CD14(++)CD16+ monocytes but not total monocyte numbers predict cardiovascular events in dialysis patients.

Migration of monocytes into the vessel wall contributes to the onset and progression of atherosclerosis. Because monocytes are a heterogeneous population, we determined potential associations between monocyte subsets and cardiovascular events in a prospective cohort of 94 dialysis patients followed for 35 months. The incidence of cardiovascular events and death measured by Kaplan-Meier plots and flow cytometric analysis of monocyte subsets showed that total leukocyte and monocyte numbers failed to predict event-free survival. Among monocyte subsets, a high CD14(++)CD16(+) monocyte number was associated with higher rates of cardiovascular events and death. In a multivariate proportional hazards model adjusted for classical cardiovascular risk factors, patients with CD14(++)CD16(+) monocyte numbers in the top quartile were at higher risk of cardiovascular events and death compared to patients in the lowest quartile. Our study suggests that the number of CD14(++)CD16(+) monocytes was independently associated with cardiovascular events and death in a high-risk population of dialysis patients.

Strong acceleration of murine lupus by injection of the SmD1(83-119) peptide.

OBJECTIVE: The mechanisms of IgG anti-double-stranded DNA (anti-dsDNA) antibody induction are incompletely understood. We recently demonstrated a high prevalence of autoantibodies to the C-terminus of SmD1 in patients with systemic lupus erythematosus (SLE) that was closely associated with anti-dsDNA reactivity. The aim of the present study was to analyze the influence of the SmD1 C-terminus on the generation of pathogenic anti-dsDNA antibodies in a murine model of SLE. METHODS: Female lupus-prone prenephritic (NZB x NZW)F1 mice (NZB/NZW mice) as well as female control BALB/c, NZW, and (BALB/c x NZW)F, mice (CWF1 mice) were subcutaneously injected with keyhole limpet hemocyanin (KLH)-coupled SmD1(83-119). Controls received injections of recombinant SmD1 (rSmD1), KLH-rSmD1, KLH-coupled randomized peptide of SmD1(83-119), ovalbumin, or saline. Animals were monitored for survival and proteinuria and for levels of plasma creatinine, urea, and autoantibodies. In addition, histologic examinations were performed and T cell responses against SmD1(83-119) peptide and rSmD1 protein were determined in SmD1(83-119)-treated and -untreated NZB/NZW mice. RESULTS: Immunization with KLH-SmD1(83-119), but not with control peptide, significantly accelerated the natural course of lupus in NZB/NZW mice, with premature renal failure and increased development of anti-dsDNA antibodies. Control strains of mice remained healthy, with no relevant anti-SmD1(83-119) antibodies detectable even after immunization. In contrast to findings in control mice, a T cell response against SmD1(83-119) was already present in unmanipulated NZB/NZW mice, and this response was further amplified after immunization. CONCLUSION: The SmD1(83-119) peptide can influence the pathogenic anti-dsDNA response in the NZB/NZW murine lupus model. The data suggest that an SmD1(83-119)-specific T cell response is critical. Therefore, modulation of these autoantigen-specific T cells by tolerance induction may provide a therapeutic approach to specific immunosuppression in lupus.

A novel epitope on the C-terminus of SmD1 is recognized by the majority of sera from patients with systemic lupus erythematosus.

The SmD1 protein is a specific target for the autoantibody response in SLE. To further analyze this reactivity epitope, mapping was performed with cellulose-bound 13-mer peptides overlapping 10 amino acids (aa). In this initial approach, 4 out of 15 SLE sera recognized more than five overlapping peptides of the SmD1 C-terminus. Therefore, longer oligopeptides of up to 37 aa of this region were generated and probed for as antigens by ELISA. For the SmD1 aa 83-119 polypeptide, there was a striking increase of reactivity with 70.0% positive reactions out of 167 SLE sera. In contrast, 105 healthy control sera were negative, and only 8.3% of sera from patients with other inflammatory diseases (n = 267) exhibited a response, which was of low level only. The anti-SmD183-119 reactivity was significantly higher in anti-dsDNA antibody positive vs. negative sera (P < 0.001) and correlated with disease activity. Four of five human monoclonal anti-dsDNA antibodies also reacted with SmD183-119. The specificity for SmD1 was demonstrated by inhibition experiments and immunization of rabbits with SmD183-119 inducing SmD1-specific antibodies. In conclusion, the SmD183-119 peptide was demonstrated to be an important and highly specific target of the autoimmune response in SLE. The high sensitivity of this ELISA probably depends on a conformational epitope, which appears not to be accessible in the full-size SmD1 protein.