Studies on ribosomal proteins in the cellular slime mold Dictyostelium discoideum. Resolution, nomenclature and molecular weights of proteins in the 40-S and 60-S ribosomal subunits

Effects of mercury on Dictyostelium discoideum: proteomics reveals the molecular mechanisms of physiological adaptation and toxicity

Dictyostelium discoideum amoebae were exposed to Hg 2 microM corresponding to a sublethal concentration and Hg 10 microM with the first effects on mortality and replication rate. A total of 900 spots were visualized by 2-DE electrophoresis. Two-hundred fifty single proteins were identified by mass spectrometry. Low Hg concentration (2 microM) treatment induced up-regulation of 13 spots, mainly involved in oxidative stress response/detoxification, oxidoreductase activity, and metabolic processes. High Hg concentration (10 microM) treatment showed a different PES with 12 proteins downregulated and only two up-regulated, mainly involved in cellular metabolic processes, metal ion binding, and transferase activity. The analyses for the carbonylation show no changes after 2 microM Hg(2+) treatment and 13 differentially carbonylated proteins after 10 microM Hg(2+) involved in a broad range of cellular processes. Our findings provide insight into the mechanisms of physiological adaptation and toxicity to a low and an high mercury concentration, respectively, of Dictyostelium amoebae.

Regulation of synthesis of cell-specific ribosomal proteins during differentiation of Dictyostelium discoideum

Proteins of ribosomes from various stages of development in Dictyostelium discoideum were analyzed by two-dimensional polyacrylamide gel electrophoresis. Significant changes in protein composition were observed; the data demonstrate that cell differentiation in a eukaryotic system is accompanied by ribosome heterogeneity. Both qualitative and quantitative differences were noted for 12 unique ribosomal proteins between the vegetative amoebae and spores (differentiated cells). Two proteins were specific to ribosomes of amoebae, and three were specific to spores. The others were common to both cells but showed characteristic stoichiometric changes. The appearance and quantitative changes of these proteins were associated with specific stages of cell differentiation and were evident only during the aggregation phase; however, further changes continued through construction of fruiting bodies. As functional mRNAs for all 12 proteins were present in both amoebae and spores, both transcriptional and translational mechanisms apparently regulate the synthesis of the various developmentally controlled ribosomal proteins in the two cell types.

Comparative analysis of the ribosomal components of the hydrogenosome-containing protist, Trichomonas vaginalis

The ribosomes of the amitochondriate but hydrogenosome-containing protist lineage, the trichomonads, have previously been reported to be prokaryotic or primitive eukaryotic, based on evidence that they have a 70S sedimentation coefficient and a small number of proteins, similar to prokaryotic ribosomes. In order to determine whether the components of the trichomonad ribosome indeed differ from those of typical eukaryotic ribosomes, the ribosome of a representative trichomonad, Trichomonas vaginalis, was characterized. The sedimentation coefficient of the T. vaginalis ribosome was smaller than that of Saccharomyces cerevisiae and larger than that of Escherichia coli. Based on two-dimensional PAGE analysis, the number of different ribosomal proteins was estimated to be approximately 80. This number is the same as those obtained for typical eukaryotes (approximately 80) but larger than that of E. coli (approximately 55). N-Terminal amino acid sequencing of 18 protein spots and the complete sequences of 4 ribosomal proteins as deduced from their genes revealed these sequences to display typical eukaryotic features. Phylogenetic analyses of the five ribosomal proteins currently available also clearly confirmed that the T. vaginalis sequences are positioned within a eukaryotic clade. Comparison of deduced secondary structure models of the small and large subunit rRNAs of T. vaginalis with those of other eukaryotes revealed that all helices commonly found in typical eukaryotes are present and conserved in T. vaginalis, while variable regions are shortened or lost. These lines of evidence demonstrate that the T. vaginalis ribosome has no prokaryotic or primitive eukaryotic features but is clearly a typical eukaryotic type.

L10 ribosomal protein from Entamoeba histolytica share structural and functional homologies with QM/Jif-1: proteins with extraribosomal functions

In the present work, the complete amino acid sequence of the Entamoeba histolytica ribosomal protein L10 (EhL10) is reported. cDNA of 630bp revealed an open reading frame that encodes a protein of 210 amino acids. Analysis of EhL10 ribosomal protein revealed 75% similarity and 57% identity with QM protein from Homo sapiens and 78 and 60%, respectively, with Arabidopsis thaliana. Western blot analysis of ribosomal proteins from E. histolytica showed that EhL10 protein is part of the ribosomal complex. Immunofluorescence analysis of EhL10 distribution in a transfected E. histolytica strain showed that EhL10 protein was mainly localized in the nucleus of trophozoites. Overexpression of EhL10 ribosomal protein in trophozoites transfected with the pExEhNeo/EhL10 vector exhibited a 60% reduction in cellular growth. DNA mobility-shift assays demonstrated that EhL10 ribosomal protein was able to destabilize the activating protein 1 (AP-1) complex binding specifically to the c-Jun-like protein. It is proposed in this study that the complex formation of EhL10 with c-Jun-like protein interferes with transcriptional activation of genes controlled by Jun (i.e. gene involved in cell growth). It is also being reported identification of a member of the AP-1 complex, the c-Jun-like protein, in nuclear extracts of E. histolytica using human-specific antibodies against this protein. The observations suggest that EhL10 may have an extraribosomal function in E. histolytica involved in suppression of cell proliferation in E. histolytica similar to the QM protein.

Synthesis of ribosomal proteins in developing Dictyostelium discoideum cells is controlled by the methylation of proteins S24 and S31

Ribosomal protein mRNAs left over from growth are selectively excluded from polyribosomes in the first half of Dictyostelium discoideum development. This is due to the fact that they are sequestered by a class of free 40S ribosomal subunits, characterized by possessing a methylated S24 protein. At the time of formation of tight cell aggregates, the methylated S24 is substituted by an unmethylated S24, while protein S31 of the same or other 40S subunits becomes methylated. This leads to a rapid degradation of the ribosomal protein mRNAs.

Induction of ribosomal subunits misassembly by antisense RNAs to control cell growth

The assembly of ribosomal subunits starting from free ribosomal RNA and protein of Dictyostelium discoideum was induced in vitro in the presence of several oligoribonucleotides complementary to defined sequences of ribosomal RNA. The reconstituted particles had a full complement of ribosomal proteins, but did not function in an in vitro protein synthesis system and were disassembled following interaction with mRNA. The same result was obtained in vivo by fusing the oligodeossiribonucleotides coding for the selected oligoribonucleotides to the promoter of the gene coding for contact site A protein. This gene is expressed only in the first part of development. Transfected growing cells, transferred in developing buffer in the presence of pulses of cAMP, accumulated significant amounts of the oligoribonucleotides. When retransferred to the growth medium, they grew progressively more slowly, until their doubling time doubled, apparently due to the availability of a limiting amount of functional ribosomes. To avoid disassembly of misassembled subunits (G. Mangiarotti et al., 1997, J. Biol. Chem. 272, 27818-27822), two oligoribonucleotides complementary to sequences present at the 5' ends of pre-17S and pre-26S RNAs were also induced to accumulate during early development with the same technique. When transfected cells were retransferred to the growth medium, their rate of growth declined rapidly to zero and cells died, apparently because they were unable to disassemble misassembled ribosomal subunits and avoid their entry into polyribosomes. This technique to perturb protein synthesis, arrest cell growth, and cause cell suicide will be tested in abnormally growing animal cells.

rRNA maturation as a "quality" control step in ribosomal subunit assembly in Dictyostelium discoideum

In Dictyostelium discoideum, newly assembled ribosomal subunits enter polyribosomes while they still contain immature rRNA. rRNA maturation requires the engagement of the subunits in protein synthesis and leads to stabilization of their structure. Maturation of pre-17 S rRNA occurs only after the newly formed 40 S ribosomal particle has entered an 80 S ribosome and participated at least in the formation of one peptide bond or in one translocation event; maturation of pre-26 S rRNA requires the presence on the 80 S particle of a peptidyl-tRNA containing at least 6 amino acids. Newly assembled particles that cannot fulfill these requirements for structural reasons are disassembled into free immature rRNA and ribosomal proteins.

Reconstitution of functional eukaryotic ribosomes from Dictyostelium discoideum ribosomal proteins and RNA

40 and 60 S ribosomal subunits have been reconstituted in vitro from purified ribosomal RNA and ribosomal proteins of Dictyostelium discoideum. The functionality of the reconstituted ribosomes was demonstrated in in vitro mRNA-directed protein synthesis. The reassembly proceeded well with immature precursors of ribosomal RNA but poorly if at all with mature cytoplasmic RNA species. Reassembly also required a preparation of small nuclear RNA(s), acting as morphopoietic factor(s).

Ribosomes from trichomonad protozoa have prokaryotic characteristics

1. Ribosomes from cells of the genera Trichomonas and Tritrichomonas have been isolated and characterized. The ribosomes from each organism had a sedimentation coefficient of 70S in calibrated sucrose gradients and the subunits sedimented as 50S and 30S particles under the same conditions. 2. The major ribosomal RNAs from each species were identical in size to prokaryotic ribosomal RNAs when examined by denaturing gel electrophoresis. The ribosomes contained both 5.8S and 5S RNAs. 3. The ribosomal proteins were compared by the methods of two-dimensional gel electrophoresis and reversed phase HPLC. Electrophoresis of the ribosomal proteins in two different gel systems indicated the presence of 56 proteins in T. gallinae, 40 in T. bactrachorum and 45 in the Tritrichomonas sp. The protein molecular mass range was 8.5-40 kDa. 4. The HPLC analysis confirmed the protein number established by the gel methods. 5. Both methods of analysis revealed greater similarities between the ribosomal proteins of the 2 Tritrichomonas sp. than between those of the more distantly related T. gallinae and T. bactrachorum.

Dictyostelium discoideum acidic ribosomal phosphoproteins: identification and in vitro phosphorylation

Four acidic phosphoproteins from the ribosomes of the slime mold Dictyostelium discoideum have been identified and partially characterized. These proteins are selectively released from ribosomal particles by salt/ethanol washes, have low molecular weight and acidic pI, and tend to aggregate in solution to form homodimers. These features correspond to proteins of different origins that have been included in the conserved family of eukaryotic A-ribosomal proteins, and, therefore, we have named them Dictyostelium ribosomal proteins A1, A2, A3 and A4. We also demonstrate that Dictyostelium ribosomal A-proteins are specifically phosphorylated in vitro by a type II casein kinase previously identified in Dictyostelium. Isoelectric focusing separation has permitted us to identify four proteins (or P-proteins) that may consist of the phosphorylated forms of A-proteins. A-proteins from Dictyostelium and yeast do not present immunological cross-reactivity. Dictyostelium A-proteins contain, therefore, some specific features in their amino acid sequence that distinguish them from other members of the conserved eukaryotic A-protein family; this conclusion is coherent with data deduced from the nucleotide sequence of cDNA clones encoding two Dictyostelium A-proteins (P1 and P2) which we have recently reported.

Identification and characterization of a Dictyostelium discoideum ribosomal protein gene

We have identified a developmentally repressed large-subunit ribosomal protein gene of Dictyostelium discoideum based on sequence similarity to other ribosomal proteins. Protein rpl7 is homologous to large subunit ribosomal proteins from the rat and possibly to Mycoplasma capricolum and Escherichia coli, but is not similar to three sequenced ribosomal proteins in Dictyostelium. The rpl7 gene is present at one copy per genome, as are six other cloned Dictyostelium ribosomal proteins. Restriction fragment length polymorphisms exist for ribosomal protein genes rpl7, rp1024, and rp110 in strain HU182; most Dictyostelium ribosomal protein genes examined are linked no closer than 30-100 kb to each other in the genome. Dictyostelium ribosomal proteins are known to be developmentally regulated, and levels of rpl7 transcript gradually decrease during the 24-hour development cycle. This drop correlates with that of rp1024, indicating these and other ribosomal protein genes may be coordinately regulated. To determine the cellular location of the protein, we raised antibodies to an rpl7-derived branched synthetic peptide. These antibodies cross-reacted with one protein of the expected size in a ribosomal protein fraction of Dictyostelium, indicating that the product of gene rpl7 is localized in the ribosome.

Identification and characterization of developmentally regulated mRNP proteins of Dictyostelium discoideum

The isolation of poly(A)+ polysomal and nonpolysomal RNPs by oligo(dT)-cellulose chromatography has led to the identification of more than 20 polypeptides that bind to the poly(A)+ mRNA in growing Dictyostelium cells. Most of these polypeptides were identified in experiments using short-wave UV light (254 nm) to crosslink specifically bound proteins to the RNA. Digestion of the RNPs with ribonucleases A and T1 prior to their application to oligo(dT)-cellulose permitted the isolation of the 3' poly(A)-protein complexes. In polysomal RNPs, two major polypeptides, with molecular weights of 31,000 (p31) and 31,500 (p31.5), are bound to poly(A). These proteins can also be purified from cytoplasmic extracts by affinity chromatography on poly(A)-Sepharose. Partial proteolytic digestion of p31 and p31.5 indicates that they are closely related. The UV-crosslinking experiments established that p31 and p31.5 bind to the non-poly(A) segments of mRNA as well. In nonpolysomal RNPs, p31 and a polypeptide with a molecular weight of 29,500 (p29.5) are the major species associated with poly(A). Partial proteolytic digestion of p29.5 indicates that it is closely related to p31 and p31.5. Only small amounts of p29.5 were observed in the polysomal poly(A)-protein complexes. Early in Dictyostelium development, when cellular translation activity is sharply reduced, most of the p29.5, p31 and p31.5 present is selectively degraded. These observations are consistent with a translational role for these proteins.

Immunological homologies between ribosomal proteins amongst lower eukaryotes

Polyclonal antibodies were raised against the purified ribosomal proteins L1 and L2, the 5S rRNA binding protein L3, all from Saccharomyces cerevisiae, and against L1 and L2 from Schizosaccharomyces pombe (numbering according to Otaka and Osawa 1981; Otaka et al. 1983, respectively). For clarity prefixes Sc and Sp have been added to the numbering of proteins derived from S. cerevisiae and S. pombe, respectively. Ribosomal proteins from these yeasts and from Kluyveromyces marxianus, Rhodotorula glutinis, the slime mold Dictyostelium discoideum and the protozoan Tetrahymena thermophila were checked for antigenic cross-reactivity by the immunoblot technique. Anti-ScL1 bound to the largest ribosomal proteins of all organisms but not with equal strength. A fast migrating protein band from R. glutinis was also reactive. Anti-ScL2 reacted strongly with L2 or analogous proteins derived exclusively from the yeasts. Anti-ScL3 cross-reacted only with one protein band from K. marxianus, whereas anti-SpL1 cross-reacted with L1 or its analogues from the other organisms, but also with proteins of lower molecular weight. In S. cerevisiae, these proteins are located exclusively on the small ribosomal subunit. L2 or analogous ribosomal proteins of all organisms were recognized by anti-SpL2 but additionally the ribosomal protein YL28 of S. cerevisiae and fast migrating proteins of T. thermophila exhibited anti-SpL2 binding.

Conservation and variation of ribosomal proteins in several species of the cellular slime molds Dictyostelium and Polysphondylium

Genus- and species-specific composition of ribosomal proteins was investigated in four species of the genus Dictyostelium (D. discoideum, D. purpureum, D. murcoroides and D. giganteum) and two species of the genus Polysphondylium (P. pallidum and P. violaceum). Ribosomal proteins were resolved by a high-resolution, two-dimensional gel method. In general, the numbers and distributions for the majority of ribosomal proteins were similar within the species of each genus, although some differences were detected. More differences were observed between Dictyostelium and Polysphondylium than among the individual species within each genus. Stage-specific ribosomal proteins previously demonstrated in D. discoideum were found to be developmentally regulated in other Dictyostelium species, and in both Polysphondylium species. The study shows that ribosomal proteins may be a potentially useful new biochemical parameter for the molecular taxonomy of the cellular slime molds.

Metabolic changes in ribosomes of Escherichia coli during prolonged culture in different media

The metabolism of ribosomes during the exponential growth and post-exponential phase of Escherichia coli cells was investigated. Incubation of E. coli cells in two rich media: L-broth and phosphate medium, up to stationary phase shows no drop in viability or any changes in ribosomes. However, the survival rate during prolonged culture of the post-stationary-phase cells has been found to be a function of the incubation medium. The decline in viability is only slight in phosphate medium but very rapid in L-broth. So long as the viability is maintained, the level of ribosomes and the relative abundance of rRNA and ribosomal proteins in ribosomes of the post-stationary cultures are remarkably stable and are similar to exponentially growing cells. On the other hand, post-stationary cultures undergoing a rapid drop in cell viability lose 95% of the original ribosomes. These cultures accumulate a large pool of 30S and 50S subunits and a few 70S monosomes, all of which show deficiency in the various ribosomal proteins. No differences in rRNA can be detected but the number and the relative stoichiometry of individual ribosomal proteins are drastically altered. Only 13 of the 53 proteins known in the E. coli ribosome appeared in the same relative amounts as in the ribosomes of the exponentially growing cells. Six proteins (S12, S21, L2, L16, L20, L34) are completely lost and all others undergo partial loss. An analysis of the number and relative abundance of ribosomal proteins in the whole cells, as oppossed to isolated ribosomes, suggests that during the initial stages of the catabolism of ribosomes a crucial step is the formation of ribosomal-subunit-membrane complexes. The data emphasize the role of the constituents of ribosomes not only for the growth but also for the survival of E. coli cells. A model for the metabolism of ribosomes during the exponential growth and post-exponential phase of E. coli is presented.

Conformation of ribosomes from the vegetative amoebae and spores of Dictyoistelium discoideum

Ribosomes from two different cell types of D. discoideum--the undifferentiated amoebae and the differentiated spores--display considerable differences in protein composition (Ramagopal and Ennis 1979 and manuscript in preparation). These differences do not affect the three-dimensional structure of monosomes and large (60S) and small (40S) subunits from the two cell types to an extent detectable by sedimentation analysis or electron microscopy. High resolution electron microscopic images of ribosomal particles from the amoebae and the spores are similar and, in general, comparable to that of 80S, 60S, and 40S ribosomal particles from other eukaryotic sources. However, distinct differences in the conformation and stability of the two types of ribosomes are detectable by circular dichroic spectroscopy. The degree of the ordered secondary structure of rRNAs is similar in the 80S monosomes from the amoebae and the spores, but higher in the amoeba subunits. The results of thermal melting experiments show that the small subunit from the spores is more stable than that from the amoebae. The established differences in the conformation of rRNAs, most probably due to the interactions with cell-specific ribosomal proteins, can be responsible for the differences in stability of ribosomes from the two cell types of slime mold.