De novo, deleterious sequence variants that alter the transcriptional activity of the homeoprotein PBX1 are associated with intellectual disability and pleiotropic developmental defects.

We present eight patients with de novo, deleterious sequence variants in the PBX1 gene. PBX1 encodes a three amino acid loop extension (TALE) homeodomain transcription factor that forms multimeric complexes with TALE and HOX proteins to regulate target gene transcription during development. As previously reported, Pbx1 homozygous mutant mice (Pbx1-/-) develop malformations and hypoplasia or aplasia of multiple organs, including the craniofacial skeleton, ear, branchial arches, heart, lungs, diaphragm, gut, kidneys, and gonads. Clinical findings similar to those in Pbx mutant mice were observed in all patients with varying expressivity and severity, including external ear anomalies, abnormal branchial arch derivatives, heart malformations, diaphragmatic hernia, renal hypoplasia and ambiguous genitalia. All patients but one had developmental delays. Previously reported patients with congenital anomalies affecting the kidney and urinary tract exhibited deletions and loss of function variants in PBX1. The sequence variants in our cases included missense substitutions adjacent to the PBX1 homeodomain (p.Arg184Pro, p.Met224Lys, and p.Arg227Pro) or within the homeodomain (p.Arg234Pro, and p.Arg235Gln), whereas p.Ser262Glnfs*2, and p.Arg288* yielded truncated PBX1 proteins. Functional studies on five PBX1 sequence variants revealed perturbation of intrinsic, PBX-dependent transactivation ability and altered nuclear translocation, suggesting abnormal interactions between mutant PBX1 proteins and wild-type TALE or HOX cofactors. It is likely that the mutations directly affect the transcription of PBX1 target genes to impact embryonic development. We conclude that deleterious sequence variants in PBX1 cause intellectual disability and pleiotropic malformations resembling those in Pbx1 mutant mice, arguing for strong conservation of gene function between these two species.

Clinical and molecular characterization of chromosome 7p22.1 microduplication detected by array CGH.

A 28-month-old Peruvian male presented with speech delay and unusual facial features including prominent forehead, anteverted nares, ocular hypertelorism, and low-set and posteriorly rotated ears with a unilateral preauricular pit. The patient had poor speech with no other developmental delays. Height and weight were normal, although closure of the anterior fontanel and bone age were delayed. Head circumference approximated the 95th centile for age. Following normal routine chromosome analysis and subtelomeric FISH, whole genome microarray revealed a novel interstitial duplication at 7p22.1, approximately 1.7 Mb in size, and containing 13 OMIM annotated genes. FISH studies on the propositus and his parents confirmed that the duplication had occurred de novo. This finding represents the smallest interstitial 7p duplication reported to date, and does not include genes previously implicated as candidates for a 7p duplication syndrome. Common phenotypic features of 7p duplication include distinctive facies with hypertelorism,large anterior fontanel, and intellectual disability. Based on the findings in our patient, and those in previously reported cases of 7p duplication, we propose that genes within this duplicated interval may have a role in skeletal maturation,craniofacial development, and speech acquisition.