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Mechanistic Insights into the Diverged Enzymes of the Amidohydrolase SuperfamilyNguyen, Tinh T. 2009 December 1900 (has links)
The amidohydrolase superfamily is a functionally diverse set of enzymes that
catalyzes predominantly hydrolysis reactions involving sugars, nucleic acids, amino
acids, and organophosphate esters. A more divergent member of this superfamily, URI
(uronate isomerase) from Escherichia coli, catalyzes the isomerization of D-glucuronate
to D-fructuronate and D-galacturonate to D-tagaturonate. In Bacillus halodurans, two
distinct operons were identified for the metabolism of D-glucuronate and D-galacturonate
based on kinetics and genomic context. The canonical uronate isomerase is encoded by
the gene Bh0705. A second URI in this organism, Bh0493, is the outlier of the group in
terms of sequence similarity. Kinetic evidences indicate that Bh0705 is relatively
specific for the isomerization of D-glucuronate, while Bh0493 is specific for the Dgalacturonate
pathway.
Bell-shaped pH-rate profiles were observed for the wild type URI from
Escherichia coli. Primary isotope effects with [2-2H]-D-glucuronate and solvent
viscosity studies are consistent with product release as the rate limiting step. X-ray
structure of Bh0493 was determined in the presence of D-glucuronate. A chemical mechanism is proposed that utilizes a proton transfer from C-2 of D-glucuronate to C-1
that is initiated by the combined actions of Asp-355 and the C-5 hydroxyl of the
substrate that is bound to the metal ion. The formation of the cis-enediol intermediate is
further facilitated by the shuttling of the proton between the C-2 and C-1 oxygens by the
conserved Tyr-50 and/or Arg-357.
Another divergent member of the AHS is the enzyme renal dipeptidase.
Structural studies of the enzyme from Streptomyces coelicolor (Sco3058) demonstrate
that the active site consists of a binuclear metal center. Bell-shaped pH-rate profiles are
observed for both Zn2+ and Cd2+ enzymes. A chemical mechanism for renal dipeptidase
is proposed based on structural analysis of the enzyme-inhibitor complex. The reaction
is initiated by the polarization of the amide bond by the B-metal. Asp-320 activates the
bridging hydroxide for nucleophilic attack at the peptide carbon center, forming a
tetrahedral intermediate that is stabilized by the metal center and His-150. The
protonated Asp-320 donates the proton to the a-amino group of the leaving group,
causing the collapse of the tetrahedral intermediate and cleavage of the carbon-nitrogen
bond.
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Investigation of the mechanism of phosphotriesterase: characterization of the binuclear metal active site by electron paramagnetic resonance spectroscopySamples, Cynthia Renee 15 May 2009 (has links)
Phosphotriesterase (PTE) from Pseudomonas diminuta is a zinc metalloenzyme
found in soil bacteria capable of organophosphate hydrolysis at rates approaching the
diffusion controlled limit. Interest in PTE for degradation of chemical warfare agents and
disposal of pesticides supports the need to understand the mechanism by which it
performs hydrolysis. For further mechanistic clarity, this work will provide direct
confirmation of the solvent bridge identity and the protonated species resulting in loss of
catalytic identity. Inhibitor and product binding to the metal center will also be
addressed; as well as the evaluation of the catalytic activity of Fe(II)-substituted PTE.
This work has determined that the Mn/Mn-PTE electron paramagnetic resonance
(EPR) spectrum exhibits exchange coupling that is facilitated through a hydroxide bridge.
Protonation of the bridging hydroxide results in the loss of the exchange coupling
between the two divalent cations and the loss of catalytic activity. The reversible
protonation of the bridging hydroxide has an apparent pKa of 7.3 based upon changes in
the EPR spectrum of Mn/Mn-PTE with alterations in pH. The pH-rate profile for the
hydrolysis of paraoxon by Mn/Mn-PTE shows the requirement of a single function group
that must be unprotonated with a pKa of 7.1. The comparable pKa values are proposed to
result from the protonation of the same ionizable species.
The effects of inhibitor and product binding on the magnetic properties of the
metal center and the hydroxyl bridge are investigated by accessing new EPR spectral features. This work concludes that the binding of inhibitor occurs at the metal center and
results in an increase of non-bridged hydroxyl species. These results, in conjunction with
kinetic and crystallographic data, suggest that substrate binding via the phosphoryl
oxygen at the ?-metal weakens the hydroxyl bridge coordination to the ?-metal. This
loss of coordination would increase the nucleophilic character of the bridge, and binding
of the substrate to the metal center would result in a stronger nucleophile for hydrolysis.
Lastly, Fe(II) binding and activation of apoenzyme is evaluated under anaerobic
conditions. This work concludes Fe/Fe-PTE is not catalytically active, but can bind up to
2 equivalent Fe(II) ions per active site.
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Structural and Mechanistic Studies on α-Amino β-Carboxymuconate ε-Semialdehyde Decarboxylase and α-Aminomuconate ε-Semialdehyde DehydrogenaseHuo, Lu 12 August 2014 (has links)
α-Amino-β-carboxymuconate-ε-semialdehyde decarboxylase (ACMSD) and α-aminomuconate-ε-semialdehyde dehydrogenase (AMSDH) are two neighboring enzymes in the L-tryptophan and 2-nitrobenzoic acid degradation pathways. The substrates of the two enzymes, α-amino-β-carboxymuconate-ε-semialdehyde (ACMS) and α-aminomuconate-ε-semialdehyde (2-AMS), are unstable and spontaneously decay to quinolinic acid and picolinic acid, respectively.
ACMSD utilizes a divalent zinc metal as cofactor and is a member of the amidohydrolase superfamily. In this dissertation work, we have identified an important histidine residue in the active site that plays dual roles in tuning metal selectivity and activating a metal bound water ligand using mutagenesis, resonance Raman, EPR, crystallography, and ICP metal analysis techniques. The crystal structures of ACMSD from Pseudomonas fluorescens (PfACMSD) have been solved as homodimers in our laboratory while human ACMSD (hACMSD) was annotated as a monomer by another group. To resolve this structural difference, we used two conserved active site arginine residues as probes to study the oligomeriztion state of ACMSD and demonstrated that these two arginine residues are involved in substrate binding and that both Pf- and h- ACMSD are catalytically active only in the dimeric state. Subsequently, we solved the crystal structure of hACMSD and found it to be a homodimer in both catalytically active and inhibitor-bound forms.
AMSDH is an NAD+ dependent enzyme and belongs to the aldehyde dehydrogenase superfamily. Due to the high instability of its substrate, AMSDH has not been studied at the molecular level prior to our work. We have cloned and expressed PfAMSDH in E. coli. The purified protein has high activity towards both 2-AMS and 2-hydroxymuconate semialdehyde (2-HMS), a stable substrate analog. We have successfully crystallized AMSDH with/without NAD+ and solved the crystal structure at up to 1.95 Å resolution. Substrate bound ternary complex structures were obtained by soaking the NAD+ containing crystals with 2-AMS or 2-HMS. Notably, two covalently bound catalytic intermediates were captured and characterized using a combination of crystallography, stopped-flow, single crystal spectroscopy, and mass spectrometry. The first catalytic working model of AMSDH has been proposed based on our success in structural and spectroscopic characterization of the enzyme in five catalytically relevant states in this dissertation work.
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Mechanistic Studies and Function Discovery of Mononuclear Amidohydrolase EnzymesHall, Richard Stuart 2009 December 1900 (has links)
The amidohydrolase superfamily is a functionally diverse group of evolutionarily
related proteins which utilize metal cofactors in the activation of a hydrolytic water
molecule and in the stabilization of the resulting tetrahedral intermediate. Members of
this superfamily have been described which use one or two divalent transition metals.
These metal cofactors are located in either or both of two active-site metal binding
centers which are labeled as the Ma and MB sites. The goal of this research was to
elucidate the nature of the reactions catalyzed by Ma and MB mononuclear members of
the amidohydrolase superfamily. This was approached through comprehensive
mechanistic evaluations of two enzymes which utilized the different metal sites. Nacetyl-
D-glucosamine-6-phosphate deacetylase from E. coli (NagA) and cytosine
deaminase from E. coli (CDA) served as models for mononuclear amidohydrolase
superfamily enzymes which have evolved to utilize a single B-metal and a single a-metal
for hydrolysis, respectively. This research elucidated the different properties imparted by
the distinct a and B active sites and the specific interactions utilized by the enzymes for
substrate binding and catalysis. These studies led to the eventual proposal of detailed chemical mechanisms and the identification of rate determining steps. Knowledge of
sequence-function relationships was applied toward the discovery of function for
enzymes related to cytosine deaminase and guanine deaminase. The first group of
enzymes investigated was proposed to catalyze the fourth step in riboflavin and
coenzyme F420 biosynthesis in Achaea. Three putative deaminases; Mm0823 from
Methanosarcina mazei, MmarC7_0625 from Methanococcus maripaludis C7 and
Sso0398 from Sulfolobus solfataricus were cloned and expressed. These proteins proved
to be intractably insoluble. A second set of enzymes, Pa0142 from Pseudomonas
aeruginosa PA01 and SGX-9236e (with crystal structure PDB: 3HPA) were found to
catalyze the novel deamination of 8-oxoguanine, a mutagenic product of DNA oxidation.
9236e was cloned from an unidentified environmental sample of the Sargasso Sea. The
closest homolog (98% identical) is Bcep18194_A5267 from Burkholderia sp. 383.
Additionally, it was discovered that the proteins SGX-9339a (with crystal structure PDB:
2PAJ) and SGX-9236b catalyzed the deamination of isoxanthopterin and pterin-6-
carboxylate in a poorly characterized folate degradation pathway. These enzymes were
also from unknown environmental samples of the Sargasso Sea. The closest homolog of
9339a (88% identical) is Bxe_A2016 from Burkholderia xenovorans LB400. The closest
homolog of 9236b (95% identical) is Bphyt_7136 from Burkholderia phytofirmans
PsJN.
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D-Aminoacylases and Dipeptidases within the Amidohydrolase Superfamily: Relationship Between Enzyme Structure and Substrate SpecificityCummings, Jennifer Ann 2010 December 1900 (has links)
Approximately one third of the genes for the completely sequenced bacterial genomes have an unknown, uncertain, or incorrect functional annotation. Approximately 11,000 putative proteins identified from the fully-sequenced microbial genomes are members of the catalytically diverse Amidohydrolase Superfamily. Members of the Amidohydrolase Superfamily separate into 24 Clusters of Orthologous Groups (cogs). Cog3653 includes proteins annotated as N-acyl-D-amino acid deacetylases (DAAs), and proteins within cog2355 are homologues to the human renal dipeptidase. The substrate profiles of three DAAs (Bb3285, Gox1177 and Sco4986) and six microbial dipeptidase (Sco3058, Gox2272, Cc2746, LmoDP, Rsp0802 and Bh2271) were examined with N-acyl-L-, N-acyl-D-, L-Xaa-L-Xaa, L-Xaa-D-Xaa and D-Xaa-L-Xaa substrate libraries. The rates of hydrolysis of the library components were determined by separating the amino acids by HPLC and quantitating the products. Gox1177 and Sco4986 hydrolyzed several N-acyl-D-amino acids, especially those where the amino acid was a hydrophobic residue. Gox1177 hydrolyzed L-Xaa-D-Xaa and N-acetyl-D-amino acids with similar catalytic efficiencies (~10⁴ M⁻¹s⁻¹). The best substrates identified for Gox1177 and Sco4986 were N-acetyl-D-Trp and N-acetyl-D-Phe, respectively. Conversely, Bb3285 hydrolyzed N-acyl-D-Glu substrates (kcat/Km ⁹́⁸ 5 x 10⁶M⁻¹s⁻¹) and, to a lesser extent, L-Xaa-D-Glu dipeptides. The structure of a DAA from A. faecalis did not help explain the substrate specificity of Bb3285. N-methylphosphonate derivatives of D-amino acids were inhibitors of the DAAs examined. The structure of Bb3285 was solved in complex with the N-methylphosphonate derivative of D-Glu or acetate/formate. The specificity of Bb3285 was due to an arginine located on a loop which varied in conformation from the A. faecalis enzyme. In a similar manner, six microbial renal dipeptidase-like proteins were screened with 55 dipeptide libraries. These enzymes hydrolyzed many dipeptides but favored L-D dipeptides. Respectable substrates were identified for proteins Bh2271 (L-Leu-D-Ala, kcat/Km = 7.4 x 10⁴ M⁻¹s⁻¹), Sco3058 (L-Arg-D-Asp, kcat/Km = 7.6 x 10⁵ M⁻¹s⁻¹), Gox2272 (L-Asn-D-Glu, kcat/Km = 4.7 x 10⁵ M⁻¹s⁻¹), Cc2746 (L-Met-D-Leu, kcat/Km = 4.6 x 10⁵ M⁻¹s⁻¹), LmoDP (L-Leu-D-Ala, kcat/Km = 1.1 x 10⁵ M⁻¹s⁻¹), Rsp0802 (L-Met-D-Leu, kcat/Km = 1.1 x 10⁵ M⁻¹s⁻¹). Phosphinate mimics of dipeptides were inhibitors of the dipeptidases. The structures of Sco3058, LmoDP and Rsp0802 were solved in complex with the pseudodipeptide mimics of L-Ala-D-Asp, L-Leu-D-Ala and L-Ala-D-Ala, respectively. The structures were used to assist in the identification of the structural determinants of substrate specificity.
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