Project description:Female sex protects against development of acute kidney injury (AKI). While sex hormones may be involved in protection, the role of differential gene expression is unknown. We conducted gene profiling in male and female mice with or without kidney ischemia-reperfusion injury. Mice underwent bilateral renal pedicle clamping (30 min), and tissues were collected 24 hours after reperfusion. RNA-sequencing was performed on proximal tubules and kidney endothelial cells. Female mice were resistant to ischemic injury compared to males, determined by plasma creatinine, histologic scores, neutrophil infiltration, and extent of apoptosis. Sham mice had sex-specific gene disparities in proximal tubule and endothelium, and male mice showed profound gene dysregulation with ischemia-reperfusion compared to females. After ischemia proximal tubules from females exhibited smaller increases compared to males in injury-associated genes Lcn2, Havcr1, and Krt18, and no upregulation of Sox9 or Krt20. Endothelial upregulation of adhesion molecules and cytokines/chemokines occurred in males, but not females. Upregulated genes in male ischemic proximal tubules were linked to tumor necrosis factor and Toll-like receptor pathways, while female ischemic proximal tubules showed upregulated genes in pathways related to transport. The data suggest that sex-specific gene expression profiles in male and female proximal tubule and endothelium may underlie disparities in susceptibility to AKI.

Project description:We combined lineage tracing of cycling (Ki67+) cells with single nuclear multiomics (single nucleus RNA-seq + single nucleus ATAC-seq) to characterize the long-term (4 weeks and 6 months) outcome of cells that initiate proliferation early after acute kidney injury (AKI). The data document a broad proliferative response to injury in epithelial and non-epithelial kidney cell types, identify novel transcription factors governing the adaptive and maladaptive proximal tubule cell state and highlight the importance of enhancer dynamics in determining cell states. Comparison of lineage traced with control proximal tubule cells reveals long-term effects of AKI on proximal tubule cells, even following adaptive repair.

Project description:To clarify the effects of cisplatin (cis-diamminedichloroplatinum II, CDDP) on the gene expression profiles in renal proximal tubules, microarray analyses were carried out using total RNA samples isolated from microdissected proximal tubules and whole kidneys. The molecular events underlying acute kidney injury (AKI) in the proximal tubules of rats with cisplatin-induced nephrotoxicity were successfully clarified with 17,000 transcripts. Renal proximal tubules were isolated under microscopy, and transcriptome data were collected with Rat Genome Survey Microarray® (Applied Biosystems)

Project description:COVID-19 associated acute kidney injury (COVID-AKI) is a common complication of SARS-CoV-2 infection in hospitalized patients. It is unclear how susceptible human kidneys are to direct SARS-CoV-2 infection and whether pharmacologic manipulation of the renin-angiotensin II signaling (RAS) pathway modulates this susceptibility. Using induced pluripotent stem cell derived kidney organoids, SARS-CoV-1, SARS-CoV-2 and MERS-CoV tropism, defined by the paired expression of a host receptor (ACE2, NRP1 or DPP4) and protease (TMPRSS2, TMPRSS4, FURIN, CTSB or CTSL), was identified primarily amongst proximal tubule cells. Losartan, an angiotensin II receptor blocker being tested in COVID-19 patients, inhibited angiotensin II mediated internalization of ACE2, upregulated interferon stimulated genes (IFITM1 and BST2) known to restrict viral entry, and attenuated the infection of proximal tubule cells by SARS-CoV-2. Our work highlights the susceptibility of proximal tubule cells to SARS-CoV-2 and reveals a putative protective role for RAS inhibitors during SARS-CoV-2 infection.

Project description:The kidney plays a critical role in fluid homeostasis, glucose control, and drug excretion. Loss of kidney function due to drug-induced nephrotoxicity affects over 20% of the adult population. The kidney proximal tubule is a complex vascularized structure that particularly vulnerable to drug-induced nephrotoxicity. Here we introduce a model of vascularized human kidney organoids with integrated tissue embedded micro-sensors for oxygen, glucose, lactate and glutamine, providing real time assessment of cellular metabolism. Our model shows that both the immunosuppressive drug cyclosporin (Neoral®) and the anti-cancer drug cisplatin (Platinol®) disrupt proximal tubule polarity at sub-toxic concentrations, leading to glucose accumulation and lipotoxicity. Impeding glucose reabsorption using glucose transport inhibitors blocked cyclosporin and cisplatin toxicity by 1,000 to 10-folds, respectively. Retrospective study of 247 patients receiving cyclosporin or cisplatin in combination with the SGLT-2 inhibitor gliflozin showed significant reduction in creatinine and uric acid recognized markers of kidney damage. These results demonstrate the potential of sensor-integrated organoid-on-chip platforms to elucidate new mechanisms of action and rapidly reformulate effective therapeutic solutions, increasing drug safety and reducing the cost of clinical and commercial failures.

Project description:To clarify the effects of cisplatin (cis-diamminedichloroplatinum II, CDDP) on the gene expression profiles in renal proximal tubules, microarray analyses were carried out using total RNA samples isolated from microdissected proximal tubules and whole kidneys. The molecular events underlying acute kidney injury (AKI) in the proximal tubules of rats with cisplatin-induced nephrotoxicity were successfully clarified with 17,000 transcripts.

Project description:Acute kidney injury (AKI) is a major health care concern. There are no therapies for the treatment of AKI. The primary site of damage during AKI is the proximal tubule, which are highly metabolically active cells that rely upon fatty acids for energy. Proximal tubules are notably mitochondria- and peroxisomes-rich cell type that mediate fatty acid oxidation (FAO). Sirtuins reverse post-translational lysine acylation and control many biological processes including FAO. Sirtuin1 and sirtuin3 are protective against AKI. However, the role of the mitochondrial Sirtuin5 (Sirt5) during AKI has yet to be determined. We found Sirt5 to be highly expressed in the proximal tubule. At baseline Sirtuin5 knockout (Sirt5-/-) animals had modestly decreased mitochondrial function but significantly increased FAO, which was localized to the peroxisome. While no overt kidney phenotype was observed in SIRT5-/- mice, following ischemia reperfusion injury Sirt5-/- animals had significantly improved kidney function and less tissue damage. This coincided with increased peroxisomal activity in the Sirt5-/- proximal tubules in preference to the mitochondria. Here we have identified a novel mechanism driving protection of kidneys from ischemic injury. If this can be harnessed it may prove to be an effective therapeutic.

Project description:Acute kidney injury and nephrotoxicity are important clinical side effects of cisplatin. Thus, the mechanisms of this disease, and potential treatment options are important to understand in their entity. Here, we analyzed the proteome of cisplatin induced acute kidney injury in a mouse model. Functionally we found that calorie restriction was able to completely blunt Cisplatin induced AKI, and hypoxia ameliorated cCisplatin induced AKI. To investigate the mechanism for this in high throughput, we performed label-free single-shot proteomic analyses of these kidneys.Acute kidney injury and nephrotoxicity are important clinical side effects of cisplatin. Thus, the mechanisms of this disease, and potential treatment options are important to understand in their entity. Here, we analyzed the proteome of cisplatin induced acute kidney injury in a mouse model. Functionally we found that calorie restriction was able to completely blunt Cisplatin induced AKI, and hypoxia ameliorated cCisplatin induced AKI. To investigate the mechanism for this in high throughput, we performed label-free single-shot proteomic analyses of these kidneys.

Project description:After acute kidney injury (AKI), patients either recover or alternatively develop fibrosis and chronic kidney disease. Interactions between injured epithelia, stroma and inflammatory cells determine whether kidneys repair or undergo fibrosis, but the molecular events that drive these processes are poorly understood. Here, we use single nucleus RNA sequencing of a mouse model of AKI to characterize cell states during repair from acute injury. We identify a distinct proinflammatory and profibrotic proximal tubule cell state that fails to repair. Deconvolution of bulk RNA-seq datasets indicates that this “failed-repair proximal tubule cell” or FR-PTC, state can be detected in other models of kidney injury, increasing in the aging rat kidney and over time in human kidney allografts. We also describe dynamic intercellular communication networks and discern transcriptional pathways driving successful vs. failed repair. Our study provides a detailed description of cellular responses after injury and suggests that the FR-PTC state may represent a therapeutic target to improve repair.

Project description:Far infrared radiation (FIR), a subdivision of the electromagnetic spectrum, has been proved to be beneficial for long-term effects of tissue healing, anti-inflammation, promoting growth, modulating sleep, acceleration of microcirculation, and pain relief. We attempt to study whether FIR would be beneficial for renal proximal tubule cell (RPTC) cultivation and renal tissue engineering. We observed the FIR effects on RPTCs, including cell viability, functional characteristics, immunofluorescence presentations, and subcellular findings. And the FIR protective effects would be further examined with HK-2 cell (Human proximal tubule cell line) against cisplatin, a nephrotoxic agent. Our study showed that daily exposure to FIR for 30 minutes could significantly increase rabbit RPTC viability in vitro assessed by MTT assay. FIR is not only beneficial in RPTC cell viability. RPTCs with FIR exposure presented higher expression of Na-K ATPase and GLUT1 (Glucose Transporter 1). The finding was documented with western blot analysis with statistical significance. With Q-PCR, CDK5R1, GNAS, NPPB, and TEK expressions were significantly enhanced. With HK-2 cell, the proximal tubule cell line, FIR had protective effects against cisplatin nephrotoxicity through reducing apoptosis. FIR is a potential photomodulation therapy to facilitate RPTC cultivation with higher cell viability and better functional chanacteristics and would possibly be applied in further nephrotoxicity protection and other cisplatin-sensitive cell protection.