SAM-VI riboswitch structure and signature for ligand discrimination.

Riboswitches are metabolite-sensing, conserved domains located in non-coding regions of mRNA that are central to regulation of gene expression. Here we report the first three-dimensional structure of the recently discovered S-adenosyl-L-methionine responsive SAM-VI riboswitch. SAM-VI adopts a unique fold and ligand pocket that are distinct from all other known SAM riboswitch classes. The ligand binds to the junctional region with its adenine tightly intercalated and Hoogsteen base-paired. Furthermore, we reveal the ligand discrimination mode of SAM-VI by additional X-ray structures of this riboswitch bound to S-adenosyl-L-homocysteine and a synthetic ligand mimic, in combination with isothermal titration calorimetry and fluorescence spectroscopy to explore binding thermodynamics and kinetics. The structure is further evaluated by analysis of ligand binding to SAM-VI mutants. It thus provides a thorough basis for developing synthetic SAM cofactors for applications in chemical and synthetic RNA biology.

Structural features of the tmRNA-ribosome interaction.

Trans-translation is a process which switches the synthesis of a polypeptide chain encoded by a nonstop messenger RNA to the mRNA-like domain of a transfer-messenger RNA (tmRNA). It is used in bacterial cells for rescuing the ribosomes arrested during translation of damaged mRNA and directing this mRNA and the product polypeptide for degradation. The molecular basis of this process is not well understood. Earlier, we developed an approach that allowed isolation of tmRNA-ribosomal complexes arrested at a desired step of tmRNA passage through the ribosome. We have here exploited it to examine the tmRNA structure using chemical probing and cryo-electron microscopy tomography. Computer modeling has been used to develop a model for spatial organization of the tmRNA inside the ribosome at different stages of trans-translation.

Alternating translocation of protein substrates from both ends of ClpXP protease.

In ClpXP protease complexes, hexameric rings of the ATP-dependent ClpX chaperone stack on one or both faces of the double-heptameric rings of ClpP. We used electron microscopy to record the initial binding of protein substrates to ClpXP and their accumulation inside proteolytically inactive ClpP. Proteins with N- or C-terminal recognition motifs bound to complexes at the distal surface of ClpX and, upon addition of ATP, were translocated to ClpP. With a partially translocated substrate, the non-translocated portion remained on the surface of ClpX, aligned with the central axis of the complex, confirming that translocation proceeds through the axial channel of ClpXP. Starting with substrate bound on both ends, most complexes translocated substrate from only one end, and rarely (<5%) from both ends. We propose that translocation from one side is favored for two reasons: initiation of translocation is infrequent, making the probability of simultaneous initiation low; and, further, the presence of protein within the cis side translocation channel or within ClpP generates an inhibitory signal blocking translocation from the trans side.

The ribosome-structure and functional ligand-binding experiments using cryo-electron microscopy.

Cryo-electron microscopy has greatly advanced our understanding of the basic steps of protein synthesis in the bacterial ribosome. This article gives an overview of what has been achieved so far. Through three-dimensional visualization of complexes that represent the ribosome in defined binding states, locations were derived for the tRNA in A, P, and E sites, as well as the elongation factors. In addition, the pathways of messenger RNA and the exiting polypeptide chain could be inferred.

A transcribing RNA polymerase molecule survives DNA replication without aborting its growing RNA chain.

We have demonstrated elsewhere that a precisely placed, stalled Escherichia coli RNA polymerase ternary transcription complex (polymerase-RNA-DNA) stays on the DNA template after passage of a DNA replication fork. Moreover, the bypassed complex remains competent to resume elongation of its bound RNA chain. But the simplicity of our experimental system left several important questions unresolved: in particular, might the observation be relevant only to the particular ternary complex that we studied, and can the finding be generalized to a transcribing instead of a stalled RNA polymerase? To address these issues, we have created three additional ternary transcription complexes and examined their fates after passage of a replication fork. In addition, we have examined the fate of moving RNA polymerase molecules during DNA replication. The results suggest that our previous finding applies to all transcription intermediates of the E. coli RNA polymerase.

Roles of a ribosome-binding site and mRNA secondary structure in differential expression of Shiga toxin genes.

The Shiga toxin operon (stx) is composed of two genes for the A and B subunits, which are transcribed from a promoter 5' to the stxA gene. The 1A:5B subunit stoichiometry of the holotoxin suggests that the stxA and stxB genes are differentially regulated. In a previous study, we demonstrated the existence of a second promoter which independently transcribes the stxB gene. However, transcription fusion analysis revealed that the independent stxB gene promoter is not solely responsible for a fivefold increase in B polypeptide production. In this study, we have investigated the role of an independent stxB gene ribosome-binding site (RBS) in the overexpression of STX B subunits. Site-directed mutagenesis was used to eliminate this RBS and establish its role in StxB production. Examination of the nucleotide sequences surrounding the stxB gene RBS revealed a potential for the formation of a stem-loop structure with a calculated delta G of -7.563 kcal/mol (ca. -31.64 kJ/mol). Sequences surrounding the stxA gene RBS were found not to possess a similar potential for secondary-structure formation. Disruption of the stem-loop surrounding the stxB gene RBS by 2- and 4-nucleotide substitutions caused a significant reduction in B polypeptide and holotoxin production, establishing the role of this secondary structure in the enhancement of translation of the stxB gene.

Regulation of the Escherichia coli uncH gene by mRNA secondary structure and translational coupling.

The uncH gene is one of the most poorly-expressed genes of the proton-translocating ATPase (unc) operon of Escherichia coli. We constructed in-frame lacZ fusions to uncH and used site-directed mutagenesis to decrease the stability of the putative mRNA secondary structure in the Shine and Dalgarno region for this gene. These mutations significantly increased the expression of uncH. We also used the unc-lac fusions to show that the insertion of stop codons and a frameshift mutation in uncF, the gene preceding uncH, caused a 10-fold reduction in uncH expression. Hybridization of total cellular RNA with a lacZ-specific probe indicated that transcriptional polarity could not account for the observed decrease in gene expression. These results demonstrate that uncH expression is controlled by mRNA sequences around the translational initiation region, and is translationally coupled to uncF, even in cases where the putative mRNA secondary structure is weakened or eliminated.

Ribosomal RNA identity elements for ricin A-chain recognition and catalysis. Analysis with tetraloop mutants.

Ricin is a cytotoxic protein that inactivates ribosomes by hydrolyzing the N-glycosidic bond between the base and the ribose of the adenosine at position 4324 in eukaryotic 28 S rRNA. Ricin A-chain will also catalyze depurination in naked prokaryotic 16 S rRNA; the adenosine is at position 1014 in a GAGA tetraloop. The rRNA identity elements for recognition by ricin A-chain and for the catalysis of cleavage were examined using synthetic GAGA tetraloop oligoribonucleotides. The RNA designated wild-type, an oligoribonucleotide (19-mer) that approximates the structure of the ricin-sensitive site in 16 S rRNA, and a number of mutants were transcribed in vitro from synthetic DNA templates with phage T7 RNA polymerase. With the wild-type tetraloop oligoribonucleotide the ricin A-chain-catalyzed reaction has a Km of 5.7 microM and a Kcat of 0.01 min-1. The toxin alpha-sarcin, which cleaves the phosphodiester bond on the 3' side of G4325 in 28 S rRNA, does not recognize the tetraloop RNA, although alpha-sarcin does affect a larger synthetic oligoribonucleotide that has a 17-nucleotide loop with a GAGA sequence; thus, there is a clear divergence in the identity elements for the two toxins. Mutants were constructed with all of the possible transitions and transversions of each nucleotide in the GAGA tetraloop; none was recognized by ricin A-chain. Thus, there is an absolute requirement for the integrity of the GAGA sequence in the tetraloop. The helical stem of the tetraloop oligoribonucleotide can be reduced to three base-pairs, indeed, to two base-pairs if the temperature is decreased, without affecting recognition; the nature of these base-pairs does not influence recognition or catalysis by ricin A-chain. If the tetraloop is opened so as to form a GAGA-containing hexaloop, recognition by ricin A-chain is lost. This suggests that during the elongation cycle, a GAGA tetraloop either exists or is formed in the putative 17-member single-stranded region of the ricin domain in 28 S rRNA and this bears on the mechanism of protein synthesis.

Prediction of three-dimensional structure of Escherichia coli ribosomal RNA.

A model for the tertiary structure of 23S, 16S and 5S ribosomal RNA molecules interacting with three tRNA molecules is presented using the secondary structure models common to E. coli, Z. mays chloroplast, and mammalian mitochondria. This ribosomal RNA model is represented by phosphorus atoms which are separated by 5.9 A in the standard A-form double helix conformation. The accumulated proximity data summarized in Table 1 were used to deduce the most reasonable assembly of helices separated from each other by at least 6.2 A. Straight-line approximation for single strands was adopted to describe the maximum allowed distance between helices. The model of a ribosome binding three tRNA molecules by Nierhaus (1984), the stereochemical model of codon-anticodon interaction by Sundaralingam et al. (1975) and the ribosomal transpeptidation model, forming an alpha-helical nascent polypeptide, by Lim & Spirin (1986), were incorporated in this model. The distribution of chemically modified nucleotides, cross-linked sites, invariant and missing regions in mammalian mitochondrial rRNAs are indicated on the model.

Three-dimensional image reconstruction from ordered arrays of 70S ribosomes.

A better understanding of the molecular mechanism of protein biosynthesis still awaits a reliable model for the ribosomal particle. We describe here the application of a diffraction technique, namely three-dimensional image reconstruction from two-dimensional sheets of 70S ribosomes from Bacillus stearothermophilus at 47 A resolution. The three-dimensional model obtained by these studies shows clearly the two subunits, the contact points between them, an empty space large enough to accommodate the components of protein biosynthesis, the location of regions rich in RNA and a possible binding site for mRNA. The tunnel within the 50S particle which may provide the path taken by the nascent polypeptide chain in partially resolved.