Team:Caltech/Project

From 2011.igem.org

Revision as of 02:01, 29 September 2011 by Doobop39 (Talk | contribs)


Caltech iGEM 2011



Home

Project

Data

Parts

Team

Notebook

Biosafety

Human Impact

References

Support

Bioremediation of Endocrine Disruptors Using Genetically Modified Escherichia Coli

Smallbeavercoli.png

Endocrine disruptors, or substances that mimic estrogen in the body, have detrimental biological effects on the reproduction of several species of fish and birds; the Caltech team focuses on bioremediation of these toxins. Our goal is to create a system housed in E. coli that can be used to process water and remove endocrine disruptors on a large scale. We focus on isolating degradation systems for the common endocrine disruptors bisphenol A (BPA), DDT, nonylphenol and 17a-ethynylestradiol. We synthesized known degradation enzymes DDT dehydrochlorinase, BisdA and BisdB, and characterized the behavior of these enzymes when acting on our target endocrine disruptors. In addition, we explored the potential of certain cytochrome p450s to initiate degradation of these chemicals, focusing on WT-F87A degradation of BPA. Finally, we characterized the functionality of E. coli protein processing when E. coli is deployed as an easily containable biofilm on various substances in aqueous environments.

Introduction:

Endocrine-disrupting chemicals (EDCs) are chemicals that interact with the endocrine system by binding to hormone receptors, causing problems in sexual development and reproduction of organisms. These chemicals are introduced to the environment from improper disposal of plastic wastes, hormonal medications remaining in human waste, and pesticides. Areas with high concentrations of estrogen in water have been shown to correlate with a higher percentage of intersex fish, and pesticides such as DDT have been shown to impact the development of the female reproductive tract in birds. Many EDCs are persistent organic pollutants, and even though regulations have been put in place for pesticide use and industrial production of endocrine disruptors, many of these chemicals continue to pollute bodies of water in significant concentrations.

Synthetic biology involves the engineering of genetic networks to create modified organisms that can address a problem or perform a task. We focus on modifying the genetic code of E. coli to remove endocrine-disrupting chemicals from water. To do this, we created constructs containing previously discovered BisdA and BisdB enzymes that have been shown to degrade BPA and we are testing their efficacy. We also assembled a gene for DDT Dehydrochlorinase, an enzyme previously shown to degrade DDT, and expressed this gene in E. coli to characterize its properties. We were able to establish that our synthesized gene expresses a protein that consistently degrades DDT. This enzyme may also be useful in degrading other EDCs. In addition to testing enzymes known to degrade EDCs, we also conducted a search for cytochrome p450s, enzymes known to initiate degradation of many compounds through an oxidation-reduction process. Using p450s selected from the Arnold lab library, we conducted reactions with BPA, DDT, nonylphenol, and 17a-ethynylestradiol. We analyzed the products of these reactions with HPLC. We found that BPA showed evidence of degradation when combined with the p450 WT-F87A, so the gene for this p450 could be useful for bioremediation.

To further explore the possibilities for bioremediation of EDCs, we performed a selection experiment on biological samples from the Los Angeles River. Since the Los Angeles River is highly polluted with plastics and located in an urban area, it is likely that some selection has already occurred to allow organisms to consume EDCs. We grew these samples on minimal media with various EDCs as carbon sources, and demonstrated the presence of live organisms after several weeks of serial selection, indicating that these organisms can degrade EDCs as a primary carbon source. In order to test the feasibility of an E. coli-housed system for bioremediation, we conducted experiments with biofilms prepared on glass beads in a column. As a model system, we used the degradation of X-gal with beta-galactosidase. We also conducted an evaluation of local water plants to determine typical purification systems for large bodies of water and see if a bioremediation unit can integrate into typical water treatment plants.

BisdA and BisdB

Plasmid map of BisdA under the lac promoter K620002 in pSB4A5.
Plamid map of BisdB under the tet promoter K6230003 in pSB3K3.

We sourced genetic material for BisdA (K123000) and BisdB (K123001) from the Registry of Standard Biological Parts. The sequence listed for these parts had the wrong codons listed, so we sequenced the parts to determine the correct codons. We then designed genetic constructs with inducible promoters, ribosome binding regions, and terminators in plasmid backbones for each gene. We accessed these parts by transforming DNA from the Registry of Standard Biological Parts into chemically competent E. coli for construction, and used PCR to extract our desired components. We attempted several methods of assembly for these pieces, including traditional assembly, Gibson assembly, and a combination of PCR assembly for the coding construct and standard assembly to insert the coding construct into a backbone. After assembly of these components was complete, we combined the two coding constructs into one vector and expressed this vector in E. coli for experimentation. We are now inducing production of BisdA and BisdB so that we can investigate their ability to degrade EDCs.


Gibson Assembly

A gel showing Gibson assembly of GFP, promoter, terminator and pSB4A5 and BisdA, lac promoter, terminator and pSB4A5 (pNT001) stopped at 0, 5, 10, 15, 30, 60 minutes. Generally, over time, the smaller bands decrease in brightness and larger bands increase in brightness

We attempted to use Gibson Assembly for creating composite BioBrick plasmids including inducible BisdA and BisdB. After many weeks of doing Gibson reactions and screening for colonies, we have observed that Gibson assembly may not be the most efficient and reliable method of assembling BioBricks. Gibson assembly may be a quicker method of cloning than using restriction enzymes and ligase, but this work indicates that quality and quantity of plasmids produced using this method are not as easily reproducible as standard assembly for assembly of multiple BioBrick parts is. If iGEM teams wish to use this method for assembly, we have shown that limiting the total DNA in the Gibson reaction, limiting the number of parts being combined in the reaction and using extremely competent cells improves the ratio of experimental colonies to negative control colonies. These can then be screened using colony PCR or sequencing. However, the high complementarity between the BioBrick prefix and suffix could contribute to the high numbers of self-ligation we observed. Due to the enzymes in the Gibson reaction, phosphatase cannot be used, a common procedure in standard assembly.

We recommend PCR assembly, if possible, of composite BioBrick inserts rather than multi-step standard assembly to increase the efficiency of assembling of BioBrick parts. Future iGEM teams are advised to try different methods of assembly and cloning in parallel, as the parts are not as modular as stated and each combination behaves differently than others.

DDT Dehydrochlorinase

The band indicating DDT dehydrochlorinase is visible in both elution columns, between the 21,500 and 31,000 g/mol bands. The DDT protein is 23,500 g/mol.
Plasmid map of K620000 in pSB1C3 (submission plasmid)
GCMS of DDT showing a clear peak at 235g/mol
DDT Molecular Structure
DDT structure after GCMS with a molecular weight of 206g/mol
DDT reaction with DDT Dehydrochlorinase analyzed with GCMS. There is a peak at 191 g/mol and a peak at 206 g/mol; the 12th minute peak is tris from the reaction buffer.
DDT structure after reaction with DDT Dehydrochlorinase and GCMS with a molecular weight of 206 g/mol;

We found DDT Dehydrochlorinase in the literature as an enzyme discovered to degrade DDT. We found the amino acid code for this enzyme on GenBank, used DNAWorks to design oligos for assembling this enzyme optimized in E. coli, and assembled this gene using PIPE cloning. We then inserted this gene in a pET vector with a his-tag and overexpressed it in E. coli. We purified the protein and ran it on a gel, indicating that this gene can be expressed in E. coli as shown in the DDT dehydrochlorinase gel image.

Plasmid map of K620000 in pET11-a to amplify and purify the protein.

We next conducted degradation experiments with DDT. We set up an experiment in which cell lysate of cells producing DDT dehydrochlorinase was prepared in a reaction with DDT and some buffers and reacted overnight. Then the reaction mixture was analyzed using electrospray GCMS, along with a control of DDT without cell lysate. As shown in the GCMS of DDT without degradation enzymes, there is a clear band at 235 g/mol. DDT's molar mass is 355. This indicates that the original structure loses a carbon and three chlorines to form a new structure with this mass during the GCMS process. The GCMS experimental results show a further degradation of DDT to a molecular weight of 206 g/mole. The degradation that could result in this weight involves the loss of two chlorines and a phenyl group. There is another mass spec band in this reading at 191 g/mol, which we are still working to identify. However, there is a clear absence of the band indicative of DDT in the reaction result. This indicates that DDT Dehydrochlorinase is indeed initiating the degradation of DDT.

Cytochrome p450s

GCMS-electrospray of BPA showing characteristic peak at 227g/mol
GCMS of BPA after reaction with the WT-F87A P450 that shows a degraded peak at 205g/mole
Plasmid map of K620001 in pSB1C3 (submission plasmid).

Cytochrome p450s are known to be initiators of degradation for several compounds. We analyzed the structures of the cytochrome p450s which the Arnold Lab possessed in their genetic library and selected four highly promiscuous p450s. We then conducted reactions of these p450s with BPA, DDT, 17a-ethinylestradiol, and nonylphenol. We attempted to analyze the product of these reactions with HPLC and with GCMS, but we found that the product did not stay ionized and therefore could not be analyzed. We formed an electrospray of the reaction products and analyzed this using GCMS. Then we found that the WT-F87A cytochrome p450 was able to act on BPA, degrading the compound from its original GCMS reading of 227 g/mol to a GCMS reading of 205g/mole. We are working to determine what degradation steps would result in this mass. However, since the GC analysis shows a wide band of molecules with a mass of 205 g/mol, this indicates that there are likely many different structural compounds with this molecular mass created when the WT-F87A p450 degrades BPA. This result establishes another degradation pathway for Bisphenol A.

Selection of EDC-Degrading Organisms

Figure 1: Liquid minimal media cultures plated on LB; week 3
Figure 2: Liquid minimal media cultures plated on LB; week 8

In order to identify an organism capable of degrading our EDCs, we collected dry and wet samples from the Los Angeles river and used these samples to inoculate liquid minimal media cultures in which the sole source of carbon was the EDC. (We used media with and without a vitamin mix to account for any compounds the organisms might not be capable of manufacturing themselves, but the presence or absence of the vitamin mix seems to have made little difference in the growth of the organisms; cultures exhibited equivalent growth both with and without the vitamin mix.) We sequentially used these cultures to inoculate new cultures every two to three days over an eight-week period in order to further isolate organisms.

At the third week we plated the cultures on LB plates and observed significant growth of many different types of organisms, indicating that our cultures contained organisms capable of surviving on our EDCs. To further isolate these organisms, colonies from each culture were resuspended in liquid minimal media; as before, new liquid minimal media cultures were inoculated from each of these every two to three days. The cultures were plated again on LB in the eighth week and again, significant growth was observed.

At this stage, we attempted to plate our cultures on solid minimal media; however, all of the compounds we chose are insoluble in water, which makes traditional plating impossible. We attempted several alternate methods of plating the EDCs together with the minimal media and cultures, but all these attempts were unsuccessful. Thus, although we demonstrated the presence of EDC-degrading organisms in our cultures, we were unable to fully isolate any organisms for further study.

Biofilm Columns

Visible layers of biofilm as visualized by crystal violet

We cultured top10 E. coli biofilms on glass beads and stained with crystal violet to show growth the bacteria. Our next step was to create a construct within the top10 bacteria which constitutively expressed the lacZ gene. Since lacZ cleaves X-gal, a clear chemical, into its component dye and galactose, the lacZ-infused bacteria was able to change a solution of X-gal bright blue in under 10 minutes. The final part of this experiment would be to grow the lacZ-infused bacteria into a biofilm onto glass beads, then flow the X-gal solution through a column of the biofilm beads. The effluent flow should be bright blue. However, this last bit hasn't been completed as of the iGEM due date.



Retrieved from "http://2011.igem.org/Team:Caltech/Project"