Xiaoling Zhao

Extracellular HSP27 acts as a signaling molecule to activate NF-κB in macrophages

Heat shock protein 27 (HSP27) shows attenuated expression in human coronary arteries as the extent of atherosclerosis progresses. In mice, overexpression of HSP27 reduces atherogenesis, yet the precise mechanism(s) are incompletely understood. Inflammation plays a central role in atherogenesis, and of particular interest is the balance of pro- and anti-inflammatory factors produced by macrophages. As nuclear factor-kappa B (NF-κB) is a key immune signaling modulator in atherogenesis, and macrophages are known to secrete HSP27, we sought to determine if recombinant HSP27 (rHSP27) alters NF-κB signaling in macrophages. Treatment of THP-1 macrophages with rHSP27 resulted in the degradation of an inhibitor of NF-κB, IκBα, nuclear translocation of the NF-κB p65 subunit, and increased NF-κB transcriptional activity. Treatment of THP-1 macrophages with rHSP27 yielded increased expression of a variety of genes, including the pro-inflammatory factors, IL-1β, and TNF-α. However, rHSP27 also increased the expression of the anti-inflammatory factors IL-10 and GM-CSF both at the mRNA and protein levels. Our study suggests that in macrophages, activation of NF-κB signaling by rHSP27 is associated with upregulated expression and secretion of key pro- and anti-inflammatory cytokines. Moreover, we surmise that it is the balance in expression of these mediators and antagonists of inflammation, and hence atherogenesis, that yields a favorable net effect of HSP27 on the vessel wall.

Heat Shock Protein 27 Protects Against Atherogenesis via an Estrogen-Dependent Mechanism Role of Selective Estrogen Receptor Beta Modulation

Objective—We recently identified HSP27 as an atheroprotective protein that acts extracellularly to prevent foam cell formation and atherogenesis in female but not male mice, where serum levels of HSP27 were increased and inversely correlated with degree of lesion burden. In the current study we sought to determine whether estrogens are required for the observed atheroprotective benefits of HSP27 as well as its extracellular release. Methods and Results—In vitro estrogens prompted the release of HSP27 from macrophages in an ERβ specific manner that involved exosomal trafficking. Ovariectomy nullified the previously recognized attenuation in aortic lesion area in HSP27o/eapoE−/− mice compared to apoE−/− mice. Supplementation with 17β-estradiol resulted in a >15× increase in uterine weight and attenuation of atherogenesis in all mice, although HSP27o/eapoE−/− had 34% less lesion burden compared to apoE−/− mice. Mice treated with the ERβ-specific agonist, DPN had no effect on uterine weight but a 28% decrease in aortic lesion area in HSP27o/eapoE−/− compared to apoE−/− mice. HSP27 serum levels showed a similar gradual increase with E2 and DPN replacement treatment but did not change in untreated mice. Conclusions—The extracellular release of and atheroprotection provided by HSP27 is estrogen dependent.

Delayed re-endothelialization with rapamycin-coated stents is rescued by the addition of a glycogen synthase kinase-3β inhibitor

AIMS Drug-eluting stents (DESs) reduce neointima area and in-stent restenosis but delay re-endothelialization. Recently, we demonstrated that pharmacological expansion and functional enhancement of endothelial progenitor cells (EPCs) can be achieved by treatment with a glycogen synthase kinase-3beta inhibitor (GSKi)-even for feeble cells derived from coronary artery disease patients. GSKi treatment enhanced EPC adhesion via up-regulated expression of the alpha-4 integrin, ameliorated re-endothelialization, and reduced neointima formation in denuded murine arteries. Hence, we hypothesized that GSKi-coated stents (GSs) will enhance EPC adhesion and attenuate delayed vascular healing associated with rapamycin, a key DES agent. METHODS AND RESULTS In vitro human EPCs adhered to GS with affinities that were 2x, 14x, and 13x greater than vehicle (VSs)-, rapamycin (RSs)-, and rapamycin plus GSKi (RGSs)-coated stents, respectively. Stents were inserted in rabbit carotid arteries, and at 14 days, neointima area was 45 and 49% lower in GSs compared with bare metal stents (BMSs) and VSs. Moreover, RSs had a 47% larger neointima area than GSs, but RGSs reduced neointima area to a level comparable to GSs. Seven days after stenting, GSs displayed re-endothelialization that was 40, 33, and 42% greater than BMSs, VSs, and RSs, respectively. Moreover, RGSs had 41% more re-endothelialization than RSs. At 14 days, the 7-day re-endothelialization patterns persisted. CONCLUSION GSKi efficiently ameliorates the vascular response to stent implantation and has an important redeeming effect on the deleterious endothelial effects of rapamycin-coated stents.

Serum Heat Shock Protein 27 Levels Represent a Potential Therapeutic Target for Atherosclerosis: Observations From a Human Cohort and Treatment of Female Mice

OBJECTIVES The aim of this study was to evaluate the potential of serum heat shock protein 27 (HSP27) as a therapeutic target in coronary artery disease. BACKGROUND Expression of HSP27 in human coronary arteries diminishes with the progression of atherosclerosis, whereas ubiquitous HSP27 overexpression in apolipoprotein E(-/-) (ApoE(-/-)) mice attenuates atherogenesis. However, it remains unclear whether increasing serum HSP27 levels alone is sufficient for atheroprotection. METHODS Low- and intermediate-risk patients undergoing coronary or computed tomography angiography had serum HSP27 levels measured. Elevated serum HSP27 levels in female atheroprone ApoE(-/-) mice were achieved by transplantation with HSP27 overexpressing bone marrow or by administering recombinant HSP27. RESULTS Patients with >50% stenosis in any major epicardial artery had lower HSP27 levels compared with those free of atherosclerosis (median [interquartile range]: 2,176 pg/ml [551-5,475] vs. 6,200 pg/ml [2,575-9,560]; p < 0.001). After a 5-year period of clinical follow-up, low serum HSP27 levels (<50th percentile) were predictive of subsequent major adverse cardiovascular events (hazard ratio: 2.93, 95% confidence interval: 1.06 to 8.12; p = 0.04). In experimental murine models of atherosclerosis, increasing serum HSP27 levels both reduced de novo atherosclerotic lesion formation and enhanced features of plaque stability. CONCLUSIONS In humans, low serum HSP27 levels are associated with the presence of coronary artery disease and prognostic of future adverse clinical events. In mouse models of atherosclerosis, increasing HSP27 levels reduced lesion progression and promoted features of plaque stability. Serum HSP27 levels may represent a potential therapeutic target for atherosclerosis.

Chronic Over-Expression of Heat Shock Protein 27 Attenuates Atherogenesis and Enhances Plaque Remodeling: A Combined Histological and Mechanical Assessment of Aortic Lesions

Aims Expression of Heat Shock Protein-27 (HSP27) is reduced in human coronary atherosclerosis. Over-expression of HSP27 is protective against the early formation of lesions in atherosclerosis-prone apoE−/− mice (apoE−/−HSP27o/e) - however, only in females. We now seek to determine if chronic HSP27 over-expression is protective in a model of advanced atherosclerosis in both male and female apoE−/− mice. Methods and Results After 12 weeks on a high fat diet, serum HSP27 levels rose more than 16-fold in male and female apoE−/−HSP27o/e mice, although females had higher levels than males. Relative to apoE−/− mice, female apoE−/−HSP27o/e mice showed reductions in aortic lesion area of 35% for en face and 30% for cross-sectional sinus tissue sections – with the same parameters reduced by 21% and 24% in male cohorts; respectively. Aortic plaques from apoE−/−HSP27o/e mice showed almost 50% reductions in the area occupied by cholesterol clefts and free cholesterol, with fewer macrophages and reduced apoptosis but greater intimal smooth muscle cell and collagen content. The analysis of the aortic mechanical properties showed increased vessel stiffness in apoE−/−HSP27o/e mice (41% in female, 34% in male) compare to apoE−/− counterparts. Conclusions Chronic over-expression of HSP27 is atheroprotective in both sexes and coincides with reductions in lesion cholesterol accumulation as well as favorable plaque remodeling. These data provide new clues as to how HSP27 may improve not only the composition of atherosclerotic lesions but potentially their stability and resilience to plaque rupture.

Heat shock protein-27 attenuates foam cell formation and atherogenesis by down-regulating scavenger receptor-A expression via NF-κB signaling

Previously, we showed an inverse correlation between HSP27 serum levels and experimental atherogenesis in ApoE(-/-) mice that over-express HSP27 and speculated that the apparent binding of HSP27 to scavenger receptor-A (SR-A) was of mechanistic importance in attenuating foam cell formation. However, the nature and importance of the interplay between HSP27 and SR-A in atheroprotection remained unclear. Treatment of THP-1 macrophages with recombinant HSP27 (rHSP27) inhibited acLDL binding (-34%; p<0.005) and uptake (-38%, p<0.05). rHSP27 reduced SR-A mRNA (-39%, p=0.02), total protein (-56%, p=0.01) and cell surface (-53%, p<0.001) expression. The reduction in SR-A expression by rHSP27 was associated with a 4-fold increase in nuclear factor-kappa B (NF-κB) signaling (p<0.001 versus control), while an inhibitor of NF-κB signaling, BAY11-7082, attenuated the negative effects of rHSP27 on both SR-A expression and lipid uptake. To determine if SR-A is required for HSP27 mediated atheroprotection in vivo, ApoE(-/-) and ApoE(-/-) SR-A(-/-) mice fed with a high fat diet were treated for 3weeks with rHSP25. Compared to controls, rHSP25 therapy reduced aortic en face and aortic sinus atherosclerotic lesion size in ApoE(-/-) mice by 39% and 36% (p<0.05), respectively, but not in ApoE(-/-)SR-A(-/-) mice. In conclusion, rHSP27 diminishes SR-A expression, resulting in attenuated foam cell formation in vitro. Regulation of SR-A by HSP27 may involve the participation of NF-κB signaling. Lastly, SR-A is required for HSP27-mediated atheroprotection in vivo.