Non-technical summary Like most cells, those of the kidney release protein and RNA in structures called exosomes. It is possible that the contents of exosomes released into the urine from one part of the kidney can alter the function of downstream cells. We have used a cell model to test whether exosomes act as cell-to-cell messengers within the kidney. First, cells were exposed to a hormone that regulates the body's retention of water. This increased the levels of water channels within the cells and also within their exosomes. Next, these exosomes were placed onto a separate batch of cells, which responded by increasing their transport of water. This study shows that exosomes are a new mechanism for the transfer of physiological information within the kidney.Abstract Exosomes are vesicles released following fusion of endosomes with the plasma membrane. Urine contains exosomes that are released from the entire length of the nephron and change in composition with kidney disease. Exosomes can shuttle information between non-renal cells via transfer of protein and RNA. In this study murine kidney collecting duct (mCCDC11) cells were used to demonstrate that exosomes can act as a signalling mechanism between cells. First, the release of exosomes by mCCDC11 cells was confirmed by multiple approaches. Following isopynic centrifugation, exosomal proteins flotillin-1 and TSG101 were identified in fractions consistent with exosomes. Electron microscopy demonstrated structures consistent in size and shape with exosomes. Exposure of mCCDC11 cells to the synthetic vasopressin analogue, desmopressin, did not affect exosomal flotillin-1 or TSG101 but increased aquaporin 2 (AQP2) in a doseand time-dependent manner that was highly correlated with cellular AQP2 (exosomal AQP2 vs. cellular AQP2, Pearson correlation coefficient r = 0.93). To test whether the ratio of exosomal AQP2/flotillin-1 is under physiological control in vivo, rats were treated with desmopressin. The ratio of AQP2/flotillin-1 in the urinary exosome was significantly increased. Inter-cellular signalling by exosomes was demonstrated: exosomes from desmopressin-treated cells stimulated both AQP2 expression and water transport in untreated mCCDc11 cells (water flow across cells: control exosome treatment 52.8 ± 11 μl cm −2 ; AQP2-containing exosomes 77.4 ± 4 μl cm −2 , P = 0.05, n = 4). In summary, the amount of AQP2 in exosomes released from collecting duct cells is physiologically regulated and exosomal AQP2 closely reflects cellular expression. Exosomes can transfer functional AQP2 between cells and this represents a novel physiological mechanism for cell-to-cell communication within the kidney. Abbreviations AQP2, aquaporin 2; AKI, acute kidney injury; mCCDC11, murine cortical collecting duct cell line; miRNA, microRNA; TEM, transmission electron microscopy; TSG101, tumor susceptibility gene 101.
Nucleotides are key subunits for nucleic acids and provide energy for intracellular metabolism. They can also be released from cells to act physiologically as extracellular messengers or pathologically as danger signals. Extracellular nucleotides stimulate membrane receptors in the P2 and P1 family. P2X are ATP-activated cation channels; P2Y and P1 are G-protein coupled receptors activated by ATP, ADP, UTP, and UDP in the case of P2 or adenosine for P1. Renal P2 receptors influence both vascular contractility and tubular function. Renal cells also express ectonucleotidases that rapidly hydrolyze extracellular nucleotides. These enzymes integrate this multireceptor purinergic-signaling complex by determining the nucleotide milieu to titrate receptor activation. Purinergic signaling also regulates immune cell function by modulating the synthesis and release of various cytokines such as IL1-β and IL-18 as part of inflammasome activation. Abnormal or excessive stimulation of this intricate paracrine system can be pro- or anti-inflammatory, and is also linked to necrosis and apoptosis. Kidney tissue injury causes a localized increase in ATP concentration, and sustained activation of P2 receptors can lead to renal glomerular, tubular, and vascular cell damage. Purinergic receptors also regulate the activity and proliferation of fibroblasts, promoting both inflammation and fibrosis in chronic disease. In this short review we summarize some of the recent findings related to purinergic signaling in the kidney. We focus predominantly on the P2X7 receptor, discussing why antagonists have so far disappointed in clinical trials and how advances in our understanding of purinergic signaling might help to reposition these compounds as potential treatments for renal disease.
This study suggests that RSV infection and influenza contribute to IPD incidence peaks differently for children than for adults. Data from other geographic areas and more rigorous study designs are required to confirm these findings.
These data show a sustained and substantial decline in severe rotavirus disease and all-cause AGE since the introduction of rotavirus vaccination, most pronounced in the target age group, but with evidence of herd immunity. The impact of rotavirus vaccination in Indigenous children in hyperendemic settings was less remarkable.
The regulation of extracellular fluid volume is a key component of blood pressure homeostasis. Long-term blood pressure is stabilized by the acute pressure natriuresis response by which changes in renal perfusion pressure evoke corresponding changes in renal sodium excretion. A wealth of experimental evidence suggests that a defect in the pressure natriuresis response contributes to the development and maintenance of hypertension. The mechanisms underlying the relationship between renal perfusion pressure and sodium excretion are incompletely understood. Increased blood flow through the vasa recta increases renal interstitial hydrostatic pressure, thereby reducing the driving force for transepithelial sodium reabsorption. Paracrine signalling also contributes to the overall natriuretic response by inhibiting tubular sodium reabsorption in several nephron segments. In this brief review, we discuss the role of purinergic signalling in the renal control of blood pressure. ATP is released from renal tubule and vascular cells in response to increased flow and can activate P2 receptor subtypes expressed in both epithelial and vascular endothelial/smooth muscle cells. In concert, these effects integrate the vascular and tubular responses to increased perfusion pressure and targeting P2 receptors, particularly P2X7, may prove beneficial for treatment of hypertension.
Salt crystallisation in pores is known to cause serious damage to masonry. Sodium sulphate, often regarded as one of the most damaging salts, has a rich hydrate chemistry including one rediscovered metastable hydrate and a new high pressure octahydrate plus five known polymorphs of the anhydrous phase. The difficulty in working with these hydrates lies in their strong tendency to dehydrate or to convert to the stable phase, in the case of the heptahydrate. We present Raman spectra and a table of peak wave numbers for randomly oriented crystals of mirabilite and the metastable heptahydrate, sufficient to distinguish between these phases that have SO4 ν1 values of 989.3 and 987.6 cm−1, respectively. Mirabilite has a Raman spectrum very similar to the free sulphate anion in solution, which is probably due to the mobility of oxygen atoms within the sulphate tetrahedron. The oxygen atoms in the heptahydrate sulphate groups have no partial occupancy, and predicted peak splitting is observed in the region 400–1200 cm−1
The significant differential effects observed are strongly suggestive of the PCV7 program being responsible for the observed reduction in pneumonia hospitalizations in Australia, and the magnitude was comparable to that documented in countries with a booster dose. This finding appears robust and may be related to high levels of vaccination coverage and catch-up early in the program, or to relatively lower levels of serotype replacement without a booster dose.
Diabetes is a leading cause of renal disease. Glomerular mesangial expansion and fibrosis are hallmarks of diabetic nephropathy and this is thought to be promoted by infiltration of circulating macrophages. Monocyte chemoattractant protein-1 (MCP-1) has been shown to attract macrophages in kidney diseases. P2X7 receptors (P2X7R) are highly expressed on macrophages and are essential components of pro-inflammatory signaling in multiple tissues. Here we show that in diabetic patients, renal P2X7R expression is associated with severe mesangial expansion, impaired glomerular filtration (≤ 40 ml/min/1.73 sq. m.), and increased interstitial fibrosis. P2X7R activation enhanced the release of MCP-1 in human mesangial cells cultured under high glucose conditions. In mice, P2X7R-deficiency prevented glomerular macrophage attraction and collagen IV deposition; however, the more severe interstitial inflammation and fibrosis often seen in human diabetic kidney diseases was not modelled. Finally, we demonstrate that a P2X7R inhibitor (AZ11657312) can reduce renal macrophage accrual following the establishment of hyperglycemia in a model of diabetic nephropathy. Collectively these data suggest that P2X7R activation may contribute to the high prevalence of kidney disease found in diabetics.
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