Xiujie Gao

HSP70 inhibits stress-induced cardiomyocyte apoptosis by competitively binding to FAF1

Stress-induced cardiomyocyte apoptosis plays an important role in the pathogenesis of a variety of cardiovascular diseases. Our early studies showed that HSP70 effectively inhibited apoptosis, but the underlying mechanism remained unclear. Fas-associated factor 1 (FAF1) is a member of the Fas death-inducing signaling complex (Fas-DISC) that acts upstream of caspase-8. We investigated the interactions among FAF1, HSP70, and FAS in stressed cardiomyocytes to elucidate the protective mechanism of HSP70. FAS and caspase-3/8 activity was higher in cardiomyocytes undergoing stress-induced apoptosis in restraint-stressed rats compared with cardiomyocytes in non-stressed rats, which indicated that the Fas signaling pathway was activated after restraint stress. Geranylgeranylacetone (GGA) induced an increase in HSP70 expression, which reduced stress-induced apoptosis. Additionally, overexpression of HSP70 via transfection with the pEGFP-rHSP70 plasmid attenuated norepinephrine (NE)-induced apoptosis. FAF1 expression increased during stress-induced apoptosis, and overexpression of FAF1 exacerbated NE-induced apoptosis. We also found that HSP70 interacted with FAF1. Overexpression of HSP70 inhibited the binding of FAF1 to FAS in H9C2 cells, which indicated that HSP70 suppressed NE-induced apoptosis by competitively binding to FAF1. An N-terminal deletion mutant of HSP70 (HSP70-△N) was unable to interact with FAF1. After HSP70-△N was transfected into H9C2 cells, the cells were unable to attenuate the NE-induced increases in caspase-8 and apoptosis. These results indicate that the 1–120 sequence of HSP70 binds to FAF1, which alters the interactions between FAS and FAF1 and inhibits the activation of the Fas signaling pathway and apoptosis.

The stress-related hormone norepinephrine induced upregulation of Nix, contributing to ECM protein expression

Organ fibrosis has been viewed as a major medical problem that leads to progressive dysfunction of the organ and eventually the death of patients. Stress-related hormone norepinephrine (NE) has been reported to exert fibrogenic actions in the injured organ. Nix plays a critical role in pressure overload-induced cardiac remodeling and heart failure through mediating cardiomyocyte apoptosis. However, cardiac remodeling also includes fibrosis. Whether Nix is involved in stress-induced fibrosis remains unclear. The present study was designed to determine the role of Nix in NE-induced NIH/3T3 fibroblasts. The results showed that Nix was upregulated and closely associated with cell proliferation, collagen and fibronectin expression in NIH/3T3 fibroblasts following NE treatment. Overexpression of Nix promoted collagen and fibronectin expression, whereas the suppression of Nix resulted in a strong reduction in collagen and fibronectin expression. Moreover, the increases in collagen and fibronectin expression induced by NE were successively increased when Nix was overexpressed and reduced when Nix was inhibited. Furthermore, we demonstrated that the PKC activation is responsible for the upregulation of Nix induced by NE. Inhibition of Nix expression with α-adrenoceptor antagonist, β-adrenoceptor antagonist or PKC inhibitor attenuated NE-induced collagen and fibronectin expression. Our data revealed that Nix is a novel mediator of NE-induced fibrosis. Thus, it would provide a new insight into the development of effective preventative measures and therapies of tissue fibrosis.

Inhibition of cystathionine β-synthase is associated with glucocorticoids over-secretion in psychological stress-induced hyperhomocystinemia rat liver.

Hyperhomocysteinemia (HHcy), a pathological condition characterized by an increase in plasma concentration of total homocysteine (Hcy), is recognized as a risk factor for several diseases. The transsulfuration pathway is the main metabolic fate of Hcy utilization, which requires the activity of cystathionine β-synthase (CBS). Our results showed the development of HHcy induced by psychological stress was mainly derived from a reduction of CBS activity in the liver, which was accompanied by a significant decrease in its mRNA level. It suggested that the hepatic CBS enzyme regulated by stress at the level of transcription would have a profound effect on circulating Hcy levels. The expression of Sp3, a negative factor for cbs transcription, obviously increased in hepatocytes nuclei of stressed rats, but Sp1 was not altered. It indicated that Sp3 was the key point of variations in cbs transcription caused by stress. Meanwhile, we detected that augmented plasma Hcy concentrations correlated with glucocordicoids (GCs) over-secretion in response to stress, and CBS mRNA levels were markedly lowered in GCs-treated rat hepatocytes. Further results found that glucocorticoids receptor (GR) expression in hepatocyte nuclei of stress rats and GR nuclear translocation ratio was increased, and the same results were proved by experiments in vitro, i.e., GR nuclear translocation and Sp3 expression was remarkably increased in GCs-treated hepatocytes. Moreover, results from ChIP suggested GCs enhanced the binding of GR to the regulatory region of the Sp3 promoter. These results indicated that GCs inhibit CBS transcription by up-regulating Sp3 in psychological stress-induced HHcy.

Dynamic proteomic and metabonomic analysis reveal dysfunction and subclinical injury in rat liver during restraint stress.

Stress is a risk factor for many diseases. In this study, we used fluorescence difference gel electrophoresis combined MALDI-TOF/TOF and 1H-NMR to monitor the intracellular processes in rat liver at proteomic and metabonomic levels when a rat was treated with restraint stress for 8 weeks. Dynamic changes in 42 proteins and 32 chemical groups were monitored and identified. These proteins and chemical groups were implicated in glycolysis, the tricarboxylic acid cycle, fatty acid oxidation, and the urea cycle. To verify the DIGE result, three proteins including DJ-1, Blvrb and AdoHycase were validated by Western blot. Furthermore, some metabolites related to diseases such as lactate, fatty acid, glucose and homocysteine, were observed to be increasing during 8 weeks of restraint stress. Our data indicated that subclinical hepatic injury occurs during restraint stress, including inhibition of glycolysis and gluconeogenesis in the liver, and dysfunction of fatty acid beta-oxidation. The results suggest a comprehensive map that addresses how functional proteins act on metabolites to produce energy and process materials in rat liver as it responds to restraint stress. Further functional study on these dynamic change proteins and metabolites may lead to better understanding of the mechanisms of stress-induced diseases.

Anti-heat shock protein 70 autoantibody epitope changes and BD091 promotes atherosclerosis in rats

It has been previously reported that the plasma levels of autoantibodies against heat shock protein 70 (HSP70) are elevated in atherosclerosis. The aim of the present study was to elucidate whether anti-HSP70 antibodies are involved in the pathogenesis of atherosclerosis. To determine this, we chose rats as an atherosclerosis model. Titers of plasma anti-HSP70 autoantibody were determined by ELISA. After the intravenous administration of antibody into the tail, the damaged areas of aorta were stained with Evans Blue, atheromatous plaque were stained by Oil Red O, and then they were measured and quantified with AxioVision computer software. The number of macrophages (

The involvement of homocysteine in stress-induced Aβ precursor protein misprocessing and related cognitive decline in rats

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Protective effect and mechanism of rat recombinant S100 calcium‑binding protein A4 on oxidative stress injury of rat vascular endothelial cells

), smooth muscle cells (SMCs), and T cells were determined by immunocytochemistry. The level of anti-HSP70 IgG1 antibody was apparently increased in the AS group at the tenth week, and one hybridoma of HSP70 antibody (BD091, IgG1, recognizing C-terminal) had the same binding epitope as plasma anti-HSP70 autoantibodies. After intravenous administration, the lesion area of aorta with BD091 was significantly larger than those of IgGmouse and SPA-810. Moreover, injection of BD091 resulted in significant endothelium damage, followed by a greater accumulation of