Hyperthermophilic Clostridium sp. N-4 produced a glycoprotein biosurfactant that enhanced recovery of residual oil at 96 °C in lab studies.

Biosurfactant producing hypethermophilic microorganisms are essentially required for Microbial Enhanced Oil Recovery (MEOR) from high temperature oil reservoirs (above 90 °C). In the present study, biosurfactant producing Clostridium sp. N-4, optimally growing at 96 °C was isolated from a high temperature oil reservoir. Effect of pH, temperature and salinity on production and activity of N-4 biosurfactant was investigated. Biosurfactant produced by N-4 was partially purified by acid precipitation, characterized using FT-IR spectroscopy; and evaluated for its ability to enhance oil recovery in sand pack studies. The strain N-4 produced biosurfactant over a wide range of pH (5.0-9.0) and salinity (0-13%) at high temperature (80-100 °C) and optimally at pH 7, 96 °C and 4% salinity. N-4 biosurfactant was active at 37-101 °C; pH, 5-10 and salinity of 0-12 % (w/v). N-4 biosurfactant, characterized as glycoprotein reduced the surface tension of water by 32 ± 0.4 mN/m at critical micelle concentration of 100 µg/ml. N-4 biosurfactant mobilized 17.15% of residual oil saturation in sand pack studies. Similarly, the strain N-4 also recovered 36.92% of the residual oil in sand pack studies under the conditions mimicking the environment of depleted high temperature oil reservoir. Thus, the biosurfactant producing Clostridium sp. N-4 was identified as a suitable agent for enhanced oil recovery from high temperature oil reservoirs.

Statistical optimization of medium components for production of extracellular chitinase by Basidiobolus ranarum: a novel biocontrol agent against plant pathogenic fungi.

The influence of concentration of medium components such as colloidal chitin, lactose, malt extract, yeast extract, and peptone on the chitinase production from Basidiobolous ranarum at the flask level were studied by using statistical tool Central Composite Design (CCD) and analysed by Response Surface Methodology (RSM). The results revealed that colloidal chitin, malt extract and peptone had significant effect (P < 0.01) on the chitinase production at their individual levels. The polynomial equation of the model developed incorporates 3 linear, 3 quadratic and 5 interactive terms. Maximum chitinase production of 3.47 U ml(-1) was achieved with 1.5% colloidal chitin, 0.125% lactose, 0.025% malt extract and 0.075% peptone. After optimization, chitinase activity was increased by 7.71 fold. A second order polynomial equation was found to be useful for the development of efficient bioprocess for chitinase production. To screen the biotechnological potential of this enzyme, degradation of fungal mycelia by ammonium sulphate precipitate of the same was studied for several pathogenic fungi-in vitro which showed promising results particularly against Rhizoctonia solani and Fusarium solani. This study provides the first evidence showing the effectiveness of RSM for the development of a robust statistical model for the chitinase production by Basidiobolus and for its application in the biocontrol of phytopathogenic fungi.