Periodic Reporting for period 4 - RENOIR (RENal prOgenItoRs as tools to understand kidney pathophysiology and treat kidney disorders)
Okres sprawozdawczy: 2020-01-01 do 2020-06-30
Moreover, we demonstrated that CXCL12 blockade increased podocyte numbers and attenuated proteinuria enhancing de novo podocyte formation from RPC.
2. We established the role of RPC in tubular injury. We developed inducible transgenic mouse models to track RPC and all tubular cells and analyze their proliferative capacity. Using these models we demonstrated that following AKI tubular regeneration is only provided by RPC, while differentiated tubular cells can only undergo hypertrophy, which would explain why functional recovery after AKI could be fast, but the risk for progressive CKD is high if many nephrons are lost.
3. We established the role of abnormal RPC function in the pathogenesis of renal cell carcinomas (RCC). We developed new transgenic mouse models to evaluate the contribution of differentiated tubular cells and of tubular progenitor cells with abnormal activation of Notch pathway to the development of RCC. Our data support the notion that hyperactivation of Notch pathway in differentiated tubular cells led to the formation of a broad spectrum of lesions of proliferative and not-proliferative nature and highlight the role of tubular progenitor cells in the formation of RCC.
4. We provided the proof of concept for the use of urine-derived RPC for personalized kidney medicine. We have started to apply exome sequencing and filtering for all known genes causative of steroid-resistant nephrotic syndrome together with personalized disease modeling using cultures of human renal progenitors derived from the patient following the protocol previously patented and published. During this period, we provided evidence that this method helps clinical diagnosis of kidney disorders and proof of concept was provided in a young girl affected by Lupus Nephritis refractory to every immunosuppressive treatment.
2. The discovery that RPC are the drivers of repair also after tubular regeneration challenges the current knowledge about acute kidney injury (AKI). Indeed, currently AKI is considered largely reversible based on the capacity of surviving tubular cells to dedifferentiate and to replace lost cells via cell division. However, we showed that AKI causes substantial tubular cell loss despite renal function recovery, that tubular cell proliferation is erroneously indicated by proliferation markers unable to ultimately identify cell division and that endocycle-mediated hypertrophy of tubular cells is the main cellular response upon AKI. By contrast, tubular progenitors got enriched via higher stress resistance and clonal expansion, regenerating tubule segments. Treatment with drugs that enhance tubular regeneration confirmed that this occurred only through progenitor mitosis. These results disprove current paradigms and demonstrate that, although a limited regeneration occurs through tubular progenitor proliferation, endocycle-mediated hypertrophy and persistent tubular cell loss are the dominant features after AKI. This change of paradigm also opens to the possibility of new strategies of treatment for AKI.
3. The observation that Notch overexpression causes different types of renal cell carcinoma in addition to chronic kidney disease (CKD), provides an explanation of the link among CKD and cancer and suggests the innovative idea that tubular progenitors are the cells of origin of at least some types of kidney cancers.
4. The successful use of urinary RPC cultures to support diagnosis of of a genetic podocytopathy in a patient affected by Lupus Nephritis resistant to immunosuppressive treatment provides the proof of concept that this technique can be successfully used in clinical practice and extremely useful to establish the correct diagnosis in difficult cases.