Influence of the state of ribosome association on the phosphorylation of ribosomal proteins in isolated ribosome--protein kinase systems from rat cerebral cortex.

Ribosomal protein phosphorylation was investigated in isolated ribosomal subunits and polyribosomes from rat cerebral cortex in the presence of [gamma-32P]ATP and purified catalytic subunit of cyclic AMP-dependent protein kinase from the same tissue. Ribosomal proteins that were most readily phosphorylated in isolated cerebral ribosomal subunits included proteins S2, S3a, S6 and S10 of the 40 S subunit and proteins L6, L13, L14, L19 and L29 of the 60 S subunit. These proteins were also phosphorylated in cellular preparations of rat cerebral cortex in situ or in vitro [Roberts & Ashby (1978) J. Biol. Chem. 253, 288-296; Roberts & Morelos (1979) Biochem. J. 184, 233-244]. However, several additional ribosomal proteins were phosphorylated when isolated 40 S or 60 S subunits were separately incubated in the reconstituted system. Analogous results were obtained with an equimolar mixture of cerebral 40 S and 60 S subunits under comparable conditions. In contrast, extensive exposure of purified cerebral polyribosomes to the catalytic subunit resulted in phosphorylation of only those ribosomal proteins of the 40 S subunit that were most highly labelled after the administration of [32P]Pi in vivo: proteins S2, S6 and S10. Ribosomal proteins of 60 S subunits that were readily phosphorylated in isolated cerebral polyribosomes included proteins L6, L13 and L29. These results indicate that polyribosome formation markedly decreases the number of ribosomal protein sites available for phosphorylation by the catalytic subunit of cyclic AMP-dependent protein kinase. Moreover, the findings suggest that, of the ribosomal protein phosphorylations observed in rat cerebral cortex in vivo, proteins S2, S6, S10, L6, L13 and L29 can be phosphorylated in polyribosomes, whereas proteins S3a, S5, L14 and L19 may become phosphorylated only in free ribosomal subunits.     

Phosphorylation in vitro and in vivo of ribosomal proteins from Saccharomyces cerevisia.

Crude ribosomes from Saccharomyces cerevisiae cultures were phosphorylated in vitro when incubated in the presence of [gamma-32P]ATP. Analysis of the ribosomal proteins with two-dimensional electrophoresis revealed that of the 29 proteins identified in the small subunit, only protein S6 was phosphorylated. Of the 37 proteins identified in the large subunit, one was highly phosphorylated (L3) and two only slightly phosphorylated (L11 and L14). The protein kinase activity associated with the ribosomes was extracted with 1 M KCl and was not dependent on adenosine 3':5'-monophosphate; it preferentially phosphorylated casein and phosvitin, but was less active on histones. Structural ribosomal proteins were also phosphorylated in vivo when the yeast cultures were incubated with [32P]orthophosphate; the radioactivity resistant to hydrolysis by hot perchloric acid was incorporated into the proteins of the two subunits. Radioactive phosphoserine was found by subjecting hydrolysates of ribosomal proteins to high-voltage electrophoresis. After two-dimensional electrophoresis, one poorly phosphorylated protein (S10) was identified in the small subunit. In the large subunit, one protein (L3) was highly labelled, and two proteins (L11 and L24) only slightly labelled.     

Changes in the reactivity of proteins of rat liver ribosomes against [C]iodoacetamide depending on their organization in ribosomal subparticles, 80S ribosomes and on the attachment of poly-(U)

(1) The isolated mixtures of ribosomal proteins can be substituted by [¹⁴C]-iodoacetamide up to an average of about 2 equivalents per 20 000 dalton. The extent of substitution of single proteins measured after two-dimensional polyacrylamide gel electrophoresis shows that all proteins are reactive.

(2) Also in the subunits, all proteins are accessible to substitution. Compared with isolated proteins, however, the reactivity is decreased and the amount of labelling for most proteins ranges as low as 5 to 20%.

(3) Reassociation of ribosomal subunits decreases the reactivity of 12 proteins of the small subunit and that of 20 proteins of the large subunit.

(4) The presence of messenger inhibits the substitution of 10 proteins of the small subunit and of 6 proteins of the large one.

(5) Seven proteins of the small subunit and 3 proteins of the large one are influenced both by the other subunit and by messenger-RNA.     

Isolation and characterization of temperature-sensitive mutants of Escherichia coli with altered ribosomal proteins

Summary The ribosomal proteins of temperature-sensitive mutants of Escherichia coli isolated independently after mutagenesis with nitrosoguanidine were analyzed by two-dimensional gel electrophoresis. Out of 400 mutants analyzed, 60 mutants (15%) showed alterations in a total of 22 different ribosomal proteins. The proteins altered in these mutants are S2, S4, S6, S7, S8, S10, S15, S16, S18, L1, L3, L6, L10, L11, L14, L15, L17, L18, L19, L22, L23 and L24. A large number of them (25 mutants) have mutations in protein S4 of the small subunit, while four mutants showed alterations in protein L6 of the large subunit. The importance of these mutants for structural and functional analyses of ribosomes is discussed.     

Molecular weight hetergeneity of proteins of the ribosomes and ribosomal subunits from dry pea seeds]

The molecular weight distribution of the total protein of ribosomes and ribosomal subunits isolated from dry pea seeds was studied by electrophoresis in polyacrylamide gel, containing sodium dodecyl sulfate. It was demonstrated that overall protein of 80 S ribosomes is separated into a number of fractions with molecular weights of 10000-64000. Treatment of ribosomes with 0.5 per cent tritone, 0.5 per cent and 1 per cent deoxycholate does not change the general pattern of the molecular weight distribution of ribosomal proteins. The large subunit reveals 19 protein zones (14 major and 5 minor zones), their molecular weights are varying from 10000 to 54000. The majority of proteins of the large subunit have molecular weights of 14000--32000. The molecular weights of 17 protein zones of the small subunit (7 major and 10 minor zones) vary from 10000 to 64000. The majority of proteins of both large and small subunits have molecular weights of 14000--32000. Electrophoretic separation of proteins in the split gel confirmed the fact that the proteins of large subunit differ in molecular weights from those of the small subunit. Thus, ribosomal proteins of pea seeds are shown to produce a typical (for 80S ribosomes) pattern of molecular weight distribution under polyacrylamide gel electrophoresis in the presence of sodium dodecul sulphate.     

Influence of magnesium and polyamines on the reactivity of individual ribosomal subunit proteins to lactoperoxidase-catalyzed iodination.

30S and 50S subunits, in the presence of either 20 mM Mg2+ or 6 mM Mg2+ and 5mM spermidine plus 25 mM putrescine, were observed to completely associate to form 70S monosomes as monitored by sucrose gradient sedimentation. Subunits maintained under the above ionic conditions were compared with 30S and 50S particles at low (6 mM) magnesium concentration with respect to the reactivity of individual ribosomal proteins to lactoperoxidase-catalyzed iodination. Altered reactivity to enzymatic iodination of ribosomal proteins S4, S9, S10, S14, S17, S19, and S20 in the small subunit of ribosomal proteins, L2, L9, L11, L27, and L30 in the large subunit following incubation with high magnesium or magnesium and polyamines suggests that a conformation change in both subunits accompanies the formation of 70S monosomes. The results further demonstrate that the effect of Mg2+ on subunit conformation is mimicked when polyamines are substituted for magnesium necessary for subunit association.     

Ribosomal RNA synthesis in mitochondria of Neurospora crassa

Ribosomal RNA synthesis in Neurospora crassa mitochondria has been investigated by continuous labeling with [5-³H]uracil and pulse-chase experiments. A short-lived 32 S mitochondrial RNA was detected, along with two other short-lived components; one slightly larger than large subunit ribosomal RNA, and the other slightly larger than small subunit ribosomal RNA. The experiments give support to the possibility that 32 S RNA is the precursor of large and small subunit ribosomal RNA's. Both mature ribosomal RNA's compete with 32 S RNA in hybridization to mitochondrial DNA. Quantitative results from such hybridization-competition experiments along with measurements of electrophoretic mobility have been used to construct a molecular size model for synthesis of mitochondrial ribosomal RNA's. The large molecular weight precursor (32 S) of both ribosomal RNA's appears to be 2.4 × 10⁶ daltons in size. Maturation to large subunit RNA (1.28 × 10⁶ daltons) is assumed to involve an intermediate ~1.6 × 10⁶ daltons in size, while cleavage to form small subunit RNA (0.72 × 10⁶ daltons) presumably involves a 0.9 × 10⁶ dalton intermediate. In the maturation process ~22% of the precursor molecule is lost. As is the case for ribosomal RNA's, the mitochondrial precursor RNA has a strikingly low G + C content.     

Phosphorylation of ribosomal proteins induced by auxins in maize embryonic tissues

The effect of auxin on ribosomal protein phosphorylation of germinating maize (Zea mays) tissues was investigated. Two-dimensional gel electrophoresis and autoradiography of [³²P] ribosomal protein patterns for natural and synthetic auxin-treated tissues were performed. Both the rate of ³²P incorporation and the electrophoretic patterns were dependent on ³²P pulse length, suggesting that active protein phosphorylation-dephosphorylation occurred in small and large subunit proteins, in control as well as in auxin-treated tissues. The effect of ribosomal protein phosphorylation on in vitro translation was tested. Measurements of poly(U) translation rates as a function of ribosome concentration provided apparent K_m values significantly different for auxin-treated and nontreated tissues. These findings suggest that auxin might exert some kind of translational control by regulating the phosphorylated status of ribosomal proteins.     

Binding of protein synthesis initiation factor IF1 to 30 S ribosomal subunits: effects of other initiation factors and identification of proteins near the binding site.

The effects of other components of the initiation complex on Escherichia coli initiation factor IFI binding to 30 S ribosomal subunits were studied. Binding of [¹⁴C]IF1 in the absence of other initiation complex components was slight. Addition of either IF2 or IF3 stimulated binding to a variable extent. Maximum binding was observed when both IF2 and IF3 were present. Addition of GTP, fMet-tRNA, and phage R17 RNA caused little or no further stimulation of [¹⁴C]IF1 binding. A maximum of 0.5 molecule of [¹⁴C]IF1 bound per 30 S subunit in the presence of an excess of each of the three factors over 30 S subunits.Complexes of 30 S subunits, [¹⁴C]IF1, IF2, and IF3 were treated with the bifunctional protein cross-linking reagent dimethyl suberimidate in order to identify the ribosomal proteins near the binding site for IF1. Non-cross-linked [¹⁴C]IF1 was removed from the complexes by sedimentation through buffer containing a high salt concentration, and total protein was extracted from the pelleted particles. Approximately 12% of the [¹⁴C]IF1 was recovered in the pellet fraction. The mixture of cross-linked products was analyzed by polyacrylamide/sodium dodecyl sulfate gel electrophoresis. Autoradiography of the gel showed radioactive bands with molecular weights of 21,000, 25,000, and many greater than 120,000. The results indicate that [¹⁴C]IF1 was cross-linked directly to at least two ribosomal proteins. Analysis of the cross-linked mixture by radioimmunodiffusion with specific antisera prepared against each of the 30 S ribosomal proteins showed radioactivity in the precipitin bands formed with antisera against S12 and S19, and in lower yield with those against S1 and S13. Antiserum against IF2 also showed [¹⁴C]IF1 in the precipitin band. The results show that [¹⁴C]IF1 was present in covalently cross-linked complexes containing 30 S ribosomal proteins S1, S12, S13 and S19, and initiation factor IF2. The same ribosomal proteins have been implicated in the binding sites for IF2 and IF3. The results suggest that the three initiation factors bind to the 30 S subunit at the same or overlapping sites.     

Comparison of phosphorylation of ribosomal proteins from HeLa and Krebs II ascites-tumour cells by cyclic AMP-dependent and cyclic GMP-dependent protein kinases.

Phosphorylation of eukaryotic ribosomal proteins in vitro by essentially homogeneous preparations of cyclic AMP-dependent protein kinase catalytic subunit and cyclic GMP-dependent protein kinase was compared. Each protein kinase was added at a concentration of 30nM. Ribosomal proteins were identified by two-dimensional gel electrophoresis. Almost identical results were obtained when ribosomal subunits from HeLa or ascites-tumour cells were used. About 50-60% of the total radioactive phosphate incorporated into small-subunit ribosomal proteins by either kinase was associated with protein S6. In 90 min between 0.7 and 1.0 mol of phosphate/mol of protein S6 was incorporated by the catalytic subunit of cyclic AMP-dependent protein kinase. Of the other proteins, S3 and S7 from the small subunit and proteins L6, L18, L19 and L35 from the large subunit were predominantly phosphorylated by the cyclic AMP-dependent enzyme. Between 0.1 and 0.2 mol of phosphate was incorporated/mol of these phosphorylated proteins. With the exception of protein S7, the same proteins were also major substrates for the cyclic GMP-dependent protein kinase. Time courses of the phosphorylation of individual proteins from the small and large ribosomal subunits in the presence of either protein kinase suggested four types of phosphorylation reactions: (1) proteins S2, S10 and L5 were preferably phosphorylated by the cyclic GMP-dependent protein kinase; (2) proteins S3 and L6 were phosphorylated at very similar rates by either kinase; (3) proteins S7 and L29 were almost exclusively phosphorylated by the cyclic AMP-dependent protein kinase; (4) protein S6 and most of the other proteins were phosphorylated about two or three times faster by the cyclic AMP-dependent than by the cyclic GMP-dependent enzyme.     

Proteins of animal ribosomes. XXV. Proteins of rat liver ribosomes protected by polyuridylic acid from methyl acetimidate substitution.

Addition of poly(U) to complexes of 40S and 60S subunits of rat liver ribosomes decreases the substitution of amino groups of 12 proteins of the small ribosomal subunit and of 11 proteins of the large subunit by [14C]-methyl acetimidate. When comparing the results obtained with this amino group specific reagent with the reactivity of the proteins against iodoacetamide it becomes obvious that 4 proteins of the small ribosomal subunit (S12, 18, 19, 24) and 3 proteins of the large one (L20, 22, 25) are partially protected by poly(U) against reaction with both reagents.     

Contacts between mammalian mitochondrial translational initiation factor 3 and ribosomal proteins in the small subunit

Mammalian mitochondrial translational initiation factor 3 (IF3(mt)) binds to the small subunit of the ribosome displacing the large subunit during the initiation of protein biosynthesis. About half of the proteins in mitochondrial ribosomes have homologs in bacteria while the remainder are unique to the mitochondrion. To obtain information on the ribosomal proteins located near the IF3(mt) binding site, cross-linking studies were carried out followed by identification of the cross-linked proteins by mass spectrometry. IF3(mt) cross-links to mammalian mitochondrial homologs of the bacterial ribosomal proteins S5, S9, S10, and S18-2 and to unique mitochondrial ribosomal proteins MRPS29, MRPS32, MRPS36 and PTCD3 (Pet309) which has now been identified as a small subunit ribosomal protein. IF3(mt) has extensions on both the N- and C-termini compared to the bacterial factors. Cross-linking of a truncated derivative lacking these extensions gives the same hits as the full length IF3(mt) except that no cross-links were observed to MRPS36. IF3 consists of two domains separated by a flexible linker. Cross-linking of the isolated N- and C-domains was observed to a range of ribosomal proteins particularly with the C-domain carrying the linker which showed significant cross-linking to several ribosomal proteins not found in prokaryotes.     

Immunological similarities between specific chloroplast ribosomal proteins from Chlamydomonas reinhardtii and ribosomal proteins from Escherichia coli

Polyclonal antibodies were elicited against seven of the 33 different proteins of the large subunit of the chloroplast ribosome from Chlamydomonas reinhardtii. Three of these proteins are synthesized in the chloroplast and four are made in the cytoplasm and imported. In western blots, six of the seven antisera are monospecific for their respective large subunit ribosomal proteins, and none of these antisera cross-reacted with any chloroplast small subunit proteins from C. reinhardtii. Antisera to the three chloroplast-synthesized ribosomal proteins cross-reacted with specific Escherichia coli large subunit proteins of comparable charge and molecular weight. Only one of the four antisera to the chloroplast ribosomal proteins synthesized in the cytoplasm cross-reacted with an E. coli large subunit protein. None of the antisera cross-reacted with any E. coli small subunit proteins. On the assumption of a procaryotic, endosymbiotic origin for the chloroplast, those chloroplast ribosomal proteins still synthesized within the organelle appear to have retained more antigenic sites in common with E. coli ribosomal proteins than have those which are now the products of cytoplasmic protein synthesis. Antisera to this cytoplasmically synthesized group of chloroplast ribosomal proteins did not recognize any antigenic sites among C. reinhardtii cytoplasmic ribosomal proteins, suggesting that the genes for the cytoplasmically synthesized chloroplast ribosomal proteins either are not derived from the cytoplasmic ribosomal protein genes or have evolved to a point where no antigenic similarities remain.      

Subcellular distribution of ribosomal proteins in Dictyostelium discoideum

The distribution of ribosomal proteins in monosomes, polysomes, the postribosomal cytosol, and the nucleus was determined during steady-state growth in vegetative amoebae. A partitioning of previously reported cell-specific ribosomal proteins between monosomes and polysomes was observed. L18, one of the two unique proteins in amoeba ribosomes, was distributed equally among monosomes and polysomes. However S5, the other unique protein, was abundant in monosomes but barely visible in polysomes. Of the developmentally regulated proteins, D and S6 were detectable only in polysomes and S14 was more abundant in monosomes. The cytosol revealed no ribosomal proteins. On staining of the nuclear proteins with Coomassie blue, about 18, 7 from 40S subunit and 11 from 60S subunit, were identified as ribosomal proteins. By in vivo labeling of the proteins with [35S]methionine, 24 of the 34 small subunit proteins and 33 of the 42 large subunit proteins were localized in the nucleus. For the majority of the ribosomal proteins, the apparent relative stoichiometry was similar in nuclear preribosomal particles and in cytoplasmic ribosomes. However, in preribosomal particles the relative amount of four proteins (S11, S30, L7, and L10) was two- to four-fold higher and of eight proteins (S14, S15, S20, S34, L12, L27, L34, and L42) was two-to four-fold lower than that of cytoplasmic ribosomes.     

Yeast ribosomal proteins: V. Correlation of several nomenclatures and proposal of a standard nomenclature

Summary A tentative nomenclature (YP number) for yeast (Saccharomyces cerevisiae) cytoplasmic ribosomal proteins, which is used in our laboratory (Otaka and Kobata 1978; Higo and Otaka 1979), has been correlated with those of Warner and Gorenstein (1978) and several others. Our nomenclature is based on the two-dimensional gel electrophoretic pattern of proteins as analyzed by a modified method of Mets and Bogorad (1974), while others have used various modifications of Kaltschmidt and Wittmann's two-dimensional gel electrophoresis (1970). The method of correlation involved the examination in our twodimensional electrophoresis system of each protein spot excised from gel patterns prepared by Kaltschmidt and Wittmann's method or vice versa.The numbers of protein species recognized in this paper are 29 for small subunit, and 44 for large subunit. Based on these results, we propose a standard nomenclature for yeast ribosomal proteins, in which the designations YS1–YS29 and YL1–YL44 have been given to the small subunit proteins and the large subunit proteins respectively.     

Accessibility of proteins in 50S ribosomal subunits of Escherichia coli to antibodies: an ultracentrifugation study.

Summary The accessibility of each of the proteins on the 50S ribosomal subunit of Escherichia coli was investigated by establishing whether immunoglobulins (IgG), specific for each of the 34 proteins from the 50S subunit, were able to bind to the 50S subunit. The main criterion for accessibility was the formation of specific antibody-50S subunit complexes that could be detected by means of analytical ultracentrifugation.The proteins fell into two main groups. Immunoglobulins against proteins L1, L2, L3, L4, L5, L6, L7/L12, L8, L9, L10, L11, L14, L15, L16, L17, L18, L19, L20, L21, L22, L23, L25, L26, L27 and L30 gave large amounts of complex (20–100%) and, therefore, these proteins were considered to be accessible sible on the surface of the 50S ribosomal subunit. The antibodies against the remaining proteins L13, L24, L28, L29 and L31 to L34 produced small amounts of complexes (10–20%). Since their effects were unequivocably stronger than those obtained with IgG's from sera of non-immunized animals, the results indicate that these proteins are probably also accessible. Nonetheless, from the ultracentrifugation studies alone definite conclusions about the exposure of the latter group of proteins could not be drawn.     

MRPS27 is a pentatricopeptide repeat domain protein required for the translation of mitochondrially encoded proteins

Mammalian pentatricopeptide repeat domain (PPR) proteins are involved in regulation of mitochondrial RNA metabolism and translation and are required for mitochondrial function. We investigated an uncharacterised PPR protein, the supernumerary mitochondrial ribosomal protein of the small subunit 27 (MRPS27), and show that it associates with the 12S rRNA and tRNA^Glu, however it does not affect their abundance. We found that MRPS27 is not required for mitochondrial RNA processing or the stability of the small ribosomal subunit. However, MRPS27 is required for mitochondrial protein synthesis and its knockdown causes decreased abundance in respiratory complexes and cytochrome c oxidase activity.

Structured summary of protein interactions

MRPS27 and MRPS15 colocalize by cosedimentation through density gradient (View Interaction)     

The mitochondrial ribosomes of Neurospora crassa. II. Comparison of the proteins from Neurospora crassa mitochondrial ribosomes with ribosomal proteins from Neurospora cytoplasm, from rat liver mitochondria and from bacteria.

1. It has been shown by Datema et al. (Datema, R., Agsteribbe, E. and Kroon, A.M. (1974) Biochim. Biophys. Acta 335, 386--395) that Neurospora mitochondria isolated in a Mg2+-containing medium (or after homogenization of the mycelium in this medium and subsequent washing of the mitochondria in EDTA-containing medium) possess 80-S ribosomes; mitochondria homogenized and isolated in EDTA medium yield 73-S ribosomes. The ribosomal proteins of the subunits of 80-S and 73-S ribosomes were compared by two-dimensional electrophoresis. The protein patterns of the large, as well as of the small subunits are very similar but not completely identical; the most conspicuous difference is that the large subunit of 80 S contains about eight more proteins than the large subunit of 73 S. 2. The contamination by Neurospora cytoplasmic 77-S ribosomes in the 80-S preparations, if present, is only minor. 3. Neurospora cytoplasmic ribosomes contain 31 proteins in the large, and 21 proteins in the small subunit. 4. Neurospora 80- mitochondrial ribosomes contain 39 proteins in the large, and 30 proteins in the small subunit 30 proteins. 5. Rat liver mitochondrial ribosomes contain 40 proteins in the large and at least 30 proteins in the small subunit. About 50% of these proteins has an isoelectric point below pH 8.6. 6. The pattern of Paracoccus denitrificans is very similar to that of other bacterial ribosomes, the large subunit contains 29, the small subunit 18 proteins.     

Sites of synthesis of chloroplast ribosomal proteins in Chlamydomonas

Cells of Chlamydomonas reinhardtii were pulse-labeled in vivo in the presence of inhibitors of cytoplasmic (anisomycin) or chloroplast (lincomycin) protein synthesis to ascertain the sites of synthesis of chloroplast ribosomal proteins. Fluorographs of the labeled proteins, resolved on two-dimensional (2-D) charge/SDS and one-dimensional (1-D) SDS-urea gradient gels, demonstrated that five to six of the large subunit proteins are products of chloroplast protein synthesis while 26 to 27 of the large subunit proteins are synthesized on cytoplasmic ribosomes. Similarly, 14 of 31 small subunit proteins are products of chloroplast protein synthesis, while the remainder are synthesized in the cytoplasm. The 20 ribosomal proteins shown to be made in the chloroplast of Chlamydomonas more than double the number of proteins known to be synthesized in the chloroplast of this alga.     

Further temperature-sensitive mutants of Escherichia coli with altered ribosomal proteins.

Summary Various alterations in ribosomal proteins were detected in forty-one mutants ofE. coli isolated as temperature-sensitive mutants. Out of these, six are new classes of mutants harboring mutations in proteins S3, L5, L7 (L12), L29, L30 and L33. One of them apparently lacks protein L7 of the large subunit. These mutants together with those reported previously (Isono et al., 1976) total one hundred and one ribosomal mutants in thirty different proteins.