Probes for INS

Preterm birth results in low nephron endowment and increased risk of acute kidney injury (AKI) and chronic kidney disease (CKD). To understand the pathogenesis of AKI and CKD in preterm humans, we generated novel mouse models with a 30-70% reduction in nephron number by inhibiting or deleting Ret tyrosine kinase in the developing ureteric bud. These mice developed glomerular and tubular hypertrophy followed by the transition to CKD, recapitulating the renal pathological changes seen in humans born preterm. We injected neonatal mice with gentamicin, a ubiquitous nephrotoxic exposure in preterm infants, and detected more severe proximal tubular injury in mice with low nephron number compared to controls with normal nephron number. Mice with low nephron number have reduced proliferative repair with more rapid development of CKD. Furthermore, mice had more profound inflammation with highly elevated levels of MCP-1 and CXCL10, produced in part by damaged proximal tubules. Our study directly links low nephron endowment with postnatal renal hypertrophy, which in this model is maladaptive and results in CKD. Underdeveloped kidneys are more susceptible to gentamicin-induced AKI, suggesting that AKI in the setting of low nephron number is more severe and further increases the risk of CKD in this vulnerable population.

Objective The healthy alveolar epithelium is protected by a heparan sulfate rich, glycosaminoglycan layer called the epithelial glycocalyx. Our group found that the epithelial glycocalyx is shed in patients with acute respiratory distress syndrome (ARDS). In murine models of LPS- or bleomycin-induced acute lung injury, sheddases (membrane-bound enzymes that cleave extracellular potions of transmembrane proteins) are upregulated and associated with glycocalyx shedding and increased lung permeability. ARDS is commonly caused by viral infections including influenza A (IAV). In murine models, IAV causes massive and persistent glycocalyx shedding into the airspace but the mechanisms by which this occurs are unknown. The objective of this work is to determine the molecular processes underlying IAV-induced shedding of the glycocalyx. Hypothesis We hypothesize that IAV causes glycocalyx shedding through induction of host sheddases. Methods We examined the literature and curated a list of sheddases associated with IAV with potential to cleave the glycocalyx (MMP-7, -2, -9 and their inhibitors TIMP-1 and -2). C57BL/6 mice were infected intranasally with A/PR/8/34 (H1N1) at 30,000 PFU/mouse and bronchoalveolar lavage and lung tissue were collected at day 1, 3, and 7 post infection. Sheddase expression was assessed by RT-qPCR and RNAscope was used to localize lung sheddase expression in infected and uninfected lungs. MLE-12 mouse lung epithelial cells were infected with viable or heat-inactivated (56C for 30 min) A/PR/8/34 (H1N1) at a MOI of 1 and sheddase expression measured by RT-qPCR. Results Mice infected with IAV develop significant lung inflammation (increased BAL inflammatory cells), lung permeability (increased BAL protein), and increased glycocalyx shedding. MMP-7 is upregulated in infected vs. uninfected lungs at day 1 and 3 post infection, then returns to baseline levels by day 7. MMP-7 is only expressed in cells that are directly infected by IAV. Expression of the MMP-7 inhibitor TIMP-1 is similar to uninfected lungs on day 1, but increases 50-fold on day 3. In contrast, MMP-2 and MMP-9, as well as their inhibitor TIMP-2 are not upregulated in the first 7 days after IAV infection. Preliminary studies in lung epithelial cells suggest that heat-inactivated IAV fails to upregulate MMP-7. Conclusions Together, these data suggest that localized IAV infection increases MMP-7 in a murine model of IAV infection, but has no effect on several other sheddases. This suggests that MMP-7 may modulate IAV-induced glycocalyx shedding. Future studies will explore the mechanisms of IAV induced glycocalyx shedding which could provide molecular targets for clinical intervention in IAV-ARDS pathogenesis.

The molecular diversity of glia in the human hippocampus and their temporal dynamics over the lifespan remain largely unknown. Here, we performed single-nucleus RNA sequencing to generate a transcriptome atlas of the human hippocampus across the postnatal lifespan. Detailed analyses of astrocytes, oligodendrocyte lineages, and microglia identified subpopulations with distinct molecular signatures and revealed their association with specific physiological functions, age-dependent changes in abundance, and disease relevance. We further characterized spatiotemporal heterogeneity of GFAP-enriched astrocyte subpopulations in the hippocampal formation using immunohistology. Leveraging glial subpopulation classifications as a reference map, we revealed the diversity of glia differentiated from human pluripotent stem cells and identified dysregulated genes and pathological processes in specific glial subpopulations in Alzheimer's disease (AD). Together, our study significantly extends our understanding of human glial diversity, population dynamics across the postnatal lifespan, and dysregulation in AD and provides a reference atlas for stem-cell-based glial differentiation.

Acute kidney injury (AKI), commonly caused by ischemia, sepsis, or nephrotoxic insult, is associated with increased mortality and a heightened risk of chronic kidney disease (CKD). AKI results in the dysfunction or death of proximal tubule cells (PTCs), triggering a poorly understood autologous cellular repair program. Defective repair associates with a long-term transition to CKD. We performed a mild-to-moderate ischemia-reperfusion injury (IRI) to model injury responses reflective of kidney injury in a variety of clinical settings, including kidney transplant surgery. Single-nucleus RNA sequencing of genetically labeled injured PTCs at 7-d ("early") and 28-d ("late") time points post-IRI identified specific gene and pathway activity in the injury-repair transition. In particular, we identified Vcam1 +/Ccl2 + PTCs at a late injury stage distinguished by marked activation of NF-κB-, TNF-, and AP-1-signaling pathways. This population of PTCs showed features of a senescence-associated secretory phenotype but did not exhibit G2/M cell cycle arrest, distinct from other reports of maladaptive PTCs following kidney injury. Fate-mapping experiments identified spatially and temporally distinct origins for these cells. At the cortico-medullary boundary (CMB), where injury initiates, the majority of Vcam1 +/Ccl2 + PTCs arose from early replicating PTCs. In contrast, in cortical regions, only a subset of Vcam1 +/Ccl2 + PTCs could be traced to early repairing cells, suggesting late-arising sites of secondary PTC injury. Together, these data indicate even moderate IRI is associated with a lasting injury, which spreads from the CMB to cortical regions. Remaining failed-repair PTCs are likely triggers for chronic disease progression.