Team:Nevada/Project

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(Goal 5)
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=== Goal 5 ===
=== Goal 5 ===
Our goal is to develop ''in vitro'' enzyme assays to assess 4-coumarate-CoA ligase and cinnamoyl-CoA reductase activity in strains developed in Goals 2, 3, and 4. These assays will be important to verify the activity and level of expression of the engineered enzymes. Furthermore, the assays will be important to obtain kinetic information to apply to the model described in Goal 1.
Our goal is to develop ''in vitro'' enzyme assays to assess 4-coumarate-CoA ligase and cinnamoyl-CoA reductase activity in strains developed in Goals 2, 3, and 4. These assays will be important to verify the activity and level of expression of the engineered enzymes. Furthermore, the assays will be important to obtain kinetic information to apply to the model described in Goal 1.
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* Assay:
 
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** Assay mixture: 3.3mg trans-cinnamic acid dissolved in 50uL ethanol, 2.0mg coenzyme A and 6.9mg adenosine triphosphate were suspended in 10mL 50mM Tris buffer 2.5mM magnesium chloride, pH 7.5.
 
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** 50uL extract was added to 500uL assay mixture at room temperature in a quartz cuvette, and change in absorbance was measured at 311nm.
 
=== Results and Discussion for Goal 5 ===
=== Results and Discussion for Goal 5 ===

Revision as of 00:52, 22 October 2009



Contents

Overall project

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Simplified Graphic of our project goal


Cinnamicide: Producing a Natural Insecticide against Mosquito Larvae in E. coli and Duckweed Cinnamaldehyde is a natural insecticide against mosquito larvae that shows low toxicity towards other organisms. The objective of this project is to engineer the cinnamaldehyde biosynthetic pathway into E. coli to develop an inexpensive and readily available source of this compound. By introducing the genes encoding phenylalanine-ammonia lyase (gene 1), 4-coumarate:CoA ligase (gene 2), and cinnamoyl-CoA reductase (gene 3), it should be possible to produce cinnamaldehyde from available phenylalanine in E. coli. Once we have demonstrated that we can produce cinnamaldehyde in E. coli, we will engineer cinnamaldehyde production in duckweed (Wolffia or Lemna species), a small aquatic plant. Because mosquito larvae feed on duckweed detritus, the engineered plant will serve as an excellent vehicle to deliver cinnamaldehyde for mosquito control.

Safety Questionnaire

Would any of your project ideas raise safety issues in terms of:

  • researcher safety,
  • public safety, or
  • environmental safety?

At this point in the project, it will not raise any safety concerns in terms of researcher safety, public safety, or environmental safety. Future portions of this project pertaining to transformation of E. coli and duckweed could raise environmental issues and proper containment monitoring will need to be addressed.

Is there a local biosafety group, committee, or review board at your institution?
Yes, there is a local biosafety review board at our institution named Environmental Health & Safety (EH&S). We also collaborated with Scott Munsen of the Washoe County Vector Control.

What does your local biosafety group think about your project?
Our local biosafety group approved our project design and subsequent facilitation of research. Scott Munsen of the Washoe County Vector Control believes this could be a usable product and will aid in the larvicidal tests of cinnamaldehyde against various mosquito species to verify its larvicidal activity and to ensure we are not harming non-target organisms.

Do any of the new BioBrick parts that you made this year raise any safety issues?
No, none of our new BioBrick parts that we made this year raise any safety issues. The genes we are using are naturally occurring genes expressed in plants and other organisms that do not raise any current harm.

Project Details

Why Produce an Insecticide against Mosquitoes?

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Aedes aegypti biting human

It is estimated that every year over 350-500 million people are infected by diseases spread by mosquitoes, and over 1 million of them die as a result. Current insecticides being used which include dichlorodiphenyltrichloroethane (DDT), organophosphates, and others, cause environmental and dangerous affects to non-target organisms, including humans. Many mosquito species gain resistance to these insecticides, so new ways to combat mosquitoes that transmit human diseases need to be produced. In order to replace these general synthetic insecticides, our proposed project is to produce a natural, low toxicity mosquito larvicide through the production of cinnamaldehyde. Finding a cost-effective, environmentally friendly manner to control mosquito populations is an important goal of this project.

Goal 1

Develop a mathematical model to predict pathway flux based on enzyme kinetic values and enzyme concentrations. The information from this model will give rationale for the best engineering design choices in order to optimize cinnamaldehyde production in E.coli.

Experiment and Results for Goal 1

1. Using Mathematica, a model was developed to describe Michaelis-Menten steady-state kinetics for the engineered cinnamaldehyde biosynthetic pathway. The published Km and Vmax values for the plant proteins phenylalanine-ammonia lyase, 4-coumarate:CoA ligase and cinnamoyl-CoA reductase (feruloyl-CoA reductase), were used in our model. The model predicted that a biosynthetic bottleneck will occur at 4-coumarate:CoA ligase. This problem appears to be primarily due to the high Km value of the enzyme for its substrate cinnamic acid. Therefore, we used the model to test two possible means of increasing pathway flux: 1) increasing 4-coumarate:CoA ligase levels and 2) decreasing 4-coumarate:CoA ligase’s Km for cinnamic acid. The results produced from the model showed that by increasing the 4-coumarate:CoA ligase concentration ten-fold relative to the other enzymes in the pathway, or by decreasing the Km forty-fold, the barrier could be bypassed in this way.

Goal 2

The second goal of this project is to clone the Arabidopsis gene cinnamaldehyde-CoA reductase (gene 3) into an E. coli expression system and test for the production of cinnamaldehyde. Currently, we are building our construct using standard parts from the registry. The goal is to produce a newly engineered part containing an IPTG-inducible (Lac I) promoter, a standard RBS, gene 3, and a standard double terminator.

Experiment and Results for Goal 2

1. Conduct a three way ligation with LacI promoter (BBa_R0011), RBS (part BBa_B0034) and a chloramphenicol resistant plasmid backbone (pSB3C5) using the standard assembly 10 protocol. DONE created intermediate part BBa_K262000

2. Conduct a three way ligation with cinnamoyl-CoA reductase (gene 3), double terminator (BBa_B0014) and chloramphenicol resistant plasmid (pSB3C5). Follows standard assembly 10 protocol. DONE created intermediate part BBa_K262002

3. Conduct a three way ligation with intermediate parts from step 1 & 2 and a tetracycline resistant plasmid backbone (pSB3T5). Standard assembly 10. 3-WAY LIGATION HAS BEEN UNSUCCESSFUL TO DATE

4. Alternative approach to step 3 is to perform a two-way ligation. Perform Restriciton Digest with Xba1 and Pst1 to isolate gene 3/double terminator, also run restriction digest with Spe1 and Pst1 Lac/RBS and clone gene3/double terminator into the chloromphenicol plasmid containing LacI+ RBS. IN PROGRESS

Goal 3

The third goal of this project is to clone the Arabidopsis gene 4-coumarate:CoA Ligase (gene 2) into an E. coli expression system and test for the production of cinnamoyl-CoA. Currently, we are building our construct using standard parts from the registry. The goal is to produce a newly engineered part containing the Lac inducible (Lac I) promoter, a standard RBS, gene 2, and a standard double terminator.

Experiment and Results for Goal 3

1. Conduct a three way ligation with 4-coumarate:CoA Ligase (gene 2), double terminator (BBa_B0014) and chloramphenicol resistant plasmid (pSB3C5). Follows standard assembly 10 protocol. DONE

2. Conduct a three way ligation with BBa_K262000 and gene 2/double terminator and a tetracycline resistant plasmid backbone (pSB3T5). Standard assembly 10. 3-WAY LIGATION HAS BEEN UNSUCCESSFUL TO DATE DECIDED TO SKIP TO 2 WAY LIGATION APPROACH BELOW

3. Alternative approach to step 3 is to perform a two-way ligation. Perform a restriciton digest of gene2/double terminator with Xba1 and Pst1, then isolate gene 2/double terminator by gel extraction. Also run restriction digest with Spe1 and Pst1 to linearize BBa_K262000 and clone gene2/double terminator into BBa_K262000. IN PROGRESS

Goal 4

Another goal of this project is to clone the Arabidopsis gene 4-coumarate:CoA ligase (gene 2) into an E. coli expression system along with cinnamoyl:CoA reductase (gene 3) and test for the production of cinnamaldehyde. Currently, we are building our construct using standard parts from the registry. The goal is to produce a newly engineered part containing the Lac IPTG-inducible (Lac I) promoter, a standard RBS, gene 2, RBS, gene 3 and a standard double terminator. We also want to do this with phenylalanine-ammonia lyase (gene 1) in order to form a novel self-sustaining pathway dependent only on the presence of phenylalanine within the cellular micro-environment.

Experiment and Results for Goal 4

1. Conduct a three-way ligation with 4-coumarate:CoA ligase (gene 2), RBS (BBa_B0034) and chloramphenicol resistant plasmid (pSB3C5). Follows standard assembly 10 protocol. IN PROGRESS

2. Conduct a three way ligation with BBa_K262000 and plasmid containing RBS/gene 2. FAILED, REVISE STRATEGY

Goal 5

Our goal is to develop in vitro enzyme assays to assess 4-coumarate-CoA ligase and cinnamoyl-CoA reductase activity in strains developed in Goals 2, 3, and 4. These assays will be important to verify the activity and level of expression of the engineered enzymes. Furthermore, the assays will be important to obtain kinetic information to apply to the model described in Goal 1.

Results and Discussion for Goal 5

IGEM Gene 2 Gel.jpg

SDS-PAGE showing 4-coumarate-CoA ligase protein expression (before it was made into a BioBrick part) under induction vs uninduced and wild type (W.T.) E. coli. An expression vector, PL N256A (donated by Dr. Kombrink at the Max Planck Institute, Munchen, Germany), containing a modified gene for 4-coumarate:CoA ligase, an IPTG inducible promoter and a 6xHis tag was used to transform E. coli, BL21 strain cells. Tagged protein in lanes 6 and 7 were purified using a Ni column ("HiTrap nickel chelating column," GE Biosciences). Lanes are as follows:

  1. Molecular weight marker
  2. W.T. E. coli, crude extract, 50ug protein
  3. W.T. E. coli, crude extract, 10ug protein
  4. Transformed E. Coli, uniduced crude protein extract, 50ug protein
  5. Transformed E. Coli, uniduced crude protein extract, 10ug protein
  6. IPTG induced transformed E. coli, Ni Column purified, Coumarate:CoA ligase extract, 50ug protein
  7. IPTG induced transformed E. coli, Ni Column purified, Coumarate:CoA ligase extract, 10ug protein
  8. Blank
  9. Molecular weight marker

Our data shows that wild type E. coli display no 4-coumarate:CoA ligase expression. Lanes 4, 5, 6 and 7 show that the transformants do express 4-coumarate-CoA ligase.

IGEM2.JPG

Time course of 4-coumarate:CoA ligase activty. 50uL of clarified E. coli extract was added to 500uL of enzyme assay solution. Black line = W.T. E. coli. Red line = E. coli transformed with PL N256A.

Igem3.JPG

Absorbance change/10 s interval given in table: assay 4 = wild type. Assay 5 = E. coli transformed with PL N256A.

Goal 6

Another goal is to put one or more genes of the cinnamaldehyde pathway into Wolffia and Lemna species. This will upregulate the already existing pathway to produce more cinnamaldehyde. Can possibly be used as an adult mosquito repellent and larvicide to certain mosquito larvae.

Experiment and Results for Goal 6

1. Conduct TOPO Cloning Reaction to put Gene 3 into pEntrD TOPO Vector (Shuttle vector which will allow us to put gene 3 into a binary plant vector) DONE

2. Conduct LR Clonase Reaction to transfer Gene 3 from pEntrD Vector to pK7WG2D.1 Binary Vector. DONE

3. Use Binary Vector pK7WG2D.1 to grow Agrobacterium EHA105 strain. Use this strain to infect Wolffia. IN PROGRESS


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Wolffia: Each "leaf" is an independent organism, one of the smallest plants in the world.
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Lemna Minor: one of the duckweed species we work with
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Observations: Nick and Joey working with the plants

References

  1. Arriaga, A.M.C., Rodrigues, F.E.A., Lemos, T.L.G., de Oliveria, M.C.F., Lima, J.Q., Santiago, G.M.P., Braz-Filho, R., Mafezoli, J. 2007.Composition and larvicidal activity of essential oils from Stemodia maritima L. NPC. 2, 1237-1239.
  2. Beuerle, T., Pichersky, E. 2002. Enzymatic synthesis and purification of aromatic coenzyme A esters. Analytical Biochemistry. 302, 305-312.
  3. bin Jantan, I., Yalvema, M.F., Ahmad, N.W., Jamal, J.A. 2005. Insecticidal activities of the leaf oils of eight Cinnamomum species against Aedes aegypti and Aedes albopictus. Pharmaceutical Biology. 43, 526-532.
  4. Chang, K.S., Tak, J.H., Kim, S.I., Lee, W.J., Ahn, Y.J. 2006. Repellency of Cinnamomum cassia bark compounds and cream containing casia oil to Aedes aegypti (Diptera: Culicidae) under laboratory and indoor conditions. 62, 1032-1038.
  5. Cheng, S.S., Liu, J.Y., Tsai, K.H., Chen, W.J., Chang, S.T. 2004. Chemical composition and mosquito larvicidal activity of essential oils from leaves of different Cinnamomum osmophloeum provenances. J. Agric. Food Chem. 52, 4395-4400.
  6. Cheng, S., Liu, J.Y., Huang, C.G., Hsui, Y.R., Chen, W.J, Chang, S.T. 2008. Insecticidal activities of leaf essential oils from Cinnamomum osmophloeum against three mosquito species. Bioresource Technology. 100, 457-464.
  7. Hamberger, B., Hahlbrock, K. 2003. The 4-coumarate:CoA ligase gene family in Arabidopsis thaliana comprises one rare, sinapate-activating and three commonly occurring isoenzymes. PNAS. 101, 2209-2214.
  8. Kim, N.J., Byun, S.G., Cho, J.E., Chung, K, Ahn, Y.J. 2008. Larvicidal activity of Kaempferia galanga rhizome phenylpropanoids towards three mosquito species. Pest Manag Sci. 64, 857-862.
  9. Lee, E.J., Kim, J.R., Choi, D.R, Ahn, Y.J. 2008. Toxicity of Cassia and Cinnamomum Oil compounds and Cinnamaldehyde-related compounds to Sitophilus oryzae (Coleoptera: curculionidae). Entomological Society of America. 101, 1960-1966.
  10. Li, J., Jain, M., Vunsh, R., Vishnevetsky, J., Hanania, U., Flaishman, M., Perl, A., Edelman, M. 2004. Callus induction and regeneration in Spirodela and Lemna. Plant Cell Rep. 22, 457-464.
  11. Mulquiney, P.J., Kuchel, P.W. Modeling Metabolism with Mathematica. CRC Press: 2003.
  12. Rajkumar, S., Jebanesan, A. 2009. Larvicidal and oviposition activity of Cassia obtusifolia Linn (Family: Leguminosae) leaf extract against malarial vector, Anopheles stephensi Liston (Diptera: Culicidae). Parasitol Res. 104, 337-340.
  13. Santos, H.S. Santiago, G.M.P., de Oliveria, J.P.P., Arriaga, A.M.C., Marques, DD., Lemos, T.L.G. 2007. NPC. 2, 1233-1236.
  14. Schneider, K., Hovel, K., Witzel, K., Hamberger, B., Schombur, D., Kombrink, E., Stuible, H.P. 2003. The substrate specificity-determining amino acid code of 4-coumarate:CoA ligase. PNAS. 100, 8601-8606.
  15. Stuible, H.P., Buttner, D., Ehlting, J., Hahlbrock, K., Kombrink, E. 2000. Mutational analysis of 4-coumarate:CoA ligase identifies functionally important amino acids and verifies its close relationship to other adenylate-forming enzymes. FEBS Letters. 467, 117-122.
  16. Williams, L.A.D., Porter, R.B., Junor, G.O. 2007. Biological activities of selected essential oils. NPC. 2, 1295-1296.
  17. Yamamoto, Y.T., Rajbhandari, N., Lin, X., Bergmann, B.A., Nishimura, Y., Stomp, A.M. 2000. Genetic transformation of duckweed Lemna Gibba and Lemna Minor. In Vitro Cell. Dev. Biol. 37. 349-353.
  18. Yun, M.S., Chen, W., Deng, F., Yogo, Y. 2005. Differential properties of 4-coumarate : CoA ligase related to growth suppression of chalcone in maize and rice. Plant Growth Regulation. 46, 169-176.
  19. Zhu, J., Zeng, X., Yanma, Liu, T., Qian, K., Han, Y., Xue, S., Tucker, B., Schultz, G., Coats, J., Rowley, W., Zhang, A. 2006. Adult repellency and larvicidal activity of five plant essential oils against mosquitoes. Jounral of the American Mosquito Control Association. 22, 515-522.
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