This protocol demonstrates a simple single-molecule fluorescence microscopy technique for visualizing DNA replication by individual replisomes in real time.
Before performing a single-molecule replication experiment, a few materials need to be prepared in advance.
1. DNA Replication Template
The substrate for the replication reaction is a biotinylated, tailed M13 rolling circle prepared using standard molecular biology techniques1,2.
Materials: M13mp18 single-stranded DNA, Biotinylated tail oligonucleotide primer (5′-Biotin-T36AATTCGTAATCATGGTCATAGCTGTTTCCT-3′), T7 DNA polymerase, Heat block, Phenol/Isoamyl Alcohol/Chloroform
2. Functionalized Coverslips
For attaching the DNA to the glass coverslip, the glass is first functionalized with an aminosilane, which is then coupled to biotinylated PEG molecules. This coating helps to reduce the nonspecific interactions of DNA and replication proteins with the surface1,3.
Materials: Glass coverslips, Staining jars, 3-aminopropyltriethoxysilane, Methoxy-PEG5k-NHS ester, Biotin-PEG5k-NHSester, Acetone, 1M KOH, Ethanol, Oven, Bath sonicator
These materials should be made ahead of time, and then used for each experiment. To start every single-molecule experiment, begin by assembling the flow chamber.
3. Flow Chamber Preparation
The experiment is performed using a simple flow chamber constructed with a functionalized coverslip, double-sided tape, a quartz slide and tubing. One flow chamber is prepared for each single-molecule experiment1,4.
Materials: Double-sided tape, Razor blade, Quartz slide with holes for tubing, Quick-dry epoxy, Functionalized coverslip (see above), Streptavidin solution (25 μL of 1 mg/mL in PBS), Tubing, Blocking buffer (20 mM Tris pH 7.5, 2 mM EDTA, 50 mM NaCl, 0.2 mg/mL BSA, 0.005% Tween-20)
4. Single-Molecule Replication Experiment
Materials: Prepared flow chamber, SYTOX Orange, TIRF microscope, 532 nm laser, CCD camera, Computer with image acquisition software, Rolling-circle DNA substrate, Replication proteins
5. Representative Results
Actively replicating molecules are easily seen as growing lines of stained DNA. In our experiments, flowing 25 pM of the M13 substrate gives 100-1000 molecules in a 60x, 125 μm x 125 μm field of view (Figure 1). Performing replication experiments using the E. coli replisome proteins at 37 °C (see Materials for details) gives 5-50 replicating molecules per field of view. At equivalent concentrations of the T7 replisome, which initiates on the substrate much more efficiently, we observe >70% of the molecules in a field replicate. These conditions yield a product density so high that individual molecules are difficult to resolve and analyze, so the T7 experiments are performed at lower protein concentrations.
Data Analysis: To obtain rate data, simply plot the endpoint of the DNA vs. time and calculate the slope (Figure 2). For processivity, determine the total length of the DNA. Both of these numbers will need to be converted to base pairs. Before performing the experiment, you should know the pixel size of the camera at the proper magnification. For basepair conversion, a good estimation is simply converting based on the crystallographic length of DNA, 2.9 bp/nm. However, laminar flow will not completely stretch the DNA, so a DNA length calibration should be performed by taking a known length DNA, e.g. 48,502 bp λ DNA, attaching it to the flow cell with a biotinylated oligo and measuring its SYTOX-stained length at the flow rate used for replication experiment. Determining the number of base pairs/pixel will allow accurate calculation of replication rates and processivities. Taking numerous images and movies will provide large numbers of product molecule, allowing plotting of rate and processivity distributions (Figure 2)1.
Figure 1: (From Ref. 1) a) Cartoon of the rolling-circle replication assay. (SA, streptavidin). Leading-strand synthesis extends the tail linking the circle and surface. The tail is converted to dsDNA by the lagging strand polymerase and stretched by laminar flow.
b) Example field of view with SYTOX Orange and 532 nm excitation. Small fluorescent spots are tethered, non-replicated substrates. Note the extreme length of the products and the large number of products per field (each flow cell contains >5000 such fields).
Figure 2: (adapted from Ref. 1) a,b) Kymographs of typical replicating molecules from T7 (a) and E. coli (b) experiments. c) Endpoint trajectories of molecules from a) and b) plotted vs. time. Trajectories are fitted with linear regression to obtain replication rates. Shown examples are 99.4 bp s-1 and 467.1 bp s-1. d) Length distributions of replication products, fit with single exponential decay to obtain processivity: 25.3 ± 1.7 kbp (T7), 85.3 ± 6.1 kbp (E. coli). e) Rate distributions of single molecule trajectories, fit with single Gaussians. Means: 75.9 ± 4.8 bp s-1 (T7), 535.5 ± 39 bp s-1 (E. coli).
One critical control is examining the effect of the stain, SYTOX Orange, on the replication proteins of interest. A simple way to do this is to perform the replication experiment in the flow cell as described but with the omission of SYTOX. After the reaction mixture has flowed through the chamber, add buffer with SYTOX to stain DNA and examine the length distribution of replicated molecules. Alternatively, standard bulk reactions can be used to check any effect of SYTOX on replication rate and efficiency.
The experiment described here uses only a single flow channel. This can be changed easily by creating multi-channel flow chambers or using PDMS or similar microfluidic devices. Increasing the number of channels greatly facilitates screening of protein concentrations, mutants, or inhibitor molecules and increases the rapidity of replication data collection.
As mentioned, we perform the E. coli replication experiments at 37 °C using a home-built aluminum flow cell heater, a resistive heating element (cartridge heater) and variable power supply. This gives good temperature stability and avoids the purchase of an objective heater. To calibrate the heater, we simply drilled a hole in the center of a quartz flow cell top, inserted a thermocouple into the flow channel and flowed buffer as normal. Measuring the flow cell buffer temperature at increasing voltages allows accurate heating.
Samir Hamdan aided in the development of this technique. E. coli proteins are from the lab of Prof. Nick Dixon, University of Wollongong, and T7 proteins are from Prof. Charles Richardson, Harvard Medical School. Work is supported by the National Institutes of Health (GM077248 to A.M.v.O.) and the Jane Coffin Childs Foundation (J.J.L.).
Material Name | Tip | Company | Catalogue Number | Comment |
---|---|---|---|---|
M13mp18 ssDNA | New England Biolabs | N4040 | ||
Biotinylated Tail Oligo | Integrated DNA Technologies | |||
T7 DNA Polymerase | New England Biolabs | M0274 | Use T7 replication buffer for substrate preparation | |
Phenol/ Isoamyl Alcohol/ Chloroform | Roche | 03117987001 | 24:24:1 v/v | |
3-aminopropyl-triethoxysilane | Sigma | A3648 | Other aminosilanes can be used or mixed with non-amine reactive silanes for sparser surfaces | |
Succinimidyl propionate PEG | Nektar | Similar PEGs can be purchased from Nanocs, CreativePEGWorks, etc. | ||
Biotin-PEG-NHS | Nektar | |||
Double-sided tape | Grace BioLabs | SA-S-1L | 100 μm thickness | |
Quartz slide | Technical Glass | 20 mm (W)x 50 mm (L)x 1mm (H) |
Size to fit on coverslips. Drill holes with diamond-tip drill bits (DiamondBurs.net) | |
Polyethylene tubing | Becton Dickinson | 427416 | 0.76 mm ID, 1.22 OD Other size tubing can be substituted. |
|
Streptavidin | Sigma | S4762 | Make 1 mg/mL solution, 25 μL aliquots in PBS pH 7.3 | |
Deoxyribonucleotide triphosphate solution mix | New England Biolabs | N0447 | ||
Ribonucleotide triphosphate solutions | Amersham | 272056 272066 272076 272086 |
||
SYTOX Orange | Invitrogen | S11368 | Other dsDNA stain can be used | |
Fluorescence Microscope with 60x TIRF objective | Olympus | IX-71 | Microscope, camera, etc. can be substituted for similar equipment | |
Syringe Pump | Harvard Apparatus | 11 Plus | Operate in refill mode to facilitate solution changes | |
532 nm laser | Coherent | Compass 215M-75 | Select wavelength to correspond to stain of choice | |
EMCCD Camera | Hamamatsu | ImagEM | ||
Emission filter | Chroma | HQ600/75m |
T7 Replication: 40 mM Tris pH 7.5, 50 mM potassium glutamate, 10 mM magnesium chloride, 100 μg/mL BSA, with 5 mM dithiothreitol, 600 μM dNTPs, 300 μM ATP, 300 μM CTP, and 15 nM SYTOX Orange added immediately before use. Proteins added as: 5 nM gp4 (hexamer), 40 nM polymerase (1:1 gp5: thioredoxin), 360 nm gp2.51,5.
E. coli Replication: 50 mM HEPES pH 7.9, 12 mM magnesium acetate, 80 mM potassium chloride, 100 μg/mL BSA with 10 mM dithiothreitol, 40 μM dNTPs, 200 μM rNTPs, and 15 nM SYTOX Orange added immediately before use. Proteins added as: 30 nM DnaB (hexamer), 180 nM DnaC (monomer), 30 nM αεθ, 15 nM τ2γ1δδ’χψ or τ3δδ’χψ, 30 nM β (dimer), 300 nM DnaG, 250 nM SSB (tetramer), 20 nM PriA, 40 nM PriB, 320 nM PriC, 480 nM DnaT1,6