The application of single-molecule fluorescence techniques to complex biological systems places demands on the performance of single fluorophores. We present an enzymatic oxygen scavenging system for improved dye stability in single-molecule experiments. We compared the previously described protocatechuic acid/protocatechuate-3,4-dioxygenase system to the currently employed glucose oxidase/catalase system. Under standardized conditions, we observed lower dissolved oxygen concentrations with the protocatechuic acid/protocatechuate-3,4-dioxygenase system. Furthermore, we observed increased initial lifetimes of single Cy3, Cy5, and Alexa488 fluorophores. We further tested the effects of chemical additives in this system. We found that biological reducing agents increase both the frequency and duration of blinking events of Cy5, an effect that scales with reducing potential. We observed increased stability of Cy3 and Alexa488 in the presence of the antioxidants ascorbic acid and n-propyl gallate. This new O(2)-scavenging system should have wide application for single-molecule fluorescence experiments.
We report on and provide a detailed characterization of the performance and properties of a recently developed, all Escherichia coli, cell-free transcription and translation system. Gene expression is entirely based on the endogenous translation components and transcription machinery provided by an E. coli cytoplasmic extract, thus expanding the repertoire of regulatory parts to hundreds of elements. We use a powerful metabolism for ATP regeneration to achieve more than 2 mg/mL of protein synthesis in batch mode reactions, and more than 6 mg/mL in semicontinuous mode. While the strength of cell-free expression is increased by a factor of 3 on average, the output signal of simple gene circuits and the synthesis of entire bacteriophages are increased by orders of magnitude compared to previous results. Messenger RNAs and protein degradation, respectively tuned using E. coli MazF interferase and ClpXP AAA+ proteases, are characterized over a much wider range of rates than the first version of the cell-free toolbox. This system is a highly versatile cell-free platform to construct complex biological systems through the execution of DNA programs composed of synthetic and natural bacterial regulatory parts.
The ribosome, a two-subunit macromolecular machine, deciphers the genetic code and catalyzes peptide bond formation. Dynamic rotational movement between ribosomal subunits is likely required for efficient and accurate protein synthesis, but direct observation of intersubunit dynamics has been obscured by the repetitive, multistep nature of translation. Here, we report a collection of single-molecule fluorescence resonance energy transfer assays that reveal a ribosomal intersubunit conformational cycle in real time during initiation and the first round of elongation. After subunit joining and delivery of correct aminoacyl-tRNA to the ribosome, peptide bond formation results in a rapid conformational change, consistent with the counterclockwise rotation of the 30S subunit with respect to the 50S subunit implied by prior structural and biochemical studies. Subsequent binding of elongation factor G and GTP hydrolysis results in a clockwise rotation of the 30S subunit relative to the 50S subunit, preparing the ribosome for the next round of tRNA selection and peptide bond formation. The ribosome thus harnesses the free energy of irreversible peptidyl transfer and GTP hydrolysis to surmount activation barriers to large-scale conformational changes during translation. Intersubunit rotation is likely a requirement for the concerted movement of tRNA and mRNA substrates during translocation.ribosome dynamics ͉ single-molecule FRET ͉ translocation T ranslation of the genetic code into proteins by the ribosome requires precise, dynamic interplay between numerous protein and RNA elements. The ribosome, a two-subunit, ribonucleoprotein assembly, coordinates these dynamics to read the genetic code and synthesize proteins (1-3). The large and small ribosomal subunits (50S and 30S, respectively) have three distinct transfer RNA (tRNA) binding sites: A (aminoacyl), P (peptidyl), and E (exit), where messenger RNA (mRNA) is decoded and peptide bonds are formed (4-6). The ribosome works in concert with protein factors, including GTPases whose catalytic activity is modulated by the ribosome and its substrates (7,8). During translation initiation, the ribosome is assembled at an AUG start codon on an mRNA and charged with fMettRNA fMet in the P site. This complex is competent to engage in repetitive cycles of peptide elongation during which aminoacyltRNAs are selected at the A site, peptide bonds are formed in the P site, and tRNAs with their associated mRNA codons are translocated from the A and P sites to the P and E sites, respectively (1, 3).Directional movement of mRNA and tRNA on the ribosome during elongation is likely controlled by dynamic changes in ribosome structure (9). High-resolution structural models suggest that the movement of ribosomal domains is intimately linked to key events during translation (10, 11). Furthermore, cryoelectron microscopy (cryo-EM) of ribosome complexes trapped during elongation has identified two functional ribosome states that are related by rotation of the 30S subunit with respect to the 50S s...
CRISPR-Cas systems offer versatile technologies for genome engineering, yet their implementation has been outpaced by ongoing discoveries of new Cas nucleases and anti-CRISPR proteins. Here, we present the use of E. coli cell-free transcription-translation (TXTL) systems to vastly improve the speed and scalability of CRISPR characterization and validation. TXTL can express active CRISPR machinery from added plasmids and linear DNA, and TXTL can output quantitative dynamics of DNA cleavage and gene repression-all without protein purification or live cells. We used TXTL to measure the dynamics of DNA cleavage and gene repression for single- and multi-effector CRISPR nucleases, predict gene repression strength in E. coli, determine the specificities of 24 diverse anti-CRISPR proteins, and develop a fast and scalable screen for protospacer-adjacent motifs that was successfully applied to five uncharacterized Cpf1 nucleases. These examples underscore how TXTL can facilitate the characterization and application of CRISPR technologies across their many uses.
Summary Recent structural data have revealed two distinct conformations of the ribosome during initiation. We employed single-molecule fluorescence methods to probe the dynamic relation of these ribosomal conformations in real time. In the absence of initiation factors, the ribosome assembles in two distinct conformations. The initiation factors discriminate between these two conformations, guiding assembly of the conformation that can enter the elongation cycle. In particular, IF2 both accelerates the rate of subunit joining and actively promotes the transition to the elongation-competent conformation. Blocking GTP hydrolysis by IF2 results in 70S complexes formed in the conformation unable to enter elongation. We observe that rapid GTP hydrolysis by IF2 drives the transition to the elongation-competent conformation, thus committing the ribosome to enter the elongation cycle.
Decades of studies have established translation as a multistep, multicomponent process that requires intricate communication to achieve high levels of speed, accuracy, and regulation. A crucial next step in understanding translation is to reveal the functional significance of the large-scale motions implied by static ribosome structures. This requires determining the trajectories, timescales, forces, and biochemical signals that underlie these dynamic conformational changes. Single-molecule methods have emerged as important tools for the characterization of motion in complex systems, including translation. In this review, we chronicle the key discoveries in this nascent field, which have demonstrated the power and promise of single-molecule techniques in the study of translation.
Initiation of translation establishes the reading frame for protein synthesis and is a key point of regulation1. Initiation involves factor-driven assembly at a start codon of an mRNA of an elongation competent 70S ribosomal particle (in bacteria) from separated 30S and 50S subunits and initiator tRNA. Here we establish by direct single-molecule tracking the timing of initiator tRNA, initiation factor 2 (IF2), 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 acceptor site. These experiments highlight the power of single-molecule approaches to delineate mechanism in complex multicomponent systems.
E. coli cell-free transcription-translation (TXTL) systems offer versatile platforms for advanced biomanufacturing and for prototyping synthetic biological parts and devices. Production and testing could be accelerated with the use of linear DNA, which can be rapidly and cheaply synthesized. However, linear DNA is efficiently degraded in TXTL preparations from Escherichia coli. Here, we show that double-stranded DNA encoding χ sites–eight base-pair sequences preferentially bound by the RecBCD recombination machinery–stabilizes linear DNA and greatly enhances the TXTL-based expression and activity of a fluorescent reporter gene, simple regulatory cascades, and T7 bacteriophage particles. The χ-site DNA and the DNA-binding λ protein Gam yielded similar enhancements, and DNA with as few as four χ sites was sufficient to ensure robust gene expression in TXTL. Given the affordability and scalability of producing the short χ-site DNA, this generalized strategy is expected to advance the broad use of TXTL systems across its many applications.
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