Mission (Im)Possible: Determine the Identity of Unknown Plasmids

Teacher Materials

Leaning Goals, Objectives, and Skills...... 2

Standards Alignments...... 3

Laboratory Set-Up Manual...... 5

Instructor Laboratory Guide...... 7

Answers to Student Questions...... 8

Mission (Im)Possible: Determine the Identity of Unknown Plasmids

Learning Goals

Students Learning Goals:

  • Students will understand what a restriction enzyme is and what it does.
  • Students will understand what a plasmid is and what it is used for.
  • Students will understand the process of agarose gel electrophoresis.
  • Students will identify a need for DNA restriction analysis.
  • Students will understand how to use restriction enzyme analysis to determine a general map of a plasmid.

Student Learning Objectives:

  • Students will plan a restriction enzymes analysis that will provide meaningful data.
  • Students will use of restriction enzymes as biotechnology tools.
  • Students will perform the technique of agarose gel electrophoresis.
  • Students will estimate DNA fragments sizes from agarose gel data.
  • Students will analyze the results of the molecule separation by gel electrophoresis.
  • Students will identify two unknown plasmids based upon their data.

Scientific Inquiry Skills:

  • Students will pose questions and form hypotheses.
  • Students will design and conduct scientific investigations.
  • Students will useexperimental data to make conclusions about the initial questionand to support or refute the stated hypothesis.
  • Students will follow laboratory safety rules and regulations.

Laboratory Technical Skills:

  • Students will demonstrate proper use of micropipettes.
  • Students will consider safety considerations when working with an electric current.
  • Students will demonstrate proper use of gel electrophoretic equipment.
  • Students will prepare and pour agarose gels.
  • Students will perform restriction enzyme digests.

1

Mission (Im)Possible: Determine the Identity of Unknown Plasmids

Standards Alignments

Alignment with MA Science and Technology/Engineering Curriculum Framework (2006)

Biology

  • 1.2 Describe the basic molecular structures and primary functions of the four major categories of organic molecules (carbohydrates, lipids, proteins, nucleic acids).
  • 3.1 Describe the basic structure (double helix, sugar/phosphate backbone, linked by complementary nucleotide pairs) of DNA, and describe its function in genetic inheritance.

Scientific Inquiry Skills

  • SIS1. Make observations, raise questions, and formulate hypotheses.
  • SIS2. Design and conduct scientific investigations.
  • SIS3. Analyze and interpret results of scientific investigations.
  • SIS4. Communicate and apply the results of scientific investigations.

Mathematical Skills

  • Solve simple algebraic expressions.
  • Measure with accuracy and precision (e.g., length, volume, mass, temperature, time)
  • Use common prefixes such as milli-, centi-, and kilo-.
  • Use ratio and proportion to solve problems.

DRAFT REVISED MA Science and Technology/Engineering Standards (2013, September 2015 update)

*Please note that these are DRAFT standards that have not yet been submitted for formal review or adoption.

Biology

HS-LS1-1. Use informational text to explain that genes are regions in the DNA that code for proteins that regulate and carry out essential functions of life. Construct a model of transcription and translation to explain the roles of DNA and RNA in coding for amino acids, which make up proteins.

Clarification Statements:

• Proteins that regulate and carry out the essential functions of life include enzymes (speed up chemical reactions), structural proteins (provide structure and enable movement), hormones and receptors (send and receive signals), and antibodies (help fight disease).

• The model should demonstrate that an individual’s characteristics (phenotype) result, in part, from complex relationships among the various proteins (and RNAs) expressed by one or more genes (genotype).

State Assessment Boundary:

• Specific names of proteins or specific steps of transcription and translation are not expected in state assessment.

NRC Practices

  • Asking questions and defining problems
  • Planning and carrying out investigations
  • Analyzing data
  • Mathematical and computational thinking
  • Constructing explanations and designing solutions
  • Engaging in argument from evidence
  • Obtaining, evaluating, and communicating information

1

Mission (Im)Possible: Determine the Identity of Unknown Plasmids

Laboratory Set-Up Manual

Supply List*:

For lab preparation:

  • 1 tube pTK-GLuc plasmid (NEB # N8084S). 1 tube will have 20gDNA in 40 L solution.
  • 1 tube pSNAPf plasmid (NEB # N9183S). 1 tube will have 20gDNA in 40 L solution.
  • 1 tube DNA Ladder: pBR322 DNA-BstNI digest (NEB # N3031S).1 tube will have 50L of DNA at 1000 g/mL
  • The following restriction enzymes 1 tube each of:BamHI-HF (NEB # R3136S), EcoRI-HF (NEB # R3101S), XbaI (NEB # R0145S), XmaI (NEB #R0180L).
  • 1tube 10X concentrated CutSmart® buffer
  • dH2O
  • 200 microcentrifuge tubes
  • distilled water
  • agarose multi-purpose, molecular biology grade. (Example: Fisher catalog # BP169-100)
  • DNA stain such as SYBR Safe or GelGreen for agarose gels
  • 500 ml of 10X TAE buffer
  • 10,000X SYBR safe for15 gels (1 l in 10 ml gel mix)
  • 15 × p200 micropipette and tips
  • 15 × p20 micropipette and tips
  • Permanent marker
  • 15 × 500 mL Graduated cylinder
  • 15 × 250 mL Erlenmeyer flask
  • 15 × 500 mL Erlenmeyer flask
  • 15 × ice buckets (or Styrofoam cups) and ice
  • 15 × microcentrifuge tube racks
  • 15 × gel electrophoresis units with power supplies
  • 1 mL loading dye
  • 37°C water bath or incubator

For each group:

  • 1 p200micropipetteand pipette tips
  • 1  p20 micropipetteand pipette tips
  • 1 microcentrifugetube rack
  • 1microcentrifuge tube with 500l distilled water
  • 1 tube with 1LpTK-GLuc plasmid, labeled S-enz
  • 1 tube with 1 L pTK-GLuc plasmid, labeled S-control
  • 1 tube with 1 L pSNAPf plasmid, labeled A-enz
  • 1 tube with 1LpSNAPf plasmid, labeled A-control
  • 1 tube with 2L DNA ladder, labeled ladder
  • 1 tube with 15LCutSmart®buffer, labeled CutSmart
  • 1 tube with 30 L loading dye. Labeled loading dye
  • 1 agarose gel
  • 1 gel electrophoresis unit with power supply
  • transilluminator or other UV source
  • permanent marker (such as Sharpie)

*Set-up assumes 30 students, working at 15 stations in groups of 2.

Set-up Calendar:

2 weeks before lab:

Check supplies and order any needed materials.

 If making any substitutions to the supply list, edit the student protocol accordingly.

1 day before lab

Set up student lab stations with all durable materials.

 Prepare TAE buffer

Morning of lab:

Prepare 1.8% agarose gel mix with DNA Stain.

Aliquot out the plasmid DNA, ladder DNA, loading dye, dH2O, buffer. Keep all tubes on ice or in freezer. We use pSNAPf as unknown plasmid A, and pTKGluc as plasmid S.

Prepare 3 ice buckets (1 for every 5 groups)

  1. Aliquot 10 L of each enzyme into its own microcentrifuge tube. Keep all tubes on ice
  2. Pour agarose gels. 1 gel/group

Mission (Im)Possible: Determine the Identity of Unknown Plasmids

Instructor Laboratory Guide

Laboratory Procedure Tips:

  1. Before starting the experiment, ask students to check their materials list to make sure they have everything.
  2. Demonstrate how to pipet very small volumes of liquid.
  3. Remind students to use a fresh pipet tip between each addition.

Teaching Tips:

Do not give too much guidance!Let the students choose their own enzymes, even if their choice will not allow them to distinguish between the two plasmids.Allowing your students to design an experiment that fails to give meaningful results can bemore impactful than guiding them through the lab.

Complete maps of the two plasmids used here can be found on the final pages of these documents.New England Biolabs has many useful Interactive tools on the NEB website:

Mission (Im)Possible: Determine the Identity of Unknown Plasmids

Answers to Student Questions

Protocol-Embedded:

p. 2:

  • The surface charge of a DNA molecule is negative.
  • The phosphate groups (PO43−)of DNA determinethe negative charge.
  • During gel electrophoresis, DNA molecules will migrate towards the positive pole.

p. 4:

  • Yes BamHI will cut the 50 bp DNA sequence shown. The resulting DNA fragments are:

5’ ATCGTAGGATCCTCGGAATATCCCGCGTATATCGGAATTCGGAACTCTCTC 3’

3’ TAGCATCCTAG GAGCCTTATAGGGCGCATATAGCCTTAAGCCTTGAGAGAG 5’

  • How many different linear fragments would you have if you…

…cut Molecule 1 with EcoRI?Three.The smallest fragment will move the furthest

…cut Molecule 1 with BamHI? Two.

…cut Molecule 2 with EcoRI? Two.

…cut Molecule 2 with BamHI? None

p. 5:

Answers will vary depending upon students’ design.

p. 7

  • To make 20 ml of 1X TAE buffer, you would mix 2mL of 10X TAE with18mL water.

20ml (1x) = ____ mL (10x); 20mL (1x)/(10x) = 2 mL

20mL (final volume) – 2 mL TAE = 18 mL water

  • To make 120 mL of 1X TAE buffer, you would mix2.4mL of 50X TAE with117.6mL water.

120 mL (1x) = ____ mL (50x); 120mL (1x)/(50x) = 2.4 mL

120mL (final volume) – 2.4 mL TAE = 117.6 mL water

p. 8:

  • The ladder DNA is like a molecular ruler. It will allow you to estimate the size of the bands generated by restriction digests.
  • These controls serve as a comparison between uncut DNA and cut DNA. They will also allow you to determine if the restrictions enzymes effectively cut the DNA.
  • The A-control and the S-control tubes would have circular DNA
  • The smallest of these three forms will move the fastest through the agarose gel. The supercoiled plasmid form is the smallest and will migrate the fastest.
  • The linear DNA molecules found in the A-control tube are linear because they have suffered a random double-stranded break. The linear DNA molecules found in the A-enz tube are all the same because they have all been cleaved at a specific restriction site.

p. 9:

  • On the image below draw what you see after gel electrophoresis.Student drawings will vary depending upon the chosen digests.
  • The multiple bands in the uncut plasmid lanes represent the different forms of the plasmids. See below.

The identity of unknown plasmid A ispSNAPf,identity of unknown plasmid S is pTK-GLuc.

Pre-Lab:

1. A plasmid is a double-stranded circular DNA molecule. It is naturally occurring in many bacterial cells.

2. This specific plasmid must carry a gene for ampicillin resistance.This gene encodes a protein that can break down ampicillin before it can kill the cell.

3. DNA is negatively charged.

4. If you were to compare the migration of DNA molecules in a 1% gel to the migration of the same molecules at the same voltage in a 2% gel you would find that the molecules move more slowly in the higher percentage gel. This is because high percentage gel has a more extensive crosslinking and thus has greater impact on the molecules trying to move through the matrix.

5. If enzyme X cuts every molecule of pSNAPf at every possible restriction site and generates 4 bands,

…then there must be 4 different sites for enzyme X.

… the fourth band would be 3949 base pairs.

Post-Lab:

1. A single digest with enzymesEcoRI, BamHI, and XbaIare poor choices for distinguishing the two plasmids because all three of these enzymes cuts each plasmid once and only once. The two linear bands produced will be difficult to distinguish from each other in a 1% gel.

2. Student answers will vary

3.If prior to restriction digest you had a million molecules of the plasmid, you would have a million molecules in each band. The total size (in base pairs) of pBR322 is 1857+1058+929+383+121 = 4348 base pairs

4. Intercalating dyesbind to DNA by inserting between the nitrogenous bases of DNA. The longer the DNA fragment, the greater the number of base pairs, and thus more dye is bound producing a brighter signal.

1