Difference between revisions of "DNA Extraction and Gel Analysis"

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<h2>1 OBJECTIVES</h2>
<h2>1 OBJECTIVES</h2>


<p>The objective of this experiment is to extract DNA from a fruit and visualize the banding pattern formed when the samples are run through a gel matrix. In doing so, you will also learn where DNA is located, how to get to it and extract it. Basic biochemical techniques will be introduced to allow you to reach, isolate, purify, and digest DNA molecules. </p>
<p>The objective of this experiment is to extract DNA from a fruit and view the banding pattern formed when the samples are run through a gel matrix. In doing so, you will also learn where DNA is located, how to get to it and extract it. Basic biochemical techniques will be introduced to allow you to isolate, purify, and digest DNA molecules. </p>


<p>You will also learn how to perform agarose gel electrophoresis in order to separate DNA fragments obtained from the digested samples. After the experiment, you should be able to distinguish between two different fruits by looking at their respective banding patterns.</p>
<p>You will also learn how to perform a restriction digest of Lambda DNA and visualize the difference in the banding pattern between unrestricted and partially restricted Lambda DNA. This will be achieved by running gel electrophoresis, which separates DNA fragments by their respective molecular weights.</p>


<h2>2 OVERVIEW</h2>
<h2>2 OVERVIEW</h2>
Line 11: Line 11:
<h3>Cellular Biology and Location of DNA</h3>
<h3>Cellular Biology and Location of DNA</h3>


<p>DNA is the blueprint of life. It is present in all living organisms. These organisms can be made of a single cell (bacteria) or trillions (approximately 50 trillion in the human body). There are two different types of cells: prokaryotes and eukaryotes. Prokaryotic cells do not have a nuclear membrane and thus, do not have a distinct nucleus. In this experiment, we are only interested in eukaryotic cells, which make up plant and animal bodies. Eukaryotic cells contain a distinct, membrane-bound nucleus, that isolates the DNA from the rest of the cell. The structure of plant cells is different from
<p>DNA is the blueprint of life and is found in all living organisms. These organisms can be as simple as a single-celled bacteria or as complex as a multi-celled human: the human body contains approximately 50 trillion cells. There are two different types of cells: prokaryotes and eukaryotes. An example of prokaryotic organism is bacteria. Prokaryotic cells do not contain a nuclear membrane and thus do not have a distinct nucleus. In this experiment, we are only interested in eukaryotic cells, which make up plants and animals. Eukaryotic cells have a distinct, membrane-bound nucleus that isolates the DNA from the rest of the cell. The structure of plant cells is different from those of animal cells in structure and cellular contents. We will only be dealing with plant cells in this experiment.</p>
those of animal cells. We will only be dealing with plant cells in this
experiment.</p>


<p>Plant cells are surrounded by a <i>cell wall</i>: it has high mechanical strength which serves to protect the cell. Directly beneath the cell wall lies the <i>plasma membrane</i> which contains the cytosol. Within the cytosol, along with the rest of the cellular organelles, is the <i>nucleus</i> enclosed in the <i>nuclear membrane</i>. <b>The nucleus is of particular interest for us since it houses the DNA in the form of chromatin</b>. Chromatin is the active form of DNA in the cell when it is not preparing for cell division. It is comprised of DNA wrapped around protein particles called histones.</p>
<p align="center">[[Image:DNA2.gif]]</p>
 
<p>Plant cells are surrounded by a <i>cell wall</i>.  It has high mechanical strength and protects the cell. Directly beneath the cell wall lies the <i>plasma membrane</i>, which contains the cytosol. The various cell organelles, including the nucleus, is found within the cytosol. <b>The nucleus is of particular interest to us since it houses the DNA in the form of chromatin.</b></p>
 
<p align="center">[[Image:DNA3.gif]]</p>
 
<p>Chromatin is the active form of DNA in the cell when it is not preparing for cell division. It is comprised of DNA wrapped around protein particles called histones.</p>


<p align="center">[[Image:DNA1.gif]]</p>
<p align="center">[[Image:DNA1.gif]]</p>
<p align="center">[[Image:DNA2.gif]] [[Image:DNA3.gif]]</p>


<h3>DNA Extraction Technique</h3>
<h3>DNA Extraction Technique</h3>
Line 33: Line 35:
<p>We have mentioned earlier that plant cells have a very rigid external structure &mdash; the cell wall &mdash; which protects it. To get to the DNA, the very first step would be to break open that wall.</p>
<p>We have mentioned earlier that plant cells have a very rigid external structure &mdash; the cell wall &mdash; which protects it. To get to the DNA, the very first step would be to break open that wall.</p>


<p>The cell wall is the first barrier in our journey towards the DNA molecule inside the cell. It is very rigid and acts as a protector and filter. It is made of cellulose, and is the reason why wood is so hard and durable. To destroy the cell wall, we need some mechanical means in order to break apart the cellulose molecules. In our experiment, we will smash the fruit <b>manually</b>.</p>
<p>The cell wall is the first barrier in our journey towards the DNA molecule inside the cell. It is very rigid and acts as a protector and filter. It is made of cellulose, and is responsible for making wood hard and durable. To destroy the cell wall, we need some mechanical means in order to break apart the cellulose molecules. In our experiment, we will mash the fruit <b>manually</b>.</p>


<h3>Destroying Membranes Within the Cell</h3>
<h3>Destroying Membranes Within the Cell</h3>


<p>In order to know how to break something, you will most likely wonder what it is made of. For example, if you want to break through a wooden or steel gate, you might consider different techniques. The same kind of critical thinking is needed here. The various membranes inside the cell are made of phospholipid bilayers. Don't mind the scary biochemistry term. Suffice it to say, they're made of fat. To destroy them, we need to break apart that mesh of fat molecules. For this purpose we use the archenemy of fat and grease: <b>soap</b>!</p>
<p>To effectively break into an organized structure, a basic understanding of its composition and structure is required. For example, different techniques are considered to break through a steel gate versus a wooden gate. We can apply a similar approach to this problem. The cell's plasma membrane is made of phospholipid bilayers. Don't mind the scary biochemistry term. Suffice it to say, they’re made of fat. To disrupt them, we need to break apart that mesh of fat molecules. For this purpose we use the archenemy of fat and grease: <b>soap</b>! Interestingly enough, the structure of soap is very similar to that of fat and grease, which allows us to exploit the structure of soap to break down grease on our plates. An easy way to remember this is "like dissolves like."</p>


<p>A soap molecule has two parts: a head and a tail. The head is polar and is therefore attracted to water while the tail is non-polar and is attracted to oil and fat. When soap molecules are in water, they group themselves into micelles &mdash; a roughly spherical structure in which all the water-loving heads point outwards (in contact with water) and all the fat-loving tails point inwards at the center of the sphere (away from the water). Therefore they can effectively trap the fat molecule inside the micelle and dissolve the cell membranes. </p>
<p>A soap molecule has two parts: a head and a tail. The head is polar and is therefore attracted to water while the tail is non-polar and is attracted to oil and fat. When soap molecules are in water, they group themselves into micelles &mdash; a roughly spherical structure in which all the water-loving heads point outwards (in contact with water) and all the fat-loving tails point inwards at the center of the sphere (away from the water). Therefore they can effectively trap the fat molecule inside the micelle and dissolve the cell membranes. How does this micelle break down the phospholipid bilayer? The molecules in the phospholipid bilayer also contain molecules that are made up of a hydrophobic (fat loving) head and a hydrophilic (water loving) tail. The soap molecules orient themselves so that their head associates with the tail of the phospholipid bilayer. In this way, the soap is able to break up the bilayer molecule by molecule.</p>


<p align="center">[[Image:DNA4.gif]]</p>
<p align="center">[[Image:DNA4.gif]][[Image:DNA_NEW.gif]]</p>


<h3>Precipitating the DNA</h3>
<h3>Precipitating the DNA</h3>


<p>When all the membranes are broken, the DNA is released into the solution along with all sorts of protein molecules and other cellular inclusions. We cannot separate the DNA from the rest of the solution yet. Why? It has to do with the physical and chemical characteristics of the DNA molecule.</p>
<p>When the membrane is successfully disrupted, the DNA is released from the cells into the solution along with protein molecules and other cellular miscellanea.</p>


<p>The DNA molecule is a double-helical polymer consisting of a sugar-phosphate backbone with nitrogenous bases running perpendicular to the backbone. These bases are often represented by letters &mdash; <b>A (adenine), G (guanine), C (cytosine) and T (thymine)</b> &mdash; are the elementary components making up the coded genetic information. The base sequence acts as the instruction manual of the cell, instructing it on how to <b>make enzymes, proteins, and ultimately everything an organism needs to survive and function</b>.</p>
<p>The DNA molecule is a double-helical polymer consisting of a sugar-phosphate backbone with nitrogenous bases running perpendicular to the backbone. These bases, often represented by letters &mdash; <b>A (adenine), G (guanine), C (cytosine) and T (thymine)</b> &mdash; are the elementary components making up the coded genetic information. The base sequence acts as the instruction manual of the cell, directing it on how to <b>make proteins, and other important molecules that an organism needs to survive and function</b>.</p>


<p>DNA molecules are soluble in water because of the sugar-phosphate backbone which is highly negatively charged and therefore, polar. Since "like dissolves like," water &mdash; a polar solvent &mdash; will dissolve DNA making it hard for us to take it out of the solution.</p>
<p>With the cell's contents mixed into a solution, the DNA needs to be separated from the rest; this process is called <b>precipitation</b>. We use salt because it disrupts the structure of the proteins and carbohydrates found in the solution. Also, the salt provides a favorable environment to extract the DNA by contributing positively charged sodium ions which neutralize the negative charge of DNA. <span style="color: lime">However, even after the addition of salt and soap, we cannot see how it is physically extracting the DNA out of the solution. It is "invisible."</span> To aide in precipitating the DNA, alcohol is added since it cannot dissolve DNA. A white substance will begin to form at the top; this is our DNA. Once it is thick enough, we will spool it out. This simple procedure is a rough extraction process which needs further purification before it can be successfully run on a gel for analysis.</p>
 
<p>To effectively take a polar compound out of a polar solvent, we need to make the compound less polar and reduce its attraction to the solution. Remember that the reason the DNA is polar is due to the presence of the negatively charged sugar-phosphate backbone. We need to make it non-negative or neutral. To do this, we will add a positively charged ion found in table salt to the solution. Table salt is made of sodium ions (which are positively charged) and chloride ions (which are negatively charged). The sugar-phosphate backbone of the DNA molecule, which has a negative charge, will be counteracted, for the most part, by the positive sodium ions, making the molecule less polar. But it is easier for the negative sugar-phosphate backbone of the DNA to bind with the positive sodium ion when it is in alcohol. That is why we will add alcohol to the solution.</p>


<p align="center">[[Image:DNA5.gif]]</p>
<p align="center">[[Image:DNA5.gif]]</p>


<h3>Gel Electrophoresis</h3>
<h3>Restriction</h3>


<p>After we extract the DNA, we want to run a gel electrophoresis in order to form banding patterns that can help us differentiate two different fruits. Gel electrophoresis is a technique used for separating molecules based on their charge and molecular weight. The sample is loaded in a gel matrix and an
<p>Often times, larger fragments of DNA are cut, or restricted, to extract a particular fragment. This is made possible by the action of restriction enzymes, which are used by bacteria to cut up foreign or enemy DNA. Restriction enzymes are catalytic proteins that recognize specific palindromic DNA sequences and cut the double-stranded DNA at particular sites. The sites that the restriction enzymes recognize are called restriction sites. There are many different types of restriction enzymes. Each type recognizes a different restriction site. In this lab, we will restrict Lambda DNA, which is a commercially available DNA normally found in a virus called Phage Lambda. We will use the restriction enzyme BamH1.</p>
electric field is applied across it. Lighter molecules will migrate to the opposite end of the gel faster than heavier molecules. The situation is
analogous to swimmers in a pool. The lighter swimmer is able to move faster than the heavier ones and is more likely to reach the end first.</p>


<p align="center">[[Image:DNA6.gif]]</p>
<p align="center">[[Image:DNA9.gif]]</p>
 
<p align="center">[[Image:DNA7.gif]]</p>
 
<h3>How Can Molecules Move in the Gel?</h3>
 
<p>We have learned that DNA is negatively charged due to the phosphate groups in the sugar-phosphate backbone. By applying a voltage difference, creating an electric field across the gel, the negatively charged molecules will move toward the positive side of the field. We assume that the applied electric field is uniform and that all molecules feel the same magnitude of electric force. Think of the uniform electric field as a strong wind blowing at the backs of sprinters, pushing each of them evenly.</p>
 
<p>The following is a gel after the samples have been run. Each column is referred to as a <i>lane</i> and represents one sample each. The individual bands contain fragments of DNA that are identical in weight.</p>
 
<p align="center">[[Image:DNA8.gif]]</p>
 
<h3>DNA Digestion</h3>
 
<p>One important issue in our instance is that the DNA we extract is too large to move through the gel. We have to cut them into smaller fragments. In order to cut DNA molecules into smaller pieces, we will digest them using restriction enzymes. These enzymes are highly specific in terms of where in the DNA sequence they cut. There are many different restriction enzymes and each recognizes a different sequence known as a recognition site. For DNA molecules from the same fruit, we will have the same number of fragments of each type.</p>
 
<h3>How Restriction Enzymes Work?</h3>
 
<p>We learned earlier that DNA bases are represented by the following letters: A, G, C, and T. </p>


<center><table border="1">
<center><table border="1">
Line 89: Line 69:
</tr>
</tr>
<tr align="center">
<tr align="center">
<td>[http://en.wikipedia.org/wiki/EcoRI EcoRI]</td>
<td>BamH1</td>
<td>[http://en.wikipedia.org/wiki/Escherichia_coli Escherichia coli]</td>
<td>Bacillus amyloliquefaciens</td>
<td><pre>5'GAATTC
<td><pre>5'GGATCC
3'CTTAAG</pre></td>
3'CCTAGG</pre></td>
<td align="left"><pre>5'---G
<td align="left"><pre>5'-----G
3'---CTTAA</pre></td>
-------CCTAG</pre></td>
<td align="right"><pre>AATTC---3'
<td align="right"><pre>GATCC------
G---5'</pre></td>
G-----5'</pre></td>
</tr>
<tr align="center">
<td>EcoRI</td>
<td>Escherichia coli</td>
<td><pre>5'GGATCC
3'CCTAGG</pre></td>
<td align="left"><pre>5'-----G
-------CCTAG</pre></td>
<td align="right"><pre>GATCC------
G-----5'</pre></td>
</tr>
<tr align="center">
<td>HindIII</td>
<td>Haemophilus influenzae</td>
<td><pre>5'AAGCTT
3'TTCGAA</pre></td>
<td align="left"><pre>5'---A
3'---TTCGA</pre></td>
<td align="right"><pre>AGCTT---3'
A---5'</pre></td>
</tr>
</tr>
</table></center>
</table></center>


<p align="center">[[Image:DNA9.gif]]</p>
<h3>Gel Electrophoresis</h3>
 
<p>To learn the technique of DNA electrophoresis, we will run our uncut and cut Lambda DNA, a commercially available DNA on an agarose gel, to visualize the characteristic banding patterns that can help us differentiate between different DNA fragments. Gel electrophoresis is a technique used for separating molecules based on their charge and molecular weight.  The sample is loaded in a gel matrix and an electric field is applied across it. The electric field enables the DNA, which is negatively charged to migrate to the end, which is positively charged. Remember, opposites attract and so the negatively charged DNA is attracted to the positive end of the gel. What causes different sized DNA to separate into different bands? Lighter molecules will migrate to the opposite end of the gel faster than heavier molecules.  The situation is analogous to swimmers in a swimming pool.  The lighter swimmer is able to move faster than the heavier ones and is more likely to reach the end first. </p>
 
<p align="center">[[Image:DNA6.gif]] [[Image:DNA7.gif]]</p>


<p>Whenever the enzyme named EcoRI sees the sequence of bases: GAATTC or CTTAAG, it will cut it right between the G and the A.</p>
<p>The following is a gel after the samples have been run. Each column is referred to as a <i>lane</i>, representing one sample each. The individual bands contain fragments of DNA that are identical in weight.</p>


<p>When a specific enzyme is used, a DNA molecule from the same plant will produce the same pattern in the gel. If we use the same enzyme on another plant, we will get another pattern, and we can effectively differentiate between the two plants.</p>
<p align="center">[[Image:DNA8.gif]]</p>


<h2>3 Your Assignment</h2>
<h2>3 Your Assignment</h2>
Line 117: Line 121:
<li>Describe the major techniques used in this lab: Gel Electrophoresis, DNA Digestion, etc.</li>
<li>Describe the major techniques used in this lab: Gel Electrophoresis, DNA Digestion, etc.</li>
<li>Explain why the incubator was used.</li>
<li>Explain why the incubator was used.</li>
<li>Discuss the important properties of DNA having a direct impact on the extraction procedure.</li>
<li>Important properties of DNA directly having an impact on the extraction procedure.</li>
<li>Clearly describe the procedural steps the way they were carried out in lab.</li>
<li>Clearly describe the procedural steps the way they were carried out in lab.</li>
<li>Describe the steps carried out by the TA after you rinse the DNA.</li>
<li>Describe the steps carried out with the TA.</li>
<li>Describe how the banding pattern is obtained.</li>
<li>Describe how the banding pattern is obtained.</li>
<li>Explain why the banding pattern aids in identifying a specific fruit sample.</li>
<li>Explain why the banding pattern aids in identifying a specific fruit sample.</li>
</ul>
</ul>


<!--<h3>Team PowerPoint Presentation</h3>
<h3>Team PowerPoint Presentation</h3>


<p>Follow the presentation guidelines laid out in the page called [[EG1004 Lab Presentation Format]] in the Introduction to Technical Presentations section of this manual. When you are preparing your presentation, consider the following points:</p>
<p>Follow the presentation guidelines laid out in the page called [[EG1004 Lab Presentation Format]] in the Introduction to Technical Presentations section of this manual. When you are preparing your presentation, consider the following points:</p>
Line 133: Line 137:
<li>Make sure you talk about real-life application of DNA sequencing.</li>
<li>Make sure you talk about real-life application of DNA sequencing.</li>
<li>Demonstrate clear understanding of each procedural step carried out and why it worked.</li>
<li>Demonstrate clear understanding of each procedural step carried out and why it worked.</li>
</ul>-->
</ul>


<h2>4 Materials and Equipment</h2>
<h2>4 Materials and Equipment</h2>
Line 144: Line 148:
<li>95% isopropyl alcohol (0 &deg;C)</li>
<li>95% isopropyl alcohol (0 &deg;C)</li>
<li>Distilled water</li>
<li>Distilled water</li>
<li>Strainer (1 per group)</li>
<li>Cheesecloth</li>
<li>Plastic cup (3 per group)</li>
<li>Plastic cups</li>
<li>Ziploc bag (1 per group)</li>
<li>Ziploc bag</li>
<li>Spoon (1 per group)</li>
<span style="color: lime"><li>Lambda DNA</li>
<li>Foam plate (1 per group)</li>
<li>Restriction enzymes</li></span>
<li>Restriction enzymes</li>
<li>Variable micropipette and tips</li>
<li>Micropipettes and tips (5 &micro;l and 10 &micro;l)</li>
<li>Incubator</li>
<li>Incubator</li>
<li>Eppendorf tube (1 per group)</li>
<li>Microcentrifuge tube</li>
<li>Precast agarose gel</li>
<li>Precast agarose gel</li>
<li>Electrophoresis system</li>
<li>Electrophoresis system</li>

Revision as of 03:26, 28 March 2009

DNA EXTRACTION AND GEL ANALYSIS

1 OBJECTIVES

The objective of this experiment is to extract DNA from a fruit and view the banding pattern formed when the samples are run through a gel matrix. In doing so, you will also learn where DNA is located, how to get to it and extract it. Basic biochemical techniques will be introduced to allow you to isolate, purify, and digest DNA molecules.

You will also learn how to perform a restriction digest of Lambda DNA and visualize the difference in the banding pattern between unrestricted and partially restricted Lambda DNA. This will be achieved by running gel electrophoresis, which separates DNA fragments by their respective molecular weights.

2 OVERVIEW

Cellular Biology and Location of DNA

DNA is the blueprint of life and is found in all living organisms. These organisms can be as simple as a single-celled bacteria or as complex as a multi-celled human: the human body contains approximately 50 trillion cells. There are two different types of cells: prokaryotes and eukaryotes. An example of prokaryotic organism is bacteria. Prokaryotic cells do not contain a nuclear membrane and thus do not have a distinct nucleus. In this experiment, we are only interested in eukaryotic cells, which make up plants and animals. Eukaryotic cells have a distinct, membrane-bound nucleus that isolates the DNA from the rest of the cell. The structure of plant cells is different from those of animal cells in structure and cellular contents. We will only be dealing with plant cells in this experiment.

DNA2.gif

Plant cells are surrounded by a cell wall. It has high mechanical strength and protects the cell. Directly beneath the cell wall lies the plasma membrane, which contains the cytosol. The various cell organelles, including the nucleus, is found within the cytosol. The nucleus is of particular interest to us since it houses the DNA in the form of chromatin.

DNA3.gif

Chromatin is the active form of DNA in the cell when it is not preparing for cell division. It is comprised of DNA wrapped around protein particles called histones.

DNA1.gif

DNA Extraction Technique

In this experiment, one of our goals is to extract the DNA from the fruit sample. Below, we will describe the scientific background behind DNA extraction.

The DNA extraction process is a fairly simple biochemical procedure that can be divided into three major steps: breaking open the cell (lysis), destroying membranes within the cell, and precipitating the DNA out of the solution.

We will describe in the section below how each step relates to the physical and biochemical properties of DNA.

Cell Lysis (Breaking Open the Cell Wall and Membranes)

We have mentioned earlier that plant cells have a very rigid external structure — the cell wall — which protects it. To get to the DNA, the very first step would be to break open that wall.

The cell wall is the first barrier in our journey towards the DNA molecule inside the cell. It is very rigid and acts as a protector and filter. It is made of cellulose, and is responsible for making wood hard and durable. To destroy the cell wall, we need some mechanical means in order to break apart the cellulose molecules. In our experiment, we will mash the fruit manually.

Destroying Membranes Within the Cell

To effectively break into an organized structure, a basic understanding of its composition and structure is required. For example, different techniques are considered to break through a steel gate versus a wooden gate. We can apply a similar approach to this problem. The cell's plasma membrane is made of phospholipid bilayers. Don't mind the scary biochemistry term. Suffice it to say, they’re made of fat. To disrupt them, we need to break apart that mesh of fat molecules. For this purpose we use the archenemy of fat and grease: soap! Interestingly enough, the structure of soap is very similar to that of fat and grease, which allows us to exploit the structure of soap to break down grease on our plates. An easy way to remember this is "like dissolves like."

A soap molecule has two parts: a head and a tail. The head is polar and is therefore attracted to water while the tail is non-polar and is attracted to oil and fat. When soap molecules are in water, they group themselves into micelles — a roughly spherical structure in which all the water-loving heads point outwards (in contact with water) and all the fat-loving tails point inwards at the center of the sphere (away from the water). Therefore they can effectively trap the fat molecule inside the micelle and dissolve the cell membranes. How does this micelle break down the phospholipid bilayer? The molecules in the phospholipid bilayer also contain molecules that are made up of a hydrophobic (fat loving) head and a hydrophilic (water loving) tail. The soap molecules orient themselves so that their head associates with the tail of the phospholipid bilayer. In this way, the soap is able to break up the bilayer molecule by molecule.

DNA4.gifFile:DNA NEW.gif

Precipitating the DNA

When the membrane is successfully disrupted, the DNA is released from the cells into the solution along with protein molecules and other cellular miscellanea.

The DNA molecule is a double-helical polymer consisting of a sugar-phosphate backbone with nitrogenous bases running perpendicular to the backbone. These bases, often represented by letters — A (adenine), G (guanine), C (cytosine) and T (thymine) — are the elementary components making up the coded genetic information. The base sequence acts as the instruction manual of the cell, directing it on how to make proteins, and other important molecules that an organism needs to survive and function.

With the cell's contents mixed into a solution, the DNA needs to be separated from the rest; this process is called precipitation. We use salt because it disrupts the structure of the proteins and carbohydrates found in the solution. Also, the salt provides a favorable environment to extract the DNA by contributing positively charged sodium ions which neutralize the negative charge of DNA. However, even after the addition of salt and soap, we cannot see how it is physically extracting the DNA out of the solution. It is "invisible." To aide in precipitating the DNA, alcohol is added since it cannot dissolve DNA. A white substance will begin to form at the top; this is our DNA. Once it is thick enough, we will spool it out. This simple procedure is a rough extraction process which needs further purification before it can be successfully run on a gel for analysis.

DNA5.gif

Restriction

Often times, larger fragments of DNA are cut, or restricted, to extract a particular fragment. This is made possible by the action of restriction enzymes, which are used by bacteria to cut up foreign or enemy DNA. Restriction enzymes are catalytic proteins that recognize specific palindromic DNA sequences and cut the double-stranded DNA at particular sites. The sites that the restriction enzymes recognize are called restriction sites. There are many different types of restriction enzymes. Each type recognizes a different restriction site. In this lab, we will restrict Lambda DNA, which is a commercially available DNA normally found in a virus called Phage Lambda. We will use the restriction enzyme BamH1.

DNA9.gif

therefore
EnzymeSource Recognition Sequence Cut
BamH1 Bacillus amyloliquefaciens
5'GGATCC
3'CCTAGG
5'-----G
-------CCTAG
GATCC------
G-----5'
EcoRI Escherichia coli
5'GGATCC
3'CCTAGG
5'-----G
-------CCTAG
GATCC------
G-----5'
HindIII Haemophilus influenzae
5'AAGCTT
3'TTCGAA
5'---A
3'---TTCGA
AGCTT---3'
A---5'

Gel Electrophoresis

To learn the technique of DNA electrophoresis, we will run our uncut and cut Lambda DNA, a commercially available DNA on an agarose gel, to visualize the characteristic banding patterns that can help us differentiate between different DNA fragments. Gel electrophoresis is a technique used for separating molecules based on their charge and molecular weight. The sample is loaded in a gel matrix and an electric field is applied across it. The electric field enables the DNA, which is negatively charged to migrate to the end, which is positively charged. Remember, opposites attract and so the negatively charged DNA is attracted to the positive end of the gel. What causes different sized DNA to separate into different bands? Lighter molecules will migrate to the opposite end of the gel faster than heavier molecules. The situation is analogous to swimmers in a swimming pool. The lighter swimmer is able to move faster than the heavier ones and is more likely to reach the end first.

DNA6.gif DNA7.gif

The following is a gel after the samples have been run. Each column is referred to as a lane, representing one sample each. The individual bands contain fragments of DNA that are identical in weight.

DNA8.gif

3 Your Assignment

Individual Lab Report

Follow the lab report guidelines laid out in the page called Specifications for Writing Your Lab Reports in the Technical Communication section of this manual. As you write, the following discussion points should be addressed in the appropriate section of your lab report:

  • Justify the use of salt, soap, and alcohol in the extraction procedure.
  • Explain how to reach the DNA and the barriers that were overcome to get to it.
  • Describe the major techniques used in this lab: Gel Electrophoresis, DNA Digestion, etc.
  • Explain why the incubator was used.
  • Important properties of DNA directly having an impact on the extraction procedure.
  • Clearly describe the procedural steps the way they were carried out in lab.
  • Describe the steps carried out with the TA.
  • Describe how the banding pattern is obtained.
  • Explain why the banding pattern aids in identifying a specific fruit sample.

Team PowerPoint Presentation

Follow the presentation guidelines laid out in the page called EG1004 Lab Presentation Format in the Introduction to Technical Presentations section of this manual. When you are preparing your presentation, consider the following points:

  • Rely heavily on graphics and pictures.
  • Make sure your Experimental Work is described simply and thoroughly.
  • Make sure you talk about real-life application of DNA sequencing.
  • Demonstrate clear understanding of each procedural step carried out and why it worked.

4 Materials and Equipment

  • Fruit sample
  • Non-iodized table salt (NaCl)
  • Hand soap (clear, unscented)
  • 95% isopropyl alcohol (0 °C)
  • Distilled water
  • Cheesecloth
  • Plastic cups
  • Ziploc bag
  • Lambda DNA
  • Restriction enzymes
  • Variable micropipette and tips
  • Incubator
  • Microcentrifuge tube
  • Precast agarose gel
  • Electrophoresis system
  • Bioimaging system
      DNA10.gif
DNA11.gif
    DNA12.gif
DNA13.gif

5 Procedure

  1. Obtain a fruit sample about the size of a strawberry. That would be about 1/4 of a medium-sized banana.
  2. Put the fruit sample in the Ziploc bag provided. Close the bag carefully so there is as little air as possible inside.
  3. Smash the sample gently with your hands. Be careful not to burst the bag to avoid a big mess! After about 5 minutes, the fruit sample will be transformed into a creamy paste. This process is known as homogenization.
  4. Prepare the buffer solution while one team member is working on the homogenization of the fruit sample. Fill a cup half-way with distilled water, and add one teaspoon of table salt. Mix the solution until the salt dissolves in the water.
  5. Add 3 squirts of soap. Stir gently with the spoon so that it doesn't foam. Keep stirring until the texture if the solution is even.
  6. Pour the prepared buffer solution into the Ziploc bag and close it. Make sure you haven't trapped air in the bag.
  7. Mix the smashed fruit and the buffer solution gently in the bag. Do it slowly. It is important that it does not foam a lot.
  8. Let the mixture sit for about 4 minutes. If it has foamed, allow the foam to go away during this time. By letting the mixture stay still, the foam will disappear.
  9. Filter the solution by using another clear plastic cup. One team member should hold the strainer on top of an empty cup while another carefully pours out the contents of the Ziploc bag. Make sure it does not foam. Pour slowly! Occasionally shake the strainer to make the liquid filter through. There will be a lot of debris.
  10. Add ice-cold alcohol to the filtered solution by pouring the alcohol against the wall of the cup. We do not want the alcohol to mix with the solution; we want it to float on top. Alcohol is very miscible with water, but IT CAN FLOAT IF IT IS POURED SLOWLY AGAINST THE WALL OF THE CONTAINER because it is less dense than water. Pour the alcohol until the total volume reaches 3/4 of the cup's volume. After about one minute, you will see threads of DNA forming into translucent gel-like globs at the interface of the filtered solution and the alcohol.
  11. Prepare two cups 1/4 filled with alcohol.
  12. Collect the DNA by spooling it, using a paperclip.
  13. Rinse the glob of DNA in the first cup for about 10 seconds. Then rinse it again the other cup. Allow it to air-dry for about 2 minutes.
  14. Call the TA who will guide you with the rest of the procedure: adding the restriction enzymes, putting it in the incubator, and running the gel electrophoresis.
  15. Clean up your station and follow the TA's instructions. It will take about 30 minutes before you can see the banding pattern formed by your digested DNA in the gel.

6 References

http://www.vernier.com

http://www.invitrogen.com

Nasco Website

http://en.wikipedia.org

The Science Creative Quarterly

http://www.hhmi.princeton.edu/documents/labprotocols

http://porpax.bio.miami.edu/~cmallery/255/255chem/255chemistry.htm

http://library.thinkquest.org/20465/DNAstruct.html