Diversity of culturable moderately halophilic bacteria producing extracellular hydrolytic enzymes from marine sediments / Diversidade de bactérias cultiváveis moderadamente halofílicas que produzem enzimas hidrolíticas extracelulares de sedimentos marinhos

A total of 114 moderately halophilic bacteria were isolated from marine sediment environments. The isolates are belonged to 23 species based on the 16S rRNA sequence analysis. 63, 52, 47, 57, 74, 15 and 4 isolates are able to produce protease, amylase, lipase, pectinase, pulluanase, xylanase, cellulase, respectively. Combined hydrolytic enzyme activity analysis show that 15 strains present 1 hydrolytic activity, 32 strains present 2 hydrolytic activities, 21 strains present 3 hydrolytic activities, 26 strains present 4 hydrolytic activities, 11 strains present 5 hydrolytic activities and 2 strains present 6 hydrolytic activities. Hydrolase activities are widely distributed in a variety of species. The highest rates for production of protease, amylase, lipase, pectinase, pullanase, xylanase and cellulase were observed in species of B. baekryungensis, Hallobacillus sp., B. pumilus, B. megaterium or P. chungwhensis, B. amyloliquefaciens, B. pumilus, B. baekryungensis, respectively. However, the higher activities of protease, pectinase and pulluanase are frequently produced by the species of Halomonas sp. B. amyloliquefaciens or P. chungwhensis, and Vibrio sp. respectively. This investigation show that the diversity of halophilic bacteria from marine sediments could serve as a potential source of hydrolytic enzymes for industrial applications. (AU)

Um total de 114 bactérias moderadamente halofílicas foram isoladas de ambientes de sedimentos marinhos. Os isolados pertencem a 23 espécies com base na análise da sequência 16S rRNA. 63, 52, 47, 57, 74, 15 e 4 isolados são capazes de produzir protease, amilase, lipase, pectinase, pululanase, xilanase, celulase, respectivamente. A análise da atividade enzimática hidrolítica combinada mostra que 15 cepas apresentam 1 atividade hidrolítica, 32 cepas apresentam 2 atividades hidrolíticas, 21 cepas apresentam 3 atividades hidrolíticas, 26 cepas apresentam 4 atividades hidrolíticas, 11 cepas apresentam 5 atividades hidrolíticas e 2 cepas apresentam 6 atividades hidrolíticas. Atividades de hidrolase são amplamente distribuídas em uma variedade de espécies. As maiores taxas de produção de protease, amilase, lipase, pectinase, pululanase, xilanase e celulase foram observadas em espécies de B. baekryungensis, Hallobacillus sp., B. pumilus, B. megaterium ou P. chungwhensis, B. amyloliquefaciens, B. pumilus, B. baekryungensis, respectivamente. No entanto, as atividades mais elevadas de protease, pectinase e pululanase são freqüentemente produzidas pelas espécies de Halomonas sp. B. amyloliquefaciens ou P. chungwhensis e Vibrio sp. respectivamente. Esta investigação mostra que a diversidade de bactérias halofílicas de sedimentos marinhos pode servir como uma fonte potencial de enzimas hidrolíticas para aplicações industriais. (AU)

Biomineralization processes of calcite induced by bacteria isolated from marine sediments

Biomineralization is a known natural phenomenon associated with a wide range of bacterial species. Bacterial-induced calcium carbonate precipitation by marine isolates was investigated in this study. Three genera of ureolytic bacteria, Sporosarcina sp., Bacillus sp. and Brevundimonas sp. were observed to precipitate calcium carbonate minerals. Of these species, Sporosarcina sp. dominated the cultured isolates. B. lentus CP28 generated higher urease activity and facilitated more efficient precipitation of calcium carbonate at 3.24 ± 0.25 × 10−4 mg/cell. X-ray diffraction indicated that the dominant calcium carbonate phase was calcite. Scanning electron microscopy showed that morphologies of the minerals were dominated by cubic, rhombic and polygonal plate-like crystals. The dynamic process of microbial calcium carbonate precipitation revealed that B. lentus CP28 precipitated calcite crystals through the enzymatic hydrolysis of urea, and that when ammonium ion concentrations reached 746 mM and the pH reached 9.6, that favored calcite precipitation at a higher level of 96 mg/L. The results of this research provide evidence that a variety of marine bacteria can induce calcium carbonate precipitation, and may influence the marine carbonate cycle in natural environments.