Interaction of two multifunctional proteins. Heterogeneous nuclear ribonucleoprotein K and Y-box-binding protein.

The heterogeneous nuclear ribonucleoprotein (hnRNP) K, a component of the hnRNP particles, appears to be involved in several steps of regulation of gene expression. To gain insight into mechanisms of K protein action, we performed two-hybrid screens using full-length hnRNP K as a bait. Several novel protein partners were identified, including Y-box-binding protein (YB-1), splicing factors 9G8 and SRp20, DNA-methyltransferase, hnRNP L, and hnRNP U. In vitro binding studies and co-immunoprecipitation from cellular extracts provided evidence for direct interaction between hnRNP K and YB-1. Two distinct domains in YB-1 were responsible for binding to K protein. Each protein was able to transactivate transcription from a polypyrimidine-rich promoter; however, this effect was reduced when K and YB-1 proteins were coexpressed suggesting a functional interaction between these two proteins.

Regulated interaction of protein kinase Cdelta with the heterogeneous nuclear ribonucleoprotein K protein.

The heterogeneous nuclear ribonucleoprotein (hnRNP) K protein recruits a diversity of molecular partners that are involved in signal transduction, transcription, RNA processing, and translation. K protein is phosphorylated in vivo and in vitro by inducible kinase(s) and contains several potential sites for protein kinase C (PKC) phosphorylation. In this study we show that K protein is phosphorylated in vitro by PKCdelta and by other PKCs. Deletion analysis and site-directed mutagenesis revealed that Ser302 is a major K protein site phosphorylated by PKCdelta in vitro. This residue is located in the middle of a short amino acid fragment that divides the two clusters of SH3-binding domains. Mutation of Ser302 decreased the level of phosphorylation of exogenously expressed K protein in phorbol 12-myristate 13-acetate-treated COS cells, suggesting that Ser302 is also a site for PKC-mediated phosphorylation in vivo. In vitro, PKCdelta binds K protein via the highly interactive KI domain, an interaction that is blocked by poly(C) RNA. Mutation of Ser302 did not alter the K protein-PKCdelta interaction in vitro, suggesting that phosphorylation of this residue alone is not sufficient to alter this interaction. Instead, binding of PKCdelta to K protein in vitro and in vivo was greatly increased by K protein phosphorylation on tyrosine residues. The ability of PKCdelta to bind and phosphorylate K protein may serve not only to alter the activity of K protein itself, but K protein may also bridge PKCdelta to other K protein molecular partners and thus facilitate molecular cross-talk. The regulated nature of the PKCdelta-K protein interaction may serve to meet cellular needs at sites of active transcription, RNA processing and translation in response to changing extracellular environment.

Point mutations in the WD40 domain of Eed block its interaction with Ezh2.

The Polycomb group proteins are involved in maintenance of the silenced state of several developmentally regulated genes. These proteins form large aggregates with different subunit compositions. To explore the nature of these complexes and their function, we used the full-length Eed (embryonic ectoderm development) protein, a mammalian homolog of the Drosophila Polycomb group protein Esc, as a bait in the yeast two-hybrid screen. Several strongly interacting cDNA clones were isolated. The cloned cDNAs all encoded the 150- to 200-amino-acid N-terminal fragment of the mammalian homolog of the Drosophila Enhancer of zeste [E(z)] protein, Ezh2. The full-length Ezh2 bound strongly to Eed in vitro, and Eed coimmunoprecipitated with Ezh2 from murine 70Z/3 cell extracts, confirming the interaction between these proteins observed in yeast. Mutations T1031A and T1040C in one of the WD40 repeats of Eed, which account for the hypomorphic and lethal phenotype of eed in mouse development, blocked binding of Ezh2 to Eed in a two-hybrid interaction in yeast and in mammalian cells. These mutations also blocked the interaction between these proteins in vitro. In mammalian cells, the Gal4-Eed fusion protein represses the activity of a promoter bearing Gal4 DNA elements. The N-terminal fragment of the Ezh2 protein abolished the transcriptional repressor activity of Gal4-Eed protein when they were coexpressed in mammalian cells. Eed and Ezh2 were also found to bind RNA in vitro, and RNA altered the interaction between these proteins. These findings suggest that Polycomb group proteins Eed and Ezh2 functionally interact in mammalian cells, an interaction that is mediated by the WD40-containing domain of Eed protein.

The oncoprotein Tax of the human T-cell leukemia virus type 1 activates transcription via interaction with cellular ATF-1/CREB factors in Saccharomyces cerevisiae.

The transcription factor Tax of the oncogenic human T-cell leukemia virus type 1 is likely to be responsible for viral replication in the host organism and for the induction of proliferation in infected cells. To investigate Tax-mediated transcription in vivo, we expressed Tax as well as CREB in Saccharomyces cerevisiae. The activity of these proteins was monitored by expression of a beta-galactosidase reporter gene, which was fused to two viral 21-bp repeats located upstream of the yeast cytochrome c1 oxidase minimal promoter. Coexpression of Tax and CREB in S. cerevisiae led to a 20-fold increase in beta-galactosidase activity in comparison with that in strains expressing either Tax or CREB alone. By screening a human cDNA library, we were able to demonstrate that the Tax transactivation assay using S. cerevisiae can be successfully applied to identify other cellular proteins forming ternary complexes with Tax and 21-bp repeats in vivo. Upon transformation in S. cerevisiae, 1 of 13,500 clones tested positive. Sequencing of the cDNA insert of the rescued plasmid revealed that this DNA encoded the ATF-1 protein. beta-Galactosidase induction was comparable to that of the Tax/CREB coexpression system. This indicates that Tax-mediated transcription is critically dependent on the presence of cellular CREB or ATF-1 in vivo. Stimulation of transcription initiation required an unmasked NH2 terminus of Tax. Fusion of Tax to the yeast Gal4 protein abolished the transactivation potential of Tax. Reconstitution of the transcriptional properties of viral Tax together with the cellular proteins of the ATF-1/CREB family in S. cerevisiae allows the functional characterization of these proteins in vivo.

Biochemical properties and excretion behavior of repressible acid phosphatases with altered subunit composition.

Yeast repressible acid phosphatase (rAP) is the oligomeric extracellular enzyme encoded by the three structural genes PH05 (p60), PHO10 (p58) and PHO11 (p56). We examined the ability of acid phosphatases formed by various subunit combinations to be excreted into the medium. Plasmids with repressible acid phosphatase structural genes under control of the yeast glyceraldehyde-phosphate dehydrogenase (GAP) promoter were constructed to obtain constitutive expression of acid phosphatase, and yeast strains with disruptions in PHO5, PHO10 and PHO11, respectively, were used to generate mutants expressing single genes or specific gene combinations. EndoF treatment of acid phosphatases, produced by these strains, followed by SDS-electrophoresis in combination with densitometry techniques revealed that the ratio p60/(p56 + p58) among structural polypeptides in extracellular enzyme is constant and equals to 6.0. A study of acid phosphatases formed by single type subunits was undertaken. Expression products of PHO5, PHO10 and PHO11 genes were isolated from the culture medium. The specific activities of the enzymes were found to be 33, 2 and 2 mM x mg-1 x min-1, respectively. The values of Mr estimated by HPLC chromatography for the enzymes encoded for by the genes PHO5, PHO10 and PHO11 and SDS-polyacrilamide gel electrophoresis data suggested an oligomeric organisation of the enzymes. Isoelectric focusing in polyacrylamide gel with immobilised pH gradient followed by activity staining yielded numerous sharp bands of homopolymeric acid phosphatases forms being different in their pI. The kinetic characterisation of the enzymes revealed differences in Km values, sensitivity to temperature inactivation, inhibition by orthophosphate and the effect of pH on the enzyme activity.

[Analysis of the quaternary structure of secreted repressible acid phosphatase from the yeast Saccharomyces cerevisiae]. / Analiz chetvertichnoi struktury sekretiruemoi repressibel'noi kisloi fosfatazy drozhzhei Saccharomyces cerevisiae.

The structural organization of extracellular repressible acid phosphatase from S. cerevisiae has been studied. The existence of multiple acid phosphatase forms with isoelectric points at pH 4.1-4.8 has been confirmed by isoelectrofocusing. The molecular masses of three acid phosphatase isoforms (56, 57-59, and 60 kDa) obtained after enzymatic deglycosylation correlate with the data obtained previously during the analysis of translation products in cell-free systems. Electron microscopic studies revealed that the acid phosphatase molecule has a square shape and is made up of four identical subunits with molecular masses of about 125 kDa.

[Possible existence of alternative secretion routes of acid phosphatase in the yeast Saccharomyces cerevisiae]. / O vozmozhnosti sushchestvovaniia razlichnykh putei sekretsii kisloi fosfatazy u drozhzhei Saccharomyces cerevisiae.

The secretion of different acid phosphatase forms into the growth medium was studied in the yeast Saccharomyces cerevisiae. The secretion of constitutive acid phosphatase highly correlated with the process of bud formation. This exoenzyme might be involved in the construction of the bud cell wall. Analysis of the rate, at which repressible acid phosphatase was excreted into the growth medium, as well as a negative correlation between its secretion and the process of bud formation were indicative of an additional route via which the repressible form of acid phosphatase was secreted. It is possible that yeast cells contain vesicles similar to "safe" vesicles in higher eukaryotic cells.