A homologue of Cdk8 is required for spore cell differentiation in Dictyostelium.

The Cdk8 proteins are kinases which phosphorylate the carboxy terminal domain (CTD) of RNA polymerase II (Pol II) as well as some transcription factors and, therefore, are involved in the regulation of transcription. Here, we report that a Cdk8 homologue from Dictyostelium discoideum is localized in the nucleus where it forms part of a high molecular weight complex that has CTD kinase activity. Insertional mutagenesis was used to abrogate gene function, and analysis of the null strain revealed that the DdCdk8 protein plays an important role in spore formation during late development. As previously reported [Dev. Growth Differ. 44 (2002) 213] Ddcdk8- cells also exhibit impaired aggregation, although we report that the severity of the defect depends upon experimental conditions. When aggregation occurs, Ddcdk8- cells form abnormal terminally differentiated structures within which the Ddcdk8- cells differentiate into stalk cells but fail to form spores, indicating a role for DdCdk8 in cell differentiation. When Ddcdk8 is expressed from its own promoter, the protein is able to rescue both the late developmental defect and the impaired aggregation. However, when expressed from an heterologous promoter, only the impaired aggregation is rescued. This result demonstrates that the defect during late development is not a consequence of impaired aggregation and indicates a direct role for DdCdk8 in spore formation.

Immunological Characterization of cdc2 and wee1 Proteins during the Growth and Differentiation of Dictyostelium discoideum.

Two different antibody preparations, raised independently against the conserved EGVPSTAIREISLLKE sequence of the protein kinases encoded by the Schizosaccharomyces pombe cdc2 gene and its species homologs, immunoblotted a Dictyostelium protein of 32 kDa (p32). This polypeptide bound to p13suc1 -agarose beads, suggesting that it represents the Dictyostelium cdc2 and / or cdk2 products. The amounts of p32 detectable in cell free extracts and bound to p13suc1 -agarose were unaltered during the growth of cells synchronized for division. Although there was also essentially no change in the level of p32 during differentiation, the protein from the pseudoplasmodial stage of development did not bind to p13suc1 -agarose, implicating a developmentally regulated modification of the kinase. One of the EGVPSTAIREISLLKE antibodies also recognized a protein of 49 kDa (p49) that increased in amount dramatically during aggregation and then remained at elevated levels throughout the remainder of the differentiation process. This protein was present in low amounts throughout the growth of cells synchronized for division and was not absorbed by p13suc1 -agarose. A 103 kDa protein (p103) was detected by Western blot analysis using antibodies raised against two different peptides corresponding to sequences in the S. pombe protein kinase p105wee1 , which is a putative upstream negative regulator of p34cdc2 in fission yeast. The levels of p103 were constant during differentiation and during the growth of cells synchronized for division.