Mediators between canagliflozin and renoprotection vary depending on patient characteristics: Insights from the CREDENCE trial

Aim: To identify the mediators between canagliflozin and renoprotection in patients with type 2 diabetes at a high risk of end-stage kidney disease (ESKD). Methods: In this post hoc analysis of the CREDENCE trial, the effect of canagliflozin on potential mediators (42 biomarkers) at 52 weeks and the association between changes in mediators and renal outcomes were evaluated using mixed-effects and Cox models, respectively. The renal outcome was a composite of ESKD, serum creatinine doubling or renal death. The percentage of the mediating effect of each significant mediator was calculated based on changes in the hazard ratios of canagliflozin after additional adjustment of the mediator. Results: Changes in haematocrit, haemoglobin, red blood cell (RBC) count and urinary albumin-to-creatinine ratio (UACR) at 52 weeks significantly mediated 47%, 41%, 40% and 29% risk reduction with canagliflozin, respectively. Further, 85% mediation was attributed to the combined effect of haematocrit and UACR. A large variation in mediating effects by haematocrit change existed among the subgroups, ranging from 17% in those patients with a UACR of more than 3000 mg/g to 63% in patients with a UACR of 3000 mg/g or less. In the subgroups with a UACR of more than 3000 mg/g, UACR change was the highest mediating factor (37%), driven by the strong association between UACR decline and renal risk reduction. Conclusions: The renoprotective effects of canagliflozin in patients at a high risk of ESKD can be significantly explained by changes in RBC variables and UACR. The complementary mediating effects of RBC variables and UACR may support the renoprotective effect of canagliflozin in different patient groups.Doi Y., Hamano T., Yamaguchi S., et al. Mediators between canagliflozin and renoprotection vary depending on patient characteristics: Insights from the CREDENCE trial. Diabetes, Obesity and Metabolism , (2023); https://doi.org/10.1111/dom.15191

New mechanism leading to alleviation of salt-sensitive hypertension by a powerful angiotensin receptor blocker, azilsartan

Hypertension is one of the most life-threatening health problems in the modern world. Particularly, salt-sensitive hypertension is often associated with cardiovascular disease and defects in the circadian rhythm of the blood pressure. To date, the effects of angiotensin receptor blocker (ARB) against salt sensitivity and the blood pressure’s circadian rhythm have been obscure. A strong ARB, azilsartan, was previously reported to improve the circadian rhythm of blood pressure in hypertensive patients. In a recently published study, we investigated the mechanism by which azilsartan brought about this reaction. We speculated that azilsartan modulated sodium transporters located in the renal tubules because the circadian rhythm of blood pressure is linked to salt handling in the kidney. We discovered that one sodium transporter, NHE3 protein, in the proximal tubules was greatly attenuated in the kidneys of 5/6 nephrectomized mice that had been treated with azilsartan, although the expression of other sodium transporter proteins remained unchanged. The genetic expression of NHE3, however, was not changed by azilsartan. In a subsequent in vitro study using OKP cells, we found that NHE3 protein reduction was induced by enhanced protein degradation by proteasomes, not lysosomes, leading to enhanced sodium excretion. It is suggested that diminished salt sensitivity in the 5/6 nephrectomized mice treated with azilsartan was due to a change in sodium handling induced by the reduction of NHE3 protein in the proximal tubules. These mechanisms underlying the decreased salt sensitivity by azilsartan treatment may lead to totally new drug discoveries

Gene expression profile of renal proximal tubules regulated by proteinuria

Gene expression profile of renal proximal tubules regulated by proteinuria.BackgroundProximal tubules activated by reabsorption of protein are thought to play significant roles in the progression of kidney diseases. Thus, identification of genes related to proteinuria should provide insights into the pathological process of tubulointerstitial fibrosis.MethodGene expression profiles were constructed by means of direct sequencing procedures to identify genes induced in the mouse kidney proximal tubules (PT) exposed to proteinuria.ResultsBy comparing the gene expression of control PT to that of disease model PT, the abundantly expressed genes in control PT were down-regulated presumably because of potentially toxic effects of proteinuria. From the more than 1000 up-regulated genes, an immunity related gene, thymic shared antigen-1 (TSA-1), and a novel gene, GS188, were selected for further characterization. The increased expression of TSA-1, a member of the Ly-6 family, and of GS188 in response to proteinuria was confirmed by Northern analysis, immunohistochemistry, in situ hybridization and laser microdissection along with real-time PCR analysis. Full length cloning of GS188 identified it as a family member of LR8 that was reported to express predominantly in fibroblasts.ConclusionsThe gene expression profiles showed that the expression patterns in PT were changed dramatically by proteinuria. The profiles include novel genes that should be further characterized to aid the understanding of the pathophysiology of progressive kidney diseases

Diagnosing metabolic acidosis in chronic kidney disease: importance of blood pH and serum anion gap

Metabolic acidosis is one of the most common complications of chronic kidney disease (CKD). It is associated with the progression of CKD, and many other functional impairments. Until recently, only serum bicarbonate levels have been used to evaluate acid-base changes in patients with reduced kidney function. However, recent emerging evidence suggests that nephrologists should reevaluate the clinical approach for diagnosing metabolic acidosis in patients with CKD based on two perspectives; pH and anion gap. Biochemistry and physiology textbooks clearly indicate that blood pH is the most important acid-base parameter for cellular function. Therefore, it is important to determine if the prognostic impact of hypobicarbonatemia varies according to pH level. A recent cohort study of CKD patients showed that venous pH modified the association between a low bicarbonate level and the progression of CKD. Furthermore, acidosis with a high anion gap has recently been recognized as an important prognostic factor, because veverimer, a nonabsorbable hydrochloride-binding polymer, has been shown to improve kidney function and decrease the anion gap. Acidosis with high anion gap frequently develops in later stages of CKD. Therefore, the anion gap is a time-varying factor and renal function (estimated glomerular filtration rate) is a time-dependent confounder for the anion gap and renal outcomes. Recent analyses using marginal structural models showed that acidosis with a high anion gap was associated with a high risk of CKD. Based on these observations, reconsideration of the clinical approach to diagnosing and treating metabolic acidosis in CKD may be warranted

Serum phosphate levels modify the impact of parathyroid hormone levels on renal outcomes in kidney transplant recipients

Separate assessment of mineral bone disorder (MBD) parameters including calcium, phosphate, parathyroid hormone (PTH), fibroblast growth factor 23 (FGF23), 25-hydroxyvitamin D, and 1,25-dihydroxyvitamin D (1,25D) predict renal outcomes in kidney transplant recipients (KTRs), with conflicting results. To date, data simultaneously evaluating these parameters and interwoven relations on renal outcomes are scarce. We conducted a prospective long-term follow-up cohort study included 263 KTRs with grafts functioning at least 1 year after transplantation. The outcome was a composite of estimated GFR halving and graft loss. Cox regression analyses were employed to evaluate associations between a panel of six MBD parameters and renal outcomes. The outcome occurred in 98 KTRs during a median follow-up of 10.7 years. In a multivariate Cox analysis, intact PTH (iPTH), phosphate, and 1,25D levels were associated with the outcome (hazard ratio, 1.60 per log scale; 95% confidence interval, 1.19–2.14, 1.60 per mg/dL; 1.14–2.23 and 0.82 per 10 pg/mL; 0.68–0.99, respectively). Competing risk analysis with death as a competing event yielded a similar result. After stratification into four groups by iPTH and phosphate medians, high risks associated with high iPTH was not observed in KTRs with low phosphate levels (P-interaction < 0.1). Only KTRs not receiving active vitamin D, poor 1,25D status predicted the worse outcome (P-interaction < 0.1). High iPTH, phosphate, and low 1,25D, but not FGF23, levels predicted poor renal outcomes. Simultaneous evaluation of PTH and phosphate levels may provide additional information regarding renal allograft prognosis.Doi Y., Hamano T., Ichimaru N., et al. Serum phosphate levels modify the impact of parathyroid hormone levels on renal outcomes in kidney transplant recipients. Scientific Reports 10, 13766 (2020); https://doi.org/10.1038/s41598-020-70709-4

New mechanism leading to alleviation of salt-sensitive hypertension by a powerful angiotensin receptor blocker, azilsartan

Hypertension is one of the most life-threatening health problems in the modern world. Particularly, salt-sensitive hypertension is often associated with cardiovascular disease and defects in the circadian rhythm of the blood pressure. To date, the effects of angiotensin receptor blocker (ARB) against salt sensitivity and the blood pressure’s circadian rhythm have been obscure. A strong ARB, azilsartan, was previously reported to improve the circadian rhythm of blood pressure in hypertensive patients. In a recently published study, we investigated the mechanism by which azilsartan brought about this reaction. We speculated that azilsartan modulated sodium transporters located in the renal tubules because the circadian rhythm of blood pressure is linked to salt handling in the kidney. We discovered that one sodium transporter, NHE3 protein, in the proximal tubules was greatly attenuated in the kidneys of 5/6 nephrectomized mice that had been treated with azilsartan, although the expression of other sodium transporter proteins remained unchanged. The genetic expression of NHE3, however, was not changed by azilsartan. In a subsequent in vitro study using OKP cells, we found that NHE3 protein reduction was induced by enhanced protein degradation by proteasomes, not lysosomes, leading to enhanced sodium excretion. It is suggested that diminished salt sensitivity in the 5/6 nephrectomized mice treated with azilsartan was due to a change in sodium handling induced by the reduction of NHE3 protein in the proximal tubules. These mechanisms underlying the decreased salt sensitivity by azilsartan treatment may lead to totally new drug discoveries