Project description:With advancing age, senescent cells accumulate as they are not efficiently cleared by the immune system anymore. Via a senescence-associated secretory phenotype, chronic senescent cells alter the microenvironment, creating an unfavorable milieu for neurogenesis and neurorepair. Using an innovative and rapid aging model, the African turquoise killifish, we have previously demonstrated a dramatic decline in neurogenic potential of non-glial progenitors with age. Even after traumatic brain injury, progenitor proliferation and neuron production was very low in aged killifish in comparison to young adult killifish, and overall neurorepair was incomplete. In the present study, we validated if the senolytic cocktail dasatinib and quercetin (D+Q) could reboot the neurogenic output by clearing chronic senescent cells from the aged killifish brain to re-create the necessary supportive environment. Our results confirm that the aged killifish telencephalon holds a very high senescent cell burden, which we could diminish by short-term systemic D+Q treatment. As a consequence of D+Q administration, proliferation of non-glial progenitors increased and more new neurons were generated and migrated into the parenchyma after injury. Injury-induced inflammation and glial scarring, a phenomenon only seen in aged killifish, remained unaltered. Senolytic treatment with D+Q might thus hold promise for improving brain function in aged populations, and is especially interesting for reviving the neurogenic potential of an already aged central nervous system.

Project description:Kidney is a vital organ responsible for homeostasis in the body. To retard kidney aging is of great importance for maintaining body health. Whereas the therapeutic strategies targeting against kidney aging are not elucidated. Recent studies show mitochondrial dysfunction is critical for renal tubular cell senescence and kidney aging, however, the underlying mechanisms of mitochondrial dysfunction in kidney aging have not been demonstrated. Herein, we found calcium overload, and the mitochondrial calcium uniporter (MCU) was induced in renal tubular cells and aged kidney. To activate MCU not only triggered mitochondrial calcium overload, but also induced reactive oxygen species (ROS) production and cellular senescence and age-related kidney fibrosis. Inversely, to block MCU or chelate calcium diminished ROS generation, restored mitochondrial homeostasis, and retarded cell senescence and protected against kidney aging. These results demonstrate MCU plays a key role in promote renal tubular cell senescence, which provides a new insight on the therapeutic strategy for fighting against kidney aging.

Project description:Hippocampal overexpression of FK506-binding protein 12.6/1b (FKBP1b), a negative regulator of ryanodine receptor Ca2+ release, reverses aging-induced memory impairment and neuronal Ca2+ dysregulation. Here, we test the hypothesis that FKBP1b also can protect downstream transcriptional networks from aging-induced dysregulation. We gave hippocampal microinjections of FKBP1b-expressing viral vector to male rats at either 13-months-of-age (long-term) or 19-months-of-age (short-term) and tested memory performance in the Morris water maze at 21-months-of-age. Aged rats treated short- or long-term with FKBP1b substantially outperformed age-matched vector controls and performed similarly to each other and young controls. Transcriptional profiling in the same animals identified 2342 genes whose hippocampal expression was up-/down-regulated in aged controls vs. young controls (the aging effect). Of these aging-dependent genes, 876 (37%) also showed altered expression in aged FKBP1b-treated rats compared to aged controls, with FKBP1b restoring expression of essentially all such genes (872/876, 99.5%) in the direction opposite the aging effect and closer to levels in young controls. This inverse relationship between the aging and FKBP1b effects suggests that the aging effects arise from FKBP1b deficiency. Functional category analysis revealed that genes downregulated with aging and restored by FKBP1b associated predominantly with diverse brain structure categories, including cytoskeleton, membrane channels and extracellular region. Conversely, genes upregulated with aging but not restored by FKBP1b associated primarily with glial-neuroinflammatory, ribosomal and lysosomal categories. Immunohistochemistry confirmed aging-induced rarefaction, and FKBP1b-mediated restoration, of neuronal microtubular structure. Thus, a previously-unrecognized genomic network modulating diverse brain structural processes is dysregulated by aging and restored by FKBP1b overexpression.

Project description:The plasminogen activator inhibitor-2 (PAI-2; encoded by the SerpinB2 gene) has been described in the context of macrophage activation and in cellular senescence. As both mechanisms are important in kidney disease we tested a possible role of PAI-2 in renal injury and repair. Methods:Aging, ischemia/reperfusion injury and unilateral ureteral obstruction were performed on the mice. Bone marrow was transplantefrom SerpinB2-/- to wild-type littermates and vice versa. Primary tubular cells and macrophages from SerpinB2-/- and wildtype mice were used for functional studies and transcriptional profiling. Results: PAI-2 expression was up-regulated in cultured senescent tubular cells and in kidneys of aged mice. In the lack of PAI-2 in SerpinB2-/- mice was associated with enhanced renal fibrosis and an inflammatory phenotype during aging and in kidney injury models. While acute injury was associated with fewer monocytes/macrophages in SerpinB2-/- kidneys the subsequent resolution of inflammation seen in wildtype kidneys was lacking in knockout mice. Conclusion: PAI-2 regulates renal aging, tubular damage, and resolution of inflammation. PAI-2 is crucial for kidney repair in mice .

Project description:Aging is a major risk factor for impaired cardiovascular health. The aging myocardium is characterized by microcirculatory and diastolic dysfunction and increased susceptibility to arrhythmias. Nerves align with vessels during development. However, the impact of aging on the cardiac neuro-vascular interface is entirely unknown. Here, we report that aging reduces nerve density specifically in the left ventricle and dysregulates vascular-derived neuro-regulatory genes. Aging leads to a down-regulation of miR-145 and de-repression of the neuro-repulsive factor Semaphorin-3A. miR-145 deletion, which increased Sema3a expression, or endothelial Sema3a overexpression reduced axon density, thus mimicking the observed aged heart phenotype. Removal of senescent cells, which accumulated with chronological age in parallel to the decline in nerve density, rescued age-induced denervation, reduced Sema3a expression, preserved heart rate variability and reduced electrical instability. These data suggest that senescence-associated regulation of neuro-regulatory genes is associated with reduced nerve density and, thereby, contributes to age-associated cardiac dysfunction.

Project description:Angiotensin receptor blockade (ARB) and sodium-glucose co-transporter 2 inhibitor (SGLT2i) have been used as the standard therapy for patients with diabetic kidney disease (DKD). However, how these two drugs possess additive renal protective effects remains unclear. Here, we conducted single cell RNA-sequencing to profile the kidney cell transcriptome of db/db mice treated with vehicle, ARB, SGLT2i, or both drugs and db/m mice. We identified 10 distinct clusters of kidney cells with predominant proximal tubular (PT) cells. We found that ARB has more anti-inflammatory and anti-fibrosis effects while SGLT2i affects more mitochondrial function. We also identified a new PT subcluster which was increased in DKD but reversed by treatments.This new subcluster was also confirmed by Immunostaining of mouse and human kidneys with DKD. Together, our study reveal kidney cell-specific gene signatures in response to ARB and SGLT2i and also identified a new PT subcluster which provides new insight into DKD.

Project description:Proteinuria is the most important predictor of outcome in glomerulonephritis and experimental data suggest that the tubular cell response to proteinuria is an important determinant of progressive fibrosis in the kidney. However, it is unclear whether proteinuria is a marker of disease severity or has a direct effect on tubular cells in the kidneys of patients with glomerulonephritis. Accordingly we studied an in vitro model of proteinuria, and identified 231 albumin-regulated genes differentially expressed by primary human kidney tubular epithelial cells exposed to albumin. We translated these findings to human disease by studying mRNA levels of these genes in the tubulo-interstitial compartment of kidney biopsies from patients with IgA nephropathy using microarrays. Biopsies from patients with IgAN (n=25) could be distinguished from those of control subjects (n=6) based solely upon the expression of these 231 albumin-regulated genes. The expression of an 11-transcript subset related to the degree of proteinuria, and this 11-mRNA subset was also sufficient to distinguish biopsies of subjects with IgAN from control biopsies. We tested if these findings could be extrapolated to other proteinuric diseases beyond IgAN and found that the all forms of primary glomerulonephritis (n=33) can be distinguished from controls (n=21) based solely on the expression levels of these 11 genes derived from our in vitro proteinuria model. Pathway analysis suggests common regulatory elements shared by these 11 transcripts. In conclusion, we have identified an albumin-regulated 11-gene signature shared between all forms of primary glomerulonephritis. Our findings support the hypothesis that albuminuria may directly promote injury in the tubulo-interstitial compartment of the kidney in patients with glomerulonephritis. We used microarrays to analyze the transcriptome of microdissected renal biopsies from patients with IgA nephropathy (IgAN) RNA from tubulointerstitial compartments was extracted and processed for hybridization on Affymetrix HG-U133A microarrays.

Project description:Proteinuria is the most important predictor of outcome in glomerulonephritis and experimental data suggest that the tubular cell response to proteinuria is an important determinant of progressive fibrosis in the kidney. However, it is unclear whether proteinuria is a marker of disease severity or has a direct effect on tubular cells in the kidneys of patients with glomerulonephritis. Accordingly we studied an in vitro model of proteinuria, and identified 231 albumin-regulated genes differentially expressed by primary human kidney tubular epithelial cells exposed to albumin. We translated these findings to human disease by studying mRNA levels of these genes in the tubulo-interstitial compartment of kidney biopsies from patients with IgA nephropathy using microarrays. Biopsies from patients with IgAN (n=25) could be distinguished from those of control subjects (n=6) based solely upon the expression of these 231 albumin-regulated genes. The expression of an 11-transcript subset related to the degree of proteinuria, and this 11-mRNA subset was also sufficient to distinguish biopsies of subjects with IgAN from control biopsies. We tested if these findings could be extrapolated to other proteinuric diseases beyond IgAN and found that the all forms of primary glomerulonephritis (n=33) can be distinguished from controls (n=21) based solely on the expression levels of these 11 genes derived from our in vitro proteinuria model. Pathway analysis suggests common regulatory elements shared by these 11 transcripts. In conclusion, we have identified an albumin-regulated 11-gene signature shared between all forms of primary glomerulonephritis. Our findings support the hypothesis that albuminuria may directly promote injury in the tubulo-interstitial compartment of the kidney in patients with glomerulonephritis. We used microarrays to analyze the transcriptome of microdissected renal biopsies from patients with IgA nephropathy (IgAN) RNA from tubulointerstitial compartments was extracted and processed for hybridization on Affymetrix HG-U133A microarrays.

Project description:Over-expression of human angiotensin-II receptor type1 (hAT1R) may cause pathological outcomes due to overactivation of renin-angiotensin system. Transgenic (TG) mice containing Hap-I (hypertensive genotype) of human hAT1R gene are more prone to develop metabolic syndrome disorders as compared to TG mice with Hap-II (normotensive genotype). This gene variant associated risk of hypertension together with Western diet and aging may lead to renal disorders. However, mechanisms underlying this process are not well examined. For this purpose, we studied the renal gene expression alterations in aged TG mice containing either Hap-I or Hap-II of hAT1R gene. Aged mice (20-24 months of age) were maintained on a regular diet or high fat diet with 2% NaCl (Western diet, WD) for 16 weeks. On a regular diet, aged Hap-I mice presented higher (~9 mmHg) systolic blood pressure with respect to age-matched Hap-II animals. Following administration of Western diet, blood pressure increased in both groups of mice, but to a larger extent in Hap-I animals (~15 mmHg in comparison to ~7 mmHg in Hap-II). Aged Hap-I mice on Western diet showed increased renal fibrosis. RNA-seq data from renal tissue of Hap-I aged mice revealed that WD significantly altered the expression of >400 genes (p-adj. <0.05). Bioinformatics analysis (Qiagen IPA software) identified major alterations in main canonical pathways involved in renal function and oxidative damage. These changes in turn resulted in kidney failure, renal tubular injury, and renal proliferation. In addition, post WD treatment, RNA seq. analysis from Hap-I and Hap-II kidneys also reveals haplotype specific regulation of genes associated with blood pressure regulation and kidney disorders. Overall, these results indicate that Western diet promotes hypertension and fibrosis in the kidneys of aged mice. These alterations are paralleled by perturbation of renal transcriptional profile. Overall, these studies will assist in the identification of novel mechanisms and molecules involved in hypertension and associated kidney pathophysiology.

Project description:Over-expression of human angiotensin-II receptor type1 (hAT1R) may cause pathological outcomes due to overactivation of renin-angiotensin system. Transgenic (TG) mice containing Hap-I (hypertensive genotype) of human hAT1R gene are more prone to develop metabolic syndrome disorders as compared to TG mice with Hap-II (normotensive genotype). This gene variant associated risk of hypertension together with Western diet and aging may lead to renal disorders. However, mechanisms underlying this process are not well examined. For this purpose, we studied the renal gene expression alterations in aged TG mice containing either Hap-I or Hap-II of hAT1R gene. Aged mice (20-24 months of age) were maintained on a regular diet or high fat diet with 2% NaCl (Western diet, WD) for 16 weeks. On a regular diet, aged Hap-I mice presented higher (~9 mmHg) systolic blood pressure with respect to age-matched Hap-II animals. Following administration of Western diet, blood pressure increased in both groups of mice, but to a larger extent in Hap-I animals (~15 mmHg in comparison to ~7 mmHg in Hap-II). Aged Hap-I mice on Western diet showed increased renal fibrosis. RNA-seq data from renal tissue of Hap-I aged mice revealed that WD significantly altered the expression of >400 genes (p-adj. <0.05). Bioinformatics analysis (Qiagen IPA software) identified major alterations in main canonical pathways involved in renal function and oxidative damage. These changes in turn resulted in kidney failure, renal tubular injury, and renal proliferation. In addition, post WD treatment, RNA seq. analysis from Hap-I and Hap-II kidneys also reveals haplotype specific regulation of genes associated with blood pressure regulation and kidney disorders. Overall, these results indicate that Western diet promotes hypertension and fibrosis in the kidneys of aged mice. These alterations are paralleled by perturbation of renal transcriptional profile. Overall, these studies will assist in the identification of novel mechanisms and molecules involved in hypertension and associated kidney pathophysiology.