Interleukin-2 receptor-α proximal promoter hypomethylation is associated with multiple sclerosis.

Genetic studies have demonstrated association between single-nucleotide polymorphisms within the IL2RA (interleukin-2 receptor α-subunit) gene and risk of developing multiple sclerosis (MS); however, these variants do not have obvious functional consequences. DNA methylation is a source of genetic variation that could impact on autoimmune disease risk. We investigated DNA methylation of the IL2RA promoter in genomic DNA obtained from peripheral blood mononuclear cells and neural tissue using matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF) mass spectrometry. A differential methylation profile of IL2RA was identified, suggesting that IL2RA expression was regulated by DNA methylation. We extended our analysis of DNA methylation to peripheral blood mononuclear cell (PBMC) of MS cases and controls using MALDI-TOF and Illumina HumanMethylation450 arrays. Analyses of CpG sites within the proximal promoter of IL2RA in PBMC showed no differences between MS cases and controls despite an increase in IL2RA expression. In contrast, we inferred significant DNA methylation differences specific to particular leukocyte subtypes in MS cases compared with controls by deconvolution of the array data. The decrease in methylation in patients correlated with an increase in IL2RA expression in T cells from MS cases in comparison with controls. Our data suggest that differential methylation of the IL2RA promoter in T cells could be an important pathogenic mechanism in MS.

Serum phosphorylated neurofilament-heavy chain levels in multiple sclerosis patients.

OBJECTIVES: We evaluated whether the measurement of serum phosphorylated neurofilament heavy chain (pNF-H) titre is likely to be a valid biomarker of axonal injury in multiple sclerosis (MS). METHODS: Serum pNF-H concentrations were measured by ELISA in cases with relapsing-remitting (RR)-MS (n=81), secondary progressive (SP) MS (n=13) and primary progressive (PP)-MS; n=6) MS; first demyelinating event (FDE; n=82); and unaffected controls (n=135). A subset of MS cases (n=45) were re-sampled on one or multiple occasions. The Multiple Sclerosis Severity Score (MSSS) and MRI measures were used to evaluate associations between serum pNF-H status, disease severity and cerebral lesion load and activity. RESULTS: We confirmed the presence of pNF-H peptides in serum by ELISA. We showed that a high serum pNF-H titre was detectable in 9% of RR-MS and FDE cases, and 38.5% of SP-MS cases. Patients with a high serum pNF-H titre had higher average MSSS scores and T2 lesion volumes than patients with a low serum pNF-H titre. Repeated sampling of a subset of MS cases showed that pNF-H levels can fluctuate over time, likely reflecting temporal dynamics of axonal injury in MS. CONCLUSIONS: A subset of FDE/MS cases was found to have a high serum pNF-H titre, and this was associated with changes in clinical outcome measures. We propose that routine measurement of serum pNF-H should be further investigated for monitoring axonal injury in MS.

Fatigue strength of human cortical bone: age, physical, and material heterogeneity effects.

Human bone is highly heterogeneous at the microscale and this heterogeneity has been thought to relate to some fracture scenarios. The fatigue strength of cortical bone has been shown to relate to its inner architecture (osteonal or fibrolamellar) and some physical characteristics in the past, but never to the heterogeneity of its microstructure. The present study examines for the first time, the fatigue strength of human bone for six individuals of various ages in three main modes (tension, compression, and shear), the salient physical characteristics of these same specimens and the elastic mismatch that is present at a microstructural level by performing microhardness measurements on osteons and their surrounding matrix areas. The results showed that the ratio of hardness values in osteons and interstitial areas adversely affects fatigue strength with an effect more potent if not equal to the other usual factors such as "age" or features, material density, porosity, and mineral content, which are measured in a homogenized (averaged over a cross section) manner at a macrostructural (large scale) level. It has been known that fatigue microcracks localize in regions between osteons and interstitial matrix and in hypermineralized matrix areas. The present results indicate that, perhaps, heterogeneity not only influences the initiation of microcracks, but also their eventual growth and coalescence into larger cracks, which are detrimental for the integrity of the material.