Seasonal changes in the physiology of male Virginia opossums (Didelphis virginiana): signs of the Dasyurid semelparity syndrome?

Semelparity, which is multiplying once in a lifetime, is a rare reproductive strategy among mammals. Several species of the marsupial family Dasyuridae experience 100% male mortality following an intense mating period. We investigated seasonal physiological changes that may be associated with early mortality in the male Virginia opossum (Didelphis virginiana; Didelphidae) and compared these changes with those of semelparous, male dasyurids. Free-ranging male Virginia opossums (n=36) were collected during 2001 at the Oklahoma State University Cross Timbers Experimental Range. Seasonal data were collected on hematological, morphological, and helminth parameters of these individuals. We used one-way ANOVA to determine whether there were seasonal differences among means for each parameter. It appeared that male Virginia opossums experienced some physiological changes similar to those of male dasyurids exhibiting semelparity. All males collected in summer (August) were juveniles of the year. Lack of adult males in August suggests high mortality of this cohort during the breeding season. Opossum characteristics exhibiting the dasyurid semelparity syndrome included packed cell volume, adrenal mass, and helminth numbers. Minor lymphocytopenia, neutrophilia, and testosterone concentrations also were similar to semelparous dasyurids. However, a lack of change in serum cortisol concentration and body mass and dynamics in immunoglobulin protein, serum protein, and testes mass were not consistent with previous reports of semelparous dasyurid physiology. Evolutionary divergence and differences in breeding behavior between dasyurids and didelphids may be responsible for the lack of consistency between the taxa.

The molecular effects of alcohol: clues to the enigmatic action of alcohol.

Chronic ethanol treatment (50 mM, five days) induces stabilization of NR1 receptor subunit mRNA in cultured fetal cortical neurons. In this paper, we investigate the mechanism(s) by which ethanol mediates its effects on NR1 mRNA. Specifically, we have determined if cellular localization of NR1 mRNA in cortical neurons and/or de novo protein synthesis is essential for ethanol-mediated stabilization of NR1 mRNA. Subcellular fractionation studies show that all detectable NR1 mRNA is associated with rough endoplasmic reticulum, indicating that subcellular distribution of NR1 mRNA in fetal cortical neurons does not play a role in ethanol-mediated NR1 mRNA stabilization. However, inhibition of protein synthesis by cycloheximide abolished the mRNA stabilizing effect of ethanol on NR1 mRNA, thus suggesting de novo protein synthesis is crucial for the action of ethanol on NR1 mRNA stabilization.