry, Arabidopsis, Mutation, Missense, Gene Expression, Plant Biology, Fatty alcohol, Saccharomyces cerevisiae, Biology, Biochemistry, Substrate Specificity, Serine, chemistry.chemical_compound, Valine, Enzyme Stability, Molecular Biology, chemistry.chemical_classification, Alanine, Methionine, Arabidopsis Proteins, Cell Biology, Protein engineering, Aldehyde Oxidoreductases, Recombinant Proteins, Amino acid, Amino Acid Substitution, chemistry, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A, Leucine

Abstract

Fatty alcohols play a variety of biological roles in all kingdoms of life. Fatty acyl reductase (FAR) enzymes catalyze the reduction of fatty acyl-coenzyme A (CoA) or fatty acyl-acyl carrier protein substrates to primary fatty alcohols. FAR enzymes have distinct substrate specificities with regard to chain length and degree of saturation. FAR5 (At3g44550) and FAR8 (At3g44560) from Arabidopsis thaliana are 85% identical at the amino acid level and are of equal length, but they possess distinct specificities for 18:0 or 16:0 acyl chain length, respectively. We used Saccharomyces cerevisiae as a heterologous expression system to assess FAR substrate specificity determinants. We identified individual amino acids that affect protein levels or 16:0-CoA versus 18:0-CoA specificity by expressing in yeast FAR5 and FAR8 domain-swap chimeras and site-specific mutants. We found that a threonine at position 347 and a serine at position 363 were important for high FAR5 and FAR8 protein accumulation in yeast and thus are likely important for protein folding and stability. Amino acids at positions 355 and 377 were important for dictating 16:0-CoA versus 18:0-CoA chain length specificity. Simultaneously converting alanine 355 and valine 377 of FAR5 to the corresponding FAR8 residues, leucine and methionine, respectively, almost fully converted FAR5 specificity from 18:0-CoA to 16:0-CoA. The reciprocal amino acid conversions, L355A and M377V, made in the active FAR8-S363P mutant background converted its specificity from 16:0-CoA to 18:0-CoA. This study is an important advancement in the engineering of highly active FAR proteins with desired specificities for the production of fatty alcohols with industrial value. Background: Fatty alcohols produced by fatty acyl reductases (FARs) have important biological roles. Results: Expression of Arabidopsis FAR5 and FAR8 mutants in yeast revealed amino acids important for their stability or substrate specificity. Conclusion: Amino acids 355 and 377 are 16:0 versus 18:0 chain length specificity determinants of FAR5 and FAR8. Significance: Engineered FAR enzymes with desired substrate specificities will enable production of high value products.

Published

2013

28. Diminished Acyl-CoA Synthetase Isoform 4 Activity in INS 832/13 Cells Reduces Cellular Epoxyeicosatrienoic Acid Levels and Results in Impaired Glucose-stimulated Insulin Secretion

Author

Matthew L. Edin, Darryl C. Zeldin, Lei O. Li, Shufen Chen, Eric L. Klett, Rosalind A. Coleman, Olga Ilkayeva, and Christopher B. Newgard

Subjects

endocrine system, medicine.medical_specialty, Blotting, Western, Glycerophospholipids, Biology, Epoxyeicosatrienoic acid, ACSL5, Biochemistry, Mitochondrial Proteins, Membrane Lipids, chemistry.chemical_compound, 8,11,14-Eicosatrienoic Acid, Cell Line, Tumor, Insulin-Secreting Cells, Internal medicine, Coenzyme A Ligases, Insulin Secretion, medicine, Animals, Insulin, Molecular Biology, Gene knockdown, Reverse Transcriptase Polymerase Chain Reaction, Activator (genetics), Fatty Acids, Cell Biology, Metabolism, Lipids, Rats, Gene Expression Regulation, Neoplastic, Glucose, Endocrinology, chemistry, Eicosanoid, cardiovascular system, Insulinoma, RNA Interference, lipids (amino acids, peptides, and proteins), Arachidonic acid, Acyl Coenzyme A, Beta cell, Oxidation-Reduction

Abstract

Glucose-stimulated insulin secretion (GSIS) in pancreatic beta-cells is potentiated by fatty acids (FA). The initial step in the metabolism of intracellular FA is the conversion to acyl-CoA by long chain acyl-CoA synthetases (Acsls). Because the predominantly expressed Acsl isoforms in INS 832/13 cells are Acsl4 and -5, we characterized the role of these Acsls in beta-cell function by using siRNA to knock down Acsl4 or Acsl5. Compared with control cells, an 80% suppression of Acsl4 decreased GSIS and FA-potentiated GSIS by 32 and 54%, respectively. Knockdown of Acsl5 did not alter GSIS. Acsl4 knockdown did not alter FA oxidation or long chain acyl-CoA levels. With Acsl4 knockdown, incubation with 17 mm glucose increased media epoxyeicosatrienoic acids (EETs) and reduced cell membrane levels of EETs. Further, exogenous EETs reduced GSIS in INS 832/13 cells, and in Acsl4 knockdown cells, an EET receptor antagonist partially rescued GSIS. These results strongly suggest that Acsl4 activates EETs to form EET-CoAs that are incorporated into glycerophospholipids, thereby sequestering EETs. Exposing INS 832/13 cells to arachidonate or linoleate reduced Acsl4 mRNA and protein expression and reduced GSIS. These data indicate that Acsl4 modulates GSIS by regulating the levels of unesterified EETs and that arachidonate controls the expression of its activator Acsl4.

Published

2013

29. Myristate-derived d16:0 Sphingolipids Constitute a Cardiac Sphingolipid Pool with Distinct Synthetic Routes and Functional Properties

Author

Rotem Tidhar, Sarah Brice Russo, Anthony H. Futerman, and L. Ashley Cowart

Subjects

Male, Programmed cell death, Ceramide, Cell Survival, Heart Ventricles, Saturated fat, Protein subunit, Serine C-Palmitoyltransferase, Gene Expression, Biology, Diet, High-Fat, Myristic Acid, Biochemistry, Gene Expression Regulation, Enzymologic, Cell Line, Substrate Specificity, Mice, chemistry.chemical_compound, Sphingosine N-Acyltransferase, Autophagy, Animals, Myocytes, Cardiac, Muscle, Skeletal, Molecular Biology, Ceramide synthase, Sphingolipids, Palmitoyl Coenzyme A, Myocardium, Serine C-palmitoyltransferase, Lipid metabolism, Cell Biology, Lipid Metabolism, Lipids, Sphingolipid, Biosynthetic Pathways, Rats, Isoenzymes, Mice, Inbred C57BL, Kinetics, chemistry, Cats, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A

Abstract

Myristate is a novel potential substrate for sphingoid base synthesis.Myocardial sphingoid base synthesis utilizes myristate; these sphingolipids are functionally non-redundant with canonical sphingoid bases.d16:0 and d16:1 sphingolipids constitute an appreciable proportion of cardiac dihydrosphingosine and dihydroceramide, with distinct biological roles.This pool of sphingolipids may play a heretofore unsuspected role in myocardial pathology or protection. The enzyme serine palmitoyltransferase (SPT) catalyzes the formation of the sphingoid base "backbone" from which all sphingolipids are derived. Previous studies have shown that inhibition of SPT ameliorates pathological cardiac outcomes in models of lipid overload, but the metabolites responsible for these phenotypes remain unidentified. Recent in vitro studies have shown that incorporation of the novel subunit SPTLC3 broadens the substrate specificity of SPT, allowing utilization of myristoyl-coenzyme A (CoA) in addition to its canonical substrate palmitoyl-CoA. However, the relevance of these findings in vivo has yet to be determined. The present study sought to determine whether myristate-derived d16 sphingolipids are represented among myocardial sphingolipids and, if so, whether their function and metabolic routes were distinct from those of palmitate-derived d18 sphingolipids. Data showed that d16:0 sphingoid bases occurred in more than one-third of total dihydrosphingosine and dihydroceramides in myocardium, and a diet high in saturated fat promoted their de novo production. Intriguingly, d16-ceramides demonstrated highly limited N-acyl chain diversity, and in vitro enzyme activity assays showed that these bases were utilized preferentially to canonical bases by CerS1. Functional differences between myristate- and palmitate-derived sphingolipids were observed in that, unlike d18 sphingolipids and SPTLC2, d16 sphingolipids and SPTLC3 did not appear to contribute to myristate-induced autophagy, whereas only d16 sphingolipids promoted cell death and cleavage of poly(ADP-ribose) polymerase in cardiomyocytes. Thus, these results reveal a previously unappreciated component of cardiac sphingolipids with functional differences from canonical sphingolipids.

Published

2013

30. Metabolome Response to Glucose in the β-Cell Line INS-1 832/13

Author

Charles F. Burant, Mahmoud A. El Azzouny, Robert T. Kennedy, and Matthew A. Lorenz

Subjects

Beta Cell, medicine.medical_treatment, Farnesyl pyrophosphate, Intermediary Metabolism, 030209 endocrinology & metabolism, Biology, Biochemistry, Cell Line, Mice, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Insulin-Secreting Cells, Insulin Secretion, medicine, Animals, Insulin, Metabolomics, Molecular Biology, 030304 developmental biology, Diacylglycerol kinase, 0303 health sciences, Cell Biology, Metabolism, Lipid Metabolism, Citric acid cycle, Metabolic pathway, Glucose, chemistry, Sweetening Agents, Metabolome, Acyl Coenzyme A, Beta cell, Energy Metabolism, Flux (metabolism)

Abstract

Background: The biochemical pathways underlying glucose-stimulated insulin secretion have not been fully elucidated. Results: Mass spectrometry analysis revealed rapid and substantial metabolic reprogramming evoked by glucose in INS-1 cells. Conclusion: Metabolomics allowed testing and generation of multiple hypotheses regarding glucose effects in insulin-secreting cells. Significance: Insights into the biochemical basis of glucose-stimulated insulin secretion are critical for understanding root causes of type 2 diabetes., Glucose-stimulated insulin secretion (GSIS) from pancreatic β-cells is triggered by metabolism of the sugar to increase ATP/ADP ratio that blocks the KATP channel leading to membrane depolarization and insulin exocytosis. Other metabolic pathways believed to augment insulin secretion have yet to be fully elucidated. To study metabolic changes during GSIS, liquid chromatography with mass spectrometry was used to determine levels of 87 metabolites temporally following a change in glucose from 3 to 10 mm glucose and in response to increasing concentrations of glucose in the INS-1 832/13 β-cell line. U-[13C]Glucose was used to probe flux in specific metabolic pathways. Results include a rapid increase in ATP/ADP, anaplerotic tricarboxylic acid cycle flux, and increases in the malonyl CoA pathway, support prevailing theories of GSIS. Novel findings include that aspartate used for anaplerosis does not derive from the glucose fuel added to stimulate insulin secretion, glucose flux into glycerol-3-phosphate, and esterification of long chain CoAs resulting in rapid consumption of long chain CoAs and de novo generation of phosphatidic acid and diacylglycerol. Further, novel metabolites with potential roles in GSIS such as 5-aminoimidazole-4-carboxamide ribotide (ZMP), GDP-mannose, and farnesyl pyrophosphate were found to be rapidly altered following glucose exposure.

Published

2013

31. An Electron-bifurcating Caffeyl-CoA Reductase

Author

Wolfgang Buckel, Volker Müller, Anutthaman Parthasarathy, and Johannes Bertsch

Subjects

inorganic chemicals, Enzyme complex, Iron, Reductase, Photochemistry, environment and public health, Microbiology, Biochemistry, Acetobacterium, Catalysis, Cofactor, chemistry.chemical_compound, Caffeic Acids, Bacterial Proteins, Oxidoreductase, Molecular Biology, Ferredoxin, Flavin adenine dinucleotide, chemistry.chemical_classification, Exergonic reaction, Flavoproteins, biology, Ferredoxin-thioredoxin reductase, Cell Biology, Aldehyde Oxidoreductases, enzymes and coenzymes (carbohydrates), Protein Subunits, chemistry, Flavin-Adenine Dinucleotide, biology.protein, bacteria, Acyl Coenzyme A, Oxidation-Reduction

Abstract

A low potential electron carrier ferredoxin (E0' ≈ -500 mV) is used to fuel the only bioenergetic coupling site, a sodium-motive ferredoxin:NAD(+) oxidoreductase (Rnf) in the acetogenic bacterium Acetobacterium woodii. Because ferredoxin reduction with physiological electron donors is highly endergonic, it must be coupled to an exergonic reaction. One candidate is NADH-dependent caffeyl-CoA reduction. We have purified a complex from A. woodii that contains a caffeyl-CoA reductase and an electron transfer flavoprotein. The enzyme contains three subunits encoded by the carCDE genes and is predicted to have, in addition to FAD, two [4Fe-4S] clusters as cofactor, which is consistent with the experimental determination of 4 mol of FAD, 9 mol of iron, and 9 mol of acid-labile sulfur. The enzyme complex catalyzed caffeyl-CoA-dependent oxidation of reduced methyl viologen. With NADH as donor, it catalyzed caffeyl-CoA reduction, but this reaction was highly stimulated by the addition of ferredoxin. Spectroscopic analyses revealed that ferredoxin and caffeyl-CoA were reduced simultaneously, and a stoichiometry of 1.3:1 was determined. Apparently, the caffeyl-CoA reductase-Etf complex of A. woodii uses the novel mechanism of flavin-dependent electron bifurcation to drive the endergonic ferredoxin reduction with NADH as reductant by coupling it to the exergonic NADH-dependent reduction of caffeyl-CoA.

Published

2013

32. Identification and Characterization of a Type III Polyketide Synthase Involved in Quinolone Alkaloid Biosynthesis from Aegle marmelos Correa

Author

E. V. Soniya, Rajesh S. Gokhale, Priyanka Verma, and Mohankumar Saraladevi Resmi

Subjects

Models, Molecular, Chalcone synthase, Aegle, Stereochemistry, Molecular Sequence Data, Plant Biology, Quinolones, Biology, Biochemistry, Mass Spectrometry, Substrate Specificity, chemistry.chemical_compound, Alkaloids, Chalcones, Protein structure, Biosynthesis, Catalytic Domain, Polyketide synthase, Amino Acid Sequence, Cloning, Molecular, Molecular Biology, Naringenin chalcone, Phylogeny, Plant Proteins, chemistry.chemical_classification, Base Sequence, Sequence Homology, Amino Acid, ATP synthase, Active site, Sequence Analysis, DNA, Cell Biology, Protein Structure, Tertiary, Amino acid, Kinetics, Amino Acid Substitution, chemistry, Mutation, Biocatalysis, biology.protein, Acyl Coenzyme A, Polyketide Synthases, Protein Binding

Abstract

Quinolone alkaloids, found abundantly in the roots of bael (Aegle marmelos), possess various biological activities and have recently gained attention as potential lead molecules for novel drug designing. Here, we report the characterization of a novel Type III polyketide synthase, quinolone synthase (QNS), from A. marmelos that is involved in the biosynthesis of quinolone alkaloid. Using homology-based structural modeling, we identify two crucial amino acid residues (Ser-132 and Ala-133) at the putative QNS active site. Substitution of Ser-132 to Thr and Ala-133 to Ser apparently constricted the active site cavity resulting in production of naringenin chalcone from p-coumaroyl-CoA. Measurement of steady-state kinetic parameters demonstrates that the catalytic efficiency of QNS was severalfold higher for larger acyl-coenzymeA substrates as compared with smaller precursors. Our mutagenic studies suggest that this protein might have evolved from an evolutionarily related member of chalcone synthase superfamily by mere substitution of two active site residues. The identification and characterization of QNS offers a promising target for gene manipulation studies toward the production of novel alkaloid scaffolds.

Published

2013

33. Physcomitrella PpORS, Basal to Plant Type III Polyketide Synthases in Phylogenetic Trees, Is a Very Long Chain 2′-Oxoalkylresorcinol Synthase

Author

Adam D. McInnes, Jordan R. Rothwell, Che C. Colpitts, Mitsuyasu Hasebe, Dae-Yeon Suh, Gertrud Wiedemann, Ralf Reski, Sun Young Kim, Christina Jepson, Mehrieh Rahimi, and Brian T. Sterenberg

Subjects

Physcomitrella, Mutant, Biology, Biochemistry, Catalysis, Gene Expression Regulation, Enzymologic, Bryopsida, Polyketide, Phylogenetics, Catalytic Domain, polycyclic compounds, Cloning, Molecular, Molecular Biology, Phylogeny, Oligonucleotide Array Sequence Analysis, Expressed Sequence Tags, Genetics, Binding Sites, ATP synthase, Phylogenetic tree, food and beverages, Active site, Cell Biology, biology.organism_classification, Recombinant Proteins, Kinetics, Models, Chemical, Mutation, Enzymology, Mutagenesis, Site-Directed, biology.protein, Acyl Coenzyme A, Polyketide Synthases, Protein Binding

Abstract

The plant type III polyketide synthases (PKSs), which produce diverse secondary metabolites with different biological activities, have successfully co-evolved with land plants. To gain insight into the roles that ancestral type III PKSs played during the early evolution of land plants, we cloned and characterized PpORS from the moss Physcomitrella. PpORS has been proposed to closely resemble the most recent common ancestor of the plant type III PKSs. PpORS condenses a very long chain fatty acyl-CoA with four molecules of malonyl-CoA and catalyzes decarboxylative aldol cyclization to yield the pentaketide 2′-oxoalkylresorcinol. Therefore, PpORS is a 2′-oxoalkylresorcinol synthase. Structure modeling and sequence alignments identified a unique set of amino acid residues (Gln218, Val277, and Ala286) at the putative PpORS active site. Substitution of the Ala286 to Phe apparently constricted the active site cavity, and the A286F mutant instead produced triketide alkylpyrones from fatty acyl-CoA substrates with shorter chain lengths. Phylogenetic analysis and comparison of the active sites of PpORS and alkylresorcinol synthases from sorghum and rice suggested that the gramineous enzymes evolved independently from PpORS to have similar functions but with distinct active site architecture. Microarray analysis revealed that PpORS is exclusively expressed in nonprotonemal moss cells. The in planta function of PpORS, therefore, is probably related to a nonprotonemal structure, such as the cuticle. Background: Physcomitrella PpORS is an ancient member of the plant type III polyketide synthase (PKS) family. Results: PpORS, produced in nonprotonemal moss cells, synthesizes pentaketide 2′-oxoalkylresorcinols using a unique substrate binding site. Conclusion: PpORS is a novel very long chain 2′-oxoalkylresorcinol synthase. Significance: This is the first step toward understanding the co-evolution of the type III PKS family and land plants.

Published

2013

34. Studies of Human 2,4-Dienoyl CoA Reductase Shed New Light on Peroxisomal β-Oxidation of Unsaturated Fatty Acids

Author

Jiangyun Wang, Dong Wu, Neil Shaw, Zhi-Jie Liu, Tian Hua, and Wei Ding

Subjects

Oxidoreductases Acting on CH-CH Group Donors, Stereochemistry, 2,4 Dienoyl-CoA reductase, Mitochondrion, Biology, Crystallography, X-Ray, Biochemistry, Catalysis, Oxidoreductase, Catalytic Domain, Peroxisomes, Humans, Fatty acid homeostasis, Molecular Biology, chemistry.chemical_classification, Catabolism, Cell Biology, Peroxisome, Protein Structure, Tertiary, Enzyme, chemistry, Protein Structure and Folding, Fatty Acids, Unsaturated, Acyl Coenzyme A, Oxidation-Reduction, NADP, Polyunsaturated fatty acid

Abstract

Peroxisomes play an essential role in maintaining fatty acid homeostasis. Although mitochondria are also known to participate in the catabolism of fatty acids via β-oxidation, differences exist between the peroxisomal and mitochondrial β-oxidation. Only peroxisomes, but not mitochondrion, can shorten very long chain fatty acids. Here, we describe the crystal structure of a ternary complex of peroxisomal 2,4-dienoyl CoA reductases (pDCR) with hexadienoyl CoA and NADP, as a prototype for comparison with the mitochondrial 2,4-dienoyl CoA reductase (mDCR) to shed light on the differences between the enzymes from the two organelles at the molecular level. Unexpectedly, the structure of pDCR refined to 1.84 Å resolution reveals the absence of the tyrosine-serine pair seen in the active site of mDCR, which together with a lysine and an asparagine have been deemed a hallmark of the SDR family of enzymes. Instead, aspartate hydrogen-bonded to the Cα hydroxyl via a water molecule seems to perturb the water molecule for protonation of the substrate. Our studies provide the first structural evidence for participation of water in the DCR-catalyzed reactions. Biochemical studies and structural analysis suggest that pDCRs can catalyze the shortening of six-carbon-long substrates in vitro. However, the K(m) values of pDCR for short chain acyl CoAs are at least 6-fold higher than those for substrates with 10 or more aliphatic carbons. Unlike mDCR, hinge movements permit pDCR to process very long chain polyunsaturated fatty acids.

Published

2012

35. Bacterial Acyl-CoA Mutase Specifically Catalyzes Coenzyme B12-dependent Isomerization of 2-Hydroxyisobutyryl-CoA and (S)-3-Hydroxybutyryl-CoA

Author

Nadya Yaneva, Denise Przybylski, Judith Schuster, Franziska Schäfer, Hauke Harms, Thore Rohwerder, Roland H. Müller, Torsten Paproth, and Vera Lede

Subjects

Spectrometry, Mass, Electrospray Ionization, Molecular Sequence Data, Hydroxybutyrates, Biochemistry, Cofactor, Substrate Specificity, Acyl-CoA, chemistry.chemical_compound, Mutase, Bacterial Proteins, Isomerism, Catalytic Domain, medicine, Amino Acid Sequence, cardiovascular diseases, Enzyme kinetics, Isoleucine, Intramolecular Transferases, Molecular Biology, chemistry.chemical_classification, Sequence Homology, Amino Acid, biology, Betaproteobacteria, Active site, Cell Biology, Hydrogen-Ion Concentration, Adenosylcobalamin, Kinetics, Protein Subunits, Vitamin B 12, Enzyme, chemistry, Mutation, Enzymology, Biocatalysis, biology.protein, lipids (amino acids, peptides, and proteins), Electrophoresis, Polyacrylamide Gel, Acyl Coenzyme A, medicine.drug

Abstract

Coenzyme B(12)-dependent acyl-CoA mutases are radical enzymes catalyzing reversible carbon skeleton rearrangements in carboxylic acids. Here, we describe 2-hydroxyisobutyryl-CoA mutase (HCM) found in the bacterium Aquincola tertiaricarbonis as a novel member of the mutase family. HCM specifically catalyzes the interconversion of 2-hydroxyisobutyryl- and (S)-3-hydroxybutyryl-CoA. Like isobutyryl-CoA mutase, HCM consists of a large substrate- and a small B(12)-binding subunit, HcmA and HcmB, respectively. However, it is thus far the only acyl-CoA mutase showing substrate specificity for hydroxylated carboxylic acids. Complete loss of 2-hydroxyisobutyric acid degradation capacity in hcmA and hcmB knock-out mutants established the central role of HCM in A. tertiaricarbonis for degrading substrates bearing a tert-butyl moiety, such as the fuel oxygenate methyl tert-butyl ether (MTBE) and its metabolites. Sequence analysis revealed several HCM-like enzymes in other bacterial strains not related to MTBE degradation, indicating that HCM may also be involved in other pathways. In all strains, hcmA and hcmB are associated with genes encoding for a putative acyl-CoA synthetase and a MeaB-like chaperone. Activity and substrate specificity of wild-type enzyme and active site mutants HcmA I90V, I90F, and I90Y clearly demonstrated that HCM belongs to a new subfamily of B(12)-dependent acyl-CoA mutases.

Published

2012

36. DHHC Protein S-Acyltransferases Use Similar Ping-Pong Kinetic Mechanisms but Display Different Acyl-CoA Specificities

Author

Maurine E. Linder and Benjamin C. Jennings

Subjects

Palmitoyl Coenzyme A, Chemistry, Acylation, Lipoylation, Tumor Suppressor Proteins, technology, industry, and agriculture, S-acylation, Substrate (chemistry), Cell Biology, Biochemistry, Substrate Specificity, Kinetics, chemistry.chemical_compound, Acyltransferases, Acyltransferase, Enzymology, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A, Fatty acylation, Molecular Biology, Acyl group, Cysteine

Abstract

DHHC proteins catalyze the reversible S-acylation of proteins at cysteine residues, a modification important for regulating protein localization, stability, and activity. However, little is known about the kinetic mechanism of DHHC proteins. A high-performance liquid chromatography (HPLC), fluorescent peptide-based assay for protein S-acylation activity was developed to characterize mammalian DHHC2 and DHHC3. Time courses and substrate saturation curves allowed the determination of V(max) and K(m) values for both the peptide N-myristoylated-GCG and palmitoyl-coenzyme A. DHHC proteins acylate themselves upon incubation with palmitoyl-CoA, which is hypothesized to reflect a transient acyl enzyme transfer intermediate. Single turnover assays with DHHC2 and DHHC3 demonstrated that a radiolabeled acyl group on the enzyme transferred to the protein substrate, consistent with a two-step ping-pong mechanism. Enzyme autoacylation and acyltransfer to substrate displayed the same acyl-CoA specificities, further supporting a two-step mechanism. Interestingly, DHHC2 efficiently transferred acyl chains 14 carbons and longer, whereas DHHC3 activity was greatly reduced by acyl-CoAs with chain lengths longer than 16 carbons. The rate and extent of autoacylation of DHHC3, as well as the rate of acyl chain transfer to protein substrate, were reduced with stearoyl-CoA when compared with palmitoyl-CoA. This is the first observation of lipid substrate specificity among DHHC proteins and may account for the differential S-acylation of proteins observed in cells.

Published

2012

37. Contributions of the Peroxisome and β-Oxidation Cycle to Biotin Synthesis in Fungi

Author

Yves Poirier, Syndie Delessert, Pasqualina Magliano, Michel Flipphi, and Bulak A. Arpat

Subjects

Auxotrophy, Mutant, Saccharomyces cerevisiae, Biotin, Biochemistry, Aspergillus nidulans, chemistry.chemical_compound, Gene Expression Regulation, Fungal, Escherichia coli, Peroxisomes, Molecular Biology, Oxidase test, ATP synthase, biology, fungi, Genetic Complementation Test, Cell Biology, Peroxisome, biology.organism_classification, Oxygen, Metabolism, chemistry, Mutation, biology.protein, Acyl Coenzyme A, Oxidation-Reduction, Gene Deletion

Abstract

The first step in the synthesis of the bicyclic rings of D-biotin is mediated by 8-amino-7-oxononanoate (AON) synthase, which catalyzes the decarboxylative condensation of l-alanine and pimelate thioester. We found that the Aspergillus nidulans AON synthase, encoded by the bioF gene, is a peroxisomal enzyme with a type 1 peroxisomal targeting sequence (PTS1). Localization of AON to the peroxisome was essential for biotin synthesis because expression of a cytosolic AON variant or deletion of pexE, encoding the PTS1 receptor, rendered A. nidulans a biotin auxotroph. AON synthases with PTS1 are found throughout the fungal kingdom, in ascomycetes, basidiomycetes, and members of basal fungal lineages but not in representatives of the Saccharomyces species complex, including Saccharomyces cerevisiae. A. nidulans mutants defective in the peroxisomal acyl-CoA oxidase AoxA or the multifunctional protein FoxA showed a strong decrease in colonial growth rate in biotin-deficient medium, whereas partial growth recovery occurred with pimelic acid supplementation. These results indicate that pimeloyl-CoA is the in vivo substrate of AON synthase and that it is generated in the peroxisome via the β-oxidation cycle in A. nidulans and probably in a broad range of fungi. However, the β-oxidation cycle is not essential for biotin synthesis in S. cerevisiae or Escherichia coli. These results suggest that alternative pathways for synthesis of the pimelate intermediate exist in bacteria and eukaryotes and that Saccharomyces species use a pathway different from that used by the majority of fungi.

Published

2011

38. Coenzyme A-dependent Aerobic Metabolism of Benzoate via Epoxide Formation

Author

Georg Fuchs, Liv J. Rather, Wolfgang Haehnel, and Bettina Knapp

Subjects

Oxygenase, Stereochemistry, Coenzyme A, Azoarcus, Epoxide, Oxygen Isotopes, Ring (chemistry), Benzoates, Biochemistry, Mass Spectrometry, Enzyme catalysis, chemistry.chemical_compound, Bacterial Proteins, Organic chemistry, Molecular Biology, Chromatography, High Pressure Liquid, DNA Primers, Flavin adenine dinucleotide, biology, Cell Biology, Chromosomes, Bacterial, biology.organism_classification, Aerobiosis, Oxygen, chemistry, Benzoyl-CoA, Flavin-Adenine Dinucleotide, Enzymology, Epoxy Compounds, Acyl Coenzyme A, Ditiocarb, NADP

Abstract

In the aerobic metabolism of aromatic substrates, oxygenases use molecular oxygen to hydroxylate and finally cleave the aromatic ring. In the case of the common intermediate benzoate, the ring cleavage substrates are either catechol (in bacteria) or 3,4-dihydroxybenzoate (protocatechuate, mainly in fungi). We have shown before that many bacteria, e.g. Azoarcus evansii, the organism studied here, use a completely different mechanism. This elaborate pathway requires formation of benzoyl-CoA, followed by an oxygenase reaction and a nonoxygenolytic ring cleavage. Benzoyl-CoA transformation is catalyzed by the iron-containing benzoyl-CoA oxygenase (BoxB) in conjunction with an FAD and iron-sulfur centers containing reductase (BoxA), which donates electrons from NADPH. Here we show that benzoyl-CoA oxygenase actually does not form the 2,3-dihydrodiol of benzoyl-CoA, as formerly postulated, but the 2,3-epoxide. An enoyl-CoA hydratase (BoxC) uses two molecules of water to first hydrolytically open the ring of 2,3-epoxybenzoyl-CoA, which may proceed via its tautomeric seven-membered oxepin ring form. Then ring C2 is hydrolyzed off as formic acid, yielding 3,4-dehydroadipyl-CoA semialdehyde. The semialdehyde is oxidized by a NADP(+)-dependent aldehyde dehydrogenase (BoxD) to 3,4-dehydroadipyl-CoA. Final products of the pathway are formic acid, acetyl-CoA, and succinyl-CoA. This overlooked pathway occurs in 4-5% of all bacteria whose genomes have been sequenced and represents an elegant strategy to cope with the high resonance energy of aromatic substrates by forming a nonaromatic epoxide.

Published

2010

39. Secondary Acylation of Vibrio cholerae Lipopolysaccharide Requires Phosphorylation of Kdo

Author

Jessica V. Hankins and M. Stephen Trent

Subjects

Acylation, Lipids and Lipoproteins: Metabolism, Regulation, and Signaling, Biology, medicine.disease_cause, Biochemistry, Sugar acids, Microbiology, Lipid A, chemistry.chemical_compound, Bacterial Proteins, Biosynthesis, medicine, Transferase, Phosphorylation, Vibrio cholerae, Molecular Biology, chemistry.chemical_classification, O Antigens, Sugar Acids, Cell Biology, chemistry, Acyltransferases, Acyltransferase, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A, Genome, Bacterial

Abstract

The lipopolysaccharide of Vibrio cholerae has been reported to contain a single 3-deoxy-d-manno-octulosonic acid (Kdo) residue that is phosphorylated. The phosphorylated Kdo sugar further links the hexa-acylated V. cholerae lipid A domain to the core oliogosaccharide and O-antigen. In this report, we confirm that V. cholerae possesses the enzymatic machinery to synthesize a phosphorylated Kdo residue. Further, we have determined that the presence of the phosphate group on the Kdo residue is necessary for secondary acylation in V. cholerae. The requirement for a secondary substituent on the Kdo residue (either an additional Kdo sugar or a phosphate group) was also found to be critical for secondary acylation catalyzed by LpxL proteins from Bordetella pertussis, Escherichia coli, and Haemophilus influenzae. Although three putative late acyltransferase orthologs have been identified in the V. cholerae genome (Vc0212, Vc0213, and Vc1577), only Vc0213 appears to be functional. Vc0213 functions as a myristoyl transferase acylating lipid A at the 2′-position of the glucosamine disaccharide. Generally acyl-ACPs serve as fatty acyl donors for the acyltransferases required for lipopolysaccharide biosynthesis; however, in vitro assays indicate that Vc0213 preferentially utilizes myristoyl-CoA as an acyl donor. This is the first report to biochemically characterize enzymes involved in the biosynthesis of the V. cholerae Kdo-lipid A domain.

Published

2009

40. Curcuminoid Biosynthesis by Two Type III Polyketide Synthases in the Herb Curcuma longa

Author

Nobutaka Funa, Sueharu Horinouchi, Yohei Katsuyama, and Tomoko Kita

Subjects

Time Factors, Stereochemistry, Biochemistry, Catalysis, chemistry.chemical_compound, Polyketide, Curcuma, Biosynthesis, Curcuminoid, Cloning, Molecular, Molecular Biology, Chromatography, High Pressure Liquid, Enzyme Catalysis and Regulation, biology, ATP synthase, Plant Extracts, Esters, Cell Biology, biology.organism_classification, Malonyl Coenzyme A, Kinetics, Metabolic pathway, Models, Chemical, chemistry, Spectrophotometry, Curcumin synthase, Curcumin, biology.protein, Acyl Coenzyme A, Polyketide Synthases

Abstract

Curcuminoids found in the rhizome of turmeric, Curcuma longa, possess various biological activities. Despite much attention regarding the biosynthesis of curcuminoids because of their pharmaceutically important properties and biosynthetically intriguing structures, no enzyme systems have been elucidated. Here we propose a pathway for curcuminoid biosynthesis in the herb C. longa, which includes two novel type III polyketide synthases. One of the type III polyketide synthases, named diketide-CoA synthase (DCS), catalyzed the formation of feruloyldiketide-CoA by condensing feruloyl-CoA and malonyl-CoA. The other, named curcumin synthase (CURS), catalyzed the in vitro formation of curcuminoids from cinnamoyldiketide-N-acetylcysteamine (a mimic of the CoA ester) and feruloyl-CoA. Co-incubation of DCS and CURS in the presence of feruloyl-CoA and malonyl-CoA yielded curcumin at high efficiency, although CURS itself possessed low activity for the synthesis of curcumin from feruloyl-CoA and malonyl-CoA. These findings thus revealed the curcumin biosynthetic route in turmeric, in which DCS synthesizes feruloyldiketide-CoA, and CURS then converts the diketide-CoA esters into a curcuminoid scaffold.

Published

2009

41. Acyl-CoA:Lysophospholipid Acyltransferases

Author

Hideo Shindou and Takao Shimizu

Subjects

Cell, MBOAT, Glycerophospholipids, Biology, Biochemistry, Substrate Specificity, chemistry.chemical_compound, Acyl-CoA, medicine, Animals, Humans, Molecular Biology, chemistry.chemical_classification, Cell Membrane, 1-Acylglycerophosphocholine O-Acyltransferase, Cell Biology, Cell biology, medicine.anatomical_structure, Enzyme, chemistry, Acyltransferases, Fatty Acids, Unsaturated, Arachidonic acid, Acyl Coenzyme A, Polyunsaturated fatty acid

Abstract

Cell membranes contain several classes of glycerophospholipids, which have numerous structural and functional roles in the cells. Polyunsaturated fatty acids, including arachidonic acid and eicosapentaenoic acid, are located at the sn-2 (but not sn-1)-position of glycerophospholipids in an asymmetrical manner. Using acyl-CoAs as donors, glycerophospholipids are formed by a de novo pathway (Kennedy pathway) and modified by a remodeling pathway (Lands' cycle) to generate membrane asymmetry and diversity. Both pathways were reported in the 1950s. Whereas enzymes involved in the Kennedy pathway have been well characterized, including enzymes in the 1-acylglycerol-3-phosphate O-acyltransferase family, little is known about enzymes involved in the Lands' cycle. Recently, several laboratories, including ours, isolated enzymes working in the remodeling pathway. These enzymes were discovered not only in the 1-acylglycerol-3-phosphate O-acyltransferase family but also in the membrane-bound O-acyltransferase family. In this review, we summarize recent studies on cloning and characterization of lysophospholipid acyltransferases that contribute to membrane asymmetry and diversity.

Published

2009

42. Metabolic Engineering of ω3-Very Long Chain Polyunsaturated Fatty Acid Production by an Exclusively Acyl-CoA-dependent Pathway

Author

Amine Abbadi, Mareike Hoffmann, Martin Fulda, Martin Wagner, and Ivo Feussner

Subjects

DNA, Complementary, Molecular Sequence Data, Restriction Mapping, Nutritional Status, Biochemistry, Metabolic engineering, chemistry.chemical_compound, Acyl-CoA, Biosynthesis, Arabidopsis, Animals, Humans, Arabidopsis thaliana, Cloning, Molecular, Molecular Biology, DNA Primers, Gene Library, Mammals, chemistry.chemical_classification, biology, Cell Biology, biology.organism_classification, Eicosapentaenoic acid, chemistry, Fatty Acids, Unsaturated, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A, Long chain fatty acid, Euglena, Polyunsaturated fatty acid

Abstract

omega3-Very long chain polyunsaturated fatty acids (VLCPUFA) are essential for human development and brain function and, thus, are indispensable components of the human diet. The current main source of VLCPUFAs is represented by ocean fish stocks, which are in severe decline, and the development of alternative, sustainable sources of VLCPUFAs is urgently required. Our research aims at exploiting the powerful infrastructure available for the large scale culture of oilseed crops, such as rapeseed, to produce VLCPUFAs such as eicosapentaenoic acid in transgenic plants. VLCPUFA biosynthesis requires repeated desaturation and repeated elongation of long chain fatty acid substrates. In previous experiments the production of eicosapentaenoic acid in transgenic plants was found to be limited by an unexpected bottleneck represented by the acyl exchange between the site of desaturation, endoplasmic reticulum-associated phospholipids, and the site of elongation, the cytosolic acyl-CoA pool. Here we report on the establishment of a coordinated, exclusively acyl-CoA-dependent pathway, which avoids the rate-limiting transesterification steps between the acyl lipids and the acyl-CoA pool during VLCPUFA biosynthesis. The pathway is defined by previously uncharacterized enzymes, encoded by cDNAs isolated from the microalga Mantoniella squamata. The conceptual enzymatic pathway was established and characterized first in yeast to provide proof-of-concept data for its feasibility and subsequently in seeds of Arabidopsis thaliana. The comparison of the acyl-CoA-dependent pathway with the known lipid-linked pathway for VLCPUFA biosynthesis showed that the acyl-CoA-dependent pathway circumvents the bottleneck of switching the Delta6-desaturated fatty acids between lipids and acyl-CoA in Arabidopsis seeds.

Published

2008

43. YLR099C (ICT1) Encodes a Soluble Acyl-CoA-dependent Lysophosphatidic Acid Acyltransferase Responsible for Enhanced Phospholipid Synthesis on Organic Solvent Stress in Saccharomyces cerevisiae

Author

Ram Rajasekharan, Geetha Ramakrishnan, and Ananda K. Ghosh

Subjects

Saccharomyces cerevisiae, Phosphatidic Acids, Lipids and Lipoproteins: Metabolism, Regulation, and Signaling, Biochemistry, Gene Expression Regulation, Enzymologic, chemistry.chemical_compound, Acyl-CoA, Gene Expression Regulation, Fungal, Lysophosphatidic acid, Hydrolase, Molecular Biology, biology, Cell Biology, Phosphatidic acid, biology.organism_classification, Recombinant Proteins, Protein Structure, Tertiary, Transmembrane domain, chemistry, Lysophospholipase, Enzyme Induction, Acyltransferase, Solvents, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A, Acyltransferases

Abstract

One of the major determinants of organic solvent tolerance is the increase in membrane phospholipids. Here we report for the first time that an increase in the synthesis of phosphatidic acid is responsible for enhanced phospholipid synthesis that confers tolerance to the organic solvent in Saccharomyces cerevisiae. This increase in phosphatidic acid formation is because of the induction of Ict1p, a soluble oleoyl-CoA:lysophosphatidic acid acyltransferase. YLR099C (ICT1) was reported to be maximally expressed during solvent tolerance (Miura, S., Zou, W., Ueda, M., and Tanaka, A. (2000) Appl. Environ. Microbiol. 66, 4883–4889); however, its physiological significance was not understood. In silico analysis revealed the absence of any transmembrane domain in Ict1p. Domain analysis showed that it has a hydrolase/acyltransferase domain with a distinct lipid-binding motif and a lysophospholipase domain. Analysis of ict1Δ strain showed a drastic reduction in phosphatidic acid suggesting the role of Ict1p in phosphatidic acid biosynthesis. Overexpression of Ict1p in S. cerevisiae showed an increase in phosphatidic acid and other phospholipids on organic solvent exposure. To understand the biochemical function of Ict1p, the gene was cloned and expressed in Escherichia coli. The purified recombinant enzyme was found to specifically acylate lysophosphatidic acid. Specific activity of Ict1p was found to be higher for oleoyl-CoA as compared with palmitoyl- and stearoyl-CoAs. This study provides a mechanism for organic solvent tolerance from the point of membrane dynamics in S. cerevisiae.

Published

2008

44. Reinvestigation of the Catalytic Mechanism of Formyl-CoA Transferase, a Class III CoA-transferase

Author

Ylva Lindqvist, Catrine L. Berthold, Cory G. Toyota, and Nigel G. J. Richards

Subjects

Protein Folding, Stereochemistry, Oxalobacter formigenes, Dimer, Carboxylic acid, Coenzyme A, Thioester, Biochemistry, Protein Structure, Secondary, Oxalate, chemistry.chemical_compound, Hydroxylamine, Bacterial Proteins, Transferase, Protein Structure, Quaternary, Molecular Biology, chemistry.chemical_classification, Oxalates, Binding Sites, biology, Active site, Cell Biology, Kinetics, chemistry, Mutation, biology.protein, Acyl Coenzyme A, Coenzyme A-Transferases, Dimerization

Abstract

Formyl-coenzyme A transferase from Oxalobacter formigenes belongs to the Class III coenzyme A transferase family and catalyzes the reversible transfer of a CoA carrier between formyl-CoA and oxalate, forming oxalyl-CoA and formate. Formyl-CoA transferase has a unique three-dimensional fold composed of two interlaced subunits locked together like rings of a chain. We here present an intermediate in the reaction, formyl-CoA transferase containing the covalent beta-aspartyl-CoA thioester, adopting different conformations in the two active sites of the dimer, which was identified through crystallographic freeze-trapping experiments with formyl-CoA and oxalyl-CoA in the absence of acceptor carboxylic acid. The formation of the enzyme-CoA thioester was also confirmed by mass spectrometric data. Further structural data include a trapped aspartyl-formyl anhydride protected by a glycine loop closing down over the active site. In a crystal structure of the beta-aspartyl-CoA thioester of an inactive mutant variant, oxalate was found bound to the open conformation of the glycine loop. Together with hydroxylamine trapping experiments and kinetic as well as mutagenesis data, the structures of these formyl-CoA transferase complexes provide new information on the Class III CoA-transferase family and prompt redefinition of the catalytic steps and the modified reaction mechanism of formyl-CoA transferase proposed here.

Published

2008

45. A Single Amino Acid Change Is Responsible for Evolution of Acyltransferase Specificity in Bacterial Methionine Biosynthesis

Author

Chloe Zubieta, Joseph M. Jez, Rebecca E. Cahoon, and Kiani A.J. Arkus

Subjects

Stereochemistry, Homoserine, Crystallography, X-Ray, Biochemistry, Substrate Specificity, Evolution, Molecular, chemistry.chemical_compound, Methionine, Bacillus cereus, Bacterial Proteins, Acetyl Coenzyme A, Acetyltransferases, Escherichia coli, Transferase, Binding site, Molecular Biology, chemistry.chemical_classification, biology, Homoserine O-Succinyltransferase, Cell Biology, biology.organism_classification, Protein Structure, Tertiary, Amino acid, Enzyme, Amino Acid Substitution, chemistry, Cereus, Acyltransferases, Acyl Coenzyme A

Abstract

Bacteria and yeast rely on either homoserine transsuccinylase (HTS, metA) or homoserine transacetylase (HTA; met2) for the biosynthesis of methionine. Although HTS and HTA catalyze similar chemical reactions, these proteins are typically unrelated in both sequence and three-dimensional structure. Here we present the 2.0 A resolution x-ray crystal structure of the Bacillus cereus metA protein in complex with homoserine, which provides the first view of a ligand bound to either HTA or HTS. Surprisingly, functional analysis of the B. cereus metA protein shows that it does not use succinyl-CoA as a substrate. Instead, the protein catalyzes the transacetylation of homoserine using acetyl-CoA. Therefore, the B. cereus metA protein functions as an HTA despite greater than 50% sequence identity with bona fide HTS proteins. This result emphasizes the need for functional confirmation of annotations of enzyme function based on either sequence or structural comparisons. Kinetic analysis of site-directed mutants reveals that the B. cereus metA protein and the E. coli HTS share a common catalytic mechanism. Structural and functional examination of the B. cereus metA protein reveals that a single amino acid in the active site determines acetyl-CoA (Glu-111) versus succinyl-CoA (Gly-111) specificity in the metA-like of acyltransferases. Switching of this residue provides a mechanism for evolving substrate specificity in bacterial methionine biosynthesis. Within this enzyme family, HTS and HTA activity likely arises from divergent evolution in a common structural scaffold with conserved catalytic machinery and homoserine binding sites.

Published

2008

46. Pentaketide Resorcylic Acid Synthesis by Type III Polyketide Synthase from Neurospora crassa

Author

Takayoshi Awakawa, Sueharu Horinouchi, and Nobutaka Funa

Subjects

Biology, Biochemistry, Mass Spectrometry, Neurospora crassa, Lactones, Hydrolysis, Polyketide, Cloning, Molecular, Molecular Biology, chemistry.chemical_classification, Molecular Structure, ATP synthase, Resorcinols, Cell Biology, biology.organism_classification, Salicylates, Kinetics, Open reading frame, Enzyme, chemistry, biology.protein, Aldol condensation, Acyl Coenzyme A, Chromatography, Thin Layer, Polyketide Synthases, Bacteria, Chromatography, Liquid

Abstract

Type III polyketide synthases (PKSs) are responsible for aromatic polyketide synthesis in plants and bacteria. Genome analysis of filamentous fungi has predicted the presence of fungal type III PKSs, although none have thus far been functionally characterized. In the genome of Neurospora crassa, a single open reading frame, NCU04801.1, annotated as a type III PKS was found. In this report, we demonstrate that NCU04801.1 is a novel type III PKS catalyzing the synthesis of pentaketide alkylresorcylic acids. NCU04801.1, hence named 2'-oxoalkylresorcylic acid synthase (ORAS), preferred stearoyl-CoA as a starter substrate and condensed four molecules of malonyl-CoA to give a pentaketide intermediate. For ORAS to yield pentaketide alkylresorcylic acids, aldol condensation and aromatization of the intermediate, which is still attached to the enzyme, are presumably followed by hydrolysis for release of the product as a resorcylic acid. ORAS is the first type III PKS that synthesizes pentaketide resorcylic acids.

Published

2007

47. Synergistic Potent Insulin Release by Combinations of Weak Secretagogues in Pancreatic Islets and INS-1 Cells

Author

Michael J. MacDonald

Subjects

medicine.medical_specialty, medicine.medical_treatment, Biology, Biochemistry, Exocytosis, Acetoacetates, Cell Line, Rats, Sprague-Dawley, Islets of Langerhans, Internal medicine, Insulin Secretion, medicine, Animals, Humans, Insulin, Molecular Biology, Pancreatic islets, Drug Synergism, Cell Biology, Metabolism, Lipid Metabolism, Rats, Insulin oscillation, Endocrinology, medicine.anatomical_structure, Secretagogue, Acyl Coenzyme A, Beta cell, Intracellular

Abstract

Insulin secretion by the beta cell depends on anaplerosis in which insulin secretagogues are metabolized by mitochondria into molecules that are most likely exported to the extramitochondrial space where they have signaling roles. However, very little is known about the products of anaplerosis. We discovered an experimental paradigm that has begun to provide new information about these products. When various intracellular metabolites were applied in combination to overnight-cultured rat or human pancreatic islets or to INS-1 832/13 cells, they interacted synergistically to strongly stimulate insulin release. When these same metabolites were applied individually to these cells, insulin stimulation was poor. Discerning the contributions of the individual compounds to metabolism has begun to allow us to dissect some of the pathways involved in insulin secretion, which was not possible from studying individual secretagogues. Monomethyl succinate (MMS) combined with a barely stimulatory concentration of α-ketoisocaproate (KIC) (2 mm) stimulated insulin release in cultured rat islets 18-fold (versus 21-fold for 16.7 mm glucose). MMS plus low glucose (2 mm) or pyruvate (5 mm) gave 11- and 9-fold stimulations. These agents also potentiated MMS-induced insulin release in fresh islets, and KIC plus MMS gave synergistic insulin release in cultured human islets. In INS-1 cells, neither MMS nor KIC (10 mm) was an insulin secretagogue, but when added together KIC (2 mm) and MMS stimulated insulin release 7-fold (versus 12-fold for glucose). In islets and INS-1 cells, conditions that stimulated insulin release caused large relative increases in acetoacetate, which is a precursor of pathways to short chain acyl-CoAs. Liquid chromatography-tandem mass spectrometry measurements of acetyl-CoA, acetoacetyl-CoA, succinyl-CoA, hydroxymethylglutaryl-CoA, and malonyl-CoA confirmed that they were increased by insulin secretagogues. The results suggest a new mechanism of insulin secretion in which anaplerosis increases short chain acyl-CoAs that have roles in insulin exocytosis.

Published

2007

48. Uptake and Utilization of Lyso-phosphatidylethanolamine by Saccharomyces cerevisiae

Author

Dennis R. Voelker and Wayne R. Riekhof

Subjects

Time Factors, Genotype, Auxotrophy, media_common.quotation_subject, Saccharomyces cerevisiae, Biology, Models, Biological, Biochemistry, chemistry.chemical_compound, Catalytic Domain, Internalization, Molecular Biology, Phospholipids, media_common, Phosphatidylethanolamine, Dose-Response Relationship, Drug, Models, Genetic, ATP synthase, Cell Membrane, Biological Transport, Cell Biology, Phosphatidylserine, biology.organism_classification, Yeast, chemistry, Acyltransferase, biology.protein, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A, Lysophospholipids, Gene Deletion

Abstract

Phosphatidylethanolamine (PtdEtn) is synthesized by multiple pathways located in different subcellular compartments in yeast. Strains defective in the synthesis of PtdEtn via phosphatidylserine (PtdSer) synthase/decarboxylase are auxotrophic for ethanolamine, which must be transported into the cell and converted to phospholipid by the cytidinediphosphate-ethanolamine-dependent Kennedy pathway. We now demonstrate that yeast strains with psd1Delta psd2Delta mutations, devoid of PtdSer decarboxylases, import and acylate exogenous 1-acyl-2-hydroxyl-sn-glycero-3-phosphoethanolamine (lyso-PtdEtn). Lyso-PtdEtn supports growth and replaces the mitochondrial pool of PtdEtn much more efficiently than and independently of PtdEtn derived from the Kennedy pathway. Deletion of both the PtdSer decarboxylase and Kennedy pathways yields a strain that is a stringent lyso-PtdEtn auxotroph. Evidence for the specific uptake of lyso-PtdEtn by yeast comes from analysis of strains harboring deletions of the aminophospholipid translocating P-type ATPases (APLTs). Elimination of the APLTs, Dnf1p and Dnf2p, or their noncatalytic beta-subunit, Lem3p, blocked the import of radiolabeled lyso-PtdEtn and resulted in growth inhibition of lyso-PtdEtn auxotrophs. In cell extracts, lyso-PtdEtn is rapidly converted to PtdEtn by an acyl-CoA-dependent acyltransferase. These results now provide 1) an assay for APLT function based on an auxotrophic phenotype, 2) direct demonstration of APLT action on a physiologically relevant substrate, and 3) a genetic screen aimed at finding additional components that mediate the internalization, trafficking, and acylation of exogenous lyso-phospholipids.

Published

2006

49. Unexpected Functional Diversity among FadR Fatty Acid Transcriptional Regulatory Proteins

Author

John E. Cronan and Surtaj H. Iram

Subjects

Hot Temperature, Time Factors, Transcription, Genetic, Entropy, lac operon, Plasma protein binding, Ligands, medicine.disease_cause, Biochemistry, Protein structure, Cloning, Molecular, Vibrio cholerae, Fatty Acids, Temperature, Salmonella enterica, Lac Operon, Plasmids, Protein Binding, Binding domain, Heterozygote, Pasteurella multocida, Blotting, Western, Molecular Sequence Data, Repressor, Calorimetry, Biology, Microbiology, Bacterial Proteins, Escherichia coli, medicine, Amino Acid Sequence, Molecular Biology, DNA Primers, Base Sequence, Sequence Homology, Amino Acid, Activator (genetics), Genetic Complementation Test, DNA, Gene Expression Regulation, Bacterial, Cell Biology, DNA-binding domain, Lipid Metabolism, beta-Galactosidase, Haemophilus influenzae, Protein Structure, Tertiary, Oxygen, Repressor Proteins, Kinetics, Acyl Coenzyme A, Oleic Acid

Abstract

The FadR protein of Escherichia coli has been shown to play a dual role in transcription of the genes of bacterial fatty acid metabolism. The protein acts as a repressor of beta-oxidation and an activator of unsaturated fatty acid synthesis. FadR DNA binding is antagonized by long chain acyl-CoAs, and thus FadR acts as a sensor of fatty acid availability in the environment. When viewed from a genomic viewpoint, FadR proteins are unusual in that the DNA binding domain is very highly conserved among FadR-containing bacteria, whereas the C-terminal acyl-CoA binding domain shows only weak conservation. To further our understanding of the role of FadR in bacterial lipid metabolism we have examined the in vivo and in vitro properties of a diverse set of FadR proteins expressed in E. coli. In addition to E. coli FadR the proteins examined were those of Salmonella enterica, Vibrio cholerae, Pasteurella multocida, and Haemophilus influenzae. These FadR proteins were found to differ markedly in their effects on repression and induction of beta-oxidation in E. coli and in their acyl-CoA binding abilities as measured by isothermal titration calorimetry. The E. coli and S. enterica proteins were the most similar, although they differed in their effects on utilization of oleic acid and acyl-CoA binding affinities, whereas the P. multocida and H. influenzae proteins showed only weak repression and poor acyl-CoA binding affinities. The V. cholerae FadR was strikingly superior to the other proteins in the amplitude of its regulatory response, and it bound long chain acyl-CoAs appreciably more strongly than the E. coli and S. enterica proteins. The significance of these findings is discussed in view of the protein sequences and the physiological niches occupied by these organisms.

Published

2005

50. Characterization of Four Variant Forms of Human Propionyl-CoA Carboxylase Expressed in Escherichia coli

Author

Hua Jiang, K. Sudhindra Rao, Jan P. Kraus, and Vivien C. Yee

Subjects

Models, Molecular, Protein Folding, Hot Temperature, Methylmalonyl-CoA Decarboxylase, Time Factors, Genotype, Protein Conformation, Ultraviolet Rays, Blotting, Western, Mutant, Biotin, Propionyl-CoA carboxylase, medicine.disease_cause, Biochemistry, Catalysis, Escherichia coli, medicine, Humans, Propionic acidemia, Molecular Biology, chemistry.chemical_classification, Polymorphism, Genetic, biology, Circular Dichroism, Temperature, Cell Biology, medicine.disease, Molecular biology, Recombinant Proteins, Protein Structure, Tertiary, Pyruvate carboxylase, Kinetics, Phenotype, Enzyme, chemistry, Chaperone (protein), Mutation, biology.protein, Electrophoresis, Polyacrylamide Gel, Acyl Coenzyme A, Methylmalonyl-CoA decarboxylase, Protein Binding

Abstract

Propionyl-CoA carboxylase (PCC) is a biotin-dependent mitochondrial enzyme that catalyzes the conversion of propionyl-CoA to D-methylmalonyl-CoA. PCC consists of two heterologous subunits, alpha PCC and beta PCC, which are encoded by the nuclear PCCA and PCCB genes, respectively. Deficiency of PCC results in a metabolic disorder, propionic acidemia, which is sufficiently severe to cause neonatal death. We have purified three PCCs containing pathogenic mutations in the beta subunit (R165W, E168K, and R410W) and one PCCB polymorphism (A497V) to homogeneity to elucidate the potential structural and functional effects of these substitutions. We observed no significant difference in Km values for propionyl-CoA between wild-type and the variant enzymes, which indicated that these substitutions had no effect on the affinity of the enzyme for this substrate. Furthermore, the kinetic studies indicated that mutation R410W was not involved in propionyl-CoA binding in contrast to a previous report. The three mutant PCCs had half the catalytic efficiency of wild-type PCC as judged by the kcat/Km ratios. No significant differences have been observed in molecular mass or secondary structure among these enzymes. However, the variant PCCs were less thermostable than the wild-type. Following incubation at 47 degrees C, blue native-PAGE revealed a lower oligomeric form (alpha2beta2) in the three mutants not detectable in wild-type and the polymorphism. Interestingly, the lower oligomeric form was also observed in the corresponding crude Escherichia coli extracts. Our biochemical data and the structural analysis using a beta PCC homology model indicate that the pathogenic nature of these mutations is more likely to be due to a lack of assembly rather than disruption of catalysis. The strong favorable effect of the co-expressed chaperone proteins on PCC folding, assembly, and activity suggest that propionic acidemia may be amenable to chaperone therapy.

Published

2005