Your search keyword '"Substrate Specificity"' showing total 10,299 results

1. Distinct Cleavage Properties of Cathepsin B Compared to Cysteine Cathepsins Enable the Design and Validation of a Specific Substrate for Cathepsin B over a Broad pH Range.

Author

Yoon, Michael, Podvin, Sonia, Mosier, Charles, ODonoghue, Anthony, Hook, Vivian, and Phan, Von

Subjects

Cathepsin B, Cathepsins, Cysteine, Endopeptidases, Lysosomes, Peptides, Substrate Specificity

Abstract

The biological and pathological functions of cathepsin B occur in acidic lysosomes and at the neutral pH of cytosol, nuclei, and extracellular locations. Importantly, cathepsin B displays different substrate cleavage properties at acidic pH compared to neutral pH conditions. It is, therefore, desirable to develop specific substrates for cathepsin B that measure its activity over broad pH ranges. Current substrates used to monitor cathepsin B activity consist of Z-Phe-Arg-AMC and Z-Arg-Arg-AMC, but they lack specificity since they are cleaved by other cysteine cathepsins. Furthermore, Z-Arg-Arg-AMC monitors cathepsin B activity at neutral pH and displays minimal activity at acidic pH. Therefore, the purpose of this study was to design and validate specific fluorogenic peptide substrates that can monitor cathepsin B activity over a broad pH range from acidic to neutral pH conditions. In-depth cleavage properties of cathepsin B were compared to those of the cysteine cathepsins K, L, S, V, and X via multiplex substrate profiling by mass spectrometry at pH 4.6 and pH 7.2. Analysis of the cleavage preferences predicted the tripeptide Z-Nle-Lys-Arg-AMC as a preferred substrate for cathepsin B. Significantly, Z-Nle-Lys-Arg-AMC displayed the advantageous properties of measuring high cathepsin B specific activity over acidic to neutral pHs and was specifically cleaved by cathepsin B over the other cysteine cathepsins. Z-Nle-Lys-Arg-AMC specifically monitored cathepsin B activity in neuronal and glial cells which were consistent with relative abundances of cathepsin B protein. These findings validate Z-Nle-Lys-Arg-AMC as a novel substrate that specifically monitors cathepsin B activity over a broad pH range.

Published

2023

2. Structural Dynamics of Cytochrome P450 3A4 in the Presence of Substrates and Cytochrome P450 Reductase.

Author

Ducharme, Julie, Sevrioukova, Irina, Thibodeaux, Christopher, and Auclair, Karine

Subjects

Animals, Cytochrome P-450 CYP3A, Humans, Models, Molecular, NADPH-Ferrihemoprotein Reductase, Protein Binding, Protein Conformation, Protein Interaction Maps, Rats, Substrate Specificity

Abstract

Cytochrome P450 3A4 (CYP3A4) is the most important drug-metabolizing enzyme in humans and has been associated with harmful drug interactions. The activity of CYP3A4 is known to be modulated by several compounds and by the electron transfer partner, cytochrome P450 reductase (CPR). The underlying mechanism of these effects, however, is poorly understood. We have used hydrogen-deuterium exchange mass spectrometry to investigate the impact of binding of CPR and of three different substrates (7-benzyloxy-4-trifluoromethyl-coumarin, testosterone, and progesterone) on the conformational dynamics of CYP3A4. Here, we report that interaction of CYP3A4 with substrates or with the oxidized or reduced forms of CPR leads to a global rigidification of the CYP3A4 structure. This was evident from the suppression of deuterium exchange in several regions of CYP3A4, including regions known to be involved in protein-protein interactions (helix C) and substrate binding and specificity (helices B and E, and loop K/β1). Furthermore, the bimodal isotopic distributions observed for some CYP3A4-derived peptides were drastically impacted upon binding to CPR and/or substrates, suggesting the existence of stable CYP3A4 conformational populations that are perturbed by ligand/CPR binding. The results have implications for understanding the mechanisms of ligand binding, allostery, and catalysis in CYP enzymes.

Published

2021

3. Cofactor Complexes of DesD, a Model Enzyme in the Virulence-related NIS Synthetase Family

Author

Hoffmann, Katherine M, Goncuian, Eliana S, Karimi, Kimya L, Amendola, Caroline R, Mojab, Yasi, Wood, Kaitlin M, Prussia, Gregory A, Nix, Jay, Yamamoto, Margaret, Lathan, Kiera, and Orion, Iris W

Subjects

Biochemistry and Cell Biology, Biological Sciences, Adenosine Monophosphate, Adenosine Triphosphate, Bacterial Proteins, Kinetics, Peptide Synthases, Protein Conformation, Siderophores, Streptomyces coelicolor, Substrate Specificity, Virulence, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

The understudied nonribosomal-peptide-synthetase-independent siderophore (NIS) synthetase family has been increasingly associated with virulence in bacterial species due to its key role in the synthesis of hydroxamate and carboxylate "stealth" siderophores. We have identified a model family member, DesD, from Streptomyces coelicolor, to structurally characterize using a combination of a wild-type and a Arg306Gln variant in apo, cofactor product AMP-bound, and cofactor reactant ATP-bound complexes. The kinetics in the family has been limited by solubility and reporter assays, so we have developed a label-free kinetics assay utilizing a single-injection isothermal-titration-calorimetry-based method. We report second-order rate constants that are 50 times higher than the previous estimations for DesD. Our Arg306Gln DesD variant was also tested under identical buffer and substrate conditions, and its undetectable activity was confirmed. These are the first reported structures for DesD, and they describe the critical cofactor coordination. This is also the first label-free assay to unambiguously determine the kinetics for an NIS synthetase.

Published

2020

4. Unexpected Differences between Two Closely Related Bacterial P450 Camphor Monooxygenases.

Author

Murarka, Vidhi, Batabyal, Dipanwita, Amaya, Jose, Sevrioukova, Irina, and Poulos, Thomas

Subjects

Camphor, Camphor 5-Monooxygenase, Catalytic Domain, Crystallography, X-Ray, Molecular Dynamics Simulation, Oxidation-Reduction, Protein Conformation, Pseudomonas, Substrate Specificity, Thermodynamics

Abstract

The bacterial cytochrome P450cam catalyzes the oxidation of camphor to 5-exo-hydroxycamphor as the first step in the oxidative assimilation of camphor as a carbon/energy source. CYP101D1 is another bacterial P450 that catalyzes the same reaction. A third P450 (P450tcu) has recently been discovered that has ≈86% sequence identity to P450cam as well as very similar enzymatic properties. P450tcu, however, exhibits three unusual features not found in P450cam. First, we observe product in at least two orientations in the X-ray structure that indicates that, unlike the case for P450cam, X-ray-generated reducing equivalents can drive substrate hydroxylation in crystallo. We postulate, on the basis of molecular dynamics simulations, that greater flexibility in P450tcu enables easier access of protons to the active site and, together with X-ray driven reduction, results in O2 activation and substrate hydroxylation. Second, the characteristic low-spin to high-spin transition when camphor binds occurs immediately with P450cam but is very slow in P450tcu. Third, isothermal titration calorimetry shows that in P450cam substrate binding is entropically driven with a ΔH of >0 while in P450tcu with a ΔH of

Published

2020

5. Structure and Function of BorB, the Type II Thioesterase from the Borrelidin Biosynthetic Gene Cluster

Author

Curran, Samuel C, Pereira, Jose H, Baluyot, Marian-Joy, Lake, Julie, Puetz, Hendrik, Rosenburg, Daniel J, Adams, Paul, and Keasling, Jay D

Subjects

Biochemistry and Cell Biology, Biological Sciences, Emerging Infectious Diseases, Genetics, 1.1 Normal biological development and functioning, Underpinning research, Bacterial Proteins, Catalytic Domain, Fatty Acid Synthases, Kinetics, Multigene Family, Protein Engineering, Streptomyces, Substrate Specificity, Thiolester Hydrolases, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

α/β hydrolases make up a large and diverse protein superfamily. In natural product biosynthesis, cis-acting thioesterase α/β hydrolases can terminate biosynthetic assembly lines and release products by hydrolyzing or cyclizing the biosynthetic intermediate. Thioesterases can also act in trans, removing aberrant intermediates and restarting stalled biosynthesis. Knockout of this "editing" function leads to reduced product titers. The borrelidin biosynthetic gene cluster from Streptomyces parvulus Tü4055 contains a hitherto uncharacterized stand-alone thioesterase, borB. In this work, we demonstrate that purified BorB cleaves acyl substrates with a preference for propionate, which supports the hypothesis that it is also an editing thioesterase. The crystal structure of BorB shows a wedgelike hydrophobic substrate binding crevice that limits substrate length. To investigate the structure-function relationship, we made chimeric BorB variants using loop regions from characterized homologues with different specificities. BorB chimeras slightly reduced activity, arguing that the modified region is a not major determinant of substrate preference. The structure-function relationships described here contribute to the process of elimination for understanding thioesterase specificity and, ultimately, engineering and applying trans-acting thioesterases in biosynthetic assembly lines.

Published

2020

6. Structure of a Mycobacterium tuberculosis Heme-Degrading Protein, MhuD, Variant in Complex with Its Product

Author

Chao, Alex, Burley, Kalistyn H, Sieminski, Paul J, de Miranda, Rodger, Chen, Xiaorui, Mobley, David L, and Goulding, Celia W

Subjects

Biochemistry and Cell Biology, Biological Sciences, Rare Diseases, Infectious Diseases, Emerging Infectious Diseases, Tuberculosis, 2.1 Biological and endogenous factors, Aetiology, 2.2 Factors relating to the physical environment, Infection, Good Health and Well Being, Bacterial Proteins, Biliverdine, Crystallography, X-Ray, Heme, Humans, Mixed Function Oxygenases, Models, Molecular, Mycobacterium tuberculosis, Point Mutation, Protein Conformation, Substrate Specificity, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Mycobacterium tuberculosis (Mtb), the causative agent of tuberculosis, requires iron for survival. In Mtb, MhuD is the cytosolic protein that degrades imported heme. MhuD is distinct, in both sequence and structure, from canonical heme oxygenases (HOs) but homologous with IsdG-type proteins. Canonical HO is found mainly in eukaryotes, while IsdG-type proteins are predominantly found in prokaryotes, including pathogens. While there are several published structures of MhuD and other IsdG-type proteins in complex with the heme substrate, no structures of IsdG-type proteins in complex with a product have been reported, unlike the case for HOs. We recently showed that the Mtb variant MhuD-R26S produces biliverdin IXα (αBV) rather than the wild-type mycobilin isomers. Given that mycobilin and other IsdG-type protein products like staphylobilin are difficult to isolate in quantities sufficient for structure determination, here we use the MhuD-R26S variant and its product αBV as a proxy to study the IsdG-type protein-product complex. First, we show that αBV has a nanomolar affinity for MhuD and the R26S variant. Second, we determined the MhuD-R26S-αBV complex structure to 2.5 Å, which reveals two notable features: (1) two αBV molecules bound per active site and (2) a novel α-helix (α3) that was not observed in previous MhuD-heme structures. Finally, through molecular dynamics simulations, we show that α3 is stable with the proximal αBV alone. MhuD's high affinity for the product and the observed structural and electrostatic changes that accompany substrate turnover suggest that there may be an unidentified class of proteins that are responsible for the extraction of products from MhuD and other IsdG-type proteins.

Published

2019

7. An Intermediate Conformational State of Cytochrome P450cam-CN in Complex with Putidaredoxin

Author

Chuo, Shih-Wei, Wang, Lee-Ping, Britt, R David, and Goodin, David B

Subjects

Biochemistry and Cell Biology, Chemical Sciences, Biological Sciences, Generic health relevance, Bacterial Proteins, Binding Sites, Biocatalysis, Camphor 5-Monooxygenase, Catalytic Domain, Ferredoxins, Molecular Dynamics Simulation, Oxidation-Reduction, Protein Binding, Protein Conformation, Pseudomonas putida, Substrate Specificity, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Cytochrome P450cam is an archetypal example of the vast family of heme monooxygenases and serves as a model for an enzyme that is highly specific for both its substrate and reductase. During catalysis, it undergoes significant conformational changes of the F and G helices upon binding its substrate and redox partner, putidaredoxin (Pdx). Recent studies have shown that Pdx binding to the closed camphor-bound form of ferric P450cam results in its conversion to a fully open state. However, during catalytic turnover, it remains unclear whether this same conformational change also occurs or whether it is coupled to the formation of the critical compound I intermediate. Here, we have examined P450cam bound simultaneously by camphor, CN-, and Pdx as a mimic of the catalytically competent ferrous oxy-P450cam-Pdx state. The combined use of double electron-electron resonance and molecular dynamics showed direct observation of intermediate conformational states of the enzyme upon CN- and subsequent Pdx binding. This state is coupled to the movement of the I helix and residues at the active site, including Arg-186, Asp-251, and Thr-252. These movements enable occupation of a water molecule that has been implicated in proton delivery and peroxy bond cleavage to give compound I. These findings provide a detailed understanding of how the Pdx-induced conformational change may sequentially promote compound I formation followed by product release, while retaining stereoselective hydroxylation of the substrate of this highly specific monooxygenase.

Published

2019

8. Probing the Electrostatic and Steric Requirements for Substrate Binding in Human Platelet-Type 12-Lipoxygenase.

Author

Aleem, Ansari, Tsai, Wan-Chen, Tena, Jennyfer, Alvarez, Gabriella, Deschamps, Joshua, Kalyanaraman, Chakrapani, Jacobson, Matthew, and Holman, Ted|Theodore

Subjects

Arachidonate 12-Lipoxygenase, Arachidonic Acid, Blood Platelets, Catalysis, Catalytic Domain, Humans, Kinetics, Molecular Docking Simulation, Mutagenesis, Site-Directed, Mutation, Protein Binding, Static Electricity, Substrate Specificity

Abstract

Human platelet ALOX12 (hALOX12 or h12-LOX) has been implicated in a variety of human diseases. The present study investigates the active site of hALOX12 to more thoroughly understand how it positions the substrate and achieves nearly perfect regio- and stereospecificities (i.e., 100 ± 5% of the 12(S)-hydroperoxide product), utilizing site-directed mutagenesis. Specifically, we have determined that Arg402 is not as important in substrate binding as previously seen for hALOX15 but that His596 may play a role in anchoring the carboxy terminal of the arachidonic acid during catalysis. In addition, Phe414 creates a π-stacking interaction with a double bond of arachidonic acid (Δ11), and Ala417/Val418 define the bottom of the cavity. However, the influence of Ala417/Val418 on the profile is markedly less for hALOX12 than that seen in hALOX15. Mutating these two residues to larger amino acids (Ala417Ile/Val418Met) only increased the generation of 15-HpETE by 24 ± 2%, but conversely, smaller residues at these positions converted hALOX15 to almost 100% hALOX12 reactivity [Gan et al. (1996) J. Biol. Chem. 271, 25412-25418]. However, we were able to increase 15-HpETE to 46 ± 3% by restricting the width of the active site with the Ala417Ile/Val418Met/Ser594Thr mutation, indicating both depth and width of the active site are important. Finally, residue Leu407 is shown to play a critical role in positioning the substrate correctly, as seen by the increase of 15-HpETE to 21 ± 1% for the single Leu407Gly mutant. These results outline critical differences between the active site requirements of hALOX12 relative to hALOX15 and explain both their product specificity and inhibitory differences.

Published

2019

9. Recent Structural Insights into Polycomb Repressive Complex 2 Regulation and Substrate Binding

Author

Kasinath, Vignesh, Poepsel, Simon, and Nogales, Eva

Subjects

Genetics, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Gene Expression Regulation, Histones, Humans, Methylation, Methyltransferases, Models, Molecular, Polycomb Repressive Complex 2, Protein Conformation, Repressor Proteins, Substrate Specificity, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Polycomb group proteins are transcriptional repressors controlling gene expression patterns and maintaining cell type identity. The chemical modifications of histones and DNA caused by the regulated activity of chromatin-modifying enzymes such as Polycomb help establish and maintain such expression patterns. Polycomb repressive complex 2 (PRC2) is the only known methyltransferase specific for histone H3 lysine 27 (H3K27) and catalyzes its trimethylation leading to the repressive H3K27me3 mark. Structural biology has made important contributions to our understanding of the molecular mechanisms that ensure the spatiotemporal regulation of PRC2 activity and the establishment of inactive chromatin domains marked by H3K27me3. In this review, we discuss the recent structural studies that have advanced our understanding of PRC2 function, in particular the roles of intersubunit interactions in complex assembly and the regulation of methyltransferase activity, as well as the mechanism of local H3K27me3 spreading leading to repressive domains.

Published

2019

10. 5 S,15 S-Dihydroperoxyeicosatetraenoic Acid (5,15-diHpETE) as a Lipoxin Intermediate: Reactivity and Kinetics with Human Leukocyte 5-Lipoxygenase, Platelet 12-Lipoxygenase, and Reticulocyte 15-Lipoxygenase-1.

Author

Green, Abigail, Freedman, Cody, Tena, Jennyfer, Tourdot, Benjamin, Liu, Benjamin, Holinstat, Michael, and Holman, Theodore

Subjects

Arachidonate 12-Lipoxygenase, Arachidonate 15-Lipoxygenase, Arachidonate 5-Lipoxygenase, Biocatalysis, Biosynthetic Pathways, Blood Platelets, Humans, Hydroxyeicosatetraenoic Acids, Kinetics, Leukocytes, Leukotrienes, Lipid Peroxides, Lipoxins, Reticulocytes, Substrate Specificity

Abstract

The reaction of 5 S,15 S-dihydroperoxyeicosatetraenoic acid (5,15-diHpETE) with human 5-lipoxygenase (LOX), human platelet 12-LOX, and human reticulocyte 15-LOX-1 was investigated to determine the reactivity and relative rates of producing lipoxins (LXs). 5-LOX does not react with 5,15-diHpETE, although it can produce LXA4 when 15-HpETE is the substrate. In contrast, both 12-LOX and 15-LOX-1 react with 5,15-diHpETE, forming specifically LXB4. For 12-LOX and 5,15-diHpETE, the kinetic parameters are kcat = 0.17 s-1 and kcat/ KM = 0.011 μM-1 s-1 [106- and 1600-fold lower than those for 12-LOX oxygenation of arachidonic acid (AA), respectively]. On the other hand, for 15-LOX-1 the equivalent parameters are kcat = 4.6 s-1 and kcat/ KM = 0.21 μM-1 s-1 (3-fold higher and similar to those for 12-HpETE formation by 15-LOX-1 from AA, respectively). This contrasts with the complete lack of reaction of 15-LOX-2 with 5,15-diHpETE [Green, A. R., et al. (2016) Biochemistry 55, 2832-2840]. Our data indicate that 12-LOX is markedly inferior to 15-LOX-1 in catalyzing the production of LXB4 from 5,15-diHpETE. Platelet aggregation was inhibited by the addition of 5,15-diHpETE, with an IC50 of 1.3 μM; however, LXB4 did not significantly inhibit collagen-mediated platelet activation up to 10 μM. In summary, LXB4 is the primary product of 12-LOX and 15-LOX-1 catalysis, if 5,15-diHpETE is the substrate, with 15-LOX-1 being 20-fold more efficient than 12-LOX. LXA4 is the primary product with 5-LOX but only if 15-HpETE is the substrate. Approximately equal proportions of LXA4 and LXB4 are produced by 12-LOX but only if LTA4 is the substrate, as described previously [Sheppard, K. A., et al. (1992) Biochim. Biophys. Acta 1133, 223-234].

Published

2018

11. 5S,15S‑Dihydroperoxyeicosatetraenoic Acid (5,15-diHpETE) as a Lipoxin Intermediate: Reactivity and Kinetics with Human Leukocyte 5‑Lipoxygenase, Platelet 12-Lipoxygenase, and Reticulocyte 15-Lipoxygenase‑1

Author

Green, Abigail R, Freedman, Cody, Tena, Jennyfer, Tourdot, Benjamin E, Liu, Benjamin, Holinstat, Michael, and Holman, Theodore R

Subjects

Arachidonate 12-Lipoxygenase, Arachidonate 15-Lipoxygenase, Arachidonate 5-Lipoxygenase, Biocatalysis, Biosynthetic Pathways, Blood Platelets, Humans, Hydroxyeicosatetraenoic Acids, Kinetics, Leukocytes, Leukotrienes, Lipid Peroxides, Lipoxins, Reticulocytes, Substrate Specificity, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

The reaction of 5 S,15 S-dihydroperoxyeicosatetraenoic acid (5,15-diHpETE) with human 5-lipoxygenase (LOX), human platelet 12-LOX, and human reticulocyte 15-LOX-1 was investigated to determine the reactivity and relative rates of producing lipoxins (LXs). 5-LOX does not react with 5,15-diHpETE, although it can produce LXA4 when 15-HpETE is the substrate. In contrast, both 12-LOX and 15-LOX-1 react with 5,15-diHpETE, forming specifically LXB4. For 12-LOX and 5,15-diHpETE, the kinetic parameters are kcat = 0.17 s-1 and kcat/ KM = 0.011 μM-1 s-1 [106- and 1600-fold lower than those for 12-LOX oxygenation of arachidonic acid (AA), respectively]. On the other hand, for 15-LOX-1 the equivalent parameters are kcat = 4.6 s-1 and kcat/ KM = 0.21 μM-1 s-1 (3-fold higher and similar to those for 12-HpETE formation by 15-LOX-1 from AA, respectively). This contrasts with the complete lack of reaction of 15-LOX-2 with 5,15-diHpETE [Green, A. R., et al. (2016) Biochemistry 55, 2832-2840]. Our data indicate that 12-LOX is markedly inferior to 15-LOX-1 in catalyzing the production of LXB4 from 5,15-diHpETE. Platelet aggregation was inhibited by the addition of 5,15-diHpETE, with an IC50 of 1.3 μM; however, LXB4 did not significantly inhibit collagen-mediated platelet activation up to 10 μM. In summary, LXB4 is the primary product of 12-LOX and 15-LOX-1 catalysis, if 5,15-diHpETE is the substrate, with 15-LOX-1 being 20-fold more efficient than 12-LOX. LXA4 is the primary product with 5-LOX but only if 15-HpETE is the substrate. Approximately equal proportions of LXA4 and LXB4 are produced by 12-LOX but only if LTA4 is the substrate, as described previously [Sheppard, K. A., et al. (1992) Biochim. Biophys. Acta 1133, 223-234].

Published

2018

12. Discovery and Characterization of a Thioesterase-Specific Monoclonal Antibody That Recognizes the 6‑Deoxyerythronolide B Synthase

Author

Li, Xiuyuan, Sevillano, Natalia, La Greca, Florencia, Hsu, Jake, Mathews, Irimpan I, Matsui, Tsutomu, Craik, Charles S, and Khosla, Chaitan

Subjects

Biotechnology, 1.1 Normal biological development and functioning, Underpinning research, Generic health relevance, Antibodies, Monoclonal, Catalysis, Crystallography, X-Ray, Erythromycin, Humans, Models, Molecular, Molecular Structure, Polyketide Synthases, Protein Conformation, Substrate Specificity, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Assembly line polyketide synthases (PKSs) are large multimodular enzymes responsible for the biosynthesis of diverse antibiotics in bacteria. Structural and mechanistic analysis of these megasynthases can benefit from the discovery of reagents that recognize individual domains or linkers in a site-specific manner. Monoclonal antibodies not only have proven themselves as premier tools in analogous applications but also have the added benefit of constraining the conformational flexibility of their targets in unpredictable but often useful ways. Here we have exploited a library based on the naïve human antibody repertoire to discover a Fab (3A6) that recognizes the terminal thioesterase (TE) domain of the 6-deoxyerythronolide B synthase with high specificity. Biochemical assays were used to verify that 3A6 binding does not inhibit enzyme turnover. The co-crystal structure of the TE-3A6 complex was determined at 2.45 Å resolution, resulting in atomic characterization of this protein-protein recognition mechanism. Fab binding had minimal effects on the structural integrity of the TE. In turn, these insights were used to interrogate via small-angle X-ray scattering the solution-phase conformation of 3A6 complexed to a catalytically competent PKS module and bimodule. Altogether, we have developed a high-affinity monoclonal antibody tool that recognizes the TE domain of the 6-deoxyerythronolide B synthase while maintaining its native function.

Published

2018

13. A Single Mutation Traps a Half-Sites Reactive Enzyme in Midstream, Explaining Asymmetry in Hydride Transfer

Author

Finer-Moore, Janet S, Lee, Tom T, and Stroud, Robert M

Subjects

Biochemistry and Cell Biology, Biological Sciences, Binding Sites, Catalytic Domain, Crystallography, X-Ray, Escherichia coli, Folic Acid, Hydrogen, Models, Molecular, Mutation, Protein Conformation, Quinazolines, Substrate Specificity, Tetrahydrofolates, Thymidylate Synthase, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

In Escherichia coli thymidylate synthase (EcTS), rate-determining hydride transfer from the cofactor 5,10-methylene-5,6,7,8-tetrahydrofolate to the intermediate 5-methylene-2'-deoxyuridine 5'-monophosphate occurs by hydrogen tunneling, requiring precise alignment of reactants and a closed binding cavity, sealed by the C-terminal carboxyl group. Mutations that destabilize the closed conformation of the binding cavity allow small molecules such as β-mercaptoethanol (β-ME) to enter the active site and compete with hydride for addition to the 5-methylene group of the intermediate. The C-terminal deletion mutant of EcTS produced the β-ME adduct in proportions that varied dramatically with cofactor concentration, from 50% at low cofactor concentrations to 0% at saturating cofactor conditions, suggesting communication between active sites. We report the 2.4 Å X-ray structure of the C-terminal deletion mutant of E. coli TS in complex with a substrate and a cofactor analogue, CB3717. The structure is asymmetric, with reactants aligned in a manner consistent with hydride transfer in only one active site. In the second site, CB3717 has shifted to a site where the normal cofactor would be unlikely to form 5-methylene-2'-deoxyuridine 5'-monophosphate, consistent with no formation of the β-ME adduct. The structure shows how the binding of the cofactor at one site triggers hydride transfer and borrows needed stabilization from substrate binding at the second site. It indicates pathways through the dimer interface that contribute to allostery relevant to half-sites reactivity.

Published

2018

14. Selective Recognition of RNA Substrates by ADAR Deaminase Domains

Author

Wang, Yuru, Park, SeHee, and Beal, Peter A

Subjects

Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Biological Sciences, Genetics, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Adenosine Deaminase, Base Sequence, Genes, Reporter, Green Fluorescent Proteins, High-Throughput Screening Assays, Humans, Protein Domains, Protein Processing, Post-Translational, RNA, RNA-Binding Proteins, Sequence Analysis, RNA, Substrate Specificity, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Adenosine deamination is one of the most prevalent post-transcriptional modifications in mRNA and is catalyzed by ADAR1 and ADAR2 in humans. ADAR1 and ADAR2 have different substrate selectivity, which is believed to mainly originate from the proteins' deaminase domains (hADAR1d and hADAR2d, respectively). RNA-seq of the Saccharomyces cerevisiae transcriptome subjected to ADAR-catalyzed RNA editing identified substrates with common secondary structure features preferentially edited by hADAR1d over hADAR2d. The relatively small size and efficient reaction of one of these substrates suggested it could be useful for further study of the hADAR1d reaction. Indeed, a short hairpin stem from the S. cerevisiae HER1 mRNA was efficiently deaminated by hADAR1d and used to generate an hADAR1d-specific fluorescent reporter of editing activity. Using substrates preferred by either hADAR1d or hADAR2d in vitro, we found that a chimeric protein bearing an RNA-binding loop from hADAR2d grafted onto hADAR1d showed ADAR2-like selectivity. Finally, a high-throughput mutagenesis analysis (Sat-FACS-Seq) of conserved residues in an RNA-binding loop of hADAR1d revealed essential amino acids for function, advancing our understanding of RNA recognition by this domain.

Published

2018

15. Statistical Coupling Analysis-Guided Library Design for the Discovery of Mutant Luciferases

Author

Liu, Mira D, Warner, Elliot A, Morrissey, Charlotte E, Fick, Caitlyn W, Wu, Taia S, Ornelas, Marya Y, Ochoa, Gabriela V, Zhang, Brendan S, Rathbun, Colin M, Porterfield, William B, Prescher, Jennifer A, and Leconte, Aaron M

Subjects

Bioengineering, Amino Acid Sequence, Amino Acid Substitution, Amino Acids, Animals, Computational Biology, Drug Design, Drug Discovery, Fireflies, Gene Library, Genes, Insect, Luciferases, Firefly, Models, Molecular, Mutation, Protein Conformation, Protein Stability, Sequence Alignment, Sequence Homology, Amino Acid, Substrate Specificity, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Directed evolution has proven to be an invaluable tool for protein engineering; however, there is still a need for developing new approaches to continue to improve the efficiency and efficacy of these methods. Here, we demonstrate a new method for library design that applies a previously developed bioinformatic method, Statistical Coupling Analysis (SCA). SCA uses homologous enzymes to identify amino acid positions that are mutable and functionally important and engage in synergistic interactions between amino acids. We use SCA to guide a library of the protein luciferase and demonstrate that, in a single round of selection, we can identify luciferase mutants with several valuable properties. Specifically, we identify luciferase mutants that possess both red-shifted emission spectra and improved stability relative to those of the wild-type enzyme. We also identify luciferase mutants that possess a >50-fold change in specificity for modified luciferins. To understand the mutational origin of these improved mutants, we demonstrate the role of mutations at N229, S239, and G246 in altered function. These studies show that SCA can be used to guide library design and rapidly identify synergistic amino acid mutations from a small library.

Published

2018

16. Crystal Structure and Mutagenesis of an XYP Subfamily Cyclodipeptide Synthase Reveal Key Determinants of Enzyme Activity and Substrate Specificity.

Author

He JB, Ren Y, Li P, Liu YP, Pan HX, Huang LJ, Wang J, Fang P, and Tang GL

Subjects

Substrate Specificity, Crystallography, X-Ray, Models, Molecular, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Protein Conformation, Amino Acid Sequence, Catalytic Domain, Streptomyces enzymology, Streptomyces genetics, Mutagenesis, Site-Directed, Peptide Synthases chemistry, Peptide Synthases metabolism, Peptide Synthases genetics

Abstract

Cyclodipeptide synthases (CDPSs) catalyze the synthesis of diverse cyclodipeptides (CDPs) by utilizing two aminoacyl-tRNA (aa-tRNA) substrates in a sequential ping-pong reaction mechanism. Numerous CDPSs have been characterized to provide precursors for diketopiperazines (DKPs) with diverse structural characteristics and biological activities. BcmA, belonging to the XYP subfamily, is a cyclo(l-Ile-l-Leu)-synthesizing CDPS involved in the biosynthesis of the antibiotic bicyclomycin. The structural basis and determinants influencing BcmA enzyme activity and substrate selectivity are not well understood. Here, we report the crystal structure of Ss BcmA from Streptomyces sapporonensis . Through structural comparison and systematic site-directed mutagenesis, we highlight the significance of key residues located in the aminoacyl-binding pocket for enzyme activity and substrate specificity. In particular, the nonconserved residues D161 and K165 in pocket P2 are essential for the activity of Ss BcmA without significant alteration of the substrate specificity, while the conserved residues F158 as well as F210 and S211 in P2 are responsible for determining substrate selectivity. These findings facilitate the understanding of how CDPSs selectively accept hydrophobic substrates and provide additional clues for the engineering of these enzymes for synthetic biology applications.

Published

2024

17. Characterization of the Flavin-Dependent Monooxygenase Involved in the Biosynthesis of the Nocardiosis-Associated Polyketide†.

Author

Del Rio Flores A and Khosla C

Subjects

Substrate Specificity, Kinetics, Polyketides metabolism, Hydroxylation, Bacterial Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins chemistry, Multigene Family, Nocardia Infections microbiology, Oxidation-Reduction, Flavins metabolism, NADP metabolism, Nocardia enzymology, Nocardia metabolism, Nocardia genetics, Mixed Function Oxygenases metabolism, Mixed Function Oxygenases genetics

Abstract

Some species of the Nocardia genus harbor a highly conserved biosynthetic gene cluster designated as the NOCardiosis-Associated Polyketide (NOCAP) synthase that produces a unique glycolipid natural product. The NOCAP glycolipid is composed of a fully substituted benzaldehyde headgroup linked to a polyfunctional alkyl tail and an O -linked disaccharide composed of 3-α-epimycarose and 2- O -methyl-α-rhamnose. Incorporation of the disaccharide unit is preceded by a critical step involving hydroxylation by NocapM, a flavin monooxygenase. In this study, we employed biochemical, spectroscopic, and kinetic analyses to explore the substrate scope of NocapM. Our findings indicate that NocapM catalyzes hydroxylation of diverse aromatic substrates, although the observed coupling between NADPH oxidation and substrate hydroxylation varies widely from substrate to substrate. Our in-depth biochemical characterization of NocapM provides a solid foundation for future mechanistic studies of this enzyme as well as its utilization as a practical biocatalyst.

Published

2024

18. Mammalian Esterase Activity: Implications for Peptide Prodrugs.

Author

Petri YD, Verresen R, Gutierrez CS, Kojasoy V, Zhang E, Abularrage NS, Wralstad EC, Weiser KR, and Raines RT

Subjects

Humans, Animals, Swine, Fluorescence Resonance Energy Transfer, Liver enzymology, Kinetics, Hydrolysis, Substrate Specificity, Esters chemistry, Esters metabolism, Prodrugs chemistry, Prodrugs metabolism, Peptides chemistry, Peptides metabolism, Esterases metabolism, Esterases chemistry

Abstract

As a traceless, bioreversible modification, the esterification of carboxyl groups in peptides and proteins has the potential to increase their clinical utility. An impediment is the lack of strategies to quantify esterase-catalyzed hydrolysis rates for esters in esterified biologics. We have developed a continuous Förster resonance energy transfer (FRET) assay for esterase activity based on a peptidic substrate and a protease, Glu-C, that cleaves a glutamyl peptide bond only if the glutamyl side chain is a free acid. Using pig liver esterase (PLE) and human carboxylesterases, we validated the assay with substrates containing simple esters ( e.g. , ethyl) and esters designed to be released by self-immolation upon quinone methide elimination. We found that simple esters were not cleaved by esterases, likely for steric reasons. To account for the relatively low rate of quinone methide elimination, we extended the mathematics of the traditional Michaelis-Menten model to conclude with a first-order intermediate decay step. By exploring two regimes of our substrate → intermediate → product (SIP) model, we evaluated the rate constants for the PLE-catalyzed cleavage of an ester on a glutamyl side chain ( k cat / K M = 1.63 × 10 3 M -1 s -1 ) and subsequent spontaneous quinone methide elimination to regenerate the unmodified peptide ( k I = 0.00325 s -1 ; t 1/2 = 3.55 min). The detection of esterase activity was also feasible in the human intestinal S9 fraction. Our assay and SIP model increase the understanding of the release kinetics of esterified biologics and facilitate the rational design of efficacious peptide prodrugs.

Published

2024

19. Decoding Substrate Selectivity of an Archaeal RlmCD-like Methyltransferase Through Its Salient Traits.

Author

Saha S and Kanaujia SP

Subjects

Substrate Specificity, Pyrococcus horikoshii enzymology, Pyrococcus horikoshii genetics, Models, Molecular, Crystallography, X-Ray, S-Adenosylmethionine metabolism, Amino Acid Sequence, Archaeal Proteins metabolism, Archaeal Proteins genetics, Archaeal Proteins chemistry, Methyltransferases metabolism, Methyltransferases chemistry, Methyltransferases genetics

Abstract

5-Methyluridine (m 5 U) rRNA modifications frequently occur at U747 and U1939 ( Escherichia coli numbering) in domains II and IV of the 23S rRNA in Gram-negative bacteria, with the help of S -adenosyl-l-methionine (SAM)-dependent rRNA methyltransferases (MTases), RlmC and RlmD, respectively. In contrast, Gram-positive bacteria utilize a single SAM-dependent rRNA MTase, RlmCD, to modify both corresponding sites. Notably, certain archaea, specifically within the Thermococcales group, have been found to possess two genes encoding SAM-dependent archaeal (tRNA and rRNA) m 5 U (Arm 5 U) MTases. Among these, a tRNA-specific Arm 5 U MTase ( Pab TrmU54) has already been characterized. This study focused on the structural and functional characterization of the rRNA-specific Arm 5 U MTase from the hyperthermophilic archaeon Pyrococcus horikoshii ( Ph RlmCD). An in-depth structural examination revealed a dynamic hinge movement induced by the replacement of the iron-sulfur cluster with disulfide bonds, obstructing the substrate-binding site. It revealed distinctive characteristics of Ph RlmCD, including elongated positively charged loops in the central domain and rotational variations in the TRAM domain, which influence substrate selectivity. Additionally, the results suggested that two potential mini-rRNA fragments interact in a similar manner with Ph RlmCD at a positively charged cleft at the interface of domains and facilitate dual MTase activities akin to the protein RlmCD. Altogether, these observations showed that Arm 5 U MTases originated from horizontal gene transfer events, most likely from Gram-positive bacteria.

Published

2024

20. Substrate Specificity of a Methyltransferase Involved in the Biosynthesis of the Lantibiotic Cacaoidin.

Author

Liang H, Luo Y, and van der Donk WA

Subjects

Substrate Specificity, Methylation, Anti-Bacterial Agents biosynthesis, Anti-Bacterial Agents metabolism, Anti-Bacterial Agents chemistry, Amino Acid Sequence, Multigene Family, Bacteriocins metabolism, Bacteriocins chemistry, Bacteriocins biosynthesis, Bacteriocins genetics, Methyltransferases metabolism, Methyltransferases chemistry, Methyltransferases genetics

Abstract

Modification of the N- and C-termini of peptides enhances their stability against degradation by exopeptidases. The biosynthetic pathways of many peptidic natural products feature enzymatic modification of their termini, and these enzymes may represent a valuable pool of biocatalysts. The lantibiotic cacaoidin carries an N , N -dimethylated N-terminal amine group. Its biosynthetic gene cluster encodes the putative methyltransferase Cao4. In this work, we present reconstitution of the activity of the enzyme, which we termed CaoS C following standardized lanthipeptide nomenclature, using a heterologously produced peptide as the model substrate. In vitro methylation of diverse lanthipeptides revealed the substrate requirements of CaoS C . The enzyme accepts peptides of varying lengths and C-terminal sequences but requires dehydroalanine or dehydrobutyrine at the second position. CaoS C -mediated dimethylation of natural lantibiotics resulted in modestly enhanced antimicrobial activity of the lantibiotic haloduracin compared to that of the native compound. Improved activity and/or metabolic stability as a result of methylation illustrates the potential future application of CaoS C in the bioengineering of therapeutic peptides.

Published

2024

21. The Drug-Resistant Variant P167S Expands the Substrate Profile of CTX‑M β‑Lactamases for Oxyimino-Cephalosporin Antibiotics by Enlarging the Active Site upon Acylation

Author

Patel, Meha P, Hu, Liya, Stojanoski, Vlatko, Sankaran, Banumathi, Prasad, BV Venkataram, and Palzkill, Timothy

Subjects

Medical Microbiology, Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Biological Sciences, Prevention, Antimicrobial Resistance, Infectious Diseases, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, Acylation, Amino Acid Substitution, Anti-Bacterial Agents, Apoenzymes, Catalytic Domain, Ceftazidime, Cephalosporins, Crystallography, X-Ray, Drug Resistance, Multiple, Bacterial, Enzyme Stability, Escherichia coli, Escherichia coli Proteins, Hydrolysis, Ligands, Models, Molecular, Mutagenesis, Site-Directed, Oximes, Point Mutation, Protein Conformation, Recombinant Proteins, Substrate Specificity, beta-Lactamases, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

CTX-M β-lactamases provide resistance against the β-lactam antibiotic, cefotaxime, but not a related antibiotic, ceftazidime. β-Lactamases that carry the P167S substitution, however, provide ceftazidime resistance. In this study, CTX-M-14 was used as a model to study the structural changes caused by the P167S mutation that accelerate ceftazidime turnover. X-ray crystallography was used to determine the structures of the P167S apoenzyme along with the structures of the S70G/P167S, E166A/P167S, and E166A mutant enzymes complexed with ceftazidime as well as the E166A/P167S apoenzyme. The S70G and E166A mutations allow capture of the enzyme-substrate complex and the acylated form of ceftazidime, respectively. The results showed a large conformational change in the Ω-loop of the ceftazidime acyl-enzyme complex of the P167S mutant but not in the enzyme-substrate complex, suggesting the change occurs upon acylation. The change results in a larger active site that prevents steric clash between the aminothiazole ring of ceftazidime and the Asn170 residue in the Ω-loop, allowing accommodation of ceftazidime for hydrolysis. In addition, the conformational change was not observed in the E166A/P167S apoenzyme, suggesting the presence of acylated ceftazidime influences the conformational change. Finally, the E166A acyl-enzyme structure with ceftazidime did not exhibit the altered conformation, indicating the P167S substitution is required for the change. Taken together, the results reveal that the P167S substitution and the presence of acylated ceftazidime both drive the structure toward a conformational change in the Ω-loop and that in CTX-M P167S enzymes found in drug-resistant bacteria this will lead to an increased level of ceftazidime hydrolysis.

Published

2017

22. Solution Conformations and Dynamics of Substrate-Bound Cytochrome P450 MycG

Author

Tietz, Drew R, Podust, Larissa M, Sherman, David H, and Pochapsky, Thomas C

Subjects

Bacterial Proteins, Cytochrome P-450 Enzyme System, Models, Molecular, Molecular Dynamics Simulation, Nuclear Magnetic Resonance, Biomolecular, Protein Conformation, Solutions, Substrate Specificity, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

MycG is a P450 monooxygenase that catalyzes the sequential hydroxylation and epoxidation of mycinamicin IV (M-IV), the last two steps in the biosynthesis of mycinamicin II, a macrolide antibiotic isolated from Micromonospora griseorubida. The crystal structure of MycG with M-IV bound was previously determined but showed the bound substrate in an orientation that did not rationalize the observed regiochemistry of M-IV hydroxylation. Nuclear magnetic resonance paramagnetic relaxation enhancements provided evidence of an orientation of M-IV in the MycG active site more compatible with the observed chemistry, but substrate-induced changes in the enzyme structure were not characterized. We now describe the use of amide 1H-15N residual dipolar couplings as experimental restraints in solvated "soft annealing" molecular dynamics simulations to generate solution structural ensembles of M-IV-bound MycG. Chemical shift perturbations, hydrogen-deuterium exchange, and 15N relaxation behavior provide insight into the dynamic and electronic perturbations in the MycG structure in response to M-IV binding. The solution and crystallographic structures are compared, and the possibility that the crystallographic orientation of bound M-IV represents an inhibitory mode is discussed.

Published

2017

23. Caenorhabditis elegans PRMT‑7 and PRMT‑9 Are Evolutionarily Conserved Protein Arginine Methyltransferases with Distinct Substrate Specificities

Author

Hadjikyriacou, Andrea and Clarke, Steven G

Subjects

Pediatric, Genetics, Generic health relevance, Amino Acid Sequence, Animals, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Crystallography, X-Ray, Isoenzymes, Plants, Protein Conformation, Protein-Arginine N-Methyltransferases, Sequence Homology, Amino Acid, Substrate Specificity, Temperature, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Caenorhabditis elegans protein arginine methyltransferases PRMT-7 and PRMT-9 are two evolutionarily conserved enzymes, with distinct orthologs in plants, invertebrates, and vertebrates. Biochemical characterization of these two enzymes reveals that they share much in common with their mammalian orthologs. C. elegans PRMT-7 produces only monomethylarginine (MMA) and preferentially methylates R-X-R motifs in a broad collection of substrates, including human histone peptides and RG-rich peptides. In addition, the activity of the PRMT-7 enzyme is dependent on temperature, the presence of metal ions, and the reducing agent dithiothreitol. C. elegans PRMT-7 has a substrate specificity and a substrate preference different from those of mammalian PRMT7, and the available X-ray crystal structures of the PRMT7 orthologs show differences in active site architecture. C. elegans PRMT-9, on the other hand, produces symmetric dimethylarginine and MMA on SFTB-2, the conserved C. elegans ortholog of human RNA splicing factor SF3B2, indicating a possible role in the regulation of nematode splicing. In contrast to PRMT-7, C. elegans PRMT-9 appears to be biochemically indistinguishable from its human ortholog.

Published

2017

24. Biochemical Analysis of the Lipoprotein Lipase Truncation Variant, LPLS447X, Reveals Increased Lipoprotein Uptake

Author

Hayne, Cassandra K, Lafferty, Michael J, Eglinger, Brian J, Kane, John P, and Neher, Saskia B

Subjects

Angiopoietin-Like Protein 4, Angiopoietins, Animals, Biological Transport, Cholesterol, HDL, Cholesterol, LDL, Cholesterol, VLDL, Gene Expression, Humans, Hyperlipidemias, Lipoprotein Lipase, Mice, Models, Molecular, Mutation, Protein Binding, Protein Domains, Protein Multimerization, Protein Structure, Secondary, Receptors, Lipoprotein, Recombinant Proteins, Serine, Substrate Specificity, Triglycerides, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Lipoprotein lipase (LPL) is responsible for the hydrolysis of triglycerides from circulating lipoproteins. Whereas most identified mutations in the LPL gene are deleterious, one mutation, LPLS447X, causes a gain of function. This mutation truncates two amino acids from LPL's C-terminus. Carriers of LPLS447X have decreased VLDL levels and increased HDL levels, a cardioprotective phenotype. LPLS447X is used in Alipogene tiparvovec, the gene therapy product for individuals with familial LPL deficiency. It is unclear why LPLS447X results in a serum lipid profile more favorable than that of LPL. In vitro reports vary as to whether LPLS447X is more active than LPL. We report a comprehensive, biochemical comparison of purified LPLS447X and LPL dimers. We found no difference in specific activity on synthetic and natural substrates. We also did not observe a difference in the Ki for ANGPTL4 inhibition of LPLS447X relative to that of LPL. Finally, we analyzed LPL-mediated uptake of fluorescently labeled lipoprotein particles and found that LPLS447X enhanced lipoprotein uptake to a greater degree than LPL did. An LPL structural model suggests that the LPLS447X truncation exposes residues implicated in LPL binding to uptake receptors.

Published

2017

25. Thermodynamics of Nanobody Binding to Lactose Permease

Author

Hariharan, Parameswaran, Andersson, Magnus, Jiang, Xiaoxu, Pardon, Els, Steyaert, Jan, Kaback, H Ronald, and Guan, Lan

Subjects

Medicinal and Biomolecular Chemistry, Chemical Sciences, Genetics, Calorimetry, Escherichia coli, Membrane Transport Proteins, Molecular Dynamics Simulation, Single-Domain Antibodies, Substrate Specificity, Thermodynamics, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Camelid nanobodies (Nbs) raised against the outward-facing conformer of a double-Trp mutant of the lactose permease of Escherichia coli (LacY) stabilize the permease in outward-facing conformations. Isothermal titration calorimetry is applied herein to dissect the binding thermodynamics of two Nbs, one that markedly improves access to the sugar-binding site and another that dramatically increases the affinity for galactoside. The findings presented here show that both enthalpy and entropy contribute favorably to binding of the Nbs to wild-type (WT) LacY and that binding of Nb to double-Trp mutant G46W/G262W is driven by a greater enthalpy at an entropic penalty. Thermodynamic analyses support the interpretation that WT LacY is stabilized in outward-facing conformations like the double-Trp mutant with closure of the water-filled cytoplasmic cavity through conformational selection. The LacY conformational transition required for ligand binding is reflected by a favorable entropy increase. Molecular dynamics simulations further suggest that the entropy increase likely stems from release of immobilized water molecules primarily from the cytoplasmic cavity upon closure.

Published

2016

26. Biochemical and Cellular Characterization and Inhibitor Discovery of Pseudomonas aeruginosa 15-Lipoxygenase

Author

Deschamps, Joshua D, Ogunsola, Abiola F, Jameson, J Brian, Yasgar, Adam, Flitter, Becca A, Freedman, Cody J, Melvin, Jeffrey A, Nguyen, Jason VMH, Maloney, David J, Jadhav, Ajit, Simeonov, Anton, Bomberger, Jennifer M, and Holman, Theodore R

Subjects

Microbiology, Medical Microbiology, Biomedical and Clinical Sciences, Biological Sciences, Cystic Fibrosis, Lung, Rare Diseases, 2.2 Factors relating to the physical environment, Aetiology, Infection, Amino Acid Sequence, Animals, Antibody Formation, Arachidonate 15-Lipoxygenase, Humans, Hydroxyeicosatetraenoic Acids, Kinetics, Lipoxygenase Inhibitors, Pseudomonas aeruginosa, Rabbits, Substrate Specificity, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Pseudomonas aeruginosa is an opportunistic pathogen that can cause nosocomial and chronic infections in immunocompromised patients. P. aeruginosa secretes a lipoxygenase, LoxA, but the biological role of this enzyme is currently unknown. LoxA is poorly similar in sequence to both soybean LOX-1 (s15-LOX-1) and human 15-LOX-1 (37 and 39%, respectively) yet has kinetics comparably fast versus those of s15-LOX-1 (at pH 6.5, Kcat = 181 ± 6 s(-1) and Kcat/KM = 16 ± 2 μM(-1) s(-1)). LoxA is capable of efficiently catalyzing the peroxidation of a broad range of free fatty acid (FA) substrates (e.g., AA and LA) with high positional specificity, indicating a 15-LOX. Its mechanism includes hydrogen atom abstraction [a kinetic isotope effect (KIE) of >30], yet LoxA is a poor catalyst against phosphoester FAs, suggesting that LoxA is not involved in membrane decomposition. LoxA also does not react with 5- or 15-HETEs, indicating poor involvement in lipoxin production. A LOX high-throughput screen of the LOPAC library yielded a variety of low-micromolar inhibitors; however, none selectively targeted LoxA over the human LOX isozymes. With respect to cellular activity, the level of LoxA expression is increased when P. aeruginosa undergoes the transition to a biofilm mode of growth, but LoxA is not required for biofilm growth on abiotic surfaces. However, LoxA does appear to be required for biofilm growth in association with the host airway epithelium, suggesting a role for LoxA in mediating bacterium-host interactions during colonization.

Published

2016

27. Nuclear Magnetic Resonance Structure of the APOBEC3B Catalytic Domain: Structural Basis for Substrate Binding and DNA Deaminase Activity

Author

Byeon, In-Ja L, Byeon, Chang-Hyeock, Wu, Tiyun, Mitra, Mithun, Singer, Dustin, Levin, Judith G, and Gronenborn, Angela M

Subjects

Biochemistry and Cell Biology, Biological Sciences, Genetics, Aetiology, Underpinning research, 2.1 Biological and endogenous factors, 1.1 Normal biological development and functioning, Generic health relevance, Catalytic Domain, Cytidine Deaminase, DNA, Humans, Minor Histocompatibility Antigens, Nuclear Magnetic Resonance, Biomolecular, Protein Binding, Protein Structure, Tertiary, Substrate Specificity, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Human APOBEC3B (A3B) is a member of the APOBEC3 (A3) family of cytidine deaminases, which function as DNA mutators and restrict viral pathogens and endogenous retrotransposons. Recently, A3B was identified as a major source of genetic heterogeneity in several human cancers. Here, we determined the solution nuclear magnetic resonance structure of the catalytically active C-terminal domain (CTD) of A3B and performed detailed analyses of its deaminase activity. The core of the structure comprises a central five-stranded β-sheet with six surrounding helices, common to all A3 proteins. The structural fold is most similar to that of A3A and A3G-CTD, with the most prominent difference being found in loop 1. The catalytic activity of A3B-CTD is ∼15-fold lower than that of A3A, although both exhibit a similar pH dependence. Interestingly, A3B-CTD with an A3A loop 1 substitution had significantly increased deaminase activity, while a single-residue change (H29R) in A3A loop 1 reduced A3A activity to the level seen with A3B-CTD. This establishes that loop 1 plays an important role in A3-catalyzed deamination by precisely positioning the deamination-targeted C into the active site. Overall, our data provide important insights into the determinants of the activities of individual A3 proteins and facilitate understanding of their biological function.

Published

2016

28. Strict Regiospecificity of Human Epithelial 15-Lipoxygenase‑2 Delineates Its Transcellular Synthesis Potential

Author

Green, Abigail R, Barbour, Shannon, Horn, Thomas, Carlos, Jose, Raskatov, Jevgenij A, and Holman, Theodore R

Subjects

Organic Chemistry, Chemical Sciences, Arachidonate 15-Lipoxygenase, Catalysis, Humans, Hydroxyeicosatetraenoic Acids, Substrate Specificity, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Lipoxins are an important class of lipid mediators that induce the resolution of inflammation and arise from transcellular exchange of arachidonic acid (AA)-derived lipoxygenase products. Human epithelial 15-lipoxygenase-2 (h15-LOX-2), the major lipoxygenase in macrophages, has exhibited strict regiospecificity, catalyzing only the hydroperoxidation of carbon 15 of AA. To determine the catalytic potential of h15-LOX-2 in transcellular synthesis events, we reacted it with the three lipoxygenase-derived monohydroperoxy-eicosatetraenoic acids (HPETE) in humans: 5-HPETE, 12-HPETE, and 15-HPETE. Only 5-HPETE was a substrate for h15-LOX-2, and the steady-state catalytic efficiency (kcat/Km) of this reaction was 31% of the kcat/Km of AA. The only major product of h15-LOX-2's reaction with 5-HPETE was the proposed lipoxin intermediate, 5,15-dihydroperoxy-eicosatetraenoic acid (5,15-diHPETE). However, h15-LOX-2 did not react further with 5,15-diHPETE to produce lipoxins. This result is consistent with the specificity of h15-LOX-2 despite the increased reactivity of 5,15-diHPETE. Density functional theory calculations determined that the radical, after abstracting the C10 hydrogen atom from 5,15-diHPETE, had an energy 5.4 kJ/mol lower than that of the same radical generated from AA, demonstrating the facility of 5,15-diHPETE to form lipoxins. Interestingly, h15-LOX-2 does react with 5S,6R-diHETE, forming LipoxinA4, indicating the gemdiol does not prohibit h15-LOX-2 reactivity. Taken together, these results demonstrate the strict regiospecificity of h15-LOX-2 that circumscribes its role in transcellular synthesis.

Published

2016

29. Biochemical and Spectroscopic Characterization of a Radical S‑Adenosyl‑l‑methionine Enzyme Involved in the Formation of a Peptide Thioether Cross-Link

Author

Bruender, Nathan A, Wilcoxen, Jarett, Britt, R David, and Bandarian, Vahe

Subjects

Biochemistry and Cell Biology, Chemical Sciences, Biological Sciences, Emerging Infectious Diseases, Amino Acid Motifs, Amino Acid Substitution, Bacterial Proteins, Biocatalysis, Computational Biology, Cysteine, Cystine, Iron-Sulfur Proteins, Models, Molecular, Mutagenesis, Site-Directed, Mutation, Oxidation-Reduction, Oxidoreductases Acting on Sulfur Group Donors, Peptide Fragments, Protein Processing, Post-Translational, Recombinant Proteins, S-Adenosylmethionine, Substrate Specificity, Thermoanaerobacter, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Peptide-derived natural products are a class of metabolites that afford the producing organism a selective advantage over other organisms in their biological niche. While the polypeptide antibiotics produced by the nonribosomal polypeptide synthetases (NRPS) are the most widely recognized, the ribosomally synthesized and post-translationally modified peptides (RiPPs) are an emerging group of natural products with diverse structures and biological functions. Both the NRPS derived peptides and the RiPPs undergo extensive post-translational modifications to produce structural diversity. Here we report the first characterization of the six cysteines in forty-five (SCIFF) [Haft, D. H. and Basu M. K. (2011) J. Bacteriol. 193, 2745-2755] peptide maturase Tte1186, which is a member of the radical S-adenosyl-l-methionine (SAM) superfamily. Tte1186 catalyzes the formation of a thioether cross-link in the peptide Tte1186a encoded by an orf located upstream of the maturase, under reducing conditions in the presence of SAM. Tte1186 contains three [4Fe-4S] clusters that are indispensable for thioether cross-link formation; however, only one cluster catalyzes the reductive cleavage of SAM. Mechanistic imperatives for the reaction catalyzed by the thioether forming radical SAM maturases will be discussed.

Published

2016

30. Polar Interactions between Substrate and Flavin Control Iodotyrosine Deiodinase Function.

Author

Lemen D and Rokita SE

Subjects

Flavins metabolism, Flavins chemistry, Substrate Specificity, Oxidation-Reduction, Kinetics, Flavin-Adenine Dinucleotide metabolism, Flavin-Adenine Dinucleotide chemistry, Flavin-Adenine Dinucleotide analogs & derivatives, Dinitrocresols metabolism, Dinitrocresols chemistry, Halogenation, Iodide Peroxidase metabolism, Iodide Peroxidase chemistry

Abstract

Flavin cofactors offer a wide range of chemical mechanisms to support a great diversity in catalytic function. As a corollary, such diversity necessitates careful control within each flavoprotein to limit its function to an appropriate subset of possible reactions and substrates. This task falls to the protein environment surrounding the flavin in most enzymes. For iodotyrosine deiodinase that catalyzes a reductive dehalogenation of halotyrosines, substrates can dictate the chemistry available to the flavin. Their ability to stabilize the necessary one-electron reduced semiquinone form of flavin strictly depends on a direct coordination between the flavin and α-ammonium and carboxylate groups of its substrates. While perturbations to the carboxylate group do not significantly affect binding to the resting oxidized form of the deiodinase, dehalogenation ( k cat / K m ) is suppressed by over 2000-fold. Lack of the α-ammonium group abolishes detectable binding and dehalogenation. Substitution of the ammonium group with a hydroxyl group does not restore measurable binding but does support dehalogenation with an efficiency greater than those of the carboxylate derivatives. Consistent with these observations, the flavin semiquinone does not accumulate during redox titration in the presence of inert substrate analogues lacking either the α-ammonium or carboxylate groups. As a complement, a nitroreductase activity based on hydride transfer is revealed for the appropriate substrates with perturbations to their zwitterion.

Published

2024

31. Gatekeeping Activity of Collinear Ketosynthase Domains Limits Product Diversity for Engineered Type I Polyketide Synthases.

Author

Yi D, Wakeel MA, and Agarwal V

Subjects

Polyketides metabolism, Polyketides chemistry, Substrate Specificity, Protein Domains, Polyketide Synthases metabolism, Polyketide Synthases chemistry, Polyketide Synthases genetics, Protein Engineering methods

Abstract

Engineered type I polyketide synthases (type I PKSs) can enable access to diverse polyketide pharmacophores and generate non-natural natural products. However, the promise of type I PKS engineering remains modestly realized at best. Here, we report that ketosynthase (KS) domains, the key carbon-carbon bond-forming catalysts, control which intermediates are allowed to progress along the PKS assembly lines and which intermediates are excluded. Using bimodular PKSs, we demonstrate that KSs can be exquisitely selective for the upstream polyketide substrate while retaining promiscuity for the extender unit that they incorporate. It is then the downstream KS that acts as a gatekeeper to ensure the fidelity of the extender unit incorporation by the upstream KS. We also demonstrate that these findings are not universally applicable; substrate-tolerant KSs do allow engineered polyketide intermediates to be extended. Our results demonstrate the utility for evaluating the KS-induced bottlenecks to gauge the feasibility of engineering PKS assembly lines.

Published

2024

32. 19 F NMR Reveals the Dynamics of Substrate Binding and Lid Closure for Iodotyrosine Deiodinase as a Complement to Steady-State Kinetics and Crystallography.

Author

Greenberg HC, Majumdar A, Cheema EK, Kozyryev A, and Rokita SE

Subjects

Kinetics, Crystallography, X-Ray methods, Nuclear Magnetic Resonance, Biomolecular, Protein Conformation, Substrate Specificity, Humans, Fluorine chemistry, Fluorine metabolism, Models, Molecular, Protein Binding, Ligands, Iodide Peroxidase metabolism, Iodide Peroxidase chemistry, Catalytic Domain

Abstract

Active site lids are common features of enzymes and typically undergo conformational changes upon substrate binding to promote catalysis. Iodotyrosine deiodinase is no exception and contains a lid segment in all of its homologues from human to bacteria. The solution-state dynamics of the lid have now been characterized using 19 F NMR spectroscopy with a CF 3 -labeled enzyme and CF 3 O-labeled ligands. From two-dimensional 19 F- 19 F NMR exchange spectroscopy, interconversion rates between the free and bound states of a CF 3 O-substituted tyrosine (45 ± 10 s -1 ) and the protein label (40 ± 3 s -1 ) are very similar and suggest a correlation between ligand binding and conformational reorganization of the lid. Both occur at rates that are ∼100-fold faster than turnover, and therefore these steps do not limit catalysis. A simple CF 3 O-labeled phenol also binds to the active site and induces a conformational change in the lid segment that was not previously detectable by crystallography. Exchange rates of the ligand (130 ± 20 s -1 ) and protein (98 ± 8 s -1 ) in this example are faster than those above but remain self-consistent to affirm a correlation between ordering of the lid and binding of the ligand. Both ligands also protect the protein from limited proteolysis, as expected from their ability to stabilize a compact lid structure. However, the minimal turnover of simple phenol substrates indicates that such stabilization may be necessary but is not sufficient for efficient catalysis.

Published

2024

33. Structural Basis of Substrate Recognition by the Postmitosane Modification Enzyme MitM in Mitomycin Biosynthesis.

Author

Dong D, Xia M, Wang S, Fang P, and Liu W

Subjects

Crystallography, X-Ray, Substrate Specificity, S-Adenosylmethionine metabolism, S-Adenosylmethionine chemistry, Methyltransferases metabolism, Methyltransferases chemistry, Models, Molecular, Catalytic Domain, Protein Conformation, S-Adenosylhomocysteine metabolism, S-Adenosylhomocysteine chemistry, Streptomyces enzymology, Mitomycin metabolism, Mitomycin chemistry, Bacterial Proteins chemistry, Bacterial Proteins metabolism

Abstract

Mitomycins make up a class of natural molecules produced by Streptomyces with strong antibacterial and antitumor activities. MitM is a key postmitosane modification enzyme involved in mitomycin biosynthesis in Streptomyces caespitosus . This protein was previously suggested to catalyze the aziridinium methylation of mitomycin A and the mitomycin intermediate 9a-demethyl-mitomycin A as an N -methyltransferase. The structural basis for MitM to recognize cofactor S -adenosyl-l-methionine (SAM) and substrate mitomycin A is unknown. Here, we determined the crystal structures of apo -MitM and MitM-mitomycin A- S -adenosylhomocysteine (SAH) ternary complexes with resolutions of 2.23 and 2.80 Å, respectively. We found that MitM adopts a class I SAM-dependent methyltransferase fold and forms a homodimer in solution. Conformational changes in a series of residues involved in the formation of active pockets assist MitM in binding SAH and mitomycin A. In particular, the 28 ALGAASLGE 36 loop changes most significantly. When mitomycin A binds, the bending direction of this loop is reversed, changing the entrance of the active site from open to closed. This study provides structural insights into MitM's involvement in the postmitosane stage of mitomycin biosynthesis and provides a template for the engineering of methyltransferases.

Published

2024

34. Enzyme Catalyzed Formation of CoA Adducts of Fluorinated Hexanoic Acid Analogues using a Long-Chain acyl-CoA Synthetase from Gordonia sp. Strain NB4-1Y.

Author

Mothersole RG, Mothersole MK, Goddard HG, Liu J, and Van Hamme JD

Subjects

Gordonia Bacterium metabolism, Gordonia Bacterium enzymology, Gordonia Bacterium genetics, Halogenation, Coenzyme A metabolism, Coenzyme A chemistry, Kinetics, Bacterial Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins chemistry, Acyl Coenzyme A metabolism, Acyl Coenzyme A chemistry, Substrate Specificity, Coenzyme A Ligases metabolism, Coenzyme A Ligases genetics, Coenzyme A Ligases chemistry, Caproates metabolism, Caproates chemistry

Abstract

Per and polyfluoroalkyl substances (PFAS) are a large family of anthropogenic fluorinated chemicals of increasing environmental concern. Over recent years, numerous microbial communities have been found to be capable of metabolizing some polyfluoroalkyl substances, generating a range of low-molecular-weight PFAS metabolites. One proposed pathway for the microbial breakdown of fluorinated carboxylates includes β-oxidation, this pathway is initiated by the formation of a CoA adduct. However, until recently no PFAS-CoA adducts had been reported. In a previous study, we were able to use a bacterial medium-chain acyl-CoA synthetase (mACS) to form CoA adducts of fluorinated adducts of propanoic acid and pentanoic acid but were not able to detect any products of fluorinated hexanoic acid analogues. Herein, we expressed and purified a long-chain acyl-CoA synthetase (lACS) and a A461K variant of mACS from the soil bacterium Gordonia sp. strain NB4-1Y and performed an analysis of substrate scope and enzyme kinetics using fluorinated and nonfluorinated carboxylates. We determined that lACS can catalyze the formation of CoA adducts of 1:5 fluorotelomer carboxylic acid (FTCA), 2:4 FTCA and 3:3 FTCA, albeit with generally low turnover rates (<0.02 s -1 ) compared with the nonfluorinated hexanoic acid (5.39 s -1 ). In addition, the A461K variant was found to have an 8-fold increase in selectivity toward hexanoic acid compared with wild-type mACS, suggesting that Ala-461 has a mechanistic role in selectivity toward substrate chain length. This provides further evidence to validate the proposed activation step involving the formation of CoA adducts in the enzymatic breakdown of PFAS.

Published

2024

35. Extracellular Domain of IL-10 Receptor Chain-2 (IL-10R2) and Its Arginine-Containing Peptides Are Susceptible Substrates for Human Prostate Kallikrein-2 (KLK2).

Author

Oliveira JR, Lacerda JT, Sellani TA, Rodrigues EG, Travassos LR, Juliano MA, and Juliano L

Subjects

Humans, Male, Arginine metabolism, Arginine chemistry, Prostate metabolism, Prostate drug effects, Macrophages metabolism, Macrophages drug effects, Animals, Mice, Peptides chemistry, Peptides pharmacology, Peptides metabolism, Protein Domains, Interleukin-10 metabolism, Substrate Specificity, Kallikreins metabolism, Kallikreins chemistry

Abstract

The kallikrein-related peptidase KLK2 has restricted expression in the prostate luminal epithelium, and its protein target is unknown. The present work reports the hydrolytic activities of KLK2 on libraries of fluorescence resonance energy-transfer peptides from which the sequence SYRIF was the most susceptible substrate for KLK2. The sequence SYRIF is present at the extracellular N -terminal segment ( 58 SYRIF 63 Q) of IL-10R2. KLK2 was fully active at pH 8.0-8.2, found only in prostate inflammatory conditions, and strongly activated by sodium citrate and glycosaminoglycans, the quantities and structures controlled by prostate cells. Bone-marrow-derived macrophages (BMDM) have IL-10R2 expressed on the cell surface, which is significantly reduced after KLK2 treatment, as determined by flow cytometry (FACS analysis). The IL-10 inhibition of the inflammatory response to LPS/IFN-γ in BMDM cells due to decreased nitric oxide, TNF-α, and IL-12 p40 levels is significantly reduced upon treatment of these cells with KLK2. Similar experiments with KLK3 did not show these effects. These observations indicate that KLK2 proteolytic activity plays a role in prostate inflammation and makes KLK2 a promising target for prostatitis treatment.

Published

2024

36. Bioinformatic, Enzymatic, and Structural Characterization of Trichuris suis Hexosaminidase HEX-2.

Author

Dutkiewicz Z, Varrot A, Breese KJ, Stubbs KA, Nuschy L, Adduci I, Paschinger K, and Wilson IBH

Subjects

Animals, Substrate Specificity, Crystallography, X-Ray, Amino Acid Sequence, Phylogeny, Models, Molecular, Hexosaminidases chemistry, Hexosaminidases metabolism, Hexosaminidases genetics, Molecular Sequence Data, Catalytic Domain, Helminth Proteins chemistry, Helminth Proteins metabolism, Helminth Proteins genetics, beta-N-Acetylhexosaminidases metabolism, beta-N-Acetylhexosaminidases chemistry, beta-N-Acetylhexosaminidases genetics, Trichuris enzymology, Computational Biology methods

Abstract

Hexosaminidases are key enzymes in glycoconjugate metabolism and occur in all kingdoms of life. Here, we have investigated the phylogeny of the GH20 glycosyl hydrolase family in nematodes and identified a β-hexosaminidase subclade present only in the Dorylaimia. We have expressed one of these, HEX-2 from Trichuris suis , a porcine parasite, and shown that it prefers an aryl β- N -acetylgalactosaminide in vitro . HEX-2 has an almost neutral pH optimum and is best inhibited by GalNAc-isofagomine. Toward N-glycan substrates, it displays a preference for the removal of GalNAc residues from LacdiNAc motifs as well as the GlcNAc attached to the α1,3-linked core mannose. Therefore, it has a broader specificity than insect fused lobe (FDL) hexosaminidases but one narrower than distant homologues from plants. Its X-ray crystal structure, the first of any subfamily 1 GH20 hexosaminidase to be determined, is closest to Streptococcus pneumoniae GH20C and the active site is predicted to be compatible with accommodating both GalNAc and GlcNAc. The new structure extends our knowledge about this large enzyme family, particularly as T. suis HEX-2 also possesses the key glutamate residue found in human hexosaminidases of either GH20 subfamily, including HEXD whose biological function remains elusive.

Published

2024

37. Structural Comparison of Substrate Binding Sites in Dehaloperoxidase A and B.

Author

Aktar MS, de Serrano V, Ghiladi RA, and Franzen S

Subjects

Crystallography, X-Ray, Substrate Specificity, Binding Sites, Catalytic Domain, Models, Molecular, Protein Conformation, Animals, Kinetics, Peroxidases chemistry, Peroxidases metabolism

Abstract

Dehalperoxidase (DHP) has diverse catalytic activities depending on the substrate binding conformation, pH, and dynamics in the distal pocket above the heme. According to our hypothesis, the molecular structure of the substrate and binding orientation in DHP guide enzymatic function. Enzyme kinetic studies have shown that the catalytic activity of DHP B is significantly higher than that of DHP A despite 96% sequence homology. There are more than 30 substrate-bound structures with DHP B, each providing insight into the nature of enzymatic binding at the active site. By contrast, the only X-ray crystallographic structures of small molecules in a complex with DHP A are phenols. This study is focused on investigating substrate binding in DHP A to compare with DHP B structures. Fifteen substrates were selected that were known to bind to DHP B in the crystal to test whether soaking substrates into DHP A would yield similar structures. Five of these substrates yielded X-ray crystal structures of substrate-bound DHP A, namely, 2,4-dichlorophenol (1.48 Å, PDB: 8EJN), 2,4-dibromophenol (1.52 Å, PDB: 8VSK), 4-nitrophenol (2.03 Å, PDB: 8VKC), 4-nitrocatechol (1.40 Å, PDB: 8VKD), and 4-bromo-o-cresol (1.64 Å, PDB: 8VZR). For the remaining substrates that bind to DHP B, such as cresols, 5-bromoindole, benzimidazole, 4,4-biphenol, 4.4-ethylidenebisphenol, 2,4-dimethoxyphenol, and guaiacol, the electron density maps in DHP A are not sufficient to determine the presence of the substrates, much less their orientation. In our hands, only phenols, 4-Br-o-cresol, and 4-nitrocatechol can be soaked into crystalline DHP A. None of the larger substrates were observed to bind. A minimum of seven hanging drops were selected for soaking with more than 50 crystals screened for each substrate. The five high-quality examples of direct comparison of modes of binding in DHP A and B for the same substrate provide further support for the hypothesis that the substrate-binding conformation determines the enzyme function of DHP.

Published

2024

38. Implication of Molecular Constraints Facilitating the Functional Evolution of Pseudomonas aeruginosa KPR2 into a Versatile α-Keto-Acid Reductase.

Author

Basu Choudhury G and Datta S

Subjects

Evolution, Molecular, Catalytic Domain, Substrate Specificity, Models, Molecular, Alcohol Oxidoreductases chemistry, Alcohol Oxidoreductases metabolism, Alcohol Oxidoreductases genetics, Crystallography, X-Ray, Protein Conformation, Kinetics, Pseudomonas aeruginosa enzymology, Pseudomonas aeruginosa genetics, Pseudomonas aeruginosa metabolism, Bacterial Proteins metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics

Abstract

Theoretical concepts linking the structure, function, and evolution of a protein, while often intuitive, necessitate validation through investigations in real-world systems. Our study empirically explores the evolutionary implications of multiple gene copies in an organism by shedding light on the structure-function modulations observed in Pseudomonas aeruginosa 's second copy of ketopantoate reductase (PaKPR2). We demonstrated with two apo structures that the typical active site cleft of the protein transforms into a two-sided pocket where a molecular gate made up of two residues controls the substrate entry site, resulting in its inactivity toward the natural substrate ketopantoate. Strikingly, this structural modification made the protein active against several important α-keto-acid substrates with varied efficiency. Structural constraints at the binding site for this altered functional trait were analyzed with two binary complexes that show the conserved residue microenvironment faces restricted movements due to domain closure. Finally, its mechanistic highlights gathered from a ternary complex structure help in delineating the molecular perspectives behind its kinetic cooperativity toward these broad range of substrates. Detailed structural characteristics of the protein presented here also identified four key amino acid residues responsible for its versatile α-keto-acid reductase activity, which can be further modified to improve its functional properties through protein engineering.

Published

2024

39. Cytochrome P450 125A4, the Third Cholesterol C‑26 Hydroxylase from Mycobacterium smegmatis

Author

Frank, Daniel J, Waddling, Christopher A, La, Maggie, and de Montellano, Paul R Ortiz

Subjects

Biochemistry and Cell Biology, Biological Sciences, Rare Diseases, Tuberculosis, Good Health and Well Being, Amino Acid Substitution, Bacterial Proteins, Catalytic Domain, Cholesterol 7-alpha-Hydroxylase, Crystallography, X-Ray, Cytochrome P-450 Enzyme System, Gene Knockout Techniques, Genes, Bacterial, Hydroxycholesterols, Kinetics, Models, Molecular, Mutagenesis, Site-Directed, Mycobacterium smegmatis, Spectrophotometry, Structural Homology, Protein, Substrate Specificity, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Mycobacterium tuberculosis (Mtb) and Mycobacterium smegmatis (Msmeg) can grow on cholesterol as the sole carbon source. In Mtb the utilization of cholesterol can be initiated by CYP125A1 or CYP142A1 and in Msmeg by the orthologous CYP125A3 and CYP142A2. Double knockout of the two enzymes in Mtb prevents its growth on cholesterol, but the double knockout of Msmeg is still able to grow, albeit at a slower rate. We report here that Msmeg has a third enzyme, CYP125A4, that also oxidizes cholesterol, although it has a much higher activity for the oxidation of 7α-hydroxycholesterol. The ability of Msmeg CYP125A4 (and Mtb CYP125A1) to oxidize 7α-hydroxycholesterol is due, at least in part, to the presence of a smaller amino acid side chain facing C-7 of the sterol substrate than in CYP125A3. The ability to oxidize 7-substituted steroids broadens the range of sterol carbon sources for growth, but even more importantly in Mtb, additional biological effects are possible due to the potent immunomodulatory activity of 7α,26-dihydroxycholesterol.

Published

2015

40. Probing Kinase Activation and Substrate Specificity with an Engineered Monomeric IKK2

Author

Hauenstein, Arthur V, Rogers, W Eric, Shaul, Jacob D, Huang, De-Bin, Ghosh, Gourisankar, and Huxford, Tom

Subjects

Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Crystallography, X-Ray, Enzyme Activation, Humans, I-kappa B Kinase, Phosphorylation, Protein Binding, Protein Engineering, Protein Multimerization, Substrate Specificity, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Catalytic subunits of the IκB kinase (IKK), IKK1/IKKα, and IKK2/IKKβ function in vivo as dimers in association with the necessary scaffolding subunit NEMO/IKKγ. Recent X-ray crystal structures of IKK2 suggested that dimerization might be mediated by a smaller protein-protein interaction than previously thought. Here, we report that removal of a portion of the scaffold dimerization domain (SDD) of human IKK2 yields a kinase subunit that remains monomeric in solution. Expression in baculovirus-infected Sf9 insect cells and purification of this engineered monomeric human IKK2 enzyme allows for in vitro analysis of its substrate specificity and mechanism of activation. We find that the monomeric enzyme, which contains all of the amino-terminal kinase and ubiquitin-like domains as well as the more proximal portions of the SDD, functions in vitro to direct phosphorylation exclusively to residues S32 and S36 of its IκBα substrate. Thus, the NF-κB-inducing potential of IKK2 is preserved in the engineered monomer. Furthermore, we observe that our engineered IKK2 monomer readily autophosphorylates activation loop serines 177 and 181 in trans. However, when residues that were previously observed to interfere with IKK2 trans autophosphorylation in transfected cells are mutated within the context of the monomer, the resulting Sf9 cell expressed and purified proteins were significantly impaired in their trans autophosphorylation activity in vitro. This study further defines the determinants of substrate specificity and provides additional evidence in support of a model in which activation via trans autophosphorylation of activation loop serines in IKK2 requires transient assembly of higher-order oligomers.

Published

2014

41. Structural Basis for Substrate Specificity and Mechanism of N‑Acetyl‑d‑neuraminic Acid Lyase from Pasteurella multocida

Author

Huynh, Nhung, Aye, Aye, Li, Yanhong, Yu, Hai, Cao, Hongzhi, Tiwari, Vinod Kumar, Shin, Don-Wook, Chen, Xi, and Fisher, Andrew J

Subjects

Biochemistry and Cell Biology, Chemical Sciences, Biological Sciences, Generic health relevance, Amino Acid Substitution, Bacterial Proteins, Biocatalysis, Catalytic Domain, Hydrolysis, Models, Molecular, Molecular Conformation, Mutagenesis, Site-Directed, Mutant Proteins, N-Acetylneuraminic Acid, Neuraminic Acids, Oxo-Acid-Lyases, Pasteurella multocida, Protein Multimerization, Protein Structure, Secondary, Protein Subunits, Recombinant Proteins, Schiff Bases, Substrate Specificity, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

N-Acetylneuraminate lyases (NALs) or sialic acid aldolases catalyze the reversible aldol cleavage of N-acetylneuraminic acid (Neu5Ac, the most common form of sialic acid) to form pyruvate and N-acetyl-d-mannosamine. Although equilibrium favors sialic acid cleavage, these enzymes can be used for high-yield chemoenzymatic synthesis of structurally diverse sialic acids in the presence of excess pyruvate. Engineering these enzymes to synthesize structurally modified natural sialic acids and their non-natural derivatives holds promise in creating novel therapeutic agents. Atomic-resolution structures of these enzymes will greatly assist in guiding mutagenic and modeling studies to engineer enzymes with altered substrate specificity. We report here the crystal structures of wild-type Pasteurella multocida N-acetylneuraminate lyase and its K164A mutant. Like other bacterial lyases, it assembles into a homotetramer with each monomer folding into a classic (β/α)₈ TIM barrel. Two wild-type structures were determined, in the absence of substrates, and trapped in a Schiff base intermediate between Lys164 and pyruvate, respectively. Three structures of the K164A variant were determined: one in the absence of substrates and two binary complexes with N-acetylneuraminic acid (Neu5Ac) and N-glycolylneuraminic acid (Neu5Gc). Both sialic acids bind to the active site in the open-chain ketone form of the monosaccharide. The structures reveal that every hydroxyl group of the linear sugars makes hydrogen bond interactions with the enzyme, and the residues that determine specificity were identified. Additionally, the structures provide some clues for explaining the natural discrimination of sialic acid substrates between the P. multocida and Escherichia coli NALs.

Published

2013

42. Kinetic and structural investigations into the allosteric and pH effect on the substrate specificity of human epithelial 15-lipoxygenase-2.

Author

Joshi, Netra, Hoobler, Eric, Perry, Steven, Diaz, Giovanni, Fox, Brian, and Holman, Ted|Theodore

Subjects

Allosteric Site, Arachidonate 15-Lipoxygenase, Humans, Hydrogen-Ion Concentration, Kinetics, Substrate Specificity

Abstract

Lipoxygenases, important enzymes in inflammation, can regulate their substrate specificity by allosteric interactions with their own hydroperoxide products. In this work, addition of both 13-(S)-hydroxy-(9Z,11E)-octadecadienoic acid [13-(S)-HODE] and 13-(S)-hydroperoxy-(6Z,9Z,11E)-octadecatrienoic acid to human epithelial 15-lipoxygenase-2 (15-LOX-2) increases the kcat/KM substrate specificity ratio of arachidonic acid (AA) and γ-linolenic acid (GLA) by 4-fold. 13-(S)-HODE achieves this change by activating kcat/KM(AA) but inhibiting kcat/KM(GLA), which indicates that the allosteric structural changes at the active site discriminate between the length and unsaturation differences of AA and GLA to achieve opposite kinetic effects. The substrate specificity ratio is further increased, 11-fold in total, with an increase in pH, suggesting mechanistic differences between the pH and allosteric effects. Interestingly, the loss of the PLAT domain affects substrate specificity but does not eliminate the allosteric properties of 15-LOX-2, indicating that the allosteric site is located in the catalytic domain. However, the removal of the PLAT domain does change the magnitude of the allosteric effect. These data suggest that the PLAT domain moderates the communication pathway between the allosteric and catalytic sites, thus affecting substrate specificity. These results are discussed in the context of protein dimerization and other structural changes.

Published

2013

43. RNA-Seq Analysis Identifies a Novel Set of Editing Substrates for Human ADAR2 Present in Saccharomyces cerevisiae

Author

Eifler, Tristan, Pokharel, Subhash, and Beal, Peter A

Subjects

Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Genetics, Biological Sciences, Rare Diseases, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Adenosine Deaminase, Basic-Leucine Zipper Transcription Factors, Humans, Oligonucleotide Array Sequence Analysis, RNA, RNA, Small Nuclear, RNA-Binding Proteins, Repressor Proteins, Saccharomyces cerevisiae, Saccharomyces cerevisiae Proteins, Substrate Specificity, Transcription Factors, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

ADAR2 is a member of a family of RNA editing enzymes found in metazoa that bind double helical RNAs and deaminate select adenosines. We find that when human ADAR2 is overexpressed in the budding yeast Saccharomyces cerevisiae it substantially reduces the rate of cell growth. This effect is dependent on the deaminase activity of the enzyme, suggesting yeast transcripts are edited by ADAR2. Characterization of this novel set of RNA substrates provided a unique opportunity to gain insight into ADAR2's site selectivity. We used RNA-Seq. to identify transcripts present in S. cerevisiae subject to ADAR2-catalyzed editing. From this analysis, we identified 17 adenosines present in yeast RNAs that satisfied our criteria for candidate editing sites. Substrates identified include both coding and noncoding RNAs. Subsequent Sanger sequencing of RT-PCR products from yeast total RNA confirmed efficient editing at a subset of the candidate sites including BDF2 mRNA, RL28 intron RNA, HAC1 3'UTR RNA, 25S rRNA, U1 snRNA, and U2 snRNA. Two adenosines within the U1 snRNA sequence not identified as substrates during the original RNA-Seq. screen were shown to be deaminated by ADAR2 during the follow-up analysis. In addition, examination of the RNA sequence surrounding each edited adenosine in this novel group of ADAR2 sites revealed a previously unrecognized sequence preference. Remarkably, rapid deamination at one of these sites (BDF2 mRNA) does not require ADAR2's dsRNA-binding domains (dsRBDs). Human glioma-associated oncogene 1 (GLI1) mRNA is a known ADAR2 substrate with similar flanking sequence and secondary structure to the yeast BDF2 site discovered here. As observed with the BDF2 site, rapid deamination at the GLI1 site does not require ADAR2's dsRBDs.

Published

2013

44. Deamination of 6‑Aminodeoxyfutalosine in Menaquinone Biosynthesis by Distantly Related Enzymes

Author

Goble, Alissa M, Toro, Rafael, Li, Xu, Ornelas, Argentina, Fan, Hao, Eswaramoorthy, Subramaniam, Patskovsky, Yury, Hillerich, Brandan, Seidel, Ron, Sali, Andrej, Shoichet, Brian K, Almo, Steven C, Swaminathan, Subramanyam, Tanner, Martin E, and Raushel, Frank M

Subjects

Biochemistry and Cell Biology, Biological Sciences, Actinomycetales, Catalytic Domain, Crystallography, X-Ray, Deamination, Deinococcus, Epsilonproteobacteria, Kinetics, Models, Molecular, Molecular Docking Simulation, Nucleoside Deaminases, Purine Nucleosides, Streptomyces, Substrate Specificity, Vitamin K 2, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Proteins of unknown function belonging to cog1816 and cog0402 were characterized. Sav2595 from Steptomyces avermitilis MA-4680, Acel0264 from Acidothermus cellulolyticus 11B, Nis0429 from Nitratiruptor sp. SB155-2 and Dr0824 from Deinococcus radiodurans R1 were cloned, purified, and their substrate profiles determined. These enzymes were previously incorrectly annotated as adenosine deaminases or chlorohydrolases. It was shown here that these enzymes actually deaminate 6-aminodeoxyfutalosine. The deamination of 6-aminodeoxyfutalosine is part of an alternative menaquinone biosynthetic pathway that involves the formation of futalosine. 6-Aminodeoxyfutalosine is deaminated by these enzymes with catalytic efficiencies greater than 10(5) M(-1) s(-1), Km values of 0.9-6.0 μM, and kcat values of 1.2-8.6 s(-1). Adenosine, 2'-deoxyadenosine, thiomethyladenosine, and S-adenosylhomocysteine are deaminated at least an order of magnitude slower than 6-aminodeoxyfutalosine. The crystal structure of Nis0429 was determined and the substrate, 6-aminodeoxyfutalosine, was positioned in the active site on the basis of the presence of adventitiously bound benzoic acid. In this model, Ser-145 interacts with the carboxylate moiety of the substrate. The structure of Dr0824 was also determined, but a collapsed active site pocket prevented docking of substrates. A computational model of Sav2595 was built on the basis of the crystal structure of adenosine deaminase and substrates were docked. The model predicted a conserved arginine after β-strand 1 to be partially responsible for the substrate specificity of Sav2595.

Published

2013

45. Predicting Enzyme–Substrate Specificity with QM/MM Methods: A Case Study of the Stereospecificity of d‑Glucarate Dehydratase

Author

Tian, Boxue, Wallrapp, Frank, Kalyanaraman, Chakrapani, Zhao, Suwen, Eriksson, Leif A, and Jacobson, Matthew P

Subjects

Generic health relevance, Adipates, Biocatalysis, Glucaric Acid, Hydro-Lyases, Models, Chemical, Models, Molecular, Molecular Dynamics Simulation, Molecular Structure, Protein Binding, Protein Structure, Tertiary, Quantum Theory, Stereoisomerism, Substrate Specificity, Thermodynamics, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

The stereospecificity of d-glucarate dehydratase (GlucD) is explored by QM/MM calculations. Both the substrate binding and the chemical steps of GlucD contribute to substrate specificity. Although the identification of transition states remains computationally intensive, we suggest that QM/MM computations on ground states or intermediates can capture aspects of specificity that cannot be obtained using docking or molecular mechanics methods.

Published

2013

46. Two-Parameter Kinetic Model Based on a Time-Dependent Activity Coefficient Accurately Describes Enzymatic Cellulose Digestion

Author

Kostylev, Maxim and Wilson, David

Subjects

Responsible Consumption and Production, Actinomycetales, Algorithms, Bacterial Proteins, Catalytic Domain, Cellulases, Cellulose, Fungal Proteins, Kinetics, Models, Biological, Models, Statistical, Substrate Specificity, Temperature, Time Factors, Trichoderma, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Lignocellulosic biomass is a potential source of renewable, low-carbon-footprint liquid fuels. Biomass recalcitrance and enzyme cost are key challenges associated with the large-scale production of cellulosic fuel. Kinetic modeling of enzymatic cellulose digestion has been complicated by the heterogeneous nature of the substrate and by the fact that a true steady state cannot be attained. We present a two-parameter kinetic model based on the Michaelis-Menten scheme ( Michaelis, L., and Menten, M. L. ( 1913 ) Biochem. Z. , 49 , 333 - 369 ) with a time-dependent activity coefficient analogous to fractal-like kinetics formulated by Kopelman ( Kopelman, R. ( 1988 ) Science 241 , 1620 - 1626 ). We provide a mathematical derivation and experimental support to show that one of the parameters is a total activity coefficient and the other is an intrinsic constant that reflects the ability of the cellulases to overcome substrate recalcitrance. The model is applicable to individual cellulases and their mixtures at low-to-medium enzyme loads. Using biomass degrading enzymes from cellulolytic bacterium Thermobifida fusca , we show that the model can be used for mechanistic studies of enzymatic cellulose digestion. We also demonstrate that it applies to the crude supernatant of the widely studied cellulolytic fungus Trichoderma reesei ; thus it can be used to compare cellulases from different organisms. The two parameters may serve a similar role to Vmax, KM, and kcat in classical kinetics. A similar approach may be applicable to other enzymes with heterogeneous substrates and where a steady state is not achievable.

Published

2013

47. Functional Annotation and Three-Dimensional Structure of an Incorrectly Annotated Dihydroorotase from cog3964 in the Amidohydrolase Superfamily

Author

Ornelas, Argentina, Korczynska, Magdalena, Ragumani, Sugadev, Kumaran, Desigan, Narindoshvili, Tamari, Shoichet, Brian K, Swaminathan, Subramanyam, and Raushel, Frank M

Subjects

Biochemistry and Cell Biology, Biological Sciences, Agrobacterium tumefaciens, Amidohydrolases, Catalytic Domain, Crystallography, X-Ray, Dihydroorotase, Glycine, Models, Molecular, Ochrobactrum anthropi, Organophosphorus Compounds, Protein Conformation, Substrate Specificity, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

The substrate specificities of two incorrectly annotated enzymes belonging to cog3964 from the amidohydrolase superfamily were determined. This group of enzymes are currently misannotated as either dihydroorotases or adenine deaminases. Atu3266 from Agrobacterium tumefaciens C58 and Oant2987 from Ochrobactrum anthropi ATCC 49188 were found to catalyze the hydrolysis of acetyl-(R)-mandelate and similar esters with values of k(cat)/K(m) that exceed 10(5) M(-1) s(-1). These enzymes do not catalyze the deamination of adenine or the hydrolysis of dihydroorotate. Atu3266 was crystallized and the structure determined to a resolution of 2.62 Å. The protein folds as a distorted (β/α)(8) barrel and binds two zincs in the active site. The substrate profile was determined via a combination of computational docking to the three-dimensional structure of Atu3266 and screening of a highly focused library of potential substrates. The initial weak hit was the hydrolysis of N-acetyl-D-serine (k(cat)/K(m) = 4 M(-1) s(-1)). This was followed by the progressive identification of acetyl-(R)-glycerate (k(cat)/K(m) = 4 × 10(2) M(-1) s(-1)), acetyl glycolate (k(cat)/K(m) = 1.3 × 10(4) M(-1) s(-1)), and ultimately acetyl-(R)-mandelate (k(cat)/K(m) = 2.8 × 10(5) M(-1) s(-1)).

Published

2013

48. Anticancer Drugs of Lysine Specific Histone Demethylase-1 (LSD1) Display Variable Inhibition on Nucleosome Substrates.

Author

Senanayaka D, Zeng D, Deniz E, Priyankara IK, Helmbreck J, Schneider O, Mardikar A, Uren A, and Reiter NJ

Subjects

Humans, Enzyme Inhibitors pharmacology, Enzyme Inhibitors chemistry, Cell Line, Tumor, Histones metabolism, Tranylcypromine pharmacology, Substrate Specificity, Kinetics, Histone Demethylases antagonists & inhibitors, Histone Demethylases metabolism, Nucleosomes metabolism, Nucleosomes drug effects, Antineoplastic Agents pharmacology

Abstract

Lysine specific demethylase-1 (LSD1) serves as a regulator of transcription and represents a promising epigenetic target for anticancer treatment. LSD1 inhibitors are in clinical trials for the treatment of Ewing's sarcoma (EWS), acute myeloid leukemia, and small cell lung cancer, and the development of robust inhibitors requires accurate methods for probing demethylation, potency, and selectivity. Here, the inhibition kinetics on the H3K4me2 peptide and nucleosome substrates was examined, comparing the rates of demethylation in the presence of reversible [CC-90011 (PD) and SP-2577 (SD)] and irreversible [ORY-1001 (ID) and tranylcypromine (TCP)] inhibitors. Inhibitors were also subject to viability studies in three human cell lines and Western blot assays to monitor H3K4me2 nucleosome levels in EWS (TC-32) cells, enabling a correlation of drug potency, inhibition in vitro , and cell-based studies. For example, SP-2577, a drug in clinical trials for EWS, inhibits activity on small peptide substrates ( K i = 60 ± 20 nM) using an indirect coupled assay but does not inhibit demethylation on H3K4me2 peptides or nucleosomes using direct Western blot approaches. In addition, the drug has no effect on H3K4me2 levels in TC-32 cells. These data show that SP-2577 is not an LSD1 enzyme inhibitor, although the drug may function independent of demethylation due to its cytotoxic selectivity in TC-32 cells. Taken together, this work highlights the pitfalls of using coupled assays to ascribe a drug's mode of action, emphasizes the use of physiologically relevant substrates in epigenetic drug targeting strategies, and provides insight into the development of substrate-selective inhibitors of LSD1.

Published

2024

49. Modifying the Basicity of the dNTP Leaving Group Modulates Precatalytic Conformational Changes of DNA Polymerase β.

Author

Alnajjar KS, Wang K, Alvarado-Cruz I, Chavira C, Negahbani A, Nakhjiri M, Minard C, Garcia-Barboza B, Kashemirov BA, McKenna CE, Goodman MF, and Sweasy JB

Subjects

Humans, Deoxycytosine Nucleotides metabolism, Deoxycytosine Nucleotides chemistry, Substrate Specificity, Models, Molecular, Kinetics, DNA metabolism, DNA chemistry, DNA Repair, DNA Polymerase beta chemistry, DNA Polymerase beta metabolism, DNA Polymerase beta genetics, Protein Conformation

Abstract

The catalytic function of DNA polymerase β (pol β) fulfills the gap-filling requirement of the base excision DNA repair pathway by incorporating a single nucleotide into a gapped DNA substrate resulting from the removal of damaged DNA bases. Most importantly, pol β can select the correct nucleotide from a pool of similarly structured nucleotides to incorporate into DNA in order to prevent the accumulation of mutations in the genome. Pol β is likely to employ various mechanisms for substrate selection. Here, we use dCTP analogues that have been modified at the β,γ-bridging group of the triphosphate moiety to monitor the effect of leaving group basicity of the incoming nucleotide on precatalytic conformational changes, which are important for catalysis and selectivity. It has been previously shown that there is a linear free energy relationship between leaving group p K a and the chemical transition state. Our results indicate that there is a similar relationship with the rate of a precatalytic conformational change, specifically, the closing of the fingers subdomain of pol β. In addition, by utilizing analogue β,γ-CHX stereoisomers, we identified that the orientation of the β,γ-bridging group relative to R183 is important for the rate of fingers closing, which directly influences chemistry.

Published

2024

50. Impact of N -Glycosylation on Protein Structure and Dynamics Linked to Enzymatic C-H Activation in the M. oryzae Lipoxygenase.

Author

Whittington C, Sharma A, Hill SG, Iavarone AT, Hoffman BM, and Offenbacher AR

Subjects

Catalytic Domain, Enzyme Activation, Glycosylation, Kinetics, Models, Molecular, Polysaccharides metabolism, Polysaccharides chemistry, Protein Conformation, Protein Processing, Post-Translational, Substrate Specificity, Fungal Proteins metabolism, Fungal Proteins chemistry, Fungal Proteins genetics, Lipoxygenase metabolism, Lipoxygenase chemistry, Lipoxygenase genetics

Abstract

Lipoxygenases (LOXs) from pathogenic fungi are potential therapeutic targets for defense against plant and select human diseases. In contrast to the canonical LOXs in plants and animals, fungal LOXs are unique in having appended N -linked glycans. Such important post-translational modifications (PTMs) endow proteins with altered structure, stability, and/or function. In this study, we present the structural and functional outcomes of removing or altering these surface carbohydrates on the LOX from the devastating rice blast fungus, M. oryzae , Mo LOX. Alteration of the PTMs did notinfluence the active site enzyme-substrate ground state structures as visualized by electron-nuclear double resonance (ENDOR) spectroscopy. However, removal of the eight N -linked glycans by asparagine-to-glutamine mutagenesis nonetheless led to a change in substrate selectivity and an elevated activation energy for the reaction with substrate linoleic acid, as determined by kinetic measurements. Comparative hydrogen-deuterium exchange mass spectrometry (HDX-MS) analysis of wild-type and Asn-to-Gln Mo LOX variants revealed a regionally defined impact on the dynamics of the arched helix that covers the active site. Guided by these HDX results, a single glycan sequon knockout was generated at position 72, and its comparative substrate selectivity from kinetics nearly matched that of the Asn-to-Gln variant. The cumulative data from model glyco-enzyme Mo LOX showcase how the presence, alteration, or removal of even a single N -linked glycan can influence the structural integrity and dynamics of the protein that are linked to an enzyme's catalytic proficiency, while indicating that extensive glycosylation protects the enzyme during pathogenesis by protecting it from protease degradation.

Published

2024