Global ETD Search

41	Dependence of substrate-water binding on protein and inorganic cofactors of photosystem II Hendry, Garth S., Garth.Hendry@baldwins.com January 2002 (has links) The photosynthetic water oxidation reaction is catalyzed by an inorganic Mn4OxCaClyHCO3-z cluster at the heart of the oxygen evolving complex (OEC) in photosystem II. In the absence of an atomic resolution crystal structure, the precise molecular organization of the OEC remains unresolved. Accordingly, the role of the protein and inorganic cofactors of PSII (Ca2+, HCO3- and Cl-) in the mechanism of O2-evolution await clarification. In this study, rapid 18O-isotope exchange measurements were applied to monitor the substrate-water binding kinetics as a function of the intermediate S-states of the catalytic site (i.e. S3, S2 and S1) in Triton X-100 solubilized membrane preparations that are enriched in photosystem II activity and are routinely used to evaluate cofactor requirements. Consistent with the previous determinations of the 18O exchange behavior in thylakoids, the initial 18O exchange measurements of native PSII membranes at m/e = 34 (which is sensitive to the 16O18O product) show that the fast and slowly exchanging substrate-waters are bound to the catalytic site in the S3 state, immediately prior to O2 release. Although the slowly exchanging water is bound throughout the entire S-state cycle, the kinetics of the fast exchanging water remains too fast in the S2, S1 [and S0] states to be resolved using the current instrumentation, and left open the possibility that the second substrate-water only binds to the active site after the formation of the S3 state. Presented is the first direct evidence to show that fast exchanging water is already bound to the OEC in the S2 state. Rapid 18O-isotope exchange measurements for Ex-depleted PSII (depleted of the 17- and 23-kDa extrinsic proteins) in the S2 state reveals a resolvable fast kinetic component of 34k2 = 120 ± 14 s-1. The slowing down of the fast phase kinetics is discussed in terms of increased water permeation and the effect on the local dielectric following removal of the extrinsic subunits. In addition, the first direct evidence to show the involvement of calcium in substrate-water binding is also presented. Strontium replacement of the OEC Ca2+-site reveals a factor of ~3-4 increase in the 18O exchange of the slowly exchanging water across the S3, S2 and S1 states while the kinetics of the fast exchanging water remain unchanged. Finally, a re-investigation of the proposed role for bicarbonate as an oxidizable electron donor to photosystem II was unable to discern any 18O enrichment of the photosynthetically evolved O2 in the presence of 18O-bicarbonate. A working model for O2-evolution in terms of these results is presented. photosystem II oxygen evolving complex substrate exchange kinetics 18-O isotope exchange mass spectrometry extrinsic proteins calcium cofactor
42	Genetic Variability in Human Bone Phenotypes : The Vitamin D Receptor Gene and the Estrogen Receptor-α Cofactor RIZ Gene Grundberg, Elin January 2006 (has links) <p>Important candidate genes to human bone phenotypes are those involved in the regulation of hormonal action, such as the vitamin D receptor (VDR) and the estrogen receptor-α (ERα) genes and their cofactors. RIZ1 is a specific ERα cofactor proved to strongly enhance the function of the ERα. </p><p>The main focus of this thesis has been to study genetic variants in the VDR and RIZ genes and their associations to human bone phenotypes using candidate gene and functional approaches. Specifically, polymorphisms in the VDR 3’ untranslated region (UTR) and a deletion/insertion polymorphism of a proline in the RIZ gene were investigated.</p><p>The candidate gene approach was applied to large-scale population-based cohorts of pre-and post-menopausal women from Sweden and of elderly men from Sweden and Hong Kong. VDR 3’ UTR polymorphisms were associated with peak bone mass and body composition in young women. Further analysis of common VDR 3’ UTR haplotypes confirmed the association with BMD and risk of fractures in elderly men from Sweden and Hong Kong. The VDR polymorphisms were investigated for cis-acting effects, affecting allelic expression in the normal chromosomal context of human bone cells. The VDR allelic transcripts in the bone samples were unequally expressed, suggesting presence of regulatory variants in the 3’ UTR. </p><p>The polymorphism in the RIZ gene was strongly associated to BMD in pre- and postmenopausal women and in elderly men. The functional analyses included reporter constructs containing the RIZ polymorphic variants transfected in a cell line and its abilities in coactivating the ERα were examined. The variants were functionally different in coactivating the ERα-receptor complex. </p><p>To summarize, the results of this thesis show novel evidence for functional relevant polymorphisms in candidate genes to human bone phenotypes. These polymorphisms may contribute to the variation seen in BMD and risk of fractures in the population.</p> Medicine Bone mineral density candidate gene approach polymorphism the vitamin D receptor the estrogen receptor α RIZ1 cofactor allelic imbalance Medicin
43	Genetic Variability in Human Bone Phenotypes : The Vitamin D Receptor Gene and the Estrogen Receptor-α Cofactor RIZ Gene Grundberg, Elin January 2006 (has links) Important candidate genes to human bone phenotypes are those involved in the regulation of hormonal action, such as the vitamin D receptor (VDR) and the estrogen receptor-α (ERα) genes and their cofactors. RIZ1 is a specific ERα cofactor proved to strongly enhance the function of the ERα. The main focus of this thesis has been to study genetic variants in the VDR and RIZ genes and their associations to human bone phenotypes using candidate gene and functional approaches. Specifically, polymorphisms in the VDR 3’ untranslated region (UTR) and a deletion/insertion polymorphism of a proline in the RIZ gene were investigated. The candidate gene approach was applied to large-scale population-based cohorts of pre-and post-menopausal women from Sweden and of elderly men from Sweden and Hong Kong. VDR 3’ UTR polymorphisms were associated with peak bone mass and body composition in young women. Further analysis of common VDR 3’ UTR haplotypes confirmed the association with BMD and risk of fractures in elderly men from Sweden and Hong Kong. The VDR polymorphisms were investigated for cis-acting effects, affecting allelic expression in the normal chromosomal context of human bone cells. The VDR allelic transcripts in the bone samples were unequally expressed, suggesting presence of regulatory variants in the 3’ UTR. The polymorphism in the RIZ gene was strongly associated to BMD in pre- and postmenopausal women and in elderly men. The functional analyses included reporter constructs containing the RIZ polymorphic variants transfected in a cell line and its abilities in coactivating the ERα were examined. The variants were functionally different in coactivating the ERα-receptor complex. To summarize, the results of this thesis show novel evidence for functional relevant polymorphisms in candidate genes to human bone phenotypes. These polymorphisms may contribute to the variation seen in BMD and risk of fractures in the population. Medicine Bone mineral density candidate gene approach polymorphism the vitamin D receptor the estrogen receptor α RIZ1 cofactor allelic imbalance Medicin
44	Development of a novel dehydrogenase and a stable cofactor regeneration system Vázquez-Figueroa, Eduardo 20 August 2008 (has links) The first goal of this work focused on the development of an amine dehydrogenase (AmDH) from a leucine dehydrogenase using site-directed mutagenesis. We aimed at reductively aminating a prochiral ketone to a chiral amine by using leucine dehydrogenase (LeuDH) as a starting template. This initial work was divided into two stages. The first focused mutagenesis to a specific residue (K68) that we know is key to developing the target functionality. Subsequently, mutagenesis focused on residues known to be in close proximity to a key region of the substrate (M65 and K68). This approach allowed for reduced library size while at the same time increased chances of generating alternate substrate specificity. An NAD+-dependent high throughput assay was optimized and will be discussed. The best variants showed specific activity in mU/mg range towards deaminating the target substrate. The second goal of this work was the development of a thermostable glucose dehydrogenase (GDH) starting with the wild-type gene from Bacillus subtilis. GDH is able to carry out the regeneration of both NADH and NADPH cofactors using glucose as a substrate. We applied the structure-guided consensus method to identify 24 mutations that were introduced using overlap extension. 11 of the tested variants had increased thermal stability, and when combined a GDH variant with a half-life ~3.5 days at 65℃ was generated--a ~10⁶increase in stability when compared to the wild-type. The final goal of this work was the characterization of GDH in homogeneous organic-aqueous solvent systems and salt solutions. Engineered GDH variants showed increased stability in all salts and organic solvents tested. Thermal stability had a positive correlation with organic solvent and salt stability. This allowed the demonstration that consensus-based methods can be used towards engineering enzyme stability in uncommon media. This is of significant value since protein deactivation in salts and organic solvents is not well understood, making a priori design of protein stability in these environments difficult. Consensus sequence Glucose dehydrogenase Cofactor regeneration Protein engineering Salt and solvent stability Biocatalysis Enzymes Mutagenesis Enzymes Synthesis Organic solvents
45	Surface modifications for enhanced immobilization of biomolecules: applications in biocatalysts and immuno-biosensor Bai, Yunling 08 August 2006 (has links) No description available. Engineering, Chemical Surface Modification Enzyme Immobilization Cofactor Regeneration Formate Dehydrogenase Purification Biotransformation Microfluidic Biosensor ELISA Foodborne Pathogen Detection
46	Caractérisation de nouvelles enzymes impliquées dans la biosynthèse de cofacteurs de microorganismes. Mécanismes des tyrosine lyases à radical SAM / Characterization of novel enzymes involved in biosynthesis of microbial cofactors. Mechanisms of radical SAM tyrosine lyases Decamps, Laure 13 January 2014 (has links) Le cofacteur F420 est un coenzyme d’oxydoréduction essentiel pour la méthanogenèse chez les archées, un processus qui influence fortement les interactions métaboliques au sein du microbiote intestinal ; en outre, il joue un rôle important dans la pathogénicité de la bactérie Mycobacterium tuberculosis. L’étude de sa biosynthèse présente donc un intérêt majeur en Biologie.La formation du chromophore du F420 est catalysée par la F0-synthase, qui contient, de façon unique, deux domaines caractéristiques des enzymes à radical SAM (rSAM). Ces enzymes catalysent le clivage de la S-adénosylméthionine (SAM) pour former un radical 5′ déoxyadénosyle, capable d’initier un grand nombre de réactions radicalaires.Nous avons réussi à identifier les substrats de la F0-synthase et à reconstituer la synthèse du F0 in vitro. Nous avons également démontré que cette enzyme contient deux centre [4Fe-4S] 2+/1+ rSAM fonctionnels et caractérisé les étapes de la synthèse du F0. Ceci nous a permis de proposer un mécanisme réactionnel pour la F0 synthase. Nous avons ensuite entrepris la comparaison de la F0 synthase avec les deux autres enzymes rSAM tyrosine lyases connues à ce jour : ThiH, impliquée dans la biosynthèse de la vitamine B1, et HydG, impliquée dans la biosynthèse du cofacteur métallique de l’hydrogénase à fer-fer. Nous avons ainsi découvert de nouveaux aspects de la réaction de clivage de la tyrosine par ces enzymes, permettant une meilleure compréhension de ce groupe émergent au sein de la superfamille des enzymes rSAM. / Cofactor F420 is a redox coenzyme crucial for methanogenesis in Archaea, a process which plays a major role in metabolic interactions in the gut microbiota ; It also constitutes a key pathogenicity factor for Mycobacterium tuberculosis. Understanding the biosynthesis of this cofactor is thus of major interest.The biosynthesis of the chromophore of F420 is catalyzed by F0 synthase, which comprises, in a unique manner, two radical SAM (rSAM) domains. These enzymes catalyze the cleavage of S adenosylmethionine (SAM) to produce a 5′-deoxyadenosyl radical, which can initiate a broad range of radical reactions.We succeeded to identify the substrates of F0-synthase and to perform the biosynthesis of F0 in vitro. We ascertained that F0-synthase contains two functional [4Fe-4S]2+/1+ rSAM clusters, and characterized the steps of the reaction of F0 synthesis. Based on these date, we proposed a mechanism for the F0-synthase reaction. Furthermore, we compared F0 synthase with the two other radical SAM tyrosine lyases identified to date: ThiH, which is involved in vitamin B1 biosynthesis, and HydG, which is involved in the biosynthesis of the metal cofactor of iron-iron hydrogenases. We obtained novel insights of the reaction of tyrosine cleavage catalyzed by these enzymes, providing a better understanding of this emerging group in the rSAM enzyme superfamily. Biosynthèse de cofacteur F420 F0 Enzyme à radical SAM Tyrosine Vitamine Fer-soufre Cofactor biosynthesis F420 F0 Radical SAM enzyme Tyrosine Vitamin Iron-sulfur
47	Regeneração de nucleotídeos β-nicotinamida adenínicos solúveis ou imobilizados em sistemas com enzimas acopladas / Regeneration of nucleotides β-nicotinamide adenine soluble or immobilized enzyme coupled systems. Andreotti, Diana Zukas 10 February 2010 (has links) As bioconversões executadas com enzimas, que requerem NADP ou NADPH, são limitadas pela eficiência com que esta substância é mantida na forma particular requerida pelo catalisador ao longo de toda a reação, assim como pela sua recuperação no final do processo. Neste trabalho, foram caracterizadas as enzimas Glicose-6-fosfato desidrogenase (G6PDH) e Glutamato desidrogenase (GLUDH), além do estudo do reciclo NADP/NADPH em sistema constituído por essas enzimas. Determinou-se a temperatura (30ºC) e pH ótimo da G6PDH (pH 7,5), assim como a temperatura (40ºC) e o pH ótimo (pH 8,0) da GLUDH, além dos volumes e concentrações dos substratos utilizados na hidrólise enzimática. No caso da reação acoplada descontínua, a duração foi de 90min, às temperaturas de 30ºC e 40ºC, utilizando-se o cofator solúvel ou imobilizado. Em ambas as condições, mais de 85% das concentrações iniciais de G6P e NH4+, respectivamente, substratos da G6PDH e GLUDH, foram convertidas, sendo o reciclo NADP/NADPH mantido durante toda a reação. No caso da reação bienzimática em reator contínuo, não foi possível chegar ao estado estacionário da reação e a conversão dos subsratos G6P e NH4+ variaram de acordo com o período do teste. / The Bioconversion performed with enzymes that require NADPH or NADP are limited by the efficiency with which this substance is maintained in the particular form required by the enzyme throughout the reaction, as well as for his recovery at the end of the process. The main aim of this work was to study the NADP/NADPH recycling through a bienzyme coupled reaction constituted by glucose-6-phosphate dehydrogenase (G6PDH) and glutamate dehydrogenase (GLUDH). The reaction was carried out in the discontinuous or continuous mode. The discontinuous process, which was carried out with soluble or immobilized NADP at 30°C or 40°C, had a total duration of 90min. Independently on the temperature used, around 85% of the initial concentration of glucose 6-phosphate (G6P) and ammonia were consumed, being the recycle of NADP/NADPH maintained throughout the reaction. In the continuous process, the addition of G6P and ammonia into the membrane reactor was made by turns of 2h. During the 15h-process the NADP/NADPH recycling was attained and the mean consumption yield of ammonia and G6P neared 30% and 60%, respectively. Cofactor immobilization Conversão multienzimática Enzimologia Enzymology Glicose-6-fosfato desidrogenase Glucose-6-phosphate dehydrogenase Glutamate dehydrogenase Glutamato desidrogenase Imobilização de cofatores Multienzimatic conversion
48	Regeneração de nucleotídeos β-nicotinamida adenínicos solúveis ou imobilizados em sistemas com enzimas acopladas / Regeneration of nucleotides β-nicotinamide adenine soluble or immobilized enzyme coupled systems. Diana Zukas Andreotti 10 February 2010 (has links) As bioconversões executadas com enzimas, que requerem NADP ou NADPH, são limitadas pela eficiência com que esta substância é mantida na forma particular requerida pelo catalisador ao longo de toda a reação, assim como pela sua recuperação no final do processo. Neste trabalho, foram caracterizadas as enzimas Glicose-6-fosfato desidrogenase (G6PDH) e Glutamato desidrogenase (GLUDH), além do estudo do reciclo NADP/NADPH em sistema constituído por essas enzimas. Determinou-se a temperatura (30ºC) e pH ótimo da G6PDH (pH 7,5), assim como a temperatura (40ºC) e o pH ótimo (pH 8,0) da GLUDH, além dos volumes e concentrações dos substratos utilizados na hidrólise enzimática. No caso da reação acoplada descontínua, a duração foi de 90min, às temperaturas de 30ºC e 40ºC, utilizando-se o cofator solúvel ou imobilizado. Em ambas as condições, mais de 85% das concentrações iniciais de G6P e NH4+, respectivamente, substratos da G6PDH e GLUDH, foram convertidas, sendo o reciclo NADP/NADPH mantido durante toda a reação. No caso da reação bienzimática em reator contínuo, não foi possível chegar ao estado estacionário da reação e a conversão dos subsratos G6P e NH4+ variaram de acordo com o período do teste. / The Bioconversion performed with enzymes that require NADPH or NADP are limited by the efficiency with which this substance is maintained in the particular form required by the enzyme throughout the reaction, as well as for his recovery at the end of the process. The main aim of this work was to study the NADP/NADPH recycling through a bienzyme coupled reaction constituted by glucose-6-phosphate dehydrogenase (G6PDH) and glutamate dehydrogenase (GLUDH). The reaction was carried out in the discontinuous or continuous mode. The discontinuous process, which was carried out with soluble or immobilized NADP at 30°C or 40°C, had a total duration of 90min. Independently on the temperature used, around 85% of the initial concentration of glucose 6-phosphate (G6P) and ammonia were consumed, being the recycle of NADP/NADPH maintained throughout the reaction. In the continuous process, the addition of G6P and ammonia into the membrane reactor was made by turns of 2h. During the 15h-process the NADP/NADPH recycling was attained and the mean consumption yield of ammonia and G6P neared 30% and 60%, respectively. Conversão multienzimática Enzimologia Glicose-6-fosfato desidrogenase Glutamato desidrogenase Imobilização de cofatores Cofactor immobilization Enzymology Glucose-6-phosphate dehydrogenase Glutamate dehydrogenase Multienzimatic conversion
49	Functional Characterization of Saccharomyces Cerevisiae SUB1 in Starvation Induced Sporulation Response Gupta, Ritu January 2014 (has links) (PDF) Among the various external signals perceived by yeast cells, nutrient availability is a condition to which these cells show a highly diverse biological response. Diploid cells in response to different nutritional stress conditions shows different developmental outcomes. On nitrogen starvation, cells undergo dimorphic transition whereby a unicellular yeast form transforms to a multicellular pseudohyphal form. While in the complete absence of a nitrogen source and a fermentable carbon source, yeast cells enter into a complex developmental program termed sporulation which culminates in haploid spores. The main objective of this work was to understand the role played by S. cerevisiaeSUB1 in starvation-induced meiotic program of diploid cells, decipher its target in sporulation specific gene expression cascade, study the domain architecture of Sub1 and examine its functional homology to mammalian PC4. Role of Sub1 in induction of sporulation and other stress responses in S. cerevisiae In a previous whole-genome screen for mutants with altered sporulation efficiency in the Saccharomyces cerevisiae S288c strain, SUB1 locus was identified as a negative regulator of sporulation (Deutschbaueret al., 2002). Moreover, genome-wide gene expression analysis in SK1 strain had shown that SUB1 transcript levels are repressed during sporulation (Chu et al., 1998). Many studies in different yeast strain backgrounds implicate more than 1,000 genesout of 6,200 genes in yeast genome as being differentially expressed during the sporulation process (Chu et al., 1998; Primiget al., 2000; Deutschbaueret al., 2002). Interestingly, these studies show the number of regulatory genes that negatively affect sporulation is far lower than those that are activators of sporulation and moreover their mechanism of action is poorly studied. S. cerevisiae.SUB1 is one among negative regulators of sporulation(Deutschbaueret al., 2002). Global transcriptome of diploid yeast cells undergoing sporulation showed SUB1 transcripts are greatly reduced with time progression (Chu et al., 1998). To understand the role of SUB1 in sporulation, we generated deletion of both SUB1 alleles in the diploid S288c strain background and compared the kinetics of asci formation in this strain with that of the wild-type. We observed that cells lacking SUB1 exhibit ~5-fold increase in tetrad asci. Based on Eosin Y and Calcoflour White staining assays, we find no change in spore morphology in the mutant. Thus the increase in sporulation efficiency in sub1/sub1diploids is not accompanied by formation of defective spores. We validated the reduction in SUB1 transcript levels during sporulation in wild-type SK1 strain background. We also examined the Sub1 protein levels by epitope-tagging of the chromosomal SUB1 open reading frame and determining protein levels in this strain. We find that consistent with the data on transcript levels, Sub1-TAP tagged protein levels too decreased gradually on shift to sporulation medium. We created sub1alleles in diploids in the SK1 strain background and using this strain background we investigated Sub1 target genes and chose IME2 (early), SMK1, SPS2 (middle), DIT1, DIT2 (mid-late) and SPS100 (late) genes as representative sporulation genes. We observed that sub1∆/sub1∆cells have a significantly elevated expression of middle genes (SPS2 and SMK1) that followed normal induction kinetics i.e., 5 hours post transfer to sporulation medium. However, the expression levels or timing for other class of sporulation genes did not change in sub1∆strain as compared with the wild-type. In order to confirm these observations, we also studied the effects of over-expression of SUB1 from the GAL1 promoter by transforming the high copy plasmid. This was done in wild-type SK1 cells and the expression of sporulation genes were analyzed. We observed that expression of SMK1 and SPS2middle sporulation genes was reduced on over-expression of SUB1.We used the Sub1-TAP protein to assess if Sub1 directly regulates these genes by Chromatin immunoprecipitation assays. For these studies, we examined the recruitment of Sub1 to these loci through the time course of sporulation. In wild-type SK1 cells, Sub1 was to bound to middle sporulation genes and this was striking in cells at 5th hour post-induction of sporulation. These data establish that Sub1 directly associates with chromatin at these loci co-incident with the time points where expression levels of these changes is altered in cells lacking Sub1. Furthermore, to assess the role of Sub1 in other stress responses, such as pseudohyphae formation in response to nitrogen starvation, pheromone-induced agar invasion and secretory stress, we employed a genetic approach. Genetic interaction studies of SUB1 with RPB4, a subunit of RNA polymerase with functions in stress response and HOS2, a subunit of Set3 complex and a close homolog of mammalian HDAC3, reported to be involved in sporulation and secretory stress, were performed. Based on sporulation frequency and pseudohyphal formation in the double mutants we conclude that SUB1 is downstream of both these genes. Moreover, our results from assays of schmoo formation and pheromone-induced agar invasion suggest that SUB1 functionally interacts with HOS2. Study of domain architecture of Sub1 and homology to human PC4 Comparison of the S. cerevisiae Sub1 protein with its higher eukaryotic homologs showed that the N-terminal region of yeast Sub1 (32-105 aa) is highly conserved (Knauset al., 1996; Henry et al., 1996) with the 106-292 C -terminal amino acids being yeast-specific. We employed deletion analysis to generate partial Sub1 proteins and used them to understand the roles played by these domains in different phenotypes associated with Sub1. Our analysis of the localization of various Sub1-GFP fusion proteins shows that 146-172 aa in the C-terminal domain of Sub1 confers nuclear localization. Sporulation frequency analysis of the different domains of Sub1 suggests that both the N and C terminal domains are necessary for sporulation function of Sub1. The N terminal domain of yeast Sub1 shares homology with human PC4 and not surprisingly possesses ssDNA binding ability first attributed to human PC4 (Kaiser et al., 1995). In order to investigate whether the effects of SUB1 on kinetics of sporulation require its ssDNA binding function, we generated the sub1(Y66A) ssDNA binding mutant (Sikorskiet al., 2011) and over-expressed it in the S288c genetic background. We assessed sporulation efficiency of sub1∆/sub1∆cells over-expressing sub1(Y66A) mutant allele as compared to cells over-expressing wild-type SUB1. Interestingly, cells with over-expression of sub1(Y66A) have reduced sporulation efficiency that is equivalent to the levels achieved on over-expression of wild type SUB1. This data suggests that the ssDNA-binding ability of Sub1 is not important for its role in sporulation. Furthermore, we examined the ability of human PC4 to contribute to yeast sporulation process by complementation analysis. We observed that over-expression of PC4 complemented the phenotypes of sub1∆strain, suggesting that the function of Sub1/PC4 family is evolutionarily conserved. Studies on biochemical interactions of Sub1 with histone proteins Human PC4 is a chromatin-associated protein, present on metaphase chromosomes (Das et al., 2006). The short C-terminal domain of PC4(62-87 aa) interacts with core histones H3 and H2B in vitro and in vivo and this interaction mediates chromatin condensation. The homology between S. cerevisiaeSub1 (32-105 aa) and human PC4 (62-127 aa)is in the domain required for their DNA binding properties and coactivator functions, suggesting possible conservation in their interactions. We tested the interactions of yeast Sub1 with histone proteins by adopting both in vitro and in vivo interaction assays. We find recombinant Sub1 had strong interactions with rat and yeast histone H3in vitro. Moreover,Sub1 was found to interact with histone H2B, but not with H2A, in vivo, a binding specificity also shown by human PC4.Thus, we demonstrate conservation in the interaction of Sub1 with histone proteins. Saccharomyces Cerevisiae Saccharomyces Cerevisiae Sporulation Saccharomyces Cerevisiae SUB1 Protein Human PC4 (Popsitive Cofactor) SUB1 Histone Protein Interactions Diploid Yeast Cells Budding Yeast Yeast Sporulation SUB1 in S. cerevisiae Microbiology
50	Structural Studies On Bovine Pancreatic Phospholipase A2 And Proteins Involved In Molybdenum Cofactor Biosynthesis Kanaujia, Shankar Prasad 10 1900 (has links) (PDF) We have carried out structural studies on bovine pancreatic phospholipase A2 (BPLA2) and two proteins involved in molybdenum cofactor (Moco) biosynthesis pathway. In addition, molecular-dynamics simulations and other analyses have been performed to corroborate the findings obtained from the crystal structures. Crystal structures of the three active-site mutants (H48N, D49N and D49K) of BPLA2 were determined to understand the mechanism by which the mutant H48N is able to catalyze the reaction of phospholipid hydrolysis and to see the effect of the loss of Ca 2+ ion in the active site of D49N and D49K mutants. We found that Asp49 could possibly play the role of a general base instead of His48 in the case of the H48N mutant. In the case of D49N and D49K mutants, the active site of the enzyme is perturbed, whereas the overall tertiary structure of these mutants is intact. In addition, a total of 24 invariant water molecules were identified in all of the crystal structures of BPLA2 available in its archive, PDB. Out of these, four water molecules are essential for the catalytic activity, whereas, the remaining water molecules play a role in the stability of the enzyme. In addition, structural studies on two proteins MoaC and MogA involved in Moco biosynthesis pathway have been carried out. For the first time, crystal structure of MoaC bound with GTP molecule has been reported. The gene id TTHA0341, which is mentioned as MoaB in the CMR database, was annotated as MogA based the comparative analysis of sequences and structures (with the present work and the structures available in the literature). The role of N-and C-termini of MoaB and MogA proteins were proposed that these residues might stabilize the substrate and/or product molecule in the active site. In addition, the residues involved in the oligomerization are compared with MD simulations. The molecular docking studies show that MoaB proteins show more preference to GTP than ATP. The comparison of the two active (MPT and AMP-binding) sites revealed that MPT-binding site is preferred over AMP-binding site for nucleotide binding. Proteins Phosphoproteins Pancreatic Phospholipase Molybdenum Biosynthesis Protein Crystallography Molecular Dynamics Simulations Molybdenum Cofactor Biosynthesis Thermus thermophilus HB8 MoaC MogA Molybdopterin Synthase Biochemistry

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