Molecular characterization of repetitive DNA sequences from B chromosome in Plantago lagopus L.

In Plantagolagopus the B chromosome has been reported by our laboratory to be the result of massive amplification of ribosomal DNA sequences. However, the presence of transposable elements and other repetitive DNA sequences together with rDNA could not be ruled out. The present study clearly demonstrated the presence of transposable elements in the B chromosomes. These transposable elements were characterized and their nature assessed. Physical mapping using double fluorescent in situ hybridization was performed using DNA probes for 5S and copia elements. The results clearly proved that the B chromosome is a mix of 5S, 45S rDNA and transposable elements. Based on the FISH and Fiber-FISH patterns, it can be concluded that while 45S rDNA sequences are restricted to the subtelomeric regions, the 5S rDNA sequences are interspersed with transposons in the body of the B chromosome. These results have further enhanced our understanding of the organization and evolution of B chromosomes.

Activation of the c-Raf protein kinase by protein kinase C phosphorylation.

The product of the c-raf-1 proto-oncogene is a cytoplasmic serine/threonine protein kinase that appears to be activated in signal transduction from a variety of cell-surface receptors. The mechanism of c-Raf activation upon stimulation of cell-surface receptors is not clear, but there seem to exist multiple pathways of activation which involve tyrosine and/or serine phosphorylation of the c-Raf protein in vivo. The activated state of Raf is reflected in an increased apparent molecular weight of the Raf protein in sodium dodecyl sulfate-polyacrylamide gels owing to hyperphosphorylation. The tumor promoter 12-O-tetradecanoyl phorbol 13-acetate (TPA) is one of the agents able to induce this hyperphosphorylation of Raf in vivo, suggesting that protein kinase C (PKC) may be involved in the activation of c-Raf in particular situations. Using recombinant baculoviruses expressing PKC and Raf polypeptides, we show here that conventional PKC types (alpha, beta, gamma) but not novel types (delta, zeta, eta) or the unrelated Mos kinase are able to activate c-Raf in a TPA-dependent manner upon coexpression in insect cells. Direct phosphorylation of the Raf protein with PKC in vitro also enhanced the kinase activity of c-Raf, suggesting that c-Raf acts immediately downstream of PKC in a protein kinase cascade which is triggered by TPA and may lead to transcriptional activation of TPA-inducible genes and tumor promotion.

Mutagenesis of the pseudosubstrate site of protein kinase C leads to activation.

Protein kinase C is maintained in an inactive state by the action of an inhibitory region within the effector binding domain of the kinase. It has been suggested that a short stretch of amino acids (pseudosubstrate site) mediates this inhibition by binding to the active site and preventing substrate interaction [House, C. and Kemp, B. E. (1987) Science 238, 1726-1728]. A mutated version of protein kinase C-alpha containing a glutamic acid for alanine substitution in this region has been analysed for biochemical properties and biological function. Consistent with the importance of this pseudosubstrate site in regulating kinase activity, this altered protein has a significantly increased effector-independent kinase activity relative to wild-type protein kinase C-alpha and shows increased sensitivity to activation by proteolysis. The increased activity of this protein in the intact cell was confirmed by its ability to stimulate expression from a phorbol-ester-inducible reporter construct in a transient transfection system. Expression of a mutant kinase with the pseudosubstrate sequence deleted causes greater induction in this transient expression system, consistent with this kinase being independent of effectors and thus constitutively active.

Protein kinase C--a family affair.

The structural analysis of protein kinase C has led to the identification of a family of related gene products. This family of kinases consists of six unique genes that give rise to at least seven polypeptides. The high degree of conservation and the differential distribution of these mRNAs/proteins suggest that they perform distinct functions in vivo. Characterization of the activities of some of these proteins in vitro shows that there are functional differences with respect to both their regulation and substrate specificity. This indicates that each member of this family may play a unique role in signal transduction.