A Novel Missense Mutation p.Gly162Glu of the Gene MYL2 Involved in Hypertrophic Cardiomyopathy: A Pedigree Analysis of a Proband.

BACKGROUND: Hypertrophic cardiomyopathy (HCM), a common and clinically heterogeneous disease characterized by unexplained ventricular myocardial hypertrophy, is mostly caused by mutations in sarcomeric genes. Identifying the genetic cause is important for management, therapy, and genetic counseling. METHODS: A molecular diagnosis was performed on a 51-year-old woman diagnosed with HCM using a next-generation sequencing workflow based on a panel designed for sequencing the most prevalent cardiomyopathy-causing genes. Segregation analysis was performed on the woman's family. RESULTS: A novel myosin regulatory light chain (MYL2) missense variant, NM_000432.3:c485G>A, p.Gly162Glu, was identified and firstly considered as a putative pathogenic mutation. Among the 27 family members tested, 16 were carriers for the MYL2-p.Gly162Glu mutation, of whom 12 with the phenotype were positive. None of the 11 family members without mutation had cardiomyopathy. CONCLUSIONS: Genetic analysis combined with a segregation study allowed us to classify this novel MYL2 variation, p.Gly162Glu, as a novel pathogenic mutation leading to a familial form of HCM. Due to absence of fast in vitro approaches to evaluate the functional impact of missense variants on HCM-causing genes, segregation studies remain, when possible, the easiest approach to evaluate the putative pathogenicity of novel gene variants, more particularly missense ones.

Degree of oxidation of low density lipoprotein affects expression of CD36 and PPARgamma, but not cytokine production, by human monocyte-macrophages.

Oxidized low-density lipoprotein (oxLDL) exhibits many atherogenic effects, including the promotion of monocyte recruitment to the arterial endothelium and the induction of scavenger receptor expression. However, while atherosclerosis involves chronic inflammation within the arterial intima, it is unclear whether oxLDL alone provides a direct inflammatory stimulus for monocyte-macrophages. Furthermore, oxLDL is not a single, well-defined entity, but has structural and physical properties which vary according to the degree of oxidation. We tested the hypothesis that the biological effects of oxLDL will vary according to its degree of oxidation and that some species of oxLDL will have atherogenic properties, while other species may be responsible for its inflammatory activity. The atherogenic and inflammatory properties of LDL oxidized to predetermined degrees (mild, moderate and extensive oxidation) were investigated in a single system using human monocyte-derived macrophages. Expression of CD36 mRNA was up-regulated by mildly- and moderately-oxLDL, but not highly-oxLDL. The expression of the transcription factor, proliferator-activated receptor-gamma (PPARgamma), which has been proposed to positively regulate the expression of CD36, was increased to the greatest degree by highly-oxLDL. However, the DNA binding activity of PPARgamma was increased only by mildly- and moderately-oxLDL. None of the oxLDL species appeared to be pro-inflammatory towards monocytes, either directly or indirectly through mediators derived from lymphocytes, regardless of the degree of oxidation.