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Novel exon-skipping variant disrupting the basic domain of HCFC1 causes intellectual disability without metabolic abnormalities in both male and female patients.

Parith WongkittichoteDaniel J WegnerMarwan S Shinawi
Published in: Journal of human genetics (2021)
HCFC1, a global transcriptional regulator, has been shown to associate with MMACHC expression. Pathogenic variants in HCFC1 cause X-linked combined methylmalonic acidemia and hyperhomocysteinemia, CblX type (MIM# 309541). Recent studies showed that certain variants in HCFC1 are associated with X-linked intellectual disability with mild or absent metabolic abnormalities. Here, we report five subjects (three males, two females) from the same family with a novel predicted loss of function HCFC1 variant. All five patients exhibit developmental delay or intellectual disability/learning difficulty and some dysmorphic features; findings were milder in the female as compared to male subjects. Biochemical studies in all patients did not show methylmalonic acidemia or hyperhomocysteinemia but revealed elevated vitamin B12 levels. Trio exome sequencing of the proband and his parents revealed a maternally inherited novel variant in HCFC1 designated as c.1781_1803 + 3del26insCA (NM_005334). Targeted testing confirmed the presence of the same variant in two half-siblings and maternal great uncle. In silico analysis showed that the variant is expected to reduce the quality of the splice donor site in intron 10 and causes abnormal splicing. Sequencing of proband's cDNA revealed exon 10 skipping. Further molecular studies in the two manifesting females revealed moderate and high skewing of X inactivation. Our results support previous observation that HCFC1 variants located outside the Kelch domain exhibit dissociation of the clinical and biochemical phenotype and cause milder or no metabolic changes. We also show that this novel variant can be associated with a phenotype in females, although with milder severity, but further studies are needed to understand the role of skewed X inactivation among females in this rare disorder. Our work expands the genotypes and phenotypes associated with HCFC1-related disorder.
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