Expression patterns of the whole troponin C gene repertoire during Drosophila development.

The success of the genomic sequencing programs allows the discovery of additional family members of genes encoding known functions. This is the case of the Troponin C gene repertoire in Drosophila melanogaster. We have found two new Troponin C genes, DmTpnC41F and DmTpnC25D, increasing to five the total number of Troponin C genes identified in this species. The comparative characterization of the five Troponin C genes in D. melanogaster demonstrates considerable variation in gene structure and expression pattern. Expression of one gene, DmTpnC41F, has more restricted tissue specificity than the rest of the TpnC genes and, with the chromosomically linked DmTpnC41C, is expressed specifically in the adult thorax. The new gene, DmTpnC25D is expressed during development more broadly than the rest. In adults, it is highly expressed in the adult head. Finally, the other two genes, DmTpnC47D and DmTpnC73F, show a high embryonic/larval expression and in adults are expressed almost exclusively in the abdomens. The functional adaptive changes that may have evolved during the expansion of this gene family are briefly discussed in terms of the expression patterns, gene and protein structures leading to a simpler, more systematic nomenclature of the gene family.

The Hox gene abdominal-A specifies heart cell fate in the Drosophila dorsal vessel.

The Drosophila melanogaster dorsal vessel is a linear organ that pumps blood through the body. Blood enters the dorsal vessel in a posterior chamber termed the heart, and is pumped in an anterior direction through a region of the dorsal vessel termed the aorta. Although the genes that specify dorsal vessel cell fate are well understood, there is still much to be learned concerning how cell fate in this linear tube is determined in an anteroposterior manner, either in Drosophila or in any other animal. We demonstrate that the formation of a morphologically and molecularly distinct heart depends crucially upon the homeotic segmentation gene abdominal-A (abd-A). abd-A expression in the dorsal vessel was detected only in the heart, and overexpression of abd-A induced heart fate in the aorta in a cell-autonomous manner. Mutation of abd-A resulted in a loss of heart-specific markers. We also demonstrate that abd-A and sevenup co-expression in cardial cells defined the location of ostia, or inflow tracts. Other genes of the Bithorax Complex do not appear to participate in heart specification, although high level expression of Ultrabithorax is capable of inducing a partial heart fate in the aorta. These findings for the first time demonstrate a specific involvement for Hox genes in patterning the muscular circulatory system, and suggest a mechanism of broad relevance for animal heart patterning.