Alexey Petrov

Coordinated conformational and compositional dynamics drive ribosome translocation.

During translation elongation, the ribosome compositional factors elongation factor G (EF-G; encoded by fusA) and tRNA alternately bind to the ribosome to direct protein synthesis and regulate the conformation of the ribosome. Here, we use single-molecule fluorescence with zero-mode waveguides to directly correlate ribosome conformation and composition during multiple rounds of elongation at high factor concentrations in Escherichia coli. Our results show that EF-G bound to GTP (EF-G–GTP) continuously samples both rotational states of the ribosome, binding with higher affinity to the rotated state. Upon successful accommodation into the rotated ribosome, the EF-G–ribosome complex evolves through several rate-limiting conformational changes and the hydrolysis of GTP, which results in a transition back to the nonrotated state and in turn drives translocation and facilitates release of both EF-G–GDP and E-site tRNA. These experiments highlight the power of tracking single-molecule conformation and composition simultaneously in real time.

Single Ribosome Dynamics and the Mechanism of Translation

Our current understanding of the mechanism of translation is based on nearly fifty years of biochemical and biophysical studies. This mechanism, which requires the ribosome to manipulate tRNA and step repetitively along the mRNA, implies movement. High-resolution structures of the ribosome and its ligands have recently described translation in atomic detail, capturing the endpoints of large-scale rearrangements of the ribosome. Direct observation of the dynamic events that underlie the mechanism of translation is challenged by ensemble averaging in bulk solutions. Single-molecule methods, which eliminate these averaging effects, have emerged as powerful tools to probe the mechanism of translation. Single-molecule fluorescence experiments have described the dynamic motion of the ribosome and tRNA. Single-molecule force measurements have directly probed the forces stabilizing ribosomal complexes. Recent developments have allowed real-time observation of ribosome movement and dynamics during translation. This review covers the contributions of single-molecule studies to our understanding of the dynamic nature of translation.

Heterogeneous pathways and timing of factor departure during translation initiation

The initiation of translation establishes the reading frame for protein synthesis and is a key point of regulation. Initiation involves factor-driven assembly at a start codon of a messenger RNA of an elongation-competent 70S ribosomal particle (in bacteria) from separated 30S and 50S subunits and initiator transfer RNA. Here we establish in Escherichia coli, using direct single-molecule tracking, the timing of initiator tRNA, initiation factor 2 (IF2; encoded by infB) and 50S subunit joining during initiation. Our results show multiple pathways to initiation, with orders of arrival of tRNA and IF2 dependent on factor concentration and composition. IF2 accelerates 50S subunit joining and stabilizes the assembled 70S complex. Transition to elongation is gated by the departure of IF2 after GTP hydrolysis, allowing efficient arrival of elongator tRNAs to the second codon presented in the aminoacyl-tRNA binding site (A site). These experiments highlight the power of single-molecule approaches to delineate mechanisms in complex multicomponent systems.

Dynamic pathways of −1 translational frameshifting

Spontaneous changes in the reading frame of translation are rare (frequency of 10−3 to 10−4 per codon), but can be induced by specific features in the messenger RNA (mRNA). In the presence of mRNA secondary structures, a heptanucleotide ‘slippery sequence’ usually defined by the motif X XXY YYZ, and (in some prokaryotic cases) mRNA sequences that base pair with the 3′ end of the 16S ribosomal rRNA (internal Shine–Dalgarno sequences), there is an increased probability that a specific programmed change of frame occurs, wherein the ribosome shifts one nucleotide backwards into an overlapping reading frame (−1 frame) and continues by translating a new sequence of amino acids. Despite extensive biochemical and genetic studies, there is no clear mechanistic description for frameshifting. Here we apply single-molecule fluorescence to track the compositional and conformational dynamics of individual ribosomes at each codon during translation of a frameshift-inducing mRNA from the dnaX gene in Escherichia coli. Ribosomes that frameshift into the −1 frame are characterized by a tenfold longer pause in elongation compared to non-frameshifted ribosomes, which translate through unperturbed. During the pause, interactions of the ribosome with the mRNA stimulatory elements uncouple EF-G catalysed translocation from normal ribosomal subunit reverse-rotation, leaving the ribosome in a non-canonical intersubunit rotated state with an exposed codon in the aminoacyl-tRNA site (A site). tRNALys sampling and accommodation to the empty A site and EF-G action either leads to the slippage of the tRNAs into the −1 frame or maintains the ribosome into the 0 frame. Our results provide a general mechanistic and conformational framework for −1 frameshifting, highlighting multiple kinetic branchpoints during elongation.

N6-methyladenosine in mRNA disrupts tRNA selection and translation elongation dynamics

N6-methylation of adenosine (forming m6A) is the most abundant post-transcriptional modification within the coding region of mRNA, but its role during translation remains unknown. Here, we used bulk kinetic and single-molecule methods to probe the effect of m6A in mRNA decoding. Although m6A base-pairs with uridine during decoding, as shown by X-ray crystallographic analyses of Thermus thermophilus ribosomal complexes, our measurements in an Escherichia coli translation system revealed that m6A modification of mRNA acts as a barrier to tRNA accommodation and translation elongation. The interaction between an m6A-modified codon and cognate tRNA echoes the interaction between a near-cognate codon and tRNA, because delay in tRNA accommodation depends on the position and context of m6A within codons and on the accuracy level of translation. Overall, our results demonstrate that chemical modification of mRNA can change translational dynamics.

Identification of Functionally Important Amino Acids of Ribosomal Protein L3 by Saturation Mutagenesis

ABSTRACT There is accumulating evidence that many ribosomal proteins are involved in shaping rRNA into their functionally correct conformations through RNA-protein interactions. Moreover, although rRNA seems to play the central role in all aspects of ribosome function, ribosomal proteins may be involved in facilitating communication between different functional regions in ribosome, as well as between the ribosome and cellular factors. In an effort to more fully understand how ribosomal proteins may influence ribosome function, we undertook large-scale mutational analysis of ribosomal protein L3, a core protein of the large subunit that has been implicated in numerous ribosome-associated functions in the past. A total of 98 different rpl3 alleles were genetically characterized with regard to their effects on killer virus maintenance, programmed −1 ribosomal frameshifting, resistance/hypersensitivity to the translational inhibitor anisomycin and, in specific cases, the ability to enhance translation of a reporter mRNA lacking the 5′ 7mGppp cap structure and 3′ poly(A) tail. Biochemical studies reveal a correlation between an increased affinity for aminoacyl-tRNA and the extent of anisomycin resistance and a decreased peptidyltransferase activity and increased frameshifting efficiency. Immunoblot analyses reveal that the superkiller phenotype is not due to a defect in the ability of ribosomes to recruit the Ski-complex, suggesting that the defect lies in a reduced ability of mutant ribosomes to distinguish between cap+/poly(A)+ and cap−/poly(A)− mRNAs. The results of these analyses are discussed with regard to how protein-rRNA interactions may affect ribosome function.

Dynamics of the translational machinery.

The recent growth in single molecule studies of translation has provided an insight into the molecular mechanism of ribosomal function. Single molecule fluorescence approaches allowed direct observation of the structural rearrangements occurring during translation and revealed dynamic motions of the ribosome and its ligands. These studies demonstrated how ligand binding affects dynamics of the ribosome, and the role of the conformational sampling in large-scale rearrangements intrinsic to translation elongation. The application of time-resolved cryo-electron microscopy revealed new conformational intermediates during back-translocation providing an insight into ribosomal dynamics from an alternative perspective. Recent developments permitted examination of conformational and compositional dynamics of the ribosome in real-time through multiple cycles of elongation at the single molecule level. The zero-mode waveguide approach allowed direct observation of the compositional dynamics of tRNA occupancy on the elongating ribosome. The emergence of single molecule in vivo techniques provided insights into the mechanism and regulation of translation at the organismal level.

High-throughput platform for real-time monitoring of biological processes by multicolor single-molecule fluorescence

Significance Zero-mode waveguides (ZMWs) provide a powerful technology for studying single-molecule real-time dynamics of biological systems. However, difficulties in instrumental implementation and ZMW fabrication prevented their widespread use. Here, we modify a commercially available ZMW-based DNA sequencer for use as a multipurpose single-molecule fluorescence instrument. The instrumentation presented here allows access to ZMWs for the general biophysics community for high-throughput multiplexed dynamics of single biological molecules. Zero-mode waveguides provide a powerful technology for studying single-molecule real-time dynamics of biological systems at physiological ligand concentrations. We customized a commercial zero-mode waveguide-based DNA sequencer for use as a versatile instrument for single-molecule fluorescence detection and showed that the system provides long fluorophore lifetimes with good signal to noise and low spectral cross-talk. We then used a ribosomal translation assay to show real-time fluidic delivery during data acquisition, showing it is possible to follow the conformation and composition of thousands of single biomolecules simultaneously through four spectral channels. This instrument allows high-throughput multiplexed dynamics of single-molecule biological processes over long timescales. The instrumentation presented here has broad applications to single-molecule studies of biological systems and is easily accessible to the biophysical community.

Evaluation of Microwave-Accelerated Residue-Specific Acid Cleavage for Proteomic Applications

Microwave-accelerated proteolysis using acetic acid has been shown to occur specifically on either or both sides of aspartic acid residues. This chemical cleavage has been applied to ovalbumin and several model peptides to test the effect on some of the more common post-translational modifications. No oxidation of methionine or cysteine was observed; however, hydrolysis of phosphate groups proceeds at a detectable rate. Acid cleavage was also extended to the yeast ribosome model proteome, where it provided information on 74% of that proteome. Aspartic acid occurs across the proteome with approximately half the frequency of the combined occurrence of the trypsin residues lysine and arginine, and implications of this are considered.

Unraveling the dynamics of ribosome translocation

Translocation is one of the key events in translation, requiring large-scale conformational changes in the ribosome, movements of two transfer RNAs (tRNAs) across a distance of more than 20Å, and the coupled movement of the messenger RNA (mRNA) by one codon, completing one cycle of peptide-chain elongation. Translocation is catalyzed by elongation factor G (EF-G in bacteria), which hydrolyzes GTP in the process. However, how the conformational rearrangements of the ribosome actually drive the movements of the tRNAs and how EF-G GTP hydrolysis plays a role in this process are still unclear. Fluorescence methods, both single-molecule and bulk, have provided a dynamic view of translocation, allowing us to follow the different conformational changes of the ribosome in real-time. The application of electron microscopy has revealed new conformational intermediates during translocation and important structural rearrangements in the ribosome that drive tRNA movement, while computational approaches have added quantitative views of the translational pathway. These recent advances shed light on the process of translocation, providing insight on how to resolve the different descriptions of translocation in the current literature.