Exploring protein-DNA interactions in 3D using in situ construction, manipulation and visualization of individual DNA dumbbells with optical traps, microfluidics and fluorescence microscopy

In this protocol, we describe a procedure to generate 'DNA dumbbells'—single molecules of DNA with a microscopic bead attached at each end—and techniques for manipulating individual DNA dumbbells. We also detail the design and fabrication of a microfluidic device (flow cell) used in conjunction with dual optical trapping to manipulate DNA dumbbells and to visualize individual protein-DNA complexes by single-molecule epifluorescence microscopy. Our design of the flow cell enables the rapid movement of trapped molecules between laminar flow channels and a flow-free reservoir. The reservoir provides the means to examine the formation of protein-DNA complexes in solution in the absence of external flow forces while maintaining a predetermined end-to-end extension of the DNA. These features facilitate the examination of the role of 3D DNA conformation and dynamics in protein-DNA interactions. Preparation of flow cells and reagents requires 2 days each; in situ DNA dumbbell assembly and imaging of single protein-DNA complexes require another day.

[1]  R. Metzler,et al.  Facilitated diffusion with DNA coiling , 2009, Proceedings of the National Academy of Sciences.

[2]  R. Baskin,et al.  Watching individual proteins acting on single molecules of DNA. , 2010, Methods in enzymology.

[3]  P. V. von Hippel,et al.  Diffusion-driven mechanisms of protein translocation on nucleic acids. 1. Models and theory. , 1981, Biochemistry.

[4]  Rod Balhorn,et al.  Processive translocation and DNA unwinding by individual RecBCD enzyme molecules , 2001, Nature.

[5]  R. Larson,et al.  Stretching of a single tethered polymer in a uniform flow. , 1995, Science.

[6]  Gijs J. L. Wuite,et al.  Counting RAD51 proteins disassembling from nucleoprotein filaments under tension , 2008, Nature.

[7]  Eric C Greene,et al.  Organized arrays of individual DNA molecules tethered to supported lipid bilayers. , 2006, Langmuir : the ACS journal of surfaces and colloids.

[8]  E. Peterman,et al.  Combining optical tweezers, single-molecule fluorescence microscopy, and microfluidics for studies of DNA-protein interactions. , 2010, Methods in enzymology.

[9]  F. Harmon,et al.  RecQ helicase, in concert with RecA and SSB proteins, initiates and disrupts DNA recombination. , 1998, Genes & development.

[10]  K. Mir,et al.  Lipid-Based Passivation in Nanofluidics , 2012, Nano letters.

[11]  D. Marenduzzo,et al.  Facilitated diffusion on confined DNA. , 2012, Physical review. E, Statistical, nonlinear, and soft matter physics.

[12]  S. Quake,et al.  Relaxation of a single DNA molecule observed by optical microscopy. , 1994, Science.

[13]  S. Kowalczykowski,et al.  Single-Molecule Imaging of DNA Pairing by RecA Reveals a 3-Dimensional Homology Search , 2011, Nature.

[14]  J. Menetski,et al.  Stable DNA heteroduplex formation catalyzed by the Escherichia coli RecA protein in the absence of ATP hydrolysis. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[15]  V. Walsh Models and Theory , 1987 .

[16]  E. Peterman,et al.  Combining optical trapping, fluorescence microscopy and micro-fluidics for single molecule studies of DNA-protein interactions. , 2011, Physical chemistry chemical physics : PCCP.

[17]  G. Whitesides The origins and the future of microfluidics , 2006, Nature.

[18]  R. Baskin,et al.  Direct imaging of human Rad51 nucleoprotein dynamics on individual DNA molecules , 2009, Proceedings of the National Academy of Sciences.

[19]  R. Baskin,et al.  Visualization of Rad54, a chromatin remodeling protein, translocating on single DNA molecules. , 2006, Molecular cell.

[20]  Kishan Dholakia,et al.  Construction and calibration of an optical trap on a fluorescence optical microscope , 2007, Nature Protocols.

[21]  Anthony J. Manzo,et al.  Do-it-yourself guide: how to use the modern single-molecule toolkit , 2008, Nature Methods.

[22]  Joost van Mameren,et al.  Unraveling the structure of DNA during overstretching by using multicolor, single-molecule fluorescence imaging , 2009, Proceedings of the National Academy of Sciences.

[23]  D E Smith,et al.  Direct observation of tube-like motion of a single polymer chain. , 1994, Science.

[24]  S. Kowalczykowski,et al.  Biochemical characterization of a mutant RecA protein altered in DNA-binding loop 1. , 2003, Biochemistry.

[25]  Ronald J. Baskin,et al.  Direct observation of individual RecA filaments assembling on single DNA molecules , 2006, Nature.

[26]  Taekjip Ha,et al.  DNA-binding orientation and domain conformation of the E. coli rep helicase monomer bound to a partial duplex junction: single-molecule studies of fluorescently labeled enzymes. , 2004, Journal of molecular biology.

[27]  R. Baskin,et al.  1P259 Direct visualization of a chromatin-remodeling protein, Rad54, translocating along single-molecules of double-stranded DNA(9. Molecular motor (I),Poster Session,Abstract,Meeting Program of EABS & BSJ 2006) , 2006 .

[28]  Piero R Bianco,et al.  Laminar flow cells for single-molecule studies of DNA-protein interactions , 2008, Nature Methods.

[29]  G. Wuite,et al.  How DNA coiling enhances target localization by proteins , 2008, Proceedings of the National Academy of Sciences.

[30]  P. V. von Hippel,et al.  Diffusion-driven mechanisms of protein translocation on nucleic acids. 2. The Escherichia coli repressor--operator interaction: equilibrium measurements. , 1981, Biochemistry.

[31]  P. V. von Hippel,et al.  Facilitated Target Location in Biological Systems* , 2022 .