Phosphorylation of β1-integrin in juxtaglomerular cells helps control blood pressure during the progression of diabetic nephropathy

The induction of a high blood pressure due to diabetic nephropathy depends on the increase in renin secretion from juxtaglomerular cells, but many aspects of how juxtaglomerular cells sense blood pressure changes in the afferent arteriole and consequently react remain unclear. In this study, we detected the juxtaglomerular cell-specific phosphorylation of the threonine-788/789 site of β1-integrin, and its expression was negatively correlated with renin production. This relationship was also observed in a culture system of a juxtaglomerular cell line, suggesting that β1-integrin is deeply involved in the regulation of renin production. The knockdown of β1-integrin in the culture system increased renin production, but the degree of the increase was comparable to the increase in renin production by knockdown of connexin-40, which is considered to be an important molecule that plays a role in the pressure sensing mechanism of juxtaglomerular cells. This suggests that the mechanism underlying the regulation of renin production by β1-integrin in juxtaglomerular cells may contribute to the pressure-sensing function of juxtaglomerular cells themselves. Threonine-788/789 phosphorylation of β1-integrin may be involved in the regulation of this pressoreceptor function. (176 words)

Abstract P060: High Salt Induces An Endothelial HDAC1-stimulating Circulating Factor Leading To Disrupted Renal Microvascular Nitric Oxide Signaling

High salt diet (HS) decreases endothelial nitric oxide (NO) signaling as described in human and rodent studies. We have previously shown that inhibition of HDAC1 restores NO signaling in the afferent arteriole of HS fed rats. It remains unknown, however, how HS initiates endothelial dysfunction and activates HDAC1. We first investigated if HS induced endothelial dysfunction is acutely regulated by a circulating factor. To test this, male Sprague Dawley rats were fed normal salt diet (NS; 0.49% NaCl) or 2 weeks of HS (4.0% NaCl). Afferent arteriole vasoconstrictor responses to the NOS inhibitor, L-NAME, were monitored using the in vitro, blood perfused juxtamedullary nephron preparation. Perfusing arterioles from NS fed rats with HS blood blunted constriction to L-NAME (88 ± 1% of Con) compared to perfusing with NS blood (76 ± 2% of Con; P=0.0003), but not completely as seen in arterioles from HS fed rats perfused with HS blood (96 ± 2% of Con; P=0.0095). HS arterioles perfused with NS blood had similar L-NAME-induced constriction (75 ± 2% of Con) compared to arterioles from NS fed rats perfused with NS blood (P=0.9107). These results suggest HS induces endothelial function through an acute-acting circulating factor. This was not due to increased plasma arginase activity (NS: 7.96 ± 3.73 U/L vs HS: 5.42 ± 1.83 U/L P=0.5813) which competes with NO synthase 3 for arginine, nor was it due to decreased superoxide scavenging capacity of the plasma (NS: 7.96 ± 3.73 U/L vs HS: 5.42 ± 1.83 U/L P=0.5813) as measured by a cytochrome c reduction based assay. We then investigated if HS increased endothelial HDAC1 activity. Renal endothelial cells were isolated via magnetic activated cell sorting from NS and HS fed rats and incubated in plasma from the same rat. HDAC1 activity was monitored as the MS-275 (HDAC1 specific inhibitor) inhibitable portion of total HDAC activity. We found HS significantly increased renal endothelium HDAC1 activity (NS: 0.38 ± 0.03 pmol/min vs HS:0.94 ± 0.19 pmol/min, P=0.01). We conclude that HS disruption of renal microvascular NO signaling is initiated by a circulating factor(s) that is dependent upon increased endothelial HDAC1 activity.

Abstract P004: Endothelial Function In Rat Juxtamedullary Afferent Arterioles After Renal Ischemia-reperfusion Injury

Renal ischemia-reperfusion (IR) induced kidney injury exhibits reduced renal blood flow (RBF) and glomerular filtration rate (GFR). Both RBF and GFR are regulated by renal microvascular function. Our previous study showed that IR caused impaired afferent arteriole autoregulatory capability via excess ROS accumulation and inflammation in renal microvessels. Other mechanisms contributing to renal microvascular dysfunction in IR have not been fully defined. In this study, we conducted acetylcholine (ACh) concentration-response experiments (n=5-7/each group) to assess endothelial function using the in vitro blood-perfused juxtamedullary nephron preparation. IR was induced by 60 minutes of bilateral renal artery occlusion followed by 24 hours or 7 days of reperfusion. Renal microvessels (RMV) were collected at either 24 hours or 7 days post-surgery for mRNA analysis. Systolic blood pressure was normal in IR rats vs. sham ranging from 126-136 mmHg (>0.05) over 7 days. IR markedly increased plasma creatinine concentration (Cr) to 3.9±0.2 mg/dL at 24 hours post-IR ( P <0.05 vs. 0.9±0.1 mg/dL in sham). Plasma Cr remained elevated in IR rats by day 7 of reperfusion (1.5±0.2 vs. 1.0±0.0 mg/dL in sham, P <0.05). Baseline afferent arteriole diameter was smaller in IR rats 24 hours post-IR and averaged 11.1±0.7 μm (P<0.05 vs. 14.2±0.7 μm in sham). Superfusion of ACh (10 -8 to 10 -4 M) caused concentration-dependent vasodilation in sham rats, increasing diameter to 23.5±2.6 μm (169±14% of the control, P <0.05) at 10 -4 M ACh. The ACh-induced vasodilation was not altered by IR insult and was indistinguishable from the sham responses. IR diameter reached a maximum of 19.7±0.9 μm (179±8% of the control) at 10 -5 M ACh. The ACh responses were also similar between sham and IR rats on day 7 post-IR. mRNA expression of endothelial markers, iCAM and vCAM, were not statistically different in RMV collected at 24 hours post-surgery between two groups, but was markedly elevated in IR RMV on day 7 post-IR (4-fold in iCAM and 2-fold in vCAM, P<0.05 vs. sham). In conclusion, upregulation of iCAM and vCAM mRNA expression in RMV 7 days post-IR suggests renal microvascular inflammation, but rat juxtamedullary afferent arterioles still maintain normal endothelium-dependent reactivity to ACh.

SO022EVALUATION OF GLOMERULAR HEMODYNAMIC CHANGES BY SGLT2 INHIBITION IN TYPE 2 DIABETIC RATS USING IN VIVO IMAGING TECHNIQUES

Background and Aims In recent clinical trials, the SGLT2 inhibitor (SGLT2i) slowed the progression of kidney disease compared with the placebo in patients with type 2 diabetes. Improvement of glomerular hyperfiltration via tubuloglomerular feedback (TGF) is considered to be one of the possible pathways for renal protection with SGLT2 inhibition (SGLT2i) in diabetic kidney disease (DKD). We have successfully developed the novel method to measure single-nephron GFR (SNGFR) in mice using multiphoton laser microscopy and demonstrated that the adenosine/adenosine A1 receptor (A1aR) pathway plays a pivotal role in the TGF mechanism in the type 1 diabetic model, Akita mice (Kengo Kidokoro, David Z. I. Cherney et al. Circulation. 2019). It has been suggested that the mechanism of improvement effects in glomerular hyperfiltration by SGLT2i is different in type 1 diabetes and type 2 diabetes. However, the detailed regulatory mechanism of GFR by SGLT2i is not fully understood in type 2 diabetes. This study aims to clarify the effects of SGLT2i on glomerular hemodynamics in type 2 diabetic rats. Method Zucker lean (ZL) rats and Zucker diabetic fatty (ZDF) rats were used. In the first experiment, SNGFR and diameters of glomerular afferent/efferent arterioles were measured in both groups. Next, we examined the change of SNGFR and diameters of glomerular afferent/efferent arterioles, as well as urinary excretions of glucose and sodium in ZDF after a single-dose administration of SGLT2i (luseogliflozin; 10mg/kg, gavage) for 120 minutes, which generated the following three groups: SGLT2i group, SGLT2i + adenosine A1 receptor (A1aR) antagonist (8-cyclopentyl-1,3-dipropylxanthine, 1mg/kg) group, and insulin group. Results SNGFR in the ZDF group was significantly higher than in the ZL group. The diameter of the afferent arteriole and efferent arteriole was also wider in ZDF rats than in ZL rats. The SNGFR and diameter of the afferent arteriole were significantly decreased after a single-dose administration of SGLT2i in ZDF. However, there was no significant diameter change in the efferent arteriole. Moreover, a decrease of SNGFR was not observed in the A1aR antagonist group after SGLT2i administration. Urinary excretions of glucose and sodium showed a similar pattern in the SGLT2i and SGLT2i+ A1aR antagonist groups. Conclusion The adenosine/A1aR pathway plays an important role in the regulation of the tonus of the afferent arteriole and is involved in the suppression of glomerular hyperfiltration by SGLT2 inhibition in type 2 diabetes.

Sox6 as a new modulator of renin expression in the kidney

Juxtaglomerular (JG) cells, major sources of renin, differentiate from metanephric mesenchymal cells that give rise to JG cells or a subset of smooth muscle cells of the renal afferent arteriole. During periods of dehydration and salt deprivation, renal mesenchymal stromal cells (MSCs) differentiate from JG cells. JG cells undergo expansion and smooth muscle cells redifferentiate to express renin along the afferent arteriole. Gene expression profiling comparing resident renal MSCs with JG cells indicates that the transcription factor Sox6 is highly expressed in JG cells in the adult kidney. In vitro, loss of Sox6 expression reduces differentiation of renal MSCs to renin-producing cells. In vivo, Sox6 expression is upregulated after a low-Na+ diet and furosemide. Importantly, knockout of Sox6 in Ren1d+ cells halts the increase in renin-expressing cells normally seen during a low-Na+ diet and furosemide as well as the typical increase in renin. Furthermore, Sox6 ablation in renin-expressing cells halts the recruitment of smooth muscle cells along the afferent arteriole, which normally express renin under these conditions. These results support a previously undefined role for Sox6 in renin expression.

Regulation of (Pro)Renin Receptor in Renin-Positive Smooth Muscle Cells of Kidney Arterioles in Rats with STZ-Induced Diabetes

Objective. The nephron (pro)renin receptor may play a pathophysiological role in renal disorders in hypertension or diabetes. The aim of this study was to determine the relationship of (pro)renin receptors and transdifferentiation between the renin-negative and renin-positive SMCs in the afferent arteriole by estimating the distribution of (pro)renin receptors in renin-positive and renin-negative SMCs of the afferent arteriole of kidneys in normal and streptozotocin- (STZ-) induced diabetic rats. Therefore in diabetes the renin granulation of afferent arterioles is different as in normal, the diabetes model for finding the differences to normal in distribution of (pro)renin receptors of afferent arterioles was used. Method. To estimate the number of (pro)renin receptors in arteriolar SMCs a special protocol of immunohistochemistry to stereology was followed. Results. Our results showed that on the surface of renin-positive SMCs the number of (pro)renin receptors was upregulated, while in the cytoplasm of SMCs there was downregulation in comparison to renin-negative SMCs. There is a significant difference between the number of (pro)renin receptors on the surface and in the cytoplasm of renin-positive SMCs in normal rats. These differences in the number of (pro)renin receptors were not present in rats with STZ-induced diabetes. Any other differences in the number of (pro)renin receptors between the STZ-induced diabetic and normal rats were not detected. The tissue level of angiotensin II did not change in the kidneys of STZ-induced diabetic rats. Conclusion. The distribution of (pro)renin receptors in afferent arteriolar SMCs is related to renin granulation of SMCs, but independent of angiotensin II plasma or tissue levels in the kidney.

Sox6: A new modulator of renin expression during physiological conditions

ABSTRACTJuxtaglomerular (JG) cells, major sources of renin, differentiate from metanephric mesenchymal cells which give rise to JG cells or a subset of smooth muscle cells of the renal afferent arteriole. During periods of dehydration and salt deprivation JG cells undergo expansion. Gene expression profiling comparing resident renal Mesenchymal Stromal Cells (MSCs) with JG cells indicate that the transcription factor Sox6 is highly expressed in JG cells in the adult kidney. In vitro, loss of Sox6 expression reduces differentiation of renal MSCs to renin producing cells. In vivo, Sox6 expression is up-regulated during JG cell expansion. Importantly, knockout of Sox6 in Ren1d+ cells halts the increase in renin expressing cells normally seen during JG cell expansion as well as the typical increase in renin. These results support a previously undefined role for Sox6 in renin expression during normal and pathophysiological conditions.