Progesterone but not ras requires MPF for in vivo activation of MAPK and S6 KII: MAPK is an essential conexion point of both signaling pathways

Induction of mitosis in Xenopus laevis oocytes by hormones and the oncogenic ras-p21 protein has been shown to correlate with a cascade of phosphorylations of the Ser/Thr family of kinases. However, the exact hierarchy of enzymes and their mutual interdependency has not been fully elucidated yet. We have used the Xenopus laevis system to investigate the mechanism of activation of the Ser/Thr kinases cascade and their relationship. Comparison between progesterone-induced germinal vesicle breakdown (GVBD), a hallmark of mitosis in oocytes, to that triggered by ras-p21, revealed the existence of at least two independent mechanisms to activate the MAP kinase enzyme in vivo. While progesterone function is dependent of cdc2 protein kinase activity, ras-p21 is independent of this enzyme. However, both progesterone and ras-p21 converge at the MAP kinase level, and depletion of MAP kinase activity inhibits the GVBD and S6 kinase II activation induced by both progesterone and ras-p21. These results provides further evidence that MAP kinase is a critical step for regulation of the cell cycle in oocytes and a critical point where ras and progesterone signaling converge.

Phosphorylcholine: a novel second messenger essential for mitogenic activity of growth factors

Growth factor stimulation of quiescent cells induces a series of intracellular early and late events that ultimately lead to DNA synthesis and cell division. We describe here that production of phosphorylcholine is an essential component of the late events involved in the induction of DNA synthesis by platelet-derived growth factor (PDGF-BB), a prototype mitogen for fibroblasts. Moreover, phosphorylcholine itself is mitogenic when added exogenously to NIH3T3 cells, further indicating its role as a crucial intracellular messenger for DNA synthesis. Choline kinase, the first step in the route of phosphatidylcholine synthesis appears to be the critical regulatory enzyme in phosphorylcholine production, indicating that regulation of choline kinase represents a key step during mitogenic stimulation. We also describe that several growth factors (PDGF-AA, basic FGF, EGF and phorbol esters) rely on their ability to generate phosphorylcholine for their proliferating activity. In contrast, DNA synthesis induced by serum did not require phosphorylcholine. Moreover, the requirement for phosphorylcholine production in PDGF-stimulated cells can be over-ruled by addition of insulin. Thus, cell proliferation in NIH3T3 cells can be triggered off by alternative pathways and one of them involves generation of phosphorylcholine.

Tumorigenic activity of rho genes from Aplysia californica

rho genes have been found in both lower and higher eucaryotes. They code for proteins of 21 kDa, highly conserved in evolution, which belong to the superfamily of ras GTPases. Among the members of this superfamily there are proteins with a regulatory function, such as ras, and proteins involved in vesicular trafficking, such as the family of rab proteins. We have investigated the putative role of rho proteins from Aplysia californica as transforming GTPases utilizing the wild-type and a Val-14 mutant, equivalent to the oncogenic Val-12 mutation of ras genes found in animal and human tumors. Over-expression of either rho gene was sufficient to confer anchorage- and serum-independent growth. Moreover, when introduced into nude mice, selected clones generated from either gene were able to induce tumors, although those carrying the mutated version were more efficient. Pathological analysis indicated that generated tumors corresponded to well-differentiated fibrosarcomas with distinct and intersecting bundles and spindle cells. By contrast, ras-induced tumors were poorly differentiated fibrosarcomas. Thus, our results indicate that under appropriate conditions rho genes function as oncogenes and may have a role in the regulation of proliferation in fibroblast cells.

Chemotactic stimulation of aggregation-stage Dictyostelium cells induces rapid changes in energy metabolism, as measured by succinic thiokinase phosphorylation

In crude mitochondrial fractions of the cellular slime mold Dictyostelium discoideum, a 38-kDa protein can be detected in phosphorylation assays under autophosphorylation conditions in SDS polyacrylamide gels. p38 can be phosphorylated in vitro using either ATP or GTP as phosphoryl donors. After stimulation of aggregation competent cells with the chemoattractant cAMP, p38 phosphorylation pattern changes rapidly. Caffeine, a known inhibitor of cAMP relay in D. discoideum inhibits cAMP induced changes in p38 phosphorylation. The rapid changes in p38 phosphorylation after cAMP stimulation reflect changes in energy metabolism and these changes are most likely mediated by changes in internal calcium concentrations. The mitochondrial localization and other data presented on the characterization of this protein led us to the conclusion that p38 is the alpha subunit of succinic thiokinase. Data showing a correlation between in-vitro p38 phosphorylation and the metabolic state of the cells at the moment of the cell lysis are included.

Study of protein-ligand binding effects by direct chromatographic on-column injection

The direct zonal on-column injection method was applied to a high-performance liquid chromatographic study of pollutant-protein binding interactions in solution. The protein and the protein-ligand complex are excluded on the basis of the size from the diol support, and the free ligand penetrates into the pores and is more retained. The pattern of the ligand elution profile depends on the protein-ligand dissociation constant. This effect was quantitatively analysed by developing a numerical simulation algorithm in which the column is divided into slices of given thickness. The column length, flow-rate and shape of the injection signal are given as input parameters. A global dispersion coefficient accounts for peak broadening. A rapid equilibrium is assumed with the hypothesis that a monovalent ligand interacts with a single binding site on the protein. The interaction of bovine serum albumin with pentachlorophenol was studied, and an apparent dissociation constant for the protein-ligand complex was determined by fitting the theoretical profile to the experimental one. The effect of the acetonitrile content in the solvent was studied. An important decrease of the dissociation constant is observed that affects the chromatographic elution pattern.

Isolation and characterization of genes encoding chaperonin 60β from Arabidopsis thaliana

Chaperonins (Cpn) are implicated in the folding and assembly of multimeric proteins in plastids and mitochondria of eukaryotes and in prokaryotes. Plastid Cpn is composed of two different polypeptides termed Cpn60 alpha and Cpn60 beta. We have isolated cDNA and genomic clones encoding Cpn60 beta from Arabidopsis thaliana. The steady-state level of the cpn60 beta mRNAs is higher in etiolated leaves and sucrose-treated plants as compared to control leaves. The A. thaliana cpn60 beta gene family consists of at least three different coding units. It was confirmed that Cpn beta-encoding genes have a high level of conservation among plants.

A phospholipid-stimulated protein kinase from Dictyostelium discoideum

A protein kinase with unusual characteristics has been found in Dictyostelium discoideum. This kinase can use histone H1 as exogenous substrate, and the activity is stimulated by phospholipids, but not by Ca2+. This enzyme has been partially purified by using chromatography on DEAE-cellulose DE-52, spermine-agarose and phosphatidylserine-polyacrylamide. The protein kinase activity is very labile, even in the presence of protease inhibitors, making further purification difficult. In the activity-containing fractions, an endogenous protein of 140 kDa is labelled in vitro with [gamma-32P]ATP under conditions in which intramolecular rather than intermolecular reactions are favoured. This protein is labelled only in the presence of phospholipids, but not of Ca2+. We propose that the 140 kDa phosphoprotein might be the autophosphorylated enzyme.