Mutagenicity of wood smoke condensates in the Salmonella/microsome assay

Smoke condensates of woods used for food preservation and aromatization in Nigeria were tested for mutagenic activity using Salmonella typhimurium TA98 and TA100. The woods were: white mangrove (Avicennia nitida), red mangrove (Rhizophora racemosa), mahogany Khaya sp.), abura (Mitragyna ciliata), alstonia (Alstonia boonei) and black afara (Terminalia ivorensis). Cigarette tar was tested for comparison. The condensates induced dose-dependent increases in the number of His+ revertants mainly with S9 mix. With the exception of mahogany and cigarette smoke condensate, the smoke condensates induced more revertants/microgram condensate in TA100 than in TA98. The number of revertants/microgram condensate ranged between 0.04 and 0.9 for the wood smoke condensates and was 0.12 for the cigarette smoke in TA100. The range was between 0.1 and 0.30 for the wood smoke condensates and 0.18 revertants/microgram condensate for cigarette smoke condensate in TA98. Concentrations of 7 polycyclic aromatic hydrocarbons (PAHs) in the condensates were determined namely, pyrene, benzo[a]pyrene, benz[a]anthracene, benzo[k]fluoranthene, benzo[b]chrysene, benzo[g,h,i]perylene and dibenzo[a,e]pyrene. The condensates contained varying concentrations of the individual PAHs and those with higher concentrations generally showed greater mutagenic activities. However, the order of mutagenic potency in the bacterial strains differed from the order of PAH concentrations, which were lower than the concentrations at which they are reported to induce mutations. When 6 of the PAHs were mixed in the concentrations in which they were found in the individual condensates, the mixtures did not induce mutation so that the contribution of the PAHs to the mutagenic activities of the condensates could not be determined.     

Ultrastructure of cyclic changes in the murine uterus,cervix, and vagina

The regional and cyclic changes in the murine genital epithelium were studied by transmission and scanning electron microscopy to provide a morphological standard to serve as a basis for investigation of host-parasite relationships in genital infections. Thus, we examined not only mucosal epithelial cell changes, but also surface mucus, normal flora and inflammatory cells. Ultrastructurally, at proestrus/estrus, we found uterine and most cervical epithelial cells covered with microvilli overlaid with mucus-like secretions and evidence of internal secretory activity. There was little normal flora anywhere in the tract. At early metestrus, we found squamous cervicovaginal epithelial cells with low discontinuous microrugae, extensive normal flora and many neutrophils beginning to migrate through the epithelium. The flora and neutrophils could explain the relative lack of susceptibility to infection at that time. At diestrus the appearance of a newly regenerated epithelium and lack of normal flora suggested that initiation of infection could occur at this stage; however, the presence of large numbers of neutrophils ready to phagocytize invading bacteria indicated a deterrent to infection. This study of cyclic changes in flora, mucus, neutrophils and epithelial cells provided ultrastructural evidence to support an earlier hypothesis that the greatest susceptibility to gonococcal infection in mice occurred at proestrus/estrus.     

Structure of a viral DNA gatekeeper at 10 A resolution by cryo-electron microscopy

In tailed bacteriophages and herpes viruses, the viral DNA is packaged through the portal protein channel. Channel closure is essential to prevent DNA release after packaging. Here we present the connector structure from bacteriophage SPP1 using cryo-electron microscopy and single particle analysis. The multiprotein complex comprises the portal protein gp6 and the head completion proteins gp15 and gp16. Although we show that gp6 in the connector has a fold similar to that of the isolated portal protein, we observe conformational changes in the region of gp6 exposed to the DNA-packaging ATPase and to gp15. This reorganization does not cause closure of the channel. The connector channel traverses the full height of gp6 and gp15, but it is closed by gp16 at the bottom of the complex. Gp16 acts as a valve whose closure prevents DNA leakage, while its opening is required for DNA release upon interaction of the virus with its host.