Background— Mutations in myofilament proteins, most commonly MYBPC3 -encoded myosin-binding protein C and MYH7 -encoded β-myosin heavy chain, can cause hypertrophic cardiomyopathy (HCM). Despite significant advances in structure-function relationships pertaining to the cardiac sarcomere, there is limited knowledge of how a mutation leads to clinical HCM. We, therefore, set out to study expression and localization of myofilament proteins in left ventricular tissue of patients with HCM. Methods and Results— Frozen surgical myectomy specimens from 47 patients with HCM were examined and genotyped for mutations involving 8 myofilament-encoding genes. Myofilament protein levels were quantified by Western blotting with localization graded from immunohistochemical staining of tissue sections. Overall, 25 of 47 (53%) patients had myofilament-HCM, including 12 with MYBPC3-HCM and 9 with MYH7-HCM. As compared with healthy heart tissue, levels of myofilament proteins were increased in patients manifesting a mutation in either gene. Patients with a frameshift mutation predicted to truncate MYBPC3 exhibited marked disturbances in protein localization as compared with missense mutations in either MYBPC3 or MYH7 . Conclusions— In this first expression study in human HCM tissue, increased myofilament protein levels in patients with either MYBPC3 - or MYH7- mediated HCM suggest a poison peptide mechanism. Specifically, the mechanism of dysfunction may vary according to the genetic subgroup suggested by a distinctly abnormal distribution of myofilament proteins in patients manifesting a truncation mutation in MYBPC3 .
Background: Spontaneous coronary artery dissection (SCAD) is an uncommon idiopathic disorder predominantly affecting young, otherwise healthy women. Rare familial cases reveal a genetic predisposition to disease. The aim of this study was to identify a novel susceptibility gene for SCAD. Methods: Whole-exome sequencing was performed in a family comprised of 3 affected individuals and filtered to identify rare, predicted deleterious, segregating variants. Immunohistochemical staining was used to evaluate protein expression of the identified candidate gene. The prevalence and spectrum of rare (<0.1%) variants within binding domains was determined by next-generation sequencing or denaturing high-performance liquid chromatography in a sporadic SCAD cohort of 675 unrelated individuals. Results: We identified a rare heterozygous missense variant within a highly conserved β-integrin–binding domain of TLN1 segregating with familial SCAD. TLN1 encodes talin 1—a large cytoplasmic protein of the integrin adhesion complex that links the actin cytoskeleton and extracellular matrix. Consistent with high mRNA expression in arterial tissues, robust immunohistochemical staining of talin 1 was demonstrated in coronary arteries. Nine additional rare heterozygous missense variants in TLN1 were identified in 10 sporadic cases. Incomplete penetrance, suggesting genetic or environmental modifiers of this episodic disorder, was evident in the familial case and 5 individuals with sporadic SCAD from whom parental DNA was available. Conclusions: Our findings reveal TLN1 as a disease-associated gene in familial and sporadic SCAD and, together with abnormal vascular phenotypes reported in animal models of talin 1 disruption, implicate impaired structural integrity of the coronary artery cytoskeleton in SCAD susceptibility.
Background: Mutations in MYBPC3 -encoded myosin binding protein C underlie the most common genotype in hypertrophic cardiomyopathy (HCM). Compared to most HCM-associated mutations which are primarily missense mutations, MYBPC3-HCM is often caused by insertions, deletions, nonsense mutations or mutations involving the canonical splice site. However, the effects of most mutations that prematurely truncate MYBPC3 are unknown. Access to cardiac specific mRNA and tissue has permitted a molecular and cellular elucidation of the consequences of two splice site mutations. Methods: Mutational analysis of MYBPC3 revealed 2 HCM-susceptibility mutations involving the splice donor sites of exons 7 and 30. Reverse transcription was performed on cDNA generated from RNA extracted from cardiac tissue obtained following surgical myectomy. Western blot analysis and immunohistochemistry (IHC) of the myofilaments were performed to further assess the impact of the splice-site mutations. Results: Both splice donor mutations produced abnormal RNA splicing of MYBPC3. The c.821+1 g>a mutation in the splice donor site of exon 7 generated two alternatively-spliced mutant transcripts resulting in two frame-shifted, premature truncations (H257 fs/37 and H257 fs/15). The c.3330+2 t>g mutation in exon 30’s splice donor site produced a single alternatively-spliced mutant transcript that translated into a frame-shifted premature truncation (V1063 fs/37). Expression levels of wild type myosin binding protein C were decreased in the myectomy specimen from the patient with the exon 7 splice donor site mutation. By IHC, the spatial organization of myosin binding protein C was disrupted severely in both patients. Conclusions: This study provides the first molecular and cellular characterization of HCM-causing mutations involving canonical splice-site motifs within the intron. Loss of function of the splice site resulted in exon skipping and generation of frame-shifted and prematurely truncated myosin binding protein C and disruption of the distribution and organization of myosin binding protein C in the heart tissue. This research has received full or partial funding support from the American Heart Association, AHA Midwest Affiliate (Illinois, Indiana, Iowa, Kansas, Michigan, Minnesota, Missouri, Nebraska, North Dakota, South Dakota & Wisconsin).
'/%3e%3c/g%3e%3cuse xlink:href='%23b' transform='matrix(1 0 0 -1 0 549)'/%3e%3c/svg%3e)
