Anaerobic biotransformation of dinitrotoluene isomers by Lactococcus lactis subsp. lactis strain 27 isolated from earthworm intestine.

Dinitrotoluenes are widely used as solvents and are intermediates in the synthesis of dyes, explosives, and pesticides. Environmental concerns regarding DNTs have increased due to their widespread use and their discharge into the environment. In this study, the anaerobic biodegradation of four dinitrotoluene isomers, 2,3-, 2,4-, 2,6- and 3,4-DNT, was investigated using Lactococcus lactis subsp. lactis strain 27, which was isolated from the intestines of earthworms. Liquid chromatography/mass spectrometry and NMR spectroscopy showed that L. lactis strain 27 non-specifically reduced the nitro groups on the tested dinitrotoluenes to their corresponding aminonitrotoluenes. L. lactis strain 27, however, did not reduce either sequentially or simultaneously two nitro groups of the dinitrotoluenes, resulting in the formation of the corresponding diaminotoluenes. In vitro formation of dinitroazoxytoluenes suggested the presence of oxygen-sensitive hydroxylaminonitrotoluenes. L. lactis strain 27 was capable of reducing 2,4-, 2,6-, 2,3-, and 3,4-dinitrotoluenes up to 173.6, 66.6, 287.1, and 355 microM, respectively in 12 h incubation. A relatively rapid reduction was observed in the case of the 2,3-, and 3,4-dinitrotoluenes, which have vicinal nitro groups on their arene structure. Non-specific anaerobic reduction of dinitrotoluenes by the intestinal bacterium L. lactis strain 27 differentiated the extent of reduction of DNTs according to the substitutional position of the nitro groups and produced in vitro more toxic dinitroazoxytoluenes, suggesting that anaerobic biotransformation of dinitrotoluenes could increase environmental risk.

Beef tallow increases apoptosis and decreases aberrant crypt foci formation relative to soybean oil in rat colon.

Although epidemiological studies have implicated red meat as increasing colon cancer risk, animal studies have generally not been supportive of such an effect. This study examined red meat components, such as beef protein and tallow, on markers of colon cancer risk. Rats administered dimethylhydrazine were fed either casein or beef protein as the protein source and soybean oil or tallow as the fat source in a 2 2 factorial design for 9 wk. There were fewer preneoplastic lesions [aberrant crypt foci (ACF)] and a greater apoptotic labeling index (P < 0.05) in the distal colonic mucosa of rats fed tallow compared with soybean oil. Fecal bile acid concentrations were significantly lower in rats fed tallow compared with soybean oil. There were no significant differences in mucosal cell proliferation. No significant effects were found due to protein source or to interactions between fat and protein sources for ACF, cell proliferation labeling indexes, or bile acid concentrations. However, there was a significant protein by fat source interaction for the apoptotic labeling index. The decreased number of ACF, decreased fecal bile acid concentration, and increased mucosal apoptosis with tallow consumption are not consistent with a role for this fat in increasing risk of colon cancer.

Plasminogen enhances virulence of group A streptococci by streptokinase-dependent and streptokinase-independent mechanisms.

Interactions between host plasminogen (Plg) and streptokinase (SK) secreted by group A streptococci (GAS) have been hypothesized to promote bacterial invasion of tissues. The virulence of GAS strain UMAA2616, after being subcutaneously inoculated into mice, was studied. Skin lesions and mortality were observed after inoculation of 7x106 cfu. Coadministration of human Plg with UMAA2616 markedly increased virulence. SK-deficient UMAA2616 (UMAA2616-SK(-)) was generated. Mean skin-lesion area and mortality, after bacterial inoculation (3x105 cfu), were significantly greater with UMAA2616 in the presence of human Plg than with UMAA2616-SK(-) in the presence of human Plg (P=.0001). Human Plg also enhanced UMAA2616-SK(-) virulence. Exogenous human Plg enhanced the virulence of MGAS166, a human clinical isolate. These findings suggest that SK-Plg interactions are an important determinant of GAS invasiveness in vivo and that both SK and host Plg activators appear to promote virulence of GAS by catalyzing plasmin formation.