Your search keyword '"Fierke CA"' showing total 20 results

1. Gambogic acid and juglone inhibit RNase P through distinct mechanisms.

Author

Wu Meyers N, Karasik A, Kaitany K, Fierke CA, and Koutmos M

Subjects

Humans, Arabidopsis metabolism, Arabidopsis Proteins antagonists & inhibitors, Arabidopsis Proteins metabolism, RNA Precursors metabolism, RNA, Transfer metabolism, Naphthoquinones pharmacology, Ribonuclease P antagonists & inhibitors, Ribonuclease P metabolism

Abstract

The first step in transfer RNA (tRNA) maturation is the cleavage of the 5' end of precursor tRNA (pre-tRNA) catalyzed by ribonuclease P (RNase P). RNase P is either a ribonucleoprotein complex with a catalytic RNA subunit or a protein-only RNase P (PRORP). In most land plants, algae, and Euglenozoa, PRORP is a single-subunit enzyme. There are currently no inhibitors of PRORP for use as tools to study the biological function of this enzyme. Therefore, we screened for compounds that inhibit the activity of a model PRORP from A. thaliana organelles (PRORP1) using a high throughput fluorescence polarization cleavage assay. Two compounds, gambogic acid and juglone (5-hydroxy-1,4-naphthalenedione) that inhibit PRORP1 in the 1 μM range were identified and analyzed. We found these compounds similarly inhibit human mtRNase P, a multisubunit protein enzyme and are 50-fold less potent against bacterial RNA-dependent RNase P. Our biochemical measurements indicate that gambogic acid is a rapid-binding, uncompetitive inhibitor targeting the PRORP1-substrate complex, while juglone acts as a time-dependent PRORP1 inhibitor. Additionally, X-ray crystal structures of PRORP1 in complex with juglone demonstrate the formation of a covalent complex with cysteine side chains on the surface of the protein. Finally, we propose a model consistent with the kinetic data that involves juglone binding to PRORP1 rapidly to form an inactive enzyme-inhibitor complex and then undergoing a slow step to form an inactive covalent adduct with PRORP1. These inhibitors have the potential to be developed into tools to probe PRORP structure and function relationships., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

2. The chaperone SmgGDS-607 has a dual role, both activating and inhibiting farnesylation of small GTPases.

Author

García-Torres D and Fierke CA

Subjects

Alkyl and Aryl Transferases chemistry, Alkyl and Aryl Transferases genetics, Alkyl and Aryl Transferases metabolism, Amino Acid Motifs, Biocatalysis, GTP Phosphohydrolases antagonists & inhibitors, GTP Phosphohydrolases metabolism, Guanine Nucleotide Exchange Factors genetics, Humans, Kinetics, Monomeric GTP-Binding Proteins chemistry, Mutagenesis, Site-Directed, Protein Binding, Protein Prenylation, Proto-Oncogene Proteins p21(ras) genetics, Proto-Oncogene Proteins p21(ras) metabolism, Recombinant Proteins biosynthesis, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Substrate Specificity, Thermodynamics, Tumor Suppressor Proteins antagonists & inhibitors, Tumor Suppressor Proteins metabolism, Guanine Nucleotide Exchange Factors metabolism, Monomeric GTP-Binding Proteins metabolism

Abstract

Ras family small GTPases undergo prenylation (such as farnesylation) for proper localization to the plasma membrane, where they can initiate oncogenic signaling pathways. Small GTP-binding protein GDP-dissociation stimulator (SmgGDS) proteins are chaperones that bind and traffic small GTPases, although their exact cellular function is unknown. Initially, SmgGDS proteins were classified as guanine nucleotide exchange factors, but recent findings suggest that SmgGDS proteins also regulate prenylation of small GTPases in vivo in a substrate-selective manner. SmgGDS-607 recognizes the polybasic region and the CAA X box of several small GTPases and inhibits prenylation by impeding their entry into the geranylgeranylation pathway. Here, using recombinant and purified enzymes for prenylation and protein-binding assays, we demonstrate that SmgGDS-607 differentially regulates farnesylation of several small GTPases. SmgGDS-607 inhibited farnesylation of some proteins, such as DiRas1, by sequestering the protein and limiting modification catalyzed by protein farnesyltransferase (FTase). We found that the competitive binding affinities of the small GTPase for SmgGDS-607 and FTase dictate the extent of this inhibition. Additionally, we discovered that SmgGDS-607 increases the rate of farnesylation of HRas by enhancing product release from FTase. Our work indicates that SmgGDS-607 binds to a broad range of small GTPases and does not require a PBR for recognition. Together, these results provide mechanistic insight into SmgGDS-607-mediated regulation of farnesylation of small GTPases and suggest that SmgGDS-607 has multiple modes of substrate recognition., (© 2019 García-Torres and Fierke.)

Published

2019

3. HDAC8 substrate selectivity is determined by long- and short-range interactions leading to enhanced reactivity for full-length histone substrates compared with peptides.

Author

Castañeda CA, Wolfson NA, Leng KR, Kuo YM, Andrews AJ, and Fierke CA

Subjects

Catalysis, Crystallography, X-Ray methods, Histone Deacetylases physiology, Histones physiology, Humans, Kinetics, Peptides chemistry, Repressor Proteins physiology, Substrate Specificity physiology, Histone Deacetylases metabolism, Histones metabolism, Repressor Proteins metabolism

Abstract

Histone deacetylases (HDACs) catalyze deacetylation of acetyl-lysine residues within proteins. To date, HDAC substrate specificity and selectivity have been largely estimated using peptide substrates. However, it is unclear whether peptide substrates accurately reflect the substrate selectivity of HDAC8 toward full-length proteins. Here, we compare HDAC8 substrate selectivity in the context of peptides, full-length proteins, and protein-nucleic acid complexes. We demonstrate that HDAC8 catalyzes deacetylation of tetrameric histone (H3/H4) substrates with catalytic efficiencies that are 40-300-fold higher than those for corresponding peptide substrates. Thus, we conclude that additional contacts with protein substrates enhance catalytic efficiency. However, the catalytic efficiency decreases for larger multiprotein complexes. These differences in HDAC8 substrate selectivity for peptides and full-length proteins suggest that HDAC8 substrate preference is based on a combination of short- and long-range interactions. In summary, this work presents detailed kinetics for HDAC8-catalyzed deacetylation of singly-acetylated, full-length protein substrates, revealing that HDAC8 substrate selectivity is determined by multiple factors. These insights provide a foundation for understanding recognition of full-length proteins by HDACs., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

4. The tumor-suppressive small GTPase DiRas1 binds the noncanonical guanine nucleotide exchange factor SmgGDS and antagonizes SmgGDS interactions with oncogenic small GTPases.

Author

Bergom C, Hauser AD, Rymaszewski A, Gonyo P, Prokop JW, Jennings BC, Lawton AJ, Frei A, Lorimer EL, Aguilera-Barrantes I, Mackinnon AC Jr, Noon K, Fierke CA, and Williams CL

Published

2016

5. The Tumor-suppressive Small GTPase DiRas1 Binds the Noncanonical Guanine Nucleotide Exchange Factor SmgGDS and Antagonizes SmgGDS Interactions with Oncogenic Small GTPases.

Author

Bergom C, Hauser AD, Rymaszewski A, Gonyo P, Prokop JW, Jennings BC, Lawton AJ, Frei A, Lorimer EL, Aguilera-Barrantes I, Mackinnon AC, Noon K, Fierke CA, and Williams CL

Subjects

Amino Acid Sequence, Breast Neoplasms enzymology, Carcinoma, Ductal, Breast enzymology, GTP Phosphohydrolases chemistry, Guanine Nucleotide Exchange Factors chemistry, Guanosine Diphosphate chemistry, Guanosine Triphosphate chemistry, HEK293 Cells, Humans, MCF-7 Cells, Molecular Docking Simulation, NF-kappa B metabolism, Protein Binding, Protein Structure, Secondary, Proto-Oncogene Proteins p21(ras) metabolism, Tumor Suppressor Proteins chemistry, rhoA GTP-Binding Protein, GTP Phosphohydrolases metabolism, Guanine Nucleotide Exchange Factors metabolism, Tumor Suppressor Proteins metabolism

Abstract

The small GTPase DiRas1 has tumor-suppressive activities, unlike the oncogenic properties more common to small GTPases such as K-Ras and RhoA. Although DiRas1 has been found to be a tumor suppressor in gliomas and esophageal squamous cell carcinomas, the mechanisms by which it inhibits malignant phenotypes have not been fully determined. In this study, we demonstrate that DiRas1 binds to SmgGDS, a protein that promotes the activation of several oncogenic GTPases. In silico docking studies predict that DiRas1 binds to SmgGDS in a manner similar to other small GTPases. SmgGDS is a guanine nucleotide exchange factor for RhoA, but we report here that SmgGDS does not mediate GDP/GTP exchange on DiRas1. Intriguingly, DiRas1 acts similarly to a dominant-negative small GTPase, binding to SmgGDS and inhibiting SmgGDS binding to other small GTPases, including K-Ras4B, RhoA, and Rap1A. DiRas1 is expressed in normal breast tissue, but its expression is decreased in most breast cancers, similar to its family member DiRas3 (ARHI). DiRas1 inhibits RhoA- and SmgGDS-mediated NF-κB transcriptional activity in HEK293T cells. We also report that DiRas1 suppresses basal NF-κB activation in breast cancer and glioblastoma cell lines. Taken together, our data support a model in which DiRas1 expression inhibits malignant features of cancers in part by nonproductively binding to SmgGDS and inhibiting the binding of other small GTPases to SmgGDS., (© 2016 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2016

6. Mechanistic Studies Reveal Similar Catalytic Strategies for Phosphodiester Bond Hydrolysis by Protein-only and RNA-dependent Ribonuclease P.

Author

Howard MJ, Klemm BP, and Fierke CA

Subjects

Anisotropy, Arabidopsis genetics, Arabidopsis Proteins genetics, Base Sequence, Binding Sites, Catalysis, Catalytic Domain, Hydrogen-Ion Concentration, Hydrolysis, Kinetics, Molecular Sequence Data, Mutation genetics, Nucleic Acid Conformation, RNA Precursors genetics, RNA Precursors metabolism, RNA, Bacterial genetics, RNA, Catalytic genetics, Ribonuclease P genetics, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Metals pharmacology, RNA, Bacterial metabolism, RNA, Catalytic metabolism, Ribonuclease P metabolism

Abstract

Ribonuclease P (RNase P) is an endonuclease that catalyzes the essential removal of the 5' end of tRNA precursors. Until recently, all identified RNase P enzymes were a ribonucleoprotein with a conserved catalytic RNA component. However, the discovery of protein-only RNase P (PRORP) shifted this paradigm, affording a unique opportunity to compare mechanistic strategies used by naturally evolved protein and RNA-based enzymes that catalyze the same reaction. Here we investigate the enzymatic mechanism of pre-tRNA hydrolysis catalyzed by the NYN (Nedd4-BP1, YacP nuclease) metallonuclease of Arabidopsis thaliana, PRORP1. Multiple and single turnover kinetic data support a mechanism where a step at or before chemistry is rate-limiting and provide a kinetic framework to interpret the results of metal alteration, mutations, and pH dependence. Catalytic activity has a cooperative dependence on the magnesium concentration (nH = 2) under kcat/Km conditions, suggesting that PRORP1 catalysis is optimal with at least two active site metal ions, consistent with the crystal structure. Metal rescue of Asp-to-Ala mutations identified two aspartates important for enhancing metal ion affinity. The single turnover pH dependence of pre-tRNA cleavage revealed a single ionization (pKa ∼ 8.7) important for catalysis, consistent with deprotonation of a metal-bound water nucleophile. The pH and metal dependence mirrors that observed for the RNA-based RNase P, suggesting similar catalytic mechanisms. Thus, despite different macromolecular composition, the RNA and protein-based RNase P act as dynamic scaffolds for the binding and positioning of magnesium ions to catalyze phosphodiester bond hydrolysis., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

7. Expansion of protein farnesyltransferase specificity using "tunable" active site interactions: development of bioengineered prenylation pathways.

Author

Hougland JL, Gangopadhyay SA, and Fierke CA

Subjects

Alkyl and Aryl Transferases chemistry, Amino Acid Sequence, Binding Sites genetics, Biocatalysis, HEK293 Cells, Humans, Kinetics, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Peptides chemistry, Protein Engineering methods, Protein Prenylation, Protein Structure, Tertiary, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits metabolism, Sequence Homology, Amino Acid, Signal Transduction, Substrate Specificity, Tryptophan chemistry, Tryptophan genetics, Tryptophan metabolism, Alkyl and Aryl Transferases genetics, Alkyl and Aryl Transferases metabolism, Catalytic Domain genetics, Peptides metabolism

Abstract

Post-translational modifications play essential roles in regulating protein structure and function. Protein farnesyltransferase (FTase) catalyzes the biologically relevant lipidation of up to several hundred cellular proteins. Site-directed mutagenesis of FTase coupled with peptide selectivity measurements demonstrates that molecular recognition is determined by a combination of multiple interactions. Targeted randomization of these interactions yields FTase variants with altered and, in some cases, bio-orthogonal selectivity. We demonstrate that FTase specificity can be "tuned" using a small number of active site contacts that play essential roles in discriminating against non-substrates in the wild-type enzyme. This tunable selectivity extends in vivo, with FTase variants enabling the creation of bioengineered parallel prenylation pathways with altered substrate selectivity within a cell. Engineered FTase variants provide a novel avenue for probing both the selectivity of prenylation pathway enzymes and the effects of prenylation pathway modifications on the cellular function of a protein.

Published

2012

8. Transient-state kinetic analysis of transcriptional activator·DNA complexes interacting with a key coactivator.

Author

Wands AM, Wang N, Lum JK, Hsieh J, Fierke CA, and Mapp AK

Subjects

DNA metabolism, Kinetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Trans-Activators metabolism, DNA chemistry, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae Proteins chemistry, Trans-Activators chemistry, Transcriptional Activation physiology

Abstract

Several lines of evidence suggest that the prototypical amphipathic transcriptional activators Gal4, Gcn4, and VP16 interact with the key coactivator Med15 (Gal11) during transcription initiation despite little sequence homology. Recent cross-linking data further reveal that at least two of the activators utilize the same binding surface within Med15 for transcriptional activation. To determine whether these three activators use a shared binding mechanism for Med15 recruitment, we characterized the thermodynamics and kinetics of Med15·activator·DNA complex formation by fluorescence titration and stopped-flow techniques. Combination of each activator·DNA complex with Med15 produced biphasic time courses. This is consistent with a minimum two-step binding mechanism composed of a bimolecular association step limited by diffusion, followed by a conformational change in the Med15·activator·DNA complex. Furthermore, the equilibrium constant for the conformational change (K(2)) correlates with the ability of an activator to stimulate transcription. VP16, the most potent of the activators, has the largest K(2) value, whereas Gcn4, the least potent, has the smallest value. This correlation is consistent with a model in which transcriptional activation is regulated at least in part by the rearrangement of the Med15·activator·DNA ternary complex. These results are the first detailed kinetic characterization of the transcriptional activation machinery and provide a framework for the future design of potent transcriptional activators.

Published

2011

9. Active site metal ion in UDP-3-O-((R)-3-hydroxymyristoyl)-N-acetylglucosamine deacetylase (LpxC) switches between Fe(II) and Zn(II) depending on cellular conditions.

Author

Gattis SG, Hernick M, and Fierke CA

Subjects

Catalytic Domain, Escherichia coli enzymology, Escherichia coli metabolism, Immunoglobulin G chemistry, Kinetics, Metalloproteins chemistry, Metals chemistry, Models, Chemical, Models, Statistical, Plasmids metabolism, Protein Binding, Thermodynamics, Amidohydrolases chemistry, Iron chemistry, Zinc chemistry

Abstract

UDP-3-O-((R)-3-hydroxymyristoyl)-N-acetylglucosamine deacetylase (LpxC) catalyzes the deacetylation of UDP-3-O-((R)-3-hydroxymyristoyl)-N-acetylglucosamine to form UDP-3-O-myristoylglucosamine and acetate in Gram-negative bacteria. This second, and committed, step in lipid A biosynthesis is a target for antibiotic development. LpxC was previously identified as a mononuclear Zn(II) metalloenzyme; however, LpxC is 6-8-fold more active with the oxygen-sensitive Fe(II) cofactor (Hernick, M., Gattis, S. G., Penner-Hahn, J. E., and Fierke, C. A. (2010) Biochemistry 49, 2246-2255). To analyze the native metal cofactor bound to LpxC, we developed a pulldown method to rapidly purify tagged LpxC under anaerobic conditions. The metal bound to LpxC purified from Escherichia coli grown in minimal medium is mainly Fe(II). However, the ratio of iron/zinc bound to LpxC varies with the metal content of the medium. Furthermore, the iron/zinc ratio bound to native LpxC, determined by activity assays, has a similar dependence on the growth conditions. LpxC has significantly higher affinity for Zn(II) compared with Fe(II) with K(D) values of 60 ± 20 pM and 110 ± 40 nM, respectively. However, in vivo concentrations of readily exchangeable iron are significantly higher than zinc, suggesting that Fe(II) is the thermodynamically favored metal cofactor for LpxC under cellular conditions. These data indicate that LpxC expressed in E. coli grown in standard medium predominantly exists as the Fe(II)-enzyme. However, the metal cofactor in LpxC can switch between iron and zinc in response to perturbations in available metal ions. This alteration may be important for regulating the LpxC activity upon changes in environmental conditions and may be a general mechanism of regulating the activity of metalloenzymes.

Published

2010

10. Activation and inhibition of histone deacetylase 8 by monovalent cations.

Author

Gantt SL, Joseph CG, and Fierke CA

Subjects

Binding Sites, Catalysis, Enzyme Activation, Histone Deacetylase Inhibitors, Humans, Kinetics, Mutation, Protein Binding, Water metabolism, Cations, Monovalent metabolism, Histone Deacetylases metabolism, Potassium metabolism, Repressor Proteins metabolism

Abstract

The metal-dependent histone deacetylases (HDACs) catalyze hydrolysis of acetyl groups from acetyllysine side chains and are targets of cancer therapeutics. Two bound monovalent cations (MVCs) of unknown function have been previously observed in crystal structures of HDAC8; site 1 is near the active site, whereas site 2 is located > 20 A from the catalytic metal ion. Here we demonstrate that one bound MVC activates catalytic activity (K(1/2) = 3.4 mM for K(+)), whereas the second, weaker-binding MVC (K(1/2) = 26 mM for K(+)) decreases catalytic activity by 11-fold. The weaker binding MVC also enhances the affinity of the HDAC inhibitor suberoylanilide hydroxamic acid by 5-fold. The site 1 MVC is coordinated by the side chain of Asp-176 that also forms a hydrogen bond with His-142, one of two histidines important for catalytic activity. The D176A and H142A mutants each increase the K(1/2) for potassium inhibition by > or = 40-fold, demonstrating that the inhibitory cation binds to site 1. Furthermore, the MVC inhibition is mediated by His-142, suggesting that this residue is protonated for maximal HDAC8 activity. Therefore, His-142 functions either as an electrostatic catalyst or a general acid. The activating MVC binds in the distal site and causes a time-dependent increase in activity, suggesting that the site 2 MVC stabilizes an active conformation of the enzyme. Sodium binds more weakly to both sites and activates HDAC8 to a lesser extent than potassium. Therefore, it is likely that potassium is the predominant MVC bound to HDAC8 in vivo.

Published

2010

11. UDP-3-O-((R)-3-hydroxymyristoyl)-N-acetylglucosamine deacetylase functions through a general acid-base catalyst pair mechanism.

Author

Hernick M, Gennadios HA, Whittington DA, Rusche KM, Christianson DW, and Fierke CA

Subjects

Amidohydrolases chemistry, Amidohydrolases metabolism, Bacteria metabolism, Binding Sites, Cacodylic Acid chemistry, Catalysis, Crystallography, X-Ray, Electrons, Escherichia coli metabolism, Histidine chemistry, Hydrogen-Ion Concentration, Ions, Kinetics, Models, Chemical, Models, Molecular, Mutagenesis, Mutagenesis, Site-Directed, Mutation, Oxygen metabolism, Palmitic Acid chemistry, Substrate Specificity, Zinc chemistry, Amidohydrolases physiology, Myristic Acids metabolism, Uridine Diphosphate N-Acetylglucosamine analogs & derivatives, Uridine Diphosphate N-Acetylglucosamine metabolism

Abstract

UDP-3-O-((R)-3-hydroxymyristoyl)-N-acetylglucosamine deacetylase (LpxC) is a zinc-dependent enzyme that catalyzes the deacetylation of UDP-3-O-((R)-3-hydroxymyristoyl)-N-acetylglucosamine to form UDP-3-O-(R-hydroxymyristoyl)glucosamine and acetate. The structural similarity of the active site of LpxC to metalloproteases led to the proposal that LpxC functions via a metalloprotease-like mechanism. The pH dependence of k(cat)/Km catalyzed by Escherichia coli and Aquifex aeolicus LpxC displayed a bell-shaped curve (EcLpxC yields apparent pKa values of 6.4+/-0.1 and 9.1+/-0.1), demonstrating that at least two ionizations are important for maximal activity. Metal substitution and mutagenesis experiments suggest that the basic limb of the pH profile is because of deprotonation of a zinc-coordinated group such as the zinc-water molecule, whereas the acidic limb of the pH profile is caused by protonation of either Glu78 or His265. Furthermore, the magnitude of the activity decreases and synergy observed for the active site mutants suggest that Glu78 and His265 act as a general acid-base catalyst pair. Crystal structures of LpxC complexed with cacodylate or palmitate demonstrate that both Glu78 and His265 hydrogen-bond with the same oxygen atom of the tetrahedral intermediate and the product carboxylate. These structural features suggest that LpxC catalyzes deacetylation by using Glu78 and His265 as a general acid-base pair and the zinc-bound water as a nucleophile.

Published

2005

12. Lysine beta311 of protein geranylgeranyltransferase type I partially replaces magnesium.

Author

Hartman HL, Bowers KE, and Fierke CA

Subjects

Alanine chemistry, Animals, Catalysis, Cloning, Molecular, Dose-Response Relationship, Drug, Escherichia coli metabolism, Hydrogen-Ion Concentration, Ions, Kinetics, Models, Molecular, Mutagenesis, Site-Directed, Mutation, Peptides chemistry, Polyisoprenyl Phosphates chemistry, Protein Binding, Rats, Recombinant Proteins chemistry, Sesquiterpenes, Temperature, Thermodynamics, Zinc chemistry, Alkyl and Aryl Transferases chemistry, Lysine chemistry, Magnesium chemistry

Abstract

Protein geranylgeranyltransferase type I (GGTase I) catalyzes the attachment of a geranylgeranyl lipid group near the carboxyl terminus of protein substrates. Unlike protein farnesyltransferase (FTase) and protein geranylgeranyltransferase type II, which require both Zn(II) and Mg(II) for maximal turnover, GGTase I turnover is dependent only on Zn(II). In FTase, the magnesium ion is coordinated by aspartate beta352 and the diphosphate of farnesyl diphosphate to stabilize the developing charge in the transition state (Pickett, J. S., Bowers, K. E., and Fierke, C. A. (2003) J. Biol. Chem. 278, 51243-51250). In GGTase I, lysine beta311 is substituted for this aspartate and is proposed to replace the catalytic function of Mg(II) (Taylor, J. S., Reid, T. S., Terry, K. L., Casey, P. J., and Beese, L. S. (2003) EMBO J. 22, 5963-5974). Here we demonstrate that the prenylation rate constant catalyzed by wild type GGTase I (k(chem) = 0.18 +/- 0.02 s(-1)) is not dependent on Mg(II), is approximately 20-fold slower than the maximal rate constant catalyzed by FTase, and has a single pKa of 6.4 +/- 0.1, likely reflecting deprotonation of the peptide thiol. Mutation of lysine beta311 in GGTase I to alanine (Kbeta311A) or aspartate (Kbeta311D) decreases the k(chem) in the absence of magnesium 9-41-fold without significantly affecting the binding affinity of either substrate. Furthermore, the geranylgeranylation rate constant is enhanced by the addition of Mg(II) for Kbeta311A and Kbeta311D GGTase I 2-5-fold compared with wild type GGTase I with K(Mg) of 140 +/- 10 mm and 6.4 +/- 0.8 mm, respectively. These results demonstrate that lysine beta311 of GGTase I partially replaces the catalytic function of Mg(II) observed in FTase.

Published

2004

13. Mutagenesis studies of protein farnesyltransferase implicate aspartate beta 352 as a magnesium ligand.

Author

Pickett JS, Bowers KE, and Fierke CA

Subjects

Alkyl and Aryl Transferases genetics, Amino Acid Substitution, Binding Sites, Catalysis, Humans, Kinetics, Ligands, Magnesium pharmacology, Polyisoprenyl Phosphates chemistry, Sesquiterpenes, Alkyl and Aryl Transferases chemistry, Aspartic Acid chemistry, Magnesium chemistry, Mutagenesis, Site-Directed

Abstract

Protein farnesyltransferase (FTase) catalyzes the addition of a farnesyl chain onto the sulfur of a C-terminal cysteine of a protein substrate. Magnesium ions enhance farnesylation catalyzed by FTase by several hundred-fold, with a KMg value of 4 mM. The magnesium ion is proposed to coordinate the diphosphate leaving group of farnesyldiphosphate (FPP) to stabilize the developing charge in the farnesylation transition state. Here we further investigate the magnesium binding site using mutagenesis and biochemical studies. Free FPP binds Mg2+ with a Kd of 120 microM. The 10-fold weaker affinity for Mg2+ observed for the FTase.FPP.peptide ternary complex is probably caused by the positive charges in the diphosphate binding pocket of FTase. Furthermore, mutation of aspartate beta 352 to alanine (D beta 352A) or lysine (D beta 352K) in FTase drastically alters the Mg2+ dependence of FTase catalysis without dramatically affecting the rate constant of farnesylation minus magnesium or the binding affinity of either substrate. In D beta 352A FTase, the KMg increases 28-fold to 110 +/- 30 mM, and the farnesylation rate constant at saturating Mg2+ decreases 27-fold to 0.30 +/- 0.05 s-1. Substitution of a lysine for Asp-beta 352 removes the magnesium activation of farnesylation catalyzed by FTase but does not significantly enhance the rate constant for farnesylation in the absence of Mg2+. In wild type FTase, Mg2+ can be replaced by Mn2+ with a 2-fold lower KMn (2 mM). These results suggest both that Mg2+ coordinates the side chain carboxylate of Asp-beta 352 and that the role of magnesium in the reaction includes positioning the FPP prior to catalysis.

Published

2003

14. Antibacterial agents that target lipid A biosynthesis in gram-negative bacteria. Inhibition of diverse UDP-3-O-(r-3-hydroxymyristoyl)-n-acetylglucosamine deacetylases by substrate analogs containing zinc binding motifs.

Author

Jackman JE, Fierke CA, Tumey LN, Pirrung M, Uchiyama T, Tahir SH, Hindsgaul O, and Raetz CR

Subjects

Amidohydrolases genetics, Amidohydrolases isolation & purification, Binding Sites, Cloning, Molecular, Escherichia coli drug effects, Gram-Negative Aerobic Rods and Cocci metabolism, Hydroxamic Acids pharmacology, Kinetics, Oxazoles pharmacology, Amidohydrolases antagonists & inhibitors, Anti-Bacterial Agents pharmacology, Gram-Negative Aerobic Rods and Cocci drug effects, Lipid A biosynthesis, Zinc metabolism

Abstract

UDP-3-O-(R-3-hydroxymyristoyl)-N-acetylglucosamine deacetylase (LpxC) catalyzes the second step in the biosynthesis of lipid A, a unique amphiphilic molecule found in the outer membranes of virtually all Gram-negative bacteria. Since lipid A biosynthesis is required for bacterial growth, inhibitors of LpxC have potential utility as antibiotics. The enzymes of lipid A biosynthesis, including LpxC, are encoded by single copy genes in all sequenced Gram-negative genomes. We have now cloned, overexpressed, and purified LpxC from the hyperthermophile Aquifex aeolicus. This heat-stable LpxC variant (the most divergent of all known LpxCs) displays 32% identity and 51% similarity over 277 amino acid residues out of the 305 in Escherichia coli LpxC. Although A. aeolicus LpxC deacetylates the substrate UDP-3-O-(R-3-hydroxymyristoyl)-N-acetylglucosamine at a rate comparable with E. coli LpxC, a phenyloxazoline-based hydroxamate that inhibits E. coli LpxC with K(i) of approximately 50 nM (Onishi, H. R., Pelak, B. A., Gerckens, L. S., Silver, L. L., Kahan, F. M., Chen, M. H., Patchett, A. A., Galloway, S. M., Hyland, S. A., Anderson, M. S., and Raetz, C. R. H. (1996) Science 274, 980-982) does not inhibit A. aeolicus LpxC. To determine whether or not broad-spectrum deacetylase inhibitors can be found, we have designed a new class of hydroxamate-containing inhibitors of LpxC, starting with the structure of the physiological substrate. Several of these compounds inhibit both E. coli and A. aeolicus LpxC at similar concentrations. We have also identified a phosphinate-containing substrate analog that inhibits both E. coli and A. aeolicus LpxC, suggesting that the LpxC reaction proceeds by a mechanism similar to that described for other zinc metalloamidases, like carboxypeptidase A and thermolysin. The differences between the phenyloxazoline and the substrate-based LpxC inhibitors might be exploited for developing novel antibiotics targeted either against some or all Gram-negative strains. We suggest that LpxC inhibitors with antibacterial activity be termed "deacetylins."

Published

2000

15. Selection of carbonic anhydrase variants displayed on phage. Aromatic residues in zinc binding site enhance metal affinity and equilibration kinetics.

Author

Hunt JA and Fierke CA

Subjects

Bacteriophages enzymology, Binding Sites, Carbonic Anhydrases chemistry, Structure-Activity Relationship, Carbonic Anhydrases metabolism, Zinc metabolism

Abstract

In all metalloenzymes, hydrophobic residues surround the metal binding site. In carbonic anhydrase II (CAII) residues Phe93, Phe95, and Trp97 flank two of the three histidines that coordinate zinc to form a hydrophobic cluster beneath the zinc binding site. A library of CAII variants differing in these hydrophobic amino acids was prepared using cassette mutagenesis, then displayed on filamentous phage, and screened for proteins retaining high zinc affinity. Wild-type CAII was enriched 20-fold by selection, and consensus residues at each position were identified from the enriched CAII variants (Ile, Phe, Leu, and Met at position 93; Ile, Leu, and Met at position 95; and Trp and Val at position 97). Highly selected variants have zinc affinity and catalytic activity nearly equal to that of wild-type CAII, indicating that the aromatic residues are not absolutely essential. However, the zinc dissociation rate constant and catalytic activity of the variants correlate with the volume of the amino acids at positions 93, 95, and 97. In summary, metalloenzyme variants displayed on phage can be selected on the basis of metal affinity; such methods will be useful for optimization of metal ion biosensors.

Published

1997

16. Evidence for a catalytic role of zinc in protein farnesyltransferase. Spectroscopy of Co2+-farnesyltransferase indicates metal coordination of the substrate thiolate.

Author

Huang CC, Casey PJ, and Fierke CA

Subjects

Animals, Apoproteins chemistry, Binding Sites, Catalysis, Cobalt, Cysteine chemistry, Farnesyltranstransferase, Rats, Recombinant Proteins, Spectrum Analysis, Structure-Activity Relationship, Alkyl and Aryl Transferases, Transferases metabolism, Zinc chemistry

Abstract

Protein farnesyltransferase (FTase) is a zinc metalloenzyme that catalyzes the addition of a farnesyl isoprenoid to a conserved cysteine in peptide or protein substrates. We have substituted the essential Zn2+ in FTase with Co2+ to investigate the function of the metal polyhedron using optical absorption spectroscopy. The catalytic activity of FTase is unchanged by the substitution of cobalt for zinc. The absorption spectrum of Co2+-FTase displays a thiolate-Co2+ charge transfer band (epsilon320 = 1030 M(-1) cm(-1)) consistent with the coordination of one cysteine side chain and also ligand field bands (epsilon560 = 140 M(-1) cm(-1)) indicative of a pentacoordinate or distorted tetrahedral metal geometry. Most importantly, the ligand-metal charge transfer band displays an increased intensity (epsilon320 = 1830 M(-1) cm(-1)) in the ternary complex of FTase x isoprenoid x peptide substrate indicative of the formation of a second Co2+-thiolate bond as cobalt coordinates the thiolate of the peptide substrate. A similar increase in the ligand-metal charge transfer band in a product complex indicates that the sulfur atom of the farnesylated peptide also coordinates the metal. Transient kinetics demonstrate that thiolate-cobalt metal coordination also occurs in an active FTase x FPP x peptide substrate complex and that the rate constant for the chemical step is 17 s(-1). These data provide evidence that the zinc ion plays an important catalytic role in FTase, most likely by activation of the cysteine thiol of the protein substrate for nucleophilic attack on the isoprenoid.

Published

1997

17. Structural and functional importance of a conserved hydrogen bond network in human carbonic anhydrase II.

Author

Krebs JF, Ippolito JA, Christianson DW, and Fierke CA

Subjects

Amino Acids chemistry, Carbon Dioxide chemistry, Carbonic Acid chemistry, Carbonic Anhydrases genetics, Carbonic Anhydrases metabolism, Crystallography, X-Ray, Esterases metabolism, Humans, Hydrogen Bonding, Mutation, Structure-Activity Relationship, Water chemistry, Carbonic Anhydrases chemistry

Abstract

Amino acid substitutions at Thr199 of human carbonic anhydrase II (CAII) (Thr199-->Ser, Ala, Val, and Pro) were characterized to investigate the importance of a conserved hydrogen bonding network. The three-dimensional structures of azide-bound and sulfate-bound T199V CAIIs were determined by x-ray crystallographic methods at 2.25 and 2.4 A, respectively (final crystallographic R factors are 0.173 and 0.174, respectively). The CO2 hydrase activities of T199S and T199P variants suggest that the side chain methyl and backbone amino functionalities stabilize the transition state by approximately 0.4 and 0.8 kcal/mol, respectively. The side chain hydroxyl group causes: stabilization of zinc-hydroxide relative to zinc-water (pKa increases approximately 2 units); stabilization of the transition state for bicarbonate dehydration relative to the CAII.HCO3- complex (approximately 5 kcal/mol); and destabilization of the CAII.HCO3- complex (approximately 0.8 kcal/mol). An inverse correlation between log(kcatCO2/KM) and the pKa of zinc-water (r = 0.95, slope = -1) indicates that the hydrogen bonding network stabilizes the chemical transition state and zinc-hydroxide similarly. These data are consistent with the hydroxyl group of Thr199 forming a hydrogen bond with the transition state and a non-hydrogen-bonded van der Waals contact with CAII.HCO3-.

Published

1993

18. Determinants of catalytic activity and stability of carbonic anhydrase II as revealed by random mutagenesis.

Author

Krebs JF and Fierke CA

Subjects

Acetazolamide metabolism, Amino Acid Sequence, Base Sequence, Binding Sites, Carbonic Anhydrases chemistry, Carbonic Anhydrases genetics, Cloning, Molecular, Dansyl Compounds metabolism, Enzyme Stability, Escherichia coli genetics, Esterases chemistry, Esterases genetics, Esterases metabolism, Humans, Isoenzymes chemistry, Isoenzymes genetics, Kinetics, Models, Molecular, Molecular Sequence Data, Protein Conformation, Protein Folding, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Carbonic Anhydrases metabolism, Isoenzymes metabolism, Mutagenesis, Site-Directed

Abstract

The functional importance of a conserved hydrophobic face in human carbonic anhydrase II (CAII), including amino acid residues 190-210, was investigated by random mutagenesis. The catalytic activity, inhibitor binding, and level of CAII expression in Escherichia coli of 57 single amino acid variants were measured revealing that the function of amino acids correlates with their secondary structure placement. Side chains of amino acids in beta-sheet structure are required for the formation of folded, stable protein while those in the turn region determine catalytic efficiency and inhibitor specificity. The CAII active site is extremely plastic, accommodating amino acid substitutions of varied size, charge, and hydrophobicity with little effect on catalysis; only substitutions at Leu198 and Thr199 decrease the rates of CO2 hydration and ester hydrolysis more than 5-fold. These results pinpoint the hydrogen bond network, including the zinc-solvent molecule and Thr199, as crucial for high catalytic efficiency and also suggest that Leu198 forms a portion of a CO2 association site. Increased activity is observed for substitutions at Thr200 (esterase) and Leu203 (hydrase). In addition, the pKa of the zinc-bound water molecule varies upon substitution of amino acids which alter the overall charge of the active site. Three residues interact with sulfonamide inhibitors; substitutions at Thr199 decrease binding (up to 10(3)-fold) while mutations at Thr200 and Cys206 increase binding of dansylamide (up to 80-fold). Mutations in the beta-sheet structure (Asp190-Ser197 and Val207-Ile-210) decrease the protein expression of CAII in E. coli, causing the formation of insoluble protein aggregates in many cases. This may suggest an important role for these residues in the folding process. In addition, mutations in Trp192, cis-Pro202, and Trp209 increase thermal lability (up to 5000-fold).

Published

1993

19. Altering the mouth of a hydrophobic pocket. Structure and kinetics of human carbonic anhydrase II mutants at residue Val-121.

Author

Nair SK, Calderone TL, Christianson DW, and Fierke CA

Subjects

Binding Sites, Carbonic Anhydrases chemistry, Carbonic Anhydrases genetics, Cloning, Molecular, Fourier Analysis, Humans, Kinetics, Mutagenesis, Site-Directed, Structure-Activity Relationship, Valine chemistry, X-Ray Diffraction, Carbonic Anhydrases metabolism

Abstract

Eleven amino acid substitutions at Val-121 of human carbonic anhydrase II including Gly, Ala, Ser, Leu, Ile, Lys, and Arg, were constructed by site-directed mutagenesis. This residue is at the mouth of the hydrophobic pocket in the enzyme active site. The CO2 hydrase activity and the p-nitrophenyl esterase activity of these CAII variants correlate with the hydrophobicity of the residue, suggesting that the hydrophobic character of this residue is important for catalysis. The effects of these mutations on the steady-state kinetics for CO2 hydration occur mainly in kcat/Km and Km, consistent with involvement of this residue in CO2 association. The Val-121----Ala mutant, which exhibits about one-third normal CO2 hydrase activity, has been studied by x-ray crystallographic methods. No significant changes in the mutant enzyme conformation are evident relative to the wild-type enzyme. Since Val-121 is at the mouth of the hydrophobic pocket, its substitution by the methyl side chain of alanine makes the pocket mouth significantly wider than that of the wild-type enzyme. Hence, although a moderately wide (and deep) pocket is important for substrate association, a wider mouth to this pocket does not seriously compromise the catalytic approach of CO2 toward nucleophilic zinc-bound hydroxide.

Published

1991

20. Two functional domains of coenzyme A activate catalysis by coenzyme A transferase. Pantetheine and adenosine 3'-phosphate 5'-diphosphate.

Author

Fierke CA and Jencks WP

Subjects

Acetoacetates pharmacology, Adenosine Diphosphate pharmacology, Animals, Enzyme Activation, Kinetics, Myocardium enzymology, Propionates pharmacology, Protein Binding, Swine, Adenosine Diphosphate analogs & derivatives, Coenzyme A metabolism, Coenzyme A-Transferases, Pantetheine pharmacology, Sulfhydryl Compounds pharmacology, Sulfurtransferases metabolism

Abstract

Studies of the reactivity of succinyl-CoA:3-keto acid CoA transferase with a small coenzyme A analog, methylmercaptopropionate, have shown that noncovalent interactions between the enzyme and the side chain of CoA are responsible for a rate acceleration of approximately 10(12), which is close to the total rate acceleration brought about by the enzyme (Moore, S. A., and Jencks, W. P. (1982) J. Biol. Chem. 257, 10893-10907). We report here that interaction between the enzyme and the pantetheine moiety of CoA provides the majority of the rate acceleration and destabilization of the enzyme-thiol ester intermediate that is observed with CoA substrates. The role of the adenosine 3'-phosphate 5'-diphosphate moiety of CoA is to provide 6.9 kcal/mol of binding energy in order to pull the pantetheine moiety into the active site. The enzyme-thiol ester intermediate, E-pantetheine, was generated by reaction of pantetheine with the thiol ester of enzyme and methylmercaptopropionate. E-Pantetheine undergoes hydrolysis with khyd = 2 min-1, 140-fold faster than E-CoA, and reacts with acetoacetate with kAcAc = 3 X 10(6) M-1 min-1, only 10-fold slower than E-CoA. However, in the reverse direction acetoacetylpantetheine reacts with CoA transferase (kAcAc-SP = 220 M-1 min-1) 1.6 X 10(6) times slower than acetoacetyl-CoA. The equilibrium constant for the reaction of pantetheine with E-CoA is approximately 8 X 10(-6).

Published

1986