Disruption of single-copy genes encoding acidic ribosomal proteins in Saccharomyces cerevisiae.

Using the cloned genes coding for the ribosomal acidic proteins L44 and L45, constructions were made which deleted part of the coding sequence and inserted a DNA fragment at that site carrying either the URA3 or HIS3 gene. By gene disruption techniques with linearized DNA from these constructions, strains of Saccharomyces cerevisiae were obtained which lacked a functional gene for either protein L44 or protein L45. The disrupted genes in the transformants were characterized by Southern blots. The absence of the proteins was verified by electrofocusing and immunological techniques, but a compensating increase of the other acidic ribosomal proteins was not detected. The mutant lacking L44 grew at a rate identical to the parental strain in complex as well as in minimal medium. The L45-disrupted strain also grew well in both media but at a slower rate than the parental culture. A diploid strain was obtained by crossing both transformants, and by tetrad analysis it was shown that the double transformant lacking both genes is not viable. These results indicated that proteins L44 and L45 are independently dispensable for cell growth and that the ribosome is functional in the absence of either of them.

Ribosomal acidic phosphoproteins P1 and P2 are not required for cell viability but regulate the pattern of protein expression in Saccharomyces cerevisiae.

Saccharomyces cerevisiae strains with either three inactivated genes (triple disruptants) or four inactivated genes (quadruple disruptants) encoding the four acidic ribosomal phosphoproteins, YP1 alpha, YP1 beta, YP2 alpha, and YP2 beta, present in this species have been obtained. Ribosomes from the triple disruptants and, obviously, those from the quadruple strain do not have bound P proteins. All disrupted strains are viable; however, they show a cold-sensitive phenotype, growing very poorly at 23 degrees C. Cell extracts from the quadruple-disruptant strain are about 30% as active as the control in protein synthesis assays and are stimulated by the addition of free acidic P proteins. Strains lacking acidic proteins do not have a higher suppressor activity than the parental strains, and cell extracts derived from the quadruple disruptant do not show a higher degree of misreading, indicating that the absence of acidic proteins does not affect the accuracy of the ribosomes. However, the patterns of protein expressed in the cells as well as in the cell-free protein system are affected by the absence of P proteins from the particles; a wild-type pattern is restored upon addition of exogenous P proteins to the cell extract. In addition, strains carrying P-protein-deficient ribosomes are unable to sporulate but recover this capacity upon transformation with one of the missing genes. These results indicate that acidic proteins are not an absolute requirement for protein synthesis but regulate the activity of the 60S subunit, affecting the translation of certain mRNAs differently.

Conformational changes induced in the Saccharomyces cerevisiae GTPase-associated rRNA by ribosomal stalk components and a translocation inhibitor.

The yeast ribosomal GTPase associated center is made of parts of the 26S rRNA domains II and VI, and a number of proteins including P0, P1alpha, P1beta, P2alpha, P2beta and L12. Mapping of the rRNA neighborhood of the proteins was performed by footprinting in ribosomes from yeast strains lacking different GTPase components. The absence of protein P0 dramatically increases the sensitivity of the defective ribosome to degradation hampering the RNA footprinting. In ribosomes lacking the P1/P2 complex, protection of a number of nucleotides is detected around positions 840, 880, 1100, 1220-1280 and 1350 in domain II as well as in several positions in the domain VI alpha-sarcin region. The protection pattern resembles the one reported for the interaction of elongation factors in bacterial systems. The results exclude a direct interaction of these proteins with the rRNA and are compatible with an increase in the ribosome affinity for EF-2 in the absence of the acidic P proteins. Interestingly, a sordarin derivative inhibitor of EF-2 causes an opposite effect, increasing the reactivity in positions protected by the absence of P1/P2. Similarly, a deficiency in protein L12 exposes nucleotides G1235, G1242, A1262, A1269, A1270 and A1272 to chemical modification, thus situating the protein binding site in the most conserved part of the 26S rRNA, equivalent to the bacterial protein L11 binding site.

The ribosomal P-proteins of the medfly Ceratitis capitata form a heterogeneous stalk structure interacting with the endogenous P-proteins, in conditional P0-null strains of the yeast Saccharomyces cerevisiae.

The genes encoding the ribosomal P-proteins CcP0, CcP1 and CcP2 of Ceratitis capitata were expressed in the conditional P0-null strains W303dGP0 and D67dGP0 of Saccharomyces cerevisiae, the ribosomes of which contain either standard amounts or are totally deprived of the P1/P2 proteins, respectively. The presence of the CcP0 protein restored cell viability but reduced the growth rate. In the W303CcP0 strain, all four acidic yeast proteins were found on the ribosomes, but in notably less quantity, while a preferable binding of the YP1alpha/YP2betapair was established. In the absence of the endogenous P1/P2 proteins in the D67CcP0 strain, the complementation capacity of the CcP0 protein was considerably reduced. The simultaneous expression of the three medfly genes resulted in alterations of the stalk composition: both the CcP1 and CcP2 proteins were found on the particles substituting the YP1alphaand YP2alpha proteins, respectively, but their presence did not alter the growth rate, except in the case of the YP1alpha/betadefective strain, where a helping effect on the binding of the YP2alphaand YP2betaproteins on the ribo-somes was confirmed. Therefore, the medfly ribosomal P-proteins complement the yeast P-protein deficient strains forming an heterogeneous ribosomal stalk, which, however, is not functionally equivalent to the endogenous one.

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.

Activities of nucleoprotein particles derived from rat liver ribosome.

80-S ribosomes and 60-S subunits from rat liver were treated at increasing KC1 concentrations giving protein-deficient ribosomal particles whose components were analyzed and their activity tested. Most of the activities assayed stand treatment up to KC1 concentrations of around 0.6 M; peptidyl transferase, measured by the fragment reaction, however was 50% inhibited by 0.5 M KC1 in 60-S subunits but not in 80-S ribosomes. Three proteins, L21, L26 and L31, might be implicated in this loss of activity. 60-S subunits forming part of the 80 S ribosome are more resistant to the salt treatment and the pattern of proteins released by the treatment differs from the one obtained from free 60-S subunits, implying perhaps a change of conformation of this subunit upon association to form 80-S couples. According to their resistance to release by KC1 the proteins of the large sub-unit can be divided into three groups: (1) easily removed, including proteins: L1, L11, L17 and L25 in 80-s subunits and in addition, L5, L8, L9, L13, L20, L22, L26, L29, L31 and L32/33 in 60-S subunits; (2) proteins resistant to release by high salt concentrations in 80-S ribosomes as well as in 60-S subunits, namely proteins L3, L14, L27, L36, L40, L41, X1 and X2; (3) the rest of the proteins which are released in a more or less continuous way throughout the treatment. 5 S RNA is not released by KC1 treatment at the concentrations used. The binding sites for the antibiotics trichodermin and anisomycin are affected in a different way by the salt treatment, indicating that they are structurally different.

Structure of the yeast ribosomes. Proteins associated with the rRNA.

Polyamines have been shown to bind to doubled stranded regions of rRNA [3]. Therefore, ribosomal proteins that can be cross linked to these molecules in the ribosomes structure must be bound to or located in the vicinity of the RNA. This technique is the first to yield results on the proteins associated with the rRNA in the eukaryotic ribosome where the lack of purified ribosomal proteins does not allow the use of direct binding studies as in bacterial systems. Proteins S7, S10, S13, S21, S22 and S27 in the small subunit and L2/3, L5, L10/12, L19/20, L22, L23, L36/37, L42 and L43' in the large subunit are labelled when cross linked to [14C]spermidine using 1,5-difluoro 2,4-dinitrobenzene and are good candidates to be RNA-binding proteins in ribosomes from Saccharomyces cerevisiae.

RAP kinase, a new enzyme phosphorylating the acidic P proteins from Saccharomyces cerevisiae.

A new protein kinase, showing a high specificity for the ribosomal acidic P proteins (RAP kinase) has been purified and characterized from Saccharomyces cerevisiae extracts. Purification was carried out by four chromatographic steps, including DEAE-cellulose, phosphocellulose, heparin-Sepharose and P protein-Sepharose. The purified enzyme preparation contains only one polypeptide of around 55 kDa as determined by SDS gel electrophoresis and gradient centrifugation. RAP kinase is different from all previous well-characterized kinases and does not show cross-reaction with antibodies to the 71 kDa 60S ribosomal subunit-specific kinase PK60 previously reported. The enzyme uses ATP as a better phosphate donor and is less sensitive to heparin than casein kinase II but is moderately affected by salt. Among the different substrates tested, ribosomal acidic proteins are preferentially modified by RAP kinase, which phosphorylates only serine residues in the four P proteins as well as the related ribosomal protein P0. Casein is phosphorylated at a much lower level. All the data indicate that RAP kinase might be the enzyme responsible for the phosphorylation of the P proteins, and in this way may also participate in a possible translational regulatory mechanism.

Proteins associated with rRNA in the Escherichia coli ribosome.

Ribosomal proteins located near the rRNA have been identified by cross linking to [14C]spermine with 1,5-difluoro-2,4-dinitrobenzene. The polyamine binds to double-stranded rRNA; those proteins showing radioactivity covalently bound after treatment with the bifunctional reagent should therefore be located in the vicinity of these regions of rRNA. Six proteins from the small subunit, S4, S5, S9, S18, S19 and S20 and ten proteins from the large subunit L2, L6, L13, L14, L16, L17, L18, L19, L22 and L27 preferentially take up the label. The results obtained with three proteins from the large subunit, L6, L16 and L27, show a high degree of variability that could reflect differences of conformation in the subunit population. Several proteins were drastically modified by the cross-linking agent but were not detected in the two-dimensional gel electrophoresis (e.g., S1, S11, S21, L7, L8 and L12) and therefore could not be studied.

Photolabeling of protein components in the pactamycin binding site of rat liver ribosomes.

The antitumoral and antibacterial drug pactamycin can be radioactively labeled by iodination without loss of biological activity. Using the labeled pactamycin, the ribosomal binding site of the drug on rat liver ribosomes has been studied by affinity labeling techniques taking advantage of the photoreactive acetophenone group present in the molecule. When 40 S ribosomal subunits are labeled, one major spot of radioactivity is found associated to protein S25. In addition, weaker spots related to proteins S14/15, S10, S17 and S7 can also be detected in the autoradiogram of the two-dimensional gel slab. Since pactamycin inhibits protein synthesis initiation, the proteins forming its binding site must be related to some step of this process. By comparison with results from pactamycin affinity labeling of Escherichia coli ribosomes (Tejedor, F., Amils, R. and Ballesta, J.P.G. (1985) Biochemistry 24, 3667-3672) these proteins could lie in the mRNA and initiation factors binding region of the rat liver ribosome.

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.

Purification and characterization of a novel poly(U), poly(C) ribonuclease from Saccharomyces cerevisiae.

A new ribonuclease from Saccharomyces cerevisiae, specific for poly(U) and poly(C) substrate, was purified near to homogeneity by successive fractionation with DEAE-Sepharose, Heparin-Sepharose and CM-Sepharose chromatography. The purified molecule detected by SDS/polyacrylimide gel electrophoresis has a molecular mass of 29 kDa. The optimum pH for the enzyme activity is 5.5-7 and its isoelectric point is 7.5. The purified enzyme was able to degrade 26S, 18S and 5S rRNAs as well as mRNA obtained from in vitro transcription. No catalytic activity was observed when the RNase was incubated with tRNA and double stranded substrate. Our findings suggest that this novel RNase may play an important role in the processing of RNA in Saccharomyces cerevisiae.

Heterologous expression of the highly conserved acidic ribosomal phosphoproteins from Dictyostelium (changed from Dictyosteliumm) discoideum in Saccharomyces cerevisiae.

The genes encoding the acidic ribosomal phosphoproteins DdP1 and DdP2 from Dictyostelium discoideum have been cloned into yeast plasmid vectors under the control of the inducible GAL1 promoter. These constructions have been used to transform S. cerevisiae strains D45 and D67 lacking the equivalent ribosomal components. The D. discoideum genes are properly transcribed when cells are grown in the presence of the inducer galactose and the mRNAs incorporated into polysomes. However, the heterologous ribosomal proteins are not able to rescue the growth deficiency in S. cerevisiae caused by the absence of their own ribosomal proteins. When the heterologous proteins are analyzed using specific antibodies, only protein DdP1 is found in the ribosomes of the transformed S. cerevisiae D67 strain. No other heterologous protein is found in any other transformed strain, suggesting that the heterologous acidic ribosomal components are rapidly degraded when they are not bound to the ribosomes. The results indicate that D. discoideum DdP1 protein is able to interact with the yeast ribosome, though the interaction is functionally inefficient. Protein DdP2, in spite of having a higher sequence similarity to its yeast counterparts, is completely inactive in S. cerevisiae. Since the P proteins from both organisms have extensive amino acid sequence similarity ranging from 60% to 70%, these results warns about establishing a direct relationship between the extent of amino acid sequence similarity and the capacity of heterologous proteins to be functional in host species. Moreover, our data suggest that evolution affected the interaction of the acidic proteins with the ribosome rather than the structural features responsible for their primary functions.

The acidic ribosomal proteins as regulators of the eukaryotic ribosomal activity.

The acidic proteins, A-proteins, from the large ribosomal subunit of Saccharomyces cerevisiae grown under different conditions have been quantitatively estimated by ELISA tests using rabbit sera specific for these polypeptides. It has been found that the amount of A-protein present in the ribosome is not constant and depends on the metabolic state of the cell. Ribosomes from exponentially growing cultures have about 40% more of these proteins than those from stationary phase. Similarly, the particles forming part of the polysomes are enriched in A-proteins as compared with the free 80 S ribosomes. The cytoplasmic pool of A-protein is considerably high, containing as a whole as much protein as the total ribosome population. These results are compatible with an exchanging process of the acidic proteins during protein synthesis that can regulate the activity of the ribosome. On the other hand, cells inhibited with different metabolic inhibitors produce a very low yield of ribosomes that contain, however, a surprisingly high amount of acidic proteins while the cytoplasmic pool is considerably reduced, suggesting that under stress conditions the ribosome and the A-protein may aggregate, forming complex structures that are not recovered by the standard preparation methods.

A sparsomycin-resistant mutant of Halobacterium salinarium lacks a modification at nucleotide U2603 in the peptidyl transferase centre of 23 S rRNA.

Sparsomycin, a broad-spectrum antibiotic, acts at the peptidyl transferase centre of the ribosome, stabilizing peptidyl-tRNA binding at the P-site and weakening ternary complex binding. A sparsomycin-resistant mutant was isolated for the archaeon Halobacterium salinarium and shown to lack a post-transcriptional modification of U2603 (Escherichia coli numbering U2584), which is a universally conserved uridine base located within the peptidyl transferase loop of 23 S rRNA. This mutant also exhibited altered sensitivities to the peptidyl transferase antibiotics anisomycin, chloramphenicol and puromycin. Several lines of evidence indicate that the unmodified uridine base lies within the P-substrate site of the peptidyl transferase centre.

Ribosomal proteins EL11 from Escherichia coli and L15 from Saccharomyces cerevisiae bind to the same site in both yeast 26 S and mouse 28 S rRNA.

The heterologous interaction of Escherichia coli ribosomal protein EL11 with yeast 26 S and mouse 28 S rRNA was studied by analysing the ability of this protein to form a specific complex with various synthetic rRNA fragments that span the structural equivalent of the EL11 binding site present in these eukaryotic rRNAs. The fragments were obtained by SP6 polymerase-directed in-vitro run-off transcription of parts of the yeast or mouse large rRNA gene cloned behind the SP6 promoter. EL11 was found to protect an oligonucleotide fragment of 63 nucleotides from both the yeast and mouse transcripts against digestion by RNase T1. In both cases, the position of this fragment in the L-rRNA sequence coincides almost exactly with that of the fragment previously found to be protected by EL11 in E. coli 23 S rRNA. Moreover, the protected yeast fragment was shown to be able to re-bind to EL11 by a nitrocellulose filter binding assay. A ribosomal protein preparation from Saccharomyces cerevisiae containing L15 (YL23) as well as the acidic proteins L44', L44 and L45 protects exactly the same oligonucleotide fragment as does EL11 in both the yeast and mouse transcripts. Evidence is provided that L15, which is known to be structurally and functionally equivalent to EL11, is the rRNA-binding protein in this preparation. Thus the structural equivalent of the EL11 binding site present in yeast 26 S rRNA constitutes the second example of functional conservation of a ribosomal protein-binding site on rRNA between prokaryotes and eukaryotes.

Isolation and expression of the genes encoding the acidic ribosomal phosphoproteins P1 and P2 of the medfly Ceratitis capitata.

The genes of the acidic ribosomal proteins P1 and P2 (CcP1 and CcP2) of the medfly Ceratitis capitata were isolated from a genomic library using homologue DNA probes prepared by PCR. Sequencing and characterization of the two genes revealed strong similarities of the encoded amino acid sequence to the homologous proteins of Drosophila melanogaster and other eukaryotic species. The predicted amino acid sequences of the CcP1 and CcP2 proteins shared an almost identical carboxyl terminal sequence of 10 amino acids common to most known acidic ribosomal proteins. The CcP2 gene lacked intervening sequences in contrast to the CcP1 gene, which was interrupted by an intron of 188 nucleotides. Both genes were cloned in expression pT7 vectors and were expressed in Esherichia coli. The 17- and 15-kDa recombinant proteins reacted with a monoclonal antibody specific to the highly conserved carboxyl terminus of eukaryotic acidic ribosomal proteins, confirming their equivalence to these ribosomal components. Both recombinant proteins were electrophoretically identical to acidic proteins extracted from purified ribosomes of C. capitata.

Deletion of 24 open reading frames from chromosome XI from Saccharomyces cerevisiae and phenotypic analysis of the deletants.

As a part of the EUROFAN program, 24 open reading frames from Saccharomyces cerevisiae (YKR010c to YKR013w, YKR015c to YKR025w, YKR081c to YKR083c, YKR087c to YKR091w and YKR096w) were disrupted in two genetic backgrounds, FY1679 and W303. Systematic deletions and phenotypic analysis were performed following a hierarchical strategy, the so-called 'mass murder'. Of the 24 genes thus deleted, four are essential, whereas the deletion of 17 did not reveal any significant difference between the parental and mutant strains. Deletions of the remaining three show some growth phenotype; ykr024c mutants grow slowly under any conditions, ykr019c mutants grow slower in a rich medium and ykr082w mutants are temperature sensitive, being unable to germinate at 30 degrees C and above.

Protein S4 is near the elongation factor G binding site in the ribosome.

Using a mild iodination method for protein radioactive labeling, it has been shown that elongation factor G, when bound to the ribosome as EFG-GDP-fusidic acid complex, protects protein S4 from labeling. The results indicate that protein S4 is probably near the ribosomal EFG binding site.

Structure-activity relationships of sparsomycin: modification at the hydroxyl group.

Ten analogues of the antibiotic sparsomycin were prepared and evaluated in several in vitro tests. Nine of them carry a modification at the hydroxymethylene group of the molecule, two have a disulfide bond instead of the S(O)-CH2-S moiety at the sulfur-containing side chain of the molecule. While the presence of the S-S group decreases the activity of the analogues in all the tests performed, the modification at the OH group has no deleterious effects on the activity when a polyphenylalanine synthesis assay is used in an Escherichia coli extract. The same modifications, however, diminish drastically the activity of the analogues when tested in a similar Saccharomyces cerevisiae extract. A polymerization system in the archaebacterium Halobacterium halobium extract behaves like the eukaryotic preparations. A discrepancy is also found between the results of the polymerization tests and those of the 'puromycin reaction' which is also less sensitive to the modified sparsomycin analogues. The results of cell growth inhibition tests in bacteria as well as in eukaryotic organisms agree only partially with the in vitro data.