When a combination of hydrogen peroxide and hypochlorite was used to surface sterilize rice seeds, a 10 2 -to 10 4 -fold decrease in CFU was observed during the first 15 h after inoculation of the rice rhizosphere organism Burkholderia vietnamiensis TVV75. This artifact could not be eliminated simply by rinsing the seeds, even thoroughly, with sterile distilled water. When growth resumed, a significant increase in the frequency of rifampin-and nalidixic acid-resistant mutants in the population was observed compared to the control without seeds. This phenomenon was a specific effect of hypochlorite; it was not observed with hydrogen peroxide alone. It was also not observed when the effect of hypochlorite was counteracted by sodium thiosulfate. We hypothesized that the hypochlorite used for disinfection reacted with the rice seed surface, forming a chlorine cover which was not removed by rinsing and generated mutagenic chloramines. We studied a set of rifampin-and nalidixic acid-resistant mutants obtained after seed surface sterilization. The corresponding rpoB and gyrA genes were amplified and sequenced to characterize the induced mutations. The mutations in five of seven nalidixic acid-resistant mutants and all of the rifampin-resistant mutants studied were found to correspond to single amino acid substitutions. Hypochlorite surface sterilization can thus be a source of artifacts when the initial bacterial colonization of a plant is studied.The use of hypochlorite salts for disinfection dates back to the mid-18th century. Since that time, chlorination has been the most widely used bactericidal treatment for conventional disinfection of municipal drinking water for prevention of epidemic diseases such as cholera and typhoid, and it is still the most widely used method for disinfecting water (18). Hypochlorite is also routinely used as a sanitizer for domestic uses, as well as in food-processing plants to remove surface contaminants which can alter food quality or lead to food-borne diseases (2,3,23,29).Hypochlorite is known to be a very effective to killer of bacteria; even micromolar concentrations are enough to reduce bacterial populations significantly (27). However, little is known about the exact mechanisms of bacterial killing by this sanitizer. When diluted in water, the hypochlorite salts used [NaOCl, Ca(OCl) 2 , LiOCl, and KOCl] lead to formation of HOCl, whose concentration is correlated with bactericidal activity (27). Bacterial killing by HOCl may be due at least in part to lethal DNA damage (13, 42). However, HOCl itself is so reactive that it is unlikely to penetrate cells and reach the DNA; rather, it seems that the bactericidal activity is due to formation of secondary products, as hypochlorous acid reacts avidly with a wide variety of subcellular compounds (membranes, proteins, etc.) (10, 18). In particular, HOCl reacts with NH 4 ϩ and organic amines to form highly toxic chloramines, which also are strong oxidizing and chlorinating compounds and could be the actual killing agents. These chloramin...
