Molecular Cloning and Characterization of Human Cardiac Homeobox Gene CSX1

Abstract

Accumulating evidence has suggested that homeodomain-containing proteins play critical roles in regulating the tissue-specific gene expression essential for tissue differentiation and in determining the temporal and spatial patterns of development. In order to elucidate the mechanisms of human heart development, we have isolated a human homologue of the murine cardiac homeobox gene Csx (also called Nkx-2.5) and denoted it as CSX1. The amino acid sequence of the CSX1 homeodomain is 100% and 67% identical to that of murine Csx/Nkx-2.5 and Drosophila tinman, respectively. CSX1 has at least three isoforms generated by an alternative splicing mechanism. One of these isoforms (CSX1a) encodes a protein of ≈35 kD that possesses the homeodomain, whereas the other two (CSX1b and CSX1c) encode a truncated protein of ≈12 kD that is identical to the CSX1a protein at the amino-terminal 112 amino acids but lacks the homeodomain. Northern blot analysis showed that CSX1 transcripts are abundantly expressed in both fetal and adult hearts, but no signal was detected in other human tissues examined. Amplification of each isoform by reverse transcriptase–polymerase chain reaction revealed that all of the three isoforms are expressed in fetal and adult hearts and that the homeobox-containing isoform CSX1a is most abundant. The homeodomain-containing protein encoded by CSX1a binds to Csx/Nkx-2.5 binding sequences and transactivates the sequence-containing luciferase reporter gene. Unexpectedly, the homeodomain-lacking protein encoded by CSX1b also transactivates the reporter gene, although CSX1b does not bind to the Csx/Nkx-2.5 binding sequences. The highly conserved homeodomain sequence in evolution and the restricted expression in the heart suggest that CSX1 plays an important role in the development and differentiation of the human heart and that there may be two different mechanisms in transcriptional regulation by the CSX1 protein, homeodomain-dependent and -independent mechanisms.