Temporal expression of nitric oxide synthase in Ilyanassa obsoleta using an Ilyanassa-specific NOS antibody

Weaver, Allison Deal.

January 1900

Thesis (M.S.)--The University of North Carolina at Greensboro, 2009. / Directed by Mark Hens; submitted to the Dept. of Biology. Title from PDF t.p. (viewed May 17, 2010). Includes bibliographical references (p. 60-65).

Nitric oxide synthase and the contribution of nitric oxide to vertebrate motor contol /

Molinari, Micol Ariella.

January 2008

Thesis (M.Phil.) - University of St Andrews, January 2008.

Pharmakologische, molekularbiologische und biochemische Untersuchungen zur Beeinflussung des Renin-Angiotensin-Systems und der renalen Cyclooxygenase- und NO-Synthase-Isoenzyme in der Frühphase der primären, genetisch bedingten und sekundären, Immunsuppressiva-induzierten Hypertonie

Dreher, Franziska.

January 2002

Regensburg, Univ., Diss., 2002.

RNA-binding proteins in yeast mitochondria

Deumer, Claudia D.

Unknown Date

Techn. University, Diss., 2002--Dresden.

Untersuchungen zur Fettsäure- und Zellwandsynthese sowie zur Glutamatbildung mit Corynebacterium glutamicum

Radmacher, Eva.

Unknown Date

Universiẗat, Diss., 2004--Düsseldorf.

Nitric oxide/peroxynitrite balance in kidney : effect of diabetes and obesity /

Huang, Xiaoyan.

January 2008

Thesis (Ph.D.)--Ohio University, November, 2008. / Release of full electronic text on OhioLINK has been delayed until December 1, 2010. Includes bibliographical references (leaves 140-162)

Caracterização de mutantes condicionais do gene da desoxi-hipusina sintase em Saccharomyces cerevisiae /

Galvão, Fábio Carrilho.

January 2011

Orientador: Cleslei Fernando Zanelli / Banca: Nilson Ivo Tonin Zanchin / Banca: Paulo Sergio Rodrigues Coelho / Resumo: O fator de início de tradução 5A (eIF5A) é altamente conservado de arqueas a mamíferos e é essencial para a viabilidade celular. Este fator é a única proteína conhecida que sofre uma modificação pós-traducional única e necessária para a função de eIF5A, em que uma lisina específica é convertida em um resíduo de hipusina pela ação das enzimas desoxi-hipusina sintase (Dys1) e desoxi-hipusina hidroxilase (Lia1). Inicialmente, eIF5A foi relacionada à etapa do início da tradução, porém, dados recentes sugerem a sua atuação na etapa de elongação ao invés de início. No entanto, além do fato de a função específica de eIF5A na célula não ser conhecida, o papel da hipusinação para o funcionamento de eIF5A também não é conhecido. Diante disso, o objetivo deste trabalho é caracterizar mutantes condicionais para o gene da desoxi- hipusina sintase e, dessa forma, contribuir para o entendimento não só da função da hipusinação sobre eIF5A, mas também para o entendimento da função específica de eIF5A na célula. Para isso, foram iniciadas análises de caracterização fenotípica com os alelos dys1Δ1-28 e dys1W75R/T118A/A147T (dys1-1). Inicialmente, foi realizada a subclonagem do alelo dys1Δ1-28 , uma vez que, por ter sido identificado em um rastreamento de duplo-híbrido, este alelo estava em fusão com a região codificadora do domínio de ativação de Gal4. Porém, após realização da subclonagem, ou seja, quando na ausência do domínio de ativação, este alelo não apresentou o fenótipo condicional de crescimento inicialmente observado. Portanto, o mutante se tornou impróprio para a realização dos ensaios subsequentes e foi descartado. Em seguida, foram iniciadas as análises com o alelo dys1-1, nas quais foi observada diminuição nos níveis totais de Dys1 mutada, e consequentemente, diminuição nos níveis de hipusinação. Devido a isso ... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: The translation initiation factor 5A (eIF5A) is highly conserved from archaea to mammals and is essential for cell viability. This factor is the only known protein that undergoes an unique and essential post-translational modification, in which a specific lysine residue is converted into hypusine by the action of the enzymes deoxyhypusine synthase (Dys1) and deoxyhypusine hydroxylase (Lia1). Initially, eIF5A was related to the initiation step of translation, however, recent data suggest a role in the elongation step of translation. However, besides the fact that the specific function of eIF5A in the cell is still obscure, the role of hypusination in eIF5A function is unknown. Thus, the goal of this project is to characterize conditional mutants of the deoxyhypusine synthase gene and thereby contribute to the understanding not only the function of hypusination in eIF5A, but also of the specific role of eIF5A in the cell. We started a phenotypic characterization of two different alleles: dys1Δ1-28 and dys1W75R/T118A/A147T (dys1-1). Initially, we performed a subcloning of the allele dys1Δ1-28 , once the allele was fused with the coding region of GAL4 activation domain, due to the fact that this allele is devived of a two-hybrid screening. However, after performing the subcloning, that is, in the absence of the activation domain, this allele showed no conditional growth phenotype as originally observed. Therefore, this mutant has become improper to carry out the subsequent analysis and was discarted. Then, the analyses with dys1-1 allele were initiated, in which it was observed a decrease in total levels of Dys1 and, consequently, a decrease in the hypusination levels. Because of that, this allele shows a decrease in cell growth rate and growth arrests after 24 hours in medium lacking the osmotic regulator. However, this growth arrest is not followed by cell lysis. Furthermore, the mutant ... (Complete abstract click electronic access below) / Mestre

Biologia molecular.

Molecular biology. eng

Deoxy hipusina synthase. eng

Activity of the beta-cyanoalanine synthase pathway is associated with the response to abiotic stress by Arabidopsis thaliana.

Machingura, Marylou

01 December 2012

Cyanide is produced throughout a plant's life cycle alongside the hormone ethylene by oxidation of 1-aminocyclopropane-1-carboxylic acid. Production increases during certain developmental stages such as seed germination, seedling elongation, fruit ripening and senescence. Abiotic stresses increase ethylene production giving rise to `stress cyanide'. Cyanide also comes from metabolism of cyanogenic compounds. Cyanide is however, a toxic chemical which readily binds to metallo-enzymes inhibiting primary metabolic processes. Plants have mechanisms to maintain cyanide homeostasis such as the β-cyanoalanine pathway whereby cysteine reacts with cyanide forming β--cyanoalanine, mediated by β-cyanoalanine synthase and cysteine synthase. A dual nitrilase 4 enzyme then converts the β-cyanoalanine into asparagine or aspartate and ammonium. Studies have suggested that the physiological function of the pathway is not restricted to detoxification and assimilation of excess cyanide. The overall research goal was to investigate the role of the pathway in plant tolerance to water deficit and exogenous cyanide exposure in Arabidopsis thaliana. The first objective was to investigate responsiveness of the pathway to duration and intensity of water deficit and cyanide exposure. The second was to investigate the contribution of enzymes associated with the pathway to cyanide metabolism. The questions addressed were whether there is enzymatic redundancy in enzymes associated with the first step of cyanide detoxification and whether there is pathway redundancy between the β-cyanoalanine and an alternative sulfurtransferase pathway. A. thaliana Col-0 and three SALK-line mutants with a T-DNA insertion for the genesAtCysA1, AtCysC1 and AtNIT4 were grown and exposed to water stress. Physiological and biochemical measurements were taken. The results showed a transient increase in cyanide concentration and β-cyanoalanine synthase activity on exposure to stress. The response pattern was similar regardless of intensity or duration of stress. Knocking out AtCysA1 or AtCysC1 did not impair the ability of plants to metabolize cyanide and tolerate stress i.e the enzymes were functionally redundant. The AtNIT4 mutant however, was impaired in cyanide metabolism and exhibited a sensitive phenotype under both stresses, suggesting that the cyanoalanine pathway is the sole pathway in cyanide detoxification. The results show that the pathway may be an important tool in improvement of plant tolerance to abiotic stress.

Arabidopsis thaliana

Cyanide

Cyanoalanine synthase

Ethylene

Nitrilase

Water deficit

Structural studies of the mitochondrial F-ATPase

Spikes, Tobias Edward

January 2018

The mitochondrial F-ATPases make about 90% of cellular ATP. They are multi-protein assemblies with a membrane extrinsic catalytic domain attached to a membrane embedded sector. They operate by a mechanical rotary mechanism powered by an electro-chemical gradient, generated across the inner mitochondrial membrane by respiration. A detailed molecular description has been provided by X-ray crystallographic studies and "single molecule" observations of the mechanism of the F1 catalytic domain. Details are known also of the architecture of the peripheral stalk of part of the stator and the membrane embedded region of the rotor. However, knowledge of the detailed structure of the rest of the membrane domain, and the detailed mechanism of generation of rotation is lacking. Recently, studies of the intact mitochondrial F-ATPases, determined by cryo-electron microscopy (cryo-em), have provided structural information at intermediate levels of resolution. Whilst these structures have given insights into the mechanism of generation of rotation, the information required for a molecular understanding of this mechanism is still lacking. Moreover, the locations and roles of six supernumerary membrane subunits are unclear. Some of them are likely to be involved in the formation of dimers of the enzyme which line the edges of mitochondrial cristae. Therefore, in this thesis, a procedure is described for the purification of dimers of the bovine and yeast F-ATPases. The structure of the bovine dimer has been determined by cryo-em at a resolution of ca. 6.9 Angstrom. This structure confirms features concerning the trans-membrane spans of the a-, A6L- and b-subunits observed in the monomeric complex. In addition, the single trans-membrane a-helix of the f-subunit has been located, and the subunit appears to mediate dimer formation. The structure of A6L has been extended, and the a-helices of subunits e- and g- have been located. Another novel feature has been assigned to the DAPIT subunit, and may provide links between dimers in forming larger oligomers. Further improvement in the resolution of the structure is hampered by the extreme conformational heterogeneity of the F-ATPase. To this end, the simpler Fo membrane domain has been isolated and characterized initially by electron microscopy in negative stain.

Identificação de elementos estruturais no tRNAsecuca determinantes da ligação com proteínas / Identification of structural elements of the tRNAsecuca determining its protein binding

Livia Regina Manzine

25 January 2012

Em Escherichia coli a formação e incorporação do aminoácido selenocisteína é um evento cotraducional dirigido pelo códon de terminação UGA e deve se a uma complexa via de biosíntese cujas principais proteínas envolvidas são: Selenocisteína sintase (SELA), Fator de elongação de selenocisteína (SELB), Selenofosfato sintetase (SELD), Seril-tRNAser sintetase, um tRNA de inserção de selenocisteína (tRNAsec ou SELC) e uma sequência específica no RNA mensageiro, denominada de Sequência de inserção de selenocisteína (SECIS). A incorporação de selenocisteína em proteínas bacterianas inicia-se com a aminoacilação do tRNAsec com serina pela enzima Seril-tRNA sintetase formando seril-tRNAsec que é posteriormente convertido a selenocisteil-tRNAsec pela enzima SELA através de selenofosfato. Dessa forma, o trabalho teve seu foco estabelecido na realização de estudos bioquímicos e biofísicos da proteína SELA e na análise da interação dessa proteína com o ligante SELC para determinação de parâmetros de ligação envolvidos na formação desse complexo. O gene codificante para a proteína SELA foi subclonado, expresso em linhagem bacteriana WL81460(DE3) e a proteína SELA foi purificada como descrito na literatura; entretanto, uma nova metodologia para sua purificação foi desenvolvida proporcionando maior rapidez e rendimento. Estudos de filtração em gel, eletroforese nativa, focalização isoelétrica, dicroísmo circular, espectroscopia de fluorescência intrínseca e crosslinking químico proporcionaram uma melhor caracterização da proteína SELA e consequentemente uma maior compreensão de seu comportamento em solução. Ensaios de espectroscopia de anisotropia de fluorescência revelaram que a proteína SELA é capaz de se associar em estruturas superiores ao estado decamérico; essa análise pôde ser corroborada principalmente por dados de microscopia eletrônica empregando a técnica de negative staining. A metodologia de anisotropia de fluorescência também permitiu analisar a interação da macromolécula SELA com o ligante específico SELC, bem como com outros tRNAs mutantes possibilitando a realização de um mapeamento das regiões de SELC importantes para a interação. Além disso, essa técnica também foi satisfatoriamente empregada na determinação da estequiometria de ligação do complexo SELA-SELC revelando a proporção de 1 molécula de SELA para 10 tRNAs, o que contraria dados literários publicados em 1991 e 1992. / The formation and incorporation of the amino acid selenocysteine in Escherichia coli is an event directed by cotraducional UGA codon and involves a complex biosynthesis pathway whose main proteins are: Selenocysteine synthase (SELA), elongation factor of selenocysteine (SELB), Selenophosphate synthetase (SELD), Seryl-tRNA synthetase, a selenocysteine tRNA (tRNAsec or SELC) and a specific sequence on the messenger RNA, called Selenocysteine insertion sequence (SECIS). The incorporation of selenocysteine in proteins of bacteria begins with the tRNAsec aminoacylation with serine by the enzyme Seryl-tRNA synthetase resulting in seryl-tRNAsec which is subsequently converted to selenocysteyl-tRNAsec by the enzyme Selenocysteine synthase (SELA). The selenium used in the conversion reaction is provided by Selenophosphate synthetase as selenophosphate and finally, the selenocysteyl-tRNAsec is delivered by the factor SELB to the ribosome. The present study focused on biochemical and biophysical studies of SELA protein and analysis of its interaction with the specific ligand (SELC) for determination of binding parameters involved in the formation of the complex. The gene coding for SELA protein was subcloned, expressed in WL81460(DE3) bacterial strain and the protein was purified as described in the literature; however a new, faster and more efficient method for its purification was developed. Studies of gel filtration, native gel electrophoresis, isoelectric focusing, circular dichroism, intrinsic fluorescence spectroscopy and chemical crosslinking provided a better characterization of SELA protein and a greater understanding of its behavior in solution. Analysis of fluorescence anisotropy spectroscopy revealed that SELA was able to associate in a supramolecular state. This analysis was mainly corroborated by data from electron microscopy employing negative staining technique. Fluorescence anisotropy methodology allowed us to analyse the interaction of SELA protein with the specific ligand SELC, as well as with others mutated tRNAs enabling a mapping of important regions in SELC for interaction. In addition, fluorescence anisotropy technique was also successfully used in determining the stoichiometry ratio of the complex SELA-SELC, showing a proportion of 1 molecule of SELA to 10 tRNAs, contraring to the literary data published in 1991 and 1992.

Selenocisteína

Selenocisteína sintase

tRNAsec

Selenocysteine

Selenocysteine synthase

tRNAsec