Cloning of a human cDNA encoding a CDC2-related kinase by complementation of a budding yeast cdc28 mutation.

We have cloned two different human cDNAs that can complement cdc28 mutations of budding yeast Saccharomyces cerevisiae. One corresponds to a gene encoding human p34CDC2 kinase, and the other to a gene (CDK2; cell division kinase) that has not been characterized previously. The CDK2 protein is highly homologous to p34CDC2 kinase (65% identical) and more significantly is homologous to Xenopus Eg1 kinase (89% identical), suggesting that CDK2 is the human homolog of Eg1. The human CDC2 and CDK2 genes were both able to complement the inviability of a null allele of S. cerevisiae CDC28. This result indicates that the CDK2 protein has a biological activity closely related to the CDC28 and p34CDC2 kinases. However, CDK2 was unable to complement cdc2 mutants in fission yeast Schizosaccharomyces pombe under the condition where the human CDC2 gene could complement them. CDK2 mRNA appeared late in G1 or in early S phase, slightly before CDC2 mRNA, after growth stimulation in normal human fibroblast cells. These results suggest that in human cells, two different CDC2-like kinases may regulate the cell cycle at distinct stages.     

Complementation of the beige mutation in cultured cells by episomally replicating murine yeast artificial chromosomes.

Chédiak-Higashi syndrome in man and the beige mutation of mice are phenotypically similar disorders that have profound effects upon lysosome and melanosome morphology and function. We isolated two murine yeast artificial chromosomes (YACs) that, when introduced into beige mouse fibroblasts, complement the beige mutation. The complementing YACs exist as extrachromosomal elements that are amplified in high concentrations of G418. When YAC-complemented beige cells were fused to human Chédiak-Higashi syndrome or Aleutian mink fibroblasts, complementation of the mutant phenotype also occurred. These results localize the beige gene to a 500-kb interval and demonstrate that the same or homologous genes are defective in mice, minks, and humans.     

DNA metabolism gene CDC7 from yeast encodes a serine (threonine) protein kinase.

The yeast Cdc7 protein is indispensable to initiation of nuclear DNA replication, based on the phenotype of the conditional, temperature-sensitive (ts) cdc7 mutants at the restrictive temperature. This protein has likewise been implicated in commitment to meiotic DNA recombination and induced mutagenesis, which may result from error-prone DNA repair. Our previous work revealed sequence similarity between the Cdc7 protein and known protein kinases. To determine whether it possesses kinase activity, we have immunoprecipitated the protein from Cdc7-overproducing yeast cells by using polyclonal antibodies raised against a nondenatured beta-galactosidase-Cdc7 fusion protein. In this report, we demonstrate that Cdc7 immune complexes are capable of phosphorylating mammalian histone H1 on serine and/or threonine residues. Immune complexes derived from cells harboring the cdc7-2 ts mutant gene on a high copy number plasmid possess a thermolabile kinase activity. Thus, we postulate that Cdc7 may regulate the various DNA metabolic pathways by phosphorylating one or more target substrates. Because Cdc7 kinase acts downstream of Cdc28/cdc2 kinase function at "start," the transition from G1 to S phase in the cell cycle may be the result of a cascade of protein phosphorylation.     

Mammalian mitogen-activated protein kinase kinase kinase (MEKK) can function in a yeast mitogen-activated protein kinase pathway downstream of protein kinase C.

Mitogen-activated protein kinase cascades are conserved in fungal, plant, and metazoan species. We expressed murine MAP kinase kinase kinase (MEKK) in the yeast Saccharomyces cerevisiae to determine whether this kinase functions as a general or specific activator of genetically and physiologically distinct MAP-kinase-dependent signaling pathways and to investigate how MEKK is regulated. Expression of MEKK failed to correct the mating deficiency of a ste11 delta mutant that lacks an MEKK homolog required for mating. MEKK expression also failed to induce expression of a reporter gene controlled by the HOG1 gene product (Hog1p), a yeast MAP kinase homolog involved in response to osmotic stress. Expression of MEKK did correct the cell lysis defect of a bck1 delta mutant that lacks an MEKK homolog required for cell-wall assembly. MEKK required the downstream MAP kinase homolog in the BCK1-dependent pathway, demonstrating that it functionally replaces the BCK1 gene product (Bck1p) rather than bypassing the pathway. MEKK therefore selectively activates one of three distinct MAP-kinase-dependent pathways. Possible explanations for this selectivity are discussed. Expression of the MEKK catalytic domain, but not the full-length molecule, corrected the cell-lysis defect of a pkc1 delta mutant that lacks a protein kinase C homolog that functions upstream of Bck1p. MEKK therefore functions downstream of the PKC1 gene product (Pkc1p). The N-terminal noncatalytic domain of MEKK, which contains several consensus protein kinase C phosphorylation sites, may, therefore, function as a negative regulatory domain. Protein kinase C phosphorylation may provide one mechanism for activating MEKK.     

A structural gene mutation affecting the regulatory subunit of cyclic AMP-dependent protein kinase in mouse lymphoma cells.

Compared to the wild-type parental line of S49 mouse lymphoma cells, intact cells of a mutant line (kin.A) are 10-fold less sensititive to biologic effects of exogenous cyclic adenosine 3':5'-monophophosphate (cAMP), such as induction of cAMP phosphodiesterase, cell cycle-specific growth inhibition, and cytolysis. The cAMP-dependent protein kinase (ATP:protein phosphotransferase; EC 2.7.1.37) activity of kin.A cells exhibits an apparent Ka for activation by cAMP 10-fold greater than that of wild type, and is much more resistant to inactivation by heat. These differences between the wild-type and mutant enzymes persist through a high degree of purification, suggesting a structural alteration in the kin.A holoenzyme. Heterologous reconstitution experiments, using separated R and C subunits of the wild-type and kin.A cAMP-dependent kinases, show that the altered cAMP affinity and thermolability are conferred by the R component of the kin.A enzyme. These results are most consistent with a structural mutation in the kin.A gene coding for the R subunit of cAMP-dependent protein kinase. Evidence for a structural mutation helps to define one mechanism of heritable variation in cultured somatic cells. The phenotype produced by the kin.A structural mutation also greatly strengthens the conslusion that cAMP-dependent protein kinase is essential for cAMP regulation of growth and enzyme induction in intact S49 cells.     

The plant cDNA LCT1 mediates the uptake of calcium and cadmium in yeast

Nonessential metal ions such as cadmium are most likely transported across plant membranes via transporters for essential cations. To identify possible pathways for Cd²⁺ transport we tested putative plant cation transporters for Cd²⁺ uptake activity by expressing cDNAs in Saccharomyces cerevisiae and found that expression of one clone, LCT1, renders the growth of yeast more sensitive to cadmium. Ion flux assays showed that Cd²⁺ sensitivity is correlated with an increase in Cd²⁺ uptake. LCT1-dependent Cd²⁺ uptake is saturable, lies in the high-affinity range (apparent K_M for Cd²⁺ = 33 μM) and is sensitive to block by La³⁺ and Ca²⁺. Growth assays demonstrated a sensitivity of LCT1-expressing yeast cells to extracellular millimolar Ca²⁺ concentrations. LCT1-dependent increase in Ca²⁺ uptake correlated with the observed phenotype. Furthermore, LCT1 complements a yeast disruption mutant in the MID1 gene, a non-LCT1-homologous yeast gene encoding a membrane Ca²⁺ influx system required for recovery from the mating response. We conclude that LCT1 mediates the uptake of Ca²⁺ and Cd²⁺ in yeast and may therefore represent a first plant cDNA encoding a plant Ca²⁺ uptake or an organellar Ca²⁺ transport pathway in plants and may contribute to transport of the toxic metal Cd²⁺ across plant membranes.     

Phosphorylation of a Ras-related GTP-binding protein, Rap-1b, by a neuronal Ca2+/calmodulin-dependent protein kinase, CaM kinase Gr.

A neuron-specific Ca2+/calmodulin-dependent protein kinase, CaM kinase Gr, phosphorylates selectively a Ras-related GTP-binding protein (Rap-1b) that is enriched in brain tissue. The phosphorylation reaction achieves a stoichiometry of about 1 and involves a serine residue near the carboxyl terminus of the substrate. Both CaM kinase Gr and cAMP-dependent protein kinase, but not CaM kinase II, phosphorylate identical or contiguous serine residues in Rap-1b. The rate of phosphorylation of Rap-1b by CaM kinase Gr is enhanced following autophosphorylation of the protein kinase. Other low molecular weight GTP-binding proteins belonging to the Ras superfamily, including Rab-3A, Rap-2b, and c-Ha-ras p21, are not phosphorylated by CaM kinase Gr. The phosphorylation of Rap-1b itself can be reversed by an endogenous brain phosphoprotein phosphatase. These observations provide a potential connection between a neuronal Ca2(+)-signaling pathway and a specific low molecular weight GTP-binding protein that may regulate neuronal transmembrane signaling, vesicle transport, or neurotransmitter release.     

Activation of yeast Snf1 and mammalian AMP-activated protein kinase by upstream kinases

The Snf1/AMP-activated protein kinase (AMPK) family plays fundamental roles in cellular responses to metabolic stress in eukaryotes. In humans, AMPK regulates lipid and glucose metabolism and has been implicated in such metabolic disorders as diabetes and obesity and in cardiac abnormalities. Snf1 and AMPK are the downstream components of kinase cascades, but the upstream kinase(s) have remained elusive. We have here identified three yeast kinases, Pak1p, Tos3p, and Elm1p, that activate Snf1 kinase in vivo. Triple deletion of the cognate genes causes a Snf- mutant phenotype and abolishes Snf1 catalytic activity. All three kinases phosphorylate recombinant Snf1p on the activation-loop threonine. Moreover, Tos3p phosphorylates mammalian AMPK on the equivalent residue and activates the enzyme, suggesting functional conservation of the upstream kinases between yeast and mammals. We further show that the closely related mammalian LKB1 kinase, which is associated with Peutz-Jeghers cancer-susceptibility syndrome, phosphorylates and activates AMPK in vitro. Thus, the identification of the yeast upstream kinases should facilitate identification of the corresponding, physiologically important mammalian upstream kinases.     

Creatine kinase protein sequence encoded by a cDNA made from Torpedo californica electric organ mRNA.

Creatine kinase (ATP creatine N-phosphotransferase, EC 2.7.3.2) is important in the maintenance of ATP levels in high energy-requiring tissues such as muscle and brain. A complete understanding of its function requires knowledge of its amino acid sequence. To obtain cDNA clones encoding creatine kinase sequences, a cDNA bank was constructed using mRNA from the electric organ of Torpedo californica and was screened by comparing differential colony hybridization of electric organ and liver-derived 32P-labeled cDNAs. Cloned DNAs have been isolated that can arrest the abundant synthesis of Mr 40,000-43,000 material seen after in vitro translation of electric organ mRNA. One of the clones, CK52g8, was sequenced by the dideoxy M13 method and was found to encode a Mr 42,941 protein, which is 68% homologous to a known partial sequence of rabbit muscle creatine kinase and which has a composition similar to creatine kinases from chicken and rabbit tissues. By contrast, no significant homology was found with the known sequences of kinases that use other substrates. RNA blot hybridization analysis indicated that CK52g8 is complementary to a 1600-base-pair mRNA. Primer extension analysis indicated that CK52g8 is only 5 nucleotides short of a full-length cDNA, implying that it encodes a complete protein sequence. The availability of this complete sequence should be useful in further studies of creatine kinase structure and function using techniques such as site-specific mutagenesis.     

Reconstitution of a yeast protein kinase cascade in vitro: activation of the yeast MEK homologue STE7 by STE11.

The mating-factor response pathway of Saccharomyces cerevisiae employs a set of protein kinase similar to kinases that function in signal transduction pathways of metazoans. We have purified the yeast protein kinases encoded by STE11, STE7, and FUS3 as fusions to glutathione S-transferase (GST) and reconstituted a kinase cascade in which STE11 phosphorylates and activates STE7, which in turn phosphorylates the mitogen-activated protein kinase FUS3. GST-STE11 is active even when purified from cells that have not been treated with alpha-factor. This observation raises the possibility that STE11 activity is governed by an inhibitor which is regulated by pheromone. We also identify a STE11-dependent phosphorylation site in STE7 which is required for activity of STE7. Conservation of this site in the mammalian STE7 homologue MEK and other STE7 relatives suggests that this may be a regulatory phosphorylation site in all MAP kinase kinases.     

A mutation in the RCC1-related protein pim1 results in nuclear envelope fragmentation in fission yeast.

Members of the RCC1 protein family are chromatin-associated guanine nucleotide exchange factors that have been implicated in diverse cellular processes in various organisms, yet no consensus has been reached as to their primary biological role. The fission yeast Schizosaccharomyces pombe, a single-celled eukaryote, provides an in vivo system in which to study the RCC1/Ran switch by using a temperature-sensitive mutant in the RCC1-related protein pim1. Mitotic entry in the pim1-d1ts mutant is normal, but mitotic exit leads to the accumulation of cells arrested with a medial septum and condensed chromosomes. Although the yeast nuclear envelope normally remains intact throughout the cell cycle, we found a striking fragmentation of the nuclear envelope in the pim1-d1ts mutant following mitosis. This resulted in chromatin that was no longer compartmentalized and an accumulation of pore-containing membranes in the cytoplasm. The development of this terminal phenotype was dependent on the passage of cells through mitosis and was coincident with the loss of viability. We propose that pim1 is required for the reestablishment of nuclear structure following mitosis in fission yeast.     

Isolation of a gene encoding a chaperonin-like protein by complementation of yeast amino acid transport mutants with human cDNA.

A human cDNA library in lambda-yes plasmid was used to transform a strain of Saccharomyces cerevisiae with defects in histidine biosynthesis (his4-401) and histidine permease (hip1-614) and with the general amino acid permease (GAP) repressed by excess ammonium. We investigated three plasmids complementing the transport defect on a medium with a low concentration of histidine. Inserts in these plasmids hybridized with human genomic but not yeast genomic DNA, indicating their human origin. mRNA corresponding to the human DNA insert was produced by each yeast transformant. Complementation of the histidine transport defect was confirmed by direct measurement of histidine uptake, which was increased 15- to 65-fold in the transformants as compared with the parental strain. Competitive inhibition studies, measurement of citrulline uptake, and lack of complementation in gap1- strains indicated that the human cDNA genes code for proteins that prevent GAP repression by ammonium. The amino acid sequence encoded by one of the cDNA clones is related to T-complex proteins, which suggests a "chaperonin"-like function. We suggest that the human chaperonin-like protein stabilizes the NPR1 gene product and prevents inactivation of GAP.     

Negative regulation of mitosis in fission yeast by the Shk1interacting protein Skb1 and its human homolog, Skb1Hs

We previously provided evidence that the protein encoded by the highly conserved skb1 gene is a putative regulator of Shk1, a p21^Cdc42/Rac-activated kinase (PAK) homolog in the fission yeast Schizosaccharomyces pombe. skb1 null mutants are viable and competent for mating but less elongate than wild-type S. pombe cells, whereas cells that overexpress skb1 are hyperelongated. These phenotypes suggest a possible role for Skb1 as a mitotic inhibitor. Here we show genetic interactions of both skb1 and shk1 with genes encoding key mitotic regulators in S. pombe. Our results indicate that Skb1 negatively regulates mitosis by a mechanism that is independent of the Cdc2-activating phosphatase Cdc25 but that is at least partially dependent on Shk1 and the Cdc2 inhibitory kinase Wee1. We provide biochemical evidence for association of Skb1 and Shk1 with Cdc2 in S. pombe, suggesting that Skb1 and Shk1 inhibit mitosis through interaction with the Cdc2 complex, rather than by an indirect mechanism. These results provide evidence of a previously undescribed role for PAK-related protein kinases as mitotic inhibitors. We also describe the cloning of a human homolog of skb1, SKB1Hs, and show that it can functionally replace skb1 in S. pombe. Thus, the molecular functions of Skb1-related proteins have likely been substantially conserved through evolution.     

Identification of a protein kinase multigene family of Dictyostelium discoideum: molecular cloning and expression of a cDNA encoding a developmentally regulated protein kinase.

We have identified protein kinase genes of Dictyostelium by using highly conserved amino acid sequence motifs to design the synthesis and amplification of DNA fragments by polymerase chain reactions (PCRs). Cloning and sequencing the PCR products have revealed five different members of the protein kinase multigene family. These five putative kinases showed varying degrees of amino acid sequence similarity (40-70%) to protein kinases in data bases and contained invariant amino acid residues characteristic of protein kinases. DNA from PCR was labeled and used to isolate several lambda gt11 cDNA clones, including one full-length one (Dd kinase-2). The nucleotide sequence of Dd kinase-2 contained a region identical to one of the cloned kinase fragments amplified by PCR, and based on the deduced amino acid sequence Dd kinase-2 encodes a protein of 479 amino acids. A 350-amino acid kinase domain at the C-terminal end shows high homology to the catalytic domains of protein kinase A, protein kinase C, S-6 kinase of Xenopus, and the suppressor of cdc25 of yeast. The N-terminal domain is highly basic and also contains alternating threonine/proline residues. The cDNA hybridized to a single copy gene but to two differentially regulated mRNAs--a 2.0-kilobase mRNA that is expressed in vegetative cells and a 2.2-kilobase mRNA that is expressed during development. The larger mRNA is induced by cAMP by using a cell-surface receptor-mediated signal transduction pathway.