Mild case of Curry-Jones syndrome.

The main features of the Curry-Jones syndrome are syndactyly, pre-axial polydactyly, craniosynostosis, absent corpus callosum, skin anomalies (characteristic pearly white areas that become scarred and atrophic, with increased hair growth), colobomas or microphthalmia and intestinal obstruction because of multiple benign myofibromata of the large bowel. Developmental delay occurs in half of the reported patients. The patient reported here has a mild form of the condition with polysyndactyly and skin changes but no craniosynostosis, bowel problems or developmental delay.

Congenital abnormalities of body patterning: embryology revisited.

Many of the developmental mechanisms and molecular pathways that underlie fundamental features of body patterning are shared by all vertebrates, and some have even been conserved across evolution from invertebrates to vertebrates. Defects in such processes are a common cause of congenital malformation syndromes, and rapid progress is being made in elucidating their embryological and genetic basis. Here, I focus on three examples, each of which has been the subject of recent advances, and which together illustrate many of the most interesting and important aspects of these disorders. The first example is the development of the pharyngeal apparatus and its perturbation in DiGeorge's syndrome; the second is the induction and differentiation of the forebrain and its perturbation in holoprosencephaly; and the third is the role played by the human HOX genes in congenital malformations.

An I47L substitution in the HOXD13 homeodomain causes a novel human limb malformation by producing a selective loss of function.

The 5' members of the Hoxa and Hoxd gene clusters play major roles in vertebrate limb development. One such gene, HOXD13, is mutated in the human limb malformation syndrome synpolydactyly. Both polyalanine tract expansions and frameshifting deletions in HOXD13 cause similar forms of this condition, but it remains unclear whether other kinds of HOXD13 mutations could produce different phenotypes. We describe a six-generation family in which a novel combination of brachydactyly and central polydactyly co-segregates with a missense mutation that substitutes leucine for isoleucine at position 47 of the HOXD13 homeodomain. We compared the HOXD13(I47L) mutant protein both in vitro and in vivo to the wild-type protein and to an artificial HOXD13 mutant, HOXD13(IQN), which is completely unable to bind DNA. We found that the mutation causes neither a dominant-negative effect nor a gain of function, but instead impairs DNA binding at some sites bound by wild-type HOXD13. Using retrovirus-mediated misexpression in developing chick limbs, we showed that wild-type HOXD13 could upregulate chick EphA7 in the autopod, but that HOXD13(I47L) could not. In the zeugopod, however, HOXD13(I47L) produced striking changes in tibial morphology and ectopic cartilages, which were never produced by HOXD13(IQN), consistent with a selective rather than generalised loss of function. Thus, a mutant HOX protein that recognises only a subset of sites recognised by the wild-type protein causes a novel human malformation, pointing to a hitherto undescribed mechanism by which missense mutations in transcription factors can generate unexpected phenotypes. Intriguingly, both HOXD13(I47L) and HOXD13(IQN) produced more severe shortening in proximal limb regions than did wild-type HOXD13, suggesting that functional suppression of anterior Hox genes by more posterior ones does not require DNA binding and is mediated by protein:protein interactions.

Broad phenotypic spectrum caused by an identical heterozygous CDMP-1 mutation in three unrelated families.

CDMP-1, a cartilage-specific member of the TGFss superfamily of secreted signaling molecules, plays a key role in chondrogenesis, growth and patterning of the developing vertebrate skeleton. Homozygous CDMP-1 mutations cause Hunter-Thompson and Grebe types of acromesomelic chondrodysplasia and DuPan syndrome in humans, as well as brachypodism in mice, while heterozygous mutations cause brachydactyly type C (BDC). We present clinical and radiographic data from three unrelated families in which 12 members share the same heterozygous CDMP-1 mutation, an insertion (insG206), resulting in a frameshift predicted to cause functional haploinsufficiency. Although eight mutation carriers display BDC, four have normal hands and feet, confirming nonpenetrance of BDC with CDMP-1 mutations. In addition, several carriers have other skeletal abnormalities, including severe bilateral vertical talus (in two), developmental hip dysplasia (in one), and short stature (in two, who are otherwise unaffected). Premature vertebral end-plate disease was observed in four mutation carriers and was associated with spondylolysis and spondylolisthesis in three of these. Axial skeletal involvement has not been previously reported in association with CDMP-1 mutations. This finding is consistent with CDMP-1 expression in human hypertrophic chondrocytes, which are present in the ring epiphyses of vertebral end plates. Phenotypic variation in BDC has previously been attributed either to locus heterogeneity or to the varied functional effects of different CDMP-1 mutations. The remarkable range of phenotypes caused by this identical CDMP-1 mutation in these families emphasizes the crucial role of genetic background, stochastic variation and/or environmental factors in modifying the observed phenotype. Our findings illustrate that nonpenetrance for the typical features of BDC can be appreciable and that atypical skeletal features that have been reported in some patients with BDC (i.e., clubfoot, short stature, spondylolysis) may also result from CDMP-1 mutation.

Limb malformations and the human HOX genes.

HOX genes encode a family of transcription factors of fundamental importance for body patterning during embryonic development. Humans, like most vertebrates, have 39 HOX genes organized into four clusters, with major roles in the development of the central nervous system, axial skeleton, gastrointestinal and urogenital tracts, external genitalia, and limbs. The first two limb malformations shown to be caused by mutations in the human HOX genes were synpolydactyly and hand-foot-genital syndrome, which result from mutations in HOXD13 and HOXA13, respectively. This review describes a variety of limb malformations now known to be caused by specific different mutations in these two genes, including polyalanine tract expansions, nonsense mutations, and missense mutations, many with phenotypic consequences that could not have been predicted from previous knowledge of mouse models or HOX protein function. Limb malformations may also result from chromosomal deletions involving the HOXD and HOXA clusters, and from regulatory mutations affecting single or multiple HOX genes.

The mutational spectrum of brachydactyly type C.

Growth/differentiation factor-5 (GDF5), also known as cartilage-derived morphogenetic protein-1 (CDMP-1), is a secreted signaling molecule that participates in skeletal morphogenesis. Heterozygous mutations in GDF5, which maps to human chromosome 20, occur in individuals with autosomal dominant brachydactyly type C (BDC). Here we show that BDC is locus homogeneous by reporting a GDF5 frameshift mutation segregating with the phenotype in a family whose trait was initially thought to map to human chromosome 12. We also describe heterozygous mutations in nine additional probands/families with BDC and show nonpenetrance in a mutation carrier. Finally, we show that mutant GDF5 polypeptides containing missense mutations in their active domains do not efficiently form disulfide-linked dimers when expressed in vitro. These data support the hypothesis that BDC results from functional haploinsufficiency for GDF5.

A HOXA13 allele with a missense mutation in the homeobox and a dinucleotide deletion in the promoter underlies Guttmacher syndrome.

Guttmacher syndrome, a dominantly inherited combination of distal limb and genital tract abnormalities, has several features in common with hand-foot-genital syndrome (HFGS), including hypoplastic first digits and hypospadias. The presence of features not seen in HFGS, however, including postaxial polydactyly of the hands and uniphalangeal 2(nd) toes with absent nails, suggests that it represents a distinct entity. HFGS is caused by mutations in the HOXA13 gene. We have therefore re-investigated the original Guttmacher syndrome family, and have found that affected individuals are heterozygous for a novel missense mutation in the HOXA13 homeobox (c.1112A>T; homeodomain residue Q50L), which arose on an allele already carrying a novel 2-bp deletion (-78-79delGC) in the gene's highly conserved promoter region. This deletion produces no detectable abnormalities on its own, but may contribute to the phenotype in the affected individuals. The missense mutation, which alters a key residue in the recognition helix of the homeodomain, is likely to perturb HOXA13's DNA-binding properties, resulting in both a loss and a specific gain of function.

A 117-kb microdeletion removing HOXD9-HOXD13 and EVX2 causes synpolydactyly.

Studies in mouse and chick have shown that the 5' HoxD genes play major roles in the development of the limbs and genitalia. In humans, mutations in HOXD13 cause the dominantly inherited limb malformation synpolydactyly (SPD). Haploinsufficiency for the 5' HOXD genes has recently been proposed to underlie the monodactyly and penoscrotal hypoplasia in two children with chromosomal deletions encompassing the entire HOXD cluster. Similar deletions, however, have previously been associated with split-hand/foot malformation (SHFM), including monodactyly. Here we report a father and daughter with SPD who carry a 117-kb microdeletion at the 5' end of the HOXD cluster. By sequencing directly across the deletion breakpoint, we show that this microdeletion removes only HOXD9-HOXD13 and EVX2. We also report a girl with bilateral split foot and a chromosomal deletion that includes the entire HOXD cluster and extends approximately 5 Mb centromeric to it. Our findings indicate that haploinsufficiency for the 5' HOXD genes causes not SHFM but SPD and point to the presence of a novel locus for SHFM in the interval between EVX2 and D2S294. They also suggest that there is a regulatory region, upstream of the HOXD cluster, that is responsible for activating the cluster as a whole.