We have recently identified endothelial cell-secreted developmental endothelial locus-1 (Del-1) as an endogenous inhibitor of β2-integrin–dependent leukocyte infiltration. Del-1 was previously also implicated in angiogenesis. Here, we addressed the role of endogenously produced Del-1 in ischemia-related angiogenesis. Intriguingly, Del-1–deficient mice displayed increased neovascularization in two independent ischemic models (retinopathy of prematurity and hind-limb ischemia), as compared to Del-1–proficient mice. On the contrary, angiogenic sprouting in vitro or ex vivo (aortic ring assay) and physiological developmental retina angiogenesis were not affected by Del-1 deficiency. Mechanistically, the enhanced ischemic neovascularization in Del-1-deficiency was linked to higher infiltration of the ischemic tissue by CD45+ hematopoietic and immune cells. Moreover, Del-1-deficiency promoted β2-integrin–dependent adhesion of hematopoietic cells to endothelial cells in vitro, and the homing of hematopoietic progenitor cells and of immune cell populations to ischemic muscles in vivo. Consistently, the increased hind limb ischemia-related angiogenesis in Del-1 deficiency was completely reversed in mice lacking both Del-1 and the β2-integrin LFA-1. Additionally, enhanced retinopathy-associated neovascularization in Del-deficient mice was reversed by LFA-1 blockade. Our data reveal a hitherto unrecognized function of endogenous Del-1 as a local inhibitor of ischemia-induced angiogenesis by restraining LFA-1–dependent homing of pro-angiogenic hematopoietic cells to ischemic tissues. Our findings are relevant for the optimization of therapeutic approaches in the context of ischemic diseases.
Kir5.1 (encoded by the Kcnj16 gene) is an inwardly rectifying K+ (Kir) channel highly expressed in the aldosterone-sensitive distal nephron of the kidney, where it forms a functional channel with Kir4.1. Kir4.1/Kir5.1 channels are responsible for setting the transepithelial voltage in the distal nephron and collecting ducts and are thereby major determinants of fluid and electrolyte distribution. These channels contribute to renal blood pressure control and have been implicated in salt-sensitive hypertension. However, mechanisms pertaining to the impact of K ir4.1/Kir5.1-mediated K+ transport on the renin–angiotensin–aldosterone system (RAAS) remain unclear. Herein, we utilized a knockout of Kcnj16 in the Dahl salt-sensitive rat (SSKcnj16-/-) to investigate the relationship between Kir5.1 and RAAS balance and function in the sensitivity of blood pressure to the dietary Na+/K+ ratio. The knockout of Kcnj16 caused substantial elevations in plasma RAAS hormones (aldosterone and angiotensin peptides) and altered the RAAS response to changing the dietary Na+/K+ ratio. Blocking aldosterone with spironolactone caused rapid mortality in SSKcnj16-/- rats. Supplementation of the diet with high K+ was protective against mortality resulting from aldosterone-mediated mechanisms. Captopril and losartan treatment had no effect on the survival of SSKcnj16-/- rats. However, neither of these drugs prevented mortality of SSKcnj16-/- rats when switched to high Na+ diet. These studies revealed that the knockout of Kcnj16 markedly altered RAAS regulation and function, suggesting Kir5.1 as a key regulator of the RAAS, particularly when exposed to changes in dietary sodium and potassium content.
NADPH oxidase 4 (NOX4) is the most abundant NOX isoform in the kidney; however, its importance for renal function has only recently emerged. The NOX4‐dependent pathway regulates many factors essential for proper sodium handling in the distal nephron. However, the functional significance of this pathway in the control of sodium reabsorption during the initiation of chronic kidney disease is not established. The goal of this study was to test Nox4‐dependent ENaC regulation in two models: SS hypertension and STZ‐induced type 1 diabetes. First, we showed that genetic ablation of Nox4 in Dahl salt‐sensitive (SS) rat attenuated a high‐salt (HS)‐induced increase in epithelial Na+ channel (ENaC) activity in the cortical collecting duct. We also found that H2O2 upregulated ENaC activity, and H2O2 production was reduced in both the renal cortex and medulla in SSNox4−/− rats fed an HS diet. Second, in the streptozotocin model of hyperglycemia‐induced renal injury ENaC activity in hyperglycemic animals was elevated in SS but not SSNox4−/− rats. NaCl cotransporter (NCC) expression was increased compared to healthy controls, while expression values between SS and SSNox4−/− groups were similar. These data emphasize a critical contribution of the NOX4‐mediated pathway in maladaptive upregulation of ENaC‐mediated sodium reabsorption in the distal nephron in the conditions of HS‐ and hyperglycemia‐induced kidney injury.
This study shows strong ACE-inhibiting effects of IW, EW and WL in HUVECs and aorta. The peptides effectively counteract angiotensin-induced vasoconstriction and preserve endothelium-dependent vessel relaxation. Thus, tryptophan-containing peptides and particularly IW may serve as innovative food additives with the goal of protection from angiotensin II-induced worsening of vascular function.
Our current knowledge of the properties of renal ion channels responsible for electrolytes and cell energy homeostasis mainly relies on rodent studies. However, it has not been established yet to what extent their characteristics can be generalized to those of humans. The present study was designed to develop a standardized protocol for the isolation of well-preserved glomeruli and renal tubules from rodent and human kidneys and to assess the functional suitability of the obtained materials for physiological studies. Separation of nephron segments from human and rodent kidneys was achieved using a novel vibrodissociation technique. The integrity of isolated renal tubules and glomeruli was probed via electrophysiological analysis and fluorescence microscopy, and the purity of the collected fractions was confirmed using quantitative RT-PCR with gene markers for specific cell types. The developed approach allows rapid isolation of well-preserved renal tubules and glomeruli from human and rodent kidneys amenable for electrophysiological, Ca2+ imaging, and omics studies. Analysis of the basic electrophysiological parameters of major K+ and Na+ channels expressed in human cortical collecting ducts revealed that they exhibited similar biophysical properties as previously reported in rodent studies. Using vibrodissociation for nephron segment isolation has several advantages over existing techniques: it is less labor intensive, requires little to no enzymatic treatment, and produces large quantities of well-preserved experimental material in pure fractions. Applying this method for the separation of nephron segments from human and rodent kidneys may be a powerful tool for the indepth assessment of kidney function in health and disease.
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