A third lineage with two-piece tmRNA

tmRNA combines tRNA and mRNA properties and helps bacteria to cope with stalled ribosomes. Its termini normally pair in the tRNA domain, closing the mRNA portion into a looping domain. A striking variation is a two-piece form that effectively breaks open the mRNA domain loop, resulting from independent gene permutation events in alphaproteobacteria and cyanobacteria. Convergent evolution to a similar form in separate bacterial lineages suggests that loop-opening benefits tmRNA function. This argument is strengthened by the discovery of a third bacterial lineage with a loop-opened two-piece tmRNA. Whereas most betaproteobacteria have one-piece tmRNA, a permuted tmRNA gene was found for Dechloromonas aromatica and close relatives. Correspondingly, two tmRNA pieces were identified, at approximately equal abundance and at a level one-fifteenth that of ribosomes, a 189 nt mRNA piece and a 65 nt aminoacylatable piece. Together these pieces were active with purified Escherichia coli translational components, but not alone. The proposed secondary structure combines common tmRNA features differently from the structures of other two-piece forms. The origin of the gene is unclear; horizontal transfer may be indicated by the similarity of the tRNA domain to that from a cyanobacterial two-piece tmRNA, but such transfer would not appear simple since the mRNA domain is most similar to that of other betaproteobacteria.     

Two-piece tmRNA in cyanobacteria and its structural analysis

tmRNA acts to rescue stalled bacterial ribosomes while encoding a peptide tag added trans-translationally to the nascent peptide, targeting it for proteolysis. The permuted gene structure found in a group of cyanobacteria is shown to produce a two-piece mature tmRNA, as had been observed previously for the independently permuted gene of α-proteobacteria. The pieces have been mapped onto the gene sequence and aligned for the permuted cyanobacterial tmRNA sequences, including four novel sequences. Structural probing and base pair co-variations support a secondary structure model in which two pairings in the tRNA-like domain hold the two pieces together, and the coding piece bearing the tag reading frame additionally contains a single transient pseudoknot and three other stem–loops. This represents a dramatic reduction in pseudoknot number from the five present in one-piece cyanobacterial tmRNA.     

ARAGORN, a program to detect tRNA genes and tmRNA genes in nucleotide sequences

A computer program, ARAGORN, identifies tRNA and tmRNA genes. The program employs heuristic algorithms to predict tRNA secondary structure, based on homology with recognized tRNA consensus sequences and ability to form a base-paired cloverleaf. tmRNA genes are identified using a modified version of the BRUCE program. ARAGORN achieves a detection sensitivity of 99% from a set of 1290 eubacterial, eukaryotic and archaeal tRNA genes and detects all complete tmRNA sequences in the tmRNA database, improving on the performance of the BRUCE program. Recently discovered tmRNA genes in the chloroplasts of two species from the ‘green’ algae lineage are detected. The output of the program reports the proposed tRNA secondary structure and, for tmRNA genes, the secondary structure of the tRNA domain, the tmRNA gene sequence, the tag peptide and a list of organisms with matching tmRNA peptide tags.     

Genetic analysis of the structure and function of transfer messenger RNA pseudoknot 1

tmRNA rescues stalled ribosomes in eubacteria by forcing the ribosome to abandon its mRNA template and resume translation with tmRNA itself as a template. Pseudoknot 1 (pk1), immediately upstream of this coding region in tmRNA, is a structural element that is considered essential for tmRNA function based on the analysis of pk1 mutants in vitro. pk1 binds near the ribosomal decoding site and may make base-specific contacts with tmRNA ligands. To study pk1 structure and function in vivo, we have developed a genetic selection that ties the life of Escherichia coli cells to tmRNA activity. Mutation of pk1 at 20% per base and selection for tmRNA activity yielded sequences that retain the same pseudoknot fold. In contrast, selection of active mutants from 10(6) completely random sequences identified hairpin structures that functionally replace pk1. Rational design of a hairpin with increased stability using an unrelated sequence yielded a tmRNA mutant with nearly wild-type activity. We conclude that the role of pk1 in tmRNA function is purely structural and that it can be replaced with a variety of hairpin structures. Our results demonstrate that in the study of functional RNAs, the inactivity of a mutant designed to destroy a given structure should not be interpreted as proof that the structure is necessary for RNA function. Such mutations may only destabilize a global fold that could be formed equally well by an entirely different, stable structure.     

Evaluation and refinement of tmRNA structure using gene sequences from natural microbial communities

DNA harvested directly from complex natural microbial communities by PCR has been successfully used to predict RNase P RNA structure, and can potentially provide an abundant source of information for structural predictions of other RNAs. In this study, we utilized genetic variation in natural communities to test and refine the secondary and tertiary structural model for the bacterial tmRNA. The variability of proposed tmRNA secondary structures in different organisms and the lack of any predicted tertiary structure suggested that further refinement of the tmRNA could be useful. To increase the phylogenetic representation of tmRNA sequences, and thereby provide additional data for statistical comparative analysis, we amplified, sequenced, and compared tmRNA sequences from natural microbial communities. Using primers designed from gamma proteobacterial sequences, we determined 44 new tmRNA sequences from a variety of environmental DNA samples. Covariation analyses of these sequences, along with sequences from cultured organisms, confirmed most of the proposed tmRNA model but also provided evidence for a new tertiary interaction. This approach of gathering sequence information from natural microbial communities seems generally applicable in RNA structural analysis.     

Functional and structural analysis of a pseudoknot upstream of the tag-encoded sequence in E. coli tmRNA

Escherichia coli tmRNA (transfer-messenger RNA) facilitates a trans-translation reaction in which a stalled ribosome on a terminatorless mRNA switches to an internal coding sequence in tmRNA, resulting in the addition of an 11 amino acid residue tag to the truncated protein that is a signal for degradation and in recycling of the stalled ribosome. A tmRNA secondary structure model with a partial tRNA-like structure and several pseudoknots was recently proposed. This report describes an extensive mutational analysis of one predicted pseudoknot (PK1) located upstream of the E. coli tmRNA tag-encoded sequence. Both the extent of aminoacylation and the alanine incorporation into the tag sequence, reflecting the two functions of tmRNA, were measured in vitro for all the engineered RNA variants. To characterize structure-function relationships for the tmRNA mutants, their solution conformations were investigated by using structural probes and by measuring the temperature dependence of their UV absorbance. This analysis strongly supports the presence of a pseudoknot in E. coli tmRNA, and its involvement in trans-translation. Mutations disrupting the first stem of the pseudoknot inactivate function and promote stable alternative conformations. Mutations of the second stem of the pseudoknot also effect both functions. The nucleotide stretch between the two stems (loop 2) is required for efficient trans-translation, and nucleotides at positions 61 and 62 must be guanine residues. The probing data suggest the presence of magnesium ion(s) interacting with loop 2. The loops crossing the minor and major grooves can be mutated without significant effects on tmRNA function. Nucleotide insertion or deletion between the pseudoknot and the coding sequence do not change the mRNA frame of the tag-peptide sequence, suggesting that the pseudoknot structure is not a determinant for the resumption of translation.     

A mathematical framework for examining whether a minimum number of chiasmata is required per metacentric chromosome or chromosome arm in human

We introduce a piecewise linear regression called "hockey stick regression" to model the relationship between genetic and physical lengths of chromosomes in a genome. This piecewise linear regression is an extension of the two-parameter linear regression we proposed earlier [W. Li and J. Freudenberg, Two-parameter characterization of chromosome-scale recombination rate, Genome Res., 19 (2009) 2300-2307]. We use this, as well as the one-piece regression with a fixed y-intercept, to compare the two competing hypotheses concerning the minimum number of required chiasmata for meiosis: minimum one chiasma per chromosome (PC) and per chromosome arm (PA). Using statistical model selection and testing, we show that for human genome data, one-piece PC (PC1) is often in a statistical tie with two-piece PA model (PA2). If an upper bound for the segmentation point in two-piece regression is imposed, PC is usually the preferred model. This indicates that a presence of more than one chiasmata is rather caused by the relationship between chromosome size and chiasma formation than by cytogenetic constraints.     

The tmRNA database (tmRDB).

This first release of the tmRNA database (tmRDB) contains 19 tmRNA sequences, a tmRNA sequence alignment with emphasis of base pairs that are supported by comparative sequence analysis, and a tabulation of tmRNA-encoded tag peptides. The tmRNADB also offers an RNA secondary structure diagram of the Escherichia coli tmRNA, as well as PDB-formatted coordinates for three-dimensional modeling. The data are available on the World Wide Web at http://www.uthct. edu/tmRDB/tmRDB.html     

tmRDB (tmRNA database)

Maintained at the University of Texas Health Science Center at Tyler, Texas, the tmRNA database (tmRDB) is accessible at the URL http://psyche.uthct.edu/dbs/tmRDB/tmRDB.html with mirror sites located at Auburn University, Auburn, Alabama (http://www.ag.auburn.edu/mirror/tmRDB/) and the Bioinformatics Research Center, Aarhus, Denmark (http://www.bioinf.au.dk/tmRDB/). The tmRDB collects and distributes information relevant to the study of tmRNA. In trans-translation, this molecule combines properties of tRNA and mRNA and binds several proteins to form the tmRNP. Related RNPs are likely to be functional in all bacteria. In this release of tmRDB, 186 new entries from 10 bacterial groups for a total of 274 tmRNA sequences have been added. Lists of the tmRNAs and the corresponding tmRNA-encoded tag-peptides are presented in alphabetical and phylogenetic order. The tmRNA sequences are aligned manually, assisted by computational tools, to determine base pairs supported by comparative sequence analysis. The tmRNA alignment, available in a variety of formats, provides the basis for the secondary and tertiary structure of each tmRNA molecule. Three-dimensional models of the tmRNAs and their associated proteins in PDB format give evidence for the recent progress that has been made in the understanding of tmRNP structure and function.     

Reverse engineering of mandible and prosthetic framework: Effect of titanium implants in conjunction with titanium milled full arch bridge prostheses on the biomechanics of the mandible

This study aimed at investigating the effects of titanium implants and different configurations of full-arch prostheses on the biomechanics of edentulous mandibles. Reverse engineered, composite, anisotropic, edentulous mandibles made of a poly(methylmethacrylate) core and a glass fibre reinforced outer shell were rapid prototyped and instrumented with strain gauges. Brånemark implants RP platforms in conjunction with titanium Procera one-piece or two-piece bridges were used to simulate oral rehabilitations. A lateral load through the gonion regions was used to test the biomechanical effects of the rehabilitations. In addition, strains due to misfit of the one-piece titanium bridge were compared to those produced by one-piece cast gold bridges. Milled titanium bridges had a better fit than cast gold bridges. The stress distribution in mandibular bone rehabilitated with a one-piece bridge was more perturbed than that observed with a two-piece bridge. In particular the former induced a stress concentration and stress shielding in the molar and symphysis regions, while for the latter design these stresses were strongly reduced. In conclusion, prosthetic frameworks changed the biomechanics of the mandible as a result of both their design and manufacturing technology.     

Independent binding sites of small protein B onto transfer-messenger RNA during trans-translation

Stalled bacterial ribosomes are freed by transfer-messenger RNA (tmRNA). With the help of small protein B (SmpB), protein synthesis restarts and tmRNA adds a tag to the stalled protein for destruction. The conformation of a 347 nt long tmRNA from a thermophile and its interactions with SmpB were monitored using structural probes. The RNA is highly folded, including the reading frame, with <30% of unpaired residues. Footprints between SmpB and tmRNA are in the elbow of the tRNA domain, in some pseudoknots including one essential for function and in the lower part of the stem exiting the tRNA domain. The footprints outside the tRNA domain are scattered onto the tmRNA sequence, but form a cluster onto its tertiary structure derived from cryo-EM data. Some footprints flank the first triplet to be translated in tmRNA, suggesting that SmpB participates in the insertion of the tmRNA-encoded reading frame into the decoding center. To discriminate between a conformational rearrangement of tmRNA and independent binding sites, surface plasmon resonance was used and has identified three independent binding sites of SmpB on the RNA, including the site on the tRNA domain. Accordingly, SmpB is proposed to move on the tmRNA scaffold during trans-translation.     

Probing the structure of the Escherichia coli 10Sa RNA (tmRNA).

The conformation of the Escherichia coli 10Sa RNA (tmRNA) in solution was investigated using chemical and enzymatic probes. Single- and double-stranded domains were identified by hydrolysis of tmRNA in imidazole buffer and by lead(II)-induced cleavages. Ribonucleases T1 and S1 were used to map unpaired nucleotides and ribonuclease V1 was used to identify paired bases or stacked nucleotides. Specific atomic positions of bases were probed with dimethylsulfate, a carbodiimide, and diethylpyrocarbonate. Covariations, identified by sequence alignment with nine other tmRNA sequences, suggest the presence of several tertiary interactions, including pseudoknots. Temperature-gradient gel electrophoresis experiments showed structural transitions of tmRNA starting around 40 degrees C, and enzymatic probing performed at selected temperatures revealed the progressive melting of several predicted interactions. Based on these data, a secondary structure is proposed, containing two stems, four stem-loops, four pseudoknots, and an unstable structural domain, some connected by single-stranded A-rich sequence stretches. A tRNA-like domain, including an already reported acceptor branch, is supported by the probing data. A second structural domain encompasses the coding sequence, which extends from the top of one stem-loop to the top of another, with a 7-nt single-stranded stretch between. A third structural module containing pseudoknots connects and probably orients the tRNA-like domain and the coding sequence. Several discrepancies between the probing data and the phylogeny suggest that E. coli tmRNA undergoes a conformational change.     

The tmRNA website.

tmRNA (10Sa RNA) has a central role in trans -translation, in which a peptide tag encoded in tmRNA is added to the abnormally short protein product of a broken mRNA, as a signal for proteolysis of the entire tagged protein. The tmRNA website was established in 1997 as a resource for phylogenetic considerations of tmRNA structure and function. Since then, three partial tmRNA sequences have been completed, and sequences from 13 more species have been identified. Forty-six species from 10 bacterial phyla and chloroplasts are now represented in the database. Provisional sequence alignments and predicted proteolysis tag sequences are provided, as well as a literature review and a guide to searching for new tmRNA sequences. The tmRNA website is accessible via WWW at a new URL: http://sunflower.bio.indiana.edu/kwilliam/tmRNA /home.html     

The tmRNA Website: invasion by an intron

tmRNA (also known as 10Sa RNA or SsrA) plays a central role in an unusual mode of translation, whereby a stalled ribosome switches from a problematic mRNA to a short reading frame within tmRNA during translation of a single polypeptide chain. Research on the mechanism, structure and biology of tmRNA is served by the tmRNA Website, a collection of sequences for tmRNA and the encoded proteolysis-inducing peptide tags, alignments, careful documentation and other information; the URL is http://www.indiana.edu/~tmrna. Four pseudoknots are usually present in each tmRNA, so the database is rich with information on pseudoknot variability. Since last year it has doubled (227 tmRNA sequences as of September 2001), a sequence alignment for the tmRNA cofactor SmpB has been included, and genomic data for Clostridium botulinum has revealed a group I (subgroup IA3) intron interrupting the tmRNA T-loop.     

反式翻译模型

反式翻译是细菌体内一种修复翻译水平上受阻的遗传信息表达过程的机制。tmRNA是反式翻译的核心分子,它兼具tRNA和mRNA的特点,在SmpB蛋白的帮助下特异性识别携带mRNA缺失体的核糖体,在核糖体蛋白S1的传递作用下结合在A位点上,一方面延续被中断的mRNA上的遗传信息,一方面终止蛋白质的合成,释放被束缚的核糖体和tRNA进入新的翻译过程。本文对近年来关于反式翻译模型的研究进行综述。     

Analysis of the role of trans-translation in the requirement of tmRNA for lambdaimmP22 growth in Escherichia coli

The small, stable RNA molecule encoded by ssrA, known as tmRNA or 10Sa RNA, is required for the growth of certain hybrid lambdaimmP22 phages in Escherichia coli. tmRNA has been shown to tag partially synthesized proteins for degradation in vivo by attaching a short peptide sequence, encoded by tmRNA, to the carboxyl termini of these proteins. This tag sequence contains, at its C terminus, an amino acid sequence that is recognized by cellular proteases and leads to degradation of tagged proteins. A model describing this function of tmRNA, the trans-translation model (K. C. Keiler, P. R. Waller, and R. T. Sauer, Science 271:990-993, 1996), proposes that tmRNA acts first as a tRNA and then as a mRNA, resulting in release of the original mRNA template from the ribosome and translocation of the nascent peptide to tmRNA. Previous work from this laboratory suggested that tmRNA may also interact specifically with DNA-binding proteins, modulating their activity. However, more recent results indicate that interactions between tmRNA and DNA-binding proteins are likely nonspecific. In light of this new information, we examine the effects on lambdaimmP22 growth of mutations eliminating activities postulated to be important for two different steps in the trans-translation model, alanine charging of tmRNA and degradation of tagged proteins. This mutational analysis suggests that, while charging of tmRNA with alanine is essential for lambdaimmP22 growth in E. coli, degradation of proteins tagged by tmRNA is required only to achieve optimal levels of phage growth. Based on these results, we propose that trans-translation may have two roles, the primary role being the release of stalled ribosomes from their mRNA template and the secondary role being the tagging of truncated proteins for degradation.     

Protein tagging at rare codons is caused by tmRNA action at the 3' end of nonstop mRNA generated in response to ribosome stalling

It has been believed that protein tagging caused by consecutive rare codons involves tmRNA action at the internal mRNA site. We demonstrated previously that ribosome stalling either at sense or stop codons caused by certain arrest sequences could induce mRNA cleavage near the arrest site, resulting in nonstop mRNAs that are recognized by tmRNA. These findings prompted us to re-examine the mechanism of tmRNA tagging at a run of rare codons. We report here that either AGG or CGA but not AGA arginine rare-codon clusters inserted into a model crp mRNA encoding cAMP receptor protein (CRP) could cause an efficient protein tagging. We demonstrate that more than three consecutive AGG codons are needed to induce an efficient ribosome stalling therefore tmRNA tagging in our system. The tmRNA tagging was eliminated by overproduction of tRNAs corresponding to rare codons, indicating that a scarcity of the corresponding tRNA caused by the rare-codon cluster is an important factor for tmRNA tagging. Mass spectrometry analyses of proteins generated in cells lacking or possessing tmRNA encoding a protease-resistant tag sequence indicated that the truncation and tmRNA tagging occur within the cluster of rare codons. Northern and S1 analyses demonstrated that nonstop mRNAs truncated within the rare-codon clusters are detected in cells lacking tmRNA but not in cells expressing tmRNA. We conclude that a ribosome stalled by the rare codon induces mRNA cleavage, resulting in nonstop mRNAs that are recognized by tmRNA.     

How does tmRNA move through the ribosome?

To test the structure of tmRNA in solution, cross-linking experiments were performed which showed two sets of cross-links in two different domains of tmRNA. Site-directed mutagenesis was used to search for tmRNA nucleotide bases that might form a functional analogue of a codon-anticodon duplex to be recognized by the ribosomal A-site. We demonstrate that nucleotide residues U85 and A86 from tmRNA are significant for tmRNA function and propose that they are involved in formation of a tmRNA element playing a central role in A-site recognition. These data are discussed in the frame of a hypothetical model that suggests a general scheme for the interaction of tmRNA with the ribosome and explains how it moves through the ribosome.     

Extensive phosphorothioate substitution yields highly active and nuclease-resistant hairpin ribozymes.

The catalytic function of the hairpin ribozyme has been investigated by modification-interference analysis of both ribozyme and substrate, using ribonucleoside phosphorothioates. Thiophosphate substitutions in two ribozyme domains were examined by using a novel and highly efficient two-piece ribozyme assembled from two independently synthesized oligoribonucleotides. The catalytic proficiency of the two-piece construct (KM = 48 nM, kcat = 2.3 min-1) is nearly identical to that of the one-piece ribozyme. The two-piece ribozyme is essentially unaffected by substitution with thiophosphates 5' to all guanosines, cytidines, and uridines. In contrast, incorporation of multiple adenosine phosphorothioates in the 5' domain of the ribozyme decreases ribozyme activity by a factor of 25. Modification-interference experiments using ribozymes partially substituted with adenosine phosphorothioate suggest that thiophosphates 5' to A7, A9 and A10 interfere with cleavage to a greater extent than substitutions at other sites within the molecule, but the effect is modest. Within the substrate, phosphorothioate substitution does not directly interfere with cleavage, rather, increasing thiophosphate content decreases the stability of the ribozyme-substrate complex. We describe the construction of a hairpin ribozyme containing dinucleotide extensions at its 5' and 3' ends. Full substitution of this molecule with G and C phosphorothioates results in a ribozyme with greatly enhanced stability against cellular ribonucleases without significant loss of catalytic efficiency.