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Abstract
zfh-1 is a member of the zfh family of proteins, which all contain zinc finger and homeodomains. The roles and mechanisms of action of most family members are still unclear. However, we have shown previously that another member of the family, the vertebrate ZEB protein, is a transcriptional repressor that binds E box sequences and inhibits myotube formation in cell culture assays. zfh-1 is downregulated in Drosophila embryos prior to myogenesis. Embryos with zfh-1 loss-of-function mutation show alterations in the number and position of embryonic somatic muscles, suggesting that zfh-1 could have a regulatory role in myogenesis. However, nothing is known about the nature or mechanism of action of zfh-1. Here, we demonstrate that zfh-1 is a transcription factor that binds E box sequences and acts as an active transcriptional repressor. When zfh-1 expression was maintained in the embryo beyond its normal temporal pattern of downregulation, the differentiation of somatic but not visceral muscle was blocked. One potential target of zfh-1 in somatic myogenesis could be the myogenic factor mef2. mef2 is known to be regulated by the transcription factor twist, and we show here that zfh-1 binds to sites in the mef2 upstream regulatory region and inhibits twist transcriptional activation. Even though there is little sequence similarity in the repressor domains of ZEB and zfh-1, we present evidence that zfh-1 is the functional homologue of ZEB and that the role of these proteins in myogenesis is conserved from Drosophila to mammals.
ACKNOWLEDGMENTS
We are extremely thankful to E. Bier, R. Cagan, S. T. Crews, T. Genetta, S. Hayashi, Y. T. Ip, D. Kiehart, R. Kopan, R. Krusnow, Z. C. Lai, B. Patterson, and C. Thummel for kindly providing antibodies, plasmids, and fly stocks. We specially thank E. N. Olson and R. Cripps for providing unpublished results on the sequence of the mef2 promoter and also E. N. Olson for critical reading of the manuscript. We also thank P. Taghert and R. Benveniste for help in managing fly stocks.
A.A.P. was supported by the Leukemia Society. This work was supported by grants to J.B.S. (from the Cancer Research Fund of the Damon Runyon-Walter Winchell Foundation Award [DRS-9] and from HHMI Res. Resources Program for Medical Schools Junior Faculty award 76296-538202) and to D.C.D. (from the NIH).