👤 Maria Sabater-Molina

Hypertrophic cardiomyopathy (HCM) is an inherited disorder whose causal variants involve sarcomeric protein genes. One of these is myosin-binding protein C (MYBPC3), being previously associated with a favourable prognosis. Our objective is to describe the clinical characteristics and events of a molecularly homogeneous HCM cohort associated with truncating A cohort of patients and relatives with HCM diagnosis and carrying a truncating This is the first molecularly homogeneous, contemporary cohort, including HCM patients secondary to Show less

Hypertrophic cardiomyopathy (HCM) is characterized by an abnormal increase in myocardial mass that affects cardiac structure and function. HCM is the most common inherited cardiovascular disease in humans (0.2%) and the most common cardiovascular disease in cats (14.7%). Feline HCM phenotype is very similar to the phenotype found in humans, but the time frame for the development of the disease is significantly shorter. Similar therapeutic agents are used in its treatment and it has the same complications, such as heart failure, thromboembolism and sudden cardiac death. In contrast to humans, in whom thousands of genetic variants have been identified, genetic studies in cats have been limited to fragment analysis of two sarcomeric genes identifying two variants in MYBPC3 and one in MYH7. Two of these variants have also been associated with human disease. The high prevalence of the reported variants in non-affected cats hinders the assumption of their pathogenicity in heterozygotes. An in-depth review of the literature about genetic studies on feline HCM in comparison with the same disease in humans is presented here. The close similarity in the phenotype and genotype between cats and humans makes the cat an excellent model for the pathophysiological study of the disease and future therapeutic agents. Show less

Duchenne muscular dystrophy is a disorder with variable expression caused by framedisrupting mutations in the dystrophin gene. It is characterized by progressive muscle weakness and dilated cardiomyopathy. In-frame dystrophin mutations cause a clinically moderate disorder named Becker muscular dystrophy. Our aim was to study the clinical and genetic characteristics of a family with inherited cardiomyopathy and Becker muscular dystrophy. The index case was diagnosed with psychomotor retardation at 5 years of age. Asymmetric left ventricular hypertrophy and a long QT interval were evidenced at the age of 12. Mild muscular weakness was developed subsequently. Three genetic variants were identified in the index case: p.Arg891Alafs*160 in the MYBPC3 gene, p.Thr263Met in the KCNJ5 gene, and p.Ser2437_Ile2554delinsPhe in the DMD gene. The latter was expected to generate an in-frame deletion of exons 51 and 52 of the dystrophin gene. A family study revealed that the father and 3 uncles were carriers of the MYBPC3 mutation. The mother and a maternal grandfather were carriers of the other 2 variants. The 80-year-old grandfather, who had the dystrophin mutation, showed no sign of cardiomyopathy or muscular weakness. The deletion of exons 51 and 52 in the DMD gene, which has been proposed as one of the therapeutic strategies for Duchenne, is consistent with a normal life expectancy and the absence of myopathic symptoms in hemizygous males. Show less

Hypertrophic cardiomyopathy (HCM) is the most common inherited cardiovascular disease. HCM is a highly complex and heterogeneous disease regarding not only the number of associated mutations but also the severity of phenotype, symptom burden, and the risk of complications, such as heart failure and sudden death. The penetrance is incomplete and it is age and gender dependent. It is accepted as a disease of the sarcomere. Sixty percent of HCM cases carry mutations in 1 of 8 sarcomere protein genes, mainly non-sense MYBPC3 and missense MYH7 variants. Young patients with severe phenotype and other clinical features are included in proposed scores for prediction of high positive genetic result. The number of genes reported as disease-causing has increased in the last few years, in some cases without robust evidence. Currently available in silico tools are not always useful for differentiation between benign and deleterious variants. There is enough information on genotype-phenotype correlations to start understanding the mechanisms of the disease. Genetic and environmental modifiers have been explored with some interesting insights from miRNA studies with potential as biomarkers and therapeutic agents. There is an additional value of genetic testing in HCM for prognosis. Knowledge about genetics and functional studies are the basis of near future therapies. Show less

Mutations in MYBPC3 are the cause of hypertrophic cardiomyopathy (HCM). Although most lead to a truncating protein, the severity of the phenotype differs. We describe the clinical phenotype of a novel MYBPC3 mutation, p.Pro108Alafs*9, present in 13 families from southern Spain and compare it with the most prevalent MYBPC3 mutation in this region (c.2308+1 G>A). We studied 107 relatives of 13 index cases diagnosed as HCM carriers of the p.Pro108Alafs*9 mutation. Pedigree analysis, clinical evaluation, and genotyping were performed. A total of 54 carriers of p.Pro108Alafs*9 were identified, of whom 39 had HCM. There were 5 cases of sudden death in the 13 families. Disease penetrance was greater as age increased and HCM patients were more frequently male and developed disease earlier than female patients. The phenotype was similar in p.Pro108Alafs*9 and in c.2308+1 G>A, but differences were found in several risk factors and in survival. There was a trend toward a higher left ventricular mass in p.Pro108Alafs*9 vs c.2308+1G>A. Cardiac magnetic resonance revealed a similar extent and pattern of fibrosis. The p.Pro108Alafs*9 mutation is associated with HCM, high penetrance, and disease onset in middle age. Show less