Protease production and molecular characterization of a protease dipeptidyl-aminopeptidase gene from different strains of Sordaria fimicola / Produção de protease e caracterização molecular de um gene de protease - DPAP (dipeptidil-aminopeptidase) de diferentes cepas de Sordaria fimicola

The current research was designed to reach extracellular protease production potential in different strains of Sordaria fimicola which were previously obtained from Dr. Lamb (Imperial College, London) from North Facing Slope and South Facing Slope of Evolution Canyon. After initial and secondary screening, two hyper-producers strains S2 and N6 were selected for submerged fermentation and cultural conditions including temperature, pH, incubation period, inoculum size, substrate concentration, and different carbon and nitrogen sources were optimized for enzyme production. S2 strain showed maximum protease production of 3.291 U/mL after 14 days of incubation at 30 °C with 7 pH, 1% substrate concentration and 1 mL inoculum, While N6 strain showed maximum protease production of 1.929 U/mL under fermentation optimized conditions. Another aim of the present research was to underpin the biodiversity of genetics and post-translational modifications (PTMs) of protease DPAP (peptidyl-aminopeptidase) in Sordaria fimicola. Five polymorphic sites were observed in amino acid sequence of S. fimicola strains with reference to Neurospora crassa. PTMs prediction from bioinformatics tools predicted 38 phosphorylation sites on serine residues for protease peptidyl-aminopeptidase in S1 strain of S. fimicola while 45 phosphorylation sites on serine in N7 strain and 47 serine phosphorylation modifications were predicted in N. crassa. Current research gave an insight that change in genetic makeup effected PTMs which ultimately affected the production of protease enzyme in different strains of same organism (S. fimicola). The production and molecular data of the research revealed that environmental stress has strong effects on the specific genes through mutations which may cause genetic diversity. S. fimicola is non- pathogenic fungus and has a short life cycle. This fungus can be chosen to produce protease enzyme on a commercial scale.

A pesquisa atual foi projetada para alcançar o potencial de produção de protease extracelular em diferentes cepas de Sordaria fimicola que foram previamente obtidas do Dr. Lamb (Imperial College, Londres) de North Facing Slope e South Facing Slope de Evolution Canyon. Após a triagem inicial e secundária, duas cepas hiperprodutoras S2 e N6 foram selecionadas para fermentação submersa e condições culturais, incluindo temperatura, pH, período de incubação, tamanho do inóculo, concentração de substrato, e diferentes fontes de carbono e nitrogênio foram otimizadas para produção de enzima. A cepa S2 apresentou produção máxima de protease de 3,291 U/mL após 14 dias de incubação a 30 °C com pH 7, concentração de substrato de 1% e inóculo de 1 mL, enquanto a cepa N6 apresentou produção máxima de protease de 1,929 U/mL em condições otimizadas de fermentação. Outro objetivo da presente pesquisa foi sustentar a biodiversidade da genética e modificações pós-tradicionais (PTMs) da protease DPAP (peptidil-aminopeptidase) em Sordaria fimicola. Cinco sítios polimórficos foram observados na sequência de aminoácidos de cepas de S. fimicola com referência a Neurospora crassa. A previsão de PTMs a partir de ferramentas de bioinformática previu 38 locais de fosforilação em resíduos de serina para protease peptidil-aminopeptidase na cepa S1 de S. fimicola, enquanto 45 locais de fosforilação em serina na cepa N7 e 47 modificações de fosforilação de serina foram previstas em N. crassa. A pesquisa atual deu uma ideia de que a mudança na composição genética afetou os PTMs que, em última análise, afetaram a produção da enzima protease em diferentes cepas do mesmo organismo (S. fimicola). A produção e os dados moleculares da pesquisa revelaram que o estresse ambiental tem fortes efeitos sobre genes específicos por meio de mutações que podem causar diversidade genética. S. fimicola é um fungo não patogênico e tem um ciclo de vida curto. Esse fungo pode ser escolhido para produzir enzima protease em escala comercial.

Essential oil of Gallesia integrifolia is active against mycobacteria.

Background: There is critical need for new therapeutic options for treatment of diseases caused by mycobacteria. Materials & methods: Gallesia integrifolia essential oils (EOs) and crude extracts (CEs) were tested for their anti-Mycobacterium tuberculosis and anti-nontuberculous mycobacteria activity. Results: Minimum inhibitory concentration (MIC) of EOs ranged from 15.63 to 62.5 µg/ml against M. tuberculosis and 62.5 to >250 µg/ml against nontuberculous mycobacteria. CEs showed low activity. All EO tested demonstrated synergism with antituberculosis drugs. The cytotoxicity of EOs and CEs, in different cell lines, showed selectivity index from 2.2 to 9.8 and >0.056 to 2.0, respectively. Conclusion: G. integrifolia EOs are a candidate for the development of new therapeutic options in the treatment of tuberculosis and other mycobacterial diseases.

A broad pH range indicator-based spectrophotometric assay for true lipases using tributyrin and tricaprylin.

A continuous assay is proposed for the screening of acidic, neutral, or alkaline lipases using microtiter plates, emulsified short- and medium-chain TGs, and a pH indicator. The lipase activity measurement is based on the decrease of the pH indicator optical density due to protonation which is caused by the release of FFAs during the hydrolysis of TGs and thus acidification. Purified lipases with distinct pH optima and an esterase were used to validate the method. The rate of lipolysis was found to be linear with time and proportional to the amount of enzyme added in each case. Specific activities measured with this microplate assay method were lower than those obtained by the pH-stat technique. Nevertheless, the pH-dependent profiles of enzymatic activity were similar with both assays. In addition, the substrate preference of each enzyme tested was not modified and this allowed discriminating lipase and esterase activities using tributyrin (low water solubility) and tricaprylin (not water soluble) as substrates. This continuous lipase assay is compatible with a high sample throughput and can be applied for the screening of lipases and lipase inhibitors from biological samples.