Vaccination against T-cell epitopes of native ApoB100 reduces vascular inflammation and disease in a humanized mouse model of atherosclerosis.

BACKGROUND AND OBJECTIVES: The T-cell response to low-density lipoprotein (LDL) in the vessel wall plays a critical role in atherosclerotic plaque formation and stability. In this study, we used a new translational approach to investigate epitopes from human apolipoprotein B100 (ApoB100), the protein component of LDL, which triggers T-cell activation. We also evaluated the potential of two selected native ApoB100 epitopes to modulate atherosclerosis in human ApoB100-transgenic Ldlr-/- (HuBL) mice. METHODS AND RESULTS: HuBL mice were immunized with human atherosclerotic plaque homogenate to boost cellular autoimmune response to tissue-derived ApoB100 epitopes. In vitro challenge of splenocytes from immunized mice with a library of overlapping native peptides covering human ApoB100 revealed several sequences eliciting T-cell proliferation. Of these sequences, peptide (P) 265 and P295 were predicted to bind several human leucocyte antigen (HLA) haplotypes and induced high levels of interferon (IFN)-γ. Vaccination of HuBL mice with these peptides mounted a strong adaptive immune response to native ApoB100, including high levels of epitope-specific plasma IgGs. Interestingly, P265 and P295 vaccines significantly decreased plaque size, reduced macrophage infiltration and increased IgG1 deposition in the plaques. Purified IgGs from vaccinated mice displayed anti-inflammatory properties against macrophages in vitro, reducing their response to LPS in a dose-dependent manner. CONCLUSION: We identified two specific epitopes from human native ApoB100 that trigger T-cell activation and protect HuBL mice against atherosclerosis when used in a vaccine. Our data suggest that vaccination-induced protective mechanisms may be mediated at least in part through specific antibody responses to LDL that inhibit macrophage activation.

Altered red blood cell distribution width in overweight adolescents and its association with markers of inflammation.

BACKGROUND: Obesity and the metabolic syndrome are dramatically increasing problems. Red blood cell distribution width (RDW), the variability in size of circulating red blood cells, has been demonstrated to be altered in different clinical settings. This analysis aimed to investigate the relationship between RDW and obesity in adolescents and in an animal model of diet-induced obesity (DIO). METHODS: Seventy-nine male adolescents (aged 13-17 years) were studied. Thirty-seven of them were overweight (body mass index ≥ 90th percentile). RDW, markers of inflammation and stem cell factor (SCF) were determined. In an animal study, mice were fed with different diets for 15 weeks. RDW was determined using an animal blood count machine. RESULTS: RDW differed significantly between normal-weight adolescents (13.07 ± 0.09) and overweight adolescents (13.39 ± 0.10, P = 0.015), whereas erythrocyte counts and haematocrit did not differ. RDW correlated to markers of inflammation and inversely to SCF. In the mice animal model, nutritional changes increased RDW, whereas overweight per se did not change RDW. CONCLUSIONS: RDW is elevated in overweight and reflects the inflammatory state. RDW potentially represents an additional and cost-effective tool to indicate inflammation. Future studies are needed to understand the differential influences of nutrition and overweight on RDW.

Expression of leptin and leptin receptor during the development of liver fibrosis and cirrhosis.

Leptin is involved in the regulation of food intake and is mainly secreted by adipocytes. Major secretagogues are cytokines such as TNF-alpha or IL-1. Leptin in turn upregulates inflammatory immune responses. Elevated leptin serum levels have been detected in patients with liver cirrhosis, a disease frequently associated with elevated levels of circulating cytokines as well as hypermetabolism and altered body weight. Recently, leptin has been detected in activated hepatic stellate cells in vitro and an involvement of leptin in liver fibrogenisis has been suggested. The current study was designed to further clarify the role of leptin in liver disease by characterizing leptin and leptin receptor expression in the development and onset of experimental liver fibrosis. Liver fibrosis and cirrhosis was induced in rats by use of phenobarbitone and increasing doses of CCl (4). Leptin and leptin receptor mRNA expression was determined by semiquantitative RT-PCR, protein expression by Western blot analysis and localization of leptin and its receptor by immunohistochemistry. Normal liver tissue does not express leptin, but leptin receptor mRNA. Increasing levels of leptin mRNA were detected in fibrotic and cirrhotic livers correlated to the degree of fibrosis. Leptin receptor mRNA expression was not significantly altered in damaged livers. Increasing levels of leptin were detected in fibrotic and cirrhotic livers, whereas protein expression of the receptor remained unchanged. Throughout different stages of liver fibrosis, leptin immunoreactivity was localized in activated hepatic stellate cells only, whereas immunoreactivity for the receptor was mainly seen on hepatocytes. In conclusion, leptin is expressed at increasing levels in activated hepatic stellate cells in vivo, which may therefore be a source of increased leptin tissue and serum levels contributing to the pathophysiology and morphological changes of chronic liver disease.