Apoptosis of endothelial cells (EC) is appreciated as a primary pathogenic event in systemic sclerosis. Yet, how apoptosis of EC leads to fibrosis remains to be determined. We report that apoptosis of EC triggers the release of novel fibrogenic mediators. Medium conditioned by apoptotic EC (SSC) was found to inhibit apoptosis of fibroblasts, whereas medium conditioned by EC in which apoptosis was blocked (with either pan-caspase inhibition or Bcl-xL overexpression) did not. PI3K was activated in fibroblasts exposed to SSC. This was associated with downstream repression of Bim-EL and long-term up-regulation of Bcl-xL protein levels. RNA interference for Bim-EL in fibroblasts blocked apoptosis. SSC also induced PI3K-dependent myofibroblast differentiation with expression of α-smooth muscle actin, formation of stress fibers, and production of collagen I. A C-terminal fragment of the domain V of perlecan was identified as one of the fibrogenic mediators present in SSC. A synthetic peptide containing an EGF motif present on the perlecan fragment and chondroitin 4-sulfate, a glycosaminoglycan anchored on the domain V of perlecan, induced PI3K-dependent resistance to apoptosis in fibroblasts and myofibroblast differentiation. Human fibroblasts derived from sclerodermic skin lesions were more sensitive to the antiapoptotic activities of the synthetic peptide and chondroitin 4-sulfate than fibroblasts derived from normal controls. Hence, we propose that a chronic increase in endothelial apoptosis and/or increased sensitivity of fibroblasts to mediators produced by apoptotic EC could form the basis of a fibrotic response characterized by sustained induction of an antiapoptotic phenotype in fibroblasts and persistent myofibroblast differentiation.
Increased endothelial apoptosis and decreased apoptosis of vascular smooth muscle cells (VSMC) are central to initiation of myo-intimal thickening. We hypothesized that apoptosis of endothelial cells (EC) induces the release of anti-apoptotic mediator(s) active on VSMC. We found that serum-free medium conditioned by apoptotic EC decreases apoptosis of VSMC compared with fresh serum-free medium. Inhibition of endothelial apoptosis during conditioning with a pan-caspase inhibitor ZVAD-FMK blocked the release of the anti-apoptotic factor(s) active on VSMC. VSMC exposed to serum-free medium conditioned by apoptotic EC showed increased ERK 1/2 phosphorylation, enhanced Bcl-xl expression, and inhibition of p53 expression. Fractionation of the conditioned medium followed by mass spectral analysis identified one bioactive component as a C-terminal fragment of the domain V of perlecan. Serum-free medium supplemented with either a synthetic peptide containing the EGF motif of the domain V of perlecan or chondroitin 4-sulfate, a glycosaminoglycan anchored on the domain V of perlecan, increased ERK 1/2 phosphorylation and Bcl-xl protein levels while inhibiting apoptosis of VSMC. These results suggest that a proteolytic activity developing downstream of activated caspases in apoptotic EC initiates degradation of pericellular proteoglycans and liberation of bioactive fragments with a robust impact on inhibition of VSMC apoptosis.
Proteolysis of extracellular matrix components and the production of cryptic bioactive factors play key roles in vascular remodeling. We showed previously that extracellular matrix proteolysis is triggered by the apoptosis of endothelial cells (EC), resulting in the release of an anti-apoptotic C-terminal fragment of endorepellin (LG3). Here, we characterize the endorepellin-cleaving proteases released by apoptotic EC using a multifaceted proteomics strategy. Cathepsin L (CathL), a cysteine protease known to be associated with cardiovascular disease progression in animal models and humans, was isolated from medium conditioned by apoptotic EC. CathL cleaved recombinant endorepellin in vitro, leading to LG3 release. Inhibition of CathL activity in EC exposed to pro-apoptotic stimuli prevented LG3 release without modulating the development of apoptosis in EC. Inhibition of caspase-3 activation in EC with the biochemical inhibitor DEVD-fluoromethyl ketone or small interfering RNAs concomitantly prevented CathL release by EC, LG3 production, and the development of paracrine anti-apoptotic activity. These data demonstrate that caspase-3 activation is a novel pathway of importance for triggering extracellular CathL release and the cleavage of extracellular matrix components. Apoptosis of endothelial cells (EC)4 is increasingly recognized as an important component of the "response to injury" process, as most clinical risk factors of atherosclerosis (such as hypertension (1, 2), hyperglycemia (3, 4), oxidized low density lipoproteins (LDLs) (5, 6) and oxidative stress (7)) induce EC apoptosis. Interventions aimed at preventing EC apoptosis in animal models of transplant vasculopathy, an immune-mediated form of atherosclerosis, prevent neointima formation, indicating that EC apoptosis is an important pro-atherosclerotic trigger (8 -13). During vascular remodeling, EC injury and apoptosis are followed by migration of ␣-smooth muscle actinpositive cells (smooth muscle cells (SMC) and myofibroblasts) that accumulate within the intima through a state of resistance to apoptosis largely dependent on Bcl-xl overexpression (14 -16).Recent evidence from our group and others suggests that apoptotic EC favor neointima formation through the release of paracrine mediators, which in turn, increase Bcl-xl expression and inhibit the apoptosis of vascular SMC and fibroblasts (17)(18)(19)(20). The production of biologically active mediators by apoptotic EC is at least partially dependent on pericellular proteolysis, leading to basement membrane and extracellular matrix (ECM) degradation with the release of cryptic anti-apoptotic factors (18 -20). A C-terminal fragment of endorepellin (perlecan domain V) released in association with EC apoptosis was found to heighten Bcl-xl expression in SMC and fibroblasts (18 -20). Perlecan is a basement membrane modular proteoglycan composed of five structural domains (21). The C-terminal domain, also called endorepellin, comprises three laminin-like globular (LG1-LG3) modules interspaced by four epiderm...
We have recently found that stable R-loop formation occurs in vivo and in vitro when a portion of the Escherichia coli rrnB operon is transcribed preferentially in its physiological orientation. Our results also suggested that the formation of such structures was more frequent in topA mutants and was sensitive to the template DNA supercoiling level. In the present report we investigated in greater detail the involvement of DNA topoisomerases in this process. By using an in vitro transcription system with phage RNA polymerases, we found that hypernegative supercoiling of plasmid DNAs in the presence of DNA gyrase is totally abolished by RNase H, suggesting that extensive R-looping occurs during transcription in the presence of DNA gyrase. When RNase A is present, significant hypernegative supercoiling occurs only when the 567-base pair rrnB HindIII fragment is transcribed in its physiological orientation. This result suggests that more stable R-loops are being produced in this orientation. Our results also suggest that DNA gyrase can participate in the process of R-loop elongation. The strong transcription-induced relaxing activity of E. coli DNA topoisomerase I is shown to efficiently counteract the effect of DNA gyrase and thus inhibit extensive R-looping. In addition, we found that an R-looped plasmid DNA is a better substrate for relaxation by E. coli DNA topoisomerase I as compared with a non-R-looped substrate.DNA topoisomerases are enzymes involved in the regulation of DNA conformation (for a review see Ref. 1). Since the topology of DNA affects most of its functions, DNA topoisomerases are considered key elements in the regulation of genomic activities. In bacteria, they are involved in the control of chromosomal DNA supercoiling (2). This task is apparently performed by two DNA topoisomerases with opposite enzymatic activities: DNA topoisomerase I (originally known as protein), encoded by the topA gene that specifically relaxes negative supercoiling (3), and DNA gyrase encoded by the gyrA and gyrB genes that introduces negative supercoiling into the DNA (4). The involvement of DNA topoisomerases in every step of DNA replication, namely initiation, elongation, and termination is also well known in bacteria (5). Although much is known about the role of DNA topoisomerases in transcription initiation through the modulation of DNA supercoiling level (6), little is known about their involvement in the two following steps, namely elongation and termination.The tight association of DNA topoisomerases with actively transcribed genes has been well-described in eucaryotes (7-13). In bacteria, changes in plasmid DNA supercoiling in topoisomerase mutants have been linked to transcription elongation in some cases (14,15). Hence, the production of positively supercoiled plasmid DNA upon DNA gyrase inactivation (16) is linked to transcription elongation (15). In the absence of the topA gene function, the production of hypernegatively supercoiled plasmid DNA (17) has also been linked to transcription elongation (14). How...
A single-center cohort study of kidney and kidneypancreas recipients was conducted to evaluate the association between new immunosuppressive regimens and risk of thrombotic microangiopathy (TMA). From January 1st,1996 to December 31, 2002, 368 patients received a kidney or kidney-pancreas transplant at our center. Four immunosuppressive regimens were evaluated as potential risk factors of TMA: cyclosporin + mycophenolate mofetil (CsA + MMF), cyclosporin + sirolimus (CsA + SRL), tacrolimus + myophenolate mofetil (FK + MMF), and tacrolimus + sirolimus (FK + SRL). Thirteen patients developed biopsy-proven TMA in the absence of vascular rejection. The incidence of TMA was significantly different in the four immunosuppressive regimens studied (p < 0.001). The incidence of TMA was highest in the CsA + SRL group (20.7%). The relative risk of TMA was 16.1 [95% confidence interval (CI): 4.3-60.8] for patients in the CsA + SRL group as compared with those in the FK + MMF group. We also investigated in vitro the pathophysiological basis of this association. The CsA-SRL combination was found to be the only regimen that concomitantly displayed pro-necrotic and anti-angiogenic activities on arterial endothelial cells. We propose that this combination concurs to development of TMA through dual activities on endothelial cell death and repair.
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