Here we describe the successful generation of an induced pluripotent stem cell (iPSC) line KCi002-A from a male with BBS, homozygous for the disease causing variant c.271insT, p.(Cys91fsX95) in BBS10.Resource table.
Sanger sequencing of the most commonly mutated genes (BBS1, BBS2 and BBS10) accounting for ∼50% of BBS patients determined mutations only in BBS2, including three novel mutations.
Sequence analysis revealed a novel homozygous missense mutation (c.281T>C, p.Ile94Thr) in the gene ARL6 in family A and a nonsense mutation (c.1075C>T, p.Gln359*) in the gene BBS10 in family B. Mutations identified in the present study extend the body of evidence implicating the genes ARL6 and BBS10 in causing Bardet-Biedl syndrome.
Such a large deletion in BBS10 has not been reported previously in any population and is likely to be contributing to the phenotype of Bardet-Biedl Syndrome in this family.
Three additional BBS genes (BBS6, BBS10, and BBS12) have homology to type II chaperonins and interact with CCT/TRiC proteins and BBS7 to form a complex termed the BBS-chaperonin complex.
Given the fact that mutations in BBS genes have already been found in Meckel-like fetuses, and in light of the major contribution of BBS10 to BBS, the BBS10 gene was sequenced in 20 fetal cases and a child diagnosed antenatally presenting with characteristic renal anomalies and polydactyly, but without biliary dysgenesis.
Our data demonstrate that BBS6, BBS10, and BBS12 are necessary for BBSome assembly, and that impaired BBSome assembly contributes to the etiology of BBS phenotypes associated with the loss of function of these three BBS genes.
These findings (a) confirm a previous report that FLJ23560 (BBS10) mutations are a significant cause of BBS, and (b) further demonstrate the utility of high-density SNP array mapping in consanguineous families for the mapping and identification of recessive disease genes.