Monocyte influx secondary to ischemia-reperfusion conditions the renal allograft to rejection by presentation of antigens and production of cytokines. Monocyte influx depends on NFkappaB-dependent transcription of genes encoding adhesion molecules and chemokines. Here we demonstrate that cationic liposomes containing phosphorothioated oligodeoxynucleotides (ODN) with the kappaB binding site serving as competitive binding decoy, can prevent TNF-alpha-induced NFkappaB activity in endothelial cells in vitro. In an allogenic rat kidney transplantation model (BN to LEW), we show that perfusing the renal allograft with this decoy prior to transplantation abolishes nuclear NFkappaB activity in vivo and inhibits VCAM-1 expression in the donor endothelium (P<0.05). At 24 h postreperfusion, periarterial infiltration of monocytes/macrophages was significantly reduced in decoy ODN-treated allografts compared to control allografts (3.7+/-0.7 vs. 9.2+/-1.2 macrophages/vessel; P<0.01). At 72 h, there was a reduction of tubulointerstitial macrophage infiltration in decoy ODN-treated kidneys compared to controls (75.6+/-13.9 vs. 120.0+/-11.2 macrophages/tubulointerstitial area; P<0.05). In conclusion, perfusion of the renal allograft with NFkappaB decoy ODN prior to transplantation decreases the initial inflammatory response in a stringent, nonimmunosuppressed allogenic transplantation model. Therefore, the NFkappaB decoy approach may be useful to explore the role of endothelium and macrophages in graft rejection and may be developed into a graft-specific immunosuppressive strategy allowing reduction of systemic immunosuppression on organ transplantation.
In these studies, we find that the vascular endothelial growth factor (VEGF) receptor KDR is expressed on subsets of mitogenactivated CD4 ؉ and CD8 ؉ T cells in vitro. We also found that KDR colocalizes with CD3 on mitogen-activated T cells in vitro and on infiltrates within rejecting human allografts in vivo. To evaluate whether VEGF and KDR mediate lymphocyte migration across endothelial cells (ECs), we used an in vitro live-time transmigration model and observed that both anti-VEGF and anti-KDR antibodies inhibit the transmigration of both CD4 ؉ and CD8 ؉ T cells across tumor necrosis factor␣ (TNF␣)-activated, but not unactivated ECs. In addition, we found that interactions among CD4 ؉ or CD8 ؉ T cells and TNF␣-activated ECs result in the induction of KDR on each T cell subset, and that KDRexpressing lymphocytes preferentially transmigrate across TNF␣-activated ECs. Finally, using a humanized severe combined immunodeficient mouse model of lymphocyte trafficking, we found that KDRexpressing lymphocytes migrate into human skin in vivo, and that migration is reduced in mice treated with a blocking anti-VEGF antibody. IntroductionVascular endothelial growth factor (VEGF), an angiogenesis factor, is established to function in the migration, proliferation, and survival of endothelial cells (ECs). 1,2 VEGF is well known to function in wound healing, organ development, and tumor growth and it serves to promote tissue protection and repair after acute injury. 3 VEGF is also expressed in association with cell-mediated immune inflammation and acute and chronic inflammatory reactions. 4 In chronic inflammatory disease processes, VEGF fails to elicit effective tissue repair, and rather may induce a pathologic form of angiogenesis that has been proposed to augment disease activity. 4,5 Indeed, several studies have demonstrated that blockade of VEGF may attenuate the progression of chronic diseases such as arthritis, atherosclerosis, and allograft rejection. [6][7][8] Although relatively underappreciated, VEGF has potent proinflammatory properties including an ability to mediate leukocyte trafficking into sites of cell-mediated immunity. [7][8][9][10][11][12][13] The proinflammatory properties of VEGF are reported to be dependent on its ability to interact directly with monocytes resulting in chemotaxis, 10 its ability to induce the expression of endothelial adhesion molecules 9,11 and chemokine production, 8,12,14 and its ability to enhance vascular permeability. 2 Furthermore, VEGF has been reported to have direct chemoattractant effects on murine and human T cells, 13,15 and blockade of VEGF in vivo has been found to inhibit lymphocyte trafficking into skin and rejecting cardiac allografts. 8,16,17 However, the mechanism underlying the ability of VEGF to interact with T cells is not known, and the molecular basis for its ability to facilitate lymphocyte chemotaxis in vitro or in vivo is poorly understood.Several recent studies have determined that the VEGF receptors Flt-1 (VEGF receptor 1), KDR (VEGF receptor 2) and neu...
Oxidative stress contributes to the development of early transplant failure. As nitric oxide synthases (NOS) can act as sources of superoxide, we investigated the effect of the NOS cofactor tetrahydrobiopterin (BH4) on oxyradical production and early rejection in a rat kidney transplantation model. Allograft transplantation (Brown Norway to Lewis) showed more renal superoxide production and monocyte infiltration when compared with isografts (Lewis to Lewis). Administration of the stable BH4 precursor sepiapterin had no effect on superoxide production in the isografts (51+/-10 vs. 69+/-17 cps/10 mg protein), but led to a marked decrease in superoxide production in the allografts (116+/-11 vs. 60+/-6 cps/10 mg protein; P<0.05) and was accompanied by a reduction in periarterial macrophage infiltration (3.3+/-0.7 vs. 1.3+/-0.3 cells/vessel; P<0.05) and an increase in NO production (78+/-22 vs. 173+/-12 AU/g kidney) (P<0.01). In vitro experiments confirm that iNOS can produce superoxide mainly from the heme domain, whereas BH4 administration can reverse this superoxide production in the presence of adequate anti-oxidant defense. Our findings support the hypothesis that BH4 can be used to modulate the function of the inflammatory iNOS isoform and suggest a potential therapeutic role for sepiapterin in early allograft rejection.
The importance of the endothelial isoform of nitric oxide synthase (eNOS) has been well established. Endothelium-derived nitric oxide has been shown to be essential for vascular homeostasis and modulation of eNOS has thus become a target in prevention of cardiovascular disease. The role of the inducible form of nitric oxide synthase (iNOS) in vascular biology, however, is less clear. Classically, iNOS has been regarded as an enzyme that produces nmolar amounts of the nitric oxide radical, thereby leading to cellular damage. More recent data, however, have shown that the iNOS can be a superoxide, peroxynitrite as well as a nitric oxide-producing enzyme, while the biological effects of iNOS probably depend upon the sort of radical species released by the enzyme as well as the anti-oxidant capacity of the cellular microenvironment of the enzyme. This brief review discusses these aspects in relation to renal transplantation.
This review discusses the concept that endothelial cells may facilitate inflammation, but are also targets of the inflammatory response. Endothelial cells express several molecules that promote leukocyte recruitment, and other molecules, such as MHC class I that enable endothelial injury. Circulating alloantibodies produced following transplantation may also target the endothelium for injury. It has been shown that the expression of select protective genes within endothelial cells, including anti-apoptotic genes, may provide resistance to immune-mediated injury. Thus, an understanding of the mechanisms by which endothelial cells are injured and by which endothelial cells are protected is important for our understanding of allograft rejection.
Abstract. This study investigated the role of renal nitric oxide synthase (NOS), endothelin, and possible mechanisms of renovascular dysfunction in salt-sensitive hypertension. Salt-sensitive (DS) and salt-resistant (DR) Dahl rats were treated for 8 wk with high salt diet (4% NaCl) alone or in combination with the ETA receptor antagonist LU135252 (60 mg/kg per d). Salt loading markedly increased NOS activity (pmol citrulline/mg protein per min) in renal cortex and medulla in DR but not in DS rats by 270 and 246%, respectively. Hypertension in DS rats was associated with renal artery hypertrophy, increased vascular and renal endothelin-1 (ET-1) protein content, and glomerulosclerosis. In the renal artery but not in the aorta of hypertensive DS rats, endothelium-dependent relaxation to acetylcholine was unchanged; however, endothelial dysfunction due to enhanced prostanoid-mediated, endothelium-dependent contractions and attenuation of basal nitric oxide release was present. Treatment with LU135252 reduced hypertension in part, but completely prevented activation of tissue ET-1 without affecting ET-3 levels. This was associated with a slight increase of renal NOS activity, normalization of endothelial dysfunction and renal artery hypertrophy, and marked attenuation of glomerulosclerosis. Thus, DS rats fail to increase NOS activity in response to salt loading. This abnormality may predispose to activation of the tissue ET-1 system, abnormal renal vasoconstriction, and renal injury. Chronic ETA receptor blockade normalized salt-induced changes in the renal artery and reduced glomerular injury, suggesting therapeutic potential for ET antagonists in salt-sensitive forms of hypertension.
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