Abstract
D e h ydro d olichyl d iphosphate s ynthase (DHDDS) is an essential enzyme required for several forms of protein glycosylation in all eukaryotic cells. Surprisingly, three mutant alleles, ( Dhdds (K42E/K42E) (K42E/K42E), Dhdds (T206A/K42E) (T206A/K42E), and found in only one patient, Dhdds (R98W/K42E) (R98W/K42E) have been reported that cause non-syndromic retinitis pigmentosa (RP59), an inherited retinal degeneration (IRD). Because T206A was only observed heterozygously with the K42E allele in RP59 patients, we used CRISPR/CAS9 technology to generate T206A/T206A, and subsequently T206A/K42E alleles in mice to assess the contribution of the T206A allele to the disease phenotype, to model the human disease, and to compare resulting phenotypes to our homozygous K42E mouse model. By postnatal (PN) 12-mo, T206A/K42E mice exhibit significant reduction of inner nuclear layer thickness as was observed in K42E/K42E mice. No change in outer nuclear layer thickness is observed in all mutant phenotypes up to PN 12 mo. Electroretinography (ERG) showed a significantly reduced b-wave without a-wave decrement and by PN 3-mo, ERG c- and d-wave responses were significantly attenuated in all phenotypes. Consistent with a reduction in inner nuclear layer thickness seen by OCT and cell loss observed by histology, bipolar and amacrine cell densities were reduced in all Dhdds mutant phenotypes compared to PN 8-12 mo age-matched controls. These results indicate that the DHDDS T206A allele causes retinal disease independent of the K42E allele, and that there likely is a common disease mechanism involving RP59-associated DHDDS mutations. We conclude that the physiological basis of retinal dysfunction in RP59 involves defective signaling in the inner retina resulting in bipolar/amacrine cell degeneration.