Mutations in the Homeodomain of HOXD13 Cause Syndactyly Type 1-c in Two Chinese Families

Hox genes regulate patterning during limb development. It is believed that they function in the determination of the timing and extent of local growth rates. Here, it is demonstrated that synpolydactyly, an inherited human abnormality of the hands and feet, is caused by expansions of a polyalanine stretch in the amino-terminal region of HOXD13. The homozygous phenotype includes the transformation of metacarpal and metatarsal bones to short carpal- and tarsal-like bones. The mutations identify the polyalanine stretch outside of the DNA binding domain of HOXD13 as a region necessary for proper protein function. Show more

Syndactyly is one of the most common hereditary limb malformations depicting the fusion of certain fingers and/or toes. It may occur as an isolated entity or a component of more than 300 syndromic anomalies. Syndactylies exhibit great inter- and intra-familial clinical variability. Even within a subject, phenotype can be unilateral or bilateral and symmetrical or asymmetrical. At least nine non-syndromic syndactylies with additional sub-types have been characterized. Most of the syndactyly types are inherited as autosomal dominant but two autosomal recessive and an X-linked recessive entity have also been described. Whereas the underlying genes/mutations for types II-1, III, IV, V, and VII have been worked out, the etiology and molecular basis of the other syndactyly types remain unknown. In this communication, based on an overview of well-characterized isolated syndactylies, their cardinal phenotypes, inheritance patterns, and clinical and genetic heterogeneities, a 'current classification scheme' is presented. Despite considerable progress in the understanding of syndactyly at clinical and molecular levels, fundamental questions regarding the disturbed developmental mechanisms leading to fused digits, remain to be answered. Show more

The structure of the four murine Hox complexes and the co-ordinate expression patterns of Hox genes have been elucidated for almost a decade. However, clues about their developmental functions have been recently uncovered from the analysis of loss-of-function mutants generated by the gene targeting technique, as well as from transgenic mice with altered Hox gene expression domains. The 'anterior' Hox genes control the morphogenetic programme of specific hindbrain segments (rhombomeres) or pharyngeal arch neural crest derivatives. Various studies indicate that Hox gene products act in a region-specific, combinatorial and partly redundant manner to specify the identities of developing vertebrae. In addition, 'posterior' HoxA and HoxD genes act coordinately to control the growth and morphogenesis of skeletal structures along the proximodistal axis of developing limbs. Studies in other vertebrate model systems suggest that the evolution of Hox gene functions has allowed for the acquisition of specific morphological features along both the vertebral column and limbs of tetrapods. Gene targeting studies have also revealed region-specific functions of Hox genes along the developing digestive and genito-urinary tracts. Show more