Gliding Motility and Por Secretion System Genes Are Widespread among Members of the Phylum Bacteroidetes

The phylum Bacteroidetes is large and diverse, with rapid gliding motility and the ability to digest macromolecules associated with many genera and species. Recently, a novel protein secretion system, the Por secretion system (PorSS), was identified in two members of the phylum, the gliding bacterium Flavobacterium johnsoniae and the nonmotile oral pathogen Porphyromonas gingivalis. The components of the PorSS are not similar in sequence to those of other well-studied bacterial secretion systems. The F. johnsoniae PorSS genes are a subset of the gliding motility genes, suggesting a role for the secretion system in motility. The F. johnsoniae PorSS is needed for assembly of the gliding motility apparatus and for secretion of a chitinase, and the P. gingivalis PorSS is involved in secretion of gingipain protease virulence factors. Comparative analysis of 37 genomes of members of the phylum Bacteroidetes revealed the widespread occurrence of gliding motility genes and PorSS genes. Genes associated with other bacterial protein secretion systems were less common. The results suggest that gliding motility is more common than previously reported. Microscopic observations confirmed that organisms previously described as nonmotile, including Croceibacter atlanticus, “Gramella forsetii,” Paludibacter propionicigenes, Riemerella anatipestifer, and Robiginitalea biformata, exhibit gliding motility. Three genes (gldA, gldF, and gldG) that encode an apparent ATP-binding cassette transporter required for F. johnsoniae gliding were absent from two related gliding bacteria, suggesting that the transporter may not be central to gliding motility.     

Reduced ribosomes of the apicoplast and mitochondrion of Plasmodium spp. and predicted interactions with antibiotics

Apicomplexan protists such as Plasmodium and Toxoplasma contain a mitochondrion and a relic plastid (apicoplast) that are sites of protein translation. Although there is emerging interest in the partitioning and function of translation factors that participate in apicoplast and mitochondrial peptide synthesis, the composition of organellar ribosomes remains to be elucidated. We carried out an analysis of the complement of core ribosomal protein subunits that are encoded by either the parasite organellar or nuclear genomes, accompanied by a survey of ribosome assembly factors for the apicoplast and mitochondrion. A cross-species comparison with other apicomplexan, algal and diatom species revealed compositional differences in apicomplexan organelle ribosomes and identified considerable reduction and divergence with ribosomes of bacteria or characterized organelle ribosomes from other organisms. We assembled structural models of sections of Plasmodium falciparum organellar ribosomes and predicted interactions with translation inhibitory antibiotics. Differences in predicted drug–ribosome interactions with some of the modelled structures suggested specificity of inhibition between the apicoplast and mitochondrion. Our results indicate that Plasmodium and Toxoplasma organellar ribosomes have a unique composition, resulting from the loss of several large and small subunit proteins accompanied by significant sequence and size divergences in parasite orthologues of ribosomal proteins.     

Effects of aminoethylation of cysteine residues on the structural and functional activities of the Escherichia coli 30 S ribosomal proteins

The purified 30 S ribosomal proteins from Escherichia coli strain Q13 were chemically modified by reaction with ethyleneimine, specifically converting cysteine residues to S-2-aminoethylcysteine residues. Proteins S1, S2, S4, S8, S11, S12, S13, S14, S17, S18 and S21 were found to contain aminoethylcysteine residues after modification, whereas proteins S3, S5, S6, S7, S9, S10, S15, S16, S19 and S20 did not. Aminoethylated proteins S4, S13, S17 and S18 were active in the reconstitution of 30 S ribosomes and did not have altered functional activities in poly(U)-dependent polyphenylalanine synthesis, R17-dependent protein synthesis, fMet-tRNA binding and Phe-tRNA binding. Aminoethylated proteins S2, S11, S12, S14 and S21 were not active in the reconstitution of complete 30 S ribosomes, either because the aminoethylated protein did not bind stably to the ribosome (S2, S11, S12 and S21) or because the aminoethylated protein did not stabilize the binding of other ribosomal proteins (S14). The functional activities of 30 S ribosomes reconstituted from a mixture of proteins containing one sensitive aminoethylated protein (S2, S11, S12, S14 or S21) were similar to ribosomes reconstituted from mixtures lacking that protein. These results imply that the sulfhydryl groups of the proteins S4, S13, S17 and S18 are not necessary for the structural or functional activities of these proteins, and that aminoethylation of the sulfhydryl groups of S2, S11, S12, S14 and S21 forms either a kinetic or thermodynamic barrier to the assembly of active 30 S ribosomes in vitro.     

Novel Features of the Polysaccharide-Digesting Gliding Bacterium Flavobacterium johnsoniae as Revealed by Genome Sequence Analysis

The 6.10-Mb genome sequence of the aerobic chitin-digesting gliding bacterium Flavobacterium johnsoniae (phylum Bacteroidetes) is presented. F. johnsoniae is a model organism for studies of bacteroidete gliding motility, gene regulation, and biochemistry. The mechanism of F. johnsoniae gliding is novel, and genome analysis confirms that it does not involve well-studied motility organelles, such as flagella or type IV pili. The motility machinery is composed of Gld proteins in the cell envelope that are thought to comprise the “motor” and SprB, which is thought to function as a cell surface adhesin that is propelled by the motor. Analysis of the genome identified genes related to sprB that may encode alternative adhesins used for movement over different surfaces. Comparative genome analysis revealed that some of the gld and spr genes are found in nongliding bacteroidetes and may encode components of a novel protein secretion system. F. johnsoniae digests proteins, and 125 predicted peptidases were identified. F. johnsoniae also digests numerous polysaccharides, and 138 glycoside hydrolases, 9 polysaccharide lyases, and 17 carbohydrate esterases were predicted. The unexpected ability of F. johnsoniae to digest hemicelluloses, such as xylans, mannans, and xyloglucans, was predicted based on the genome analysis and confirmed experimentally. Numerous predicted cell surface proteins related to Bacteroides thetaiotaomicron SusC and SusD, which are likely involved in binding of oligosaccharides and transport across the outer membrane, were also identified. Genes required for synthesis of the novel outer membrane flexirubin pigments were identified by a combination of genome analysis and genetic experiments. Genes predicted to encode components of a multienzyme nonribosomal peptide synthetase were identified, as were novel aspects of gene regulation. The availability of techniques for genetic manipulation allows rapid exploration of the features identified for the polysaccharide-digesting gliding bacteroidete F. johnsoniae.Flavobacterium johnsoniae (formerly Cytophaga johnsonae) is a member of the large and diverse phylum of gram-negative bacteria known as the Bacteroidetes. Members of this group of organisms have a number of unique characteristics that distinguish them from other bacteria. Some have novel cell surface machinery to utilize polysaccharides (85, 95, 96). Rapid gliding motility over surfaces is also common among these bacteria (59), as are unusual outer membrane sulfonolipids (29) and flexirubin pigments (78). Bacteroidete gene expression and regulation also have novel aspects (10, 11, 20, 39, 92). The many unusual features of these common but understudied bacteria provide numerous avenues for further exploration, which can be greatly aided by analysis of genome sequences.F. johnsoniae digests many polysaccharides and proteins, but it is best known for its ability to rapidly digest insoluble chitin (87). Chitin is one of the most abundant biopolymers on earth (63). F. johnsoniae and other members of the Bacteroidetes phylum are thought to play important roles in the turnover of this compound in many environments (47). F. johnsoniae has become a model system for the study of bacteroidete gliding motility biochemistry and molecular biology (20, 27-29, 59, 72). This paper highlights novel features of the F. johnsoniae genome, with particular emphasis on genes and proteins likely to be involved in polysaccharide utilization, gliding motility, and the novel biochemistry of this organism.     

Flavobacterium johnsoniae Chitinase ChiA Is Required for Chitin Utilization and Is Secreted by the Type IX Secretion System

Flavobacterium johnsoniae, a member of phylum Bacteriodetes, is a gliding bacterium that digests insoluble chitin and many other polysaccharides. A novel protein secretion system, the type IX secretion system (T9SS), is required for gliding motility and for chitin utilization. Five potential chitinases were identified by genome analysis. Fjoh_4555 (ChiA), a 168.9-kDa protein with two glycoside hydrolase family 18 (GH18) domains, was targeted for analysis. Disruption of chiA by insertional mutagenesis resulted in cells that failed to digest chitin, and complementation with wild-type chiA on a plasmid restored chitin utilization. Antiserum raised against recombinant ChiA was used to detect the protein and to characterize its secretion by F. johnsoniae. ChiA was secreted in soluble form by wild-type cells but remained cell associated in strains carrying mutations in any of the T9SS genes, gldK, gldL, gldM, gldNO, sprA, sprE, and sprT. Western blot and liquid chromatography-tandem mass spectrometry (LC-MS/MS) analyses suggested that ChiA was proteolytically processed into two GH18 domain-containing proteins. Proteins secreted by T9SSs typically have conserved carboxy-terminal domains (CTDs) belonging to the TIGRFAM families TIGR04131 and TIGR04183. ChiA does not exhibit strong similarity to these sequences and instead has a novel CTD. Deletion of this CTD resulted in accumulation of ChiA inside cells. Fusion of the ChiA CTD to recombinant mCherry resulted in secretion of mCherry into the medium. The results indicate that ChiA is a soluble extracellular chitinase required for chitin utilization and that it relies on a novel CTD for secretion by the F. johnsoniae T9SS.     

Flavobacterium johnsoniae gldN and gldO Are Partially Redundant Genes Required for Gliding Motility and Surface Localization of SprB

Cells of the gliding bacterium Flavobacterium johnsoniae move rapidly over surfaces. Mutations in gldN cause a partial defect in gliding. A novel bacteriophage selection strategy was used to aid construction of a strain with a deletion spanning gldN and the closely related gene gldO in an otherwise wild-type F. johnsoniae UW101 background. Bacteriophage transduction was used to move a gldN mutation into F. johnsoniae UW101 to allow phenotypic comparison with the gldNO deletion mutant. Cells of the gldN mutant formed nonspreading colonies on agar but retained some ability to glide in wet mounts. In contrast, cells of the gldNO deletion mutant were completely nonmotile, indicating that cells require GldN, or the GldN-like protein GldO, to glide. Recent results suggest that Porphyromonas gingivalis PorN, which is similar in sequence to GldN, has a role in protein secretion across the outer membrane. Cells of the F. johnsoniae gldNO deletion mutant were defective in localization of the motility protein SprB to the cell surface, suggesting that GldN may be involved in secretion of components of the motility machinery. Cells of the gldNO deletion mutant were also deficient in chitin utilization and were resistant to infection by bacteriophages, phenotypes that may also be related to defects in protein secretion.Cells of Flavobacterium johnsoniae, and of many other members of the phylum Bacteroidetes, crawl over surfaces at approximately 2 μm/s in a process called gliding motility. F. johnsoniae cells glide on agar, glass, polystyrene, Teflon, and many other surfaces (16, 22). Cells suspended in liquid also bind and propel added particles such as polystyrene latex spheres (23). The mechanism of this form of cell movement is not well understood despite decades of research (15). Genome analyses suggest that F. johnsoniae gliding is genetically unrelated to other well-studied forms of bacterial movement such as bacterial flagellar motility, type IV pilus-mediated twitching motility, myxobacterial gliding motility, and mycoplasma gliding motility (10, 20, 21). Genes and proteins required for F. johnsoniae motility have been identified (1-3, 7-9, 17, 18). GldA, GldF, and GldG appear to form an ATP-binding cassette transporter that is required for gliding (1, 7). Eight other Gld proteins (GldB, GldD, GldH, GldI, GldJ, GldK, GldL, and GldM) are also required for movement (2, 3, 8, 9, 17, 18). Many of these are unique to members of the phylum Bacteroidetes. Disruption of the genes encoding any of these 11 proteins results in complete loss of motility. The mutants form nonspreading colonies, and individual cells exhibit no movement on agar, glass, Teflon, and other surfaces tested. The Gld proteins are associated with the cell envelope and presumably constitute the gliding motor, but none of them appear to be exposed on the cell surface. Mutations in sprA and sprB, which encode cell surface proteins, result in partial motility defects. Cells form nonspreading colonies, but some of the cells exhibit limited movement in wet mounts. SprA is required for efficient attachment to glass (22), and SprB appears to be a mobile adhesin that is propelled along the cell surface by the gliding motor and thus transmits the force generated by the motor to the surface over which cells crawl (10, 21). The surface localization of SprA and SprB and the phenotypes of sprA and sprB mutants suggest that the gliding motor is at least partially functional in these mutants but that force is inefficiently transmitted to the substratum. Analysis of the F. johnsoniae genome revealed the presence of multiple paralogs of sprB, which may explain the residual motility of sprB mutants (20).gldN lies downstream of gldL and gldM, and the three genes constitute an operon (2). Cells with transposon insertions in gldN form nonspreading colonies that are indistinguishable from those of other gld mutants. However, unlike other gld mutants, gldN mutants exhibit some residual ability to glide in wet mounts (2). One possible explanation for this phenotype is that GldN may have a peripheral and nonessential role in gliding. Alternatively, GldN may perform a critical function in gliding, but in its absence another cellular protein may compensate for the missing GldN function. F. johnsoniae has a gldN paralog, gldO, that is located downstream of gldN but is transcribed independently (2). The GldN and GldO proteins are 85% identical over their entire lengths, making GldO a prime candidate for a protein that might compensate for lack of GldN.Recent results suggest that some of the F. johnsoniae Gld and Spr proteins, including GldN, may be components of a novel bacteroidete protein translocation apparatus referred to as the Por secretion system (PorSS) (28). This conclusion emerged from studies of gingipain protease secretion by the distantly related nonmotile bacteroidete Porphyromonas gingivalis. P. gingivalis is a human periodontal pathogen, and gingipain proteases are important virulence factors. Gingipains have signal peptides that allow export across the cytoplasmic membrane via the Sec machinery, but they rely on components of the PorSS for secretion across the outer membrane (27-29). P. gingivalis cells with mutations in genes homologous to F. johnsoniae gldK, gldL, gldM, gldN, and sprA are defective in gingipain secretion across the outer membrane (28). F. johnsoniae has a homologue to another P. gingivalis gene required for gingipain secretion, porT. Disruption of the F. johnsoniae porT homologue (referred to as sprT) results in motility defects and defects in surface localization of SprB (28).This study was designed to identify possible roles for GldN in motility and to determine whether GldN and GldO are partially redundant components of the motility apparatus. The results demonstrate that F. johnsoniae GldN has an important function in motility and that GldO can replace GldN in this role. They suggest that GldN is needed for efficient secretion of the cell surface motility protein SprB, which may explain some of the motility defects of the gldN mutants.     

Flavobacterium johnsoniae PorV Is Required for Secretion of a Subset of Proteins Targeted to the Type IX Secretion System

Flavobacterium johnsoniae exhibits gliding motility and digests many polysaccharides, including chitin. A novel protein secretion system, the type IX secretion system (T9SS), is required for gliding and chitin utilization. The T9SS secretes the cell surface motility adhesins SprB and RemA and the chitinase ChiA. Proteins involved in secretion by the T9SS include GldK, GldL, GldM, GldN, SprA, SprE, and SprT. Porphyromonas gingivalis has orthologs for each of these that are required for secretion of gingipain protease virulence factors by its T9SS. P. gingivalis porU and porV have also been linked to T9SS-mediated secretion, and F. johnsoniae has orthologs of these. Mutations in F. johnsoniae porU and porV were constructed to determine if they function in secretion. Cells of a porV deletion mutant were deficient in chitin utilization and failed to secrete ChiA. They were also deficient in secretion of the motility adhesin RemA but retained the ability to secrete SprB. SprB is involved in gliding motility and is needed for formation of spreading colonies on agar, and the porV mutant exhibited gliding motility and formed spreading colonies. However, the porV mutant was partially deficient in attachment to glass, apparently because of the absence of RemA and other adhesins on the cell surface. The porV mutant also appeared to be deficient in secretion of numerous other proteins that have carboxy-terminal domains associated with targeting to the T9SS. PorU was not required for secretion of ChiA, RemA, or SprB, indicating that it does not play an essential role in the F. johnsoniae T9SS.     

Turnover of chloroplast and cytoplasmic ribosomes during gametogenesis in Chlamydomonas reinhardi

A number of novel observations on ribosomal metabolism were made during gametic differentiation of Chlamydomonas reinhardi. Throughout the gametogenic process the amount of chloroplast and cytoplasmic ribosomes decreased steadily. The kinetics and extent of such decreases were different for each of the two ribosomal species. Comparable rRNA degradation accompanied this ribosome degradation. Concurrent with the substantial ribosome degradation was the synthesis of rRNA, ribosomal proteins and the assembly of new chloroplast and cytoplasmic ribosomes throughout gametogenesis. The newly synthesized chloroplast ribosomes exhibited distinctively faster turnover than their cytoplasmic counterpart. Cytoplasmic ribosomes, pulse-labeled in early gametogenic stages, retained label until differentiation was nearly complete even though a net decrease in the level of cytoplasmic ribosomes continued, indicating that the newly synthesized cytoplasmic ribosomes were preferentially retained during differentiation. Hence the regulation of ribosome metabolism during gametogenesis contrasts with the conservation of ribosomes obtained during vegetative growth of C. reinhardi and other organisms. This unique pattern of ribosome metabolism suggests that new ribosome synthesis is necessary during gametogenesis and that some specific structural or functional difference relating to the development stage of the life cycle might exist between degraded and newly synthesized ribosomes.     

Translation activity of chimeric ribosomes composed of Escherichia coli and Bacillus subtilis or Geobacillus stearothermophilus subunits

Ribosome composition, consisting of rRNA and ribosomal proteins, is highly conserved among a broad range of organisms. However, biochemical studies focusing on ribosomal subunit exchangeability between organisms remain limited. In this study, we show that chimeric ribosomes, composed of Escherichia coli and Bacillus subtilis or E. coli and Geobacillus stearothermophilus subunits, are active for β-galactosidase translation in a highly purified E. coli translation system. Activities of the chimeric ribosomes showed only a modest decrease when using E. coli 30 S subunits, indicating functional conservation of the 50 S subunit between these bacterial species.     

Dynamic proton-dependent motors power type IX secretion and gliding motility in Flavobacterium

Motile bacteria usually rely on external apparatus like flagella for swimming or pili for twitching. By contrast, gliding bacteria do not rely on obvious surface appendages to move on solid surfaces. Flavobacterium johnsoniae and other bacteria in the Bacteroidetes phylum use adhesins whose movement on the cell surface supports motility. In F. johnsoniae, secretion and helicoidal motion of the main adhesin SprB are intimately linked and depend on the type IX secretion system (T9SS). Both processes necessitate the proton motive force (PMF), which is thought to fuel a molecular motor that comprises the GldL and GldM cytoplasmic membrane proteins. Here, we show that F. johnsoniae gliding motility is powered by the pH gradient component of the PMF. We further delineate the interaction network between the GldLM transmembrane helices (TMHs) and show that conserved glutamate residues in GldL TMH2 are essential for gliding motility, although having distinct roles in SprB secretion and motion. We then demonstrate that the PMF and GldL trigger conformational changes in the GldM periplasmic domain. We finally show that multiple GldLM complexes are distributed in the membrane, suggesting that a network of motors may be present to move SprB along a helical path on the cell surface. Altogether, our results provide evidence that GldL and GldM assemble dynamic membrane channels that use the proton gradient to power both T9SS-dependent secretion of SprB and its motion at the cell surface.

Motile bacteria usually rely on external apparatus like flagella or pili, but gliding bacteria do not rely on obvious surface appendages for their movement. This study shows that bacteria in the phylum Bacteroidetes use proton-dependent motors to power protein secretion and gliding motility.     

Widespread use of unconventional targeting signals in mitochondrial ribosome proteins

Mitochondrial ribosomes are complex molecular machines indispensable for respiration. Their assembly involves the import of several dozens of mitochondrial ribosomal proteins (MRPs), encoded in the nuclear genome, into the mitochondrial matrix. Proteomic and structural data as well as computational predictions indicate that up to 25% of yeast MRPs do not have a conventional N‐terminal mitochondrial targeting signal (MTS). We experimentally characterized a set of 15 yeast MRPs in vivo and found that five use internal MTSs. Further analysis of a conserved model MRP, Mrp17/bS6m, revealed the identity of the internal targeting signal. Similar to conventional MTS‐containing proteins, the internal sequence mediates binding to TOM complexes. The entire sequence of Mrp17 contains positive charges mediating translocation. The fact that these sequence properties could not be reliably predicted by standard methods shows that mitochondrial protein targeting is more versatile than expected. We hypothesize that structural constraints imposed by ribosome assembly interfaces may have disfavored N‐terminal presequences and driven the evolution of internal targeting signals in MRPs.     

Ribosome-binding sites on chloroplastrbcL andpsbA mRNAs and light-induced initiation of D1 translation

Chloroplast ribosome-binding sites were identified on the plastidrbcL andpsbA mRNAs using toeprint analysis. TherbcL translation initiation domain is highly conserved and contains a prokaryotic Shine-Dalgarno (SD) sequence (GGAGG) located 4 to 12 nucleotides upstream of the initiator AUG. Toeprint analysis ofrbcL mRNA associated with plastid polysomes revealed strong toeprint signals 15 nucleotides downstream from the AUG indicating ribosome binding at the translation initiation site.Escherichia coli 30S ribosomes generated similar toeprint signals when mixed withrbcL mRNA in the presence of initiator tRNA. These results indicate that plastid SD sequences are functional in chloroplast translation initiation. ThepsbA initiator region lacks a SD sequence within 12 nucleotides of the initiator AUG. However, toeprint analysis of soluble and membrane polysome-associatedpsbA mRNA revealed ribosomes bound to the initiator region.E. coli 30S ribosomes did not associate with thepsbA translation initiation region.E. coli and chloroplast ribosomes bind to an upstream region which contains a conserved SD-like sequence. Therefore, translation initiation onpsbA mRNA may involve the transient binding of chloroplast ribosomes to this upstream SD-like sequence followed by scanning to localize the initiator AUG. Illumination 8-day-old dark-grown barley seedlings caused an increase in polysome-associatedpsbA mRNA and the abundance of initiation complexes bound topsbA mRNA. These results demonstrate that light modulates D1 translation initiation in plastids of older dark-grown barley seedlings.     

Identification of a major glucose transporter in Flavobacterium johnsoniae: Inhibition of F. johnsoniae colony spreading by glucose uptake

Many members of the phylum Bacteroidetes, such as Flavobacterium johnsoniae, can glide over a solid surface: an ability called gliding motility. It can be usually observed on agar plates as thin, flat, spreading colonies with irregular, feathery edges; this phenomenon is called colony spreading. Colony spreading of F. johnsoniae on 1.5% agar plates containing poor nutrients is dose‐dependently inhibited by addition of D‐glucose, as previously reported. Accordingly, here, we created mutants (by transposon mutagenesis) that partially suppressed glucose‐mediated inhibition of colony spreading. Among the isolates, we found that one had a transposon insertion in Fjoh_4565, tentatively named mfsA, which encodes a major facilitator superfamily (MFS) transporter previously shown to be required for growth on glucose, N‐acetyl‐glucosamine, and chitin. We constructed an mfsA deletion mutant and found that the mutant showed no glucose‐mediated acceleration of growth or glucose uptake. The mfsA gene complemented the phenotype of a glucose‐negative Escherichia coli. These results suggest that the mfsA gene encodes the sole MFS transporter of glucose in F. johnsoniae and that glucose uptake is partially required for the glucose‐mediated inhibition of F. johnsoniae colony spreading.

     

Ribosomes in thiostrepton-resistant mutants of Bacillus megaterium lacking a single 50 S subunit protein.

A protein required for the binding of thiostrepton to ribosomes of Bacillus megaterium has been purified and further characterized by immunological techniques. This protein, which does not bind the drug off the ribosome, is serologically-homologous to Escherichia coli ribosomal protein L11 and is designated BM-L11. Ribosomes from certain thiostrepton-resistant mutants of B. megaterium appear to be totally devoid of protein BM-L11 as judged by modified immunoelectrophoresis. Such ribosomes are significantly less sensitive than those from wild-type organisms to the action of thiostrepton in vitro but retain substantial protein synthetic activity. Re-addition of protein BM-L11 to ribosomes from the mutants restores them to wild-type levels of activity and thiostrepton sensitivity. Thus ribosomal protein BM-L11 is involved not only in binding thiostrepton but also in determining the thiostrepton phenotype.     

The Kinetics of the Synthesis of Ribosomal RNA in E. coli

The kinetics of the synthesis of ribosomal RNA in E. coli has been studied using C¹⁴-uracil as tracer. Two fractions of RNA having sedimentation constants between 4 and 8S have kinetic behavior consistent with roles of precursors. The first consists of a very small proportion of the RNA found in the 100,000 g supernatant after ribosomes have been removed. It has been separated from the soluble RNA present in much larger quantities by chromatography on DEAE-cellulose columns. The size and magnitude of flow through this fraction are consistent with it being precursor to a large part of the ribosomal RNA.

A fraction of ribosomal RNA of similar size is also found in the ribosomes. This fraction is 5 to 10 per cent of the total ribosomal RNA and a much higher proportion of the RNA of the 20S and 30S ribosomes present in the cell extract. The rate of incorporation of label into this fraction and into the main fractions of ribosomal RNA of 18S and 28S suggests that the small molecules are the precursors of the large molecules. Measurements of the rate of labeling of the 20, 30, and 50S ribosomes made at corresponding times indicate that ribosome synthesis occurs by concurrent conversion of small to large molecules of RNA and small to large ribosomes.

     

Proteomic analysis of the Trypanosoma cruzi ribosomal proteins

Trypanosoma cruzi is a parasite responsible for Chagas disease. The identification of new targets for chemotherapy is a major challenge for the control of this disease. Several lines of evidences suggest that the translational system in trypanosomatids show important differences compared to other eukaryotes. However, there little is known information about this. We have performed a detailed data mining search for ribosomal protein genes in T. cruzi genome data base combined with mass spectrometry analysis of purified T. cruzi ribosomes. Our results show that T. cruzi ribosomal proteins have ∼50% sequence identity to yeast ones. Nevertheless, some parasite proteins are longer due to the presence of several N- or C-terminal extensions, which are exclusive of trypanosomatids. In particular, L19 and S21 show C-terminal extensions of 168 and 164 amino acids, respectively. In addition, we detected two 60S subunit proteins that had not been previously detected in the T. cruzi total proteome; namely, L22 and L42.     

Changes in the conformation of 5S rRNA cause alterations in principal functions of the ribosomal nanomachine

5S rRNA is an integral component of the large ribosomal subunit in virtually all living organisms. Polyamine binding to 5S rRNA was investigated by cross-linking of N¹-azidobenzamidino (ABA)-spermine to naked 5S rRNA or 50S ribosomal subunits and whole ribosomes from Escherichia coli cells. ABA-spermine cross-linking sites were kinetically measured and their positions in 5S rRNA were localized by primer extension analysis. Helices III and V, and loops A, C, D and E in naked 5S rRNA were found to be preferred polyamine binding sites. When 50S ribosomal subunits or poly(U)-programmed 70S ribosomes bearing tRNA^Phe at the E-site and AcPhe-tRNA at the P-site were targeted, the susceptibility of 5S rRNA to ABA-spermine was greatly reduced. Regardless of 5S rRNA assembly status, binding of spermine induced significant changes in the 5S rRNA conformation; loop A adopted an apparent ‘loosening’ of its structure, while loops C, D, E and helices III and V achieved a more compact folding. Poly(U)-programmed 70S ribosomes possessing 5S rRNA cross-linked with spermine were more efficient than control ribosomes in tRNA binding, peptidyl transferase activity and translocation. Our results support the notion that 5S rRNA serves as a signal transducer between regions of 23S rRNA responsible for principal ribosomal functions.     

Regulation of the Escherichia coli secA Gene Is Mediated by Two Distinct RNA Structural Conformations

Expression from the secA gene, encoding a key component of the general secretory pathway of Escherichia coli, is influenced by the secretion status of the cell, autogenous translational repression, and translational coupling to the upstream gene, X. SecA binds to its mRNA in a region overlapping its ribosome binding site, thus competing with ribosomes that would initiate secA translation. Mapping of the geneX-secA mRNA secondary structure has demonstrated that the RNA can adopt two distinct conformations in solution. The first conformation arises from the base-pairing of the secA Shine-Dalgarno (SD) sequence with the geneX terminus. The second conformation, in which the secA SD sequence is no longer paired with the geneX terminus, contains a GC-rich stem upstream of the secA SD sequence. The presence of this GC-rich stem is supported by structure mapping of a mutant RNA containing a deletion in the geneX terminus. The former structure appears to be involved in translational coupling by directly linking the geneX and secA sequences, where geneX translation activates secA translational initiation through the unpairing and unmasking of the secA SD sequence. As indicated by SecA-RNA binding assays, the latter structure is probably involved in SecA binding and translational repression of the secA gene. The stabilizing effect of magnesium ions toward occlusion of the secA SD sequence supports the presence of RNA tertiary structure in this regulatory domain. Received: 30 July 1998 / Accepted: 18 September 1998     

Influences on gene expression in vivo by a Shine-Dalgarno sequence

The Shine-Dalgarno (SD+: 5'-AAGGAGG-3') sequence anchors the mRNA by base pairing to the 16S rRNA in the small ribosomal subunit during translation initiation. We have here compared how an SD+ sequence influences gene expression, if located upstream or downstream of an initiation codon. The positive effect of an upstream SD+ is confirmed. A downstream SD+ gives decreased gene expression. This effect is also valid for appropriately modified natural Escherichia coli genes. If an SD+ is placed between two potential initiation codons, initiation takes place predominantly at the second start site. The first start site is activated if the distance between this site and the downstream SD+ is enlarged and/or if the second start site is weakened. Upstream initiation is eliminated if a stable stem-loop structure is placed between this SD+ and the upstream start site. The results suggest that the two start sites compete for ribosomes that bind to an SD+ located between them. A minor positive contribution to upstream initiation resulting from 3' to 5' ribosomal diffusion along the mRNA is suggested. Analysis of the E. coli K12 genome suggests that the SD+ or SD-like sequences are systematically avoided in the early coding region suggesting an evolutionary significance.     

Adaptive Potential of Wheat Ribosomes toward Heat Depends on the Large Ribosomal Subunit and Ribosomal Protein Phosphorylation

In a study of the translational efficiency of ribosomal subunits as a function of an in vivo temperature pretreatment, ribosomes were isolated from heat-pretreated (36°C) and reference (20°C) wheat seedlings (Triticum aestivum L.). The efficiency of recombined subunits in translating polyuridylic acid was assessed. A threefold increase in the rate of incorporation of phenylalanine by ribosomes from heat-pretreated plants was due to the large ribosomal subunit. This adaptive temperature effect was not correlated with a higher thermal stability of ribosomes or subunits from heat-pretreated seedlings, and two-dimensional gel electrophoresis failed to detect structural alterations of ribosomal proteins. Phosphorylation of ribosomal proteins in vitro showed no differences between ribosomes or subunits from heat-pretreated and reference plants. Incubation with [³²P]orthophosphate in vivo led to twice the amount of phosphate in ribosomal proteins from heat-pretreated wheat seedlings. This result is important with respect to the evaluation of the molecular basis of enhanced translational efficiency of ribosomes isolated from heat-pretreated wheat seedlings.