Molecular biology techniques were applied to analyze nitrifying bacterial diversity in the laboratory-scale membrane bioreactor (MBR) system. The high removal efficiencies of COD and BOD were obtained under the steady state, at which hydraulic retention time (HRT) and sludge retention time (SRT) were 0.75 days and 30 days, respectively. The MBR system was able to retain high concentrations of MLSS at tank in the range of 28000~32000 mg L(superscript -1). The results indicated that nitrification is a crucial process in the system. Therefore, the diversity of nitrifying bacteria in the system had been investigated by 16S rDNA molecular approach, including DNA extraction, polymerase chain reaction (PCR), cloning, restriction fragment length polymorphism (RFLP), sequencing and construction of phylogenic tree. The results of AOB in this study, 12 strains were classified from the results of RFLP. Besides, the clone NO.AOB-2 was dominate, the clone percentage of AOB-2 being 75.6% (121/160) in the system, similar to Thauera mechernichensis with the similarity of 96% by the sequencing data. The identified strain Thauera mechernichensis, characterized as nitrifying bacteria under aerobic and anaerobic condition, was isolated under the process of nitrification. In addition, Clone NO.AOB-11, AOB-23, AOB-33, AOB-34, AOB-71 and AOB-139) were clustered far away from the identified AOB in the gene bank, the percentage of the above mentioned clones being 15.0 % (24/160), could be novel bacteria due to the low similarity with identified AOB. In terms of NOB, the clone NO.NOB1-3 was the first dominate, the clone percentage of NOB1-3 being 40.1% (59/147) in the system, similar to Nitrite-oxidizing bacterium with the similarity of 99% by the sequencing data. The clone NO.NOB1-6 was the second dominate, the clone percentage of NOB1-6 being 30% (44/147) in the system, similar to Uncultured Nitrobacter sp. with the similarity of 97% by the sequencing data. We proposed that 30% of NOB1 was affiliated to the Uncultured Nitrobacter sp, characterized as nitrifying bacteria in the high salinity breeding water. In addition, Clone NO. NOB1-106 and NOB1-132 were 5/147, could be novel bacteria due to the low similarity with identified NOB. The molecular data indicates that nitrifying bacterial diversity in the MBR system was different from nitrifying bacterial diversity in the traditional activated sludge process. The results of molecular data could be applied for designing, operation and analyses of bacteria in the MBR system.