Phosphorylation and/or Presence of Serine 37 in the Movement Protein of Tomato Mosaic Tobamovirus Is Essential for Intracellular Localization and Stability In Vivo

The P30 movement protein (MP) of tomato mosaic tobamovirus (ToMV) is synthesized in the early stages of infection and is phosphorylated in vivo. Here, we determined that serine 37 and serine 238 in the ToMV MP are sites of phosphorylation. MP mutants in which serine was replaced by alanine at positions 37 and 238 (LQ37A238A) or at position 37 only (LQ37A) were not phosphorylated, and mutant viruses did not infect tobacco or tomato plants. By contrast, mutation of serine 238 to alanine did not affect the infectivity of the virus (LQ238A). To investigate the subcellular localization of mutant MPs, we constructed viruses that expressed each mutant MP fused with the green fluorescent protein (GFP) of Aequorea victoria. Wild-type and mutant LQ238A MP fusion proteins showed distinct temporally regulated patterns of MP-GFP localization in protoplasts and formation of fluorescent ring-shaped infection sites on Nicotiana benthamiana. However mutant virus LQ37A MP-GFP did not show a distinct pattern of localization or formation of fluorescent rings. Pulse-chase experiments revealed that MP produced by mutant virus LQ37A was less stable than wild-type and LQ238A MPs. MP which contained threonine at position 37 was phosphorylated, but the stability of the MP in vivo was very low. These studies suggest that the presence of serine at position 37 or phosphorylation of serine 37 is essential for intracellular localization and stability of the MP, which is necessary for the protein to function.     

Phosphorylation down-regulates the RNA binding function of the coat protein of potato virus A

Plant viruses encode movement proteins (MPs) to facilitate transport of their genomes from infected into neighboring healthy cells through plasmodesmata. Growing evidence suggests that specific phosphorylation events can regulate MP functions. The coat protein (CP) of potato virus A (PVA; genus Potyvirus) is a multifunctional protein involved both in virion assembly and virus movement. Labeling of PVA-infected tobacco leaves with [(33)P]orthophosphate demonstrated that PVA CP is phosphorylated in vivo. Competition assays established that PVA CP and the well characterized 30-kDa MP of tobacco mosaic virus (genus Tobamovirus) are phosphorylated in vitro by the same Ser/Thr kinase activity from tobacco leaves. This activity exhibits a strong preference for Mn(2+) over Mg(2+), can be inhibited by micromolar concentrations of Zn(2+) and Cd(2+), and is not Ca(2+)-dependent. Tryptic phosphopeptide mapping revealed that PVA CP was phosphorylated by this protein kinase activity on multiple sites. In contrast, PVA CP was not phosphorylated when packaged into virions, suggesting that the phosphorylation sites are located within the RNA binding domain and not exposed on the surface of the virion. Furthermore, two independent experimental approaches demonstrated that the RNA binding function of PVA CP is strongly inhibited by phosphorylation. From these findings, we suggest that protein phosphorylation represents a possible mechanism regulating formation and/or stability of viral ribonucleoproteins in planta.     

Regulation of plasmodesmal transport by phosphorylation of tobacco mosaic virus cell-to-cell movement protein

Cell-to-cell spread of tobacco mosaic virus (TMV) through plant intercellular connections, the plasmodesmata, is mediated by a specialized viral movement protein (MP). In vivo studies using transgenic tobacco plants showed that MP is phosphorylated at its C-terminus at amino acid residues Ser258, Thr261 and Ser265. When MP phosphorylation was mimicked by negatively charged amino acid substitutions, MP lost its ability to gate plasmodesmata. This effect on MP-plasmodesmata interactions was specific because other activities of MP, such as RNA binding and interaction with pectin methylesterases, were not affected. Furthermore, TMV encoding the MP mutant mimicking phosphorylation was unable to spread from cell to cell in inoculated tobacco plants. The regulatory effect of MP phosphorylation on plasmodesmal permeability was host dependent, occurring in tobacco but not in a more promiscuous Nicotiana benthamiana host. Thus, phosphorylation may represent a regulatory mechanism for controlling the TMV MP-plasmodesmata interactions in a host-dependent fashion.     

Phosphorylation of hepatitis B virus core C-terminally truncated protein (Cp149) by PKC increases capsid assembly and stability

The HBV (hepatitis B virus) core is a phosphoprotein whose assembly, replication, encapsidation and localization are regulated by phosphorylation. It is known that PKC (protein kinase C) regulates pgRNA (pregenomic RNA) encapsidation by phosphorylation of the C-terminus of core, which is a component packaged into capsid. Neither the N-terminal residue phosphorylated by PKC nor the role of the C-terminal phosphorylation have been cleary defined. In the present study we found that HBV Cp149 (core protein C-terminally truncated at amino acid 149) expressed in Escherichia coli was phosphorylated by PKC at Ser(106). PKC-mediated phosphorylation increased core affinity, as well as assembly and capsid stability. In vitro phosphorylation with core mutants (S26A, T70A, S106A and T114A) revealed that the Ser(106) mutation inhibited phosphorylation of core by PKC. CD analysis also revealed that PKC-mediated phosphorylation stabilized the secondary structure of capsid. When either pCMV/FLAG-Cp149[WT (wild-type)] or pCMV/FLAG-S106A Cp149 was transfected into Huh7 human hepatoma cells, mutant capsid level was decreased by 2.06-fold with the S106A mutant when compared with WT, although the same level of total protein was expressed in both cases. In addition, when pUC1.2x and pUC1.2x/S106A were transfected, mutant virus titre was decreased 2.31-fold compared with WT virus titre. In conclusion, PKC-mediated phosphorylation increased capsid assembly, stability and structural stability.     

Identification of a phosphorylation site within the P protein important for mRNA transcription and growth of parainfluenza virus 5

The viral RNA-dependent RNA polymerase (vRdRp) of paramyxovirus consists of the large (L) protein and the phosphoprotein (P). P is heavily phosphorylated, and it is thought that the phosphorylation of P plays a role in regulating viral RNA synthesis. However, no phosphorylation site within the P protein in paramyxovirus has been identified as playing a positive role in viral RNA synthesis in virus infection. Using mass spectrometry analysis, the threonine residue at position 286 of P of parainfluenza virus 5 (PIV5) was found phosphorylated. Mutation of T286 to alanine (T286A), aspartic acid (T286D), or glutamic acid (T286E) reduced minigenome activity. Recombinant virus containing a mutation at the T286 position (rPIV5-P-T286A) grew slower than wild-type virus; viral mRNA synthesis and protein expression of rPIV5-P-T286A were delayed. Biochemical studies showed that the binding of NP or L protein with the P mutants or tetramer formation by the mutant P proteins was unaltered from that for wild-type P. While we failed to rescue rPIV5-P-T286E virus, several revertant viruses were obtained. All non-wild-type revertants had mutations at T286 and showed defects in both minigenome activity and viral growth. This is the first time that a phosphorylation site within the P protein in paramyxovirus has been found to play a positive role in viral mRNA synthesis and virus growth.     

A lens intercellular junction protein, MP26, is a phosphoprotein

The major protein present in the plasma membrane of the bovine lens fiber cell (MP26), thought to be a component of intercellular junctions, was phosphorylated in an in vivo labeling procedure. After fragments of decapsulated fetal bovine lenses were incubated with [32P]orthophosphate, membranes were isolated and analyzed by SDS PAGE and autoradiography. A number of lens membrane proteins were routinely phosphorylated under these conditions. These proteins included species at Mr 17,000 and 26,000 as well as a series at both 34,000 and 55,000. The label at Mr 26,000 appeared to be associated with MP26, since (a) boiling the membrane sample in SDS led to both an aggregation of MP26 and a loss of label at Mr 26,000, (b) the label at 26,000 was resistant to both urea and nonionic detergents, and (c) two-dimensional gels showed that a phosphorylated Mr 24,000 fragment was derived from MP26 with V8 protease. Studies with proteases also provided for a localization of most label within approximately 20 to 40 residues from the COOH-terminus of MP26. Published work indicates that the phosphorylated portion of MP26 resides on the cytoplasmic side of the membrane, and that this region of MP26 contains a number of serine residues. The same region of MP26 was labeled when isolated lens membranes were reacted with a cAMP-dependent protein kinase prepared from the bovine lens. After the in vivo labeling of lens fragments, phosphoamino acid analysis of MP26 demonstrated primarily labeled serines, with 5-10% threonines and no tyrosines. Treatments that lowered the intracellular calcium levels in the in vivo system led to a selective reduction of MP26 phosphorylation. In addition, forskolin and cAMP stimulated the phosphorylation of MP26 and other proteins in concentrated lens homogenates. These findings are of interest because MP26 appears to serve as a protein of cell-to-cell channels in the lens, perhaps as a lens gap junction protein.     

Sites of in vivo phosphorylation of vesicular stomatitis virus matrix protein.

We mapped the in vivo phosphorylation sites for the matrix (M) protein of the Orsay and San Juan strains of vesicular stomatitis virus, Indiana serotype, using limited proteolysis and phosphoamino acid analysis. M protein was solubilized from 32P-labeled virions by using detergent and high-salt conditions, then treated with either trypsin or Staphylococcus aureus V8 protease, and analyzed by polyacrylamide gel electrophoresis and autoradiography to determine which fragments contained phosphate residues. The M protein fragment extending from amino acid 20 to the carboxy terminus contained approximately 70% of the control 32P label, while the fragment extending from amino acid 35 to the carboxy terminus had only trace amounts of label. These data indicate that the major phosphorylation site was between amino acids 20 and 34 in the Orsay strain M protein. Phosphoamino acid analysis of M protein by thin-layer electrophoresis showed the presence of phosphothreonine and phosphoserine and that phosphothreonine continued to be released after prolonged vapor-phase acid hydrolysis. These data identify Thr-31 as the primary in vivo phosphate acceptor for M protein of the Orsay strain of vesicular stomatitis virus. The San Juan strain M protein has serine at position 32, which may also be an important phosphate acceptor. In addition, phosphorylation at Ser-2, -3, or -17 occurs to a greater extent in the San Juan strain M protein than in the Orsay strain M protein. The subcellular distribution of phosphorylated M protein was investigated to determine a probable intracellular site(s) of phosphorylation. Phosphorylated M protein was associated primarily with cellular membranes, suggesting phosphorylation by a membrane-associated kinase. Virion M protein was phosphorylated to a greater extent than membrane-bound M protein, indicating that M protein phosphorylation occurs at a late stage in virus assembly. Phosphorylation of wild-type and temperature-sensitive mutant M protein was studied in vivo at the nonpermissive temperature. The data show that phosphorylated M protein was detected only in wild-type virus-infected cells and virions, suggesting that association with nucleocapsids may be required for M protein phosphorylation or that misfolding of mutant M protein at the nonpermissive temperature prevents phosphorylation.     

Comparison of phosphorylation of two polyoma virus middle T antigens in vivo and in vitro.

Two species of polyoma virus middle T antigen were detected in both lytically infected and transformed cells by in vitro kinase assay of immunoprecipitates. A minor species with an apparent molecular weight of 58,000 (58K) represented less than 10% of the total middle T protein. This species was roughly 10 times more active as a phosphate acceptor than was the predominant 56K form. Partial proteolytic mapping experiments showed that the same site was phosphorylated in both species. Mapping of the middle T antigens from a series of deletion mutants suggested that the major site of phosphorylation is tyrosine residue 315. Phosphorylation occurred on both middle T species in vivo, involving sites predominantly other than the tyrosine labeled in vitro. The 56K and 58K middle T forms differed from each other in their in vivo phosphorylation patterns. Some phosphate was incorporated into the 58K species in a region of the molecule to which at least part of the apparent molecular weight different could be mapped. hr-t mutant NG-59, which codes for a slightly altered middle T, produced only a single species (56K) which was inactive in the in vitro kinase reaction. Moreover, no 58K species appeared in vivo with this mutant. hr-t mutants are therefore defective in both aspects of phosphorylation. Phenotypically normal revertant cells of a polyoma transformed line failed to express any middle T antigens or associated kinase activity.     

Phosphorylated serine residues and an arginine-rich domain of the moloney murine leukemia virus p12 protein are required for early events of viral infection

Mutational analyses of the p12 Gag phosphoprotein of Moloney murine leukemia virus have demonstrated its participation in both virus assembly and the early stages of infection. The molecular mechanisms by which p12 functions in these events are still poorly understood. We performed studies to examine the significance of p12 phosphorylation in the viral life cycle. Alanine substitutions were introduced at the potential phosphorylation sites in p12, and the resulting mutants were tested for replication. Mutant viruses with changes at S61 and S78 were severely impaired, whereas the other mutant viruses were viable. S61 was shown to be required for normal levels of phosphorylation of p12 in vivo. These defective mutant viruses showed no apparent alteration to Gag protein processing or reduction in the yield of virions after transient transfection, but the mutants failed to form circular viral DNAs in acutely infected cells. Sequence analysis of revertant clones derived from S(61,65)A mutant virus revealed two classes: one group with a single mutation at a residue adjacent to S61 and another group with mutations introducing new positive charges surrounding S61. In vivo [32P]orthophosphate labeling indicated that the rescue of the S(61,65)A mutant virus did not result in a significant increase in the phosphorylation level of p12. Alanine substitutions of an arginine-rich stretch near S61 (at R-66, -68, -70, and -71) resulted in the same phenotype as the S(61,65)A mutant virus. The restored function of S(61,65)A mutant virus by second or third site mutations may result from a structural change or the addition of positively charged residues in the arginine-rich region.     

Identification of the threonine phosphorylation sites on the polyomavirus major capsid protein VP1: relationship to the activity of middle T antigen.

Phosphorylation of the polyomavirus major capsid protein VP1 was examined after in vivo 32P labeling of virus-infected cells. Two phosphorylated peptide fragments of VP1 were identified by protease digestion, high-performance liquid chromatography purification, mass spectrometry, and N-terminal sequencing. The peptides from residues 58 to 78 and residues 153 to 173 were phosphorylated on threonine. Site-directed mutations were introduced at these threonine sites, and mutant viruses were reconstructed. A threonine-to-glycine change at residue 63 (mutant G63) and a threonine-to-alanine change at residue 156 (mutant A156) resulted in viruses defective in phosphorylation of the respective peptides after in vivo labeling. Growth of the mutant G63 virus was similar to that of the wild-type virus, but the mutant A156 was inefficient in assembly of 240S viral particles. Polyomavirus nontransforming host range (hr-t) mutants are defective in VP1 threonine phosphorylation when grown in nonpermissive cells (R. L. Garcea, K. Ballmer-Hofer, and T. L. Benjamin, J. Virol. 54:311-316, 1985). Proteolytic mapping of VP1 peptides after in vivo labeling from hr-t mutant virus infections demonstrated that both residues T-63 and T-156 were affected. These results suggest that the block in virion assembly in hr-t mutant viruses is associated with a defect in phosphorylation of threonine 156.     

Activation of CheY mutant D57N by phosphorylation at an alternative site, Ser-56

The site of phosphorylation of the chemotaxis response regulator CheY is aspartate 57. When Asp-57 is replaced with an asparagine, the resultant protein can be phosphorylated at an alternative site. We report here that phosphorylation of this mutant protein, CheY D57N, at the alternative site affords the protein activity in vivo in the absence of CheZ. Using a direct phosphopeptide mapping approach, we identified the alternate phosphorylation site as serine 56. Introduction of a Ser-->Ala substitution at this position in wild-type CheY had no effect on function. However, replacement of Ser-56 with Ala in CheY D57N abrogated the activity seen in vivo for the CheY D57N single mutant protein, and no phosphorylation of the CheY S56A/D57N double mutant protein was observed in vitro. Construction and analysis of double mutants CheY D57N/T87A and CheY D57N/K109R, which were both inactive, suggested that phosphorylation at Ser-56 or Asp-57 may activate the protein by similar mechanisms. In contrast to CheY D57N, mutant CheY D57E displayed no activity in vivo, despite its ability to be phosphorylated in vitro. Acid-base stability analysis indicated that CheY D57E phosphorylates on an acidic residue, presumably Glu-57. These data suggest that a key determinant of the ability of a phosphoryl group to activate CheY is proximity to the hydrophobic core of the protein, with consequent opportunity to reposition key residues, irrespective of the chemical nature of the linkage attaching the phosphoryl group to CheY.     

Phosphorylation of the Abelson murine leukemia virus transforming protein.

The Abelson murine leukemia virus transforming gene product is a phosphorylated protein encoded by both viral and cellular sequences. This gene product has an amino-terminal region derived from the gag gene of its parent virus and a carboxyl-terminal region of (abl) derived from a normal murine cellular gene. Using a combination of partial proteolytic cleavage techniques and antisera specific for gag and abl sequences, we mapped in vivo phosphorylation sites to different regions of the protein. Phosphoproteins encoded by strain variants and transformation-defective mutants of Abelson murine leukemia virus with defined deletions in the primary sequence of the abl region were compared by two dimensional limit digest peptide mapping. Specific phosphorylation pattern differences for wild-type and mutant proteins probably represented deletions of specific phosphate acceptor sites in the abl region. An in vitro autophosphorylation activity copurified with the Abelson murine leukemia virus protein from transformation-competent strains. A peptide analysis of such in vitro reactions demonstrated that these phosphorylation sites were restricted to the amino-terminal region, and the specific sites appeared to be unrelated to the sites found on proteins phosphorylated in vivo. Thus, the autophosphorylation reaction probably correlates with an activity important in transformation, but the specific end product in vitro bears little resemblance to its function in vivo.     

Specific phosphorylation of the acidic central region of the N-myc protein by casein kinase II.

The central region of the N-myc protein has a characteristic amino acid sequence EDTLSDSDDEDD, which is very similar to those of particular domains of adenovirus E1A, human papilloma virus E7, Simian virus 40 large T, c-myc and L-myc proteins. Domains of these three viral oncoproteins have recently been shown to be specific binding sites for the tumor-suppressor gene retinoblastoma protein. We have noted that the sequence of serine followed by a cluster of acidic amino acids is exactly the same as that of a typical substrate of casein kinase II (CKII). Therefore, we investigated whether these nuclear oncoproteins are phosphorylated by CKII. For this purpose, we fused the beta-galactosidase and N-myc genes including this domain and expressed it in Escherichia coli cells. Several mutant N-myc genes, containing single amino acid substitutions in this domain, were also used to produce fused proteins. Strong phosphorylation by CKII was detected with the fused protein of wild-type N-myc. However, no phosphorylation of beta-galactosidase itself was observed and the phosphorylations of fused mutant proteins were low. Another fused N-myc protein containing most of the C-terminal region downstream of this acidic region was not phosphorylated by CKII. Analysis of phosphorylation sites in synthetic peptides of this acidic region identified the major sites phosphorylated by CKII as Ser261 and Ser263. On two-dimensional tryptic mapping of phosphorylated N-myc proteins, major spots of in vitro-labeled and in-vivo-labeled N-myc proteins were detected in the same positions. These results suggest that two serine residues of the acidic central region of the N-myc protein are phosphorylated by CKII in vivo as well as in vitro. The functional significance of this acidic domain is discussed.     

Identification of the phosphorylation sequence in the cytoplasmic tail of the varicella-zoster virus Fc receptor glycoprotein gpI.

Varicella-zoster virus (VZV) glycoprotein gpI, the homolog of herpes simplex virus gE, functions as a receptor for the Fc portion of immunoglobulin G. Like other cell surface receptors, this viral receptor is highly phosphorylated in cell culture. To identify the precise location of the cellular kinase-mediated phosphorylation, we generated a tailless deletion mutant and several point mutants which had altered serine and threonine residues within the cytoplasmic domain of gpI. The mutated and wild-type genes of gpI were transfected and expressed within a vaccinia virus-T7 polymerase transfection system in order to determine what effect these mutations had on the phosphorylation state of the protein in vivo and in vitro. Truncation of the cytoplasmic domain of gpI diminished the phosphorylation of gpI in vivo. Examination of the point mutants established that the major phosphorylation sequence of gpI was located between amino acids 593 and 598, a site which included four phosphorylatable serine and threonine residues. Phosphorylation analyses of the mutant and wild-type glycoproteins confirmed that gpI was a substrate for casein kinase II, with threonines 596 and 598 being critical residues. Although the mutant glycoproteins were phosphorylated by casein kinase I, protease V8 partial digestion profiles suggested that casein kinase II exerted the major effect. Thus, these mutagenesis studies demonstrated that the gpI cytoplasmic sequence Ser-Glu-Ser-Thr-Asp-Thr was phosphorylated in mammalian cells in the absence of any other herpesvirus products. Since the region defined by transfection was consistent with results obtained with in vitro phosphorylation by casein kinase II, we propose that VZV gpI is a physiologic substrate for casein kinase II. Immunofluorescence and pulse-chase experiments demonstrated that the mutant glycoproteins were processed and transported to the outer cell membrane.     

Identification of the Sites for Suppressor Mutations on the Hemagglutinin Molecule to Temperature-Sensitive Phenotype of the Influenza Virus

A temperature-sensitive (ts) mutant of the influenza virus A/WSN/ 33 strain, ts-134, possessed a defect in intracellular transport at the nonpermissive temperature and marked thermolability of hemagglutinin (HA) activity at 51 C. These were caused by a change at amino acid residue 157 from tyrosine to histidine in the HA protein. We isolated 37 spontaneous revertant clones from ts-134 at the nonpermissive temperature and determined their HA sequences. The deduced amino acid sequences demonstrated that one was a true revertant and the others were revertants with suppressor mutations, each of which had an additional amino acid change besides those of ts-134. The changed amino acids were located at 14 positions on the HA molecule, and eight of them were found in multiple revertants. These were located in five to six distinct regions on the three-dimensional structure of the HA molecule. However, the heat stability of HAs in the revertants was recovered differently depending on the sites of the changed amino acids. The kinetics of transport of the HA protein in the revertants were slightly delayed compared to the wild-type both at permissive and nonpermissive temperatures.     

Identification of Ser424 as the protein kinase A phosphorylation site in CTP synthetase from Saccharomyces cerevisiae.

The URA7-encoded CTP synthetase [EC 6.3.4.2, UTP:ammonia ligase (ADP-forming)] in the yeast Saccharomyces cerevisiae is phosphorylated on a serine residue and stimulated by cAMP-dependent protein kinase (protein kinase A) in vitro. In vivo, the phosphorylation of CTP synthetase is mediated by the RAS/cAMP pathway. In this work, we examined the hypothesis that amino acid residue Ser424 contained in a protein kinase A sequence motif in the URA7-encoded CTP synthetase is the target site for protein kinase A. A CTP synthetase synthetic peptide (SLGRKDSHSA) containing the protein kinase A motif was a substrate (Km = 30 microM) for protein kinase A. This peptide also inhibited (IC50 = 45 microM) the phosphorylation of purified wild-type CTP synthetase by protein kinase A. CTP synthetase with a Ser424 --> Ala (S424A) mutation was constructed by site-directed mutagenesis. The mutated enzyme was not phosphorylated in response to the activation of protein kinase A activity in vivo. Purified S424A mutant CTP synthetase was not phosphorylated and stimulated by protein kinase A. The S424A mutant CTP synthetase had reduced Vmax and elevated Km values for ATP and UTP when compared with the protein kinase A-phosphorylated wild-type enzyme. The specificity constants for ATP and UTP for the S424A mutant CTP synthetase were 4.2- and 2.9-fold lower, respectively, when compared with that of the phosphorylated enzyme. In addition, the S424A mutant enzyme was 2.7-fold more sensitive to CTP product inhibition when compared with the phosphorylated wild-type enzyme. These data indicated that the protein kinase A target site in CTP synthetase was Ser424 and that the phosphorylation of this site played a role in the regulation of CTP synthetase activity.     

Identification of the major phosphorylation site of the hepatitis C virus H strain NS5A protein as serine 2321.

The hepatitis C virus (HCV) NS5A protein is phosphorylated by a cellular, serine/threonine kinase. To identify the major site(s) of NS5A phosphorylation, radiolabeled HCV-H NS5A phosphopeptides were purified and subjected to phosphoamino acid analysis and Edman degradation. These data identified the major intracellular phosphorylation site in the HCV-H NS5A protein as Ser(2321), a result verified by two additional, independent methods: (i) substitution of Ala for Ser(2321) and the concomitant disappearance of the major in vivo phosphorylated peptides and corresponding in vitro phosphorylated peptides; and (ii) comigration of the digestion products of a synthetic peptide phosphorylated on Ser(2321) with the major in vivo phosphorylated NS5A peptides. Site-directed mutagenesis of Ser(2321) suggested that phosphorylation of NS5A is dispensable for previously described interactions with NS4A and PKR, a cellular, antiviral kinase that does not appear to catalyze NS5A phosphorylation. The proline-rich nature of the amino acid sequence flanking Ser(2321) (PLPPPRS(2321) PPVPPPR) suggests that a proline-directed kinase is responsible for the majority of HCV NS5A phosphorylation, consistent with previous kinase inhibitor studies.     

Analysis of the phosphorylation sites of herpes simplex virus type 1 regulatory protein ICP27

The herpes simplex virus type 1 (HSV-1) regulatory protein ICP27 is a 63-kDa phosphoprotein required for viral replication. ICP27 has been shown to contain both stable phosphate groups and phosphate groups that cycle on and off during infection (K. W. Wilcox, A. Kohn, E. Sklyanskaya, and B. Roizman, J. Virol. 33:167-182, 1980). Despite extensive genetic analysis of the ICP27 gene, there is no information available about the sites of the ICP27 molecule that are phosphorylated during viral infection. In this study, we mapped several of the phosphorylation sites of ICP27 following in vivo radiolabeling. Phosphoamino acid analysis showed that serine is the only amino acid that is phosphorylated during infection. Two-dimensional phosphopeptide mapping showed a complex tryptic phosphopeptide pattern with at least four major peptides and several minor peptides. In addition, ICP27 purified from transfected cells yielded a similar phosphopeptide pattern, suggesting that cellular kinases phosphorylate ICP27 during viral infection. In vitro labeling showed that protein kinase A (PKA), PKC, and casein kinase II (CKII) were able to differentially phosphorylate ICP27, resulting in distinct phosphopeptide patterns. The major phosphorylation sites of ICP27 appeared to cluster in the N-terminal portion of the protein, such that a frameshift mutant that encodes amino acids 1 to 163 yielded a phosphopeptide pattern very similar to that seen with the wild-type protein. Further, using small deletion and point mutations in kinase consensus sites, we have elucidated individual serine residues that are phosphorylated in vivo. Specifically, the serine at residue 114 was highly phosphorylated by PKA and the serine residues at positions 16 and 18 serve as targets for CKII phosphorylation in vivo. These kinase consensus site mutants were still capable of complementing the growth of an ICP27-null mutant virus. Interestingly, phosphorylation of the serine at residue 114, which lies within the major nuclear localization signal, appeared to modulate the efficiency of nuclear import of ICP27.     

Microsome protein phosphorylation in Acer pseudoplatanus cells as influenced by intracellular alkalinization

Abstract. The authors have previously shown that cell treatments causing intra-cellular alkalinization stimulate the in vivo phosphorylation of a 33-K Dalton polypeptide (33 KP) (Tognoli & Basso, 1987). Here, the authors report that this polypeptide belongs to a protein associated with the microsomal membranes. They show that treatment of cells which induce intracellular alkalinization stimulate 33-KP phosphorylation, whether the phosphorylation is performed in vivo (cells loaded with ³²Pi before treatments) or in vitro (microsomes from control and treated cells, incubated with γ³²P ATP). In both cases, 33 KP is phosphorylated on a serine residue. Microsomes do not show any phosphatase activity towards this phosphorylated protein, indicating involvement of a protein kinase reaction as an effector of changes induced by intracellular alkalinization. The number of phosphorylated sites or molecules of this protein increases as a result of intracellular alkalinization, suggesting that intracellular alkalinization causes topological or conformational modifications to a protein kinase or its substrate protein. The in vitro phosphorylation is not specifically influenced by the pH of the in vitro phosphorylation medium, suggesting that protein phosphorylation is not directly controlled by cytoplasmic pH.     

Serine 3 is critical for phosphorylation at the N-terminal end of the nucleoprotein of influenza virus A/Victoria/3/75.

The influenza A virus nucleoprotein (NP) is a phosphoprotein that encapsidates the viral genomic RNA. To map the in vivo phosphorylation site(s) of this protein, 32P-labeled NP was purified from cell cultures infected with influenza virus A/Victoria/3/75 by immunoaffinity chromatography. The purified protein was then subjected to chemical digestion with formic acid, which cleaves proteins at Asp-Pro bonds, and the resulting products were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Two of the phosphorylated products obtained were identified as fragments corresponding to the N-terminal 88 amino acids and to the C-terminal 196 residues of the NP. To identify the phosphate acceptor site(s) at the N-terminal phosphorylated region of NP, each of the seven serines within this region was individually changed to alanine by site-directed mutagenesis. The mutant proteins were then transiently expressed in mammalian cells and analyzed for their phosphorylation state. It was observed that the S-to-A mutation at position 3 drastically reduced the amount of 32P label incorporated into NP, whereas the other substitutions did not have a discernible effect on the phosphorylation level of the protein. In addition, all serine-altered proteins were tested for their functionality in an artificial system in which expression of a synthetic chloramphenicol acetyl-transferase RNA molecule is driven by influenza virus proteins synthesized from cloned genes. The results obtained demonstrate that all mutant proteins were competent to cooperate with the subunits of the viral polymerase for expression of the synthetic virus-like chloramphenicol acetyltransferase RNA in vivo. These data are discussed regarding the possible roles of NP phosphorylation for the viral replicative cycle.