Thesis advisor: Evan R. Kantrowitz / The understanding of how cells regulate and control all aspects of their function is vital for our ability to intervene when these control mechanisms break down. Almost all modes of cellular regulation can be related in some manner to protein conformational changes such as the quaternary conformational changes of allosteric enzymes that alter enzyme activity to regulate metabolism. The control of metabolic pathways by allosteric enzymes is analogous to a molecular valve with "on" and "off" positions. In the "off" position, flow through the pathway is severely hindered, while in the "on" position the flow is normal. For a comprehensive understanding of allosteric regulation we must elucidate in molecular detail how the allosteric signal is transmitted to the active site to alter enzyme activity. In this work we use unnatural amino acid mutagenesis to introduce a fluorescent amino acid into the allosteric binding site of aspartate transcarbamoylase (ATCase), the enzyme responsible for regulation of pyrimidine nucleotide biosynthesis. The fluorescence from the amino acid is exquisitely sensitive to the binding of the allosteric effectors ATP, CTP, UTP, and GTP. In particular we show how the asymmetric nature of the allosteric sites of the enzyme are used to achieve regulatory sensitivity over a broad range of mixed heterotropic effector concentrations as is observed in the cell. Furthermore, employing the method of random sampling - high dimensional model representation (RS-HDMR) we derived a model for how ATCase is regulated when all four nucleotides are present at fluctuating concentrations, consistent with physiological conditions. We've discovered the fundamental requirements to induce the allosteric transition to the R state by showing that although ATCase can accept L-asparagine as an unnatural substrate, the transition to the R allosteric state requires the correct positioning of the alpha-carboxylate of its natural substrate L-aspartate. However, linking the functionalities of L-asparagine and carbamoyl phosphate into a single molecule is sufficient to correctly position the bi-substrate analog in the active site to induce the allosteric transition to the R-state. The cooperative nature of ATCase was further investigated through the isolation of a unique quaternary structure of ATCase consisting of two catalytic trimers linked covalently by disulfide bonds. By relieving the quaternary constraints imposed by the bridging regulatory subunits of the native holoenzyme, the flexibility of the c6 subunit significantly enhanced enzyme activity over the native holoenzyme. Unlike the native c3 catalytic subunit, the c6 species displays homotropic cooperativity for L-aspartate demonstrating that, when two catalytic trimers are linked, a binding event at one or more active sites can be transmitted through the molecule to the other active sites in the absence of regulatory subunits. The catalytic reaction of ATCase follows an ordered sequential mechanism that is complicated by the transition from the T state to the R state upon the binding of the second substrate L-aspartate. Acquiring X-ray crystal structures at each step along the pathway has advanced our understanding of the catalytic mechanism, yet R-state structures are difficult to obtain. Using a mutant version of ATCase locked in the R-allosteric state by disulfide bonds we captured crystallographic images of ATCase in the R state bound to the true substrates (CP and Asp), products (CA and Pi), and in the process of releasing the final product (Pi) prior to reversion of the molecule to the T state. These structures depict the steps in the catalytic cycle immediately before the catalytic reaction occurs, immediately after the reaction, and after the first product has been released from the active site. This work also focuses on developing allosteric inhibitors of the enzyme fructose-1,6-bisphosphatase (FBPase), one of the enzymes responsible for regulation of the gluconeogenesis pathway. Inhibitors of FBPase could serve as potential therapeutic agents against type-2 diabetes. / Thesis (PhD) — Boston College, 2010. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.
Identifer | oai:union.ndltd.org:BOSTON/oai:dlib.bc.edu:bc-ir_101383 |
Date | January 2010 |
Creators | Mendes, Kimberly Rose Marie |
Publisher | Boston College |
Source Sets | Boston College |
Language | English |
Detected Language | English |
Type | Text, thesis |
Format | electronic, application/pdf |
Rights | Copyright is held by the author, with all rights reserved, unless otherwise noted. |
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