Caracterização funcional dos resíduos centrais da rede estrutural da β-glicosidase Sfβgli de Spodoptera frugiperda / Functional characterization of the central residues of the structural network of β-glucosidase Sfβgly from Spodoptera frugiperda

Cecília Midori Ikegami

14 May 2013

Na última década, a análise da estrutura proteica baseada em teoria de redes/grafos tem emergido. A abstração da estrutura tridimensional proteica em forma de uma rede, leva em consideração os resíduos de aminoácidos e suas interações através do espaço, e apresenta um conjunto de conexões e propriedades mais complexas do que aquelas visualizadas apenas com a estrutura covalente. A análise da estrutura proteica identificou que as proteínas pertencem às redes de classes de \"mundo pequeno\" (small-world) e \"sem escala\" (scale-free), o que significa que seus resíduos de aminoácidos são altamente agregados e que existem poucas conexões entre 2 resíduos quaisquer da proteína. A identificação dos resíduos com alto grau de conexão, chamados centrais (\"resíduos hubs\"), é feita pela determinação do caminho mais curto que conecta um dado resíduo aos demais compreendidos nesta rede. A remoção destes resíduos centrais (hubs) afeta a integridade da rede de forma mais contundente diferentemente da remoção de resíduos que não são centrais. Até o momento estes \"resíduos hubs\" ainda não foram experimentalmente correlacionados com as propriedades enzimáticas de proteínas. Para tal finalidade, a estrutura terciária de uma β-glicosidase de Spodoptera frugiperda (Sfβgli) foi analisada como uma rede. Após calcular-se os caminhos médios entre todos os pares de aminoácidos da β-glicosidase, encontrou-se 11 resíduos centrais (\"resíduos hubs\"). Alinhamento de sequências e comparações estruturais indicaram alta conservação destes \"resíduos hubs\". Nosso objetivo foi produzir esta β-glicosidase mutando-se a maioria dos \"resíduos hubs\" e 3 aminoácidos não centrais (\"não hubs\"), expressar estes mutantes em E. coli, determinar suas propriedades enzimáticas como atividade catalítica e preferência pelo substrato e verificar a estabilidade destes mutantes em experimentos de inativação térmica. Os resultados obtidos sugerem que mutações nos \"resíduos hubs\" não afetam as propriedades catalíticas, contudo as enzimas com mutações nos \"resíduos hubs\" apresentaram uma menor estabilidade térmica. Estes resultados sugeriram que os \"resíduos hubs\" são relevantes na difusão da energia cinética (vibração) introduzida na estrutura desta β-glicosidase pelo seu aquecimento / In recent years, graph-theoretic approaches have established that protein structures can be modeled as complex networks of interacting residues. Proteins structures can be represented as small-world and scale-free networks that are usually highly clustered with few links connecting any pair of nodes. The identification of nodes with high connection degrees, called hubs, is made by determining the shortest path linking one amino acid to the further nodes comprising the network. Targeted removal of the hubs has greater affect on the integrity of the network structure in contrast to a random removal of amino acid residues comprising the network. Nevertheless these hubs had not previously been correlated with enzymatic properties. The tertiary structure of β-glycosidase from S. furgiperda (Sfβgly) was analyzed as a network. After calculating the averaged paths between all pairs of amino acid residues of Sfgly, we defined 11 hubs, which have the highest centrality on the network. Sequence alignment and structural comparison showed that these hubs residue are conserved among β-glycosidases. Our goal was to mutate most hubs and 3 ´non-hubs´ residues from Sfβgly, express these mutant enzymes in E. coli, test their enzymatic properties as catalytic efficiency and substrate preference, and verify the thermal stability of these mutants. The results implied that mutations in these hubs do not cause changes in catalytic properties although enzymes containing mutations in hubs showed lower thermal stability. Based on that, it was suggested that hub residues are important in the diffusion of kinetic energy (vibrations) introduced in the Sfβgly structure by heating

Aminoácidos centrais

Atividade enzimática

Beta-glicosidase

Enzima mutante

Enzimologia

Inativação térmica

Rede

Beta-glucosidase

Enzyme activity

Enzymology

Hubs

Mutation

Network

Thermal inactivation

Impact of yeast present during pre-fermentation cold maceration on Pinot noir wine aroma

Hall, Harper L.

14 June 2012

This research investigated yeast populations and diversity during pre-fermentation cold maceration and alcoholic fermentation of Vitis vinifera L. cv. Pinot noir grapes from a commercial vineyard (Dayton, OR). Fermentations were conducted at the Oregon State University research winery in 100 L tanks while grapes from the same vineyard lot were fermented at a commercial winery. Samples were taken daily during pre-fermentation maceration (9°C) and alcoholic fermentation (27°C) and plated on WL and lysine media to determine Saccharomyces and non-Saccharomyces populations and diversity. Total non-Saccharomyces populations increased from 1 x 10³ cfu/mL to 1 x 10⁵ cfu/mL during pre-fermentation cold maceration and reached a maximum of 1 x 10⁷ cfu/mL during alcoholic fermentation. Thirteen distinct yeast species were tentatively identified based on appearance on WL media and were initially screened for β-glucosidase activity using 4-methyllumbelliferyl-β-D-gluconopyranoside (4-MUG) plates. The identity of the isolates screening positive for β-glucosidase activity was determined by sequence analysis of the D1/D2 domain of the 26S rDNA gene. The five isolates identified were Metschnikowia pulcherrima, Hanseniaspora uvarum, Kluveromyces thermotolerans, and two Saccharomyces cerevisiae isolates. β-glucosidase activity was further characterized and quantified using a liquid media representing grape must conditions (pH 3.5, 20° Brix) at two temperatures (25°C and 8°C). While increasing sugar concentration suppressed the β-glucosidase activity of H. uvarum (-99%), β-glucosidase activity still remained relatively high for M. pulcherrima, S. cerevisiae isolate 1, and S. cerevisiae isolate 2. At 8°C, β-glucosidase activity was reduced for M. pulcherrima compared to activity at 25°C, but activity increased for K. thermotolerans, S. cerevisiae isolate 1, and S. cerevisiae isolate 2. The yeast isolates possessing β-glucosidase activity were used in fermentations of Vitis vinifera L. cv. Pinot Noir grapes. The grapes were treated with high hydrostatic pressure (HHP) to inactivate naturally occurring yeast and bacteria. All yeast isolates grew during pre-fermentation cold maceration (7 days at 9°C) and populations increased 3 to 4 logs. Following pre-fermentation cold maceration, all ferments were warmed to 27°C and inoculated with S. cerevisiae RC212. Alcoholic fermentations were all complete within eight days and after pressing wines were analyzed for volatile aroma compounds by SPME-GC-MS. The presence of different yeast isolates during pre-fermentation cold maceration resulted in wines with unique aroma profiles. Ethyl ester concentrations were highest in the wine that did not undergo a pre-fermentation cold maceration, while concentrations of branch-chained esters were higher in the treatments with yeast present during pre-fermentation cold maceration. Pre-fermentation cold maceration with yeast isolates demonstrating β-glucosidase did not affect the concentration of β-damascenone or β-ionone. Wines that had undergone pre-fermentation cold maceration with S. cerevisiae isolate 1, S. cerevisiae isolate 2, and a combination of all isolates resulted in over twice the concentration of β-citronellol over wines that did not undergo a pre-fermentation cold maceration. / Graduation date: 2013

Pinot noir

wine aroma

non-Saccharomyces

Saccharomyces

pre-fermentation cold maceration

beta-glucosidase

Kluveromyces thermotolerans

Hanseniaspora uvarum

Pinot noir (Wine) -- Oregon

Wine -- Flavor and odor -- Oregon

Yeast

Wine and wine making -- Oregon

Activity and kinetics of microbial extracellular enzymes in organic-poor sands of a south Texas estuary

Souza, Afonso Cesar Rezende de, 1968-

22 March 2011

The respective kinetics of bacterial leucine aminopeptidase and [beta]-glucosidase activities were investigated to improve understanding of factors controlling activity and hydrolytic capacity in estuarine organic-poor sands. Depth distributions of enzyme activity and bulk organic matter content were determined in sediments of Aransas Bay and Copano Bay Texas, to investigate enzyme dynamics as related to the geochemical properties of the sediment. Vertical profiles of activity in sediment showed that the enzymes were more active at the surface and that the potential hydrolysis rate of leucine aminopeptidase was higher than that of [beta]-glucosidase. Vertical patterns of enzyme activity correlated (weakly) with variations in sediment organic matter (TOC, TN, and carbohydrates) content. Enrichments of sediment samples with monomeric organic compounds and inorganic nutrients did not affect leucine aminopeptidase and [beta]-glucosidase activities in short- and long-term incubations. Enzyme activity was independent of nutrient availability and suggested that microbial communities were not nutrient-limited. Time-course assays of bacterial hydrolysis of TOC, TN, and carbohydrates provided information about how substrate limitation may affect enzyme activity. Positive correlations between bulk TOC and TN content and enzyme activity indicated enzyme dependence on polymeric substrate content. Induction of enzyme activity after sediment enrichments with specific labile compounds confirmed the importance of available organic substrate to enzyme hydrolysis efficiency. A kinetic approach established the occurrence of enzyme inhibition and its effects on enzyme hydrolytic capacity. The addition of a specific-enzyme substrate to sediment samples modified enzyme parameters and indicated that a substrate-reversible type of inhibitor could reduce enzyme hydrolytic capacity. The addition of polyphenol, as a natural inhibitor of enzyme activity, to the sediment resulted in a concomitant reduction of leucine aminopeptidase activity and ammonium regeneration rate, and thus demonstrated a close coupling between enzyme activity and sediment ammonium regeneration. These research results demonstrate the dynamic nature of the hydrolytic enzymes, provide information about the mechanisms of induction and inhibition of activity, and demonstrate some implications of reducing the hydrolytic capacity to organic matter decomposition and nutrient regeneration rates. / text

Microbial extracellular enzymes

Enzyme kinetics

Enzyme activity

Enzyme dynamics

Organic-poor sands

Estuarine sands

Aransas Bay, Texas

Copano Bay, Texas

Bacterial leucine aminopeptidase

[beta]-glucosidase

Sediments

Hydrolysis

Enzyme hydrolytic capacity

South Texas