Acidic phosphoproteins of the 60-S ribosomal subunits from HeLa cells

The highly conserved protein P0 carboxyl end is essential for ribosome activity only in the absence of proteins P1 and P2

Protein P0 together with proteins P1 and P2 form the stalk in eukaryotic ribosomes. P0 has a carboxyl-terminal domain about 100 amino acids long that has high sequence similar to the ribosomal proteins P1 and P2. By sequential deletion of this region, a series of Saccharomyces cerevisiae truncated P0 genes have been constructed that encode proteins lacking 21, 87, and 132 amino acids from the carboxyl terminus, respectively. These constructions have been used to transform yeast P0 conditional null mutants to test their capacity to restore cell growth. Removal of only the last 21 amino acids causes a small effect on cell growth in wild-type strains; however, this deletion is lethal in strains having P protein-deficient ribosomes. A P0 lacking 87 amino acids allows cell growth at a low rate, and ribosomes bind P proteins with much less affinity. Lastly, removal of 132 amino acids totally inactivates P0; this deleted protein is unable to bind to the particles, causing a deficiency in active 60 S subunits and making the cell nonviable. These results indicate that at least one out of the five protein P-like carboxyl termini present in the ribosome has to be firmly bound to the particle for protein synthesis and cell viability, and this structure can be provided by protein P0. The part of P0 from around positions 230-290 is important for the interaction of proteins P1/P2 with the ribosome, but it is not essential for protein synthesis. Finally, the region including from residues 185 to 230 is required for the interaction of P0 with the rRNA.

Human acidic ribosomal phosphoproteins P0, P1, and P2: analysis of cDNA clones, in vitro synthesis, and assembly

cDNA clones encoding three antigenically related human ribosomal phosphoproteins (P-proteins) P0, P1, and P2 were isolated and sequenced. P1 and P2 are analogous to Escherichia coli ribosomal protein L7/L12, and P0 is likely to be an analog of L10. The three proteins have a nearly identical carboxy-terminal 17-amino-acid sequence (KEESEESD(D/E)DMGFGLFD-COOH) that is the basis of their immunological cross-reactivity. The identities of the P1 and P2 cDNAs were confirmed by the strong similarities of their encoded amino acid sequences to published primary structures of the homologous rat, brine shrimp, and Saccharomyces cerevisiae proteins. The P0 cDNA was initially identified by translation of hybrid-selected mRNA and immunoprecipitation of the products. To demonstrate that the coding sequences are full length, the P0, P1, and P2 cDNAs were transcribed in vitro by bacteriophage T7 RNA polymerase and the resulting mRNAs were translated in vitro. The synthetic P0, P1, and P2 proteins were serologically and electrophoretically identical to P-proteins extracted from HeLa cells. These synthetic P-proteins were incorporated into 60S but not 40S ribosomes and also assembled into a complex similar to that described for E. coli L7/L12 and L10.

Human acidic ribosomal phosphoproteins P0, P1, and P2: analysis of cDNA clones, in vitro synthesis, and assembly

cDNA clones encoding three antigenically related human ribosomal phosphoproteins (P-proteins) P0, P1, and P2 were isolated and sequenced. P1 and P2 are analogous to Escherichia coli ribosomal protein L7/L12, and P0 is likely to be an analog of L10. The three proteins have a nearly identical carboxy-terminal 17-amino-acid sequence (KEESEESD(D/E)DMGFGLFD-COOH) that is the basis of their immunological cross-reactivity. The identities of the P1 and P2 cDNAs were confirmed by the strong similarities of their encoded amino acid sequences to published primary structures of the homologous rat, brine shrimp, and Saccharomyces cerevisiae proteins. The P0 cDNA was initially identified by translation of hybrid-selected mRNA and immunoprecipitation of the products. To demonstrate that the coding sequences are full length, the P0, P1, and P2 cDNAs were transcribed in vitro by bacteriophage T7 RNA polymerase and the resulting mRNAs were translated in vitro. The synthetic P0, P1, and P2 proteins were serologically and electrophoretically identical to P-proteins extracted from HeLa cells. These synthetic P-proteins were incorporated into 60S but not 40S ribosomes and also assembled into a complex similar to that described for E. coli L7/L12 and L10.

Identification and chemical synthesis of a ribosomal protein antigenic determinant in systemic lupus erythematosus

The characteristics of eukaryotic ribosomal proteins P0, P1, and P2 (P proteins) and their antigenic determinants were studied using the sera of patients with systemic lupus erythematosus (SLE). P0, P1, and P2 were isolated as a macromolecular complex by preparative isoelectric focusing and anion-exchange chromatography in the presence of 6 M urea. The apparent molecular size of the complex was 140 kDa as determined by gel filtration on a Sephadex G-200 column. P0 may, therefore, be the eukaryotic equivalent of Escherichia coli ribosomal protein L10. In addition, all three P proteins were detected in the postribosomal supernatant of HeLa cells, and P0 and P1 were found to be more acidic than their ribosome-bound counterparts. Partial proteolysis experiments revealed that SLE anti-P sera recognized one or both ends of the P2 equivalent protein from Artemia salina (eL12). Sixteen SLE sera containing antibodies to P0, P1, and P2 reacted with a carboxyl-terminal peptide 22 amino acids in length of eL12 and not with an amino-terminal peptide of 20 amino acids. Even though the carboxyl-terminal peptide completely inhibited the ability of the antiserum to react with all three proteins on an immunological blot, the same peptide produced only small decreases in binding of the SLE antibody to the native, nondenatured P proteins. These findings indicate that SLE anti-P antibodies react with a single sequential (linear) antigenic determinant on all three P proteins, but that additional antibodies recognize a conformational determinant(s).

Structural homology between Drosophila melanogaster and Escherichia coli acidic ribosomal proteins

Antibodies raised against Drosophila melanogaster ribosomal proteins (r-proteins) were used to examine possible structural relationships between eukaryotic and prokaryotic r-proteins. The antisera were raised against either groups of r-proteins or individually purified r-proteins. Two antisera showed a cross-reaction with total Escherichia coli r-proteins in Ouchterlony double immunodiffusion assays: an antiserum against the D. melanogaster small subunit protein S14 (anti-S14) and an antiserum against a group of D. melanogaster r-proteins (anti-TP80). The specificity of the antisera and the identity of the homologous E. coli r-proteins were characterized by using immunooverlay and immunoblot assays. These assays indicated that anti-S14 was highly specific for protein S14 and anti-TP80 was a multispecific serum that recognized several of the D. melanogaster ribosomal proteins. The E. coli protein homologous to D. melanogaster protein S14 was identified as E. coli protein S6. By adsorption of the anti-TP80 serum, we determined that D. melanogaster protein 7/8 is homologous to the acidic E. coli protein L7/L12. D. melanogaster acidic protein 13 was also shown to be immunologically related to D. melanogaster protein 7/8.

Acidic ribosomal proteins of Neurospora crassa

Neurospora crassa acidic ribosomal proteins from the high salt-ethanol extract of 80 S ribosomes have been fractionated by DEAE-cellulose chromatography. Six acidic ribosomal proteins were purified. All resemble Escherichia coli L7 and L12 in amino acid composition and molecular weight but each has a slightly different net charge at pH 3.2. Four have an apparent molecular weight of approx. 14 000, and two have a molecular weight of approx. 14 800. The amino acid compositions and circular dichroism (CD) spectra of the purified Neuropsora proteins are identical for the four 14 kDa proteins, but clearly distinguishable from the two 14.8 kDa proteins. The latter are also identical in amino acid composition and CD spectra. This suggests that there are two Neurospora acidic, or 'A', proteins, one of which exists in four microheterogeneous forms and the other exists in two forms.

Effects of adenovirus infection on rRNA synthesis and maturation in HeLa cells

The production of cytoplasmic and nucleolar rRNA species was examined in HeLa cells infected with high multiplicities of adenovirus type 5. Both 28S and 18S rRNA newly synthesized in infected cells ceased to enter the cytoplasm as reported previously (N. Ledinko, Virology 49: 79-89, 1972; H. J. Raskas, D. C. Thomas, and M. Green, Virology 40: 893-902, 1970). However, the effects on 28S cytoplasmic rRNA were observed considerably earlier in the infectious cycle than those on 18S rRNA. The inhibition of cellular protein synthesis and of the appearance in the cytoplasm of labeled cellular mRNA sequences (G. A. Beltz and S. J. Flint, J. Mol. Biol. 131: 353-373, 1979) were also monitored in infected cultures. During the later periods of an infectious cycle, from 18 h after infection, nucleolar rRNA synthesis and processing and exit of 18S rRNA from the nucleus were inhibited, probably reflecting the failure of infected cells to synthesize normal quantities of ribosomal proteins. The earliest responses of cellular RNA metabolism to adenovirus infection were, however, the rapid and apparently coordinate reductions in the levels of newly synthesized 28S rRNA and cellular mRNA sequences entering the cytoplasm.

Effects of adenovirus infection on rRNA synthesis and maturation in HeLa cells

The production of cytoplasmic and nucleolar rRNA species was examined in HeLa cells infected with high multiplicities of adenovirus type 5. Both 28S and 18S rRNA newly synthesized in infected cells ceased to enter the cytoplasm as reported previously (N. Ledinko, Virology 49: 79-89, 1972; H. J. Raskas, D. C. Thomas, and M. Green, Virology 40: 893-902, 1970). However, the effects on 28S cytoplasmic rRNA were observed considerably earlier in the infectious cycle than those on 18S rRNA. The inhibition of cellular protein synthesis and of the appearance in the cytoplasm of labeled cellular mRNA sequences (G. A. Beltz and S. J. Flint, J. Mol. Biol. 131: 353-373, 1979) were also monitored in infected cultures. During the later periods of an infectious cycle, from 18 h after infection, nucleolar rRNA synthesis and processing and exit of 18S rRNA from the nucleus were inhibited, probably reflecting the failure of infected cells to synthesize normal quantities of ribosomal proteins. The earliest responses of cellular RNA metabolism to adenovirus infection were, however, the rapid and apparently coordinate reductions in the levels of newly synthesized 28S rRNA and cellular mRNA sequences entering the cytoplasm.

Ribosomal acidic proteins of eucaryotic cells. Isolation of a protein from pea seedlings equivalent to E. coli L7/L12

By the method of ethanol-salt extraction with ion-exchange chromatography on CM-cellulose an acidic protein of pea 80S ribosomes was isolated. This protein located in the large subunit, had a molecular weight of 14 000 and an IEP of 4.7. The protein is partially phosphorylated, alanine-rich and has methionine at the N-terminal position. Based on these characteristics and on the comparative study of tryptic hydrolyzates of the plant protein and E. coli L7/L12, the protein so obtained is found to be homologous to the L7/L12 of the procaryotic ribosomes.

Ribosomal proteins of sea urchin eggs. I. Characterization of cytoplasmic ribosomal proteins

Ribosomal proteins from the eggs of sea urchin, Pseudocentrotus depressus, were analyzed by two-dimensional polyacrylamide gel electrophoresis (PAGE) and sodium dodecyl sulfate (SDS)-PAGE. Thirty different proteins including three acidic proteins were detected in the small subunit. The large subunit was found to contain at least 43 different proteins, 42 basic and one acidic. The ribosomal proteins from the small subunit have molecular weights ranging from 11,900 to 51,700 (average molecular weight: 25,600). The molecular weights of the large subunit proteins range from 12,700 to 76,300 (average molecular weight: 28,700).

The acidic proteins of eukaryotic ribosomes. A comparative study

The acidic proteins extracted by 0.4 M NH4Cl and 50% ethanol from ribosomes from Saccharomyces cerevisiae, wheat germ, Artemia salina, Drosophila melanogaster, rat liver and rabbit reticulocytes have been studied comparatively in several structural and functional aspects. All the species studied have in the ribosome two strongly acidic proteins with pI values not greater than pH 4.5., which appear to be monophosphorylated in the case of S. cerevisiae, A.Salina, D. melanogaster and wheat germ. Rat liver proteins are multiphosphorylated, as possibly are those from reticulocytes. The molecular weight of these acidic proteins as determined by SDS electrophoresis ranges from around 13,500 to 17,000 and, except in the case of yeast, of which both proteins have the same molecular weight, the size of the two proteins in the other species differs by approx. 1,000-2,000. In general, the size of the proteins increases with the evolutionary position of the organism, as seems to be the case with the degree of phosphorylation. From an immunological point of view the ribosomal acid proteins of eukaryotic cells are partically related, since antisera against yeast protein cross-react with proteins from wheat germ, rat liver and reticulocytes. Bacterial proteins L7 and L12 are very weakly recognized by the anti-yeast sera. Anti-bacterial acidic proteins do not cross-react with any of the protein from the species studied. The proteins from all the species studied are functional equivalents and can reconstitute the activity of particles of S. cerevisiae deprived of their acidic proteins.

Differences in the distribution of phosphate content in the ribosomal subunit proteins of free and membrane-bound ribosomes from normal and regenerating rat liver

Proteins of membrane-bound ribosomes from normal liver contained 60-70% more phosphate than did proteins from free ribosomes. This difference was not a reflection of the phosphate contents of respective 40 S subunits. Instead, it was owing to the presence of high levels of phosphorylated proteins in the 60 S subunits, i.e., phosphate contents equal to or greater than those for 40 S subunits. The proteins of membrane-bound 60 S subunits contained twice the phosphate as free 60 S subunits. In regenerating rat liver, membrane-bound ribosomes had increased phosphate in the proteins of the 40 S subunits and decreased phosphate in proteins of the 60 S subunit when compared to controls for normal rat liver. No significant changes occurred in the proteins of free ribosomes from regenerating rat liver. These findings are discussed with respect to (a) the importance of assessing total phosphate contents of proteins in the study of ribosomal protein phosphorylation, and (b) the possible involvement of ribosomal protein phosphorylation in the segregation of ribosomes into free and membrane-bound populations and the regulation of these distributions to meet changes in the translational demands of the cell.

Turnover rates of phosphoryl groups in ribosomal proteins of Physarum polycephalum. Evidence for two different mechanisms

The rate of phosphate exchange in individual ribosomal proteins of Physarum polycephalum was determined in vivo. It was observed that the phosphoryl groups of S3, the major phosphoprotein, had a turnover rate of 1.5% per minute. The phosphoryl groups of proteins L1, L20 and L24 were stable. These results show that the phosphorylation of ribosomal proteins is regulated by at least two different mechanisms. The rapid turnover of phosphoryl groups of the major phosphoprotein is in agreement with the general observation that the phosphate content of this protein is modulated by the physiological state of the cells and possibly involved in the regulation of ribosome activity. The absence of phosphate exchange in acidic proteins suggests that these groups could play a structural role in the ribosome functions.

Effect of phosphorylation on the affinity of acidic proteins from Saccharomyces cerevisiae for the ribosomes

Electrofocusing of the acidic proteins extracted from Saccharomyces cerevisiae ribosomes shows the presence of eight bands in the gels, which upon treatment with alkaline phosphatase are reduced to three. Two of them, proteins L44 and L45, correspond to the proteins equivalent to the bacterial L7 and L12 and the third, protein Ax, behaves like a supernatant factor. In the ribosome, proteins L44 and L45 are found unphosphorylated and monophosphorylated while protein Ax is detected mostly in a modified state, showing from one to three phosphate groups per molecule. In the cytoplasm where protein Ax is abundant and proteins L44 and L45 are present in small quantities, the three proteins are unphosphorylated. Protein Ax, having one or two phosphate groups, can be removed from the ribosomes in conditions that release the initiation factors, while the triphosphorylated molecules are tightly bound to the particles. The data indicate a relationship between the degree of phosphorylation of protein Az and its affinity for the ribosome.

Acidic ribosomal proteins from eukaryotic cells. Effect on ribosomal functions

Precipitation of Saccharomyces cerevisiae ribosomes by ethanol under experimental conditions that do not release the ribosomal proteins can affect the activity of the particles. In the presence of 0.4 M NH4Cl and 50% ethanol only the most acidic proteins from yeast and rat liver ribosomes are released. At 1 M NH4Cl two more non-acidic proteins are lost from the ribosomes. The release of the acidic proteins causes a small inactivation of the polymerizing activity of the particles, additional to that caused by the precipitation itself. The elongation-factor-2-dependent GTP hydrolysis of the ribosomes is, however, more affected by the loss of acidic proteins. These proteins can stimulate the GTPase but not the polymerising activity when added back to the treated particles. Eukaryotic proteins cannot be substituted for bacterial acidic proteins L7 and L12. We have not detected immunological cross-reaction between acidic proteins from Escherichia coli and those from yeast, Artemia salina and rat liver or between acidic proteins from these eukaryotic ribosomes among themselves.

Ribosomal proteins in growing and starved Tetrahymena pyriformis. Starvation-induced phosphorylation of ribosomal proteins

The complements of ribosomal proteins in growing and starved cells of Tetrahymena pyriformis strain GL were examined by two-dimensional gel electrophoresis. In growing cells, the 40-S ribosomal subunit contained 30 proteins, 4 of which migrated toward the anode at pH 8.6, while the 60-S ribosomal subunit contained 46 proteins, 9 of which migrated toward the anode at pH 8.6. When exponentially growing cells were transferred into a non-nutrient medium pronounced phosphorylation of a single 40-S ribosomal subunit protein, S6, was induced. The phosphorylation was very specific; more than 99.5% of the [32P]phosphate incorporated into ribosomal proteins was associated with S6. Phosphate was incorporated into S6 as O-phosphoserine and O-phosphothreonine. Two-dimensional gel electrophoresis indicated that the complement of proteins associated with the ribosomes isolated from starved cells differed from that of growing cells. Careful examination, however, suggested that except for the phosphorylation of certain ribosomal proteins in starved cells, the observed differences did not reflect starvation-induced changes in vivo, but most probably different levels of artifactual modifications (limited proteolysis) during the preparation of the ribosomes.

Isolation and characterization of the acidic phosphoproteins of 60-S ribosomes from Artemia salina and rat liver

Eucaryotic L7/L12-type proteins are present in ethanol/salt extracts (P1 protein) of ribosomes from Artemia salina and rat liver. These proteins are partially phosphorylated and occur in two forms of closely related structure: a major form eL12 having methionine at the N-terminal position and a minor form of eL12 (eL12') which seems slightly elongated and contains a blocked N terminus. Purification of the four different forms of this protein, eL12, eL12-P, eL12' and eL12'-P, was performed by ion-exchange chromatography on carboxymethyl-cellulose and DEAE-cellulose. Using a radioimmuno assay, 1.8 copies of eL12 and 0.9 of eL12' were found on the 80-S A. salina ribosome. In ribosomes of both rat liver and A. salina, eL12 is present in a larger quantity than eL12'. 40-S and 60-S ribosomal subunits extracted with ethanol/salt were essentially free of eL12 proteins. A large pool of eL12 was found in the cytosol after removal of the ribosomes by centrifugation or molecular sieving. The proteins of rat liver and A. salina are similar with regard to their isoelectric points and molecular weights. Sedimentation equilibrium studies indicated that the isolated protein eL12 occurs as a dimer.

Identification and characterization of ribosomal proteins phosphorylated in vaccinia-virus-infected HeLa cells

Two-dimensional analysis of 32P-labelled ribosomal proteins revealed three proteins which are phosphorylated in vaccinia-virus-infected HeLa cells. All three proteins belong to the 40-S ribosomal subunits and were identified as S2, S6 and S16. The ribosomal protein S6 is phosphorylated also in uninfected HeLa cells. Phosphoserine was detected in all three proteins, phosphothreonine only in the protein S2. Phosphorylation of these ribosomal proteins in infected cells is dependent on the multiplicity of the viral infection and increases during the first six hours of infection. All three proteins are also phosphorylated in virus-infected cells treated with cycloheximide and in cells infected with ultraviolet-irradiated virus. This suggests that the phosphorylation reaction involves a vaccinia virion-associated protein kinase.

Occurrence of phosphorylated forms of an acidic protein in the large ribosomal subunit of rat liver

An acidic protein from rat liver 60-S ribosomal subunits was selectively extracted with 50% ethanol. It was revealed as three different spots by two-dimensional gel electrophoresis, two of them being attributable to phosphorylated forms since they disappeared after alkaline phosphatase treatment. The relationship between this protein and similar acidic proteins found in eucaryotic cells is discussed.

Ribosomal proteins of HeLa cells

Ribosomal proteins from HeLa cells were analyzed by two-dimensional polyacrylamide gel electrophoresis (Kaltschmidt-Wittmann) and dodecylsulfate polyacrylamide gel electrophoresis (Laemmli). 35 proteins are associated with the small ribosomal subunit and 47 proteins with the large ribosomal subunit. The HeLa ribosomal proteins S6, S32, L40b,c, L41 and L42 are phosphorylated in vivo and in vitro. Minor differences between HeLa and rat liver ribosomal proteins were revealed by their direct coelectrophoresis.