Predominant cellular mitochondrial dysfunction in the TOP3A gene-caused Bloom syndrome-like disorder

TOP3A promotes processing of double Holliday junction dissolution and also plays an important role in decatenation and segregation of human mtDNA. Recently, TOP3A mutations have been reported to cause Bloom syndrome-like disorder. However, whether the two function play equal roles in the disease pathogenesis is unclear. We retrospectively studied the disease progression of two siblings with Bloom-like syndrome caused by two novel mutations of TOP3A, p.Q788* and p.D479G. Beside the common clinical manifestations, our patients exhibited liver lipid storage with hepatomegaly. In cellular and molecular biological studies, TOP3A deficiency moderately increased sister chromatid exchanges and decreased cell proliferation compared with BLM or RMI2 deficiency. These changes were rescued by ectopic expression of either of the wildtype TOP3A or TOP3A-D479G. In contrast, reduced mitochondrial ATP generation and oxygen consumption rates observed in TOP3A defective cells were rescued by over-expression of the wildtype TOP3A, but not TOP3A-D479G. Considering the different impact of the TOP3A-D479G mutation on the genome stability and mitochondrial metabolism, we propose that the impaired mitochondrial metabolism plays an important role in the pathogenesis of TOP3A-deficient Bloomlike disease.

Automated summary

The study investigated a Bloom-like syndrome caused by TOP3A mutations, showing that the defects affect both genome stability and mitochondrial metabolism, suggesting the importance of impaired mitochondrial metabolism in disease pathogenesis.