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

The amino terminal end determines the stability and assembling capacity of eukaryotic ribosomal stalk proteins P1 and P2

The eukaryotic ribosomal proteins P1 and P2 bind to protein P0 through their N-terminal domain to form the essential ribosomal stalk. A mutational analysis points to amino acids at positions 2 and 3 as determinants for the drastic difference of Saccharomyces cerevisiae P1 and P2 half-life, and suggest different degradation mechanisms for each protein type. Moreover, the capacity to form P1/P2 heterodimers is drastically affected by mutations in the P2β four initial amino acids, while these mutations have no effect on P1β. Binding of P2β and, to a lesser extent, P1β to the ribosome is also seriously affected showing the high relevance of the amino acids in the first turn of the NTD α-helix 1 for the stalk assembly. The negative effect of some mutations on ribosome binding can be reversed by the presence of the second P1/P2 couple in the ribosome, indicating a stabilizing structural influence between the two heterodimers. Unexpectedly, some mutations totally abolish heterodimer formation but allow significant ribosome binding and, therefore, a previous P1 and P2 association seems not to be an absolute requirement for stalk assembly. Homology modeling of the protein complexes suggests that the mutated residues can affect the overall protein conformation.

Structural and functional characterization of the amino terminal domain of the yeast ribosomal stalk P1 and P2 proteins

The essential ribosomal stalk is formed in eukaryotes by a pentamer of two P1-P2 protein heterodimers and the P0 rRNA binding protein. In contrast to the highly stable prokaryotic complex, the P1 and P2 proteins in the eukaryotic stalk undergo a cyclic process of assembly and disassembly during translation that seems to modulate the ribosome activity. To better understand this process, the regions of the Saccharomyces cerevisiae P1alpha and P2beta proteins that are directly involved in heterodimer formation and ribosome binding have been characterized using a series of P1alpha/P2beta chimeras. The region required for a stable interaction with the ribosome is formed by the first three predicted alpha-helices in the N-terminal domain of both proteins. The same region is required for heterodimer formation in P2beta but the third helix is dispensable for this association in P1alpha. It seems, therefore, that stable ribosome binding is more structurally demanding than heterodimerization. A fourth predicted alpha-helix in the N-terminal domain of P1alpha and P2beta appears not to be involved in the assembly process but rather, it contributes to the conformation of the proteins by apparently restricting the mobility of their C-terminal domain and paradoxically, by reducing their activity. In addition, the study of P1/P2 chimeras showed that the C-terminal domains of these two types of protein are functionally identical and that their protein specificity is exclusively determined by their N-terminal domains.

Elevated copy number of L-A virus in yeast mutant strains defective in ribosomal stalk

The eukaryotic ribosomal stalk, composed of the P-proteins, is a part of the GTPase-associated-center which is directly responsible for stimulation of translation-factor-dependent GTP hydrolysis. Here we report that yeast mutant strains lacking P1/P2-proteins show high propagation of the yeast L-A virus. Affinity-capture-MS analysis of a protein complex isolated from a yeast mutant strain lacking the P1A/P2B proteins using anti-P0 antibodies showed that the Gag protein, the major coat protein of the L-A capsid, is associated with the ribosomal stalk. Proteomic analysis revealed that the elongation factor eEF1A was also present in the isolated complex. Additionally, yeast strains lacking the P1/P2-proteins are hypersensitive to paromomycin and hygromycin B, underscoring the fact that structural perturbations in the stalk strongly influence the ribosome function, especially at the level of elongation.

Different roles of P1 and P2 Saccharomyces cerevisiae ribosomal stalk proteins revealed by cross-linking

The stalk is an essential domain of the large ribosomal subunit formed by a complex of a set of very acidic proteins bound to a core rRNA binding component. While in prokaryotes there is only one type acidic protein, L7/12, two protein families are found in eukaryotes, phosphoproteins P1 and P2, which presumably have different roles. To search for differences zero-length cross-linking by S-S bridge formation was applied using Saccharomyces cerevisiae mutant P1 and P2 proteins carrying single cysteine residues at various positions. The results show a more exposed location of the N-terminal domain of the P2 proteins, which in contrast to P1, can be found as dimers when the Cys is introduced in this domain. Similarly, the Cys containing C-terminal domain of mutant P2 proteins shows a notable capacity to form cross-links with other proteins, which is considerably lower in the P1 type. On the other hand, mutation at the conserved C-domain of protein P0, the eukaryotic stalk rRNA binding component, results in removal of about 14 terminal amino acids. Protein P2, but not P1, protects mutant P0 from this truncation. These results support a eukaryotic stalk structure in which P1 proteins are internally located with their C-terminals having a restricted reactivity while P2 proteins are more external and accessible to interact with other cellular components.

Yeast ribosomal P0 protein has two separate binding sites for P1/P2 proteins

The ribosome has a distinct lateral protuberance called the stalk; in eukaryotes it is formed by the acidic ribosomal P-proteins which are organized as a pentameric entity described as P0-(P1-P2)(2). Bilateral interactions between P0 and P1/P2 proteins have been studied extensively, however, the region on P0 responsible for the binding of P1/P2 proteins has not been precisely defined. Here we report a study which takes the current knowledge of the P0 - P1/P2 protein interaction beyond the recently published information. Using truncated forms of P0 protein and several in vitro and in vivo approaches, we have defined the region between positions 199 and 258 as the P0 protein fragment responsible for the binding of P1/P2 proteins in the yeast Saccharomyces cerevisiae. We show two short amino acid regions of P0 protein located at positions 199-230 and 231-258, to be responsible for independent binding of two dimers, P1A-P2B and P1B-P2A respectively. In addition, two elements, the sequence spanning amino acids 199-230 and the P1A-P2B dimer were found to be essential for stalk formation, indicating that this process is dependent on a balance between the P1A-P2B dimer and the P0 protein.

Tag-mediated fractionation of yeast ribosome populations proves the monomeric organization of the eukaryotic ribosomal stalk structure

The analysis of the not well understood composition of the stalk, a key ribosomal structure, in eukaryotes having multiple 12 kDa P1/P2 acidic protein components has been approached using these proteins tagged with a histidine tail at the C-terminus. Tagged Saccharomyces cerevisiae ribosomes, which contain two P1 proteins (P1 alpha and P1 beta) and two P2 proteins (P2 alpha and P2 beta), were fractionated by affinity chromatography and their stalk composition was determined. Different yeast strains expressing one or two tagged proteins and containing either a complete or a defective stalk were used. No indication of protein dimers was found in the tested strains. The results are only compatible with a stalk structure containing a single copy of each one of the four 12 kDa proteins per ribosome. Ribosomes having an incomplete stalk are found in wild-type cells. When one of the four proteins is missing, the ribosomes do not carry the three remaining proteins simultaneously, containing only two of them distributed in pairs made of one P1 and one P2. Ribosomes can carry two, one or no acidic protein pairs. The P1 alpha/P2 beta and P1beta/P2 alpha pairs are preferentially found in the ribosome, but they are not essential either for stalk assembly or function.

Characterization of interaction sites in the Saccharomyces cerevisiae ribosomal stalk components

The interactions among the yeast stalk components (P0, P1alpha, P1beta, P2alpha and P2beta) and with EF-2 have been explored using immunoprecipitation, affinity chromatography and the two-hybrid system. No stable association was detected between acidic proteins of the same type. In contrast, P1alpha and P1beta were found to interact with P2beta and P2alpha respectively. An interaction of P0 with P1 proteins, but not with P2 proteins, was also detected. This interaction is strongly increased with the P0 carboxyl end, which is able to form a pentameric complex with the four acidic proteins. The P1/P2 binding site has been located between residues 212 and 262 using different C-terminal P0 fragments. Immunoprecipitation shows the association of EF-2 with protein P0. However, the interaction is stronger with the P1/P2 proteins than with P0 in the two-hybrid assay. This interaction improves using the 100-amino-acid-long C-end of P0 and is even higher with the last 50 amino acids. The data indicate a specific association of P1alpha with P2beta and of P1beta with P2alpha rather than the dimerization of the acidic proteins found in prokaryotes. In addition, they suggest that stalk assembly begins by the interaction of the P1 proteins with P0. Moreover, as functional interactions of the complete P0 were found to increase using protein fragments, the data suggest that some active sites are exposed in the ribosome as a result of conformational changes that take place during stalk assembly and function.

Regulated heterogeneity in 12-kDa P-protein phosphorylation and composition of ribosomes in maize (Zea mays L.)

Maize (Zea mays L.) possesses four distinct approximately 12-kDa P-proteins (P1, P2a, P2b, P3) that form the tip of a lateral stalk on the 60 S ribosomal subunit. RNA blot analyses suggested that the expression of these proteins was developmentally regulated. Western blot analysis of ribosomal proteins isolated from various organs, kernel tissues during seed development, and root tips deprived of oxygen (anoxia) revealed significant heterogeneity in the levels of these proteins. P1 and P3 were detected in ribosomes of all samples at similar levels relative to ribosomal protein S6, whereas P2a and P2b levels showed considerable developmental regulation. Both forms of P2 were present in ribosomes of some organs, whereas only one form was detected in other organs. Considerable tissue-specific variation was observed in levels of monomeric and multimeric forms of P2a. P2b was not detected in root tips, accumulated late in seed embryo and endosperm development, and was detected in soluble ribosomes but not in membrane-associated ribosomes that copurified with zein protein bodies of the kernel endosperm. The phosphorylation of the 12-kDa P-proteins was also developmentally and environmentally regulated. The potential role of P2 heterogeneity in P-protein composition in the regulation of translation is discussed.

Yeast protein phosphatase active with acidic ribosomal proteins

A protein phosphatase dephosphorylating acidic ribosomal proteins was purified from Saccharomyces cerevisiae ribosome-free extract. It was shown that phosphoproteins from both P1 and P2 subfamilies as well as 60S "core" P0 protein were substrates for the enzyme. The phosphatase can dephosphorylate ribosomes as well as histones and casein but the two last substrates with significantly lower efficiency. It was found that the enzyme activity is Mn(2+)-dependent and inhibited by okadaic acid, tautomycin, cantharidin and nodularin at concentrations typical for protein phosphatase type 2A. The possible implications of those findings in the control of ribosome phosphorylation and therefore in the control of translation is discussed.

The rpl16a gene for ribosomal protein L16A identified from expressed sequence tags is differentially expressed during sexual development of Aspergillus nidulans

We obtained 305 expressed sequence tags (ESTs), which are from the poly(A) site to the most proximal MboI site, from mycelia at the early sexual developmental (ESD) stage of Aspergillus nidulans. By comparison of these ESTs with those obtained previously from the vegetative stage and from the late sexual developmental stage followed by Northern blot analyses, genes of 17 ESTs were identified as being expressed more abundantly at the ESD stage than at the vegetative stage. Five of 17 genes were expressed more abundantly in the presence of the veA gene or the nsdD gene, suggesting that these 5 genes may be involved in sexual development. In a gene of one EST, appearing three times among 305 ESTs and identified by GenBank, polyadenylation seemed to occur at two sites. Nucleotide sequences of the gene having the EST and its cDNA revealed that the gene can code for a 202-amino-acid polypeptide with an estimated molecular mass of 23 kDa. The deduced amino acid showed 73% identity to Saccharomyces cerevisiae ribosomal protein L16A (RPL16A), and therefore the gene was named rpl16a. A. nidulans RPL16A had a putative leucine zipper motif and a basic leucine zipper motif like those of other organisms. The expression level of the rpl16a gene, present as a single copy in this organism, reached a maximum after 2 h, decreased thereafter, and increased again 30 to 50 h after the end of induction of sexual development. These results clearly indicated that the rpl16a gene is expressed differentially during sexual development.

Analysis of the protein-protein interactions between the human acidic ribosomal P-proteins: evaluation by the two hybrid system

The surface acidic ribosomal proteins (P-proteins), together with ribosomal core protein P0 form a multimeric lateral protuberance on the 60 S ribosomal subunit. This structure, also called stalk, is important for efficient translational activity of the ribosome. In order to shed more light on the function of these proteins, we are the first to have precisely analyzed mutual interactions among human P-proteins, employing the two hybrid system. The human acidic ribosomal P-proteins, (P1 or P2,) were fused to the GAL4 binding domain (BD) as well as the activation domain (AD), and analyzed in yeast cells. It is concluded that the heterodimeric complex of the P1/P2 proteins is formed preferentially. Formation of homodimers (P1/P1 and P2/P2) can also be observed, though with much less efficiency. Regarding that, we propose to describe the double heterodimeric complex as a protein configuration which forms the 60 S ribosomal stalk: P0-(P1/P2)(2). Additionally, mutual interactions among human and yeast P-proteins were analyzed. Heterodimer formation could be observed between human P2 and yeast P1 proteins.

The RNA interacting domain but not the protein interacting domain is highly conserved in ribosomal protein P0

Protein P0 interacts with proteins P1alpha, P1beta, P2alpha, and P2beta, and forms the Saccharomyces cerevisiae ribosomal stalk. The capacity of RPP0 genes from Aspergillus fumigatus, Dictyostelium discoideum, Rattus norvegicus, Homo sapiens, and Leishmania infantum to complement the absence of the homologous gene has been tested. In S. cerevisiae W303dGP0, a strain containing standard amounts of the four P1/P2 protein types, all heterologous genes were functional except the one from L. infantum, some of them inducing an osmosensitive phenotype at 37 degrees C. The polymerizing activity and the elongation factor-dependent functions but not the peptide bond formation capacity is affected in the heterologous P0 containing ribosomes. The heterologous P0 proteins bind to the yeast ribosomes but the composition of the ribosomal stalk is altered. Only proteins P1alpha and P2beta are found in ribosomes carrying the A. fumigatus, R. norvegicus, and H. sapiens proteins. When the heterologous genes are expressed in a conditional null-P0 mutant whose ribosomes are totally deprived of P1/P2 proteins, none of the heterologous P0 proteins complemented the conditional phenotype. In contrast, chimeric P0 proteins made of different amino-terminal fragments from mammalian origin and the complementary carboxyl-terminal fragments from yeast allow W303dGP0 and D67dGP0 growth at restrictive conditions. These results indicate that while the P0 protein RNA-binding domain is functionally conserved in eukaryotes, the regions involved in protein-protein interactions with either the other stalk proteins or the elongation factors have notably evolved.

Protein kinases phosphorylating acidic ribosomal proteins from yeast cells

Phosphorylation of ribosomal acidic proteins of Saccharomyces cerevisiae is an important mechanism regulating a number of active ribosomes. The key role in the regulatory mechanism is played by specific phosphoprotein kinases and phosphoprotein phosphatases. Three different cAMP-independent protein kinases phosphorylating acidic ribosomal proteins have been identified and characterized. The protein kinase 60S (PK60S), RAP kinase, and casein kinase type 2 (CK2). All three protein kinases phosphorylate serine residues which are localized in the C-terminal end of phosphoproteins. Synthetic peptides were used to determinate the amino acid sequence of phosphoacceptor site for PK60S. Peptide AAEESDDD derived from phosphoproteins YP1 beta/beta' and YP2 alpha turned out to be the best substrate for PK60S. A number of halogenated benzimidazoles and 2-azabenzimidazoles were tested as inhibitors of the three protein kinases. 4,5,6,7-Tetrabromo-2-azabenzimidazole inhibits phosphorylation only of these polypeptides phosphorylated by protein kinase 60S, namely YP1 beta/beta' and YP2 alpha, but not the other, YP1 alpha and YP2 beta phosphorylated by protein kinases RAP and CK2. RAP kinase has been found in an active form in the soluble fraction of S. cerevisiae. The enzyme uses ATP as a phosphate donor and is less sensitive to heparin than casein kinase 2. RAP kinase monophosphorylates the four acidic proteins. The ribosome-bound proteins are a better substrate for the enzyme. Multifunctional CK2 kinase phosphorylate all four acidic proteins. The kinase phosphorylates preferentially serine or threonine residues surrounded by cluster of acidic residues. The enzyme activity is stimulated in vitro by the presence of polylysine and inhibited by heparin.

Structure and function of the stalk, a putative regulatory element of the yeast ribosome. Role of stalk protein phosphorylation

The ribosomal stalk is involved directly 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 protein P0. All these proteins are found to be phosphorylated in eukaryotic organisms. Previous in vitro data suggested this modification was involved in the activity of this structure. To confirm this possibility a mutational study has shown that phosphorylation takes place at a serine residue close to the carboxyl end of proteins P1, P2 and P0. This serine is part of a consensus casein kinase II phosphorylation site. However, by using a yeast strain carrying a temperature sensitive mutant, it has been shown that CKII is probably not the only enzyme responsible for this modification. Three new protein kinases, RAPI, RAPII and RAPIII, have been purified and compared with CKII and PK60, a previously reported enzyme that phosphorylates the stalk proteins. Differences among the five enzymes have been studied. It has also been found that some typical effectors of the PKC kinase stimulate the in vitro phosphorylation of the stalk proteins. All the data available suggest that phosphorylation, although it is not involved in the interaction of the acidic proteins with the ribosome, affects ribosome activity and might participate in some ribosome regulatory mechanism.

The GTPase center protein L12 is required for correct ribosomal stalk assembly but not for Saccharomyces cerevisiae viability

Protein L12, together with the P0/P1/P2 protein complex, forms the protein moiety of the GTPase domain in the eukaryotic ribosome. In Saccharomyces cerevisiae protein L12 is encoded by a duplicated gene, rpL12A and rpL12B. Inactivation of both copies has been performed and confirmed by Southern and Western analyses. The resulting strains are viable but grow very slowly. Growth rate is recovered upon transformation with an intact copy of the L12 gene. Ribosomes from the disrupted strain lack protein L12 but are able to carry out translation in vitro at about one fourth of the control rate. The L12-deficient ribosomes have also a defective stalk containing standard amounts of the 12-kDa acidic proteins P1beta and P2alpha, but proteins P1alpha and P2beta are drastically reduced. Moreover, the affinity of P0 is reduced in the defective ribosomes. Footprinting of the 26 S rRNA GTPase domain indicates that protein L12 protects in different extent residues G1235, G1242, A1262, A1270, and A1272 from chemical modification. The results in this report indicate that protein L12 is not essential for cell viability but has a relevant role in the structure and stability of the eukaryotic ribosomal stalk.

Acidic phosphoprotein complex of the 60S ribosomal subunit of maize seedling roots. Components and changes in response to flooding

We determined that ribosomes of seedling roots of maize (Zea mays L.) contain the acidic phosphoproteins (P-proteins) known to form a flexible lateral stalk structure of the 60S subunit of eukaryotic ribosomes. The P-protein stalk, composed of P0, P1, and P2, interacts with elongation factors, mRNA, and tRNA during translation. Acidic proteins of 13 to 15.5 kD were released as a complex from ribosomes with 0.4 M NH4Cl/50% ethanol. Protein and cDNA sequence analysis confirmed that maize ribosomes contain one type of P1, two types of P2, and a fourth and novel P1/P2-type protein. This novel P-protein, designated P3, has the conserved C terminus of P1 and P2. P1, P2, and P3 are similar in deduced mass (11.4-12.2 kD) and isoelectric point (4.1-4.3). A 35.5- to 36-kD acidic protein was released at low levels from ribosomes with 1.0 M NH4Cl/50% ethanol and identified as P0. Labeling of roots with [32P]inorganic phosphate confirmed the in vivo phosphorylation of the P-proteins. Flooding caused dynamic changes in the P-protein complex, which affected the potential of ribosome-associated kinases and casein kinase II to phosphorylate the P-proteins. We discuss possible alterations of the ribosomal P-protein complex and consider that these changes may be involved in the selective translation of mRNA in flooded roots.

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 P1, P2, and P0, components of the eukaryotic ribosome stalk. New structural and functional aspects

The eukaryoic ribosomal stalk is thought to consist of the phosphoproteins P1 and P2, which form a complex with protein PO. This complex interacts at the GTPase domain in the large subunit rRNA, overlapping the binding site of the protein L11-like eukaryotic counterpart (Saccharomyces cerevisiae protein L15 and mammalian protein L12). An unusual pool of the dephosphorylated forms of proteins P1 and P2 is detected in eukaryotic cytoplasm, and an exchange between the proteins in the pool and on the ribosome takes place during translation. Quadruply disrupted yeast strains, carrying four inactive acidic protein genes and, therefore, containing ribosomes totally depleted of acidic proteins, are viable but grow with a doubling time threefold higher than wild-type cells. The in vitro translation systems derived from these stains are active but the two-dimensional gel electrophoresis pattern of proteins expressed in vivo and in vitro is partially different. These results indicate that the P1 and P2 proteins are not essential for ribosome activity but are able to affect the translation of some specific mRNAs. Protein PO is analogous to bacterial ribosomal protein L10 but carries an additional carboxyl domain showing a high sequence homology to the acidic proteins P1 and P2, including the terminal peptide DDDMGFGLFD. Successive deletions of the PO carboxyl domain show that removal of the last 21 amino acids from the PO carboxyl domain only slightly affects the ribosome activity in a wild-type genetic background; however, the same deletion is lethal in a quadruple disruptant deprived of acidic P1/P2 proteins. Additional deletions affect the interaction of PO with the P1 and P2 proteins and with the rRNA. The experimental data available support the implication of the eukaryotic stalk components in some regulatory process that modulates the ribosomal activity.

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.

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.

Eukaryotic acidic phosphoproteins interact with the ribosome through their amino-terminal domain

Variable-size fragments of the four yeast acidic ribosomal protein genes rpYP1 alpha, rpYP1 beta, rpYP2 alpha and rpYP2 beta were fused to the LacZ gene in the vector series YEp356-358. The constructs were used to transform wild-type Saccharomyces cerevisiae and several gene-disrupted strains lacking different acidic ribosomal protein genes. The distribution of the chimeric proteins between the cytoplasm and the ribosomes, tested as beta-galactosidase activity, was estimated. Hybrid proteins containing around a minimum of 65-75 amino acids from their amino-terminal domain are able to bind to the ribosomes in the presence of the complete native proteins. Hybrid proteins containing no more than 36 amino terminal amino acids bind to the ribosomes in the absence of a competing native protein. The fused YP1-beta-galactosidase proteins are also able to form a complex with the native YP2 type proteins, promoting their binding to the ribosome. The stability of the hybrid polypeptides seems to be inversely proportional to the size of their P protein fragment. These results indicate that only the amino-terminal domain of the eukaryotic P proteins is needed for the P1-P2 complex formation required for interaction with the ribosome. The highly conserved P protein carboxyl end is not implicated in the binding to the particles and is exposed to the medium.

RPL44 and RPL44', encoding acidic ribosomal phosphoproteins YP2 alpha(L44) and YP1 beta(L44'), are adjacent to rig and STF1 on Saccharomyces cerevisiae chromosomes XV and IV respectively

The RPL44' gene from Saccharomyces cerevisiae encoding the ribosomal protein YP1 beta(L44') has been found to be linked to the STF1 gene, encoding a stabilizing factor of the F1F0-ATPase inhibitor protein from mitochondria. Evidence of this linkage comes from results obtained from Northern hybridization using a DNA probe that contains a complementary region to the 5' end of the mRNA of RPL44'. Similarly, a data bank search has shown that RPL44, encoding ribosomal protein YP2 alpha (L44) is linked to the rig gene that encodes ribosomal protein S21.

Known heat-shock proteins are not responsible for stress-induced rapid degradation of ribosomal protein mRNAs in yeast

We have previously shown that the heat-induced enhanced decay of yeast mRNAs encoding ribosomal proteins (rp-mRNAs) requires ongoing transcription during the heat treatment [Herruer et al. (1988) Nucl. Acids Res. 16, 7917]. In order to determine whether this requirement reflects the need for heat-shock protein (hsp), we analysed the effect of heat shock on rp-mRNA levels in several yeast strains in which each of the heat-shock genes encoding hsp26, hsp35 or hsp83 had been individually disrupted. In all three strains we still observed increased degradation of rp-mRNAs immediately after the temperature shift, demonstrating that hsp26, hsp35 and hsp83 are not required for this effect. Accelerated turnover of rp-mRNA was also found to occur upon raising the growth temperature of a mutant strain that contains a disruption of the gene specifying the heat-shock transcription factor and in wild-type yeast cells treated with canavanine, an arginine analogue that will be incorporated into all known hsps and that is known to cause misfolding of the polypeptide chain. Latter observation suggests that enhanced rp-mRNA decay is a more general stress-related phenomenon. Taken together, these data strongly indicate that the trans-acting factor required for the increase in the rate of degradation of rp-mRNAs upon stress is not one of the known yeast hsps.

Chromatin diminution in nematode development

Chromatin diminution in Parascaris and Ascaris represents the classical case of a developmentally programmed genome rearrangement. The process is very specific with respect to ontogenetic timing and chromosomal localization, and involves chromosomal breakage, new telomere formation and DNA degradation. Recent evidence from Ascaris lumbricoides var. suum suggests that chromatin diminution might have a function in gene regulation.

Characterization of the yeast acidic ribosomal phosphoproteins using monoclonal antibodies. Proteins L44/L45 and L44' have different functional roles

In order to characterize the acidic ribosomal proteins immunologically and functionally, a battery of monoclonal antibodies specific for L44, L44' and L45, the three acidic proteins detected in Saccharomyces cerevisiae, were obtained. Eight monoclonal antibodies were obtained specific for L45, three for L44' and one for L44. In addition, two mAbs recognizing only the phosphorylated forms of the three proteins were obtained. The specific immunogenic determinants are located in the middle region of the protein structure and are differently exposed in the ribosomal surface. The common determinants are present in the carboxyl end of the three proteins. An estimation of the acidic proteins by ELISA indicated that, in contrast to L44 and L45, L44' is practically absent from the cell supernatant; this suggests that protein L44' does not intervene in the exchange that has been shown to take place between the acidic proteins in the ribosome and in the cytoplasmic pool. It has also been found that, while IgGs specific for L44 and L45 do not inhibit the ribosome activity, the anti-L44' effectively blocks the polymerizing activity of the particles. These results show for the first time that the different eukaryotic acidic ribosomal proteins play a different functional role.

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.