Dilated Cardiomyopathy due to the Novel MT-CYB Missense Mutation m.14757T>C.

Mitochondrial DNA (mtDNA) mutations frequently manifest with multisystem disease, including cardiomyopathy (CM). Various studies described mutations in protein-encoding mtDNA genes, such as cytochrome-b, manifesting with CM. A detailed clinical, biochemical, and molecular genetic analysis was performed in a 40-year-old male with dilated CM (DCM) to detect the underlying mtDNA defect. Muscle biopsy showed complex-III deficiency, and sequencing of the cytochrome-b gene revealed the pathogenic variant m.14757T>C in MT-CYB, resulting in the replacement of the hydrophobic methionine by the polar threonine (M4T). By application of the PolyPhen algorithm the variant was predicted as pathogenic. The mutation was not found in 100 healthy controls and never reported as a neutral polymorphism despite extensive sequencing of the cytochrome-b gene in 2,704 normal healthy controls from different ethnic backgrounds. In conclusion, the novel variant m.14757T>C in MT-CYB is associated with DCM suggesting a pathophysiologic role of the variant in the development of DCM.

Novel m.15434C>A (p.230L>I) Mitochondrial Cytb Gene Missense Mutation Associated with Dilated Cardiomyopathy.

Background. Previously it has been shown that various types of hypertrophic and dilative cardiomyopathy (hCMP, dCMP) can be attributed to disturbed mitochondrial oxidative energy metabolism. Several studies described mutations in mitochondrial DNA-located genes encoding for subunits of respiratory chain complexes, including the cytochrome b gene (MT-CYB), causing CMPs. Methods and Results. In the present study the MT-CYB gene was analysed in 30 patients with hCMP, 40 patients with dCMP, and 50 controls for alterations. Altogether, 27 MT-CYB variants were detected. Twenty-four of them were single nucleotide polymorphisms defining common haplogroups. The variant m.15434C>A was found in a single patient with severe dCMP and assessed as novel mutation, since it was not found in healthy controls or available data sets, and was nonhaplogroup associated with Phylotree. This variant altered an amino acid (L230I) with a high interspecific amino acid conservation index (CI = 97.7%) indicative of the functional importance of the residue. Conclusions. Though the L230I mutation seems to play a causative role for dCMP, prospective studies on yeast or transgenic mice models with defined mutation are warranted to study the pathogenetic impact of this mutation.

Transition m.3308T>C in the ND1 gene is associated with left ventricular hypertrabeculation/noncompaction.

Though left ventricular hypertrabeculation/noncompaction (LVNC) is frequently associated with mitochondrial DNA (mtDNA) mutations, it has not been reported in association with the transition m.3308T>C of the NADH dehydrogenase subunit 1 (ND1) gene. The index patient is a 16-year-old Tunisian female who was investigated for a systolic murmur and cardiomegaly. Echocardiography revealed tricuspid insufficiency, moderate left ventricular dilatation, Ebstein's anomaly, a superior caval vein draining into the coronary sinus and, surprisingly, LVNC of the apex and the lateral wall. LVNC was absent in all other cardiologically investigated siblings. RNA and mtDNA sequence analysis revealed the known homoplasmic mutation m.3308T>C resulting in the replacement of the first amino acid methionine by threonine in the ND1 subunit of respiratory chain complex I. The m.3308T>C mutation was also present in the patient's mother and several other family members but absent in 350 controls. Additionally, the index patient carried the polymorphisms m.8248A>G in the COX2 gene and m.8468C>T in the ATP8 gene. It is concluded that LVNC may be associated with the known homoplasmic m.3308T>C mutation in the ND1 gene. However, the pathogenetic role of this mutation in the development of LVNC remains elusive.