Showing papers by "Detlef Weigel published in 1988"

Functional interactions of neurogenic genes of Drosophila melanogaster.

Abstract: The neurogenic genes of Drosophila melanogaster are involved in the decision of ectodermal cells to take on a neural or an epidermal fate. We present evidence in support of the notion that six of the neurogenic genes are functionally related. We studied the phenotype of embryos lacking one of the neurogenic genes in the presence of an increased dosage of the wild-type allele of another neurogenic gene. Our analysis also included the Hairless locus, whose function is related to that of the neurogenic genes, as well as to many other genes. The effects observed were asymmetric in that triploidy for a given gene modified the phenotype of loss of the function of another gene, but triploidy of the latter gene did not modify the phenotype of loss of the function of the former gene. These asymmetries allowed us to establish a polarity of gene interactions, as well as to order the genes according to the assumed ability of some of them to modify the activity of others. In this sequence, almondex is the first link and Enhancer of split the last one. Our evidence suggests that the function of big brain is independent of the function of the other six. The consequences of this arrangement for the commitment of ectodermal cells are discussed.

Terminal versus segmental development in the Drosophila embryo: the role of the homeotic gene fork head

Abstract: Mutations of the homeotic gene fork head (fkh) of Drosophila transform the non-segmented terminal regions of the embryonic ectoderm into segmental derivatives: Pre-oral head structures and the foregut are replaced by post-oral head structures which are occasionally associated with thoracic structures. Posterior tail structures including the hindgut and the Malpighian tubules are replaced by post-oral head structures associated with anterior tail structures. The fkh gene shows no maternal effect and is required only during embryogenesis. The phenotypes of double mutants indicate that fkh acts independently of other homeotic genes (ANT-C, BX-C, spalt) and caudal. In addition, the fkh domains are not expanded in Polycomb (Pc) group mutant embryos. Ectopic expression of the homeotic selector genes of the ANT-C and BX-C in Pc group mutant embryos causes segmental transformations in terminal regions of the embryo only in the absence of fkh gene activity. Thus, fkh is a region-specific homeotic rather than a selector gene, which promotes terminal as opposed to segmental development.