David A. Hartley

slit: An EGF-homologous locus of D. melanogaster involved in the development of the embryonic central nervous system

A family of loci homologous to the EGF-like portion of Notch, a gene involved in neurogenesis, have been identified in D. melanogaster. The sequence, spatial, and temporal distribution of both RNA and protein of one of these loci suggest a possible role in the development of the central nervous system (CNS). In situ hybridization and antibody staining of embryos show initial localization in cells along the midline of the neuroepithelium. High level expression is restricted in the developing embryo to a subset of six midline glial cells abutting growing axons. Extracellular localization is suggested by the presence of EGF-like repeats in the deduced protein sequence and antibody staining. Cytological, immunocytochemical, genetic, and molecular data show that this gene corresponds to the slit locus. Mutations in this locus result in the collapse of the regular scaffold of commissural and longitudinal axon tracts in the embryonic central nervous system.

The molecular genetics of Enhancer of split, a gene required for embryonic neural development in Drosophila.

In Drosophila, the very first steps in neurogenesis appear to be controlled by a small group of zygotically acting genes termed the neurogenic loci. Mutations in any of these genes result in a misrouting of epidermal lineages into the neural pathway. Morphological and molecular studies suggest that the correct ectodermal differentiation is mediated by a cell‐cell interaction mechanism and that at least some of the neurogenic loci are involved in this mechanism. The molecular analyses of the neurogenic loci Notch and Delta revealed that the putative gene products are large transmembrane proteins with homology to mammalian epidermal growth factor. We describe here a molecular analysis of Enhancer of split [E(spl)], a third neurogenic locus, which displays striking genetic interactions with both Notch and Delta, suggesting a close functional relationship of the respective gene products. We provide evidence for a single genetic complementation group corresponding to a single transcription unit which is necessary for wild‐type E(spl) function. P‐element‐mediated transformation indicates that this transcription unit includes functions associated with both the dominant E(spl)D mutation and the recessive visible allele groucho, and is necessary for the correct differentiation of the embryonic nervous system.

The embryonic expression of the Notch locus of Drosophila melanogaster and the implications of point mutations in the extracellular EGF-like domain of the predicted protein.

The Notch locus of Drosophila melanogaster is one of a small number of zygotically acting ‘neurogenic’ genes necessary for the correct segregation of neural from epidermal lineages during embryogenesis. The predicted gene product is implicated in a cell interaction mechanism required to achieve this ectodermal differentiation. We have examined wild‐type Notch expression by in situ hybridization and find it to be expressed in more cells than we would have predicted given a sole function in regulating neurogenesis. We conclude from these data that Notch plays a more general role in development. In order to assess the dependence of Notch expression on other neurogenic gene function we have hybridized Notch probes to Enhancer of split mutants which are known to interfere with expression of Notch phenotypes. We intimate that the nature of interaction between these genes is not at the level of transcription. Instead, the DNA sequence of split, which is a missense mutation in the EGF‐like extracellular domain of the Notch protein, suggests a direct biochemical interaction between Notch and E(spl) proteins. The similar site of a second point mutation, AxE2, implies that protein interactions also occur between Notch proteins. Finally we discuss the general implications of our findings with a view to the models and mechanisms of Notch action in regulating individual cellular interactions during development.

Spontaneous deletion formation at the aprt locus of hamster cells: the presence of short sequence homologies and dyad symmetries at deletion termini.

To examine the factors governing the generation of DNA sequence rearrangements in mammalian somatic cells, we have cloned and sequenced novel junctions produced by six spontaneous deletion mutations at the aprt locus of Chinese hamster ovary cells. Our analyses indicate that these rearrangements were produced by non‐homologous recombinational events occurring between short (2‐7 bp) sequence repeats at the two termini of the deletion which leave one copy of the repeat in the mutant gene. Certain tri‐ and tetranucleotides recur at the deletion termini, suggesting that these may possibly be a recognition sequence for an enzyme involved in the event. No other gene structural alterations were found at the novel junctions or in neighbouring sequences. The deletions are not randomly distributed over the aprt gene; four termini clustered in a 40‐bp sequence. This region of aprt is unusual as it contains both significant stretches of dyad symmetry which could potentially form stable DNA secondary structures and short direct repeats. Regions of dyad symmetry were also found at at least one terminus of all the deletions. In view of the similar properties of this set of deletions, possible mechanisms for the formation of this type of gene rearrangement are considered.

INHIBITION OF CELL FATE IN DROSOPHILA BY ENHANCER OF SPLIT GENES

The neurogenic genes of Drosophila act during many different times and places during development. It is thought their role is to repress cell fate within a group of equivalent cells and thus allow the singling out of discrete numbers of precursors. Amongst the genes at the neurogenic locus, Enhancer of split is a family of seven related genes that encode proteins containing the basic helix-loop-helix motif characteristic of transcriptional regulators. Previous functional analyses of these genes have relied on deletions which eliminate many other genes. We have ectopically expressed two of the Enhancer of split basic helix-loop-helix genes, m5 and m8, to test their effect on the determination of the precursor cells of adult sensory organs. Ectopic expression of m5 or m8 before bristle precursor division results in loss of sensory bristles from all parts of the adult fly. Ectopic expression after bristle precursor division produces bristles with aberrant cuticular structures. We have also tested the effect of reducing Enhancer of split gene function using mitotic recombination and show that this de-represses the neural fate and produces supernumerary sensory bristle neurons. We conclude that the Enhancer of split basic helix-loop-helix genes inhibit neural fate during the selection of neural precursors, and that they also play a role in restricting the neuronal fate to one of the four progeny cells of the bristle precursor.