20.109(S11):Evaluate DNA and choose clone (Day6): Difference between revisions

Introduction

Last time you transformed your new DNA construct into the edge detector strain (JW3367c) cells. You prepared three candidate plates, each of which should now contain colonies that are genetically identical to each other. We grew one colony from each plate in liquid culture, and today you will pick one of those to assay for reduced P_lux-λ leakiness. You will figure out which clone to use by analyzing your sequencing data.

The invention of automated sequencing machines has made sequence determination a relatively fast and inexpensive endeavor. The method for sequencing DNA is not new but automation of the process is recent, developed in conjunction with the massive genome sequencing efforts of the 1990s. At the heart of sequencing reactions is chemistry worked out by Fred Sanger in the 1970s which uses dideoxynucleotides (see schematic above left). These chain-terminating bases can be added to a growing chain of DNA but cannot be further extended. Performing four reactions, each with a different chain-terminating base, generates fragments of different lengths ending at G, A, T, or C. The fragments, once separated by size, reflect the DNA’s sequence. In the “old days” (all of 10 years ago!) radioactive material was incorporated into the elongating DNA fragments so they could be visualized on X-ray film (image above center). More recently fluorescent dyes, one color linked to each dideoxy-base, have been used instead. The four colored fragments can be passed through capillaries to a computer that can read the output and trace the color intensities detected (image above right). Your sample was sequenced in this way on an ABI 3730 DNA Analyzer.

Analysis of sequence data is no small task. “Sequence gazing” can swallow hours of time with little or no results. There are also many web-based programs to decipher patterns. The nucleotide or its translated protein can be examined in this way. Thanks to the genome sequence information that is now available, a new verb, “to BLAST,” has been coined to describe the comparison of your own sequence to sequences from other organisms. BLAST is an acronym for Basic Local Alignment Search Tool, and can be accessed through the National Center for Biotechnology Information (NCBI) home page.

A complementary alternative to sequencing is the diagnostic digest. Imagine that your insert modification introduced a new restriction site, or deleted one that was there before. If the banding pattern that results from cutting with this enzyme (and perhaps one other to decrease fragment size) is distinguishable for the original and modified plasmid, then seeing the latter pattern strongly suggests that the candidate clone is correct. You will perform some theoretical diagnostic digests for homework, as this is a very useful skill. However, you might be wondering why you would ever go through the trouble of designing and performing diagnostic digests, when sequencing is relatively simple and yields more information. Here, the idea of scale becomes important. Sequencing costs $8 per reaction, which can add up if you need to examine, say, 10 or more candidates. Agarose gel electrophoresis, by comparison, costs perhaps $1 per candidate. Since both methods require DNA isolation, one is not dramatically more labour intensive than the other. (A method called colony PCR avoids this labour. Can you guess what it might entail?) Finally, banding patterns can give a quick readout of many candidate colonies compared to the time it takes for the individual sequencing analyses you will perform today. Of course, there's no reason one couldn't automate the analysis process with a bit of (computer, not DNA) code! Typically, screening many candidates by diagnostic digest (also called restriction mapping) and then choosing a select few for sequencing gives the best of both worlds.

Protocols

Part 1: EHS Talk

In preparation for the tissue culture work you will do in Module 3, today you will hear a talk on Biosafety by Martha Anne Adams from the Environment, Health and Safety Office.

Part 2: Model system solid cultures

1. Begin by following the Day 1 protocol for preparing edge detection plates. Prepare N plates, X with cells carrying the original pED-IPTG-INS plasmid, and X carrying your modified plasmid.
2. After the plates have hardened, carefully mark two spots at the edge of both the plate and the lid, 90 ° apart. Using the slightly protruding lines that mark the lid into quarters may work best.
3. Using a ruler, mark a dot 1.5 cm inward from the edge for each of the two dots you made before.
4. In one spot, put X μL of IPTG, and in the other put Y μL of AHL.

...

Part 3: Analyze sequence data

Your goal today is to analyze the sequencing data for three independent colonies from your pED_IPTG-YFD cloning experiment, and one X clone for practice? - and then decide which colony to proceed with. You will want to have this document (LINK) handy, and to mark the expected location of your mutation with bold text before proceeding. Hmmm, have them use ApE instead of Word? Free, etc.

The data from the MIT Biopolymers Facility is available at this link. Choose the "Login to dnaLIMS" link and then use "astachow" and "be109" to login. At the bottom of the left panel should be a link to download your sequencing results. First, select order #X and sample BLAH, then click "submit." Later you can select the order # for your own design (xxxxx for T/R, xxxxx for W/F). The quickest way to start working with your data is to follow the "view" link. From this link you'll see the sequencing traces and can click on "sequence text" to view it.

Rather than look through the sequence to magically find the relevant portion, you can align the data you just got with the standard inverse pericam sequence and the differences will be quickly identified. There are several web-based programs for aligning sequences and still more programs that can be purchased. The steps for using one web-based tool are sketched below.

Align with "bl2seq" from NCBI

1. The alignment program can be accessed through the NCBI BLAST page or directly from this link
2. To allow for gaps in the sequence alignment, uncheck the "filter" box. All the other default settings should be fine.
3. Paste the sequence text from your sequencing run into the "Sequence 1" box. This will now be the "query." If there were ambiguous areas of your sequencing results, these will be listed as "N" rather than "A" "T" "G" or "C" and it's fine to include Ns in the query.
4. Paste the inverse pericam sequence into the "Sequence 2" box. For samples probed with the forward primer, use the regular IPC sequence; for those using a reverse primer, you should put in the reverse complement. Which alignment will be more useful depends on the location of your mutation.
5. Click on Align. Matches will be shown by vertical lines between the aligned sequences. You should see a long stream of matches, followed by lots of errors in the last ~200bp of the sequence – ignore the error-ridden part of the data, as it may not accurately reflect your mutant plasmid. In this stream of matches, the 1-3 missing lines indicating your mutant codon should stand out. If they don’t, use the numbering or Find tool to locate the appropriate codon.
6. You should print a screenshot of each alignment to pdf (and to paper if you desire). These will be used to prepare a figure showing what you found today. You might want to email yourself the alignment screen shots or post them to your wiki userpage.

If all three colonies for your design have the correct sequence, pick any of them; ditto if all are inconclusive. If one appears right and the others don’t, of course proceed with the former. Finally, if all are clearly wrong, talk to a member of the teaching faculty.

Part 4: Prepare liquid cultures for β-gal assay of modified system

REVISE FOR THIS DAY'S SAMPLES

1. If you are waiting for the spectrophotometer, you can begin by picking up eight X mL round-bottom tubes and preparing sticky labels for your samples (described in step 6).
2. Measure the OD₆₀₀ value of a 1:10 dilution of your cells (use a total volume of 600 μL).
3. In a 50 mL conical tube, add 25 μL of ampicillin to 25 mL of LB medium and invert briefly to mix.
4. Dilute the cell stock to an OD of 0.0025 in the 25 mL volume.
   • Remember to take into account that you measured a diluted sample!
   • You can treat the cell volume as negligible.
5. Distribute 2.5 mL of cells to each round-bottom tube with a 5 or 10 mL serological pipet.
6. Distribute additives to each tube according to the scheme below, making sure that each tube is well-labeled:
   • Two tubes get nothing further.
   • Two tubes get 2.5 μL of AHL (1000X stock).
   • Two tubes get 12.5 μL of IPTG (1 M stock). (What is the final IPTG concentration?)
   • Two tubes get both AHL and IPTG.
7. Make sure each cap is snapped shut. You will hear a "snap" when it's really closed. If you're uncertain whether your tubes are closed, please ask one of the teaching faculty.
8. Ask an instructor to show you how to operate the roller wheel in the incubator.
9. Your cultures will be grown overnight, then moved to 4 °C until next time.

For next time

draft introduction

draft outline/structure of results section

theoretical diagnostic digest

Reagent list

text here so works