Daigoro Hirohama

Fibroblast growth factor 23 accelerates phosphate-induced vascular calcification in the absence of Klotho deficiency

Fibroblast growth factor 23 (FGF23) is a phosphate-regulating hormone that acts primarily on the kidney and parathyroid. With declining kidney function there is an increase in circulating FGF23 levels, which is associated with vascular calcification and mortality in chronic kidney disease. Whether FGF23 exerts direct effects on vasculature is unclear. We evaluated the expression of Klotho and FGF receptors in rat aortic rings and rat aorta vascular smooth muscle cells maintained in culture by reverse transcription-PCR, western blotting, and immunostaining. Signaling pathways underlying FGF23 effects were assessed by western blotting, and effects of FGF23 on osteogenic markers and phosphate transporters were assessed by real-time reverse transcription-PCR. We detected Klotho and FGFR1 in total aorta but not in vascular smooth muscle cells. FGF23 augmented phosphate-induced vascular calcification in the aortic rings from uremic rats and dose dependently increased ERK1/2 phosphorylation in Klotho-overexpressing but not naive vascular smooth muscle cells. FGF23-induced ERK1/2 phosphorylation was inhibited by SU5402 (FGFR1 inhibitor) and U0126 (MEK inhibitor). FGF23 enhanced phosphate-induced calcification in Klotho-overexpressing vascular smooth muscle cells and increased osteoblastic marker expression, which was inhibited by U0126. In contrast, phosphate transporter expression was not affected by phosphate or FGF23. Thus, FGF23 enhances phosphate-induced vascular calcification by promoting osteoblastic differentiation involving the ERK1/2 pathway.

High-salt in addition to high-fat diet may enhance inflammation and fibrosis in liver steatosis induced by oxidative stress and dyslipidemia in mice

BackgroundIt is widely known that salt is an accelerating factor for the progression of metabolic syndrome and causes cardiovascular diseases, most likely due to its pro-oxidant properties. We hypothesized that excessive salt intake also facilitates the development of nonalcoholic steatohepatitis (NASH), which is frequently associated with metabolic syndrome.MethodsWe examined the exacerbating effect of high-salt diet on high-fat diet-induced liver injury in a susceptible model to oxidative stress, apoE knockout and lectin-like oxidized low-density lipoprotein receptor-1 (LOX-1) transgenic mice.ResultsHigh-salt diet led to NASH in high-fat diet-fed LOX-1 transgenic/apoE knockout mice without affecting high-fat diet-induced dyslipidemia or hepatic triglyceride accumulation. Additionally, a high-salt and high-fat diet stimulated oxidative stress production and inflammatory reaction to a greater extent than did a high-fat diet in the liver of LOX-1 transgenic/apoE knockout mice.ConclusionsWe demonstrated that high-salt diet exacerbated NASH in high-fat diet-fed LOX-1 transgenic /apoE knockout mice and that this effect was associated with the stimulation of oxidative and inflammatory processes; this is the first study to suggest the important role of excessive salt intake in the development of NASH.

Lactoferrin Suppresses Neutrophil Extracellular Traps Release in Inflammation

Neutrophils are central players in the innate immune system. They generate neutrophil extracellular traps (NETs), which protect against invading pathogens but are also associated with the development of autoimmune and/or inflammatory diseases and thrombosis. Here, we report that lactoferrin, one of the components of NETs, translocated from the cytoplasm to the plasma membrane and markedly suppressed NETs release. Furthermore, exogenous lactoferrin shrunk the chromatin fibers found in released NETs, without affecting the generation of oxygen radicals, but this failed after chemical removal of the positive charge of lactoferrin, suggesting that charge-charge interactions between lactoferrin and NETs were required for this function. In a model of immune complex-induced NET formation in vivo, intravenous lactoferrin injection markedly reduced the extent of NET formation. These observations suggest that lactoferrin serves as an intrinsic inhibitor of NETs release into the circulation. Thus, lactoferrin may represent a therapeutic lead for controlling NETs release in autoimmune and/or inflammatory diseases.

Hypokalemia and Pendrin Induction by Aldosterone

Aldosterone plays an important role in regulating Na-Cl reabsorption and blood pressure. Epithelial Na+ channel, Na+-Cl− cotransporter, and Cl−/HCO3− exchanger pendrin are the major mediators of Na-Cl transport in the aldosterone-sensitive distal nephron. Existing evidence also suggests that plasma K+ concentration affects renal Na-Cl handling. In this study, we posited that hypokalemia modulates the effects of aldosterone on pendrin in hyperaldosteronism. Chronic aldosterone infusion in mice increased pendrin levels at the plasma membrane, and correcting hypokalemia in this model almost completely blocked pendrin upregulation. However, hypokalemia induced by a low-K+ diet resulted in pendrin downregulation along with reduced plasma aldosterone levels, indicating that both hypokalemia and aldosterone excess are necessary for pendrin induction. In contrast, decreased plasma K+ levels were sufficient to increase Na+-Cl− cotransporter levels. We found that phosphorylation of mineralocorticoid receptor that prevents aldosterone binding in intercalated cells was suppressed by hypokalemia, which resulted in enhanced pendrin response to aldosterone, explaining the coordinated action of aldosterone and hypokalemia in pendrin regulation. Finally, to address the physiological significance of our observations, we administered aldosterone to mice lacking pendrin. Notably, plasma K+ levels were significantly lower in pendrin knockout mice (2.7±0.1 mmol/L) than in wild-type mice (3.0±0.1 mmol/L) after aldosterone infusion, demonstrating that pendrin alleviates hypokalemia in a state of aldosterone excess. These data indicate that the decreased plasma K+ levels promote pendrin induction by aldosterone, which, in concert with Na+-Cl− cotransporter, counteracts the progression of hypokalemia but promotes hypertension in primary aldosterone excess.

Renal Dysfunction Induced by Kidney-Specific Gene Deletion of Hsd11b2 as a Primary Cause of Salt-Dependent Hypertension

Genome-wide analysis of renal sodium-transporting system has identified specific variations of Mendelian hypertensive disorders, including HSD11B2 gene variants in apparent mineralocorticoid excess. However, these genetic variations in extrarenal tissue can be involved in developing hypertension, as demonstrated in former studies using global and brain-specific Hsd11b2 knockout rodents. To re-examine the importance of renal dysfunction on developing hypertension, we generated kidney-specific Hsd11b2 knockout mice. The knockout mice exhibited systemic hypertension, which was abolished by reducing salt intake, suggesting its salt-dependency. In addition, we detected an increase in renal membrane expressions of cleaved epithelial sodium channel-&agr; and T53-phosphorylated Na+-Cl− cotransporter in the knockout mice. Acute intraperitoneal administration of amiloride-induced natriuresis and increased urinary sodium/potassium ratio more in the knockout mice compared with those in the wild-type control mice. Chronic administration of amiloride and high-KCl diet significantly decreased mean blood pressure in the knockout mice, which was accompanied with the correction of hypokalemia and the resultant decrease in Na+-Cl− cotransporter phosphorylation. Accordingly, a Na+-Cl− cotransporter blocker hydrochlorothiazide significantly decreased mean blood pressure in the knockout mice. Chronic administration of mineralocorticoid receptor antagonist spironolactone significantly decreased mean blood pressure of the knockout mice along with downregulation of cleaved epithelial sodium channel-&agr; and phosphorylated Na+-Cl− cotransporter expression in the knockout kidney. Our data suggest that kidney-specific deficiency of 11&bgr;-HSD2 leads to salt-dependent hypertension, which is attributed to mineralocorticoid receptor–epithelial sodium channel–Na+-Cl− cotransporter activation in the kidney, and provides evidence that renal dysfunction is essential for developing the phenotype of apparent mineralocorticoid excess.

Oxidative Stress in Multiple Organ Damage in Hypertension, Diabetes and CKD, Mechanisms and New Therapeutic Possibilities

Hypertension, diabetes, hypercholesterolemia and chronic kidney disease (CKD) lead to cardiovascular (CV) events and cardiovascular death consists of main cause in mortality of those diseases. Understanding of pathophysiology that links them and CV events has been vigorously studied and several factors are believed to play roles such as NO, reninangiotensin system, and oxidative stress. It has been shown that those factors affect endothelial function and consequently organ circulation as well as function and viability of cells and organs. Despite overwhelming evidences in the consequences of experimental models of ROS-induced organ damage, large-scale clinical trials of former antioxidant therapies, such as vitamin C, vitamin E or -carotene, could not demonstrate satisfactory benefit to patients and they seemed to be harmful in some cases (Hennekens et al., 1996; Omenn et al., 1996; Virtamo et al., 1998; Hercberg et al., 1999; Lee et al., 1999; Yusuf et al., 2000; de Gaetano, 2001; Heart, 2002; Vivekananthan et al., 2003; Hercberg et al., 2004; KrisEtherton et al., 2004; Lonn et al., 2005). Several studies concluded that β-carotene supplementation increased the relative risk of death in patients with some types of cancer and had no benefit on patients with cardiovascular disease. Another study said vitamin E increased hemorrhagic stroke. Even antioxidant cocktails increased in all-cause motality (Omenn et al., 1996; Rosen et al., 2001a). So far, supplementation with vitamins C and E, either alone or in combination with each other or with other antioxidant vitamins, does not appear to be efficacious for the treatment of cardiovascular disease (Lonn et al., 2005). We investigated role of oxidative stress in consequences of multiple organ damages in mouse and possible new therapeutic agent.

Aberrant DNA methylation of hypothalamic angiotensin receptor in prenatal programmed hypertension

Maternal malnutrition, which causes prenatal exposure to excessive glucocorticoid, induces adverse metabolic programming, leading to hypertension in offspring. In offspring of pregnant rats receiving a low-protein diet or dexamethasone, a synthetic glucocorticoid, mRNA expression of angiotensin receptor type 1a (Agtr1a) in the paraventricular nucleus (PVN) of the hypothalamus was upregulated, concurrent with reduced expression of DNA methyltransferase 3a (Dnmt3a), reduced binding of DNMT3a to the Agtr1a gene, and DNA demethylation. Salt loading increased BP in both types of offspring, suggesting that elevated hypothalamic Agtr1a expression is epigenetically modulated by excessive glucocorticoid and leads to adult-onset salt-sensitive hypertension. Consistent with this, dexamethasone treatment of PVN cells upregulated Agtr1a, while downregulating Dnmt3a, and decreased DNMT3a binding and DNA demethylation at the Agtr1a locus. In addition, Dnmt3a knockdown upregulated Agtr1a independently of dexamethasone. Hypothalamic neuron-specific Dnmt3a-deficient mice exhibited upregulation of Agtr1a in the PVN and salt-induced BP elevation without dexamethasone treatment. By contrast, dexamethasone-treated Agtr1a-deficient mice failed to show salt-induced BP elevation, despite reduced expression of Dnmt3a. Thus, epigenetic modulation of hypothalamic angiotensin signaling contributes to salt-sensitive hypertension induced by prenatal glucocorticoid excess in offspring of mothers that are malnourished during pregnancy.

Aberrant DNA methylation of pregnane X receptor underlies metabolic gene alterations in the diabetic kidney

Epigenetic abnormalities have been suggested to mediate metabolic memory observed in diabetic complications. We have shown that epigenetic alterations may induce persistent phenotypic changes in the proximal tubules of the diabetic kidneys. In this study, we show that pregnane X receptor (PXR), a xenobiotic nuclear receptor, is epigenetically altered and upregulated and may have a possible function in the diabetic kidney. PXR has been shown to play a critical role in metabolic changes in obesity and diabetes; however, its distribution and function in the kidney are unknown. In the normal kidney, Pxr was selectively expressed in the proximal tubular cells with demethylation in the promoter DNA. In db/db mice, significant increases in Pxr mRNA, further demethylation of DNA, and stimulatory histone marks in the promoter were observed. Epigenetic changes are likely to play a causative role in PXR induction, since a DNA methyltransferase inhibitor increased PXR mRNA in cultured human proximal tubular cells. Administration of a PXR agonist increased mRNA levels of solute carrier organic anion transporter family member 2B1 ( Slco2b1), a xenobiotic transporter; response gene to complement 32 ( Rgc32), a molecule known to exert fibrotic effects in the kidney; and phosphoenolpyruvate carboxykinase 1 ( Pck1), a gluconeogenic enzyme in the kidney. The expressions of these genes were inhibited by PXR small interfering RNA in cultured proximal tubular cells. Increased mRNA levels of Slco2b1, Rgc32, and Pck1 were also observed in the kidney of db/db mice. These data indicate that PXR is upregulated in the diabetic kidney with aberrant epigenetic modifications and may modulate the course of diabetic kidney disease through the activation of these genes.

Aldosterone Is Essential for Angiotensin II-Induced Upregulation of Pendrin

The renin-angiotensin-aldosterone system has an important role in the control of fluid homeostasis and BP during volume depletion. Dietary salt restriction elevates circulating angiotensin II (AngII) and aldosterone levels, increasing levels of the Cl-/HCO3- exchanger pendrin in β-intercalated cells and the Na+-Cl- cotransporter (NCC) in distal convoluted tubules. However, the independent roles of AngII and aldosterone in regulating these levels remain unclear. In C57BL/6J mice receiving a low-salt diet or AngII infusion, we evaluated the membrane protein abundance of pendrin and NCC; assessed the phosphorylation of the mineralocorticoid receptor, which selectively inhibits aldosterone binding in intercalated cells; and measured BP by radiotelemetry in pendrin-knockout and wild-type mice. A low-salt diet or AngII infusion upregulated NCC and pendrin levels, decreased the phosphorylation of mineralocorticoid receptor in β-intercalated cells, and increased plasma aldosterone levels. Notably, a low-salt diet did not alter BP in wild-type mice, but significantly decreased BP in pendrin-knockout mice. To dissect the roles of AngII and aldosterone, we performed adrenalectomies in mice to remove aldosterone from the circulation. In adrenalectomized mice, AngII infusion again upregulated NCC expression, but did not affect pendrin expression despite the decreased phosphorylation of mineralocorticoid receptor. By contrast, AngII and aldosterone coadministration markedly elevated pendrin levels in adrenalectomized mice. Our results indicate that aldosterone is necessary for AngII-induced pendrin upregulation, and suggest that pendrin contributes to the maintenance of normal BP in cooperation with NCC during activation of the renin-angiotensin-aldosterone system by dietary salt restriction.

Renal Denervation Improves Cardiac Diastolic Dysfunction by Restoring Serca2a Transcription in Uninephrectomized Rats

Background: The mortality and morbidity of heart failure with preserved ejection fraction has increased. Sarcoplasmic reticulum Ca2+-ATPase type 2a (SERCA2a) regulates cardiac functions, and a reduction in SERCA2a expression has been documented in left ventricular (LV) diastolic dysfunction. By contrast, SERCA2a overexpression improves LV diastolic dysfunction. Thus, transcriptional regulation of SERCA2a may be a new therapeutic target. The aim of this study was to determine whether renal denervation, a treatment for resistant hypertension, is a regulator of SERCA2a transcription in vivo. Methods: Uninephrectomy and 6-week salt loading in three-week-old male Sprague-Dawley rats were used to devise a cardiac diastolic dysfunction model, and mechanical renal denervation was performed. The expression of SERCA2a and related molecules was evaluated with quantitative polymerase chain reaction and western blot analyses. The maximal positive LV pressure development (+dP/dtmax) and time constant at the isovolumic relaxation phase (Tau) were determined with cardiac catheters. Results: Uninephrectomy combined with a high-salt diet significantly reduced the messenger RNA expression and protein abundance of SERCA2a, which were restored by renal denervation. In accordance with changes in SERCA2a transcription, uninephrectomy and the high-salt diet decreased LV diastolic function, which was evaluated by Tau and restored by renal denervation. LV systolic function, measured with +dp/dtmax, was preserved. Renal denervation did not lower blood pressure, urinary protein levels, cardiac hypertrophy, or fibrosis. Conclusions: We found that renal denervation is a regulator of SERCA2a transcription in vivo. Our data may provide new therapeutic insights into LV diastolic dysfunction and warrant further study.