Real-time monitoring of cell-free translation on a quartz-crystal microbalance

The SecM arrest peptide traps a pre-peptide bond formation state of the ribosome

Nascent polypeptide chains can induce translational stalling to regulate gene expression. This is exemplified by the E. coli secretion monitor (SecM) arrest peptide that induces translational stalling to regulate expression of the downstream encoded SecA, an ATPase that co-operates with the SecYEG translocon to facilitate insertion of proteins into or through the cytoplasmic membrane. Here we present the structure of a ribosome stalled during translation of the full-length E. coli SecM arrest peptide at 2.0 Å resolution. The structure reveals that SecM arrests translation by stabilizing the Pro-tRNA in the A-site, but in a manner that prevents peptide bond formation with the SecM-peptidyl-tRNA in the P-site. By employing molecular dynamic simulations, we also provide insight into how a pulling force on the SecM nascent chain can relieve the SecM-mediated translation arrest. Collectively, the mechanisms determined here for SecM arrest and relief are also likely to be applicable for a variety of other arrest peptides that regulate components of the protein localization machinery identified across a wide range of bacteria lineages.

Thrombin binding aptamer G-quadruplex stabilized by pyrene-modified nucleotides

Guanine-rich regions of the human genome can adopt non-canonical secondary structures. Their role in regulating gene expression has turned them into promising targets for therapeutic intervention. Ligands based on polyaromatic moieties are especially suitable for targeting G-quadruplexes utilizing their size complementarity to interact with the large exposed surface area of four guanine bases. A predictable way of (de)stabilizing specific G-quadruplex structures through efficient base stacking of polyaromatic functional groups could become a valuable tool in our therapeutic arsenal. We have investigated the effect of pyrene-modified uridine nucleotides incorporated at several positions of the thrombin binding aptamer (TBA) as a model system. Characterization using spectroscopic and biophysical methods provided important insights into modes of interaction between pyrene groups and the G-quadruplex core as well as (de)stabilization by enthalpic and entropic contributions. NMR data demonstrated that incorporation of pyrene group into G-rich oligonucleotide such as TBA may result in significant changes in 3D structure such as formation of novel dimeric topology. Site specific structural changes induced by stacking of the pyrene moiety on nearby nucleobases corelate with distinct thrombin binding affinities and increased resistance against nuclease degradation.

Conformational Dynamics of the RNA G-Quadruplex and its Effect on Translation Efficiency

During translation, intracellular mRNA folds co-transcriptionally and must refold following the passage of ribosome. The mRNAs can be entrapped in metastable structures during these folding events. In the present study, we evaluated the conformational dynamics of the kinetically favored, metastable, and hairpin-like structure, which disturbs the thermodynamically favored G-quadruplex structure, and its effect on co-transcriptional translation in prokaryotic cells. We found that nascent mRNA forms a metastable hairpin-like structure during co-transcriptional folding instead of the G-quadruplex structure. When the translation progressed co-transcriptionally before the metastable hairpin-like structure transition to the G-quadruplex, function of the G-quadruplex as a roadblock of the ribosome was sequestered. This suggested that kinetically formed RNA structures had a dominant effect on gene expression in prokaryotes. The results of this study indicate that it is critical to consider the conformational dynamics of RNA-folding to understand the contributions of the mRNA structures in controlling gene expression.

Recovery of the Formation and Function of Oxidized G-Quadruplexes by a Pyrene-Modified Guanine Tract

Oxidation is one of the frequent causes of DNA damage, especially to guanine bases. Guanine bases in the G-quadruplex (G4) are sensitive to damage by oxidation, resulting in transformation to 8-oxo-7,8-dihydroguanine (8-oxoG). Because the formation of G4 represses the expression of some cancer-related genes, the presence of 8-oxoG in a G4 sequence might affect G4 formation and induce cancer progression. Thus, oxidized-G4 formation must be controlled using a chemical approach. In the present study, we investigated the effect of introduction of 8-oxoG into a G4 sequence on the formation and function of the G4 structure. The 8-oxoG-containing G4 derived from the promoter region of the human vascular endothelial growth factor ( VEGF) gene differed topologically from unoxidized G4. The oxidized VEGF G4 did not act as a replication block and was not stabilized by the G4-binding protein nucleolin. To recover G4 function, we developed an oligonucleotide consisting of a pyrene-modified guanine tract that replaces the oxidized guanine tract and forms stable intermolecular G4s with the other intact guanine tracts. When this oligonucleotide was used, the oxidized G4 stalled replication and was stabilized by nucleolin as with the unmodified G4. This strategy generally enables recovery of the function of any oxidized G4s and therefore has potential for cancer therapy.

Antigen-responsive fluorescent antibody probes generated by selective N-terminal modification of IgGs

Fluorescent antibody probes showing antigen-dependent fluorescence responses were developed by N-terminal-selective reductive alkylation of IgGs.

In situ monitoring of structural changes during formation of 30S translation initiation complex by energy dissipation measurement using 27-MHz quartz-crystal microbalance

Ribosome is a bionanomachine that facilitates an orderly translation process during protein synthesis in living cells. Real-time monitoring of conformational changes in ribosomal subunits in aqueous solution is important to understand the regulatory mechanism of protein synthesis, because conformational changes in ribosome in E. coli have been predicted to operate the switch from translation initiation to an elongation process during translation. We performed an energy dissipation measurement by using a quartz-crystal microbalance-admittance (QCM-A) technique for in situ monitoring of conformational changes in pre-30S translation initiation complex in response to the binding of fMet-tRNA(fMet) in aqueous solution. The addition of fMet-tRNA(fMet) caused changes in the physical property (increased dehydration and elasticity) in 30S ribosomal subunit in the presence of mRNA and IF2/guanosine 5'-triphosphate (GTP) on the QCM plate. Furthermore, two sequential changes triggered by the addition of fMet-tRNA(fMet) were observed in 30S ribosomal subunit bound to mRNA in the presence of IF2/GTP and IF3. These observations suggest that the structural changes in 30S ribosomal subunit caused by the binding of fMet-tRNA(fMet) with IF2/GTP in the presence of IF3 could act as a switch to regulate the orderly processing in the construction of translation initiation complex, because the structural distinction can be a guidepost in the process for the relevant biomolecules.

Translation enhancer improves the ribosome liberation from translation initiation

For translation initiation in bacteria, the Shine-Dalgarno (SD) and anti-SD sequence of the 30S subunit play key roles for specific interactions between ribosomes and mRNAs to determine the exact position of the translation initiation region. However, ribosomes also must dissociate from the translation initiation region to slide toward the downstream sequence during mRNA translation. Translation enhancers upstream of the SD sequences of mRNAs, which likely contribute to a direct interaction with ribosome protein S1, enhance the yields of protein biosynthesis. Nevertheless, the mechanism of the effect of translation enhancers to initiate the translation is still unknown. In this paper, we investigated the effects of the SD and enhancer sequences on the binding kinetics of the 30S ribosomal subunits to mRNAs and their translation efficiencies. mRNAs with both the SD and translation enhancers promoted the amount of protein synthesis but destabilized the interaction between the 30S subunit and mRNA by increasing the dissociation rate constant (koff) of the 30S subunit. Based on a model for kinetic parameters, a 16-fold translation efficiency could be achieved by introducing a tandem repeat of adenine sequences (A20) between the SD and translation enhancer sequences. Considering the results of this study, translation enhancers with an SD sequence regulate ribosomal liberation from translation initiation to determine the translation efficiency of the downstream coding region.

Translational halt during elongation caused by G-quadruplex formed by mRNA

mRNA forms various secondary and tertiary structures that affect gene expression. Although structures formed in the untranslated regions (UTRs) of mRNAs that inhibit translation have been characterized, stable mRNA structures in open reading frames (ORFs) may also cause translational halt or slow translation elongation. We previously established a method, termed a synchronized translation assay, that enables time course analysis of single turnover translation elongation. In this method, translation initiation, which is a rate determining step of the translation procedure, can be ignored because all ribosomes are synchronized on a specific position of mRNA before translation elongation is restarted from this position. In this paper, we used the synchronized translation assay to evaluate the effects of a G-quadruplex structure located at various positions within the mRNA ORF on translational halt.

Direct monitoring of initiation factor dynamics through formation of 30S and 70S translation-initiation complexes on a quartz crystal microbalance

Translation initiation is a dynamic and complicated process requiring the building a 70S initiation complex (70S-IC) composed of a ribosome, mRNA, and an initiator tRNA. During the formation of the 70S-IC, initiation factors (IFs: IF1, IF2, and IF3) interact with a ribosome to form a 30S initiation complex (30S-IC) and a 70S-IC. Although some spectroscopic analyses have been performed, the mechanism of binding and dissociation of IFs remains unclear. Here, we employed a 27 MHz quartz crystal microbalance (QCM) to evaluate the process of bacterial IC formation in translation initiation by following frequency changes (mass changes). IFs (IF1, IF2, and IF3), N-terminally fused to biotin carboxyl carrier protein (bio-BCCP), were immobilized on a Neutravidin-covered QCM plate. By using bio-BCCP-IF2 immobilized to the QCM, three steps of the formation of ribosomal initiation complex could be sequentially observed as simple mass changes in real time: binding of a 30S complex to the immobilized IF2, a recruitment of 50S to the 30S-IC, and formation of the 70S-IC. The kinetic parameters implied that the release of IF2 from the 70S-IC could be the rate-limiting step in translation initiation. The IF3-immobilized QCM revealed that the affinity of IF3 for the 30S complex decreased upon the addition of mRNA and fMet-tRNA(fMet) but did not lead to complete dissociation from the 30S-IC. These results suggest that IF3 binds and stays bound to ICs, and its interaction mode is altered during the formation of 30S-IC and 70S-IC and is finally induced to dissociate from ICs by 50S binding. This methodology demonstrated here is applicable to investigate the role of IFs in translation initiation driven by other pathways.

Traveling Time of a translating ribosome along messenger RNA monitored directly on a quartz crystal microbalance

During translation, the biosynthesis of polypeptides is dynamically regulated. The translation rate along messenger RNA (mRNA), which is dependent on the codon, structure, and sequence, is not always constant. However, methods for measuring the duration required for polypeptide elongation on an mRNA of interest have not been developed. In this work, we used a quartz crystal microbalance (QCM) technique to monitor mRNA translation in an Escherichia coli cell-free translation system in real time. This method permitted us to evaluate the translation of proteins of interest fused upstream of a streptavidin-binding peptide (SBP) fusion protein. The translation of mRNA encoding the SBP fusion protein alone was observed as a mass increase on a streptavidin-modified QCM plate. Addition of the protein of interest resulted in a delay in the mass change corresponding to the traveling time of the ribosome along the coding region of the protein of interest. With this technique, the lengths of coding sequences, codon usages, influences of unique sequences, and various protein-coding sequences were evaluated. The results showed that the traveling time of the translating ribosome depends on the length of the coding region translated but is also affected by the sequence itself. Differences in the time lags for various proteins imply that mRNA coding sequences may regulate gene expression.

Synchronized translation for detection of temporal stalling of ribosome during single-turnover translation

Arrhythmic translation caused by temporal stalling of ribosome during translation elongation is essential for gene expression and protein folding. To analyze the positions of the temporarily stalled ribosome and length of the stalling, the ribosomes must be synchronized during translation elongation. In this study, we designed a two-step translation reaction to synchronize the ribosome during a single-turnover translation. First, ribosomes decoding mRNA were artificially and specifically halted before isoleucine codon by reducing isoleucyl-tRNA synthetase from reaction mixture of in vitro translation. Then, translation elongation was restarted simultaneously to synchronize the translation. It enabled evaluation of translation elongation with time resolving capacity shorter than ever before. In addition, position-specific incorporation of fluorescent amino acid and mass spectrometry analyses enabled trace of translation elongation after gel electrophoresis and accurate determination of ribosome positions temporarily stalled before rare codons, respectively. The synchronized translation demonstrated here would be useful to evaluate trans- and cis-elements that affect rate of the translation elongation.

Real-time monitoring of a stepwise transcription reaction on a quartz-crystal microbalance

We monitored real-time DNA transcription by T7 RNAP using a 27-MHz DNA-immobilized quartz-crystal microbalance (QCM) in buffer solution to investigate the stepwise reaction of transcription. We designed a template double-stranded DNA that consisted of a T7 promoter, a stall position (15 bp downstream from the promoter), and a 73-bp transcription region. Based on the frequency (mass) changes of the template-immobilized QCM in response to the addition of T7 RNAP and monomers of NTP, we obtained the kinetic parameters of each step of the T7 RNAP reactions: the enzyme-binding rate (k(on)) to and the dissociation rate (k(off)) from the promoter, the proceeding rate (k(for)) from the promoter to the forward stall position, the polymerization rate (k(cat)) of RNA along DNA, and the release rate (k(r)) from the end of the template DNA. We found that k(cat) (120 s⁻¹) was extremely large compared with k(off) (0.014 s⁻¹), k(for) (0.062 s⁻¹), and k(r) (0.014 s⁻¹), revealing that the rate-limiting steps of T7 RNAP involve the binding to the promoter, the movement to the stall position, and the release from DNA. These kinetic parameters were compared with values for other DNA-binding enzymes.

In vitro protein expression: an emerging alternative to cell-based approaches

Protein expression remains a bottleneck in the production of proteins. Owing to several advantages, cell-free translation is emerging as an alternative to cell-based methods for the generation of proteins. Recent advances have led to many novel applications of cell-free systems in biotechnology, proteomics and fundamental biological research. This special issue of New Biotechnology describes recent advances in cell-free protein expression systems and their applications.

Measuring cotranslational folding of nascent polypeptide chains on ribosomes

Protein folding has been studied extensively in vitro, but much less is known about how folding proceeds in vivo. A particular distinction of folding in vivo is that folding begins while the nascent polypeptide chain is still undergoing synthesis by the ribosome. Studies of cotranslational protein folding are inherently much more complex than classical in vitro protein folding studies, and historically there have been few methods available to produce the quantities of pure material required for biophysical studies of the nascent chain, or assays to specifically interrogate its conformation. However, the past few years have produced dramatic methodological advances, which now place cotranslational folding studies within reach of more biochemists, enabling a detailed comparison of the earliest stages of protein folding on the ribosome to the wealth of information available for the refolding of full-length polypeptide chains in vitro.