A novel variant in ubiquinone biosynthesis highly prevalent in Papua New Guinea children increases mortality following bacterial pneumonia

Abstract To identify immune variants predisposing to severe pneumonia, we performed whole exome sequencing in a pediatric population highly susceptible to acute lower respiratory infections, identifying a candidate novel variant in the ubiquinone (CoQ10) biosynthetic pathway. To evaluate the effect of this variant on immune function during bacterial pneumonia, we generated a mouse line using CRISPR-Cas9 that expresses the homologous aspartate to tyrosine variant in the enzyme COQ6. Intra-tracheal S. pneumoniae infection leads to increased bacteremia and mortality in mice homozygous for the variant despite similar numbers of immune cells in the lung. Mechanistic studies show that macrophages expressing the variant have decreased mitochondrial activity at the ubiquinone-dependent reduction of cytochrome c by complex III, as well as decreased maximum respiratory capacity in response to acute stimulation. Variant-expressing macrophages also exhibit impaired generation of mitochondrial reactive oxygen species (mROS) causing a direct, intrinsic defect in intracellular killing of internalized bacteria. Thus, the novel variant in CoQ10 biosynthesis leads to changes in macrophage mitochondria and an intrinsic inability to kill internalized bacteria. As alveolar macrophages are the first responders in the lung to bacterial challenge, the inability of these macrophages to mount a sufficient immune response can explain the observed increase in mortality following bacterial pneumonia. Because variants in CoQ10 biosynthesis can be supplemented with CoQ10, a readily available therapy may be able to correct this defect and improve survival in children with this variant