Experimental nephrology最新文献

Background/aim: The new immunosuppressant SDZ RAD, a rapamycin derivative, inhibits growth factor driven cell proliferation. SDZ RAD designed for transplantation may also be a candidate agent to treat inflammatory kidney diseases. Therefore, we investigated the effects of SDZ RAD in two different animal models of glomerulonephritis, in anti- Thy1.1 nephritis and in acute puromycin aminonucleoside (PAN) nephrosis.

Methods: Eighty-seven male Wistar rats were investigated. Anti-Thy1.1 nephritis: healthy rats (n = 9), SDZ RAD-treated healthy rats (n = 6), nephritic rats (n = 9), SDZ RAD placebo treated nephritic rats (n = 6), SDZ RAD-pretreated nephritic rats (n = 9), and early (n = 6) as well as delayed (n = 6) SDZ RAD-posttreated nephritic rats. PAN nephrosis: healthy rats (n = 6), SDZ RAD-treated healthy rats (n = 6), nephritic rats (n = 12), and SDZ RAD-pretreated nephritic rats (n = 12). In a separate study, 12 male Sprague-Dawley rats were analyzed in anti-Thy1.1 nephritis: healthy rats (n = 3), nephritic rats (n = 3) and pretreated nephritic rats (n = 6). SDZ RAD and SDZ RAD placebo were given at single doses of 2.5 mg/kg body weight per day by gavage. The experiments lasted until days +2 and +9 after induction of anti-Thy1. 1 nephritis and until day +13 in the case of PAN nephrosis.

Results: In anti-Thy1.1 nephritis, SDZ RAD demonstrated marked proinflammatory effects in a time-dependent manner, as reflected by severe focal damage to glomerular histology including inhibition of mesangial cell proliferation, reduction of creatinine clearance, and increase in plasma creatinine levels as well as proteinuria. Almost identical results were obtained in both rat strains. In contrary, SDZ RAD ameliorated significantly the development of PAN nephrosis. Animals pretreated by this agent showed a significant reduction of proteinuria and of glomerular invasion of monocytes/macrophages.

Conclusion: Some caution is warranted for the use of SDZ RAD in inflammatory glomerular diseases, since it accentuated glomerular damage induced by anti-Thy1.1 antibodies.

Glomerulonephritis is a significant factor fueling the rapid increase in the population of patients with end-stage renal disease. Novel therapeutic strategies targeting specific mechanisms of glomerular destruction are the most reasonable approaches to arrest ongoing injury. In this review, we summarize some of our results obtained in our effort to characterize the role of 15-lipoxygenase activation as one of the mechansisms operative during the early, prefibrotic stage of glomerular immune injury. We also summarize the effects of cytokines released during these processes, as well as the activation by aspirin of the synthesis of 15-R-HETE (see text). Finally, we will propose a clinical approach to this group of disorders, based on emerging concepts of the pathophysiology of glomerulonephritis from our work and that of several other investigators.

Several animal models for Alport syndrome have been described. These are available for studies on the pathogenetic mechanisms of the disease, as well as for the development of new technologies for gene therapy in this progressive hereditary kidney disease. This review summarizes current knowledge on the molecular basis of Alport syndrome, and on the animal models which all remarkably well resemble the human disease. Recent work aimed at the development of gene therapy, including hurdles and progress are discussed.

Although the importance of the human kidney in a variety of disease states is well recognised, the exact mechanisms involved remain unclear. Animal disease models suggest that while high local concentrations of nitric oxide (NO) may play a key role in the initiation and progression of renal disease, low levels may also be essential for normal renal function and cell protection, possibly explaining the variable reports of both beneficial and detrimental responses of renal disease models following NO inhibition. NO has both physiological and pathological roles and clearly a balance between these two primary roles is likely to prevail leading to the conclusion that partial rather than total inhibition of NO production may be beneficial. Despite increasing evidence for the role of NO from animal disease models, little is known of the role of NO and potential modulators within the human kidney. In this review we describe three series of studies during which we examined the ability of primary cultures of human proximal tubular cells to produce NO in response to inflammatory cytokines and the possible role of potential modulators such as the natriuretic peptides. Following challenge with the combination of inflammatory cytokines IL-1beta, TNF-alpha, and IFN-gamma, such cultures exhibit a time-dependent increase in inducible NO synthetase induction and corresponding NO production, an effect which was inhibited by L-NMMA. In the second series of studies we demonstrated that increasing concentrations of atrial natriuretic factor (ANF) or C((4-23))ANF could stimulate a time- and concentration-dependent increase in nitric oxide production which was again abolished by L-NMMA. These results suggested that ANF acting at the natriuretic peptide receptor C could stimulate nitric oxide production in human proximal tubular cells. In the final series of studies we demonstrated that pro-inflammatory cytokine-induced nitric oxide production could be inhibited by ANF, brain natriuretic peptide, C-type natriuretic peptide or C((4-23))ANF. The actions of the natriuretic peptides and C((4-23))ANF was to return pro-inflammatory nitric oxide production to those observed when human proximal tubular cells were incubated with ANF alone indicating that this inhibition was mediated via the natriuretic peptide receptor C. The function of NO in the kidney is unclear but undoubtedly it has both beneficial and detrimental actions which in health remain in balance. However, when the kidney is subjected to an immune challenge, high cytotoxic levels of NO are produced locally and appear to be responsible for local damage, unfortunately total inhibition of NO production during such disease states does not always result in benefit. Clearly total abolition of an NO response removes important integral protective actions such as vasodilation. In the ideal situation, treatment of disease processes related to NO excess would involve the inhibition of these high local levels while still

The clinical utility of cyclosporin A (CyA) as an immunosuppressive agent has been significantly limited by the frequent occurrence of chronic nephrotoxicity, characterised by tubular atrophy, interstitial fibrosis and progressive renal impairment. The pathogenesis of this condition remains poorly understood, but has been postulated to be due to either direct cytotoxicity or indirect injury secondary to chronic renal vasoconstriction. Using primary cultures of human proximal tubule cells (PTCs) and renal cortical fibroblasts (CFs) as an in vitro model of the tubulointerstitium, we have been able to demonstrate that clinically relevant concentrations of CyA are directly toxic to these cells and promote fibrogenesis by a combination of suppressed matrix metalloproteinase activity and augmented fibroblast collagen synthesis. The latter effect occurs secondary to the ability of CyA to stimulate autocrine secretion of insulin-like growth factor-I by CFs and paracrine secretion of transforming growth factor-beta(1) by PTCs. Many of these pro-fibrotic mechanisms are completely reversed by concurrent administration of the angiotensin-converting enzyme inhibitor, enalaprilat, which has proven efficacy in preventing chronic CyA nephropathy in vivo. These studies highlight the unique potential that human renal cell cultures offer for studying the role of local cytokine networks in tubulointerstitial disease and for developing more effective treatment strategies which specifically target fibrogenic growth factor activity following nephrotoxic injuries.

Most chronic human kidney diseases are characterized by a final common pathway consisting of interstitial inflammation and ultimately leading to interstitial fibrosis. Within this process, tubular epithelial cells (TECs) play a critical role. Both in vitro and in vivo it has been demonstrated that TECs are an important source of various cytokines, chemokines, growth factors, adhesion molecules and extracellular matrix components. In the present review we will outline the capacity of TECs to produce inflammatory mediators and discuss the different mechanisms involved in the regulation of production of these mediators.

Background: Development of the culture of renal epithelial cells in a serum-free growth medium was driven by the need to examine the effects of hormones and other effector molecules on differentiated cell function without interference from the complex mixture of substances in serum. The present report details this laboratory's cumulative experience in the use of a defined growth medium for the propagation of epithelial cells from adult, fetal, and malignant human renal tissue.

Methods: Routine cell culture technology was used to determine the capability of a defined growth medium to support the growth of renal epithelial cells isolated by collagenase dissociation of tissue from adult and fetal kidneys, renal cell carcinoma, and Wilms' tumors.

Results: The defined growth medium formulation consistently allows the isolation and growth of transporting renal epithelial cells from both normal adult and fetal kidneys. This growth medium only rarely supports the growth of epithelial cells from renal cell carcinomas and Wilms' tumors.

Conclusions: The method developed for the culture of human proximal tubule cells requires minimal cell culture expertise and equipment, and results in the repeatable isolation of transporting epithelial cell cultures that retain features of differentiated proximal tubule cells.

An in vitro model was used to investigate the terminal differentiation mechanisms leading from embryonic to adult renal tissue. For these experiments the capsula fibrosa with adherent embryonic tissue was isolated from neonatal rabbit kidneys. These explants were mounted onto special tissue carriers and cultured in medium containing serum for 24 h. During that time collecting duct (CD) cells grew out and formed a monolayered epithelium covering the whole surface of the explant. The carriers were then transferred to perfusion culture containers to obtain an optimal degree of differentiation. A special type of container allowed us to continuously superfuse the epithelia with individual media on the luminal and basal sides. Using this method it became possible to culture embryonic CD epithelia in a fluid gradient for weeks. The epithelia were superfused with standard Iscove's modified Dulbecco's medium (IMDM) on the basal side, while IMDM containing additional NaCl was used on the luminal side. In controls IMDM was superfused on both the luminal and basal sides. It was found that the degree of differentiation in the CD epithelia is dependent on the influence of fluid gradient exposure. Perfusion culture under isotonic conditions revealed that less than 5% of cells were immunopositive for principal and intercalated cell features, while epithelia cultured in a luminal-basal gradient showed more than 80% positive cells. Immunoreactivity for characteristic markers started to develop after an unexpectedly long latent period of 3-6 days, then increased continuously during the following 5 days and reached a maximum on day 14. After switching back from the gradient to isotonic culture conditions the immunoreactivity for some markers decreased within 5 days, while other characteristic features remained stable. Thus, differentiation was not only under the control of growth factors but was also regulated by the electrolyte environment.

Chronic renal diseases with highly enhanced glomerular permeability to proteins are accompanied by tubulointerstitial inflammation and scarring and progression to renal failure. As a consequence of increased glomerular permeability, proteins filtered through the glomerular capillary in excessive amount have intrinsic renal toxicity at least partially linked to their accumulation in the proximal tubular cell cytoplasm during the process of reabsorption along the nephron. Experimental evidence is available showing that protein overload per se activates proximal tubular epithelial cells in culture to upregulate genes encoding for endothelin, chemokines and cytokines. These vasoactive and inflammatory substances, formed in excessive quantities by the tubular cells, are released mainly into the basolateral compartment, a pattern of secretion that in the kidney would favor recruitment and activation of inflammatory cells into the renal interstitium and fibrogenic reaction leading to renal scarring.

Targeted oncogenesis in transgenic mice, where an oncogene is placed under the control of the regulatory sequences of a cell-specific gene, has been used to derive several new types of differentiated nonepithelial and epithelial cell lines. This review summarizes the properties of cell lines derived from proximal, distal and collecting duct cells. The cells were obtained from kidneys of transgenic mice harboring the 5' regulatory sequences of the L-type pyruvate kinase or vimentin genes controlling the expression of either the large T and little t antigens or the temperature-sensitive large T antigen.