Project description:Fibroblast growth factor-23 (FGF23), a circulating protein produced in bone, causes renal inorganic phosphate (Pi) wasting by down-regulation of sodium phosphate co-transporter 2a (Npt2a). The mechanism behind this action is unknown. We have previously generated transgenic mice (TG) expressing human wild-type FGF23 under the control of the α1 (I) collagen promoter. In this study we performed a large scale gene expression study of kidneys from TG mice and wild-type littermates. Several genes that play a role in Pi regulation had decreased expression levels, such as Npt2a, but also Pdzk1 which is a scaffolding protein known to interact with NPT2a. Importantly, the Klotho gene, a suggested crucial co-factor for FGF23 receptor binding and activation, was the most affected decreased gene. However, other genes proposed to regulate Pi levels, such as secreted Frizzled Related Protein 4 (sFRP4), Na+/H+ exchanger regulatory factor 1 (NHERF1) and the FGF-receptors 1-4, revealed no changes. Interestingly, expression levels of inflammatory response genes were increased and histological analysis revealed tubular nephropathy in the TG mice kidneys. In conclusion, FGF23 TG mice have altered kidney gene expression levels of several genes thought to be part of Pi homeostasis and an increase in inflammatory response genes, data supported by histological analysis. These findings may lead to further understanding of how FGF23 mediates its actions on renal Pi regulation. Keywords: Genetic Modification

Project description:Tight control of both extracellular and intracellular inorganic phosphate (Pi) levels is critical to the normal functioning of virtually all biochemical and physiological processes. The kidney participates in Pi homeostasis by controlling Pi reabsorption from the primary urine. Pi is freely filtered at the kidney glomerulus and is reabsorbed in the renal tubule by the action of the apical sodium-dependent phosphate transporters NaPi-IIa/NaPi-IIc/Pit2. The molecular identity of transporter(s) involved in the basolateral Pi efflux remains unknown. Recent evidence has suggested that the retroviral receptor XPR1 might be a candidate for this role. Here we show that conditional inactivation of Xpr1 in the renal tubule in mice results in impaired renal Pi reabsorption associated with a generalized proximal tubular dysfunction, or Fanconi syndrome, characterized by glycosuria, aminoaciduria, calciuria and albuminuria. Bone histomorphometry showed that the Xpr1-deficient mice develop hypophosphatemic osteomalacia secondary to the renal dysfunction. The analysis of Pi transport in primary culture of the proximal tubular cells revealed that the Pi efflux was significantly affected in cells devoid of Xpr1. These results identify XPR1 as a major player in Pi homeostasis and as a potential therapeutic target in bone and kidney disorders.

Project description:The renal adaptation to changing dietary phosphate levels is not well understood. The dominant Hyp mutation of the Phex gene in mice causes X-linked hypophosphatemia with low renal retention of phosphate and blocks physiologic adaptation to low phosphate diets. At P < 0.01, there were 1,711 transcripts significantly affected by genotype, 1,428 by diet and 5,601 by sex. Many renal transporters other than phosphate, as well as many novel transcripts of unknown function, were affected by the Hyp mutation. Some genes for fat metabolism and inflammation were up-regulated in Hyp kidneys. Of the genes affected by genotype and diet, only 378 were affected by both. In summary, the Hyp mutation induced changes in mRNA levels for numerous transcripts exceeding that required to alter phosphate retention. The data suggest broader physiological roles for the Phex gene unrelated to phosphate conservation. Keyword = Phex Keyword = Hyp Keyword = mouse Keyword = kidney Keyword = sex Keyword = mRNA Keyword = microarray Keyword = low phosphorus diet Keywords: disease state analysis

Project description:The renal adaptation to changing dietary phosphate levels is not well understood. The dominant Hyp mutation of the Phex gene in mice causes X-linked hypophosphatemia with low renal retention of phosphate and blocks physiologic adaptation to low phosphate diets. At P < 0.01, there were 1,711 transcripts significantly affected by genotype, 1,428 by diet and 5,601 by sex. Many renal transporters other than phosphate, as well as many novel transcripts of unknown function, were affected by the Hyp mutation. Some genes for fat metabolism and inflammation were up-regulated in Hyp kidneys. Of the genes affected by genotype and diet, only 378 were affected by both. In summary, the Hyp mutation induced changes in mRNA levels for numerous transcripts exceeding that required to alter phosphate retention. The data suggest broader physiological roles for the Phex gene unrelated to phosphate conservation. Keyword = Phex; Keyword = Hyp; Keyword = mouse; Keyword = kidney; Keyword = sex; Keyword = mRNA; Keyword = microarray; Keyword = low phosphorus diet Experiment Overall Design: A 2x2x2 factorial design, balanced for genotype (normal vs. Hyp), diet (control vs. low phosphate), and sex (male vs. female) was employed. Control or low phosphate diets were fed for three days to 10-week-old mice. A total of 24 samples of renal RNA were collected from 72 mice (3/array), processed to biotin-labeled cRNA, and hybridized to Affymetrix mouse MOE 430A and 430B for measurement of expression of over 45,000 transcripts.

Project description:In general populations, age-dependent renal impairment contributes to the progression of renal dysfunction. It has not been known which molecules are involved in age-dependent renal im-pairment. Messenger RNA (mRNA) has been reported to modulate various renal diseases, and we therefore investigated mRNA signatures in age-dependent renal impairment. We performed an initial microarray-profiling analysis to screen mRNAs, the expression levels of which changed in the kidneys of 50-week-old senescence-accelerated prone (SAMP1) mice (which have accelerated age-dependentd renal impairments) compared with those of 50 -wk- old senes-cence-accelerated-resistant (SAMR1) mice (which have normal aged kidneys) and with younger (10 -wk- old) SAMP1 and SAMR1 mice. We next assessed the expressions of mRNAs that were differentially expressed in the kidneys of SAMP1-50wk mice by conducting a quantitative real-time polymerase chain reaction (qRT-PCR) and compared the expressions among the SAMP1-10wk, SAMR1-10wk, and SAMR1-50wk mice. The results of the microarray together with the qRT-PCR analysis revealed five mRNAs whose expression levels were significantly altered in SAMP1-50wk mouse kidneys versus the control mice. The expression levels of the five mRNAs’ expression levels were increased in the kidneys of the mice with age-dependent renal impairment. Our findings in-dicate that the five mRNAs might be related and could become therapeutic targets for age-dependent renal impairment.

Project description:<p><ol> <li>Several different genes cause, when mutated, increased urinary phosphate excretion and hypophosphatemia leading to rickets/osteomalacia; however, the majority of phosphate-wasting disorders has not yet been defined at the molecular level. Identification of phosphate-regulating genes has provided important novel insights into the mechanism contributing to phosphate homeostasis, which remains incompletely understood. We therefore pursue exome-wide nucleotide sequence analysis to define the underlying mutations, which is expected to provide novel insights into the regulation of this important mineral.</li> <li>Virtually nothing is known about the genetic mutations that cause non-syndromic structural abnormalities involving the urinary tract, which represent about 50&#37; of the causes of end-stage renal disease (ESRD). The completion of the human genome project and the technological advances that allow low cost whole exome sequencing have now made it feasible to readily search for the cause of different inherited disorders in humans, particularly if clinical information and genomic DNA is available from larger kindreds with multiple affected members that can be used for mapping the disease-causing genetic locus. Furthermore, catalogs were generated that document the expression profiles of numerous genes during embryonic, fetal, and postnatal development, thereby supporting the exploration of kidney involvement in animal models of different diseases and in human genetic syndromes. We therefore plan to define the mechanisms leading to inherited disorders of the urogenital tract and the kidneys by establishing the causative genetic defects through a combination of genetic mapping and whole exome sequencing.</li> <li>Hajdu-Cheney Syndrome (HCS) is a rare autosomal-dominant skeletal disorder characterized by severe osteoporosis, acroosteolysis of the distal phalanges, renal cysts and other abnormalities. Our goal is to identify the genetic cause of HCS using exome sequencing.</li> <li>Opsismodysplasia is a very rare recessive spondylometaphyseal dysplasia characterized by delayed epiphyseal ossification, shortness of bones and sometimes low serum phosphate levels. Discovery of the causing mutation will give us insights into the pathogenesis of this often lethal disease.</li> </ol></p>

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.

Project description:<p>Renal fibrosis, a hallmark of chronic kidney diseases, is driven by the activation of renal fibroblasts. Recent studies have highlighted the role of glycolysis in this process. Nevertheless, one critical glycolytic activator, 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase 3 (PFKFB3), remains unexplored in renal fibrosis. Upon reanalyzing the single-cell sequencing data from Dr. Humphreys' lab, we noticed an upregulation of glycolysis, gluconeogenesis, and TGFβ signaling pathway in myofibroblasts from fibrotic kidneys after unilateral ureter obstruction (UUO) or kidney ischemia/reperfusion. Furthermore, our experiments showed significant induction of PFKFB3 in mouse kidneys following UUO or kidney ischemia/reperfusion. To delve deeper into the role of PFKFB3, we generated mice with Pfkfb3 deficiency specifically in myofibroblasts (Pfkfb3f/fPostnMCM). Following UUO or kidney ischemia/reperfusion, a substantial decrease of fibrosis in injured kidneys of Pfkfb3f/fPostnMCM mice was identified compared to their wild-type littermates. Additionally, in cultured renal fibroblast NRK-49F cells, PFKFB3 was elevated upon exposure to TGFβ1, accompanied by the increase of α-SMA and fibronectin. Notably, this upregulation was significantly diminished with PFKFB3 knockdown, correlated with a glycolysis suppression. Mechanistically, the glycolytic metabolite lactate promoted the fibrotic activation of NRK-49F. In conclusion, our study demonstrates the critical role of PFKFB3 in driving fibroblast activation and subsequent renal fibrosis.</p>

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 .