Difference between revisions of "Team:Hong Kong HKU/Results"

Simplified Beacon

It is not difficult to observe a simplified molecular beacon can be assembled Oligo 1 and Oligo 5, in which they possess a complementary region as counterparts. This region is a functional unit of a YES-Gate, which are the essential components of the tetrahedron structure (see later for more).
We started off with this simplified version of the nanostructure to do several prelimary testings. One of the testings was to check whether they are able to anneal as a response to the addition of input.

Below shows the results of 12% PAGE for the assembly of the beacon and the addition of the input. The beacon was made by adding equal quantity of Oligos 1 and 5 in TM Buffer. It is noted that the formation of complex nanostructures is allowed by a standard procedure of heating it up followed by step-wise cooling. The detailed protocol regarding Nanostructure Assembly could be found here.

12% PAGE stained with GelRed and photographed under UV light to check for beacon assembly and input addition.

Tetrahedron nanostructure

The tetrahedron nanostructure is much more complex. It consists of a total of 5 oligos and has a wider range of combinations subjected to investigation.
We have performed 12% PAGE to investigate into the migration of all 31 combinations of the 5 oligos (oligos alone included). Several combinations of oligos are expected to anneal to form dimers, trimers and quadruplexes.

The results from PAGE were consistent with the list below.

It is quite easy to notice that the assembled tetrahedron stationed at the very top of the gel, meaning that perhaps it might be too large in size that is hard to move along.
A lower arcylamide percentage of the gel might give a signifcantly different result.
With the same tube of tetrahedron sample, we therefore later on performed a 8% PAGE to observe any differences on the migration of the tetrahedron.

8% PAGE gel stained with GelRed and visualized under UV light to check for differences in migration compared to gels with higher acrylamide concentration (12%)

From the above PAGE gels, still, it was well observed that the tetrahedron remained at the very top position of the gel. It reflects the diameter of the tetrahedron to be larger than that of the pore sizes of 8% polyacrylamide gels. We proceed to replicate the experiment on an 1% agarose gel. Now, the oligos alone are expected to be dots as they are too small to be resolved well at 1% Agarose.

1% agarose gel stained with GelRed and visualized under UV light to show assembly of the tetrahedral structure from the five oligos O1 to O5.

It is clear that there are still some trapped at the well of the Agarose gel. From such observations, and from literature, the gel pore size of 1% Agarose gel ranges from 100nm to 500nm. The diameter of our nanostructure is expected to be greater than 500nm.
ref: Jean-Louis Viovy (2000). "Electrophoresis of DNA and other polyelectrolytes: Physical mechanisms".Reviews of Modern Physics. 72: 813–872. Bibcode:2000RvMP...72..813V.doi:10.1103/RevModPhys.72.813. ^ Jump up to:a b Philip Serwer (1983). "Agarose gels: Properties and use for electrophoresis". Electrophoresis. 4 (6): 375–382. doi:10.1002/elps.1150040602.

PAGE and Agarose Gel Electrophoresis

The figure recalls the strand displacement reaction.

Another replication of the identical PAGE experiment with the abive is conducted at 15% arcylamide percentage. Apart from providing another strong evidence of the successful assembly of the tetrahedral nanostructure (Lane 7 and Lane 10), it is even more clearer to observe a signifcant difference in the band in Lane 6 (Oligo 5), Lane 8 (Input Oligo) and Lane 9 (Oligo 5 + Input Oligo). The formation of a larger complex proves a strand displacement to occur when the two oligo meets.

15% PAGE gel stained with GelRed and visualized under UV light to demonstrate successful assembly of the tetrahedron and displacement by input strand.

Similar to the assembly protocol, the experiment was replicated on a 1% Agarose gel:
Once again, the bands in Lanes 8 and Lane 9 demostrated a strand displacement.

1% agarose gel stained with GelRed and visualized under UV light to demonstrate successful assembly of the tetrahedron and displacement by input strand.

O1+O5 beacon and others

The following is the result of a 15% PAGE experiements that includes the analysis of the O1+O5 beacon, O1-O4 beacon and the tetrahedron. This gel image provides another promising evidence of the assembly of O1+O5. With reference to Lane 7 and Lane 8, Lane 4 and Lane 10, and Lane 9, it was showed that O5 is necessary for the strand displacement as the input strand binds to and only to Oligo 5 as the speciflied target.

15% PAGE gel stained with GelRed and visualized under UV light for analysis of O1+O5 beacon, O1-O4 beacon and the tetrahedron.

PCR Method

Due to the small size of the output product, or, the dimer between the input strand and Oligo 5 (30 nucleotides long), we manipulated this as the primers to amplify the template strand. The template strand was made from 2 complementary single-stranded sequences in the thermocycler, and was designed in such that both the sense and antisense strands of the output dsDNA can anneal and hence act as primers. We first run an Agarose Gel electrophoresis against the tetrahedron displacement, which provides another solid evidence of the strand displacement. We then extracted the output product from the gel. Below shows the difference between before and after cutting the 1% Agarose gel for extraction. The yellow and blue boxes indicate the site where the expected displaced products should be.

1% agarose gel stained with GelRed and visualized under UV light for demonstration of strand displacement and extraction of output product.

We then set the PCR program with the aid of NEB T_m calculator for the anneal temperature to start the PCR run and performed the PAGE with appropriate controls.

We used nanodrop to measure the concentrations of all the tubes that had been in the thermocycler. Each PCR tube contains 2nM of the template strand, as contained components according to the protocol available on the NEB website.

	From Gel Extraction				After PCR
	OUT	TD1	TD2	TD3	OUT	TD1	TD2	TD3	Control
Nanodrop result (ng/μL)	7.5	8.6	4.6	5.0	396.1	398.4	391.6	403.9	1.4

Image J analyais of the gel was performed so as to analyze the relative increase to the marker (OUT), which acted as a positive control.

	A	B	C	D	E
Output (O5 & input)		+	+	+	+
Template	+	+	+	+	+
Peak intensities (arbitrary units)	1571	9835	7627	7440	8024

It is clear that the concentration increased and this shows the correct output product via strand displacement. Mutants

We tested in total 6 mutants, where 3 experienced single-base mutation, each of two experienced double- and triple-base mutation, and one random mutant strand of the same length as out target DNA. We also aspired to try the RNA inputs to test our probe, which proves the application with miRNAs as targets, which are promising biomarkers.

	Sequence	Length
DNA Input	CAATCAGGGTCTAACTCCACTGGGTGCCAT	30
DNA Mutant	CAGGCAGTATCATGCGACATTGGGTGCAGC	30
DNA Input	CAAUCAGGGUCUAACUCCACUGGGUGCCAU	30
DNA Mutant	CAGGCAGUAUCAUGCGACAUUGGGUGCAGC	30

We performed PAGE and compared the relative intensities of the output product using ImageJ®. The relative intensities are expected to reflect the rate of strand displacement.

DNA
Gel image showing correct vs random input (same length)

12% PAGE gel stained with GelRed and visualized under UV light to analyze output products.

ABTS Assay is one of the methods to test the G-quadruplex (Gq) formation. While the the upper strand of our nanostructure, Oligo 5, is displaced (shown in the schematic diagram) as the input hybridizes with the bottom strand, Oligo 1, which contains split Gq sequences quickly folds into a 4-strand structure, in the presence of potassium ions. When Gq forms a complex with hemin, it exhibits peroxidase activity and functions as a DNAzyme. It reacts with ABTS or TMB, together with H2O2 and gives out colour change from colorless to green, or to blue for TMB. We perform ABTS assay on a 96-well plate where triplicates are made possible. The experimental procedures of the ABTS assay can be found in here.

Fold Change

In the early stage of our experiment, we tested both the tetrahedral DNA nanostructure and a simplified version of the active component of the tetrahedron (consisting of the O1's G-quadruplex side and O5 of the tetrahedron) for DNA detection. DNA input was added in a 1:1 molar ratio to DNA nanostructure (100nM final). After measuring the absorbance at 420nm, we determined the fold change using the following formula.
Fold change = (absorbance of sample) ÷ (absorbance of -ve control)
Negative control refers to the reaction mixture without DNA nanostructure and DNA input.

Fold changes after the addition of DNA input was shown in the following graph, with the controls of not adding any DNA input to the DNA nanostructure.

Fig. A: Fold change in absorbance at 420nm after the addition of DNA input to the DNA nanostructures (tetrahedron and a simplified version from tetrahedron, which is termed as "beacon" in the above graph). The absorbance was taken 9 minutes after the addition of ABTS and H₂O₂. Error bars show standard deviation from triplicates.

From the above bar chart, since the error bars did not overlap, it shows there is a significant increase in the absorbance with the addition of DNA input. Hence, this is a promising evidence of the Gq formation. It is also noted that the activity of the simplified version of tetrahedron (termed as "beacon" in Fig. A) is similar to that of the tetrahedron.

Mutant testing

After showing that there is indeed an increase in absorbance due to the addition of input and hence the formation of G-quadruplex, we went further to test if such change is specific to the sequence of our input by testing random DNA sequence. The sequences of DNA inputs tested are shown in the table below.

Input (DNA)	Sequence	Length (nucleotide)
Specificd Input	CAATCAGGGTCTAACTCCACTGGGTGCCAT	30
Random mutant	CAGGCAGTATCATGCGACATTGGGTGCAGC

Again, we carried out ABTS assay to detect the presence of G-quadruplex as a result of strand displacement by the input. The probe used in this section is a simplified version consisting of only the Gq side O1 and O5 of the tetrahedron, which is the active component of our tetrahedral DNA nanostructure. Below is the bar chart showing the absorbance of the detection beacon with the addition of a correct DNA input and random DNA, together with appropriate controls.

Fig. B: Absorbance at 420nm after the addition of different DNAs to the simplified DNA nanostructure (formed from O1's G-quadruplex side and O5 of the tetrahedron) which is termed as "beacon" in the above graph. The absorbance was taken 10 minutes after the addition of ABTS and H₂O₂. Error bars show standard deviation from triplicates.

It can be seen that adding a random DNA resulted in an absorbance similar to adding no input to our detection beacon, while adding the correct input results in a much higher absorbance. This reflected that our detection beacon can differentiate the correct DNA input from a random DNA sequence.

Limit of Detection

After knowing that our design can distinguish the correct DNA input from random sequence, we were interested to know what was the lowest concentration of input that can be detected.. As a result, we determined the limit of detection (LOD) of our detection beacon (formed from O1's G-quadruplex side and O5 of the tetrahedron, the active component of the tetrahedral nanostructure) by ABTS assay. Different concentrations of input (DNA) were added and their respective absorbance at 420nm was measured. A regression line obtained is shown in the following graph.

Fig. C: Absorbance at 420nm against the concentration of DNA input to the simplified DNA nanostructure (formed from O1's G-quadruplex side and O5 of the tetrahedron). The absorbance was taken 15 minutes after the addition of ABTS and H₂O₂. Error bars show standard deviation from triplicates. The regression line obtained is y=0.0009x+0.2089 (R²=0.9637). The LOD is calculated as follows.

C_LOD = 3(s_y/x)÷b, where

C_LOD is the concentration LOD,
s_y/x is the standard error of regression, and
b is the slope of regression line.

First, the standard error of regression is determined.

X	Y	Y'	Y-Y'	(Y-Y')2
0	0.201	0.2089	-0.00789999999999999	0.0000624099999999998
20	0.230333333333333	0.2269	0.00343333333333301	0.0000117877777777756
40	0.249	0.2449	0.00409999999999999	0.0000168099999999999
60	0.273666666666667	0.2629	0.010766666666667	0.000115921111111118
80	0.279	0.2809	-0.00189999999999996	0.00000360999999999984
100	0.295	0.2989	-0.00390000000000001	0.0000152100000000001
SSE		0.000225748888888893

(Y' is the predicted value from the regression line y=0.0009x+0.2089)

Standard error of regression = √(SSE÷no. of pairs)=√(0.0002257÷6)=0.006133

Limit of detection
C_LOD = 3(s_y/x)÷b = 3(0.006133)÷0.0009 = 20.44nM


A step closer to real-world application - moving to RNA detection

After conducting a series of experiments to detect DNA, we moved on to RNA detection which is more closely related to the potential real-world application of miRNA detection using DNA nanostructure for disease diagnosis. Results regarding RNA detection can be found in here.