EEC syndrome is an autosomal dominant disorder characterized by ectrodactyly, ectodermal dysplasia, and facial clefts. We have mapped the genetic defect in several EEC syndrome families to a region of chromosome 3q27 previously implicated in the EEC-like disorder, limb mammary syndrome (LMS). Analysis of the p63 gene, a homolog of p53 located in the critical LMS/EEC interval, revealed heterozygous mutations in nine unrelated EEC families. Eight mutations result in amino acid substitutions that are predicted to abolish the DNA binding capacity of p63. The ninth is a frameshift mutation that affects the p63alpha, but not p63beta and p63gamma isotypes. Transactivation studies with these mutant p63 isotypes provide a molecular explanation for the dominant character of p63 mutations in EEC syndrome.
Ulnar-mammary syndrome (UMS) is a pleiotropic disorder affecting limb, apocrine-gland, tooth, hair, and genital development. Mutations that disrupt the DNA-binding domain of the T-box gene, TBX3, have been demonstrated to cause UMS. However, the 3' terminus of the open reading frame (ORF) of TBX3 was not identified, and mutations were detected in only two families with UMS. Furthermore, no substantial homology outside the T-box was found among TBX3 and its orthologues. The subsequent cloning of new TBX3 cDNAs allowed us to complete the characterization of TBX3 and to identify alternatively transcribed TBX3 transcripts, including one that interrupts the T-box. The complete ORF of TBX3 is predicted to encode a 723-residue protein, of which 255 amino acids are encoded by newly identified exons. Comparison of other T-box genes to TBX3 indicates regions of substantial homology outside the DNA-binding domain. Novel mutations have been found in all of eight newly reported families with UMS, including five mutations downstream of the region encoding the T-box. This suggests that a domain(s) outside the T-box is highly conserved and important for the function of TBX3. We found no obvious phenotypic differences between those who have missense mutations and those who have deletions or frameshifts.
A major goal of biology has been to understand the developmental mechanisms behind evolutionary trends. This has led to a growing interest in studying the molecular basis of the evolution of developmental programs such as those mediating the diversification of tetrapod limbs. Over the last 10 y, it has become clear that the genes and general developmental programs used to build a limb are strongly conserved among widely disparate species. This finding suggests that altered regulation of the timing and locations of developmental events may be responsible for the morphologic variation observed among some species. However, genetic analyses of the regulatory regions of genes controlling vertebrate developmental programs are very limited. Characterization of the genetic basis of human birth defects of the limb provides an opportunity to dissect the developmental programs used to modify the architecture of the hominoid limb. This may allow us to assess the relative contributions of altered gene regulation to morphologic variation among species and reconstruct the evolutionary history of the hominid limb. Such insight is also important because morphologic differences in the hominid upper limb have been correlated with the use of tools, and tool making is often regarded as the milestone that marked the emergence of the genus Homo.
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