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Isozymes of Human Triosephosphate Isomerase: Isolation and CharacterizationSawyer, Thomas H. 08 1900 (has links)
The isolation and purification of triosephosphate isomerase from humanerythrocytes, cardiac and skeletal muscle, liver, and brain has been described. Subsequent isolation and characterization of three isozymes from three tissues was effected.
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Molecular Aging of Triosephosphate IsomeraseYüksel, K. Umit 05 1900 (has links)
This work was initiated to acquire a better understanding of the mechanisms, regulations, and significances of deamidation, as well as its role in the aging process.
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Probing the Role of Highly Conserved Residues in Triosephosphate Isomerase : Biochemical & Structural InvestigationsBandyopadhyay, Debarati January 2015 (has links) (PDF)
Conserved residues in protein are crucial for maintaining structure and function, either by direct involvement in chemistry or indirectly, by being essential for folding, stability and oligomerisation and are mostly clustered near active sites. The variability of sequences of the same protein from diverse organisms is a reflection of the selective pressures of evolution.
Sequence conservation analysis with 3397 bacterial triosephosphate isomerase (TIM) sequences using Plasmodium falciparum (Pf) TIM as template, showed full conservation of ten residues, K12, T75, H95, E97, C126, E165, P166, G209, G210 and G228. The integrity of the enzyme active site, which lies near the dimer interface, makes TIM an obligatory dimer. Attempts to engineer active monomeric TIM have not been successful. The present study assesses the effects of mutations at fully conserved position 75 (Thr) and the highly conserved position 64 (Q: 3011, E: 383) near the dimer interface, using the recombinant Plasmodial enzyme. Residue 64, Gln in Pf, and T75 interact with the catalytic E97 and K12, respectively. Preliminary analysis of available crystal structures showed that Gln 64 takes part in a single intersubunit interaction and maintains the obligatory strained backbone angles of the catalytic K12 residue, while Thr 75 is involved in four intersusunit hydrogen bond interactions. This led to the hypothesis that mostly, Gln at position 64 is crucial for enzyme activity and Thr at position 75 for the integrity of the dimer.
Biophysical and kinetic data are reported for four T75 (T75S/V/C/N) and two Q64 (Q64N/E) mutants. The major findings revealed that the mutations at position 64 have a significant effect on dimer integrity with a 1000 fold increase in the dimer dissociation constant compared to the wild type enzyme, while dimer stability was unimpaired for the T75 mutants. Concentration dependence of activity yielded an estimate of dimer dissociation constant (Kd) values (Q64N 73.7±9.2 nM and Q64E 44.6±8.4 nM). Enzyme activity values of the T75 mutants are comparable to the wild type, except for T75N which shows a 4-fold drop in activity. All four T75 mutants show a dramatic fall in activity between 35 °-45 °C. Crystal structure determination of the T75S/V/N mutant offers insights into the variation in local interactions with T75N showing the largest changes. These results were unanticipated emphasising the uncertainties involved in inferring functional and structural role for individual residues based only on analysis of interactions observed in crystal structures.
Nanospray ionisation mass spectrometric studies has also been used to probe the oligomeric properties of the three mutant proteins Q64N, Q64E and T75S and the wild type enzyme in the gas phase. The gas phase distributions of dimeric and monomeric species have been examined under a wild range of collision energies (40 – 160 eV). The order in the gas phase, PfTIM wild type > T75S > Q64E ~ Q64N, together with the solution phase experiments described above establish the importance of Q64 and T75 in influencing stability and activity. Inhibition studies with a 27 residue synthetic dimer interface peptide and the Q64 mutants establish that the interaction between the protein and the peptide was facilitated in the case of monomeric species.
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Isolation and Characterization of Triosephosphate Isomerase Isozymes from Human PlacentaDewan, Rahul Nath 08 1900 (has links)
Two isozymes of triosephosphate isomerase have been isolated to homogeneity from human placenta. Triosephosphate isomerase A and triosephosphate isomerase B were compared in terms of their chemical, and biological properties.
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How Do Enzymes Wear Out? Effects of Posttranslational Modifications on Structure and Stability of Proteins; The Triosephosphate Isomerase ModelSun, An-Qiang 12 1900 (has links)
Triosephosphate isomerase (EC 5.3.1.1., TPI) undergoes specific posttranslational modifications (deamidation and oxidation) which are believed to initiate protein turnover by destabilization of the dimer. The crystal structures, amino acid sequences, and aging related changes of TPI from various species have been independently characterized by several laboratories. TPI has thus become the prototype enzyme for examining the initial steps in protein turnover. The binding of substrate enhances the specific deamidation of the mammalian enzyme, and a general mechanism of 'molecular wear and tear' [Gracy, R. W., Yiiksel, K. 0., Chapman, M. L., and Dimitrijevich, S. D. (1990) in Isozymes-Structure, Function and Use in Biology and Medicine (Ogita, Z-I., and Markert, C. L., Eds) pp. 787-817, Wiley-Liss, New York] has been proposed to explain how enzymes may wear out.
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Exploring The Role Of The Highly Conserved Residues In Triosephosphate IsomeraseSamanta, Moumita 05 1900 (has links) (PDF)
This thesis discusses the structure-function studies on triosephosphate isomerase (TIM) from Plasmodium falciparum (Pf), directed towards understanding the roles of highly conserved residues by site derected mutagenesis. Chapter 1 provides an introductory overview to the relevant literature on triosephosphate isomerase. In addition, this Chapter provides an analysis of conserved residues in TIM, and amino acid diversity at specific positions in the structure using a dataset of 503 TIM sequences. Chapter 2 reports the work on the completely conserved residue, C126 in TIM, which is proximal to the active site. Five mutants, C126S, C126A, C126V, C126M and C126T have been characterized. Crystal structures of 3-phosphoglycolate (PGA) bound C126S mutant and the unliganded forms of the C126S and C126A mutants have been determined at a resolution of 1.7 Å to 2.1 Å. Kinetic studies reveal a ~5 fold drop in kcat for the C126S and C126A mutants, while a ~ 10 fold drop is observed for the other three mutants. All the mutants show reduced stability at lower concentration and higher temperature. Chapter 3 presents the kinetic and structural characterization for the E97Q and E97D mutants of Pf TIM. A 4000 fold reduction in kcat is observed for E97Q, 100 fold reduction for the E97D mutant, while a ~ 9000 fold drop in activity for the control mutant, E165A. A large conformational change for the critical K12 side chain is observed in the crystal structure of the E97Q mutant, while it remains unchanged in the E97D structure. The results are interpreted to invoke a direct role for E97 in the catalytic proton transfer cycle, eliminating the need to invoke the formation of the energetically unfavorable imidazolate anion at H95. Chapter 4 reports investigations with position 96 by the biochemical and structural characterization of single mutants, F96Y, F96A and the double mutants, F96S/S73A and F96S/L167V. F96Y showed ~100 fold drop in activity, F96A revealed ~10 fold drop in activity, while F96S/S73A showed 100 fold lower activity than that of the wild type enzyme. Interestingly, the double mutant F96S/L167V proved to be a partial pseudorevertant, showing 10 fold higher activity than the single mutant, F96S. Chapter 5 describes the cloning, and preliminary kinetic and biophysical characterization of the enzyme, Dm TIM. A survey of disease causing mutations in TIM and the relationship of these sites of mutation to the active site and the dimer interface of TIM is presented in this Chapter.
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Analysis of a Human Transfer RNA Gene Cluster and Characterization of the Transcription Unit and Two Processed Pseudogenes of Chimpanzee Triosephosphate IsomeraseCraig, Leonard C. (Leonard Callaway) 08 1900 (has links)
An 18.5-kb human DNA segment was selected from a human XCharon-4A library by hybridization to mammalian valine tRNAiAc and found to encompass a cluster of three tRNA genes. Two valine tRNA genes with anticodons of AAC and CAC, encoding the major and minor cytoplasmic valine tRNA isoacceptors, respectively, and a lysine tRNAcuu gene were identified by Southern blot hybridization and DNA sequence analysis of a 7.1-kb region of the human DNA insert. At least nine Alu family members were found interspersed throughout the human DNA fragment. The tRNA genes are accurately transcribed by RNA polymerase III in a HeLa cell extract, since the RNase Ti fingerprints of the mature-sized tRNA transcription products are consistent with the DNA sequences of the structural genes. Three members of the chimpanzee triosephosphate isomerase (TPI) gene family, the functional transcription unit and two processed pseudogenes, were characterized by genomic blotting and DNA sequence analysis. The bona fide TPI gene spans 3.5 kb with seven exons and six introns, and is the first complete hominoid TPI gene sequenced. The gene exhibits a very high identity with the human and rhesus TPI genes. In particular, the polypeptides of 248 amino acids encoded by the chimpanzee and human TPI genes are identical, although the two coding regions differ in the third codon wobble positions for five amino acids. An Alu member occurs upstream from one of the processed pseudogenes, whereas an isolated endogenous retroviral long terminal repeat (HERV-K) occurs within the structural region of the other processed pseudogene. The ages of the processed pseudogenes were estimated to be 2.6 and 10.4 million years, implying that one was inserted into the genome before the divergence of the chimpanzee and human lineages, and the other inserted into the chimpanzee genome after the divergence.
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Structural Studies Of E. Coli Thioredoxin And P. Falciparum Triosephosphate Isomerase By NMR And Computational MethodsShahul Hameed, M S 03 1900 (has links) (PDF)
To unravel the mysteries of complex biological processes carried out by biomolecules it is necessary to adopt a multifaceted approach, which involves employing a wide variety of tools both computational and experimental. In order to gain a clear understanding of the function of biomolecules their three dimensional structure is required. X-ray crystallography and Nuclear Magnetic Resonance (NMR) spectroscopy are the only two methods capable of providing high-resolution three-dimensional structure of biomolecules. NMR has the advantage of allowing the study of structure of biomolecules in solution and is better equipped to characterize the dynamics of the protein. Protein structure determination by NMR spectroscopy consists of recombinant expression of isotopically labeled proteins, purification, data collection, data processing, resonance assignment, distance restraint and angular restraint generation, structure calculation and structure validation. Apart from 3D structure determination of biomolecules NMR has become the method of choice for studying transient protein-protein interactions, which are notoriously difficult to study at higher resolution by other methods.
Mass spectrometry plays an important role in enabling rapid identification of biomolecules and their modifications. The high sensitivity and resolution mass spectrometry offers makes it the method of choice for studying post-transitional modification of proteins.
Use of computers in biology has played an essential role in elucidating those structure function relationships in biomolecules that are not possible to study by experimental techniques.
The first chapter of this thesis deals with the introduction of methods used in this study. A brief introduction about the theory of Nuclear Magnetic Resonance (NMR) spectroscopy is given. Protein NMR methods used for structure determination of medium sized proteins are discussed. A part of this chapter discusses about the application of mass spectrometry in biochemistry and the use of tandem MS/MS experiments in identification of proteins and peptide fragments. Finally, the last part of this chapter gives an introduction about the theory of molecular dynamics and techniques used in the post processing of MD trajectories to elucidate the dynamics of proteins.
The second chapter of this thesis is concerned with NMR characterization of a novel protein-protein interaction between the glycolytic enzyme Triosephosphate isomerase and the redox protein Thioredoxin. Chemical shift perturbation studies have been done to map the binding interfaces of these proteins. The structure of the complex was then modeled using NMR restraints based docking using the known 3D structure of these proteins. The docked complex reveals crucial insights into the glutathione mediated redox regulation of Triosephosphate isomerase and the role of thioredoxin as a deglutathionylating agent. Enzyme activity assays of Triosephosphate isomerase were done to show the inhibitory effects of s-glutathionylation of Cys217 and the role of thioredoxin as a deglutathionylating agent.
The third chapter of the thesis is aimed to address some important issues related to the inhibition of Plasmodium falciparum Triosephosphate isomerase by S-glutathionylation. Oxidative stress induces protein glutathionylation which is a reversible post translational modification consisting of the formation of a mixed disulfide between protein cysteines and glutathione. Mass spectrometric analysis of the kilnetics of glutathionylation along with enzyme activity assays clearly show that gluthionylation of either Cys-13 (situated in the dimmer interface) or Cys-217 (situated in Helix G) can render the enzyme inactive. Molecular dynamics simulations provide a mechanistic basis of inhibition and predict that glutathionylation at Cys217 allosterically induces loop 6 disorder.
The fourth chapter of this thesis addresses the stabilizing effect of introduction of a cross-strand disulfide bond across a non-hydrogen bonded position of an antiparallel beta sheet. Multidimensional heteronuclear NMR experiments have been used to get the backbone and side-chain resonance assignments, distance and angular restraints. In addition RDC based restraints have been used to calculate the structure of oxidixed form of L79C, T89C thiroedoxin. The observation of predominantly –RH staple conformation among the NMR ensemble in typical of cross-strand disulfides.
The fifth chapter of this thesis deals with the dynamics of thioredoxin using computational methods.In this chapter analysis of known complexes of thiroedoxin was done to determine binding hot spot residues using free energy calculations. The physicochemical basis for the multispecificity of thioredoxin is probed using molecular dynamics simulations. In this chapter it has been shown that conformational selection plays a very important role in thioredoxin target recognition.
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Development of benign synthesis of some terminal α-hydroxy ketones and aldehydesVaismaa, M. (Matti) 11 August 2009 (has links)
Abstract
The synthesis of α-hydroxy aldehydes and hydroxymethyl ketones as well as their interconversion to each other are discussed in this thesis. The literature survey of the monograph reviews the synthetic methods for the preparation of 1,2-bifunctionalized hydroxy aldehydes and ketones. The keto-aldehyde isomerisation reaction catalyzed by Triosephosphate isomerase enzyme (TIM) and organic compounds that interact with the TIM are also introduced. In addition, the microwave heating techniques in organic syntheses are reviewed. The practical work consists of two entities: The synthesis of new substrate candidates and transition state analogues for a mutated monomeric TIM. These compounds are model compounds for the catalytic activity and the structural studies of the mutated monomeric TIM. The synthesis of the sulphonyl α-hydroxy ketone-based substrate candidates consists of four successive syntheses. The microwave-activation was utilized in the preparation of a carbon-sulphur bond and the synthesis of hydroxymethyl ketones. The improved synthesis of the terminal α-hydroxy ketone functionality with microwave activation is presented. The formation of charged compounds was utilized to improve the absorption of microwave energy of reaction mixtures. The design and the synthetic work were carried out in accordance to principles of green chemistry. The second part of the practical work is the development of an organocatalytic α-oxybenzoylation reaction of aldehydes with high enantiomeric selectivity. This novel method generated enantiomerically pure α-hydroxy aldehydes in the stable benzoate-protected form from achiral starting materials under mild conditions at the presence of air and moisture.
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Biochemical characterisation of unusual glycolytic enzymes from the human intestinal parasite Blastocystis hominisAbdulla, Sheera January 2016 (has links)
Blastocystis is an important parasite that infects humans and a wide range of animals like rats, birds, reptiles, etc. infecting a sum of 60% of world population. It belongs to the Stramenopiles, a Heterologous group that includes for example the Phythophthora infestans the responsible for the Irish potato famine. Previous work had reported the presence of an unusual fusion protein that is composed of two of the main glycolytic enzymes; Triosephosphate isomerase-glyceraldehyde-3-phosphate dehydrogenase (TPI-GAPDH). Little is known about this protein. Blastocystis TPI-GAPDH and Blastocystis enolase were both characterized biochemically and biophysically in this project. The phylogenetic relationships of those two proteins among other members of either Stramenopiles, or other members of the kingdom of life were examined and found to be grouping within the chromalveolates. Our studies revealed that those two proteins, Blastocystis enolase and Blastocystis TPI-GAPDH, had a peptide signal targeting them to the mitochondria. This was an unusual finding knowing that text books always referred to the glycolytic pathway as a canonical cytoplasmic pathway. Structural studies had also been conducted to unravel the unknown structure of the fusion protein Blastocystis TPI-GAPDH. X-ray crystallography had been conducted to solve the protein structure and the protein was found to be a tetrameric protein composed of a central tetrameric GAPDH protein flanked with two dimmers of TPI protein. Solving its structure would be the starting point towards reviling the role that TPI-GAPDH might play in Blastocystis and other organisms that it was found in as well. Although a fusion protein, the individual components of the fusion were found to contain all features deemed essential for function for TPI and GAPDH and contain all expected protein motifs for these enzymes.
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