A hypomorphic FLVCR2 variant resulting in moderate transport deficiency causes hydranencephaly syndrome with brain calcifications.

Abstract

FLVCR2 is a highly conserved member of the major facilitator superfamily (MFS), the largest superfamily of solute carriers that are involved in the transport of small molecules across lipid bilayers. The loss of the murine ortholog Mfsd7c, an endothelial transporter in brain blood vessels, causes brain angiogenic growth deficiency and lethality. Recessive FLVCR2 variants cause proliferative vasculopathy and hydranencephaly-hydrocephaly syndrome (PVHH), also known as Fowler syndrome. This often-lethal condition features microcephaly, skeletal deformities, and severe cerebrovascular defects. Although a number of cases have been reported, very limited evidence of the pathogenicity of FLVCR2 variants is available. In this study, we thoroughly investigated a new fetal case of Fowler syndrome. Through exome sequencing, we identified two compound heterozygous FLVCR2 variants: the maternal c.1124+3_1124+6del and the paternal p.(Arg492Trp). The effects of the c.1124+3_1124+6del variant were investigated through a minigene assay, which showed impaired splicing of the exon 5 of FLVCR2. To characterize the impact of the p.(Arg492Trp) substitution, we performed protein modeling using Rosetta and DynaMut2, that showed a highly destabilizing effect. Then, based on the very recent evidence that choline is a major FLVCR2 ligand, we performed a radiolabeled-choline or ethanolamine transport assays in HEK 293 cells and found that the p.(Arg492Trp) variant causes a 50-60% reduction of FLVCR2 transport activity, resulting in a net activity of 25-30%. Our findings suggest that FLVCR2 deficiency may be sufficient to cause PVHH even in the absence of a complete loss of transport activity, possibly involving extragenetic factors in the pathophysiology of this complex condition.