Gad Shaulsky

A two-component histidine kinase gene that functions in Dictyostelium development.

A mutant which failed to complete development was isolated from a population of cells that had been subjected to insertional mutagenesis using restriction enzyme‐mediated integration. The disrupted gene, dhkA, encodes the conserved motifs of a histidine kinase as well as the response regulator domain. It is likely that the histidine in DhkA is autophosphorylated and the phosphate passed to one or more response regulators. Such two‐component systems function in a variety of bacterial signal transduction pathways and have been characterized recently in yeast and Arabidopsis. In Dictyostelium, we found that DhkA functions both in the regulation of prestalk gene expression and in the control of the terminal differentiation of prespore cells.

SDF-2 Induction of Terminal Differentiation in Dictyostelium discoideum Is Mediated by the Membrane-Spanning Sensor Kinase DhkA

ABSTRACT SDF-2 is a peptide released by prestalk cells during culmination that stimulates prespore cells to encapsulate. Genetic evidence indicates that the response is dependent on the dhkA gene. This gene encodes a member of the histidine kinase family of genes that functions in two-component signal transduction pathways. The sequence of the N-terminal half of DhkA predicts two hydrophobic domains separated by a 310-amino-acid loop that could bind a ligand. By inserting MYC6 epitopes into DhkA, we were able to show that the loop is extracellular while the catalytic domain is cytoplasmic. Cells expressing the MYC epitope in the extracellular domain of DhkA were found to respond only if induced with 100-fold-higher levels of SDF-2 than required to inducedhkA+ cells; however, they could be induced to sporulate by addition of antibodies specific to the MYC epitope. To examine the enzymatic activity of DhkA, we purified the catalytic domain following expression in bacteria and observed incorporation of labelled phosphate from ATP consistent with histidine autophosphorylation. Site-directed mutagenesis of histidine1395 to glutamine in the catalytic domain blocked autophosphorylation. Furthermore, genetic analyses showed that histidine1395 and the relay aspartate2075 of DhkA are both critical to its function but that another histidine kinase, DhkB, can partially compensate for the lack of DhkA activity. Sporulation is drastically reduced in double mutants lacking both DhkA and DhkB. Suppressor studies indicate that the cyclic AMP (cAMP) phosphodiesterase RegA and the cAMP-dependent protein kinase PKA act downstream of DhkA.

The wacA gene of Dictyostelium discoideum is a developmentally regulated member of the MIP family

We isolated a cDNA from Dictyostelium discoideum that encodes a 30 kDa protein with significant similarity to members of the major intrinsic protein (MIP) family of membrane transporters. The most closely related protein in the public data bases is an aquaporin from Cicadella viridis which shows 34% identity. The cDNA was used to isolate and characterize genomic fragments carrying the Dictyostelium gene which we named wacA. Genomic probes were used to recognize wacA mRNA isolated at various stages of development. The results showed that the gene is developmentally regulated such that the mRNA first appears at 12 h of development and is retained throughout the remainder of development. In situ hybridization of whole mounts prepared at 15 h of development showed that wacA mRNA accumulates exclusively in prespore cells and is absent from prestalk cells. Although wacA expression is prespore specific, disruption of the gene by homologous recombination did not result in observable alterations in the formation of spores or their resistance to osmotic challenges.

Molecular Networks that Regulate Development

Changing networks of genes and proteins underlie the development of all multicellular organisms. Specific cell types arise as the result of their developmental history and adapt their physiology to their function. Understanding the structure of the networks that gate and regulate the temporal sequence of events leading to the terminally differentiated state requires knowledge of the critical molecular components and their interconnections. Once the general architecture of a network is known with some confidence, detailed quantitative analyses of the individual reactions can lead to testable predictions (Loomis and Sternberg, 1995). However, embryogenesis of most metazoans is so complex that it will be some time before it is possible to have a complete understanding of the sequence of events leading from an egg to a newborn. At present we can only glimpse the workings of certain subsystems. Luckily, the evolution of development has followed the path of least resistance and used pre-existing networks that were present in simpler ancestors. With some tinkering, networks selected for one function can be adapted to another.