[Composition diversity of the multifunctional bacterium community NSC-7].

The NSC-7 microbial community could decompose cellulose and lindan with high efficiency. In order to determine the bacterial composition of the community, 11 isolate strains were detected by plate isolation, while a community reset by the 11 isolate strains lost the capacity of degrading cellulose. The capacity of degrading of the filter paper in double deck plate and monolayer plate were determined, only the filter paper in double deck plate were degraded, that means the main or key microbe are anaerobic. The denaturing gradient gel electrophoresis (DGGE) and construction of 16S rDNA clone library were used to identify the composition diversity of NSC-7 community. 195 clones and 25 strains were detected in clone library, and about 60% closest relative among them was known the detailed information which were belonged to Clostridium, Petrobacter, Bacteria, Paenibacillus, Proteobacterium. Furthermore, there were 40% closest relative belonged to uncultured bacterium clone.

[Construction and function of a high-efficient complex microbial system to degrade cellulose and lindane in compost].

A complex microbial system capable of degrading cellulose and lindane with high efficiency was isolated from four compost heaps. It was selected and domesticated through two methods and by combination of different microbial communities. The results show that the complex microbial system can decompose filter paper, absorbent cotton, rice straw powder and sawdust effectively, especially has high degrading activity for the materials with higher native cellulose such as filter paper and absorbent cotton. As for both of them, the CMC saccharification activity is more than 40U and the degradation efficiency is more than 95% on the 5th day of inoculation. The complex microbial system can also keep a higher degrading capability in a wider range of pH. Filter paper and lindane can be degraded effectively by the complex microbial system during pH 7.0 - 9.0, and the degradation rates are more than 90 % and 45% respectively. Under pH 6.0 - 9.0, there is a good consistency between the degradation of Lindane and the decomposition of filter paper.

[Capability and stability of degrading rice straw of composite microbial system MC1].

The capability of degrading rice straw of lignocellulolytic composite microbial system MC1 was investigated under different methods of preservation and temperatures treatments of 80 degrees C to 95 degrees C, and stability of composite microbial system MC1 was studied through the method of Denaturing Gradient Gel Electrophoresis (DGGE). The results indicate that the rice straw of 2% dry weight of medium can be degraded completely at 50 degrees C within 10 days under static culture. After 9 days inoculating MC1, the dry weight of rice straw, cellulose, hemicellulose and lignin content was degraded by 81% , 99%, 74% and 51%, respectively. Capability of cellulose degrading and stability of composite microbial system MC1 is sustained under 4 years of continuing subculture, 4 years of dry preservation at room temperature, 4 years of preservation at - 20 degrees C, 1 year of liquid preservation at room temperature and at 4 degrees C, and treatment of 90 degrees C for 30 min, respectively. Plate culture results show that composite microbial system MC1 are consisted of bacteria. The main DNA bands are not changed by the method of 16S rDNA PCR-DGGE after culture of six months so that microbial composition of MC1 is very stable.