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Probing the Mechanism of the Allosteric Transition of Aspartate Transcarbamoylase via Fluorescence, Physical Entrapment, and Small-Angle X-Ray ScatteringWest, Jay M. January 2009 (has links)
Thesis advisor: Evan R. Kantrowitz / The regulatory mechanism of allostery is exhibited by certain proteins such as Escherichia coli aspartate transcarbamoylase (ATCase), and is defined as the change in shape and activity (of enzymes) resulting from the binding of particular molecules at locations distant from the active site. This particular enzyme and the property of allostery in general have been investigated for several decades, yet the molecular mechanisms underlying allosteric regulation remain unclear. Therefore in this thesis we have attempted via several biophysical methods, along with the tools of molecular biology and biochemistry, to correlate the changes in allosteric structure with presence of the allosteric effectors and enzymatic activity. We created a double mutant version of ATCase, in which the only native cysteine residue in the catalytic chain was mutated to alanine and another alanine on a loop was mutated to cysteine, in order to lock the enzyme into the R allosteric state by disulfide bonds. This disulfide locked R state exhibited no regulation by the allosteric effectors ATP and CTP and lost all cooperativity for aspartate, and then regained those regulatory properties after the disulfide links were severed by addition of a reducing agent. This double mutant was then chemically modified by covalent attachment of a fluorescent probe. The T and R allosteric states of this fluorophore-labeled enzyme had dramatically different fluorescence emission spectra, providing a highly sensitive tool for testing the effects of the allosteric effectors on the allosteric state. The changes in the fluorescence spectra, and hence quaternary structure, matched the changes in activity after addition of ATP or CTP. This fluorophore labeled enzyme was also encapsulated within a solgel, changing the time scale of the allosteric transition from milliseconds to several hours. The fluorophore labels allowed monitoring the allosteric state within the sol-gel, and the physically trapped T and R states both showed no regulation by the allosteric effectors ATP and CTP, and no cooperativity for aspartate. The trapped T state had low-affinity for aspartate and low activity, and the trapped R state had high-affinity for aspartate and high activity. Timeresolved small-angle x-ray scattering (TR-SAXS) was used to determine the kinetics of the allosteric transition, and to monitor the structure of the enzyme in real time after the addition of substrates and allosteric effectors. These TR-SAXS studies demonstrated a correlation between the presence of the allosteric effectors, the quaternary allosteric state, and activity, suggesting like the previous studies in this thesis that the behavior of ATCase is well explained by the twostate model. However, the effector ATP appeared to destabilize the T state and CTP to destabilize the R state, suggesting a different allosteric molecular mechanism than that of the two-state model. This thesis demonstrates the validity of many of the concepts of the two-state model, while suggesting minor modifications to that elegantly simple model in order to conform with the complex structure and function of ATCase. / Thesis (PhD) — Boston College, 2009. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.
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Characterization of the Aspartate Transcarbamoylase that is Found in the pyrBC Complex of Bordetella PertussisDill, Michael T 12 1900 (has links)
An aspartate transcarbamoylase (ATCase) gene from Bordetella pertussis was amplified by PCR and ligated into pT-ADV for expression in Escherichia coli. This particular ATCase (pyrB) was an inactive gene found adjacent to an inactive dihydroorotase (DHOase) gene (pyrC'). This experiment was undertaken to determine whether this pyrB gene was capable of expression alone or if it was capable of expression only when cotransformed with a functional pyrC'. When transformed into E. coli TB2 pyrB-, the gene did not produce any ATCase activity. The gene was then co-transformed into E. coli TB2 pyrB- along with a plasmid containing the pyrC' gene from Pseudomonas aeruginosa and assayed for ATCase activity. Negative results were again recorded.
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Comparative Biochemistry and Evolution of Aspartate Transcarbamoylase from Diverse BacteriaHooshdaran, Massoumeh Ziba 05 1900 (has links)
Aspartate transcarbamoylase (ATCase) catalyzes the first committed step in pyrimidine biosynthesis. Bacterial ATCases are divided into three classes, A, B and C. Class A ATCases are largest at 450-500, are. dodecamers and represented by Pseudomonas ATCase. The overlapping pyrBC' genes encode the Pseudomonases ATCase, which is active only as a 480 kDa dodecamer and requires an inactive pyrC'-encoded DHOase for ATCase activity. ATCase has been studied in two non-pathogenic members of Mycobacterium, M. smegmatis and M. phlei. Their ATCases are dodecamers of molecular weight 480 kDa, composed of six PyrB and six PyrC polypeptides. Unlike the Pseudomonas ATCase, the PyrC polypeptide in these mycobacteria encodes an active DHOase. Moreover, the ATCase: DHOase complex in M. smegmatis is active both as the native 480 kDa and as a 390 kDa complex. The latter lacks two PyrC polypeptides yet retains ATCase activity. The ATCase from M. phlei is similar, except that it is active as the native 480 kDa form but also as 450,410 and 380 kDa forms. These complexes lack one, two, and three PyrC polypeptides, respectively. By contrast,.ATCases from pathogenic mycobacteria are active only at 480 kDa. Mycobacterial ATCases contain active DHOases and accordingly. are placed in class A1 . The class A1 ATCases contain active DHOases while class A2 ATCases contain inactive DHOases. ATCase has also been purified from Burkholderia cepacia and from an E. coli strain in which the cloned pyrB of B. cepacia was expressed. The B. cepacia ATCase has a molecular mass of 550 kDa, with two different polypeptides, PyrB (52 kDa) and PyrC of (39 kDa). The enzyme is active both as the native enzyme at 550 kDa and as smaller molecular forms including 240 kDa and 165 kDa. The ATCase synthesized by the cloned pyrB gene has a molecular weight of 165 kDa composed of three identical PyrB and no PyrC polypeptides. Nucleotide effectors ATP, CTP, and UTP inhibited all forms of enzymes. Because of its size and its activity as a trimer and smaller than native forms, the B. cepacia enzyme is placed in a new class.
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Characterization of Aspartate Transcarbamoylase in the Archaebacterium Methanococcus JannaschiiStewart, John E. B. (John Edward Bakos) 12 1900 (has links)
Asparate transcarbamoylase catalyzes the first committed step in the de novo synthesis of pyrmidine nucleotides UMP, UDP, UTP, and CTP. The archetype enzyme found in Escherichia coli (310 kDa) exhibits sigmodial substrate binding kinetics with positive control by ATP and negative control with CTP and UTP. The ATCase characterized in this study is from the extreme thermophilic Archaebacterium, Methanococcus jannaschii. The enzyme was very stable at elevated temperatures and possessed activity from 20 degrees Celsius to 90 degrees Celsius. M. Jannaschii ATCase retained 75% of its activity after incubation at 100 degrees Celsius for a period of 90 minutes. No sigmodial allosteric response to substrate for the enzyme was observed. Velocity substrate plots gave Michaelis-Menten (hyperbolic) kinetics. The Km for aspartate was 7 mM at 30 degrees Celsius and the KM for carbamoylphosphate was .125 mM. The enzyme from M. jannaschii had a broad pH response with an optimum above pH 9. Kinetic measurements were significantly affected by changes in pH and temperature. The enzyme catalyzed reaction had an energy of activation of 10,300 calories per mole. ATCase from M. jannaschii was partially purified. The enzyme was shown to have a molecular weight of 110,000 Da., with a subunit molecular weight of 37,000 Da. The enzyme was thus a trimer composed of three identical subunits. The enzyme did not possess any regulatory response and no evidence for a regulatory polypeptide was found, DNA from M. jannaschii did hybridize to probes corresponding to genes for both the catalytic and regulatory subunits from E. coli. Analysis of DNA sequences for the M. jannaschii ATCase genes showed that the gene for the catalytic subunits shares significant homology with the pyrB genes from E. coli, and maximum homology amongst known ATCase genes to pyrB from Bacillus. An unlinked gene homologous to E. coli pyrl encoding the regulatory subunit was identified, though its expression and true function remain uncharacterized.
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Aspartate Transcarbamoylase of Aeromonas HydrophilaHigginbotham, Leah 12 1900 (has links)
This study focused on the enzyme, aspartate transcarbamoylase (ATCase) from A. hydrophila, a Gram-negative bacterium found in fresh water. The molecular mass of the ATCase holoenzyme from A. hydrophila is 310 kDa. The enzyme is likely composed of 6 catalytic polypeptides of 34 kDa each and 6 regulatory polypeptides of 17 kDa each. The velocity-substrate curve for A. hydrophila ATCase is sigmoidal for both aspartate and carbamoylphosphate. The Km for aspartate was the highest to date for an enteric bacterium at 97.18 mM. The Km for carbamoylphosphate was 1.18 mM. When heated to 60 ºC, the specific activity of the enzyme dropped by more than 50 %. When heated to 100 ºC, the enzyme showed no activity. The enzyme's activity was inhibited by ATP, CTP or UTP.
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Regulatory Divergence of Aspartate Transcarbamoylase from the PseudomonadsLinscott, Andrea J. (Andrea Jane) 12 1900 (has links)
Aspartate transcarbamoylase (ATCase) was purified from 16 selected bacterial species including existing Pseudomonas species and former species reassigned to new genera. An enormous diversity was seen among the 16 enzymes with each class of ATCase being represented. The smallest class, class C, with a catalytically active homotrimer, at 100 kDa, was found in Bacillus and other Gram positive bacteria. In this report, the ATCases from the Gram negatives, Shewanella putrefaciens and Stenotrophomonas maltophilia were added to class C membership. The enteric bacteria typify class B ATCases at 310 kDa, with a dodecameric structure composed of two catalytic trimers coupled to three regulatory dimers. A key feature of class B ATCases is the dissociability of the holoenzyme into regulatory and catalytic subunits which were enzymatically active. In this report, the ATCase from Pseudomonas indigofera was added to class B ATCases. The largest class, at 480 kDa, class A, contains the fluorescent Pseudomonas including most members of the 16S rRNA homology group I. Two polypeptides are produced from overlapping pyrBC' genes. The former, pyrB, encodes a 34 kDa catalytic polypeptide while pyrC' encodes a 45 kDa dihydroorotase-like polypeptide. Two non active trimers are made from six 34 kDa chains which are cemented by six 45 kDa chains to form the active dodecameric structure. Dissociation of the holoenyzme into its separate active subunits has not been possible. In this report, the ATCases from Comamonas acidovorans and C. testosteroni, were added to the class A enzymes. An even larger class of ATCase than class A at 600 kDa was discovered in Burkholderia cepacia. Stoichiometric measurements predict a dodecamer of six 39 kDa polypeptides and six 60 kDa polypeptides. Unlike other large pseudomonads ATCases, the enzyme from B. cepacia was dissociable into smaller active forms. Both the holoenzyme and its dissociated forms were regulated by nucleotide effectors. A new class of ATCase was proposed for B. cepacia type enzymes.
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Characterization of Aspartate Transcarbamoylase and Dihydroorotase in Moraxella CatarrhalisFowler, Michael A. (Michael Allen), 1961- 05 1900 (has links)
Bacterial aspartate transcarbamoylases (ATCase's) are divided into three classes that correspond to taxonomic relationships within the bacteria. The opportunistic pathogen Moraxeila catarrhalis has undergone several reclassifications based on traditional microbiological criteria. The previously uncharacterized ATCase from M. catarrhalis was purified to homogeneity and its chemical properties characterized. The ATCase from M. catarrhalis is a class C ATCase with an apparent molecular mass of 480-520 kDa. The M. catarrhalis ATCase is a dodecomer composed of six 35 kDa polypeptides and six 45 kDa polypeptides. The enzyme has an unusually high pH optimum of greater than pH 10. The enzyme exhibited hyperbolic kinetic with a Km for aspartate of 2 mM. A single, separate 78 kDa dihydroorotase from M. catarrhalis was identified and it was not associated with ATCase. These data support the reclassification of M. catarrhalis out of the Neisseriaceae family.
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Assembly of Pseudomonas putida Aspartate Transcarbamoylase and Possible Roles of the PyrC' Polypeptide in the Folding of the Dodecameric EnzymeHongsthong, Apiradee, 1970- 05 1900 (has links)
Aspartate transcarbamoylase (ATCase) of Pseudomonas putida consists of two different polypeptides, PyrB and PyrC' (Schurr et al, 1995). The role of the PyrC' and the assembly of PyrB and PyrC' have been studied. The ATCase made in vitro of P.putida PyrB with P.putida PyrC', and of E.coli PyrB with P.putida PyrC ' were generated under two different conditions, denaturation and renaturation, and untreated. It was found that PyrC' plays a role in the enzymatic regulation by ATP, CTP and UTP. In addition to playing a role in substrate binding, the PyrB polypeptide is also involved in effector binding (Kumar et al., manuscript in preparation). The most energetically preferred form of the P.putida WT is a dodecamer with a molecular mass of 480 kDa. The ratio between the PyrB and the PyrC' is 1:1. In studies of nucleotide binding, it was discovered that the P.putida PyrB was phosphorylated by a protein kinase in the cell extract. In the presence of 20 mM EDTA, this phosphorylation was inhibited and the inhibition could be overcome by the addition of divalent cations such as Zn2+ and Mg2+. This result suggested that the phosphorylation reaction required divalent cations. In the CAD complex of eukaryotes, phosphorylations of the CPSase and the linker region between ATCase and DHOase did not occur in the presence of UTP and it was hypothesized (Carrey, 1993) that UTP and phosphorylation(s) regulated the conformational change in the enzyme complex. Therefore, the same idea was approached with P.putida ATCase, where it was found that 1.0 mM UTP inhibited the phosphorylation of PyrB by more than 50%. These results suggested that the regulation of the conformational change of the P.putida ATCase might be similar to that of CAD. Furthermore, peptide mapping for phosphorylation sites was performed on P.putida ATCase WT, WT --11 amino acids and WT --34 amino acids from the N-terminus of the PyrB polypeptide. The results showed that the phosphorylation sites were located on the fragment that contained amino acid number-35 to amino acid number-112 from the N-terminus of the PyrB polypeptide.
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Pyrimidine Biosynthesis in the Genus Streptomyces : Characterization of Aspartate Transcarbamoylase and Its Interaction with Other Pyrimidine EnzymesHughes, Lee E. (Lee Everette) 05 1900 (has links)
Aspartate transcarbamoylase (ATCase) of Streptomyces was characterized and its interaction with other pyrimidine enzymes explored.
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Isolation and Characterization of the Operon Containing Aspartate Transcarbamoylase and Dihydroorotase from Pseudomonas aeruginosaVickrey, John F. (John Fredrick), 1959- 05 1900 (has links)
The Pseudomonas aeruginosa ATCase was cloned and sequenced to determine the correct size, subunit composition and architecture of this pivotal enzyme in pyrimidine biosynthesis. During the course of this work, it was determined that the ATCase of Pseudomonas was not 360,000 Da but rather present in a complex of 484,000 Da consisting of two different polypeptides (36,000 Da and 44,000 Da) with an architecture similar to that of E. coli ATCase, 2(C3):3(r2). However, there was no regulatory polypeptide found in the Pseudomonas ATCase.
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