Upregulation of rat P23 (a member of the YjgF protein family) by fasting, glucose diet and fatty acid feeding.

In a previous study, we identified and purified a 99-amino-acid rat liver-kidney perchloric-acid-soluble 23-kDa protein (P23) which displays 30% identity with a highly conserved domain of heat shock proteins (HSPs), as well as an AT-rich 3' untranslated region, which has also been described to play a role in H70 mRNA life span and protein expression. An identical perchloric-acid-soluble protein inhibiting protein synthesis in a rabbit reticulocyte lysate system was also found 2 years later by another group. More recently, the novel, the YjgF, protein family has been described, comprising, 24 full-length homologues, including P23, highly conserved through evolution, and consisting of approximately 130 residues each and sharing a common ternary structure. Independent studies from different laboratories have provided various hypothetical functions for each of these proteins. The high degree of evolutionary conservation may suggest that these proteins play an important role in cellular regulation. Although the function of none of these proteins is known precisely, we present experimental evidence which, combined with the relationship to glucose-regulating protein revealed here, and the relationship to fatty-acid-binding protein revealed by others, allow us to propose a role for P23. In rat liver, P23 expression is developmentally regulated and modulated by dietary glucose, and its mRNA is induced by starvation, in the presence of fatty-acids and in 3-MeDAB-induced hepatomas. The mRNA encoding mouse liver P23 is also hormonally modulated in a mouse line AT1F8. These data indicate that P23 protein might be a key controller of intermediary metabolism during fasting.

Characterization, purification and cDNA cloning of a rat perchloric-acid-soluble 23-kDa protein present only in liver and kidney.

A novel protein was extracted with 5% perchloric acid from rat liver and kidney. It is absent from other rat organs. Its apparent molecular mass is 23 kDa as determined by HPLC gel filtration. A single band, corresponding to 10 kDa, was observed after SDS/PAGE, suggesting that the protein consists of two subunits with similar molecular masses. This protein can neither be phosphorylated by ATP, nor acetylated. The sequence of the cDNA encoding this protein was determined. Southern-blot analysis showed that the corresponding gene spanned at least 10 kb and contained at least five introns. Zoo-blot analysis at medium stringency strongly suggests that the gene has been conserved during evolution. The amino-acid sequence of this protein with a highly conserved region is similar to that of a heat-shock protein.

The protein kinases tightly bound to DNA are present in normal tissues and in regenerating liver, but strongly decreased in hepatomas.

We have previously described in rat liver two protein kinases tightly bound to DNA, one is serine-specific, the other arginine-specific. In this work we show that both enzymes are present in various rat tissues and in liver from various species. Both kinase specific activities are strongly decreased in methyl-DBA-induced hepatomas and in HTC cells but not in regenerating liver after hepatectomy. This decrease is then not related to cell proliferation.

Characterization of an arginine-specific protein kinase tightly bound to rat liver DNA.

A new protein kinase has been characterized among the proteins tightly bound to rat liver DNA and released by DNase I and RNase A treatment. This enzyme was separated by gel filtration from this released material. Its apparent molecular mass was found to be 34 kDa and it is made of a single unit. The main characteristic of this protein kinase is that it is arginine-specific. Isolation of phosphoarginine required the use of proteolytic enzymes at alkaline pH since the phosphate bond is highly acid-labile. This protein kinase is able to autophosphorylate and to phosphorylate a single chromosomal protein of 11 kDa also tightly bound to DNA. It uses ATP and dATP as phosphate donors and is cAMP-independent. Its optimal activity requires Mn2+ ions. Vanadate, spermine and heparin have no effect on its activity.

Rat liver nuclear protein kinases NI and NII. Purification, subunit composition, substrate specificity, possible levels of regulation.

Rat liver nuclear protein kinases NI and NII have been purified to homogeneity by an improved method. This method includes a casein-phosvitin-Sepharose column step, which separates the enzymes from the other chromosomal non-histone proteins, and a gel filtration at high ionic strength in the presence of a high concentration of protease inhibitors to separate the two enzymes from each other. NI has an apparent molecular mass of approximately 50 kDa and is composed of a single subunit. NII has an apparent molecular mass of 133 kDa and is composed of two subunits of identical molecular mass. The V and the Km of the two enzymes were determined for several substrates. Both enzymes phosphorylate chromosomal non-histone proteins with partly different specificities as shown by two-dimensional electrophoreses. When incubated in the absence of protease inhibitors, the enzymes were degraded into discrete polypeptides. Autophosphorylation of a polypeptide derived from NII was observed after incubation of the enzyme with ATP. This phosphorylation stimulated the enzyme activity. Several chromosomal proteins coeluted with NII from the casein-phosvitin-Sepharose column. They remained associated with the enzyme in sucrose gradients, during gel filtration performed at physiological ionic strength, and are dissociated at high ionic strength. These proteins were highly phosphorylated when the protein-NII complex was incubated with ATP.

Separation of nuclear cAMP independent protein kinases NI and NII from their chromosomal protein substrates and enzyme inhibitors by the use of a casein-phosvitin-Sepharose column.

A casein-phosvitin-Sepharose chromatography column allows separation of nuclear protein kinases from their chromosomal phosphoprotein substrates and from at least some protein kinase inhibitors in a single step. The additional step of passing the eluted material through a partially hydrolyzed, dephosphorylated casein-Sepharose column separates the two protein kinases, NI and NII, from each other.

The 25 kDa protein kinase inhibitor present in liver cell is absent in fast growing HTC cells and is induced in sodium butyrate treated cells.

We have recently characterized a cAMP independent protein kinase inhibitor in rat liver. This inhibitor is absent or inactive in fast growing HTC cells and is induced according to exponential kinetics by sodium butyrate, a compound which arrests cell growth at the G1 phase of the cell cycle. It is suggested that the inhibitor could be involved in cell growth regulation.

A 25 000 dalton inhibitor of cAMP independent protein kinases present in rat liver HMG protein preparations.

A protein kinase inhibitor was found in rat liver cells as a component of HMG proteins. It is located in cytosol as well as in nuclei. It inhibits all tested cAMP independent protein kinases and has no effect on cAMP dependent protein kinases. This inhibitor is a 25 000 Da protein. It has no ATPase, phosphoprotein phosphatase or proteinase activity and is heat unstable.

A new cAMP independent protein kinase tightly bound to DNA, in rat liver nuclei.

A protein kinase has been characterized among the proteins tightly bound to DNA. It is not extracted with 1 M NaCl and is released by extensive DNase I digestion. This enzyme is able to phosphorylate nucleosomal histones, essentially H2B and H3, and several non-histone proteins associated with DNA, on serine residue(s). It does not phosphorylate protamine, casein, phosvitin and the chromosomal non-histone proteins extracted with 1 M NaCl and is cAMP independent. This protein kinase can be distinguished from the previously described enzymes.

In vitro, non enzymatic labelling of histone H1 with [14C] acetyl CoA.

Histones H 1A and H 1B, in nuclear homogenates or after purification, are able to be acetylated or labelled by [14C] acetyl CoA in the absence of enzyme, as shown after blotting into nitrocellulose sheets. The reaction is pH-dependent, resistant to 2 M NaCl and does not occur at high ionic strength.