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 YP1α/YP2β pair 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 YP1α and YP2α proteins, respectively, but their presence did not alter the growth rate, except in the case of the YP1α/β defective strain, where a helping effect on the binding of the YP2α and YP2β proteins on the ribosomes 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.     

Isolation of a CK2α Subunit and the Holoenzyme from the Mussel <Emphasis Type="Italic">Mytilus galloprovincialis</Emphasis> and Construction of the <Emphasis Type="Italic">CK2α</Emphasis> and <Emphasis Type="Italic">CK2β</Emphasis> cDNAs

Protein kinase CK2 is a ubiquitous, highly pleiotropic, and constitutively active phosphotransferase that phosphorylates mainly serine and threonine residues. CK2 has been studied and characterized in many organisms, from yeast to mammals. The holoenzyme is generally composed of two catalytic (α and/or α′) and two regulatory (β) subunits, forming a differently assembled tetramer. The free and catalytically active α/α′ subunits can be present in cells under some circumstances. We present here the isolation of a putative catalytic CK2α subunit and holoenzyme from gills of the mussel Mytilus galloprovincialis capable of phosphorylating the purified recombinant ribosomal protein rMgP1. For further analysis of M. galloprovincialis protein kinase CK2, the cDNA molecules of CK2α and CK2β subunits were constructed and cloned into expression vectors, and the recombinant proteins were purified after expression in Escherichia coli. The recombinant MgCK2β subunit and MgP1 were phosphorylated by the purified recombinant MgCK2α subunit. The mussel enzyme presented features typical for CK2: affinity for GTP, inhibition by both heparin and ATP competitive inhibitors (TBBt, TBBz), and sensitivity towards NaCl. Predicted amino acid sequence comparison showed that the M. galloprovincialis MgCK2α and MgCK2β subunits have similar features to their mammalian orthologs.     

Assembly of Saccharomyces cerevisiae ribosomal stalk: binding of P1 proteins is required for the interaction of P2 proteins

The yeast ribosomal stalk is formed by a protein pentamer made of the 38 kDa P0 and four 12 kDa acidic P1/P2. The interaction of recombinant acidic proteins P1 alpha and P2 beta with ribosomes from Saccharomyces cerevisiae D4567, lacking all the 12 kDa stalk components, has been used to study the in vitro assembly of this important ribosomal structure. Stimulation of the ribosome activity was obtained by incubating simultaneously the particles with both proteins, which were nonphosphorylated initially and remained unmodified afterward. The N-terminus state, free or blocked, did not affect either the binding or reactivating activity of both proteins. Independent incubation with each protein did not affect the activity of the particles, however, protein P2 beta alone was unable to bind the ribosome whereas P1 alpha could. The binding of P1 alpha alone is a saturable process in acidic-protein-deficient ribosomes and does not take place in complete wild-type particles. Binding of P1 proteins in the absence of P2 proteins takes also place in vivo, when protein P1 beta is overexpressed in S. cerevisiae. In contrast, protein P2 beta is not detected in the ribosome in the P1-deficient D67 strain despite being accumulated in the cytoplasm. The results confirm that neither phosphorylation nor N-terminal blocking of the 12 kDa acidic proteins is required for the assembly and function of the yeast stalk. More importantly, and regardless of the involvement of other elements, they indicate that stalk assembling is a coordinated process, in which P1 proteins would provide a ribosomal anchorage to P2 proteins, and P2 components would confer functionality to the complex.     

Characterization of a novel acidic protein of 38 kDa, A0, in yeast ribosomes which immunologically cross-reacts with the 13 kDa acidic ribosomal proteins, A1/A2

A new ribosomal protein of 38 kDa, named A0, was detected in yeast ribosomes on immunoblotting. The antibody used here was that against A1/A2, 13 kDa acidic ribosomal proteins which cross-reacted with A0. Although A0 and A1/A2 share common antigenic determinants, they differ in the following biochemical properties. While A1/A2 could be extracted from ribosomes with ethanol and ammonium sulfate, A0 could not. A0 gave two protein spots in a less acidic region than for A1/A2 on two-dimensional gel electrophoresis. The heterogeneity observed for A0 was ascribable to phosphorylation because one spot disappeared after treatment of the ribosomes with phosphatase. The syntheses of A0 and A1/A2 are directed by different mRNA species, as judged with a cell-free translation system, ruling out the possibility that A0 is a precursor of A1/A2. Although a mammalian ribosomal protein equivalent to A0 has been shown to be associated with 13 kDa acidic proteins in the cytoplasm, essentially no A0 was detected on immunoblotting in the yeast cytosol, while a small but detectable amount of A1/A2 was present. The possibility that A0 is a eukaryotic equivalent of L10 of Escherichia coli is discussed.     

Protein kinases CKI and CKII are implicated in modification of ribosomal proteins of the yeast Trichosporon cutaneum

Phosphorylation of acidic ribosomal proteins P1/P2-P0 is a common phenomenon in eukaryotic organisms. It was found previously that in Trichosporon cutaneum, unlike in other yeast species, in addition to the two acidic ribosomal proteins, two other proteins of 15 kDa and 19 kDa of the small ribosomal subunit were phosphorylated. Here we describe two protein kinases: CKI and CKII, which are engaged in the modification of T. cutaneum ribosomal proteins. The acidic ribosomal proteins and the protein of 19 kDa were modified by CKII associated with ribosomes, while the protein of 15 kDa was modified by CKI. Protein kinase CKI was purified from cell-free extract (CKIC) and from ribosomal fraction (CKIR). The molecular mass of CKIC was established at 33 kDa while that of CKIR at 35-37 kDa. A protein of 40 kDa copurified with CKIR but not CKIC. Heparin significantly increased 40 kDa protein phosphorylation level by CKIR. Microsequencing analysis revealed the presence of CKI recognition motifs in the N-terminal fragment of the 40 kDa protein.     

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 polypepties 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. Previousin 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 effects of the PKC kinase stimulate thein 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. Presented at theSymposium on Regulation of Translation of Genetic Information by Protein Phosphorylation, 21st Congress of the Czechoslovak Society for Microbiology, Hradec Králové (Czech Republic), September 6–10, 1998.     

The gene and the primary structure of acidic ribosomal protein A0 from yeast Saccharomyces cerevisiae which shows partial homology to bacterial ribosomal protein L10

Eukaryotic ribosomes contain an acidic ribosomal protein of about 38 kDa which shows immunological cross-reactivity with the 13 kDa-type acidic ribosomal proteins that are related to L7/L12 of bacterial ribosomes. By using a cDNA clone for 38 kDa-type acidic ribosomal protein A0 from the yeast Saccharomyces cerevisiae, we have cloned a genomic DNA encoding A0 and determined the sequence of 1,614 nucleotides including about 500 nucleotides in the 5'-flanking region. The gene lacks introns and possesses two boxes homologous to upstream activation sequences (UASrpg) in the 5'-flanking region. The amino acid sequence of A0 deduced from the nucleotide sequence shows that A0 shares a highly similar carboxyl-terminal region of about 40 amino acids in length with 13 kDa-type acidic ribosomal proteins, including an identical carboxyl-terminal, DDDMGFGLFD. In the amino-terminal region A0 contains an arginine-rich segment which shows a low but distinct similarity to that of bacterial ribosomal protein L10 through which L10 is thought to bind to 23S rRNA. On the other hand, the carboxyl-terminal half of A0 is enriched with hydrophobic amino acid residues including four pairs of phenylalanine residues which are all conserved in a human homologue.     

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.     

The amino terminal domain from Mrt4 protein can functionally replace the RNA binding domain of the ribosomal P0 protein

In Saccharomyces cerevisiae, the Mrt4 protein is a component of the ribosome assembly machinery that shares notable sequence homology to the P0 ribosomal stalk protein. Here, we show that these proteins can not bind simultaneously to ribosomes and moreover, a chimera containing the first 137 amino acids of Mrt4 and the last 190 amino acids from P0 can partially complement the absence of the ribosomal protein in a conditional P0 null mutant. This chimera is associated with ribosomes isolated from this strain when grown under restrictive conditions, although its binding is weaker than that of P0. These ribosomes contain less P1 and P2 proteins, the other ribosomal stalk components. Similarly, the interaction of the L12 protein, a stalk base component, is affected by the presence of the chimera. These results indicate that Mrt4 and P0 bind to the same site in the 25S rRNA. Indeed, molecular dynamics simulations using modelled Mrt4 and P0 complexes provide further evidence that both proteins bind similarly to rRNA, although their interaction with L12 displays notable differences. Together, these data support the participation of the Mrt4 protein in the assembly of the P0 protein into the ribosome and probably, that also of the L12 protein.     

In vivo analysis of the acidic ribosomal proteins BmP1 and BmP2 of the silkworm Bombyx mori in the yeast Saccharomyces cerevisiae

In the silkworm Bombyx mori the ribosomal stalk P-protein family consists of two low MW acidic proteins, BmP1 and BmP2, and of one higher MW protein, BmP0, as shown by electrophoretical and immunoblotting western blot analysis of purified ribosomes. Treatment of ribosomes with alkaline phosphatase followed by electrofocusing shifted the isoelectric points to higher pH, implying phosphorylation of the proteins. The cDNAs encoding BmP1 and BmP2 proteins were constructed and expressed in the Saccharomyces cerevisiae mutant strains defective in either the endogenous P1 or P2 proteins. The recombinant silkworm proteins could complement the absence of the homologous yeast proteins and were incorporated to the ribosomes of the transformed strains, helping the binding of the remaining endogenous acidic proteins, present in the cytoplasm in different extent. Thus, BmP1 was able to replace YP1alpha, preferentially binding YP2beta to the ribosome, while BmP2 replaced both yeast P2 proteins and induced the binding of both YP1alpha and YP1beta.     

八肋游仆虫酸性核糖体磷酸化蛋白P1有2个亚型

真核生物酸性核糖体磷酸化蛋白(P0、P1、P2)位于核糖体60S大亚基上,它们在核糖体上共同组成一个向外侧凸出的五聚体的柄状复合物［P0·(P1·P2)2］,该复合物在蛋白质合成延伸过程中起着重要作用．为了探讨单细胞真核生物核糖体柄状复合物的组成形式及在蛋白质合成中的作用,对八肋游仆虫（Euplotes octocarinatus）的P1进行了研究．通过生物信息学方法,分析八肋游仆虫基因组及转录组数据,找到2个酸性核糖体蛋白P1基因,从DNA 和cDNA中都扩增到这2个P1基因,表明八肋游仆虫酸性核糖体磷酸化蛋白P1确实存在2个亚型. 将2个基因克隆后分别构建重组表达质粒pET28a-P1A和pGEX-6P-1-P1B,在大肠杆菌BL21中获得高效表达.经镍柱和GST柱亲和层析后,获得较高纯度的八肋游仆虫酸性核糖体蛋白EoP1A和EoP1B,表达产物经Western印迹检测为阳性．Pull-down分析了EoP1A和EoP1B之间的相互作用．结果表明,游仆虫酸性核糖体磷酸化蛋白P1的2个亚型EoP1A和EoP1B之间存在相互作用.     

The acidic protein binding site is partially hidden in the free Saccharomyces cerevisiae ribosomal stalk protein P0

The ribosomal stalk is essential for translation; however, its overall structure is poorly understood. Characterization of the region involved in the interactions between protein P0 and the 12 kDa acidic proteins P1 and P2 is fundamental to understand the assembly and function of this structure in the eukaryotic ribosome. The acidic protein content is important for the ribosome efficiency and affects the translation of specific mRNAs. By usage of a series of progressively truncated fragments of protein P0 in the two-hybrid test, a region between positions 213 and 250 was identified as the minimal protein part able to interact with the acidic proteins. Extensions at either end affect the binding capacity of the fragment either positively or negatively depending on the number of added amino acids. Deletions inside the binding region confirm its in vivo relevance since they drastically reduce the P0 interacting capacity with the 12 kDa acidic proteins, which are severely reduced in the ribosome when the truncated protein is expressed in the cell. Moreover, recombinant His-tagged P0 fragments containing the binding site and bound to Ni(2+)-NTA columns can form a complex with the P1 and P2 proteins, which is able to bind elongation factor EF2. The results indicate the existence of a region in P0 that specifically interacts with the acidic proteins. These interactions are, however, hindered by the presence of neighbor protein domains, suggesting the need for conformational changes in the complete P0 to allow the assembly of the ribosomal stalk.     

Chagas disease: a homology model for the three-dimensional structure of the Trypanosoma cruzi ribosomal P0 antigenic protein

Ribosomal P proteins form a “stalk” complex in the large subunit of the ribosomes. In Trypanosoma cruzi, the etiological agent of Chagas disease, the complex is formed by five P protein members: TcP0, TcP1α, TcP1β, TcP2α and TcP2β. The TcP0 protein has 34 kDa, and TcP1 and TcP2 proteins have 10 kDa. The structure of T. cruzi P0 and the stalk complex TcP0–TcP1α–TcP1β–TcP2α–TcP2β have not been solved to date. In this work, we constructed a three-dimensional molecular model for TcP0 using homology modeling as implemented in the MODELLER 9v12 software. The model was constructed using different templates: the X-ray structures of the protein P0 from Pirococcus horikoshii, a segment from the Danio renio Ca⁺²/K⁺ channel and the C-terminal peptide (C13) from T. cruzi ribosomal P2 protein; the Cryo-EM structure of Triticum aestivum P0 protein and the NMR structure of Homo sapiens P1 ribosomal protein. TcP0 has a 200-residue-long N-terminal, which is an α/β globular stable domain, and a flexible C-terminal, 120-residue-long domain. The molecular surface electrostatic potential and hydrophobic surface were calculated. The surface properties are important for the C-terminal's antigenic properties. They are also responsible for P0-specific binding to RNA26S and the binding to the P1–P2 proteins. We explored and identified protein interactions that may be involved in conformational stability. The structure proposed in this work represents a first structural report for the TcP0 protein.     

Interaction map of the Trypanosoma cruzi ribosomal P protein complex (stalk) and the elongation factor 2

The large subunit of the eukaryotic ribosome possesses a long and protruding stalk formed by the ribosomal P proteins. This structure is involved in the translation step of protein synthesis through interaction with the elongation factor 2 (EF‐2). The Trypanosoma cruzi stalk complex is composed of four proteins of about 11 kDa, TcP1α, TcP1β, TcP2α, TcP2β and a fifth TcP0 of about 34 kDa. In a previous work, a yeast two‐hybrid (Y2H) protein–protein interaction map of T. cruzi ribosomal P proteins was generated. In order to gain new insight into the assembly of the stalk, a complete interaction map was generated by surface plasmon resonance (SPR) and the kinetics of each interaction was calculated. All previously detected interactions were confirmed and new interacting pairs were found, such as TcP1β–TcP2α and TcP1β–TcP2β. Moreover P2 but not P1 proteins were able to homo‐oligomerize. In addition, the region comprising amino acids 210–270 on TcP0 was identified as the region interacting with P1/P2 proteins, using Y2H and SPR. The interaction domains on TcP2β were also mapped by SPR identifying two distinct regions. The assembly order of the pentameric complex was assessed by SPR showing the existence of a hierarchy in the association of the different P proteins forming the stalk. Finally, the TcEF‐2 gene was identified, cloned, expressed and refolded. Using SPR analysis we showed that TcEF‐2 bound with similar affinity to the four P1/P2 ribosomal P proteins of T. cruzi but with reduced affinity to TcP0. Copyright © 2010 John Wiley & Sons, Ltd.     

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.     

The ribosomal stalk is required for ribosome binding,depurination of the rRNA and cytotoxicity of ricin A chain in Saccharomyces cerevisiae

Ribosome inactivating proteins (RIPs) like ricin, pokeweed antiviral protein (PAP) and Shiga‐like toxins 1 and 2 (Stx1 and Stx2) share the same substrate, the α‐sarcin/ricin loop, but differ in their specificities towards prokaryotic and eukaryotic ribosomes. Ricin depurinates the eukaryotic ribosomes more efficiently than the prokaryotic ribosomes, while PAP can depurinate both types of ribosomes. Accumulating evidence suggests that different docking sites on the ribosome might be used by different RIPs, providing a basis for understanding the mechanism underlying their kingdom specificity. Our previous results demonstrated that PAP binds to the ribosomal protein L3 to depurinate the α‐sarcin/ricin loop and binding of PAP to L3 was critical for its cytotoxicity. Here, we used surface plasmon resonance to demonstrate that ricin toxin A chain (RTA) binds to the P1 and P2 proteins of the ribosomal stalk in Saccharomyces cerevisiae. Ribosomes from the P protein mutants were depurinated less than the wild‐type ribosomes when treated with RTA in vitro. Ribosome depurination was reduced when RTA was expressed in the ΔP1 and ΔP2 mutants in vivo and these mutants were more resistant to the cytotoxicity of RTA than the wild‐type cells. We further show that while RTA, Stx1 and Stx2 have similar requirements for ribosome depurination, PAP has different requirements, providing evidence that the interaction of RIPs with different ribosomal proteins is responsible for their ribosome specificity.     

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.     

Role of the ribosomal stalk components in the resistance of Aspergillus fumigatus to the sordarin antifungals

Aspergillus fumigatus, an important human nosocomial pathogen, is resistant to sordarin derivatives, a new family of antifungals that inhibit protein synthesis by interaction with the EF-2-ribosomal stalk complex. To explore the role of the A. fumigatus ribosome in the resistance mechanism, the fungal stalk proteins were biochemically and genetically characterized and expressed in the sensitive Saccharomyces cerevisiae. Two acidic phosphoproteins homologous to the 12 kDa P1 and P2 proteins described in other organisms were found together with the 34 kDa P0 protein, the third stalk component. The genes encoding each fungal stalk protein were expressed in mutant S. cerevisiae strains lacking the equivalent proteins. Both AfP1 and AfP2 proteins interact with their yeast counterparts of the opposite type and bind to the ribosomal particles in the presence of either the S. cerevisiae or the A. fumigatus P0 protein. The A. fumigatus acidic phosphoproteins did not alter the yeast ribosome sordarin sensitivity. On the contrary, the presence of the fungal P0 induces in vivo and in vitro resistance to sordarin derivatives when present in the yeast ribosome. The mutations A117-->E, P122-->R and G124-->V in A. fumigatus P0 reduce the resistance capacity of the protein. An S. cerevisiae strain with the complete ribosomal stalk of A. fumigatus was obtained, which could be useful for the screening of new antifungals against this pathogenic fungus.     

Acquisition of a stable structure by yeast ribosomal P0 protein requires binding of P1A-P2B complex: in vitro formation of the stalk structure

Saccharomyces cerevisiae ribosomal stalk consists of five proteins: P0 protein, with molecular mass of 34 kDa, and four small, 11 kDa, P1A, P1B, P2A and P2B acidic proteins, which form a pentameric complex P0-(P1A-P2B)/(P1B-P2A). This structure binds to a region of 26S rRNA termed GTPase-associated domain and plays a crucial role in protein synthesis. The consecutive steps leading to the formation of the stalk structure have not been fully elucidated and the function of individual P-proteins in the assembling of the stalk and protein synthesis still remains elusive. We applied an integrated approach in order to examine all the P-proteins with respect to stalk assembly. Several in vitro methods were utilized to mimic protein self-organization in the cell. Our efforts resulted in reconstitution of the whole recombinant stalk in solution as well as on the ribosomal particle. On the basis of our analysis, it can be inferred that the P1A-P2B protein complex may be regarded as the key element in stalk formation, having structural and functional importance, whereas P1B-P2A protein complex is implicated in regulation of stalk function. The mechanism of quaternary structure formation could be described as a sequential co-folding/association reaction of an oligomeric system with P0-(P1A-P2B) protein complex as an essential element in the acquisition of a stable quaternary structure of the ribosomal stalk. On the other hand, the P1B-P2A complex is not involved in the cooperative stalk formation and our results indicate an increased rate of protein synthesis due to the latter protein pair.