Faculty Bibliography

The reduction rate of nitroimidazole derivatives by pyruvate:ferredoxin oxidoreductase activity in ferredoxin depleted hydrogenosomal extracts of Trichomonas vaginalis depended on the one-electron midpoint potential (E7(1)) of 15 compounds out of the 16 tested. The results showed a linear correlation with a positive slope between the logarithm of the rate and the E7(1) in the range from -564 to -260 mV. Addition of T. vaginalis ferredoxin stimulated the reduction. The additional rate (stimulated rate minus basal rate) was proportional to the concentration of ferredoxin and independent of the E7(1) of the compounds. The compound with the most positive E7(1) (-243 mV) was, however, reduced more slowly than expected. These findings indicate that reduction in the presence of ferredoxin is the sum of two processes, i.e. electron transfer directly from pyruvate:ferredoxin oxidoreductase and from reduced ferredoxin generated by pyruvate:ferredoxin oxidoreductase activity. The relative role of ferredoxin in reductive activation of nitroimidazole derivatives is greater for compounds with more negative E7(1) values. This observation correlates with the high selectivity of the more negative 5-nitroimidazoles against anaerobic prokaryotic and eukaryotic microorganisms in which ferredoxin plays an important metabolic role.

We have studied the spontaneous killing of B5(59) melanoma cells by Bacillus Calmette-Guerin (BCG)-elicited macrophages under strictly anaerobic conditions to investigate the role of oxygen in macrophage-mediated cytotoxicity. The number of melanoma cells capable of forming colonies after aerobic or anaerobic incubation with BCG-macrophages was used as the index of cytotoxicity. The BCG-macrophages killed melanoma cells regardless of the amount of oxygen present. The killing observed was proportional to the ratio of effector cells added; a ratio of 25:1 effector to target cells was required to achieve nearly 90% cytotoxicity both aerobically and anaerobically. This cytotoxicity was not dependent on a diffusible macrophage product nor on alteration of the medium by macrophages, since tumor cells incubated in the same culture medium, but not in contact with a mixed population of tumor cells and macrophages, were not killed. These results also indicated that macrophage-mediated cytotoxicity was dependent on macrophage-tumor cell contact. The mechanism responsible for the oxygen-independent cytotoxicity is unknown at present.

Three Trichomonas vaginalis isolates with low in vivo susceptibilities to metronidazole (95% curative dose, greater than 3 X 100 mg kg-1 in subcutaneous infections in mice) were compared with strain ATCC 30001 and with four isolates exhibiting high in vivo susceptibilities (95% curative dose, less than 3 X 15 mg kg-1). Activity of pyruvate:ferredoxin oxidoreductase, anaerobic fermentation, and anaerobic intracellular accumulation of [14C]metronidazole label showed no significant isolate-dependent differences which could be correlated with drug susceptibility. The results suggest that processes providing electrons for metronidazole activation are not defective in the resistant strains. Aerobiosis, known to inhibit the antimicrobial action of metronidazole, inhibited accumulation of label more strongly in resistant isolates than in susceptible ones. No differences were detected, however, between resistant and susceptible isolates in respiration, aerobic fermentation, and the specific activity of NADH and NADPH oxidases, the main terminal oxidases of T. vaginalis. These findings suggest that the production of electrons is not diminished under aerobic conditions. The inhibitory effect of aerobic conditions on metronidazole activation, possibly due to competition for the electrons, is markedly enhanced in the resistant isolates compared to the susceptible ones. The mechanism of this effect, however, remains unknown.

A low molecular weight iron-sulfur protein has been purified from Tritrichomonas foetus by deoxycholate extraction of whole cells, ion exchange chromatography, and gel filtration. The purified protein was essentially homogeneous as judged by isoelectric focusing, polyacrylamide gel electrophoresis, and gel filtration. A pI of 4.3 was observed. The molecular weight of the protein was estimated to be 12,000. Chemical and spectral analysis showed the protein to have a [2Fe-2S] cluster. The absorbance spectrum of the oxidized protein showed maxima at 280, 340, 458 and shoulders at 410 and 550 nm. The maximum observed A458/A280 ratio was 0.82 and the absorbance of the oxidized protein at 458 nm was 8,000 M-1 X cm-1. The low temperature EPR spectrum of the protein reduced with dithionite revealed axial symmetry with features at g values of g = 1.94 and g = 2.02. The oxidized protein gave no EPR signal in the g = 1.8 to 2.2 range. Cell fractionation studies indicated the localization of this protein in the hydrogenosome. The protein was able to function as an electron transport component in the reduction of metronidazole (a 5-nitroimidazole derivative) by pyruvate:ferredoxin oxidoreductase and hydrogenase from T. foetus and also from Trichomonas vaginalis and Clostridium pasteurianum as well as in the reduction of cytochrome c by plant NADPH:ferredoxin oxidoreductase. This protein has the characteristics of a ferredoxin and is likely to be a physiological electron carrier in hydrogenosomal pyruvate oxidation.

An area of the hindgut of the cockroach, Eublaberus posticus, is characterized by its black color. This area is the site of accumulation of metal sulfides in the lumen next to the gut wall. In addition to the normal hindgut flora, two unusual procaryotic organisms are seen by both scanning and transmission electron microscopy only in this area of the hindgut. They are (i) a large rod (1.2 by 6 micrometers) with a tuft of polar flagella, many inclusion bodies, and a distinctive complex wall and (ii) an apparently flexible rod with a helically ridged wall. In addition, phagelike particles are described which are apparently infecting gram-positive bacteria attached to the gut wall in the black band area.

Cell extracts from fermentatively grown Rhodospirillum rubrum reduced about 80 nmol of nicotinamide adenine dinucleotide (NAD) per mg of protein per min under anaerobic conditions with sodium pyruvate. The reaction was specific for pyruvate and NAD; NAD phosphate was not reduced. Results indicated that pyruvate-linked NAD reduction occurred via pyruvate:lipoate oxidoreductase. The reaction required catalytic amounts of both coenzyme A and thiamine pyrophosphate. Addition of sodium arsenite inhibited enzyme activity by 90%. Pyruvate:lipoate oxidoreductase was the only system detected in anaerobic, dark-grown R. rubrum cell extracts which operated to produce reduced NAD. The low activity of the enzyme system suggested that it was not quantitatively important in ATP formation.

Rhodospirillum rubrum grew anaerobically in darkness and fermented sodium pyruvate by a pyruvate formate-lyase reaction. During 30 min of anaerobic dark or light incubation with sodium pyrivate, crude extracts from fermentatively grown cells produced about 6 micronmol of acetylphosphate and formate per mg of protein in reactions performed at pH 8.3. Cell extracts also catalyzed the exchange of sodium [14C]formate into sodium pyruvate at an apparent pH optimum of 7.3 to 7.5, but only about 2.5 micronmol of acetylphosphate was produced at this lower pH value. R. rubrum may also form pyruvate:ferredoxin oxidoreductase activity, as evidenced by low bicarbonate exchange activity. However, its participation in pyruvate metabolism in anaerobic dark-grown cells was not understood. During anaerobic, dark growth with pyruvate, formate was an intermediate in H2 and CO2 gas evolution. In contrast with H2 production by a light-dependent H2-nitrogenase system in photosynthetically grown cells, H2 formation in fermenting R. rubrum occurred through a carbon monoxide-sensitive formic hydrogenlyase reaction not influenced by light.