Bilateral native nephrectomy improves renal isograft function in rats

Bilateral native nephrectomy improves renal isograft function in rats. Bilateral native nephrectomy has been suggested to improve renal allograft survival in man. This effect may be most prominent in patients experiencing acute tubular necrosis following transplantation. Thus, native kidneys may alter the course of ischemic acute tubular necrosis in the transplanted kidney. In the present studies, we utilized an experimental model of syngeneic transplantation in which rejection does not occur. We studied Lewis rat renal isografts transplanted into littermates following sham, unilateral or bilateral native nephrectomy. In a fourth group of rats, we evaluated the importance of native kidney excretory function by studying isografts transplanted into littermates with bilaterally obstructed native kidneys. Renal blood flow and excretory function were measured in vivo, eight days following transplantation. Renal excretory function of isografts transplanted into animals following bilateral native nephrectomy was similar to normal nontrans-planted Lewis kidneys. The presence of either one or both functioning native kidneys significantly reduced isograft inulin clearance, PAH clearance, and blood flow. However, when isografts were transplanted into Lewis rats with bilaterally obstructed native kidneys, renal isograft inulin clearance and blood flow were not significantly impaired Non-transplanted kidneys demonstrated “functional hypertrophy” following contralateral nephrectomy, with glomerular filtration rate and renal blood flow increasing by approximately 50%. In contrast, isograft glomerular filtration rate in animals following bilateral native nephrectomy was equivalent to that of single kidneys from normal animals with both kidneys in situ. However, renal blood flow of isografts from these animals increased to the same level as nontransplanted Lewis kidneys following contralateral nephrectomy. Histological examination of isografts from animals with functioning native kidneys in situ demonstrated extensive disruption of normal renal architecture with tubular and interstitial injury. This was in marked contrast to the appearance of Lewis–Brown Norway allografts, to isografts from animals following bilateral native nephrectomy, and to isografts from animals with bilaterally obstructed native kidneys. In Lewis–Brown Norway allografts, there was evidence of rejection with active inflammatory cell infiltration, arteriolitis and venulitis. In isografts from animals following bilateral native nephrectomy or with bilaterally obstructed native kidneys, renal architecture was normal. Thus, the detrimental effect of native kidneys on isograft function may be related to impaired recovery from ischemia or potentiation of ischemic injury which occurs during the transplantation procedure

bFGF and its low affinity receptors in the pathogenesis of HIV-associated nephropathy in transgenic mice

bFGF and its low affinity receptors in the pathogenesis of HIV-associated nephropathy in transgenic mice. HIV-associated nephropathy is characterized by extensive tubulointerstitial disease with epithelial cell injury, microcystic proliferation, and tubular regeneration with glomerulosclerosis. To explore the role of bFGF as a mediator of HIV-induced interstitial disease, we utilized an HIV transgenic mouse model that manifests clinical and histological features observed in patients. In transgenic mice, simultaneous renal epithelial cell proliferation and injury were detected in vivo. In areas of microcystic proliferation, immunoreactive bFGF colocalized with extracellular matrix. Kidneys from transgenic mice had increased bFGF low affinity binding sites, particularly in the renal interstitium. In vitro, transgenic renal tubular epithelial cells proliferated more rapidly and generated tubular structures spontaneously, in marked contrast to nontransgenic renal cells where these pathologic features could be mimicked by exogenous bFGF. These studies suggest that renal bFGF and its receptors play an important role in the pathogenesis of HIV-associated nephropathy

Chronic rejection of mouse kidney allografts

Chronic rejection of mouse kidney allografts.BackgroundChronic renal allograft rejection is the leading cause of late graft failure. However, its pathogenesis has not been defined.MethodsTo explore the pathogenesis of chronic rejection, we studied a mouse model of kidney transplantation and examined the effects of altering the expression of donor major histocompatibility complex (MHC) antigens on the development of chronic rejection.ResultsWe found that long-surviving mouse kidney allografts develop pathological abnormalities that resemble chronic rejection in humans. Furthermore, the absence of MHC class I or class II antigens did not prevent the loss of graft function nor alter the pathological characteristics of chronic rejection. Expression of transforming growth factor-β (TGF-β), a pleiotropic cytokine suggested to play a role in chronic rejection, was markedly enhanced in control allografts compared with isografts. However, TGF-β up-regulation was significantly blunted in MHC-deficient grafts. Nonetheless, these differences in TGF-β expression did not affect the character of chronic rejection, including intrarenal accumulation of collagens.ConclusionsReduced expression of either class I or II direct allorecognition pathways is insufficient to prevent the development of chronic rejection, despite a reduction in the levels of TGF-β expressed in the allograft. This suggests that the severity of chronic rejection is independent of the level of MHC disparity between donor and recipient and the level of TGF-β expression within the allograft

Expression of HIV transgene aggravates kidney injury in diabetic mice

With the widespread use of combination antiretroviral agents, the incidence of HIV-associated nephropathy has decreased. Currently, HIV-infected patients live much longer and often suffer from comorbidities such as diabetes mellitus. Recent epidemiological studies suggest that concurrent HIV infection and diabetes mellitus may have a synergistic effect on the incidence of chronic kidney disease. To address this, we determined whether HIV-1 transgene expression accelerates diabetic kidney injury using a diabetic HIV-1 transgenic (Tg26) murine model. Diabetes was initially induced with low-dose streptozotocin in both Tg26 and wild-type mice on a C57BL/6 background, which is resistant to classic HIV-associated nephropathy. Although diabetic nephropathy is minimally observed on the C57BL/6 background, diabetic Tg26 mice exhibited a significant increase in glomerular injury compared with nondiabetic Tg26 mice and diabetic wild-type mice. Validation of microarray gene expression analysis from isolated glomeruli showed a significant upregulation of proinflammatory pathways in diabetic Tg26 mice. Thus, our study found that expression of HIV-1 genes aggravates diabetic kidney disease

The imperative to invest in science has never been greater

In order to sustain and improve the health of Americans, to ensure our ability to overcome new health challenges, and to realize the economic benefits of a vigorous scientific economy, we encourage our government to implement three actions. First, establish predictable, managed growth in the US scientific enterprise by establishing a sustainable and predictable real annual increase in science funding. This will require additional investments in the proven NIH-university partnership to maintain our world-leading position in biomedical science. Second, preserve the current cadre of well-trained junior scientists, including physician-scientists, and maintain a pipeline of young scientists motivated to innovate and improve health. Third, analyze changing health needs and priorities for health science–related investments in order to address ongoing shifts in population demographics and diseases, opportunities for improved prevention or treatment, and the availability of new scientific tools and disciplines. It is in the nation’s best interests -- for good health, for a robust economy, and for scientific leadership -- to advocate for strong federal support of biomedical science in America’s great research universities. Translation of this science yields enormous benefits to our nation’s health and to the economy

FAT10: a Novel Mediator of Vpr-Induced Apoptosis in Human Immunodeficiency Virus-Associated Nephropathy▿

Human immunodeficiency virus (HIV)-associated nephropathy is a significant cause of morbidity and mortality in HIV-infected persons. Vpr-induced cell cycle dysregulation and apoptosis of renal tubular epithelial cells are important components of the pathogenesis of HIV-associated nephropathy (HIVAN). FAT10 is a ubiquitin-like protein that is upregulated in renal tubular epithelial cells in HIVAN. In these studies, we report that Vpr induces increased expression of FAT10 in tubular cells and that inhibition of FAT10 expression prevents Vpr-induced apoptosis in human and murine tubular cells. Moreover, we found that Vpr interacts with FAT10 and that these proteins colocalize at mitochondria. These studies establish FAT10 as a novel mediator of Vpr-induced cell death