Global ETD Search

71	GENERATION, CLONING, AND SMALL-SCALE EXPRESSION OF SITE-DIRECTED MUTANTS OF HEN EGG WHITE LYSOZYME IN PICHIA PASTORIS Patton, Nichole L. 28 September 2012 (has links) No description available. Biochemistry Molecular Biology site-directed mutants hen egg white lysozyme pichia pastoris
72	Computational, Synthetic, Biochemical and Biological Studies and Characterization on STAT3 Inhibitors for Potential Anticancer Therapy Yu, Wenying 04 September 2013 (has links) No description available. Pharmacy Sciences STAT3 Anti-cancer therapy In silico site-directed FBDD MLSD
73	Identification of Potential TonB-Interactive Sites in the Periplasmic Domain of the ExbD Protein Cholewa, Kelly M. 18 November 2016 (has links) No description available. Biology Microbiology Molecular Biology ExbD TonB System Site-Directed Mutagenesis E coli
74	Site-directed mutagenesis of the ncd microtubule motor protein Schmidt, William Richard 30 December 2008 (has links) Ncd is a member of the kinesin family of motor proteins. Ncd is involved in the processes of meiosis and early mitosis in <i>D. melanogaster</i>. PCR-mediated site-directed mutagenesis was utilized to introduce specific mutations into pET/MC6, a construct containing the motor domain of ncd. Six mutations were generated, two at glutamic acid residue 656, two at proline residue 649, one at arginine residue 623, and one double mutant at arginine residue 623 and threonine residue 632. Mutants proteins were expressed in bacteria and further characterized. Mutagenesis of the proline or glutamic acid residues resulted in insoluble proteins. The one exception is the mutagenesis of glutamic acid residue 656 into a glutamine, which resulted in a partially soluble protein. Mutagenesis of the arginine residue into an alanine (MC6-A623) resulted in a soluble protein while the double mutation of the arginine and threonine was insoluble. MC6-A623 exhibited a similar S-sepharose ion exchange chromatography binding and elution profile as MC6. Peptide antibodies made to conserved ncd motor domain sequences also recognized MC6- A623. The affinity of MC6-A623 (under the conditions tested) for microtubules was less than MC6. Most interestingly, under the conditions tested, MC6-A623 did not exhibit an increased ATPase rate in the presence of microtubules, a hallmark of the kinesin family of microtubule motor proteins. Analysis of the published ncd crystal structure, other motor protein sequences, and the experimental results of the mutagenesis of arginine residue 623, suggest that this residue is involved in the binding of MC6 to microtubules. / Master of Science kinesin motor protein ncd non-claret disjunctional site-directed mutagenesis LD5655.V855 1996.S365
75	Mechanistic Studies of the Roles of the Transcriptional Activator ExsA and Anti-activator Protein ExsD in the Regulation of the Type Three Secretion System in Pseudomonas aeruginosa Shrestha, Manisha 19 June 2018 (has links) Pseudomonas aeruginosa is a ubiquitous opportunistic pathogen that is a substantial threat, particularly in hospital settings, causing severe infections in immunocompromised patients that may lead to death. Pseudomonas aeruginosa harbors a multitude of virulence factors that enable this pathogen to establish both acute and chronic infections in humans. A key determinant of acute infections is a hollow molecular needle structure used for injecting toxins into a host cell, called the type three secretion system (T3SS). The secretion machinery itself is highly complex and, together with the specific secreted factors, requires expression of more than 30 genes. Due to the high energy cost of its synthesis to the organism this system is highly regulated to finely time gene expression to coincide with host contact. ExsA, a member of the AraC-type transcription factor family, is the main transcriptional activator of all the genes necessary for expression of the T3SS. Members of the AraC family are characterized by the presence of two helix-turn-helix (HTH) motifs, which bind to the promoter DNA and activate transcription. ExsA uses its HTH containing C-terminal domain (CTD) to regulate gene expression from 10 different promoters. The N-terminal domain (NTD) of ExsA mediates dimerization and regulation of ExsA-activity. While most AraC-type activators are regulated by a small molecule ligands, ExsA is regulated by another protein, ExsD. As part of a four-protein signaling cascade, ExsD interacts directly with ExsA to prevent transcription of T3SS-associated genes under non-inducing conditions prior to host cell contact. The entire regulatory cascade includes of two additional proteins, ExsC and ExsE. ExsA, ExsC, ExsD, and ExsE follow a partner-switching mechanism to link expression of the secretion system with host cell contact. Our laboratory is working to understand this unique signaling mechanism by determining the molecular basis for the regulation of this important virulence factor. Previous studies in the laboratory have solved the structures of ExsE, ExsC and ExsD, and shed light on how these proteins interact and compete for overlapping binding sites. However, it is still unclear as to how the ExsA and ExsD interact and thus how regulation is mediated at the molecular level. In the presented study, we sought to map the molecular interface between ExsA and ExsD. First, the crystal structure of ExsA-NTD is presented wherein the dimerization interface of the protein was identified. Two of the well-studied AraC-type proteins, AraC and ToxT crystal structures have been solved by others in the presence of their respective ligands. Residues that were involved in ligand binding in AraC and ToxT were aligned with the residues in ExsA and analyzed for interaction with ExsD. However, this canonical binding pocket appeared to be not involved in the interaction between ExsA and ExsD. Structure directed site-specific mutagenesis was carried out to construct many different variants of ExsD and ExsA. Thus constructed variants were purified and analyzed in a functional assay. Using this approach, we were able to identify regions on ExsD and ExsA that are crucial for the interaction and for the regulation of ExsA-dependent transcription. It turns out that backbone interactions between the amino-terminal residues of ExsD and the beta-barrel region of the ExsA-NTD are pivotal. This result explains how ExsA and ExsC compete for ExsD binding, since both target the same regions on ExsD. / PHD / Pseudomonas aeruginosa is an opportunistic pathogen that is notorious for causing severe infections in immunocompromised individuals. Acute Pseudomonas aeruginosa infections are characterized by immediate adverse effects. An initial acute infection may become chronic, leading to long-term morbidity and mortality in affected individuals. During the initial stages of infection P. aeruginosa uses the type three secretion system, a syringe-like structure, to puncture the host cell and inject potent toxins. The activation of the genes required for forming this structure is tightly controlled by an activator protein, ExsA. When P.aeruginosa is not invading a host, ExsA is inhibited by another protein called ExsD, to prevent the needless production of the secretion apparatus. The presented work explores the mechanism of how ExsD achieves this inhibition of ExsA. This information is of potential biomedical interest because a clear understanding of the molecular basis for the interaction could inform the development of a small-molecule mimic of ExsD to be used in therapy. In Chapter 2 we report the structure of the domain of ExsA that is known to bind ExsD. Also, in this chapter and more so in Chapter 3, we performed a detailed analysis of potential interacting regions and ultimately succeeded in identifying key interacting regions in both ExsA and ExsD. transcription activator type three secretion system pseudomonas aeruginosa Crystal structure site-directed mutagenesis
76	Site-Directed Mutagenesis in Francisella Tularensis by Allelic Wang, Xiaoshan 03 January 2008 (has links) Francisella tularensis is a Gram-negative, facultative intracellular coccobacillus and the etiologic agent of tularemia for a wide variety of vertebrate and invertebrate animal species. Several species and subspecies of Francisella are currently recognized. However, the majority of infections are caused by F. tularensis subspecies tularensis (type A) and subspecies holarctica (type B). Given the low infectious dose, multiple transmission routes, severity of illness, and lack of licensed vaccines, F. tularensis has long been considered a potential biological weapon and is now classified as a category A select agent by the National Institutes of Health and the Centers for Disease Control and Prevention. The investigation of the mechanisms of pathogenesis by F. tularensis type A and B strains is hindered by the difficulty and lack of methods to mutate the putative genes that encode for virulence factors. New genetic tools have been developed that have enabled mutagenesis of F. tularensis type A and type B stains. However, site-specific mutations remain difficult to execute or these methods generate random mutations. In this study a novel method was developed to create site-directed mutations in a putative capsule biosynthesis locus to knock out encapsulation of the attenuated F. tularensis live vaccine strain. Two suicide vectors for mutagenesis of F. tularensis were constructed based on the commercial PCR cloning vector pSC-A. These vectors were created by inserting into the cloning site a kanamycin resistance gene boarded upstream by 1.3 kb of N-terminal DNA and downstream by 1.3 kb of C-terminal DNA that flanks the target gene. Cryotransformation was used to introduce the vectors into F. tularensis. Open reading frame (ORF) FTT0793, which may encode for an ABC transporter involved in capsule export, was initially selected for mutagenesis in order to generate a mutant that was nonencapsulated, but could still synthesize capsule and induce a host immune response. Mutagenesis of this gene was successful. However, phenotypic assays could not confirm that the mutant was nonencapsulated compared to the parent. Therefore, adjacent ORFs FTT0798 and FTT0799, which may encode for a galactosyl transferase and mannosyl transferase, respectively, were also deleted to completely knock out capsule synthesis. The resulting mutant appeared to be nonencapsulated as determined by negative staining transmission electron microscopy. In this study, a plasmid and method for generating allelic exchange mutants is reported, which should be useful for generating additional mutants of F. tularensis for use in clarifing the roles of specific genes. This vector is currently being used to make a nonencapsulated mutant of a virulent type A strain to determine the role of capsule in virulence. / Master of Science suicide vector galactosyl transferase mannosyl transferase Capsule lipopolysaccharide site-directed mutagenesis virulence Francisella tularensis ABC transporter
77	Using Site-Directed Mutagenesis to Determine Impact of Amino Acid Substitution on Substrate and Regiospecificity of Grapefruit Flavonol 3-O-Glucosyltransferase Adepoju, Olusegun A., Shiva, Devaiah K., McIntosh, Cecelia A. 03 April 2014 (has links) Flavonoids are secondary metabolites that are important in plant defense, protection and human health. Most naturally-occurring flavonoids are found in glucosylated form. Glucosyltransferases (GTs) are enzymes that catalyze the transfer of glucose from a high energy sugar donor to an acceptor molecule. A flavonol-specific 3-O-GT enzyme has been identified and cloned from leaf tissues of grapefruit. The enzyme shows rigid substrate specificity and regiospecificity. F3-O-GTs from grape (Vitis vinifera) and grapefruit (Citrus paradisi) were modeled against F7-O-GTs from Crocus sativus and Scrutellaria biacalensis, and several non-conservative amino acid differences were identified that may impact regioselectivity. This research is designed to test the hypothesis that specific amino acid residues impart the regiospecificity of the grapefruit enzyme. Site-directed mutagenesis was performed on three potentially key amino acid residues within the grapefruit F3-O-GT that were identified through homology modeling. Analyses of the enzyme activity of the mutant F3-O-GT proteins revealed that the single point mutations of serine 20 to leucine (S20L) and proline 297 to phenylalanine (P297F) rendered the recombinant enzyme inactive with flavonol substrates. Mutation of glycine 392 to glutamate (G392E) was active at 80% relative to the wild type. The mutant enzyme also did not show broadened acceptor specificity as it also favored flavonols as the preferred acceptor substrate. The glucosylation products of the active mutant enzyme will be analyzed to determine if this resulted in a change in regiospecificity. site-directed mutational anaylsis flavonol-3-O-glucosyltransferases citrus paradisi site-directed mutagenesis amino acid substitution substrate regiospecificity grapefruit flavonol GTs Biological Sciences School of Graduate Studies Biochemistry Molecular Biology Plant Biology
78	Structural and functional characterization of the arrestin-rhodopsin complex Lally, Ciara 24 November 2017 (has links) Die Aufgabe des Proteins Arrestin ist die Beendigung der Signalweitergabe über den GPCR Signalweg. In Stäbchenzellen bindet Arrestin an Licht-aktiviertes phosphoriliertes Rhodopsin um die Signalweitergabe zu unterdrücken. Die Bindung von Arrestin an Rhodopsin erfolgt in zwei Schritten. Zunächst wechselwirkt Arrestin mit dem phosphorilierten C-Terminus von Rhodopsin und bildet einen prä-Komplex, dies induziert Konformationsänderungen im Arrestin wodurch die Bildung eines High-affinity Komplex unter Kopplung an den helikalen Kern des aktivierten Rezeptors erfolgen kann. Biochemische Untersuchungen und Kristallstrukturen haben einen Einblick in die Konformation des Komplexes aus Arrestin und Rhodopsin ermöglicht. In dieser Arbeit werden site-directed Fluorezenz Experimente angewandt um die strukturellen Änderungen zu untersuchen, die bei der Bindung von Arrestin an Rhodopsin ablaufen und der nterschiedlichen Bindungsmodi innerhalb der Wechselwirkung zwischen Arrestin und Rhodopsin. Insbesondere wird hier eine, bisher nicht beschriebene, Assoziation von Arrestin an die Membran untersucht. Des Weiteren wurden Erkenntnisse über die Struktur des prä-Komplexes gewonnen. Die Konformation vom Arrestin im prä-Komplex scheint die Konformation im Basalzustand nachzubilden unter Beteiligung zweier Kontaktstellen: Interaktion mit dem phosphorilierten C-Terminus des Rezeptors und Assoziation mit der Membran. Beim Übergang in den High-affinity Komplex durchläuft Arrestin eine Konformationsänderung in eine aktivere Konformation: der C-Terminus wird verdrängt, es erfolgt eine Neuausrichtung der zentralen flexiblen Schleifen und die Orientierung des Membranankers ändert sich. Die Aufgabe des prä-Komplexes ist somit Arrestin und den Rezeptor zusammen zu bringen sowie die korrekte Orientierung sicherzustellen um einen schnellen Übergang in den High-affinity Komplex zu ermöglichen. / The protein arrestin is responsible for termination of GPCR signalling. In the rod cell, arrestin binds light-activated phosphorylated rhodopsin in order to block further signal transduction. The binding of arrestin to rhodopsin is a two-step process. Arrestin first interacts with the phosphorylated receptor C-terminus in a pre-complex, which induces conformational changes in arrestin that allow coupling to the helical core of the active receptor in a high-affinity complex. Biochemical studies and crystal structures have provided insights into the conformation of the arrestin-rhodopsin complex. This dissertation describes site-directed fluorescence experiments, which were carried out to further investigate the conformational changes occurring upon arrestin binding to rhodopsin and the nature of different binding modes of the arrestin-rhodopsin interaction. In particular this involved characterization of a previously unidentified association of arrestin with the membrane, as well as further elucidation of the structure of the pre-complex. The conformation of arrestin in the pre-complex is indicated to resemble that of the basal state of arrestin, and involves two sites of contact: interaction with the phosphorylated receptor C-terminus, and association with the membrane. Upon transition to the high-affinity complex, arrestin undergoes a conformational change to a more active conformation: the auto-inhibitory C-tail is displaced, there is movement within the central flexible loops, and the orientation of the membrane anchor changes. The pre-complex therefore most likely functions to bring arrestin and the receptor into close contact, and in the correct orientation, to allow for fast transition to the high-affinity complex. Arrestin Arrestin-Membran Interaktionen Rhodopsin GPCR Interaktionen site-directed Fluorezenz Arrestin Arrestin-membrane interaction Rhodopsin GPCR interactions site-directed fluorescence spectroscopy 570 Biologie 572 Biochemie WW 1780 ddc:570 ddc:572
79	Efeito da suramina na atividade da fosfolipase A2 secretada humana do grupo IIA / Effect of the suramin in the activity of the human secreted phospholipase A2 of the group IIA Aragão, Elisângela Aparecida 19 December 2008 (has links) As fosfolipases A2 (PLA2s, ou fosfatidil-acil hidrolases EC 3.1.1.4) catalisam especificamente a hidrólise das ligações ácido-éster na posição sn-2 de glicerofosfolipídios liberando, como produto da catálise, ácidos graxos e lisofosfolipídio. São encontradas em plantas, mamíferos e em veneno de animais vertebrados e invertebrados e estão envolvidas em uma ampla variedade de processos fisiológicos. A fosfolipase A2 secretada humana do grupo IIA (hsPLA2 gIIA) é uma proteína de fase aguda da resposta imunológica, pois sua expressão é induzida por endotoxinas e citocinas via processos autócrinos e/ou parácrinos durante processos inflamatórios de relevância clínica. A hsPLA2 gIIA mostra efeito bactericida contra infecção por Staphylococcus aureus, e tem marcada preferência por fosfolipídios aniônicos tais como fosfatidilglicerol (PG) encontrados em membranas bacterianas. Uma grande variedade de inibidores de PLA2 do grupo IIA foi descrita na literatura, incluindo substâncias polianiônicas que atuam contra os efeitos inflamatórios destas enzimas. Suramina é um derivado de naftiluréia polissulfonado que recentemente mostrou ligação com os resíduos catiônicos no sítio de reconhecimento interfacial de Bothropstoxina-I (BthTX-I), uma PLA2-Lys49 isolada do veneno de Bothrops jararacussu, inibindo a atividade miotóxica da proteína. Devido ao tipo de interação diferenciada da suramina com BthTX-I em relação aos inibidores competitivos de PLA2, nós avaliamos a especificidade de ligação da suramina na hsPLA2 gIIA como um modelo para estudar este novo tipo de inibidor de PLA2s. O efeito da suramina nas atividades biológicas e de membranas artificiais da hsPLA2 gIIA foi avaliado. A suramina aboliu tanto a atividade hidrolítica da hsPLA2 gIIA quanto a atividade de danificação de membranas artificiais Ca2+ independente. Embora a suramina não tenha inibido a atividade bactericida da hsPLA2 gIIA contra a linhagem Micrococcus luteus, a ativação de macrófagos foi abolida pela mesma de maneira dependente de hidrólise. Além disso, técnicas de simulação de dinâmica molecular, calorimetria de titulação isotérmica e mutagênese sítio dirigida foram utilizadas para mapear os sítios de ligação da suramina na proteína. A interação da suramina com a hsPLA2 gIIA resultou de interações eletrostáticas entre grupos sulfonados com cadeias laterais de aminoácidos da região do sítio ativo e dos resíduos em torno das posições 15 e 116 localizados, respectivamente, na N- e Cterminal. Portanto, estes resultados permitem sugerir que a suramina pode atuar como inibidor de sPLA2s / Suramin is a polysulphonated napthylurea used as an antiprotozoal drug that presents inhibitory activity against a broad range of enzymes. We have evaluated the effect of suramin against the artificial and biological activities of the secreted human group IIA phospholipase A2 (hsPLA2 gIIA), a protein involved in inflammatory processes. To map the suramin binding sites on the hsPLA2 gIIA, proteins with mutations in the active site region and in the protein surface that makes contact with the phospholipids membrane were expressed in E. coli and refolded from inclusion bodies. The activation of macrophage cell line RAW 264.7 by hsPLA2 gIIA was monitored by nitric oxide release, and bactericidal activity of the protein against Micrococcus luteus was evaluated by colony counting and by flow cytometry. The hydrolytic activity of the hsPLA2 gIIA against lipossomes composed of a mixture of dioleoylphosphatidylcholine/dioleoylphosphatidylglycerol (DOPC/DOPG) was inhibited by a concentration of 100 nM suramin. The activation of macrophages by hsPLA2 gIIA was abolished at protein/suramin molar ratios where the hydrolytic activity of the enzyme was inhibited. In contrast, both the bactericidal activity of hsPLA2 gIIA against Micrococcus luteus and permeabilization of the bacterial inner membrane were unaffected by suramin concentrations up to 50 M. The affinity of interaction of the suramin with hsPLA2 gIIA was evaluated by suramine fluorescence and the mutants K15A, K38A, R54A and K123A presented a reduced affinity. The binding of the suramin/hsPLA2 gIIA complex was investigated by molecular dynamics simulations, which indicated two conformations of the bound inhibitor, which involve cationic amino-acid side chains in the active-site region and residues around positions 15 and 116 located in the N- and C-termini respectively in the substrate recognition surface. These results were correlated with isothermal titration calorimetry data, which demonstrated 2.7 suramin-binding sites on the hsPLA2 gIIA. These results suggested that suramin represents a novel class of phospholipase A2 inhibitor Atividade bactericida Bactericidal activity Danificação de membranas Fosfolipases A2 Membrane damage Mutagênese sítio dirigida Phospholipase A2 Site-directed mutagenesis Suramin Suramina
80	Caracterização de linhagens de saccharomyces cerevisiae deficientes na biossíntese da Coenzima Q. / Characterization of saccharomyces cerevisiae strains deficient in the biosynthesis of Coenzyme Q. Paulela, Janaina Areias 20 April 2018 (has links) Coenzima Q (CoQ) é uma molécula de função essencial na transferência de elétrons da cadeia respiratória mitocondrial. Em Saccharomyces cerevisiae , a CoQ é constituída por um anel de benzeno associado a uma cadeia poliprenil, com 6 unidades de repetição, sendo por isso também denominada CoQ6 ou Q6. Ao todo já foram identificados treze genes (COQ1 COQ11, ARH1 e YAH1) nucleares necessários para biossíntese da CoQ. A maioria dos produtos Coq estão fisicamente associados em um complexo biossintético ancorado na membrana mitocondrial interna. Neste projeto, tentamos descrever resíduos relevantes de Coq3p e Coq7p aliando análises de bioinformática com testes fenotípicos para balizamento funcional. Coq7p é uma proteína com dois centros de ferro com íons carboxilato e catalisa a hidroxilação de demetoxi-Q6 (DMQ6). Neste estudo, indicamos um grupo de resíduos que modulam a atividade e a estabilidade de Coq7p: D53, R57, V111 e S114. Enquanto R57, V111 e S114 são resíduos muito conservados, V111 e S114 estão correlacionados em comunidades de coevolução. Aqui, demonstramos também que o duplo mutante S114A, V111G e o mutante S114E apresentam deficiência respiratória em temperatura não permissiva, além de acumularem o intermediário DMQ6 e sintetizarem baixas quantidades de Q6, concluindo assim que o fosmimético S114E inibe a atividade Coq7p. Dessa forma, propomos que a fosforilação do resíduo S114 promove o deslocamento de uma alça entre as hélices 2 e 3, afetando assim a atividade do centro catalítico Coq7p. Por sua vez, Coq3p atua como uma metiltransferase, catalisando diferentes passos durante a biossíntese da CoQ. Aqui, identificamos resíduos que colaboram para a atividade funcional de Coq3p: E123, S125, C131, G133, G134, H165, D203, E219, K258 e S262. Mutantes carregando as alterações E123A, H165A, D203A, E219A, K258A e S62A apresentam discreto crescimento respiratório e expressão de Coq3p similares à da linhagem selvagem, além de acumularem baixas quantidades de Q6. Enquanto C131, G133 e G134 são resíduos altamente conservados, localizados em uma alça no espaço entre fitas beta, no provável sítio ativo da proteína, mutantes C131A, G133A e G134A se superexpressos apresentam crescimento respiratório em meio contendo fonte de carbono não fermentável, além de acumularem Q6 compatíveis com os níveis de expressão proteica. Propomos assim um modelo para Coq3p, tendo os resíduos C131, G133 e G134 como centro catalítico de Coq3p. / Coenzyme Q (CoQ) is a molecule of essential function in the transfer of electrons of the mitochondrial respiratory chain. In saccharomyces cerevisiae , CoQ is constituted by a benzene ring associated with a polyprenyl chain with 6 repetition units, being therefore also denominated CoQ6 or Q6. Thirteen nuclear genes have already been identified (COQ1 COQ11, ARH1 and YAH1) required for coenzyme Q biosynthesis. Most of Coq products are physically associated in a biosynthetic complex anchored at the mitochondrial internal membrane. In this project, we identified Coq3p and Coq7p residues relevant for their respective role in CoQ synthesis combining bioinformatics analyzes with phenotypic tests for functional mapping. Coq7p is a carboxylate-bridged di-iron protein that catalyzes the hydroxylation of demetoxy-Q6 (DMQ6), the last monooxygenase step in the synthesis of CoQ. In this study, we found a group of residues that modulate the activity and stability of Coq7p: D53, R57, V111 and S114. While R57, V111 and S114 are highly conserved residues, V111 and S114 are correlated in communities of coevolution. We also demonstrate that the double mutant S114A, V111G and the mutant S114E have respiratory deficiency at non-permissive temperature, in addition to accumulating of the intermediate DMQ6 and low amounts of Q6, thus concluding that phosmimetic S114E inhibits the activity of Coq7p. Hence, we propose that the phosphorylation of S114 is required to move a loop between helices 2 and 3, thus affecting the activity of the catalytic center Coq7p. For its part, Coq3p acts as a methyltransferase, catalyzing different steps during biosynthesis of CoQ. Here we identified residues that collaborate for functional activity of Coq3p: E123, S125, C131, G133, G134, H165, D203, E219, K258 and S262. Mutants E123A, H165A, D203A, E219A, K258A and S62A, have mild respiratory growth, and expression of Coq3p levels similar to the wild strain, in addition to accumulating low amounts of Q6. While C131, G133, and G134 are residues highly conserved, located in a loop in the space between beta sheets, the overexpression of the mutants C131A, G133A and G134A present respiratory growth in medium containing non-fermentable carbon source, in addition to accumulate Q6 compatible with the levels of protein expression. We propose a model for Coq3p, with residues C131, G133 and G134 as part of Coq3p catalytic center. Coenzima Q Coenzyme Q COQ3 COQ3. COQ7 COQ7 Mutagênese sítio-dirigida Saccharomyces cerevisiae Saccharomyces cerevisiae Site-directed mutagenesis

Search results