Your search keyword '"Coenzyme A-Transferases biosynthesis"' showing total 18 results

1. Metabolic engineering of Escherichia coli for the production of four-, five- and six-carbon lactams.

Author

Chae TU, Ko YS, Hwang KS, and Lee SY

Subjects

Clostridium enzymology, Bacterial Proteins biosynthesis, Bacterial Proteins genetics, Clostridium genetics, Coenzyme A-Transferases biosynthesis, Coenzyme A-Transferases genetics, Escherichia coli genetics, Escherichia coli metabolism, Lactams metabolism, Metabolic Engineering methods

Abstract

Microbial production of chemicals and materials from renewable sources is becoming increasingly important for sustainable chemical industry. Here, we report construction of a new and efficient platform metabolic pathway for the production of four-carbon (butyrolactam), five-carbon (valerolactam) and six-carbon (caprolactam) lactams. This pathway uses ω-amino acids as precursors and comprises two steps. Activation of ω-amino acids catalyzed by the Clostridium propionicum β-alanine CoA transferase (Act) followed by spontaneous cyclization. The pathway operation was validated both in vitro and in vivo. Three metabolically engineered Escherichia coli strains were developed by introducing the newly constructed metabolic pathway followed by systems-level optimization, which resulted in the production of butyrolactam, valerolactam and caprolactam from renewable carbon source. In particular, fed-batch fermentation of the final engineered E. coli strain produced 54.14g/L of butyrolactam in a glucose minimal medium. These results demonstrate the high efficiency of the novel lactam pathway developed in this study., (Copyright © 2017 International Metabolic Engineering Society. Published by Elsevier Inc. All rights reserved.)

Published

2017

2. Successful adaptation to ketosis by mice with tissue-specific deficiency of ketone body oxidation.

Author

Cotter DG, Schugar RC, Wentz AE, d'Avignon DA, and Crawford PA

Subjects

Adaptation, Physiological, Animals, Animals, Newborn, Caloric Restriction adverse effects, Coenzyme A-Transferases biosynthesis, Coenzyme A-Transferases genetics, Heterozygote, Hypoglycemia etiology, Ketone Bodies blood, Ketosis blood, Ketosis etiology, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Muscle, Skeletal metabolism, Myocytes, Cardiac metabolism, Nerve Tissue Proteins biosynthesis, Nerve Tissue Proteins genetics, Nerve Tissue Proteins metabolism, Neurons metabolism, Organ Specificity, Oxidation-Reduction, Aging, Coenzyme A-Transferases metabolism, Ketone Bodies metabolism, Ketosis physiopathology, Muscle, Skeletal enzymology, Myocytes, Cardiac enzymology, Neurons enzymology

Abstract

During states of low carbohydrate intake, mammalian ketone body metabolism transfers energy substrates originally derived from fatty acyl chains within the liver to extrahepatic organs. We previously demonstrated that the mitochondrial enzyme coenzyme A (CoA) transferase [succinyl-CoA:3-oxoacid CoA transferase (SCOT), encoded by nuclear Oxct1] is required for oxidation of ketone bodies and that germline SCOT-knockout (KO) mice die within 48 h of birth because of hyperketonemic hypoglycemia. Here, we use novel transgenic and tissue-specific SCOT-KO mice to demonstrate that ketone bodies do not serve an obligate energetic role within highly ketolytic tissues during the ketogenic neonatal period or during starvation in the adult. Although transgene-mediated restoration of myocardial CoA transferase in germline SCOT-KO mice is insufficient to prevent lethal hyperketonemic hypoglycemia in the neonatal period, mice lacking CoA transferase selectively within neurons, cardiomyocytes, or skeletal myocytes are all viable as neonates. Like germline SCOT-KO neonatal mice, neonatal mice with neuronal CoA transferase deficiency exhibit increased cerebral glycolysis and glucose oxidation, and, while these neonatal mice exhibit modest hyperketonemia, they do not develop hypoglycemia. As adults, tissue-specific SCOT-KO mice tolerate starvation, exhibiting only modestly increased hyperketonemia. Finally, metabolic analysis of adult germline Oxct1(+/-) mice demonstrates that global diminution of ketone body oxidation yields hyperketonemia, but hypoglycemia emerges only during a protracted state of low carbohydrate intake. Together, these data suggest that, at the tissue level, ketone bodies are not a required energy substrate in the newborn period or during starvation, but rather that integrated ketone body metabolism mediates adaptation to ketogenic nutrient states.

Published

2013

3. Oxalate-degrading activity in Bifidobacterium animalis subsp. lactis: impact of acidic conditions on the transcriptional levels of the oxalyl coenzyme A (CoA) decarboxylase and formyl-CoA transferase genes.

Author

Turroni S, Bendazzoli C, Dipalo SC, Candela M, Vitali B, Gotti R, and Brigidi P

Subjects

Carboxy-Lyases genetics, DNA, Bacterial chemistry, DNA, Bacterial genetics, Gene Expression Profiling, Gene Expression Regulation, Bacterial drug effects, Gene Order, Molecular Sequence Data, Sequence Analysis, DNA, Transcription, Genetic, Bacterial Proteins biosynthesis, Bifidobacterium metabolism, Carboxy-Lyases biosynthesis, Coenzyme A-Transferases biosynthesis, Enzyme Activators metabolism, Gene Expression, Oxalates metabolism

Abstract

Oxalic acid occurs extensively in nature and plays diverse roles, especially in pathological processes. Due to its highly oxidizing effects, hyperabsorption or abnormal synthesis of oxalate can cause serious acute disorders in mammals and can be lethal in extreme cases. Intestinal oxalate-degrading bacteria could therefore be pivotal in maintaining oxalate homeostasis and reducing the risk of kidney stone development. In this study, the oxalate-degrading activities of 14 bifidobacterial strains were measured by a capillary electrophoresis technique. The oxc gene, encoding oxalyl-coenzyme A (CoA) decarboxylase, a key enzyme in oxalate catabolism, was isolated by probing a genomic library of Bifidobacterium animalis subsp. lactis BI07, which was one of the most active strains in the preliminary screening. The genetic and transcriptional organization of oxc flanking regions was determined, unraveling the presence of two other independently transcribed open reading frames, potentially responsible for the ability of B. animalis subsp. lactis to degrade oxalate. pH-controlled batch fermentations revealed that acidic conditions were a prerequisite for a significant oxalate degradation rate, which dramatically increased in cells first adapted to subinhibitory concentrations of oxalate and then exposed to pH 4.5. Oxalate-preadapted cells also showed a strong induction of the genes potentially involved in oxalate catabolism, as demonstrated by a transcriptional analysis using quantitative real-time reverse transcription-PCR. These findings provide new insights into the characterization of oxalate-degrading probiotic bacteria and may support the use of B. animalis subsp. lactis as a promising adjunct for the prophylaxis and management of oxalate-related kidney disease.

Published

2010

4. The Vibrio cholerae quorum-sensing autoinducer CAI-1: analysis of the biosynthetic enzyme CqsA.

Author

Kelly RC, Bolitho ME, Higgins DA, Lu W, Ng WL, Jeffrey PD, Rabinowitz JD, Semmelhack MF, Hughson FM, and Bassler BL

Subjects

Binding Sites, Coenzyme A-Transferases genetics, Models, Molecular, Mutagenesis, Site-Directed, Pyridoxal Phosphate chemistry, Signal Transduction, Substrate Specificity, Amines metabolism, Coenzyme A-Transferases biosynthesis, Ketones metabolism, Quorum Sensing, Vibrio cholerae enzymology

Abstract

Vibrio cholerae, the bacterium that causes the disease cholera, controls virulence factor production and biofilm development in response to two extracellular quorum-sensing molecules, called autoinducers. The strongest autoinducer, called CAI-1 (for cholera autoinducer-1), was previously identified as (S)-3-hydroxytridecan-4-one. Biosynthesis of CAI-1 requires the enzyme CqsA. Here, we determine the CqsA reaction mechanism, identify the CqsA substrates as (S)-2-aminobutyrate and decanoyl coenzyme A, and demonstrate that the product of the reaction is 3-aminotridecan-4-one, dubbed amino-CAI-1. CqsA produces amino-CAI-1 by a pyridoxal phosphate-dependent acyl-CoA transferase reaction. Amino-CAI-1 is converted to CAI-1 in a subsequent step via a CqsA-independent mechanism. Consistent with this, we find cells release > or =100 times more CAI-1 than amino-CAI-1. Nonetheless, V. cholerae responds to amino-CAI-1 as well as CAI-1, whereas other CAI-1 variants do not elicit a quorum-sensing response. Thus, both CAI-1 and amino-CAI-1 have potential as lead molecules in the development of an anticholera treatment.

Published

2009

5. Identification of genes required for Pseudomonas aeruginosa carnitine catabolism.

Author

Wargo MJ and Hogan DA

Subjects

Alcohol Oxidoreductases biosynthesis, Alcohol Oxidoreductases genetics, Betaine metabolism, Carnitine analogs & derivatives, Coenzyme A-Transferases biosynthesis, Coenzyme A-Transferases genetics, DNA Transposable Elements, Gene Expression Regulation, Bacterial, Operon, Pseudomonas aeruginosa genetics, Transcription Factors metabolism, Transcriptional Activation, Carnitine metabolism, Genes, Bacterial, Pseudomonas aeruginosa metabolism

Abstract

Carnitine is a quaternary amine compound prevalent in animal tissues, and a potential carbon, nitrogen and energy source for pathogens during infection. Characterization of activities in Pseudomonas aeruginosa cell lysates has previously shown that carnitine is converted to 3-dehydrocarnitine (3-dhc) which is in turn metabolized to glycine betaine (GB), an intermediate metabolite in the catabolism of carnitine to glycine. However, the identities of the enzymes required for carnitine catabolism were not known. We used a genetic screen of the P. aeruginosa PA14 transposon mutant library to identify genes required for growth on carnitine. We identified two genomic regions and their adjacent transcriptional regulators that are required for carnitine catabolism. The PA5388-PA5384 region contains the predicted P. aeruginosa carnitine dehydrogenase homologue along with other genes required for growth on carnitine. The second region identified, PA1999-PA2000, encodes the alpha and beta subunits of a predicted 3-ketoacid CoA-transferase, an enzymic activity hypothesized to be involved in the first step of deacetylation of 3-dhc. Furthermore, we confirmed that an intact GB catabolic pathway is required for growth on carnitine. The PA5389 and PA1998 transcription factors are required for growth on carnitine. PA5389 is required for induction of the PA5388-PA5384 transcripts in response to carnitine, and the PA1999-PA2000 transcripts are induced in a PA1998-dependent manner and induction appears to depend on a carnitine catabolite, possibly 3-dhc. These results provide important insight into elements required for carnitine catabolism in P. aeruginosa and probably in other bacteria.

Published

2009

6. Liver-specific silencing of the human gene encoding succinyl-CoA: 3-ketoacid CoA transferase.

Author

Orii KE, Fukao T, Song XQ, Mitchell GA, and Kondo N

Subjects

Base Sequence, Cell Line, Tumor, Cloning, Molecular, DNA Primers chemistry, HeLa Cells, Humans, Ketones metabolism, Liver enzymology, Mitochondria metabolism, Models, Genetic, Molecular Sequence Data, Promoter Regions, Genetic, Coenzyme A-Transferases biosynthesis, Coenzyme A-Transferases genetics, Gene Expression Regulation, Enzymologic, Gene Silencing, Liver metabolism

Abstract

The human succinyl-CoA: 3-ketoacid CoA transferase (SCOT) gene encodes the ketolytic enzyme that functions in the mitochondrial matrix. The activation of acetoacetate to acetoacetyl-CoA by SCOT is essential for the use of ketone bodies as an energy source. The ketolytic capacity of tissues is proportional to their level of SCOT activity. Normal hepatocytes, the site of ketone body synthesis, have no detectable SCOT protein. The absence of SCOT in hepatocytes is an important element in energy metabolism, suppressing ketolysis in the liver. To study the tissue-specific silencing of SCOT expression, we analyzed the promoter function of SCOT gene in three different human cell lines. Immunoblot analysis showed that SCOT protein was detectable in HeLa cervical cancer cells and Chang liver cells. However, SCOT protein was not detected in HepG2 hepatoma cells and liver tissues, indicating that HepG2 hepatoma cells maintain the characteristics of liver cells in the ketone body metabolism. Luciferase reporter assays in HeLa and Chang liver cells showed that the 361-bp proximal region of the SCOT gene was responsible for the basal promoter activity and contained two GC boxes, each of which was bound in vitro by Sp1, a ubiquitously expressed transcription factor. These results suggest that these GC boxes may be important for SCOT gene expression. Moreover, the region between -2168 and -361 appeared to inhibit the SCOT promoter activity in HepG2 cells. Thus, liver-specific silencing of the SCOT gene expression may be mediated in part by its 5'-flanking sequence.

Published

2008

7. cAMP-responsive element in TATA-less core promoter is essential for haploid-specific gene expression in mouse testis.

Author

Somboonthum P, Ohta H, Yamada S, Onishi M, Ike A, Nishimune Y, and Nozaki M

Subjects

5' Flanking Region, Animals, Base Sequence, Binding Sites, Coenzyme A-Transferases biosynthesis, Cyclic AMP metabolism, Cyclic AMP Response Element Modulator, Electroporation, Haploidy, Male, Mice, Mice, Transgenic, Molecular Sequence Data, Sequence Alignment, Spermatids metabolism, TATA Box, Transcription, Genetic, Transfection, Coenzyme A-Transferases genetics, DNA-Binding Proteins metabolism, Promoter Regions, Genetic, Response Elements, Testis metabolism, Transcription Factors metabolism

Abstract

Promoters, including neither TATA box nor initiator, have been frequently found in testicular germ cell-specific genes in mice. These investigations imply that unique forms of the polymerase II transcription initiation machinery play a role in selective activation of germ cell-specific gene expression programs during spermatogenesis. However, there is little information about testis-specific core promoters, because useful germ cell culture system is not available. In this study, we characterize the regulatory region of the haploid-specific Oxct2b gene in detail by using in vivo transient transfection assay in combination with a transgenic approach, with electrophoretic mobility shift and chromatin immunoprecipitation assays. Expression studies using mutant constructs demonstrate that a 34 bp region, which extends from -49 to -16, acts as a core promoter in an orientation-dependent manner. This promoter region includes the cAMP-responsive element (CRE)-like sequence TGACGCAG, but contains no other motifs, such as a TATA box or initiator. The CRE-like element is indispensable for the core promoter activity, but not for activator in testicular germ cells, through the binding of a testis-specific CRE modulator transcription factor. These results indicate the presence of alternative transcriptional initiation machinery for cell-type-specific gene expression in testicular germ cells.

Published

2005

8. Correlation between methylation profile of promoter cpg islands of seven metastasis-associated genes and their expression states in six cell lines of liver origin.

Author

Li JL, Fei Q, Yu J, Zhang HY, Wang P, and Zhu JD

Subjects

Calcium-Binding Proteins biosynthesis, Calcium-Binding Proteins genetics, Carcinoma, Hepatocellular metabolism, Carcinoma, Hepatocellular pathology, Cell Line, Tumor, Cells, Cultured, Coenzyme A-Transferases genetics, Gene Expression Regulation, Neoplastic, Humans, Integrin alpha Chains biosynthesis, Integrin alpha Chains genetics, Liver cytology, Liver metabolism, Liver Neoplasms pathology, Membrane Proteins biosynthesis, Membrane Proteins genetics, Mixed Function Oxygenases biosynthesis, Mixed Function Oxygenases genetics, Muscle Proteins biosynthesis, Muscle Proteins genetics, Promoter Regions, Genetic, RNA, Messenger biosynthesis, RNA, Messenger genetics, Coenzyme A-Transferases biosynthesis, CpG Islands genetics, DNA Methylation, Liver Neoplasms metabolism, Neoplasm Metastasis genetics

Abstract

Background & Objective: DNA methylation has been regarded as an important epigenetic signature reflecting the transcription state of DNA in cells. This study was to assess the correlation between methylation state of promoter CpG islands of metastasis-associated genes and their expression in 6 liver cell lines, including 5 cancerous., Methods: Methylation specific polymerase chain reaction method (MSP) and DNA sequencing verification were used to analyze the methylation state of promoter CpG islands of 7 genes (ASPH, ENO3, ITGA9, LRP6, MTHFD2, OXCT, and SRP72) in 5 liver cancer cell lines (BEL-7402, SMMC-7721, Hep3B, HepG2, and HCCLM3), and 1 immortalized liver cell line (L-02). Expression of 6 genes in this list was assessed by the semi-quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) method., Results: The methylation state of genes was either unmethylated or heterozygously methylated in these 7 liver cell lines. Except for no expression of OXCT gene was detected by RT-PCR in both HepG2 and HCCLM3 cells where it was heterozygously methylated, there was expression of genes in all the remaining cases., Conclusion: Although expression state of genes in this study supported the general notion that hypermethylation state of promoter CpG islands of genes represents the silenced state of gene transcription, there were exceptions. Therefore, other mechanisms are likely to contribute to the observed expression state of these 7 genes in this study.

Published

2004

9. Growth-inhibitory effects of the ketone body, monoacetoacetin, on human gastric cancer cells with succinyl-CoA: 3-oxoacid CoA-transferase (SCOT) deficiency.

Author

Sawai M, Yashiro M, Nishiguchi Y, Ohira M, and Hirakawa K

Subjects

Cell Division drug effects, Cell Line, Tumor, Coenzyme A-Transferases biosynthesis, Coenzyme A-Transferases genetics, Growth Inhibitors pharmacology, Humans, RNA, Messenger biosynthesis, RNA, Messenger genetics, Reverse Transcriptase Polymerase Chain Reaction, Stomach Neoplasms genetics, Stomach Neoplasms pathology, Acetoacetates pharmacology, Coenzyme A-Transferases deficiency, Glycerides pharmacology, Stomach Neoplasms drug therapy, Stomach Neoplasms enzymology

Abstract

Background: Monoacetoacetin (MAA) has been used experimentally as a physiological energy source in parenteral nutrition. Succinyl-CoA: 3-oxoacid CoA transferase (SCOT) is a key enzyme in the metabolism of MAA. In this study, the effect of MAA on the growth of human gastric cancer cells was examined in relation to SCOT expression., Materials and Methods: Four gastric cancer cell lines, OCUM-2M, MKN-28, MKN-45 and MKN-74, and two fibroblast cell lines were used in this study. The proliferation of gastric cancer cells was determined by MTT assay, by calculating the number of cancer cells, and by [3H]-thymidine uptake. Cells were cultured in DMEM containing 10% FBS with glucose (4.5 g/L) as the control or with MAA (4.5 g/L). SCOT mRNA expression was examined by RT-PCR., Results: The growth of OCUM-2M and MKN-28 cells was significantly suppressed in MAA medium compared with glucose medium. In contrast the growth of MKN-74, MKN-45 and normal fibroblasts was not suppressed in MAA medium. SCOT mRNA was expressed in MKN-45, MKN-74 and normal fibroblasts, but not in MKN-28 or OCUM-2M., Conclusion: Parenteral nutrition with MAA may provide preferential energy for patients with some types of gastric cancer with SCOT deficiency.

Published

2004

10. Overexpression of groESL in Clostridium acetobutylicum results in increased solvent production and tolerance, prolonged metabolism, and changes in the cell's transcriptional program.

Author

Tomas CA, Welker NE, and Papoutsakis ET

Subjects

1-Butanol pharmacology, Blotting, Western, Carboxy-Lyases biosynthesis, Clostridium genetics, Clostridium growth & development, Coenzyme A-Transferases biosynthesis, Fermentation, Gene Expression Profiling, HSP70 Heat-Shock Proteins analysis, Oligonucleotide Array Sequence Analysis, Bacterial Proteins physiology, Chaperonins physiology, Clostridium metabolism, Escherichia coli Proteins, Solvents metabolism, Transcription, Genetic

Abstract

DNA array and Western analyses were used to examine the effects of groESL overexpression and host-plasmid interactions on solvent production in Clostridium acetobutylicum ATCC 824. Strain 824(pGROE1) was created to overexpress the groESL operon genes from a clostridial thiolase promoter. The growth of 824(pGROE1) was inhibited up to 85% less by a butanol challenge than that of the control strain, 824(pSOS95del). Overexpression of groESL resulted in increased final solvent titers 40% and 33% higher than those of the wild type and plasmid control strains, respectively. Active metabolism lasted two and one half times longer in 824(pGROE1) than in the wild type. Transcriptional analysis of 824(pGROE1) revealed increased expression of motility and chemotaxis genes and a decrease in the expression of the other major stress response genes. Decreased expression of the dnaKJ operon upon overexpression of groESL suggests that groESL functions as a modulator of the CIRCE regulon, which is shown here to include the hsp90 gene. Analysis of the plasmid control strain 824(pSOS95del) revealed complex host-plasmid interactions relative to the wild-type strain, resulting in prolonged biphasic growth and metabolism. Decreased expression of four DNA gyrases resulted in differential expression of many key primary metabolism genes. The ftsA and ftsZ genes were expressed at higher levels in 824(pSOS95del), revealing an altered cell division and sporulation pattern. Both transcriptional and Western analyses revealed elevated stress protein expression in the plasmid-carrying strain.

Published

2003

11. Antisense RNA downregulation of coenzyme A transferase combined with alcohol-aldehyde dehydrogenase overexpression leads to predominantly alcohologenic Clostridium acetobutylicum fermentations.

Author

Tummala SB, Junne SG, and Papoutsakis ET

Subjects

Alcohol Dehydrogenase biosynthesis, Alcohols metabolism, Aldehyde Dehydrogenase biosynthesis, Bioreactors, Clostridium enzymology, Down-Regulation, Fermentation, Gene Expression Regulation, Bacterial, Gene Expression Regulation, Enzymologic, Protein Engineering, Alcohol Dehydrogenase genetics, Aldehyde Dehydrogenase genetics, Clostridium genetics, Coenzyme A-Transferases biosynthesis, RNA, Antisense metabolism, RNA, Bacterial metabolism

Abstract

Plasmid pAADB1 for the overexpression of the alcohol-aldehyde dehydrogenase (aad) gene and downregulation of the coenzyme A transferase (CoAT) using antisense RNA (asRNA) against ctfB (the second CoAT gene on the polycistronic aad-ctfA-ctfB message) was used in order to increase the butanol/acetone ratio of Clostridium acetobutylicum ATCC 824 fermentations. Acetone and butanol levels were drastically reduced in 824(pCTFB1AS) (expresses only an asRNA against ctfB) compared to 824(pSOS95del) (plasmid control). Compared to strain 824(pCTFB1AS), 824(pAADB1) fermentations exhibited two profound differences. First, butanol levels were ca. 2.8-fold higher in 824(pAADB1) and restored back to plasmid control levels, thus supporting the hypothesis that asRNA downregulation of ctfB leads to degradation of the whole aad-ctfA-ctfB transcript. Second, ethanol titers in 824(pAADB1) were ca. 23-fold higher and the highest (ca. 200 mM) ever reported in C. acetobutylicum. Western blot analysis confirmed that CoAT was downregulated in 824(pAADB1) at nearly the same levels as in strain 824(pCTFB1AS). Butyrate depletion in 824(pAADB1) fermentations suggested that butyryl-CoA was limiting butanol production in 824(pAADB1). This was confirmed by exogenously adding butyric acid to 824(pAADB1) fermentations to increase the butanol/ethanol ratio. DNA microarray analysis showed that aad overexpression profoundly affects the large-scale transcriptional program of the cells. Several classes of genes were differentially expressed [strain 824(pAADB1) versus strain 824(pCTFB1AS)], including genes of the stress response, sporulation, and chemotaxis. The expression patterns of the CoAT genes (ctfA and ctfB) and aad were consistent with the overexpression of aad and asRNA downregulation of ctfB.

Published

2003

12. [Acyl-CoA synthetase].

Author

Iwamoto-Kihara A and Kawaguchi A

Subjects

Adrenoleukodystrophy metabolism, Animals, Brain metabolism, Coenzyme A-Transferases biosynthesis, Coenzyme A-Transferases genetics, Humans, Liver metabolism, Rats, Coenzyme A-Transferases chemistry

Published

2001

13. Isolation and characterization of a haploid germ cell-specific novel complementary deoxyribonucleic acid; testis-specific homologue of succinyl CoA:3-Oxo acid CoA transferase.

Author

Koga M, Tanaka H, Yomogida K, Nozaki M, Tsuchida J, Ohta H, Nakamura Y, Masai K, Yoshimura Y, Yamanaka M, Iguchi N, Nojima H, Matsumiya K, Okuyama A, and Nishimune Y

Subjects

Amino Acid Sequence, Animals, Base Sequence, Blotting, Northern, Cell Fractionation, Cloning, Molecular, Coenzyme A-Transferases genetics, DNA, Complementary genetics, DNA, Complementary isolation & purification, Gene Library, Germ Cells enzymology, Germ Cells ultrastructure, Haploidy, Immunohistochemistry, In Situ Hybridization, Male, Mice, Mice, Inbred C57BL, Molecular Sequence Data, RNA analysis, RNA genetics, RNA isolation & purification, Testis ultrastructure, Coenzyme A-Transferases biosynthesis, DNA, Complementary metabolism, Germ Cells metabolism, Testis enzymology

Abstract

We have isolated a cDNA clone encoding a mouse haploid germ cell-specific protein from a subtracted cDNA library. Sequence analysis of the cDNA revealed high homology with pig and human heart succinyl CoA:3-oxo acid CoA transferase (EC 2.8.3.5), which is a key enzyme for energy metabolism of ketone bodies. The deduced protein consists of 520 amino acid residues, including glutamate 344, known to be the catalytic residue in the active site of pig heart CoA transferase and the expected mitochondrial targeting sequence enriched with Arg, Leu, and Ser in the N-terminal region. Thus, we termed this gene scot-t (testis-specific succinyl CoA:3-oxo acid CoA transferase). Northern blot analysis, in situ hybridization, and Western blot analysis demonstrated a unique expression pattern of the mRNA with rapid translation exclusively in late spermatids. The scot-t protein was detected first in elongated spermatids at step 8 or 9 as faint signals and gradually accumulated during spermiogenesis. It was also detected in the midpiece of spermatozoa by immunohistochemistry. The results suggest that the scot-t protein plays important roles in the energy metabolism of spermatozoa.

Published

2000

14. DNA sequencing and expression of the formyl coenzyme A transferase gene, frc, from Oxalobacter formigenes.

Author

Sidhu H, Ogden SD, Lung HY, Luttge BG, Baetz AL, and Peck AB

Subjects

Amino Acid Sequence, Bacterial Proteins biosynthesis, Bacterial Proteins genetics, Bacterial Proteins metabolism, Base Sequence, Cloning, Molecular, Coenzyme A-Transferases metabolism, Enzyme Activation genetics, Escherichia coli enzymology, Escherichia coli genetics, Gene Expression, Molecular Sequence Data, Coenzyme A-Transferases biosynthesis, Coenzyme A-Transferases genetics, Genes, Bacterial, Gram-Negative Anaerobic Bacteria enzymology, Gram-Negative Anaerobic Bacteria genetics

Abstract

Oxalic acid, a highly toxic by-product of metabolism, is catabolized by a limited number of bacterial species utilizing an activation-decarboxylation reaction which yields formate and CO2. frc, the gene encoding formyl coenzyme A transferase, an enzyme which transfers a coenzyme A moiety to activate oxalic acid, was cloned from the bacterium Oxalobacter formigenes. DNA sequencing revealed a single open reading frame of 1,284 bp capable of encoding a 428-amino-acid protein. A presumed promoter region and a rho-independent termination sequence suggest that this gene is part of a monocistronic operon. A PCR fragment containing the open reading frame, when overexpressed in Escherichia coli, produced a product exhibiting enzymatic activity similar to the purified native enzyme. With this, the two genes necessary for bacterial catabolism of oxalate, frc and oxc, have now been cloned, sequenced, and expressed.

Published

1997

15. Supraoperonic clustering of pca genes for catabolism of the phenolic compound protocatechuate in Agrobacterium tumefaciens.

Author

Parke D

Subjects

Adipates metabolism, Agrobacterium tumefaciens enzymology, Amino Acid Sequence, Base Sequence, Biological Evolution, Catechols metabolism, Cloning, Molecular, Coenzyme A-Transferases biosynthesis, Gene Expression Regulation, Bacterial, Molecular Sequence Data, Mutagenesis, Insertional, Restriction Mapping, Agrobacterium tumefaciens genetics, Genes, Bacterial genetics, Hydroxybenzoates metabolism, Multigene Family genetics, Operon genetics

Abstract

The protocatechuate branch of the beta-ketoadipate pathway comprises the last six enzymatic steps in the catabolism of diverse phenolic compounds to citric acid cycle intermediates. In this paper, the regulation and tight supraoperonic clustering of the protocatechuate (pca) genes from Agrobacterium tumefaciens A348 are elucidated. A previous study found that the pcaD gene is controlled by an adjacent regulatory gene, pcaQ, which encodes an activator. The activator responded to beta-carboxy-cis,cis-muconate and was shown to control the synthesis of at least three genes (pcaD and pcaHG). In this work, eight genes required for the catabolism of protocatechuate were localized within a 13.5-kb SalI region of DNA. Isolation and characterization of transposon Tn5 mutant strains facilitated the localization of pca genes. Five structural genes were found to respond to the tricarboxylic acid and to be contiguous in an operon transcribed in the order pcaDCHGB. These genes encode enzymes beta-ketoadipate enol-lactone hydrolase, gamma-carboxymuconolactone decarboxylase, protocatechuate 3,4-dioxygenase (pcaHG), and beta-carboxy-cis,cis-muconate lactonizing enzyme, respectively. Approximately 4 kb from the pcaD gene are the pcaIJ genes, which encode beta-ketoadipate succinyl-coenzyme A transferase for the next-to-last step of the pathway. The pcaIJ genes are transcribed divergently from the pcaDCHGB operon and are expressed in response to beta-ketoadipate. The pattern of induction of pca genes by beta-carboxy-cis,cis-muconate and beta-ketoadipate in A. tumefaciens is similar to that observed in Rhizobium leguminosarum bv. trifolii and is distinct from induction patterns for the genes from other microbial groups.

Published

1995

16. Regulation of succinyl coenzyme A:acetoacetyl coenzyme A transferase in rat hepatoma cell lines.

Author

Zhang WW, Lindahl R, and Churchill P

Subjects

Animals, Coenzyme A-Transferases biosynthesis, Coenzyme A-Transferases immunology, Female, Molecular Weight, Protein Biosynthesis, Rabbits, Rats, Rats, Inbred Strains, Tumor Cells, Cultured, Coenzyme A-Transferases analysis, Liver Neoplasms, Experimental enzymology

Abstract

The regulation of succinyl-CoA:acetoacetyl-CoA transferase (CoA transferase) has been studied in 8 rat hepatoma cell lines. Compared with normal rat hepatocytes, which have almost nondetectable activity of the enzyme, the hepatoma cell lines have a wide range of expression of CoA transferase activity, from as low as 45 nmol/min/mg to as high as 960 nmol/min/mg. Western blotting showed that the different levels of CoA transferase activity were due to differing amounts of the enzyme in the cells. This was further attributed to the varying amounts of the enzyme synthesized in the cells as monitored by L-[35S]methionine labeling followed by immunoprecipitation. To study further the differential expression of CoA transferase in the hepatoma cell lines, the relative quantity of functional CoA-transferase mRNA in the cells was measured by in vitro translation. The results showed that the levels of functional CoA transferase mRNA detected were consistent with the differences in the enzyme activity in the cells. Since CoA transferase is the key enzyme responsible for the utilization of ketone bodies as an alternative energy source, the expression of CoA transferase in hepatoma cells may play a role in energy production.

Published

1990

17. Cloning and expression of Clostridium acetobutylicum ATCC 824 acetoacetyl-coenzyme A:acetate/butyrate:coenzyme A-transferase in Escherichia coli.

Author

Cary JW, Petersen DJ, Papoutsakis ET, and Bennett GN

Subjects

Acetates metabolism, Amino Acid Sequence, Bacteriophages genetics, Base Sequence, Butyrates metabolism, Butyric Acid, Cloning, Molecular, Clostridium enzymology, Coenzyme A-Transferases biosynthesis, DNA, Bacterial analysis, DNA, Recombinant analysis, Gene Expression, Genes, Bacterial, Molecular Sequence Data, Oligonucleotide Probes, Restriction Mapping, Sequence Homology, Nucleic Acid, Clostridium genetics, Coenzyme A-Transferases genetics

Abstract

Coenzyme A (CoA)-transferase (acetoacetyl-CoA:acetate/butyrate:CoA-transferase [butyrate-acetoacetate CoA-transferase] [EC 2.8.3.9]) of Clostridium acetobutylicum ATCC 824 is an important enzyme in the metabolic shift between the acid-producing and solvent-forming states of this organism. The purification and properties of the enzyme have recently been described (D. P. Weisenborn, F. B. Rudolph, and E. T. Papoutsakis, Appl. Environ. Microbiol. 55:323-329, 1989). The genes encoding the two subunits of this enzyme have been cloned by using synthetic oligodeoxynucleotide probes designed from amino-terminal sequencing data from each subunit of the CoA-transferase. A bacteriophage lambda EMBL3 library of C. acetobutylicum DNA was prepared and screened by using these probes. Subsequent subcloning experiments established the position of the structural genes for CoA-transferase. Complementation of Escherichia coli ato mutants with the recombinant plasmid pCoAT4 (pUC19 carrying a 1.8-kilobase insert of C. acetobutylicum DNA encoding CoA-transferase activity) enabled the transformants to grow on butyrate as a sole carbon source. Despite the ability of CoA-transferase to complement the ato defect in E. coli mutants, Southern blot and Western blot (immunoblot) analyses showed that neither the C. acetobutylicum genes encoding CoA-transferase nor the enzyme itself shared any apparent homology with its E. coli counterpart. Polypeptides of Mr of the purified CoA-transferase subunits were observed by Western blot and maxicell analysis of whole-cell extracts of E. coli harboring pCoAT4. The proximity and orientation of the genes suggest that the genes encoding the two subunits of CoA-transferase may form an operon similar to that found in E. coli.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1990

18. A glucose-repressible gene encodes acetyl-CoA hydrolase from Saccharomyces cerevisiae.

Author

Lee FJ, Lin LW, and Smith JA

Subjects

Acetyl-CoA Hydrolase biosynthesis, Acetyl-CoA Hydrolase metabolism, Amino Acid Sequence, Base Sequence, Cloning, Molecular, Coenzyme A-Transferases biosynthesis, Coenzyme A-Transferases metabolism, Enzyme Repression, Gene Library, Molecular Sequence Data, Molecular Weight, Peptide Mapping, Protein Conformation, Restriction Mapping, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins biosynthesis, Saccharomyces cerevisiae Proteins metabolism, Trypsin, Acetyl-CoA Hydrolase genetics, Coenzyme A-Transferases genetics, Genes, Fungal drug effects, Glucose pharmacology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Thiolester Hydrolases genetics

Abstract

Acetyl-CoA hydrolase, catalyzing the hydrolysis of acetyl-CoA, is presumably involved in regulating the intracellular acetyl-CoA pool. Recently, a yeast acetyl-CoA hydrolase was purified to homogeneity from Saccharomyces cerevisiae and partially characterized (Lee, F.-J. S., Lin, L.-W., and Smith, J. A. (1989) Eur. J. Biochem. 184, 21-28). In order to study the biological function and regulation of the acetyl-CoA hydrolase, we cloned and sequenced the full length cDNA encoding yeast acetyl-CoA hydrolase. RNA blot analysis indicates that acetyl-CoA hydrolase is encoded by a 2.5-kilobase mRNA. DNA blot analyses of genomic and chromosomal DNA reveal that the gene (so-called ACH1, acetyl-CoA hydrolase) is present as a single copy located on chromosome II. Acetyl-CoA hydrolase is established to be a mannose-containing glycoprotein, which binds concanavalin A. By measuring the levels of ACH1 mRNA and acetyl-CoA hydrolase activity in different growth phases and by examining the effects of various carbon sources, we have demonstrated that ACH1 expression is repressed by glucose.

Published

1990