Cosmic kidney disease: an integrated pan-omic, physiological and morphological study into spaceflight-induced renal dysfunction.

Missions into Deep Space are planned this decade. Yet the health consequences of exposure to microgravity and galactic cosmic radiation (GCR) over years-long missions on indispensable visceral organs such as the kidney are largely unexplored. We performed biomolecular (epigenomic, transcriptomic, proteomic, epiproteomic, metabolomic, metagenomic), clinical chemistry (electrolytes, endocrinology, biochemistry) and morphometry (histology, 3D imaging, miRNA-ISH, tissue weights) analyses using samples and datasets available from 11 spaceflight-exposed mouse and 5 human, 1 simulated microgravity rat and 4 simulated GCR-exposed mouse missions. We found that spaceflight induces: 1) renal transporter dephosphorylation which may indicate astronauts' increased risk of nephrolithiasis is in part a primary renal phenomenon rather than solely a secondary consequence of bone loss; 2) remodelling of the nephron that results in expansion of distal convoluted tubule size but loss of overall tubule density; 3) renal damage and dysfunction when exposed to a Mars roundtrip dose-equivalent of simulated GCR.

Female and male microglia are not different in the dentate gyrus of postnatal day 10 mice.

Microglia, the resident immune cells of the brain, support normal brain function and the brain's response to disease and injury. The hippocampal dentate gyrus (DG) is important for microglial study due to its central role in many behavioral and cognitive functions. Interestingly, microglia and related cells are distinct in female vs. male rodents, even in early life. Indeed, postnatal day (P)-dependent sex differences in number, density, and morphology of microglia have been reported in certain hippocampal subregions at specific ages. However, sex differences in the DG have not yet been assessed at P10, a translationally relevant time point as the rodent neuroanatomical eqivalent of human term gestation. To address this knowledge gap, Iba1+ cells in the DG (which are enriched in the Hilus and Molecular Layer) in female and male C57BL/6J mice were analyzed for their number (via stereology) and density (via stereology and via sampling). Next, Iba1+ cells were classified into morphology categories previously established in the literature. Finally, the percent of Iba1+ cells in each morphology category was multiplied by total cell number to generate a total number of Iba1+ cells in each category. Results show no sex difference in Iba1+ cell number, density, or morphology in the P10 Hilus or Molecular Layer. The lack of sex difference in Iba1+ cells in P10 DG using commonly-employed methodologies (sampling, stereology, morphology classification) provides a baseline from which to interpret microglia changes seen after injury.

Contextual processing elicits sex differences in dorsal hippocampus activation following footshock and context fear retrieval.

Establishing a contextual representation of an environment places specific spatial-temporal processing demands on the mammalian hippocampus, a region showing sex-differences in processing capabilities. However, evidence for sex differences in these processing demands during contextual fear learning remains limited. Here, we examined the relationship among contextual processing, timing of footshock, and activation of the dorsal hippocampus and basolateral amygdalar nuclei (BLA) in male and female mice (C57Bl/6 J). We modified the initial exposure time to the conditioning context prior to administration, or not, of a single footshock. We then quantified Fos- ir neurons activated by acquisition or retrieval of contextual fear memories in the rostral half of the dorsal CA1 (proximal - distal regions), CA3, Dentate Gyrus and basolateral amygdalar nuclei corresponding to atlas levels of the Allen Reference Atlas. In experiment 1, we found that sex differences in context elicited freezing were evident at the longest context placement-to-shock interval and that context fear retrieval with increasing contextual exposure periods increased CA1 Fos-ir in males, but not females. In experiment 2, we observed that an aversive footshock in males potentiated CA1 activation, while it downregulated CA1 activation in females. We also found that an aversive footshock independent of sex moderated Dentate Gyrus activation that normally showed increased activation with greater context exposure periods. Lastly, we identified a heightened responsiveness in BLA neurons to both footshock and length of context exposure in females compared to males. Overall, our findings suggest that sex differences in contextual fear conditioning may arise from marked sex differences in the contextual processing demands of the dorsal hippocampus subfields largely modulated by aversive outcomes.