Regulation of mitotic inhibitor Mik1 helps to enforce the DNA damage checkpoint.

The protein kinase Chk1 enforces the DNA damage checkpoint. This checkpoint delays mitosis until damaged DNA is repaired. Chk1 regulates the activity and localization of Cdc25, the tyrosine phosphatase that activates the cdk Cdc2. Here we report that Mik1, a tyrosine kinase that inhibits Cdc2, is positively regulated by the DNA damage checkpoint. Mik1 is required for checkpoint response in strains that lack Cdc25. Long-term DNA damage checkpoint arrest fails in Deltamik1 cells. DNA damage increases Mik1 abundance in a Chk1-dependent manner. Ubiquitinated Mik1 accumulates in a proteasome mutant, which indicates that Mik1 normally has a short half-life. Thus, the DNA damage checkpoint might regulate Mik1 degradation. Mik1 protein and mRNA oscillate during the unperturbed cell cycle, with peak amounts detected around S phase. These data indicate that regulation of Mik1 abundance helps to couple mitotic onset to the completion of DNA replication and repair. Coordinated negative regulation of Cdc25 and positive regulation of Mik1 ensure the effective operation of the DNA damage checkpoint.

Pch1(+), a second essential C-type cyclin gene in Schizosaccharomyces pombe.

The Schizosaccharomyces pombe gene pch1(+) (pombe cyclin C homology) was isolated in a two-hybrid screen for proteins that interact with Cdc2. The cyclin box region of Pch1 protein shares greatest sequence identity with mammalian and Drosophila C-type cyclins ( approximately 33% identity). Pch1 is significantly less similar to Mcs2 (19% identity), a second member of the C-type cyclin family in S. pombe. Cdc2 co-precipitates with Pch1 in S. pombe cell lysates, although Cdc2 may not be the major catalytic partner of a Pch1 kinase in vivo. Purified Pch1-associated kinase phosphorylated myelin basic protein, histone H1, and a peptide corresponding to the carboxyl-terminal domain repeat of RNA polymerase II. The amount of pch1 mRNA does not oscillate during the cell cycle, as is the case for mRNA transcripts of other C-type cyclin genes. Deltapch1 cells are inviable, therefore S. pombe has two essential genes that encode members of the C-type cyclin family, pch1(+) and mcs2(+). The Deltapch1 mutation causes pleiotropic morphological defects and an associated growth deficiency, but loss of Pch1 activity does not result in a cdc cell cycle-arrest phenotype.

Hypoxia increases rate of transcription and stability of tyrosine hydroxylase mRNA in pheochromocytoma (PC12) cells.

Reduced arterial oxygen tension (i.e. hypoxia) is a powerful physiological stimulus that induces synthesis and release of dopamine from O2-sensitive (type I) cells in the mammalian carotid bodies. We reported recently that hypoxia stimulates gene expression for tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine synthesis in type I cells of the carotid body. Efforts to identify the mechanisms regulating TH gene expression in O2-sensitive cells during hypoxia have been hampered by the lack of an appropriate model cell culture system. Here we report that TH gene expression in the rat pheochromocytoma cell line (PC12) is regulated during hypoxia in a manner similar to that measured in carotid body type I cells. PC12 cells might therefore be useful as an experimental model for identifying the molecular mechanisms that regulate TH gene expression during hypoxia. Nuclear runoff assays revealed that transcription of the wild type TH gene was enhanced during exposures to hypoxia lasting 12 h. Chloramphenicol acetyltransferase assays with constructs that contained different fragments of TH promoter revealed that the regulatory sequences that mediate the hypoxia-induced increase in transcription are located between bases -272 and +27 of the TH gene. Findings from experiments in which transcription was inhibited either with actinomycin D or 5,6-dichloro-1-D-ribofuranosylbenzimidazole, as well as pulse-chase experiments using 4-thiouridine showed that the half-life of TH mRNA was substantially increased during hypoxia. Thus, in the present paper we show that TH gene expression in PC12 cells during hypoxia is regulated by increases in both the rate of TH gene transcription and TH mRNA stability.

Human cytomegalovirus immediate-early gene 2 protein interacts with itself and with several novel cellular proteins.

The human cytomegalovirus immediate-early gene product 2 (IE2) is able to transactivate homologous and heterologous promoters alone or augmented by immediate-early gene product 1 (IE1). IE2 has also been shown to autoregulate the major immediate-early promoter by directly binding to a cis repression signal located between the TATA box and the cap site. However, IE2 has not been shown to act directly through a specific DNA sequence in transactivating various promoters. To understand whether IE2 can be indirectly involved in DNA sequence-specific transactivation through interactions with other transcriptional factors, we performed a study of the interactions of IE2 with cellular proteins. In order to study these interactions, IE cDNAs were subcloned into a bacterial expression vector, pGEX2T, by polymerase chain reaction amplification to produce fusion proteins which were full-length as well as proteins which contained various functional domains. We were able to demonstrate IE2's ability to interact directly or indirectly with several cellular proteins ranging from > 200 to 14 kDa through glutathione S-transferase-fusion protein precipitation and far-Western analysis. These interactions have been mapped to domains within IE2 which are known to be necessary for either transactivation or both transactivation and autoregulation. All of the IE2-associated proteins are nuclear proteins, and a subset are phosphorylated. In vitro-synthesized 35S-IE2 protein and bacterially expressed IE2 fusion proteins were used to study IE2-IE2 interaction by binding assay and far-Western analysis. IE2-IE2 interactions were mapped to a domain containing a putative helix-turn-helix motif located near the C terminus of IE2, between amino acids 456 and 539. However, IE2 was unable to directly interact with either IE1, an alternatively spliced variant of IE2 (55 kDa), or IE2 deletion mutants that did not contain the multimerization domain.