Identification of N-homocysteinylated apolipoprotein AI in normal human serum

Background: In human serum, a portion of homocysteine (Hcy) exists as an N-linked form to the {varepsilon}-amino group of protein lysine residues. N-homocysteinylated proteins differ structurally and functionally from native proteins. The present study strives to develop detection and potential semi-quantification methods for N-homocysteinylated apolipoprotein AI (N-Hcy-apoAI) in human serum.Methods: Serum treated with or without cysteamine was supplied to isoelectric focusing (IEF) followed by an immunoblot using an anti-apoAI antibody. Cysteamine treatment increased the isoelectric point for N-Hcy-apoAI, but not for unmodified apoAI, due to the presence of -SH group(s) derived from Hcy and the absence of a cysteine residue in the apoAI molecule. N-Hcy-apoAI was semi-quantified from the scanned immunoblot pattern via a computer.Results: After cysteamine treatment, N-Hcy-apoAI in the serum was identified by IEF at the position with a higher pI value compared with intact apoAI. The reproducibility (between assays) of the semi-quantification method was 19.1% CV (coefficient of variation) for an average ratio 5.9% of N-Hcy-apoAI to the whole apoAI in the serum. Approximately 1.0–7.4% of apoAI was N-homocysteinylated in the serum obtained from 27 healthy subjects. Neither the ratio of N-Hcy-apoAI nor its concentration, calculated by total apoAI concentration, indicated correlation with the so-called total (free and S-linked) Hcy concentration.Conclusions: We directly found that a portion of apoAI in the serum undergoes homocysteinylation in an N-linkage manner, and used this to develop a potential semi-quantification method for N-Hcy-apoAI

Pandemic A/H1N1v influenza 2009 in hospitalized children: a multicenter Belgian survey

<p>Abstract</p> <p>Background</p> <p>During the 2009 influenza A/H1N1v pandemic, children were identified as a specific "at risk" group. We conducted a multicentric study to describe pattern of influenza A/H1N1v infection among hospitalized children in Brussels, Belgium.</p> <p>Methods</p> <p>From July 1, 2009, to January 31, 2010, we collected epidemiological and clinical data of all proven (positive H1N1v PCR) and probable (positive influenza A antigen or culture) pediatric cases of influenza A/H1N1v infections, hospitalized in four tertiary centers.</p> <p>Results</p> <p>During the epidemic period, an excess of 18% of pediatric outpatients and emergency department visits was registered. 215 children were hospitalized with proven/probable influenza A/H1N1v infection. Median age was 31 months. 47% had ≥ 1 comorbid conditions. Febrile respiratory illness was the most common presentation. 36% presented with initial gastrointestinal symptoms and 10% with neurological manifestations. 34% had pneumonia. Only 24% of the patients received oseltamivir but 57% received antibiotics. 10% of children were admitted to PICU, seven of whom with ARDS. Case fatality-rate was 5/215 (2%), concerning only children suffering from chronic neurological disorders. Children over 2 years of age showed a higher propensity to be admitted to PICU (16% vs 1%, p = 0.002) and a higher mortality rate (4% vs 0%, p = 0.06). Infants less than 3 months old showed a milder course of infection, with few respiratory and neurological complications.</p> <p>Conclusion</p> <p>Although influenza A/H1N1v infections were generally self-limited, pediatric burden of disease was significant. Compared to other countries experiencing different health care systems, our Belgian cohort was younger and received less frequently antiviral therapy; disease course and mortality were however similar.</p

Macrophage populations and expressions of regulatory proinflammatory factors in the rat meninx under lipopolysaccharide treatment in vivo and in vitro

Macrophages play important roles in host defense mechanisms. In the brain, besides microglial cells, meningeal macrophages are present. However, the pathobiological characteristics of meningeal macrophages in rats remain to be investigated. In normal meninx, immunohistochemically, macrophages reacting to CD163 (macrophage scavenger receptor) and major histocompatibility complex (MHC) class II-expressing cells (involving activated macrophages or dendritic cells) were sporadically seen without age-dependent changes. Injection of lipoplysaccharide (LPS) (5 μg; Escherichia coli) into the cerebrum increased the number of anti-CD68-positive macrophages (with greater phagocytic activity) in the meninx, with a peak at 12 h during observation period until 48 h; MHC class IIexpressing cells showed a gradual increase in number from 3 h after injection; however, anti-CD163-positive macrophages did not show significant change. In in vitro studies, LPS (0, 0.02, 0.05, 0.5, 5, 50 and 100 μg/ml) was added to KMY-1 or KMY-2 cells, both of which had been established from a rat malignant meningioma. KMY-1 originally reacted to CD163, but LPS addition at 0.5 μg/ml and greater concentrations decreased the anti- CD163-positive cell number and instead increased the anti-CD68-positive cell number. LPS-treated KMY-2 increased the anti-CD163-positive cell number at 0.05 and 0.5 μg/ml. By RT-PCR methods, LPS (0, 0.5, 5, 50, and 100 μg/ml)-treated KMY-1 and KMY-2 showed an increase in mRNA of monocyte chemoattractant protein- 1 (MCP-1, a chemokine), and LPS-treated KMY-2 increased mRNA of nerve growth factor (NGF, an immunological effecter). Collectively, under LPS treatment, macrophages with heterogeneous functions appear in rat meninx; rat meninx-forming cells may be involved in pathogenesis of meningeal inflammation by expressing different immunophenotypes and by producing regulatory proinflammatory factors such as MCP-1 and NGF