Effects of phosphorylation of avian retrovirus nucleocapsid protein pp12 on binding of viral RNA

The major nucleocapsid protein of avian retroviruses, pp12, preferentially binds to the single-stranded regions of 60 S viral RNA with a apparent binding constant (Kapp) of 1.2 X 10(11) M-1. If the phosphate associated with serine residues of pp12 is hydrolyzed by either alkali treatment or with partially purified phosphoprotein phosphatase activities isolated from virions, the Kapp for binding to 60 S RNA decreases 100-fold. The high affinity binding of pp12 to viral RNA can be restored by phosphorylation of the protein with a protein kinase, protease-activated kinase I. The same serine residues phosphorylated in vivo are phosphorylated by protease kinase I in vitro. These residues have been identified as serine residues 40 and either 76 or 77. The protein purified from virions is phosphorylated primarily at serine residue 40 (greater than 90%). This suggests that phosphoserine residue 40 is responsible for modulating the binding of the protein to RNA. Thus, the phosphorylation state of pp12 can be reversibly altered in vitro resulting in the interconversion of the protein between a state of high and low affinity for single-stranded viral RNA.     

Functional characterization of the major and minor phosphorylation sites of the P protein of Borna disease virus

The phosphoprotein P of Borna disease virus (BDV) is an essential cofactor of the viral RNA-dependent RNA polymerase. It is preferentially phosphorylated at serine residues 26 and 28 by protein kinase C epsilon (PKCepsilon) and, to a lesser extent, at serine residues 70 and 86 by casein kinase II (CKII). To determine whether P phosphorylation is required for viral polymerase activity, we generated P mutants lacking either the PKCepsilon or the CKII phosphate acceptor sites by replacing the corresponding serine residues with alanine (A). Alternatively, these sites were replaced by aspartic acid (D) to mimic phosphorylation. Functional characterization of the various mutants in the BDV minireplicon assay revealed that D substitutions at the CKII sites inhibited the polymerase-supporting activity of P, while A substitutions maintained wild-type activity. Likewise, D substitutions at the PKC sites did not impair the cofactor function of BDV-P, whereas A substitutions at these sites led to increased activity. Interestingly, recombinant viruses could be rescued only when P mutants with modified PKCepsilon sites were used but not when both CKII sites were altered. PKCepsilon mutant viruses showed a reduced capacity to spread in cell culture, while viral RNA and protein expression levels in persistently infected cells were almost normal. Further mutational analyses revealed that substitutions at individual CKII sites were, with the exception of a substitution of A for S86, detrimental for viral rescue. These data demonstrate that, in contrast to other viral P proteins, the cofactor activity of BDV-P is negatively regulated by phosphorylation.     

Phosphorylation of the yeast ribosomal stalk. Functional effects and enzymes involved in the process

The ribosomal stalk is directly involved in the interaction of the elongation factors with the ribosome during protein synthesis. The stalk is formed by a complex of five proteins, four small acidic polypeptides and a larger protein which directly interacts with the rRNA at the GTPase center. In eukaryotes the acidic components correspond to the 12-kDa P1 and P2 proteins, and the RNA binding component is the P0 protein. All these proteins are found phosphorylated in eukaryotic organisms, and previous in vitro data suggested this modification was involved in the activity of this structure. Results from mutational studies have shown that phosphorylation takes place at a serine residue close to the carboxy end of the P proteins. Modification of this serine residue does not affect the formation of the stalk and the activity of the ribosome in standard conditions but induces an osmoregulation-related phenotype at 37 degrees C. The phosphorylatable serine is part of a consensus casein kinase II phosphorylation site. However, although CKII seems to be responsible for part of the stalk phosphorylation in vivo, it is probably not the only enzyme in the cell able to perform this modification. Five protein kinases, RAPI, RAPII and RAPIII, in addition to the previously reported CKII and PK60 kinases, are able to phosphorylate the stalk proteins. A comparison of the five enzymes shows differences among them that suggest some specificity regarding the phosphorylation of the four yeast acidic proteins. It has been found that some typical effectors of the PKC kinase stimulate the in vitro phosphorylation of the stalk proteins. All the data suggest that although phosphorylation is not involved in the interaction of the acidic P proteins with the ribosome, it can affect the ribosome activity and might participate in a possible ribosome regulatory mechanism.     

Identification of enhanced serine kinase activity in insulin resistance

Insulin receptor substrate (IRS) proteins play a crucial role as signaling molecules in insulin action. Serine phosphorylation of IRS proteins has been hypothesized as a cause of attenuating insulin signaling. The current study investigated serine kinase activity toward IRS-1 in several models of insulin resistance. An in vitro kinase assay was developed that used partially purified cell lysates as a kinase and glutathione S-transferase fusion proteins that contained various of IRS-1 fragments as substrates. Elevated serine kinase activity was detected in Chinese hamster ovary/insulin receptor (IR)/IRS-1 cells and 3T3-L1 adipocytes chronically treated with insulin, and in liver and muscle of obese JCR:LA-cp rats. It phosphorylated the 526-859 amino acid region of IRS-1, whereas phosphorylation of the 2-516 and 900-1235 amino acid regions was not altered. Phosphopeptide mapping of the 526-859 region of IRS-1 showed three major phosphopeptides (P1, P2, and P3) with different patterns of phosphorylation depending on the source of serine kinase activity. P1 and P2 were strongly phosphorylated when the kinase activity was prepared from insulin-resistant Chinese hamster ovary/IR/IRS-1 cells, weakly phosphorylated by the kinase activity from insulin-resistant 3T3-L1 adipocytes, and barely phosphorylated when the extract was derived from insulin-resistant liver. In contrast, P3 was phosphorylated by the serine kinase activity prepared from all insulin-resistant cells and tissues of animals. P1 and P2 phosphorylation can be explained by mitogen-activated protein kinase activity based on the phosphopeptide map generated by recombinant ERK2. In contrast, mitogen-activated protein kinase failed to phosphorylate the P3 peptide, suggesting that another serine kinase regulates this modification of IRS-1 in insulin-resistant state.     

Phosphorylation of a chloroplast RNA-binding protein changes its affinity to RNA.

An RNA-binding protein of 28 kDa (28RNP) was previously isolated from spinach chloroplasts and found to be required for 3' end-processing of chloroplast mRNAs. The amino acid sequence of 28RNP revealed two approximately 80 amino-acid RNA-binding domains, as well as an acidic- and glycine-rich amino terminal domain. Upon analysis of the RNA-binding properties of the 'native' 28RNP in comparison to the recombinant bacterial expressed protein, differences were detected in the affinity to some chloroplastic 3' end RNAs. It was suggested that post-translational modification can modulate the affinity of the 28RNP in the chloroplast to different RNAs. In order to determine if phosphorylation accounts for this post-translational modification, we examined if the 28RNP is a phosphoprotein and if it can serve as a substrate for protein kinases. It was found that the 28RNP was phosphorylated when intact chloroplasts were metabolically labeled with [32P] orthophosphate, and that recombinant 28RNP served as an excellent substrate in vitro for protein kinase isolated from spinach chloroplasts or recombinant alpha subunit of maize casein kinase II. The 28RNP was apparently phosphorylated at one site located in the acidic domain at the N-terminus of the protein. Site-directed mutagenesis of the serines in that region revealed that the phosphorylation of the protein was eliminated when serine number 22 from the N-terminus was changed to tryptophan. RNA-binding analysis of the phosphorylated 28RNP revealed that the affinity of the phosphorylated protein was reduced approximately 3-4-fold in comparison to the non-phosphorylated protein. Therefore, phosphorylation of the 28RNP modulates its affinity to RNA and may play a significant role in its biological function in the chloroplast.     

Molecular approaches to examine the phosphorylation state of the C type natriuretic peptide receptor

The intracellular domain of the C type natriuretic peptide receptor (NPRC) contains one threonine and several serine residues where phosphorylation is thought to occur. Several phosphorylation consensus sequences for various kinases have been identified within the intracellular domain of NPRC, but the exact residues that are phosphorylated and the specific kinases responsible for their phosphorylation have not been thoroughly defined. Here we introduce a recombinant GST fusion protein and a rat gastric mucosa (RGM1) cell line as molecular tools to study the phosphorylation state of NPRC in vitro and in vivo, respectively. We utilize a previously characterized polyclonal antibody against NPRC to probe for total NPRC protein and various phosphospecific and substrate motif antibodies to probe for phosphorylation of NPRC. Phosphoprotein staining reagents were used with a phosphoprotein control set to detect phosphorylation of NPRC at serine and threonine residues. Recombinant GST‐NPRC fusion protein was phosphorylated in vitro by RGM1 lysate in the presence of adenosine‐5'‐triphosphate (ATP). Western blot analysis using a monoclonal phospho‐Thr antibody, which exclusively detects phosphorylated threonine residues, and does not cross‐react with phosphorylated serine residues revealed NPRC immunoprecipitated from RGM1 lysate is phosphorylated on a threonine residue. Global analysis of the entire rat NPRC sequence using a protein kinase A (PKA) prediction algorithm, identified five putative PKA phosphorylation sites containing a serine residue and one containing a threonine residue, Thr 505. Taken together, the data presented here suggest that rat NPRC is a substrate for PKA and Thr 505 located within the intracellular domain of NPRC is a likely candidate site for the phosphorylation. J. Cell. Biochem. 110: 985–994, 2010. © 2010 Wiley‐Liss, Inc.     

Proteolytic cleavage of phospholamban purified from canine cardiac sarcoplasmic reticulum vesicles. Generation of a low resolution model of phospholamban structure

Purified phospholamban isolated from canine cardiac sarcoplasmic reticulum vesicles was subjected to proteolysis and peptide mapping to localize the different sites of phosphorylation on the protein and to gain further information on its subunit structure. Five different proteases (trypsin, papain, chymotrypsin, elastase, and Pronase) degraded the oligomeric 27-kDa phosphoprotein into a major 21-22-kDa protease-resistant fragment. No 32P was retained by this protease-resistant fragment, regardless of whether phospholamban had been phosphorylated by cAMP-dependent protein kinase, Ca2+/calmodulin-dependent protein kinase, or protein kinase C. Phosphoamino acid analysis and thin-layer electrophoresis of liberated phosphopeptides revealed that 1 threonine and 2 serine residues were phosphorylated in phospholamban and that 1 of these serine residues and the threonine residue were in close proximity. Only serine was phosphorylated by cAMP-dependent protein kinase, whereas Ca2+-calmodulin-dependent protein kinase phosphorylated exclusively threonine. The results demonstrate that phospholamban has a large protease-resistant domain and a smaller protease-sensitive domain, the latter of which contains all of the sites of phosphorylation. The 21-22-kDa protease-resistant domain, although devoid of incorporated 32P, was completely dissociated into identical lower molecular weight subunits by boiling in sodium dodecyl sulfate, suggesting that this region of the molecule promotes the relatively strong interactions that hold the subunits together. The data presented lend further support for a model of phospholamban structure in which several identical low molecular weight subunits are noncovalently bound to one another, each containing one site of phosphorylation for cAMP-dependent protein kinase and another site of phosphorylation for Ca2+/calmodulin-dependent protein kinase.     

Conserved phosphorylation of serines in the Ser-X-Glu/Ser(P) sequences of the vitamin K-dependent matrix Gla protein from shark, lamb, rat, cow, and human.

The present studies demonstrate that matrix Gla protein (MGP), a 10-kDa vitamin K-dependent protein, is phosphorylated at 3 serine residues near its N-terminus. Phosphoserine was identified at residues 3, 6, and 9 of bovine, human, rat, and lamb MGP by N-terminal protein sequencing. All 3 modified serines are in tandemly repeated Ser-X-Glu sequences. Two of the serines phosphorylated in shark MGP, residues 2 and 5, also have glutamate residues in the n + 2 position in tandemly repeated Ser-X-Glu sequences, whereas the third, shark residue 3, would acquire an acidic phosphoserine in the n + 2 position upon phosphorylation of serine 5. The recognition motif found for MGP phosphorylation, Ser-X-Glu/Ser(P), has been seen previously in milk caseins, salivary proteins, and a number of regulatory peptides. A review of the literature has revealed an intriguing dichotomy in the extent of serine phosphorylation among secreted proteins that are phosphorylated at Ser-X-Glu/Ser(P) sequences. Those phosphoproteins secreted into milk or saliva are fully phosphorylated at each target serine, whereas phosphoproteins secreted into the extracellular environment of cells are partially phosphorylated at target serine residues, as we show here for MGP and others have shown for regulatory peptides and the insulin-like growth factor binding protein 1. We propose that the extent of serine phosphorylation regulates the activity of proteins secreted into the extracellular environment of cells, and that partial phosphorylation can therefore be explained by the need to ensure that the phosphoprotein be poised to gain or lose activity with regulated changes in phosphorylation status.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphorylation of Glial Fibrillary Acidic Protein and Vimentin by Cytoskeletal-Associated Intermediate Filament Protein Kinase Activity in Astrocytes

These studies describe a cytoskeletal-associated protein kinase activity in astrocytes that phosphorylated the intermediate filament proteins glial fibrillary acidic protein (GFAP) and vimentin and that appeared to be distinct from protein kinase C (PK-C) and the cyclic AMP-dependent protein kinase (PK-A). The cytoskeletal-associated kinase activity phosphorylated intermediate filament proteins in the presence of 10 mM MgCl2 and produced an even greater increase in 32P incorporation into these proteins in the presence of calcium/calmodulin. Tryptic peptide mapping of phosphorylated intermediate filament proteins showed that the intermediate filament protein kinase activity produced unique phosphopeptide maps, in both the presence and the absence of calcium/calmodulin, as compared to that of PK-C and PK-A, although there were some common sites of phosphorylation among the kinases. In addition, it was determined that the intermediate filament protein kinase activity phosphorylated both serine and threonine residues of the intermediate filament proteins, vimentin and GFAP. However, the relative proportion of serine and threonine residues phosphorylated varied depending on the presence or absence of calcium/calmodulin. The magnesium-dependent activity produced the highest proportion of threonine phosphorylation, suggesting that the calcium/calmodulin-dependent kinase activity acts mainly at serine residues. PK-A and PK-C phosphorylated mainly serine residues. Also, the intermediate filament protein kinase activity phosphorylated both the N-and the C-terminal domains of vimentin and the N-terminal domain of GFAP. In contrast, both PK-C and PK-A are known to phosphorylate the N-terminal domains of both proteins.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphorylation of the GABAa/Benzodiazepine Receptor α Subunit by a Receptor-Associated Protein Kinase

Abstract: Partially purified preparations of GABA_a/benzodiazepine receptor from rat brain were found to contain high levels of a protein kinase activity that phosphorylated a small number of proteins in the receptor preparations, including a 50-kilodalton (kD) phosphoprotein that comigrated on two-dimensional electrophoresis with purified, immunolabeled, and photolabeled receptor α subunit. Further evidence that the comigrating 50-kD phosphoprotein was, in fact, the receptor α subunit was obtained by peptide mapping analysis: the 50-kD phosphoprotein yielded one-dimensional peptide maps identical to those obtained from iodinated, purified α subunit. Phosphoamino acid analysis revealed that the receptor α subunit is phosphorylated on serine residues by the protein kinase activity present in receptor preparations. Preliminary characterization of the receptor-associated protein kinase activity suggested that it may be a second messenger-independent protein kinase. Protein kinase activity was unaltered by cyclic AMP, cyclic GMP, calcium plus calmodulin, calcium plus phosphatidylserine, and various inhibitors of these protein kinases. Examination of the substrate specificity of the receptor-associated protein kinase indicated that the enzyme preferred basic proteins as substrates. Endogenous phosphorylation experiments indicated that the receptor α subunit may also be phosphorylated in crude membranes by a protein kinase activity present in those membranes. As with phosphorylation of the receptor in purified preparations, its phosphorylation in crude membranes also appeared to be unaffected by activators and inhibitors of second messenger-dependent protein kinases. These findings raise the possibility that the phosphorylation of the α subunit of the GABA_a/ benzodiazepine receptor by a receptor-associated protein kinase plays a role in modulating the physiological activity of the receptor in vivo.