Click to edit Master subtitle style 9/13/10 Remediation of Phenol Resin Using White Rot Lignin Peroxidase in E. Coli Lorena Christensen Michelle Fretheim Gabe Martin
9/13/10 The Problem with Plastics Our team was formed out of an interest in the possibility of the breakdown of plastics. There are numerous products and multiple types of plastics, all of which prove difficult if not impossible to degrade over time. Online research using and Google scholar into possible candidates for remediation of plastic yielded a fungus called Phanerochaete chrysosporium, common name White Rot. It is capable of degrading phenol (Gusse et al, 1).
9/13/10 To recombine desired Lignin Peroxidase gene from White rot (Accession # EF on ncbi.nlm.nih.gov) into E. Coli and have offspring of bacteria display ability to break down phenol. -- Lignin peroxidase decomposes phenolic resin, a structure of phenol and formaldehyde (Gusse et al). The Goal
9/13/10 How this is new... Transferring DNA of white rot into E. coli and then monitoring offspring ability to decompose phenol resin is completely new. The lignin peroxidase has been previously placed into E. coli but we didn't locate any instances of testing the offspring organism's abilities to break down phenol itself.
9/13/10 Plan of Action Obtain specimen of white rot from Professor Bumpus in form of mycelium. Use specific protocol for removal of DNA from mycelium per Weiland. (
9/13/10 After amplification of gene of interest with PCR, will need to build forward and reverse primers. Five introns in the gene will need to be circumvented.
9/13/10 Gene of interest exons: coding, complement, reverse complemtent Join 1-9, , , , ; the rest are introns. BLACK = EXON, ORANGE = COMPLEMENT (3’-5’), BLUE = REVERSE COMPLEMENT (5’-3’) # 1 ccttcgtat ggaagcata atacgaagg
9/13/10 #2 ggtcttcca cgactccatc gctatctcgc ccaagcttca gtcgcagggc aagtttgg ccagaaggt gctgaggtag cgatagagcg ggttcgaagt cagcgtcccg ttcaaacc ccaaactt gccctgcgac tgaagcttgg gcgagatagc gatggagtcg tggaagacc #3 c ggcggcggcg cggacggctc gatcatcacc ttctcctcga tcgagaccac gtaccacccg aacatcggcc tcgacgaggt cgtcgccatc cagaagccgt tcatcgcgaa gcacggcgtc acgcccggcg acttcatcgc gttcgccggt gccgtcggcg tgagcaactg cccgggcgcg ccgcagatgc agttcttcct cggccgcccc gaggcgacgc aggctgcccc cgacggtctc gtgcccgagc ccttcc g ccgccgccgc gcctgccgag ctagtagtgg aagaggagct agctctggtg catggtgggc ttgtagccgg agctgctcca gcagcggtag gtcttcggca agtagcgctt cgtgccgcag tgcgggccgc tgaagtagcg caagcggcca cggcagccgc actcgttgac gggcccgcgc ggcgtctacg tcaagaagga gccggcgggg ctccgctgcg tccgacgggg gctgccagag cacgggctcg ggaagg ggaagg gctcgggcac gagaccgtcg ggggcagcct gcgtcgcctc ggggcggccg aggaagaact gcatctgcgg cgcgcccggg cagttgctca cgccgacggc accggcgaac gcgatgaagt cgccgggcgt gacgccgtgc ttcgcgatga acggcttctg gatggcgacg acctcgtcga ggccgatgtt cgggtggtac gtggtctcga tcgaggagaa ggtgatgatc gagccgtccg cgccgccgcc g
9/13/10 #4 acacc atcgatcagg ttctcgctcg catgcttgat gctggcggct tcgacgagat cgagactgtc tggctgctct ctgc tgtgg tagctagtcc aagagcgagc gtacgaacta cgaccgccga agctgctcta gctctgacag accgacgaga gacg gcag agagcagcca gacagtctcg atctcgtcga agccgccagc atcaagcatg cgagcgagaa cctgatcgat ggtgt #5 cca ctccatcgcg gctgcgaacg acgtcgaccc gaccatctcc ggcctgccgt tcgactccac ccctggccag ttcgactccc agttcttcgt cgagacgcag ctccgcggta ccgcattccc tgg ggt gaggtagcgc cgacgcttgc tgcagctggg ctggtagagg ccggacggca agctgaggtg gggaccggtc aagctgaggg tcaagaagca gctctgcgtc gaggcgccat ggcgtaaggg acc cca gggaatgcgg taccgcggag ctgcgtctcg acgaagaact gggagtcgaa ctggccaggg gtggagtcga acggcaggcc ggagatggtc gggtcgacgt cgttcgcagc cgcgatggag tgg #6 caa gaccggcatc cagggcaccg tcatgtcccc gctcaagggc gagatgcgtc tgcagacgga ccacttgttc gcgcgcgact cgcgcacggc g gtt ctggccgtag gtcccgtggc agtacagggg cgagttcccg ctctacgcag acgtctgcct ggtgaacaag cgcgcgctga gcgcgtgccg c c gccgtgcgcg agtcgcgcgc gaacaagtgg tccgtctgca gacgcatctc gcccttgagc ggggacatga cggtgccctg gatgccggtc ttg
9/13/10 In order to avoid the numerous introns we will build oligonucleotides for desired exon segments our gene:1-9, , , , ; the rest are introns: *1-9 connected to with 16-base overlaps (10-61 and are introns) 3’Ccttcgtatccagaaggtgctgagg caagcttcagtcgcagggcaagtttgg 5’ Ggtcttccacgactccatcgctatctcgccgttcgaagtcagcgtc * too big for this method ( is an intron) * oligos connected with 16-base overlaps ( is an intron) 3’Acaccatcgatcaggttctcgctcgctacgatctacgaccgc agatcgagactgtctggctgctctctgc 5’Atgcttgatgctggcggcttcgacgtctagctctgacagac
9/13/10 * oligos connected with 16-base overlaps 3’Ccactccatcgcggctgcgaacgacgagctgggctggtagag ttcgactccacccctggccagttc... 5’ tcgacccgaccatctccggcctgccgaagctgaggtggggac 3’ctgagggtcaagaagc gctccgcggtaccgcattccctgg 5’gactcccagttcttcgtcgagacgcacgaggcgccatggcgt * oligos connected with 16-base overlaps 3’Attgcagcaagaccggcatccacccgtggcagtacagg agggccagatgcgtctgcagacg... 5’ gggcaccgtcatgtccccgctcatcccggtctacgcaga 3’ctggtgaacaagcgcg 5’gaccacttgttcgcgcgcgactcgcgcacggcg
9/13/10 To verify introns were successfully removed, we will add restriction enzymes to DNA obtained from PCR amplification, run gels and check fragment sizes. Restriction enzymes used for the project are ECOR I, Xbai, Spe I and PST I. Verified that these would not cut our desired sequence in any undesired areas using the NEB cutter tool.
9/13/10 The sequence used will be built into a biobrick, with required format E-X-Part of Interest-S-P (Schwekendiek, 3). Will select vector for procedure per guidelines of partsregistry.org in order to submit created items.
9/13/10 Will follow general protocol for recombination as follows: 1. Use appropriate restriction enzymes to cut vector and gene of interest. 2. Will ligate into appropriate plasmid (or other recommended vector). 3. Will then introduce into E. coli
9/13/10 The next step will be the observation of traits in offspring and testing for presence of desired gene. In order to properly test for lignin peroxidase in offspring, will need to subject them to media limited in Carbon, Nitrogen and sulfur in order to remove repression of LiP production.
9/13/10 Phenol placed on such limited substrate will show discoloration from presence of the LiP in the offspring if the transfer is successful.
9/13/10 The Backup Plan If this project fails due to death of created offspring during breakdown of the phenol resin, there is currently no other organism capable of the desired results so there is nothing we can replace it with. We could attempt to find the gene in the parent fungus DNA that allows it to resist the toxicity of the phenol and transfer that to the E. coli offspring and retry decomposition of the phenol resin.
9/13/10 References 08h Lecture 09/2010 Schwekendiek