The metagenomic approach was applied to characterize variations of microbial structure and functions in raw (RW) and treated water (TW) in a drinking water treatment plant (DWTP) at Pearl River Delta, China. Microbial structure was significantly influenced by the treatment processes, shifting from Gammaproteobacteria and Betaproteobacteria in RW to Alphaproteobacteria in TW. Further functional analysis indicated the basic metabolic functions of microorganisms in TW did not vary considerably. However, protective functions, i.e. glutathione synthesis genes in 'oxidative stress' and 'detoxification' subsystems, significantly increased, revealing the surviving bacteria may have higher chlorine resistance. Similar results were also found in glutathione metabolism pathway, which identified the major reaction for glutathione synthesis and supported more genes for glutathione metabolism existed in TW. This metagenomic study largely enhanced our knowledge about the influences of treatment processes, especially chlorination, on bacterial community structure and protective functions (e.g. glutathione metabolism) in ecosystems of DWTPs.M odern drinking water (DW) treatment usually is a multistep process, including flocculation, sedimentation, filtration and disinfection, to reduce the carrying particles and microorganisms in raw water (RW) 1 . Among these processes, disinfection is a key step in DW treatment plants (DWTPs) to eliminate pathogenic microorganisms by applying various disinfectants, such as chlorine, monochloramine, and ozone 2 . Although microorganisms can be effectively removed after treatment, some of them may survive and proliferate in DW distribution system (DWDS), and subsequently induce several serious problems 3,4 , including biofilm growth, nitrification, microbially mediated corrosion, and pathogens persistence. Thus, fully investigation of microbial structure and functions in RW and treated water (TW) of DWTPs is necessary and will facilitate the enhancement of treatment efficiency, the development of anti-pathogen strategies, and the optimization of DWDS.Recently, high-throughput sequencing (HTS) techniques have shown great advantages on analyzing the microbial community for its unprecedented sequencing depth 5 . Compared with traditional shotgun sequencing method, HTS techniques, such as 454 pyrosequencing and Illumina sequencing, are proven to be more timesaving and cost-effective 6 , and have been applied for investigating microbial structure and/or functions in various complex environments, such as fresh water 7 , sea water 8 , soil 9 , and human guts 10 . Recently, several studies have applied HTS technique to evaluate microbial community in DWTPs and DWDS [11][12][13] . These studies successfully assessed the microbial community before and after treatment and provided useful information for optimizing the DW treatment processes. However, they did not study the variation of microbial functions, which might be crucial for understanding treatment processes more comprehensively. Up to now, only on...
