Detection of N-(3-oxohexanoyl)-L-homoserine lactone in mice infected with Yersinia enterocolitica serotype O8

Yersinia enterocolitica synthesizes N-acyl-L-homoserine lactone (AHL) signal molecules via the LuxR-LuxI homologues YenR-YenI. In this study we checked two prototypes of mouse-virulent Y. enterocolitica serotype O8 strains WA-314 and 8081 for AHL production in vitro and in vivo (mouse infection model). We used thin-layer chromatography in combination with the Escherichia coli AHL biosensor to identify the AHL species produced. We detected only OHHL [N-(3-oxohexanoyl)-L-homoserine lactone] and not HHL (N-hexanoyl-L-homoserine lactone) produced by Y. enterocolitica O8 in culture supernatant or infected mouse tissue. This is the first report demonstrating AHL production by yersiniae during infection.     

Effect of two complex platinum salts on human sperm motility and acrosome reaction

Hydrogen hexachloroplatinate, H2PtCl6, has been shown to induce the human sperm acrosome reaction in vitro. However, the molecular mechanism underlying this exocytic process has not been studied. Therefore, two structurally and chemically different platinum (Pt) compounds, the potent sensitizer sodium-hexachloro-platinate-(IV), Na2[PtCl6], and the nonimmunogenic tetraamineplatinum-(II)-chloride, [Pt(NH3)4]Cl2, were selected for the experiments. Their effects on human sperm function and second messenger pathways were investigated. Washed human spermatozoa were treated with different concentrations of both Pt salts (0.5-1000 microM) during or after capacitation for 3 h at 37 degrees C. In addition, spermatozoa were incubated with Pt salts in calcium-free medium or in the presence of the protein kinase A+C inhibitor H7. Sperm motility was evaluated by computer-assisted sperm analysis; acrosomal loss was detected by triple staining. Compared with the controls (6.6+/-2.4%), the percentages of living acrosome-reacted spermatozoa showed a significant dose-dependent increase (P<0.001) after 3 h of incubation with Na2[PtCl6] (7.9+/-4.2% for 0.5 microM 25.0+/-2.9% for 1 mM) and [Pt(NH3)4]Cl2 (7.9+/-3.9% to 21.0+/-5.8%). Sperm motility was markedly reduced in samples containing the highest concentrations of the Pt salts. The acrosome reaction was also significantly increased when spermatozoa had first been capacitated and then treated with both Pt salts. Calcium-free medium had no effect on the ability of both Pt salts to induce the acrosome reaction. However, incubation of Na2[PtCl6] in the presence of H7 tendentiously decreased the percentage of acrosome-reacted spermatozoa. In conclusion, complex Pt salts such as Na2[PtCl6] or [Pt(NH3)4]Cl2 influence human sperm functions by inducing the acrosome reaction during or after capacitation. This stimulatory effect is independent of calcium and seems to be dependent on protein kinase A or C.     

Nylon-fiber-induced neutrophil fragmentation

We have investigated the effects of mechanical elution of neutrophils from nylon-wool fiber (NWF) using the scanning electron microscope and biochemical analysis of elution fractions. We have determined that mechanical removal of neutrophils from nylon-wool fiber disrupts neutrophils adherent to nylon-wool fiber and augments release of granules, release of peripheral cytoplasmic fragments, and release of lactic dehydrogenase, a soluble cytoplasmic enzyme. Mechanical shearing of the adherent cell, and not adherence per se, causes the fragmentation. The extent of fragmentation is proportional to the NWF surface area available to neutrophils and is maximal at the temperature for optimal adherence and spreading. Agents that decrease cell spreading (n-ethylmaleimide and cold) diminish fragmentation. Cytochalasin B, an agent that destabilizes the neutrophil cortex, increases fragmentation. Fragmentation may be an important contributing cause of the abnormal morphology, function, and in vivo survival of nylon-wool-fiber procured human neutrophils. The prevention of fragmentation would appear to be necessary to insure the procurement of optimally functioning cells. Elution of NWF-adherent neutrophils in the cold might be a practical way to diminish neutrophil damage during clinical filtration leukapheresis.