1962: nobel prize in physiology and medicine james d. watson francis h. crick maurice h. f. wilkins...
TRANSCRIPT
1962: Nobel Prize in Physiology and Medicine
James D.Watson
Francis H.Crick
Maurice H. F.Wilkins
What about?Rosalind Franklin
DNA (deoxyribonucleic acid) is a chain of nucleotides
Sugar - deoxyribose
Phosphate
Base - one of four types: adenine (A), thymine (T)
guanine (G), cytosine (C)
Nucleotides are composed of:
Chemical Structure of DNA
Carbon 1 (C1) is where the base is attached.
Carbon 2 (C2) tells you if it is a ribose or deoxyribose. In deoxyribose "de oxy" is missing.
Carbon 3 (C3) is the point of attachment for more nucleotides.
Carbon 4 (C4) completes the ring via an oxygen which bridges to the carbon 1 (C1).
Carbon 5 (C5) hangs away from the ring and is the point of attachment for its phosphate(s).
The stands are "antiparallel," meaning they run in opposite directions.
Adenine (A) and thymine (T) form two hydrogen bonds between them.
Guanine (G) and cytosine (C) form three hydrogen bonds between them.
hydrogenbonds
3’
5’ 3’
5’
phosphodiesterbonds
A Typical Electrophoresis Gel Setup
Positive end + + + + + + + + + +
Negative end - - - - - - - - - - - - - Direction
of DNA
movement
Direction
of DNA
movement
Gel Electrophoresis
The gel acts as a sieve to filter the DNA fragments
Smaller fragments move faster through the gel than larger fragments
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
+ + + + + + + + + + + + + + + + + + + + + + + + ++ + + + + + + + + +
DNA is negatively charged and therefore repelled from the negative pole and attracted towards the positive pole
_ _ _ _ _ _ _ _ _ _ _ _
+ + + + + + + + + + + + +
A Typical Image of an Agarose Gel Under UV Light
The DNA fragments can be visualized using a special dye that specifically binds DNA and fluoresces under illumination with UV light
Decreasing DNASize
Largest DNA fragments
Smallest DNA fragments
Sizing The Fragments of DNA
The sizes of the various fragments can be identified by including a “ladder” in the gel A ladder is a mixture of DNA fragments
of known size When run in a gel electrophoresis,
these fragments will separate into distinct bands that can be used as references
Typical Ladders-100 bp & 1 kbp (1000 bp)
The 100 bp ladder is composed of a mixture of small fragments (100 to 2000 bp)
The 1000 bp ladder is composed of a mixture of larger fragments (500 to 12000 bp)
Sizing a Gel Product
BasePairs(bp)4000
3000
2000
1600
1000
500
1Kbp Sample
ladder
2000 bp
1000 bp
What is the Size of this Fragment?
4000
3000
2000
1600
1000
500
Sample 1Kbp
ladder
Background About Agarose
Agarose is a mixture of long chains of saccharides (sugar)
It is extracted from a seaweed and is used in oriental cuisine as a gelling agent for desserts
The greater the agarose concentration, the smaller the pores within the gel
This changes the ease with which the DNA can travel through the gel
By increasing the agarose concentration the smaller DNA fragments will give a clearer separation
By lowering the agarose concentration the larger fragments of DNA will give a clearer separation
By optimizing the % agarose one can clearly separate a mixture of similar DNA fragments
Effects of Changing Gel Concentration
Effect of Percent Agarose on Fragment SeparationAn example
Note how the bands have moved further in the low % agarose gel and the higher bp fragment are better defined. The low bp fragments are better defined in the high % agarose gel and are unresolved in the low % agarose gel
1.6% Agarose
80V – 2 hours
0.8% Agarose
80V – 2 hours
1600 bp
1000 bp 500 bp 200 bp
1600
1000
500300 bp400 bp
The 1kbp The 1kbp ladder and ladder and the 100bp the 100bp ladder were ladder were run with 0.8 run with 0.8 and 1.6 % and 1.6 % agarose gels agarose gels under the under the same same conditions conditions
Electrophoresis of Food Coloring
Purpose
Dye mixtures will be used to simulate DNA fingerprints.
Analyze the fragments produced from the different dyes.
Procedure for Day 1
1. Determine amount of agar and buffer needed to make 50 ml of 1% agar.
2. Microwave the mixture for about 30 seconds.3. Using a hot pad, take the flask out of the microwave
and swirl gently. Make sure all the powder has dissolved.
4. Set on your bench to cool for 5 minutes.5. Insert the comb into the first slot on the gel tray.6. Pour the cool to the touch liquid gel into the tray. 7. Let the gel harden for at least 30 minutes. 8. Get a ziplock bag and write your group number on it.
Leave the bag on the counter next to the gel.
Procedure for Day 2
1. Pull out the comb from the wells by pulling gently upwards.
2. Place the gel into the gel box. Make sure the wells are at the black end.
3. Add 350 ml of TAE buffer to flood the gel and fill the wells.
4. Load 7 µl of each sample into a well on the gel.
5. During the lab, note where each sample was loaded on a diagram of your gel.
6. Put the cover on the electrophoresis box so that the electrodes are connected. Double check that the samples are closest to the negative (BLACK) electrode.
7. Plug the other end of the electrodes into the power supply and run at 100 volts for 30 minutes.
8. After the samples have run out, make a drawing of how the gel looked in your lab notebook.
Conclusion
1. What is the charge of these colored dyes?
2. What would happen to the samples if the gel were flipped around so that the sample wells were put closest to the positive (red) electrode, instead of the negative (black) electrode?
3. What would happen to the samples if you ran the gel at 200 volts for 15 minutes?
4. What is the charge on DNA?
5. Which colored dye moved the farthest distance through the gel?
6. Which colored dye moved the shortest distance through the gel?
7. Which colored dye is the smallest in size?
8. Which colored dye is the largest in size?9. What is the relationship between
distance traveled and size of the molecule in an agarose gel?