A novel family of T-box genes in urodele amphibian limb development and regeneration: candidate genes involved in vertebrate forelimb/hindlimb patterning

Correlation of wing-leg identity in ectopic FGF-induced chimeric limbs with the differential expression of chick Tbx5 and Tbx4

It has been reported that members of the fibroblast growth factor (FGF) family can induce additional limb formation in the flank of chick embryos. The phenotype of the ectopic limb depends on the somite level at which it forms: limbs in the anterior flank resemble wings, whereas those in the posterior flank resemble legs. Ectopic limbs located in the mid-flank appear chimeric, possessing characteristics of both wings and legs; feather buds are present in the anterior halves with scales and claws in the posterior halves. To study the mechanisms underlying the chimerism of these additional limbs, we cloned chick Tbx5 and Tbx4 to use as forelimb and hindlimb markers and examined their expression patterns in FGF-induced limb buds. We found that Tbx5 and Tbx4 were differentially expressed in the anterior and posterior halves of additional limb buds in the mid-flank, respectively, consistent with the chimeric patterns of the integument. A boundary of Tbx5/Tbx4 exists in all ectopic limbs, indicating that the additional limbs are essentially chimeric, although the degree of chimerism is dependent on the position. The boundary of Tbx5/Tbx4 expression is not fixed at a specific position within the interlimb region, but dependent upon where FGF was applied. Since the ectopic expression patterns of Tbx5/Tbx4 in the additional limbs are closely correlated with the patterns of their chimeric phenotypes, it is likely that Tbx5 and Tbx4 expression in the limb bud is involved in determination of the forelimb and hindlimb identities, respectively, in vertebrates.

The T-box gene family

A novel family of transcription factors that appears to play a critical role in the development of all animal species was recently uncovered on the basis of homology of the DNA binding domain of the Brachyury, or T locus, gene product. Phylogenetic studies have shown the ancient origin of this gene family, which has been named the T-box family, prior to the divergence of metazoa from a common ancestral type. T-box genes have now been identified in the genomes of C. elegans, Drosophila, sea urchin, ascidian, amphioxus, Xenopus, chick, zebrafish, mouse, and human and will probably be found in the genomes of all animals. Although functional analyses of T-box family members have just begun, the results show a wide range of roles in developmental processes that extend over time from the unfertilized egg through organogenesis. Only a few mutations in T-box genes are known, but all have drastic effects on development, including a targeted mutation in mice causing an embryonic lethal phenotype, and two human T-box gene mutations that results in developmental syndromes. This review presents a current overview of progress made in the analysis of T-box genes and their products in a variety of model systems.