SURF1 deficiency causes demyelinating Charcot-Marie-Tooth disease

Objective: To investigate whether mutations in the SURF1 gene are a cause of Charcot-Marie-Tooth (CMT) disease. Methods: We describe 2 patients from a consanguineous family with demyelinating autosomal recessive CMT disease (CMT4) associated with the homozygous splice site mutation c.107-2A>G in the SURF1 gene, encoding an assembly factor of the mitochondrial respiratory chain complex IV. This observation led us to hypothesize that mutations in SURF1 might be an unrecognized cause of CMT4, and we investigated SURF1 in a total of 40 unrelated patients with CMT4 after exclusion of mutations in known CMT4 genes. The functional impact of c.107-2A>G on splicing, amount of SURF1 protein, and on complex IV activity and assembly was analyzed. Results: Another patient with CMT4 was found to harbor 2 additional SURF1 mutations. All 3 patients with SURF1-associated CMT4 presented with severe childhood-onset neuropathy, motor nerve conduction velocities G mutation produced no normally spliced transcript, leading to SURF1 absence. However, complex IV remained partially functional in muscle and fibroblasts. Conclusions: We found SURF1 mutations in 5% of families (2/41) presenting with CMT4. SURF1 should be systematically screened in patients with childhood-onset severe demyelinating neuropathy and additional features such as lactic acidosis, brain MRI abnormalities, and cerebellar ataxia developing years after polyneuropathy

The wide POLG-related spectrum: An integrated view.

The aims of this study were to describe the spectrum of recessively inherited POLG-related disorders, to report new POLG mutations and to discuss genotype-phenotype correlations in order to propose a strategy for diagnosis. Twenty eight patients diagnosed with two POLG mutations at 12 tertiary European centers of adult neurology were studied. Exhaustive phenotypic data, brain MRI, muscle analysis, mitochondrial DNA and POLG analysis findings were collected. Five distinct phenotypes were observed: Sensory Ataxic Neuropathy, Dysarthria and Ophthalmoparesis (SANDO), autosomal recessive Progressive External Ophthalmoplegia (arPEO), Spino Cerebellar Ataxia with Epilepsy (SCAE), Mitochondrial Neuro Gastro Intestinal Encephalopathy (MNGIE)-like phenotype and Sensory Ataxic Neuropathy with Ophthalmoparesis but without dysarthria which we propose to name SANO. An increasing gradient of functional severity was appreciated from PEO with the best prognosis, to SANO, SANDO and finally SCAE respectively. Four new missense mutations were found. Regarding genotype/phenotype correlations, P587L mutation was associated with SANO rather than with SANDO (p < 0.005) and W748S mutation was associated with SANDO or SCAE (with more severe disease progression), rather than with SANO or PEO (p < 0.004). Distinguishing between various phenotypes can have important diagnosis and prognosis implications. POLG mutations should be priority searched for in cases of SANDO or SANO. Mitochondrial respiratory chain and mitochondrial DNA studies should be considered in the case of negative POLG analysis or other phenotypes