Diagnosis of TBC1D32-associated conditions: Expanding the phenotypic spectrum of a complex ciliopathy.

Exome sequencing is a powerful tool in prenatal and postnatal genetics and can help identify novel candidate genes critical to human development. We describe seven unpublished probands with rare likely pathogenic variants or variants of uncertain significance that segregate with recessive disease in TBC1D32, including four fetal probands in three unrelated pedigrees and three pediatric probands in unrelated pedigrees. We also report clinical comparisons with seven previously published patients. Index probands were identified through an ongoing prenatal exome sequencing study and through an online data sharing platform (Gene Matcher™). A literature review was also completed. TBC1D32 is involved in the development and function of cilia and is expressed in the developing hypothalamus and pituitary gland. We provide additional data to expand the phenotype correlated with TBC1D32 variants, including a severe prenatal phenotype associated with life-limiting congenital anomalies.

Ciliary genes TBC1D32/C6orf170 and SCLT1 are mutated in patients with OFD type IX.

Clinical syndromes caused by defects in the primary cilium are heterogeneous but there are recurrent phenotypic manifestations that define them as a collective group known as ciliopathies. Dozens of genes have been linked to various ciliopathies but large patient cohorts have clearly revealed the existence of additional genetic heterogeneity, which is yet to be fully appreciated. In our search for novel ciliopathy-linked genes through the study of unmapped ciliopathy phenotypes, we have identified two simplex cases with a severe ciliopathy phenotype consistent with oro-facio-digital syndrome type IX featuring midline cleft, microcephaly, and colobomatous microphathalmia/anophthalmia. In addition, there was variable presence of polydactyly, absent pituitary, and congenital heart disease. The autozygome of each index harbored a single novel truncating variant as revealed by exome sequencing, and the affected genes (SCLT1 and TBC1D32/C6orf170) have established roles in centrosomal biology and ciliogenesis. Our findings suggest a previously unrecognized role of SCLT1 and TBC1D32 in the pathogenesis of ciliopathy in humans.

Loss-of-Function Variants in TBC1D32 Underlie Syndromic Hypopituitarism.

CONTEXT: Congenital pituitary hormone deficiencies with syndromic phenotypes and/or familial occurrence suggest genetic hypopituitarism; however, in many such patients the underlying molecular basis of the disease remains unknown. OBJECTIVE: To describe patients with syndromic hypopituitarism due to biallelic loss-of-function variants in TBC1D32, a gene implicated in Sonic Hedgehog (Shh) signaling. SETTING: Referral center. PATIENTS: A Finnish family of 2 siblings with panhypopituitarism, absent anterior pituitary, and mild craniofacial dysmorphism, and a Pakistani family with a proband with growth hormone deficiency, anterior pituitary hypoplasia, and developmental delay. INTERVENTIONS: The patients were investigated by whole genome sequencing. Expression profiling of TBC1D32 in human fetal brain was performed through in situ hybridization. Stable and dynamic protein-protein interaction partners of TBC1D32 were investigated in HEK cells followed by mass spectrometry analyses. MAIN OUTCOME MEASURES: Genetic and phenotypic features of patients with biallelic loss-of-function mutations in TBC1D32. RESULTS: The Finnish patients harboured compound heterozygous loss-of-function variants (c.1165_1166dup p.(Gln390Phefs*32) and c.2151del p.(Lys717Asnfs*29)) in TBC1D32; the Pakistani proband carried a known pathogenic homozygous TBC1D32 splice-site variant c.1372 + 1G > A p.(Arg411_Gly458del), as did a fetus with a cleft lip and partial intestinal malrotation from a terminated pregnancy within the same pedigree. TBC1D32 was expressed in the developing hypothalamus, Rathke's pouch, and areas of the hindbrain. TBC1D32 interacted with proteins implicated in cilium assembly, Shh signaling, and brain development. CONCLUSIONS: Biallelic TBC1D32 variants underlie syndromic hypopituitarism, and the underlying mechanism may be via disrupted Shh signaling.