DNA EXTRACTION AND DETERMINATION OF THE LENGTH OF UNKNOWN DNA FRAGMENT BY GEL ELECTROPHORESIS

This experiment aimed to extract DNA from cheek cells and decide the size of an unknown DNA fragment utilizing gel electrophoresis. The DNA was extracted by swishing Gatorade within the mouth, adopted by mixing with detergent, pineapple juice, and isopropyl alcohol, which precipitated the DNA. The extracted DNA was visualized on the interface of the alcohol and answer. For gel electrophoresis, DNA samples, together with a dye combination, unknown DNA, and DNA markers, had been loaded into an agarose gel, and an electrical area was utilized to separate the fragments by measurement. The space migrated by the DNA markers allowed for the estimation of the unknown DNA fragment’s size. The outcomes confirmed that the unknown DNA fragment was roughly 2.7 kilobases (kb) lengthy, based mostly on the semi-logarithmic customary curve. This experiment efficiently demonstrated DNA extraction and electrophoresis, offering insights into molecular biology strategies for DNA evaluation.

Gel electrophoresis separates DNA, RNA, or proteins by measurement (Hames et.al, 1990). Every DNA molecule is a double helix made up of two complementary nucleotide strands held collectively by hydrogen bonds between the bottom pairs guanine (G)-cytosine (C) and adenine (A)-thymine (T). DNA consists of negatively charged phosphate spine causes migration towards the optimistic electrode below an electrical area (Alberts et. al, 2002). Dyes like ethidium bromide and SmartGlow Pre Stain (a non-carcinogenic different) visualize DNA by fluorescing below UV mild. Molecules transfer by the gel’s pores at charges inversely proportional to their size; smaller fragments migrate quicker (Mika et. al, 2024).

Agarose gels are primarily utilized in gel electrophoresis, the place an electrical area is utilized to separate biomolecules based mostly on their measurement and cost. The gel matrix acts as a molecular sieve, permitting smaller molecules emigrate quicker than bigger ones. Agarose gel is a gel-like substance derived from agar; a polysaccharide obtained from pink algae. It’s extensively utilized in molecular biology for the separation and evaluation of nucleic acids (DNA and RNA) and proteins. Gel focus impacts pore measurement and resolving energy, and migration distances may be plotted in opposition to the logarithm of molecular size. DNA markers or ladders, containing recognized fragment sizes, permit for correct measurement estimation of unknown samples by evaluating migration distances. By creating a typical curve from known-length molecules, the lengths of unknown DNA may be calculated, sometimes expressed in kilobases (kb) or base pairs (bp) (Lee et. al, 2012).

The target of this experiment is to measure the size of an unknown DNA fragment by analyzing its electrophoretic migration compared to customary DNA fragments of recognized lengths.

If the unknown DNA fragment migrates equally to a typical DNA fragment of recognized size, then its measurement may be estimated based mostly on that comparability.

DNA Extraction from Cheek Cells

DNA extraction from cheek cells concerned swishing 5 ml of Gatorade of their mouth for two minutes, then transferring the answer to a check tube. After including 2 ml of dishwashing detergent and swirling the tubes to combine, 2 ml of pineapple juice was added to the answer. The tubes had been inverted to combine. Subsequent, 2 ml of ice-cold isopropyl alcohol was gently added, and the tube was left for 10 minutes to precipitate the DNA (Mika et al., 2024).

Preparation of Agarose gel

For the following experiment, Agarose gels had been ready upfront and saved with the grey plastic comb in place. This comb was fastidiously eliminated after the gel solidified and saved for reuse. Every pupil was assigned a selected gel and electrophoresis unit, with the chamber designed to accommodate one gel. When loading samples, it was suggested to skip the tip wells to stop contamination, and college students had been inspired to load two samples of every DNA sort if desired.

Agarose Gel Electrophoresis

Every gel was loaded with three forms of samples: a dye combination, unknown DNA, and a DNA marker, with every effectively holding roughly 25 µL of pattern.

The DNA samples had been ready and frozen previous to the experiment. To load the samples, a micropipette outfitted with a disposable pipet tip was used. The tip was submerged within the pattern answer, and by urgent the thumb button, 25 µL of the pattern was drawn into the pipet tip. Care was taken to verify for and expel any air bubbles earlier than fastidiously directing the pipet tip into the submerged effectively of the gel. Every effectively was crammed to its 25 µL capability with out overfilling, and a brand new pipet tip was used for every pattern to keep away from cross-contamination. After loading, the pattern vials had been returned to the freezer.

As soon as the DNA samples had been loaded, the gels had been positioned within the electrophoresis chamber with the wells closest to the black (detrimental) electrode, guaranteeing that DNA would migrate towards the pink (optimistic) electrode. The buffer answer (0.04 M Tris-Acetate EDTA, pH 8.0) was ready and chilled upfront, and roughly 200 mL of this chilly buffer was added to cowl the gels fully, eliminating any trapped air bubbles. The orange lid was positioned gently on prime, adjusting as mandatory.

An 8 cm clear ruler was positioned on the lid, aligned with the wells to observe DNA migration visually. The gel electrophoresis unit was then related to an influence supply, and the settings had been adjusted to run at 100 volts for 35 minutes. The timer was set, and the beginning button was pressed as soon as all parameters had been confirmed. The progress of DNA migration was noticed by turning on the blue LED mild beneath the chamber, which illuminated the bands as they moved away from the wells.

Electrophoresis continued till the dye combination had migrated to inside 2-3 mm of the gel’s finish. After the run, the unit was turned off, and the cables had been disconnected. The gels had been visualized below the blue LED mild, and pictures had been taken utilizing a black imaging field with an orange filter taped to the lid. Care was taken to align the digital camera with the ruler for correct measurement of bands.

Knowledge Evaluation

Following imaging, the space migrated by DNA Marker Fragment was measured in mm utilizing ruler. Outcomes had been recorded in a delegated desk for evaluation. This distance was plotted on a semi-logarithmic graph in opposition to the recognized sizes of the DNA markers to estimate the unknown fragment’s size in kilobases (kb). The space migrated by the unknown DNA fragment was measured from the effectively to the vanguard of the band. Utilizing the usual curve, the corresponding worth on x-axis of graph, which is the size of unknown DNA fragment (Mika et al., 2024).

Simplified protocol

DNA Extraction from Cheek Cells:

1. Swish 5 mL of Gatorade in mouth for two minutes.
2. Switch the answer to a check tube.
3. Add 2 mL of dishwashing detergent and swirl to combine.
4. Add 2 mL of pineapple juice and invert the tube to combine.
5. Gently add 2 mL of ice-cold isopropyl alcohol.
6. Depart the tube for 10 minutes to precipitate the DNA.

Agarose Gel Electrophoresis:

1. Put together agarose gels upfront, storing them with a grey plastic comb.
2. Take away the comb fastidiously after the gel solidifies for reuse.
3. Assign particular gels and electrophoresis items to every pupil.
4. Skip finish wells to keep away from contamination when loading samples.
5. Load three forms of samples into the wells: dye combination, unknown DNA, and DNA marker (25 µL per effectively).
6. Put together and freeze DNA samples previous to the experiment.
7. Use a micropipette with a disposable pipet tip to load samples into the wells.
8. Guarantee no air bubbles within the pipette tip and use a brand new tip for every pattern.
9. Make sure the gel is positioned within the electrophoresis chamber with the wells close to the black (detrimental) electrode.
10. Put together and chill 200 mL of buffer answer (0.04 M Tris-Acetate EDTA, pH 8.0) upfront.
11. Add the chilled buffer to cowl the gels fully, eradicating air bubbles.
12. Place the orange lid on the electrophoresis chamber, adjusting if mandatory.
13. Use an 8 cm clear ruler to observe DNA migration visually, aligned with the wells.
14. Set the electrophoresis unit to 100 volts for 35 minutes.
15. Observe the DNA migration utilizing the blue LED mild beneath the chamber.
16. Proceed electrophoresis till the dye combination is 2-3 mm from the tip of the gel.
17. After the run, flip off the unit and disconnect the cables.
18. Visualize the gels below blue LED mild and take images utilizing a black imaging field with an orange filter.
19. Align the digital camera with the ruler for correct measurement of bands.

Knowledge Evaluation:

1. Measure the space migrated by the DNA Marker Fragment in mm utilizing a ruler.
2. Document the measurements in a desk for evaluation.
3. Plot the migration distance on a semi-logarithmic graph in opposition to the recognized DNA marker sizes.
4. Estimate the size of the unknown DNA fragment in kilobases (kb) utilizing the usual curve.

Outcomes

The DNA extracted from cheek cells was efficiently precipitated and have become seen on the interface of the alcohol and the answer within the check tube.

The space migrated by DNA marker fragment was measured. The distances had been plotted in a semi-log graph.

Desk 1: DNA Marker Fragment Size

The space migrated by unknown DNA fragment was measured and the fragment size was recognized by evaluating with the corresponding worth of marker in semi-log paper.

Desk 2: Unknown DNA Fragment Size Willpower

Dialogue