Revision as of 18:14, 21 October 2009

University of Alberta - BioBytes

Anchor Binding Capacity

What you will need:

Paramagnetic Streptavidin Beads
Annealed Anchor

Binding Capacity

Prepare a 20 μM solution of the Anchor (same as Annealing Anchor/Terminator but using 30 μL water instead of 80 μL)
Set up a set of microcentrifuge tubes with 10, 20, 30, 40, 50, 60, 70, 80 μL of 4 mg mL^-1 beads dispensed into the respectively labelled tubes.
Wash the beads twice with 100 μL Wash/Binding buffer and once with 100 μL water, then aspirate water off the beads.
Prepare 4 μL of the 20 μM Anchor solution to separate tubes (corresponding to which bead-containing tube they will be added to) along with enough water to bring the final solution volume up to half the dispensed bead volume. (i.e. to the 40 μL tube add 4 μL Anchor + 16 μL water).
Add half of this solution to the tubes containing the washed beads. Retain the other half.
Suspend the beads in the DNA solution.
Let bind at room temperature for 10 minutes.
Pellet the beads with a magnet and aspirate the solution.
Take readings at A₂₆₀ with a UV-Vis Spectrophotometer of the DNA solutions prior to binding to bead (the half you retained) and after binding to bead (the aspirated solution). (ng of DNA can also be found by in-gel band intensity quantification methods)

Calculation

Using the A₂₆₀ readings, calculate respective ng of DNA by multiplying volume of DNA applied to beads.
Calculate the difference of DNA for each set of readings per bead volume to give ng of DNA bound to bead.
Substite the ng DNA bound into the following equation to get pmol of DNA:
$(ng DNA$ _bound x 10⁹) / (21519.1 g mol^-1 x 10¹²)
Divide this number by the μL of beads used to get binding capacity:
$μL Beads x 10$ ³ x 4 mg mL^-1

Disclaimer

By doing the binding capacity in this manner we found that binding capacity is highly dependant on DNA and bead concentration (see the graphs href="https://2009.igem.org/Team:Alberta/DNAanchor"). Thus, we simply used the calculated binding capacity for 40 μL of beads since this is the volume we use for all builds. A better binding capacity assay should be developed, but due to time constraints this method proved good enough since multiple runs of this experiment yielded numbers with small standard deviation:
209 +/- 20 pmol mg^-1

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	<h3>Disclaimer</h3>		<h3>Disclaimer</h3>
-	<p>By doing the binding capacity in this manner we found that binding capacity is highly dependant on DNA and bead concentration (see the graphs <a href="https://2009.igem.org/Team:Alberta/DNAanchor"</a>). Thus, we simply used the calculated binding capacity for 40 μL of beads since this is the volume we use for all builds. A better binding capacity assay should be developed, but due to time constraints this method proved good enough since multiple runs of this experiment yielded numbers with small standard deviation: <br>209 +/- 20 pmol mg<sup>-1</sup></br>	+	<p>By doing the binding capacity in this manner we found that binding capacity is highly dependant on DNA and bead concentration (see the graphs <a> href="https://2009.igem.org/Team:Alberta/DNAanchor"</a>). Thus, we simply used the calculated binding capacity for 40 μL of beads since this is the volume we use for all builds. A better binding capacity assay should be developed, but due to time constraints this method proved good enough since multiple runs of this experiment yielded numbers with small standard deviation: <br>209 +/- 20 pmol mg<sup>-1</sup></br>

Team:Alberta/Project/BeadBindingCapacity

From 2009.igem.org