Prodigiosin Production in E. Coli

Slides:



Advertisements
Similar presentations
Subcloning Techniques
Advertisements

JY BB JK JK CS LE MG AR NG JS SJ YW MK DS LL DH JB.
CLONING AND EXPRESSION OF NEUTRAL PROTEASE GENE FROM B. STEAROTHERMOPHILUS.
Biotechnology Bacterial Transformation. Biotechnology Can Be Used to Treat Disease.
Molecular cloning overview Steps to prepare vector hour overnight culture 2.Minipreps (day immediately following O/N) (use Qiaprep spin miniprep.
pARA-R Sequence LABS 2a and 4a RFP Expression Sequence
Flashing Bacteria Morgan Haskell Coby Turner. What We Wanted To Do  University of California in San Diego  Biological synchronized clocks  Flash to.
CRISPR System Caroline Vrana Davidson College Synthetic Biology Summer 2012.
Extraction of Nucleic Acids (Genomic DNA, mRNA and Plasmid DNA)
Chapter 4: recombinant DNA
Cloning a DNA segment from bacteriophage Recombinant DNA transformed into bacterial cells Last week we plated cells onto agar plates + ampicillin + X-gal.
Cloning a DNA segment from sheep Recombinant DNA transformed into bacterial cells Last week we plated cells onto agar plates + ampicillin + X-gal Controls:
A Look into the Process of Marker Development Matt Robinson.
PRESENTED BY: LAUREN SHIN MENTOR: DR. LUIZ BERMUDEZ MICROBIOLOGY DEPARTMENT Determining the Role of the luxR homolog in Mycobacterium avium subsp. paratuberculosis.
Cloning DNA into Plasmid Vectors and Sequencing. ABE Workshop 2007 Josh Nelson 26 – Jun – 2007.
Recombinant DNA Techniques Laboratory Bi 431/531
Molecular Cloning Biology 20L Spring Overview of Molecular Cloning Restriction digest of plasmid pUC19 and phage –GOAL: Linear pUC19 DNA and several.
Transformation of Escherichia coli
Analysis of Gene Expression of Arabidopsis using RT-PCR and DNA Cloning Presented by Neha Jain ABE Workshop 2006 June 30, 2006.
Cloning with Plasmids Genetic Engineering Invented.
Engineering the Subtilisin Gene into E. coli
Plasmid DNA Isolation Exercise 8.
Tina Khoury Jeremy Gerbig Derek Blanchard Kerwin Dunham.
Construction, Transformation, and Prokaryote Expression of a Fused GFP and Mutant Human IL-13 Gene Sequence Lindsay Venditti, Department of Biological.
20.1 – 1 Look at the illustration of “Cloning a Human Gene in a Bacterial Plasmid” (Figure 20.4 in the orange book). If the medium used for plating cells.
Section G-II Gene Manipulation G3 Electrophoresis G4-1 Ligation G4-2 Transformation and G4-3 Analysis.
CULTURE INDEPENDENT ANALYSIS OF MICROBIAL COMMUNITIES IN SOIL
Biotechnology and Bacterial Transformation
Manufacture of Human Interleukin 13 Protein Using a Prokaryotic Expression System Ryan Rupp, York College of Pennsylvania, Department of Biological Sciences.
20.1 – 1 Look at the illustration of “Cloning a Human Gene in a Bacterial Plasmid” (Figure 20.4 in the orange book). If the medium used for plating cells.
I.INTRODUCTION Huntington’s disease (HD) is an autosomal dominant neurological disorder, leading to progressive degeneration of the nervous system. Usually.
Austin Jones Jace Dolphin. Methylosinus trichosporium culture courtesy of Dr. Alan DiSpirito, ISU Phenol/Chloroform Genomic DNA Extraction from protocol.
Introduction to pGLO lab Bacteria Transformation Please take these notes carefully. You do not need to write anything in RED.
PGLO Bacterial Transformation, Purification and SDS gel.
Human Genomic DNA Isolation Zelha Nil Nov DNA Structure Composed of nucleotides: A, T, G, C Synthesized in 5’ to 3’ direction through formation.
Week 7 Wednesday: –Screening of library transformants –Innoculation of colonies for plasmid preps –Practice PCR Turn in Lab #11 Thursday: –Plasmid minipreps.
Cloning the OOMT2 Gene in Roses Kim Lovik Megan Hughes.
Determining if the fused product of Botox A and GFP can be used to observe the binding patterns of Botulinum toxin A. Felicia Yothers Department of Biological.
Confirmation of positive clones Screening of positive clones Selection of high copy number clones Selection of positive clones FLUTCORE vaccine yeast constructs.
Group 4 Data Diane Meas The 3 A-Michaels (get it??) 3 amigos… a-michaels….
LET’S PLAY THE REVIEW GAME! (a.k.a how much did you forget this summer?)
Prodigiosin Production in E. Coli Brian Hovey and Stephanie Vondrak.
Prodigiosin Production in E. Coli
Neutrophil-specific Overexpression of FCHO2, a PCH family protein, in Danio rerio Chelsey Warning and Kate Cooper, PhD Loras College Department of Biology.
T9: Molecular Characterization of an Unknown P-element Insertion in Drosophila melanogaster.
Prodigiosin Production in E. Coli Brian Hovey and Stephanie Vondrak.
Molecular Cloning.
Catherine Shea and Shruti Panchavati Dr. Sarah Ades Lab
MOLECULAR BIOLOGY IN ACTION In this project, students will use what they have learned in the previous courses to complete a larger multi-step molecular.
Laboratory: Bacterial Transformation Introduction of plasmid DNA into E. coli E. coli.
Molecular Cloning. Definitions   Cloning :   Obtaining a piece of DNA from its original source (Genome) and introducing it in a DNA vector   Sub-cloning:
Testing the Efficiency of HindIII Restriction Enzyme at Various Temperatures using Plasmid DNA Kathleen West Marietta Wright, M.S. and Chad Sethman, Ph.
Transformation MISS : SALSABEEL H. AL- JOUJOU.
Miniprep 학기 기초유전학실험.
Cloning of a PCR Amplified Gene PPT 2. About Plasmids The plasmid pUC19 used for this experiment is derived from the pUC series. It has a single recognition.
pGLO™ Transformation and Purification of
Transformation of Escherichia coli
Jeopardy Final Jeopardy Gene Cloning Plasmids Ligase PCR $100 $100
Biochemical Tests.
COURSE OF MICROBIOLOGY
Team Fun Guys: Lorena Christensen, Michelle Fretheim, Gabriel Martin
DNA EXTRACTION Protocol and notes 9/17/2018.
Bacterial Transformation
RESULTS AND DISCUSSION
Cloning the OOMT2 Gene in Roses
ChIP DNA Sample Preparation
Week 1: Tutorial Outline
Transformation of Escherichia coli
Plasmid DNA Isolation Exercise 8.
Transformation of Escherichia coli
Presentation transcript:

Prodigiosin Production in E. Coli Stephanie Vondrak Brian Hovey

Review Our goal was to clone the pigI gene from Serratia marcescens into E. Coli Just to review: Prodigiosin is a secondary metabolite of various strains of Serratia, and other Gram negative gammaproteobacteria. It is responsible for the red pigment produced by Serratia marcescens. Produced under the control of 14 genes(pigA-pigN) We chose prodigiosin because of the recent attention to its newfound benefits Benefits such as: antibacterial, antifungal, antiprotozoal, antimalarial, immunosuppressive, and anticancer properties

Review Gene of Interest - We chose pigI because it is involved in one of the beginning pathways of MBC(4-methoxy-2,2`- bipyrrole-5-carbaldehydе) - This is a precursor of prodigiosin

Review Experimental Approach: Growth of S. marcescens Extraction of DNA PCR Amplification of gene of interest Site directed mutagenesis Insertion of gene of interest into vector Transformation of vector into E. Coli Selection of vector through Arabinose activation and ampicillin Check for gene of interest in vectors taken up by E.Coli via SDS-PAGE or sequencing

Growth of S. marcescens S. marcescens culture obtained from Dr. Walter Grew on a streak plate to see if culture was viable Culture then grown overnight in LB at 37°C Flasks were quite turbid so we proceeded to DNA extraction

Extraction of DNA DNA was first extracted according to protocols obtained from the USDA Amounts were reduced by a factor of 10 or more in most cases (Ex: 500ml to 5ml) Potential DNA (at least protein) was precipitated DNA samples ran through simple gel electrophoresis Digested and undigested samples run We assumed that these bands represented DNA because a streak showed up in a digestible lane (lane 7) We proceeded to PCR amplification to confirm the presence of DNA (and our target gene)

PCR Amplification On our first PCR run, the positive control failed, so we couldn’t conclude anything from our results Temperatures: Lane 3 – Biobrick oligo control Lane 4 – No Biobrick oligo control Lane 5 – Marker Lane 6 – Biobrick 50 C Lane 7 – Biobrick 52.9 C Lane 8 – Biobrick 62 C Lane 9 – Nobiobrick 50 C Lane 10 – Nobiobrick 52.9 C Lane 11 – Nobiobrick 62 C Lane 12 – Marker Annealing time – 1 min 30 sec Positive Control (or lack thereof)

DNA Concentration After consulting with Dr. Schwekendiek, we noticed that our DNA may have been over diluted (we had our samples suspended in 1ml of solution, when Dr. Schwekendiek noted 100µl was the usual dilution) To rectify this, we concentrated our DNA in a Speed Vacuum Concentrator overnight After running our samples through the Speed Vacuum Concentrator, we ran them through simple gel electrophoresis Sample 3 (lane 5) was the only sample that showed up in with any significant brightness, so we only used that sample for testing for the rest of our experiments (with our first extraction)

DNA Confirmation - Only sample 3 produced visible bands and we wanted to confirm the presence of DNA, so we ran a undigested and digested sample 3 through simple gel electrophoresis Sample 3 - As you can see, the gel was faulty, but we decided that there was a clear enough distinction between undigested and digested to proceed to PCR confirmation

DNA Confirmation Our positive control worked (4th lane from the left), but our samples (lanes 5 and 6 from the left) did not display the expected brightness. It is important to note that our annealing time was only 1 minute 30 seconds and our target gene is 1473 b.p., so that may have an effect on our results. We decided to run PCR again to see if the annealing time had an effect on our outcome Annealing time = 1 min 30 sec Lane 2 – Marker Lane 3 – Negative Control Lane 4 – Positive control Lane 5 – Bio (Sample 3) 50 C Lane 6 – NoBio (Sample 3) 50C

DNA Confirmation - An hour after we started our second PCR run, we discovered that we incorrectly set our PCR cycle order, stopped it, fixed the protocols and ran it again. Annealing time = 3 minutes Lane 3 – Marker Lane 4 – Pos control Lane 5 – Neg Control Lane 6 – Sample 3 Bio 55C Lane 7 – Sample 3 NoBio 55C Lane 8 – Sample 3 Bio 58.7 C Lane 9 – Sample 3 NoBio 58.7 C Lane 10 – Sample 3 Bio 65 C Lane 11 – Sample 3 NoBio 65 C Our positive control failed, so we were unable to draw any conclusions about the quality of our DNA We decided that while we could confirm these results by running another simple gel electrophoresis, we felt that the DNA obtained through the USDA extraction protocols was faulty, so we prepared for another DNA extraction using protocols from Open WetWare

DNA Extraction We grew up another culture from a set of streak plates provided by Dr. Walter We extracted DNA from this culture using Open WetWare protocols and then ran it through simple gel electrophoresis We had no visible bands We suspected this is because we didn’t let our DNA properly dissolve in solution at the end of extraction, due to rushing to electrophoresis We decided to run another gel electrophoresis after we let the DNA fully dissolve

DNA Confirmation - The results of our gel electrophoresis (undigested and digested samples were run) were as follows: - These results correspond with digestible DNA, so we took what we determined to be the best sample (sample 2) and ran it through PCR

DNA Confirmation Annealing time = 3 minutes Temperatures Lane 9 – Marker Lane 10 – Positive control Lane 11 – Neg Control Lane 12 – NoBio 55 C Lane 13 – Bio 55 C Lane 14 – NoBio 58.7 C Lane 15 – Bio 58.7 C Lane 16 – NoBio 65 C Lane 17 – Bio 65 C Lane 18 - Marker The results show a strong band at around 1500 b.p., which corresponds to the size of our target gene (pigI)

Experimental Approach Alteration We decided that because time was limited we would alter our experimental protocol as follows: Growth of S. marcescens Extraction of DNA PCR Amplification DNA Purification T-Vector Ligation T-Vector Transformation Growth of Transformed Cells (DH5α) Plasmid Extraction DNA confirmation Sequencing We are here at this point

DNA Purification Since the PCR showed bright bands at the range our target gene should be at (~1500 b.p.) we excised the DNA from the gel and purified it with a GeneJet Gel Extraction Kit We then ran the DNA through a simple gel electrophoresis - We had bright bands show up at around 1500 b.p. again, so we felt confident that our target gene had been successfully purified

T-vector ligation and transformation We proceeded to T-vector ligation with our target gene using a pGEM-T Easy Vector kit We then add DH5α (E. coli) to the ligated T-Vectors and grew the solution on ampicillin plates to find potentially viable colonies Our results were: 3Amp: 2 colonies (only one was present at the time of picking) 2Amp: 0 colonies 1Amp: 0 colonies +Amp: 20 colonies -Amp: 0 colonies -NoAmp: plate completely covered. 5 colonies from the positive control and the one colony from Amp 3 plate were picked and incubated in 5ml of LB overnight Growth was observed in all tubes

Plasmid Extraction and DNA Confirmation We used a GeneJet Plasmid Miniprep Kit to extract the plasmid from the DH5α cells We then ran this through gel electrophoresis We have a bright band at approximately 3000 b.p. which corresponds to the size of our vector (~3200 b.p.) We did not notice a band for our target gene, but we sent it off for sequencing confirmation

DNA Sequencing - Our results came back Tuesday - Comparing the pGEM T-Easy Vector sequence to our sequenced PCR showed that the sequences were identical – there was no sign of our target gene

References Neil R. Williamson, 1 Henrik T. Simonsen, 2 Raef A. A. Ahmed, 2 Gabrielle Goldet, 2 Holly Slater, 1 Louise Woodley, 1 Finian J. Leeper 2 and George P. C. Salmond 1 *. "Biosynthesis of the Red Antibiotic, Prodigiosin, in Serratia : Identification of a Novel 2-methyl-3-n-amylpyrrole (MAP) Assembly Pathway, Definition of the Terminal Condensing Enzyme, and Implications for Undecylprodigiosin Biosynthesis in Streptomyces." (n.d.): n. pag. Print. Serratia Marcescens., 2011. Web. 3 Sept. 2012. www.serratiamarcescens.net http://microbewiki.kenyon.edu/index.php/Serratia_marcescens Harris, A. K. P. "The Serratia Gene Cluster Encoding Biosynthesis of the Red Antibiotic, Prodigiosin, Shows Species- and Strain-dependent Genome Context Variation." Microbiology 150.11 (2004): 3547-560. Print. Williamson, Neil R., Peter C. Fineran, Tamzin Gristwood, Suresh R. Chawrai, Finian J. Leeper, and George PC Salmond. "Anticancer and Immunosuppressive Properties of Bacterial Prodiginines." Future Microbiology 2.6 (2007): 605-18. Print.