Exome sequence analysis of siblings affected with Niemann-Pick type C disease

Abstract

Mutations in either the Niemann-Pick type C1 or C2 (NPC1/NPC2) gene result in a fatal lysosomal storage disorder, Niemann-Pick type C (NP-C) disease, for which there is no effective cure. The disease is characterized by systemic and neurodegenerative symptoms arising from toxic accumulation of unesterified cholesterol within the late endosome and lysosome, with a common cause of death for patients being respiratory failure or recurrent infection of pulmonary tissue. Interestingly, the disease symptoms are heterogeneous, with age of onset and severity varied, even among siblings with the same mutations in the NPC1 or NPC2 gene causing this monogenic disease. To date there is no clear explanation for disease severity in siblings with the same mutation. As siblings are raised in the same environment, the major hypothesis of this thesis is that there are genetic modifiers that explain variation in disease severity within siblings. To determine if there are genetic variants associated with disease severity, exomes were sequenced from five sibling pairs exhibiting divergent onset and progression of NPC disease. Out of 23,105 genes, 26 variants were identified that were predicted to have functional consequences in NP-C patients, of which homozygous MUC5B and MARCH8 variants segregated across siblings that exhibited increased and decreased severity of disease, respectively. A cluster of variants was discovered on chromosome 11 belonging to the matrix metalloproteinase (MMP) family. Further investigation of one of these variants, a frameshift insertion in MMP-12, confirmed that this locus regulates the accumulation of unesterified cholesterol in primary neurons derived from a murine model of NPC disease. However, this region on chromosome 11 did not have any statistically significant copy number alteration detectable through a depth of coverage analysis. Overall, these results provide groundwork into the sequence variants mediating disease severity, which with further investigations, may be novel pharmacological targets to treat NPC disease.