Null mutations at the polyhomeotic locus of Drosophila produce a complex phenotype during embryogenesis, which includes death of the ventral epidermis, misregulation of homeotic and segmentation gene expression, and global misrouting of CNS axons. It is shown here, through the use of mosaic analyses, double mutant combinations, and in vitro culture experiments, that all aspects of the phenotype with the exception of the axonal phenotype are cell autonomous. The changes in homeotic and segmentation gene expression in the CNS are not caused by death of the ventral epidermis, but are cell autonomous effects which most likely cause changes in neuronal cell identity. The axonal phenotype associated with ph mutations is also independent of epidermal cell death, but may be due to the nonautonomous effects of altered neuronal identities or to death or transformation of some as yet unidentified cell type. Despite the apparent autonomy of the ph mutation, mutant neurons can influence the development of adjacent wild-type neurons, presumably by depriving them of their normal fasciculation partners.

Hypomorphic alleles of the locus polyhomeotic (ph) produce multiple, homeotic-like transformations in adult flies that mimic dominant mutations in the Antennapedia and Bithorax complexes. Analysis of null alleles of ph has revealed a complex, embryonically lethal phenotype that includes cell death of the ventral epidermis and abnormalities in the patterns of expression of homeotic and segmentation genes. There is also a dramatic alteration in the pattern of axon pathways in the central nervous system, such that the wild-type array of segmentally repeated commissures and connectives is replaced by bundles of axons confined to the hemiganglia of origin. It is possible that this axonal phenotype is the result of loss of neuronal identity caused by abnormal homeotic and segmentation gene expression.