摘要
The stationary phase of microbial growth is a very complex state regulated by various environmental and physiological factors. An intensive study of stationary phase could promote a comprehensive understanding of the complete life cycle of microorganisms, and may provide important insights into their adaptation to harsh and nutrient-depleted conditions. Although the underlying mechanisms have been weU-studied in bacteria and yeasts (Herman, 2002; Navarro Llorens et al., 2010), less is known about this growth phase in archaea yet. The haloarchaeon Haloferax mediterranei has served as a good model for studying haloarchaeal physiology and metabolism for several decades because of its accelerated growth, remarkable metabolic ability and genomic stability (Han et al., 2012). During stationary phase, H. mediterranei can produce halocin H4 (Cheung et al.,
The stationary phase of microbial growth is a very complex state regulated by various environmental and physiological factors. An intensive study of stationary phase could promote a comprehensive understanding of the complete life cycle of microorganisms, and may provide important insights into their adaptation to harsh and nutrient-depleted conditions. Although the underlying mechanisms have been weU-studied in bacteria and yeasts (Herman, 2002; Navarro Llorens et al., 2010), less is known about this growth phase in archaea yet. The haloarchaeon Haloferax mediterranei has served as a good model for studying haloarchaeal physiology and metabolism for several decades because of its accelerated growth, remarkable metabolic ability and genomic stability (Han et al., 2012). During stationary phase, H. mediterranei can produce halocin H4 (Cheung et al.,
基金
supported by the grants from the National Natural Science Foundation of China(Nos.30925001 and 31271334)
the Chinese Academy of Sciences(No. KSCX2-EW-G-2-4)
