[Effects of Phyllostachys edulis cultivation on soil bacterial and fungal community structure and diversity]. / æ¯›ç«¹ç§æ¤å¯¹åœŸå£¤ç»†èŒå’ŒçœŸèŒç¾¤è½ç»“æž„åŠå¤šæ ·æ€§çš„å½±å“.

This study examined how soil bacterial and fungal communities responded to the cultivation history of Moso bamboo in Anji and Changxing counties, Huzhou, Zhejiang, China. Soil samples (0-20 and 20-40 cm) were taken from bamboo plantations subjected to different cultivation histories and analyzed the community structures of soil bacterial and fungal by PCR-DGGE methods. It was found that soil bacterial and fungal communities varied greatly with the development of bamboo plantations which converted from Masson pine forest or formed via invading adjacent broadleaf shrub forest. Soil bacterial community structures exhibited a greater response to bamboo cultivation time than fungal community, but bacteria structure of surface soil displayed an ability of resiliency to disturbance and the tendency to recover to the original state. The cultivation time, sampling site and soil layer significantly affected the biodiversity of soil bacteria and fungi, especially the latter two factors. Redundancy analysis (RDA) of soil properties and bacteria or fungi communities showed that there were no accordant factors to drive the alteration of microbial structure, and the first two axes explained less than 65.0% of variance for most of the sampling sites and soil layers, indicating there existed soil parameters besides the five examined that contributed to microbial community alteration.

[Effects of intensive management on abundance and composition of soil N2-fixing bacteria in Phyllostachys heterocycla stands].

Denaturing gradient-gel electrophoresis and real-time quantitative PCR (qPCR) were employed to determine the effects of intensive management on soil N2-fixing bacteria in a moso bamboo (Phyllostachys heterocycla) plantation. Soil samples were collected from the moso bamboo stands receiving 0 (CK), 10, 15, 20, and 25 years of intensive management. It was found that intensive management caused a strong decrease in soil pH but a general increase in soil available nutrients. The structure of the N2-fixing bacterial communities in the soils having received 10 and 25 years of intensive management were quite similar to that from the CK; however, those from 15 and 20 years of intensification differed from the CK. With increasing time of intensive management, the abundance and diversity of the nifH gene at first decreased and then increased, with the minimum values being observed after 15 years of intensive management, indicating the eventual resiliency of N2-fixing bacteria to disturbance induced by intensive management. Redundancy analysis indicated that soil available potassium, available nitrogen, nitrite nitrogen, and ammonium nitrogen were more closely related to the changes of N2-fixing bacterial community structure compared with the other soil indices measured. In conclusion, the soil N2-fixing bacterial community was negatively affected by intensive management in the short term, but could recover in the long term.