Ravindra V. Dalal scite author profile

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.D etermining the molecular details of the time evolution of complex multicomponent biological systems requires analysis at the single-molecule level because of their stochastic and heterogeneous nature. Ideally, such experiments would track simultaneously the composition of a biological system (bound ligands, factors, and cofactors) and the conformation of the individual molecules in real time. Single-molecule fluorescence methods, such as total internal reflection fluorescence (TIRF) microscopy, allow the observations of the compositional dynamics (through arrival of fluorescently labeled ligands, factors, or cofactors) and conformational dynamics (through FRET) of single-molecular species. However, these traditional singlemolecule methods are hindered by limitations in maximal fluorescent component concentrations (up to 50 nM) (1), limited simultaneous detection (two to three colors) (2-6), and low throughput (a few hundred molecules at most per experiment) (7). As such, the full potential of single-molecule fluorescence to investigate a range of biological problems under physiologically relevant conditions has not yet been harnessed.Zero-mode waveguides (ZMWs) are small metallic apertures patterned on glass substrates that overcome the concentration restrictions by optically limiting background excitation (8). Each ZMW consists of an ∼150-nm-diameter metallic aperture that restricts the excitation light to a zeptoliter volume, making possible experiments with near-physiological concentrations (up to 20 μM) of fluorescently labeled ligands (1). Previous advances in nanofabrication (9), surface chemistry (10), and detection instrumentation (11) have led to ZMW-based instrumentation capable of the direct observation of DNA polymerization (12), reverse transcription (13), processive myosin motion (14), and translation by the ribosome (15, 16) with multicolor single-molecule detection. However, this sophisticated technology has not been broadly available to the scientific community. Despite multiple efforts to develop ZMW instrumentation, the combined difficulties in fabrica...

show abstract

Sequence-Dependent Pausing of Single Lambda Exonuclease Molecules

Perkins

Dalal

Mitsis³

et al. 2003

Science

129

136

View full text Add to dashboard Cite

Lambda exonuclease processively degrades one strand of duplex DNA, moving 5′-to-3′ in an ATPindependent fashion. When examined at the single-molecule level, the speeds of digestion were nearly constant at 4 nanometers per second (12 nucleotides per second), interspersed with pauses of variable duration. Long pauses, occurring at stereotypical locations, were strand-specific and sequence-dependent. Pause duration and probability varied widely. The strongest pause, GGCGATTCT, was identified by gel electrophoresis. Correlating single-molecule dwell positions with sequence independently identified the motif GGCGA. This sequence is found in the left lambda cohesive end, where exonuclease inhibition may contribute to the reduced recombination efficiency at that end.Exonucleases are integral components of many genetic repair and recombination pathways (1). Processive 5′→3′ exonucleases generate DNA intermediates with long 3′-overhangs involved in these pathways (1, 2); in bacteriophage lambda, the Red α gene encodes the 24-kD subunit of such a nuclease (3). The structure of lambda exonuclease (λ-exo) consists of a toroidal homotrimer of subunits, with a tapered central channel sufficient to admit doublestranded DNA (dsDNA) at its entrance but only wide enough to pass single-stranded DNA (ssDNA) through its exit (4). A topological constraint may therefore underlie the high processivity of λ-exo (>3000 base pairs, where 1 bp corresponds to a helical rise of 0.338 nm along dsDNA) (5). λ-exo digestion requires Mg 2+ , but does not require ATP or GTP, and proceeds along DNA at rates of 2 to 3.5 nm/s, as determined by bulk biochemical studies (6, 7).Here, we developed a novel high-resolution, single-molecule assay to study λ-exo motion by optical trapping nanometry. Besides measuring individual translocation rates, single-molecule studies provide insights into other processes that are obscured by bulk averages. For example, certain processive DNA enzymes pause for variable intervals, a behavior that may reflect offpathway branches in the reaction cycle. Pausing behavior has been observed in single-molecule ‡To whom correspondence should be addressed.

show abstract

Forward and Reverse Motion of Single RecBCD Molecules on DNA

Perkins

Dalal

et al. 2004

Biophysical Journal

135

122

View full text Add to dashboard Cite

RecBCD is a processive, DNA-based motor enzyme with both helicase and nuclease activities. We used highresolution optical trapping to study individual RecBCD molecules moving against applied forces up to 8 pN. Fine-scale motion was smooth down to a detection limit of 2 nm, implying a unitary step size below six basepairs (bp). Episodes of constantvelocity motion over hundreds to thousands of basepairs were punctuated by abrupt switches to a different speed or by spontaneous pauses of mean length 3 s. RecBCD occasionally reversed direction, sliding backward along DNA. Backsliding could be halted by reducing the force, after which forward motion sometimes resumed, often after a delay. Elasticity measurements showed that the DNA substrate was partially denatured during backsliding events, but reannealed concomitant with the resumption of forward movement. Our observations show that RecBCD-DNA complexes can exist in multiple, functionally distinct states that persist for many catalytic turnovers: such states may help tune enzyme activity for various biological functions.

show abstract

Pulling on the Nascent RNA during Transcription Does Not Alter Kinetics of Elongation or Ubiquitous Pausing

et al. 2006

View full text Add to dashboard Cite

Transcriptional elongation and termination by RNA polymerase (RNAP) are controlled by interactions among the nascent RNA, DNA, and RNAP that comprise the ternary transcription elongation complex (TEC). To probe the effects of cotranscriptionally folded RNA hairpins on elongation as well as the stability of the TEC, we developed a single-molecule assay to monitor RNA elongation by Escherichia coli RNAP molecules while applying controlled loads to the nascent RNA that favor forward translocation. Remarkably, forces up to 30 pN, twice those required to disrupt RNA secondary structure, did not significantly affect enzyme processivity, transcription elongation rates, pause frequencies, or pause lifetimes. These results indicate that ubiquitous transcriptional pausing is not a consequence of the formation of hairpins in the nascent RNA. The ability of the TEC to sustain large loads on the transcript reflects a tight binding of RNA within the TEC and has important implications for models of transcriptional termination.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Ravindra V. Dalal

Real-Time DNA Sequencing from Single Polymerase Molecules

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

Sequence-Dependent Pausing of Single Lambda Exonuclease Molecules

Forward and Reverse Motion of Single RecBCD Molecules on DNA

Pulling on the Nascent RNA during Transcription Does Not Alter Kinetics of Elongation or Ubiquitous Pausing

Contact Info

Product

Resources

About