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Abstract
Stage-specific activator protein (SSAP) is a 41-kDa polypeptide that binds to embryonic enhancer elements of the sea urchin late H1 gene. These enhancer elements mediate the transcriptional activation of the late H1 gene in a temporally specific manner at the mid-blastula stage of embryogenesis. Although SSAP can transactivate the late H1 gene only at late stages of the development, it resides in the sea urchin nucleus and maintains DNA binding activity throughout early embryogenesis. In addition, it has been shown that SSAP undergoes a conversion from a 41-kDa monomer to a ∼80- to 100-kDa dimer when the late H1 gene is activated. We have demonstrated that SSAP is differentially phosphorylated during embryogenesis. Serine 87, a cyclic AMP-dependent protein kinase consensus site located in the N-terminal DNA binding domain, is constitutively phosphorylated. At the mid-blastula stage of embryogenesis, temporally correlated with SSAP dimer formation and late H1 gene activation, a threonine residue in the C-terminal transactivation domain is phosphorylated. This phosphorylation can be catalyzed by a break-ended double-stranded DNA-activated protein kinase activity from the sea urchin nucleus in vitro. Microinjection of synthetic SSAP mRNAs encoding either serine or threonine phosphorylation mutants results in the failure to transactivate reporter genes that contain the enhancer element, suggesting that both serine and threonine phosphorylation of SSAP are required for the activation of the late H1 gene. Furthermore, SSAP can undergo blastula-stage-specific homodimerization through its GQ-rich transactivation domain. The late-specific threonine phosphorylation in this domain is essential for the dimer assembly. These observations indicate that temporally regulated SSAP activation is promoted by threonine phosphorylation on its transactivation domain, which triggers the formation of a transcriptionally active SSAP homodimer.
ACKNOWLEDGMENTS
We thank Mitchell Benuck for his help during manuscript preparation and George Orr for his helpful suggestions on phosphopeptide mapping protocols and for his critical review of the manuscript. We also thank Andrew Eisen for his generous gift of highly purified human DNA-PK and Richard E. Stanley for allowing us to use the Hunter thin-layer electrophoresis system in his lab.
This work was supported by NIH grant GM 30333.