Differences in initial rate of intracellular killing of Salmonella typhimurium by resident peritoneal macrophages from various mouse strains

To determine the underlining mechanism of the difference in innate susceptibility of mouse strains to infection by Salmonella typhimurium, the ingestion and in vitro intracellular killing of S. typhimurium by resident peritoneal macrophages of mouse strains that differ in natural resistance to this microorganism has been studied. The results revealed that the rate constants of in vitro phagocytosis (Kph) in the presence of inactivated rabbit immune serum did not differ between macrophages of susceptible C57BL/10 and resistant CBA mice (for both strains: Kph = 0.021 min-1). The rate constant of in vitro intracellular killing (Kk) was determined 1) after in vivo phagocytosis (CBA, Kk = 0.055 min-1; C57BL/10, Kk = 0.031 min-1), 2) after in vitro phagocytosis of preopsonized bacteria (CBA, Kk = 0.020 min-1; C57BL/10, Kk = 0.012 min-1), and 3) during continuous phagocytosis in vitro (CBA, Kk = 0.029 min-1; C57BL/10, Kk = 0.013 min-1). With all three approaches, the initial rate of intracellular killing by normal macrophages of Salmonella-resistant CBA mice amounted to about 1.7 times the value found for macrophages of susceptible C57BL/10 mice (p less than 0.01). This trait difference was independent of the previous way of ingestion of the bacteria, unaffected by the kind of opsonization, and specific for S. typhimurium, because Staphylococcus aureus and Listeria monocytogenes were killed by macrophages of these mouse strains with equal efficiency (p greater than 0.50). These findings indicate that a difference in genetic background expressed in the efficacy of intracellular killing by resident peritoneal macrophages immediately upon ingestion of S. typhimurium is relevant for the innate resistance of mice against S. typhimurium.     

Apoptosis and mammary gland involution: reviewing the process

Apoptosis is a process of programmed cell death. Mammary gland involution is a tissue remodelling process. Mammary epithelial cell apoptosis is an integral component of tissue remodelling but it is only one element. Equally important are the factors which degrade basement membrane and extracellular matrix. Both operations are required for completion of mammary gland involution. The primary apoptotic process occurs first and is temporally distinct from the second stage of involution typified by lobular-alveolar collapse. Local factors related to milk accumulation trigger the first stage, but loss of systemic hormonal stimulation governs the second stage. Changes in the expression patterns of cell cycle control genes and bcl-2 family member genes are found in the first stage. Proteinase gene activation dominates the second stage. These findings support a two stage model of mammary gland involution. Both mammary epithelial cell apoptosis and mammary gland remodelling advance through a process which includes both loss of survival factors and gain of death factors. This review focuses on signalling pathways and genetic controls which are activated and repressed during mammary gland involution.     

Tritium release from [19-3H]-19,19-difluoroandrost-4-ene-3,17-dione during inactivation of aromatase

Aromatase is a cytochrome P-450 enzyme involved in the conversion of androst-4-ene-3,17-dione to estrogen via sequential oxidations at the 19-methyl group. Previous studies from this laboratory showed that 19,19-difluoroandrost-4-ene-3,17-dione (5) is a mechanism-based inactivator of aromatase. The mechanism of inactivation was postulated to involve enzymic oxidation at, and hydrogen loss from, the 19-carbon. The deuteriated analogue 5b has now been synthesized and shown to inactivate aromatase at the same rate as the nondeuteriated parent (5). We conclude that C19-H bond cleavage is not the rate-limiting step in the overall inactivation process caused by 5. [19-3H]-19,19-Difluoroandrost-4-ene-3,17-dione (5b) with specific activity of 31 mCi/mmol was also synthesized to study the release of tritium into solution during the enzyme inactivation process. Incubation of [19-3H]19,19-difluoroandrost-4-ene-3,17-dione with human placental microsomal aromatase at differing protein concentrations resulted in time-dependent NADPH-dependent, and protein-dependent release of tritium. This tritium release is not observed in the presence of (19R)-10 beta-oxiranylestr-4-ene-3,17-dione, a powerful competitive inhibitor of aromatase. We conclude that aromatase attacks the 19-carbon of 19,19-difluoroandrost-4-ene-3,17-dione, as originally postulated.     

Stereoselective inhibition of human placental aromatase

We have synthesized the (19R)- and (19S)-isomers (2 and 3 respectively) of 10 beta-oxiranylestr-4-ene-3,17-dione. The configurations and conformations of these compounds were established by X-ray crystallographic analysis. Each of these compounds is a powerful competitive inhibitor of human placental microsomal aromatase, and stereoselectivity of inhibition was observed (Ki values for 2 and 3 were 7 and 75 nanomolar, respectively). Spectroscopic studies with purified aromatase indicate that the inhibition process involves reversible binding of oxirane oxygen to the heme iron of the enzyme. The (19R)- and (19S)-10 beta-thiiranes (6 and 7) corresponding to 2 and 3 have been synthesized from the oxiranes by a stereospecific process. The thiiranes are very effective competitive inhibitors of placental aromatase, and show even greater stereoselectivity in binding than the oxiranes (Ki values for 6 and 7 were 1 and 75 nanomolar, respectively). Spectroscopic studies with purified aromatase indicate that the inhibition process involves reversible binding of thiirane sulfur to heme iron.     

Abundant expression of ras proteins in Aplysia neurons

We have cloned a DNA fragment from the marine mollusc Aplysia californica, which contains sequences homologous to mammalian ras genes, by screening a genomic library with a viral Ha-ras oncogene probe under conditions of low stringency hybridization. Nucleotide sequencing revealed a putative exon that encodes amino acids sharing 68% homology with residues 5 to 54 of mammalian p21ras polypeptides, and which therefore is likely to encode a ras-like Aplysia protein. The cloned locus, designated Apl-ras, is distinct from the Aplysia rho (ras-homologue) gene and appears to be more closely related to mammalian ras. We used a panel of monoclonal antibodies raised against v-Ha-ras p21 to precipitate an Mr 21,000 protein from extracts of Aplysia nervous tissue, ovotestis, and, to a much lesser degree, buccal muscle. Fluorescence immunocytochemistry revealed that ras-like protein is most abundant in neuronal cell bodies and axon processes, with staining most prominent at plasma membranes. Much less was present in other tissues. The prominence of ras protein in neurons, which are terminally differentiated and non-proliferating, indicates that the control of cell division is not the sole function of this proto-oncogene. The large identified neurons of Aplysia offer the opportunity to examine how ras protein might function in mature nerve cells.     

Differences in initial rate of intracellular killing of Salmonella typhimurium by granulocytes of Salmonella-susceptible C57BL/10 mice and Salmonella-resistant CBA mice

The contribution of granulocytes to differences in the innate susceptibility of mouse strains to infection by Salmonella typhimurium was assessed on the basis of the size and composition of the inflammatory exudate after i.p. injection of bacteria and the intracellular killing of the bacteria by exudate peritoneal cells and blood granulocytes of resistant CBA and susceptible C57BL/10 mice. The increase in the numbers of both peritoneal granulocytes and macrophages 24 hr after i.p. injection of various numbers of live S. typhimurium was two to four times higher in C57BL/10 mice (p less than 0.05) than in CBA mice. However, despite the larger number of phagocytes in the inflammatory exudate, the numbers of viable S. typhimurium in the peritoneal cavity 24 hr after injection was higher (p less than 0.01) in C57BL/10 mice than in CBA mice. Because the proportion of noningested bacteria was similar in the two mouse strains (less than 30%), these findings indicate a difference in the rate of intracellular killing of the bacteria by exudate peritoneal cells (greater than 75% granulocytes) of the two mouse strains. Subsequent determination of the initial rate of intracellular killing (Kk) of S. typhimurium revealed that after phagocytosis of the bacteria in vivo, exudate peritoneal granulocytes (harvested 24 hr after i.p. injection of 10(3) live S. typhimurium) of CBA mice killed S. typhimurium twice as efficiently (Kk = 0.014 min-1; p less than 0.01) as exudate granulocytes of C57BL/10 mice (Kk = 0.008 min-1) did. Similarly, the initial rate of intracellular killing of the ingested S. typhimurium by blood granulocytes of CBA mice (Kk = 0.017 min-1) was two times higher (p less than 0.01) than that of C57BL/10 mice (Kk = 0.007 min-1). These findings may be specific for S. typhimurium, because L. monocytogenes were killed with equal efficiency by exudate granulocytes and blood granulocytes of these mouse strains (p greater than 0.20). The results of the present study are relevant with respect to the innate resistance of mice to S. typhimurium, particularly during the initial phase of infection when the inflammatory exudate contains predominantly granulocytes.