Difference between revisions of "Team:UrbanTundra Edmonton/Description"

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<h5 style="font-size: 24px;">Sustainable Living on Mars: Remediation of Martian Soil to Produce Oxygen</h5>
 
<h5 style="font-size: 24px;">Sustainable Living on Mars: Remediation of Martian Soil to Produce Oxygen</h5>
  
<p>In 2008, the Phoenix Mars Lander detected perchlorate (ClO4⁻) in Martian regolith at a concentration of 0.5% - 1.0%, up to 10 000 times higher than that on Earth. Perchlorate is a chemical anion that has adverse health effects on humans, rendering Martian soil unfarmable and posing a challenge to any future pursuits at colonization. The main sources of exposure to perchlorate on Mars would be through the inhalation of dust and the ingestion of contaminated food/water. Once it enters the body, its primary target is the thyroid gland, which regulates the body’s metabolism. ClO4⁻ directly competes with the uptake of iodine ions by the thyroid, leading to decreased hormonal output, slowed metabolism, and the hindered function of many organ systems. If colonization on Mars is to be made possible, detoxifying the soil of perchlorate is a necessity.
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<p>In 2008, the Phoenix Mars Lander detected perchlorate (ClO4⁻) in Martian regolith at a concentration of 0.5% - 1.0%, up to 10 000 times higher than that on Earth. Perchlorate is a chemical anion that has adverse health effects on humans, rendering Martian soil inarable and posing a challenge to any future pursuits at colonization. The main sources of exposure to perchlorate on Mars would be through the inhalation of dust and the ingestion of contaminated food/water. Once it enters the body, its primary target is the thyroid gland, which regulates the body’s metabolism. ClO4⁻ directly competes with the uptake of iodine ions by the thyroid, leading to decreased hormonal output, slowed metabolism, and the hindered function of many organ systems. If colonization on Mars is to be made possible, detoxifying the soil of perchlorate is a necessity.
 
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<p>We want to design an efficient metabolic pathway for the breakdown of perchlorate to produce oxygen by inserting the genes for these enzymes into E. coli, one of the fastest growing bacteria on Earth.  
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<h5 style="font-size: 24px;">Ideonella dechloratans</h5>
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<p>Ideonella dechloratans, one of the many perchlorate reducing microorganisms, is the species in which we focused our investigations on. I. dechloratans utilizes two enzymes, Perchlorate Reductase (Pcr) and Chlorite Dismutase (Cld), to convert perchlorate ions to chloride ions and oxygen gas (http://aem.asm.org/content/78/12/4380.full). As of now, only Cld has been successfully expressed by other scientists. Throughout the summer, we focused on taking the latter half of this perchlorate reducing pathway, the one involving Chlorite Dismutase, and transforming it into E. coli to explore its effectiveness towards the biodegradation of martian perchlorate as an effective tool for oxygen production.
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<h5 style="font-size: 24px;">Our Goal</h5>
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<p>we want to show that Chlorite Dismutase, when expressed in an E. coli chassis, is functional regarding the conversion of chlorite ions into both oxygen gas and chloride ions. This project is essentially a proof of concept, which shows the viability that a
 
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<h5>Our Goal</h5>
 
<h5>Our Goal</h5>
  
<p>The purpose of this project is to show that Chlorite Dismutase can be expressed by E. coli and that it is enzymatic action can produce oxygen gas. Our ultimate aim is to show that this solution is a viable option for future colonization initiatives on Mars as a proof of concept.  
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<p>The purpose of this project is to show that Chlorite Dismutase can be expressed by E. coli and that it is enzymatic action can produce oxygen gas. Our ultimate aim is to show that this solution based on synthetic biology is a viable option for future colonization initiatives on Mars as a proof of concept.  
 
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Revision as of 02:13, 19 October 2016


Urban Tundra | Intelligent Innovation

Background

Sustainable Living on Mars: Remediation of Martian Soil to Produce Oxygen

In 2008, the Phoenix Mars Lander detected perchlorate (ClO4⁻) in Martian regolith at a concentration of 0.5% - 1.0%, up to 10 000 times higher than that on Earth. Perchlorate is a chemical anion that has adverse health effects on humans, rendering Martian soil inarable and posing a challenge to any future pursuits at colonization. The main sources of exposure to perchlorate on Mars would be through the inhalation of dust and the ingestion of contaminated food/water. Once it enters the body, its primary target is the thyroid gland, which regulates the body’s metabolism. ClO4⁻ directly competes with the uptake of iodine ions by the thyroid, leading to decreased hormonal output, slowed metabolism, and the hindered function of many organ systems. If colonization on Mars is to be made possible, detoxifying the soil of perchlorate is a necessity.

When we dug deeper, we stumbled on the work of Davila et al [1]who proposed that the toxic concentration of ClO4⁻in Martian soil was actually a resource that could be exploited both as a source of rocket fuel and O2, while remediating the soil in the process. It can be broken down further into perchlorite (ClO2⁻), chlorine (Cl-), and oxygen (O2) using two already sequenced enzymes, perchlorate reductase and chlorite dismutase.

Ideonella dechloratans

Ideonella dechloratans, one of the many perchlorate reducing microorganisms, is the species in which we focused our investigations on. I. dechloratans utilizes two enzymes, Perchlorate Reductase (Pcr) and Chlorite Dismutase (Cld), to convert perchlorate ions to chloride ions and oxygen gas (http://aem.asm.org/content/78/12/4380.full). As of now, only Cld has been successfully expressed by other scientists. Throughout the summer, we focused on taking the latter half of this perchlorate reducing pathway, the one involving Chlorite Dismutase, and transforming it into E. coli to explore its effectiveness towards the biodegradation of martian perchlorate as an effective tool for oxygen production.

Our Goal

we want to show that Chlorite Dismutase, when expressed in an E. coli chassis, is functional regarding the conversion of chlorite ions into both oxygen gas and chloride ions. This project is essentially a proof of concept, which shows the viability that a

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<img src="http://moneyinc.com/wp-content/uploads/2016/06/Mars.jpg">

Sustainable Living on Mars: Remediation of Martian Soil to Produce Oxygen
Perchlorate on Mars

In 2008, the Phoenix Mars Lander detected perchlorate (ClO4⁻) in Martian regolith at a concentration of 0.5% - 1.0%, up to 10 000 times higher than that on Earth. Perchlorate is a chemical anion that has adverse health effects on humans, rendering Martian soil inarable and posing a challenge to any future pursuits at colonization. The main sources of exposure to perchlorate on Mars would be through the inhalation of dust and the ingestion of contaminated food/water. Once it enters the body, its primary target is the thyroid gland, which regulates the body’s metabolism. ClO4⁻ directly competes with the uptake of iodine ions by the thyroid, leading to decreased hormonal output, slowed metabolism, and the hindered function of many organ systems. If colonization on Mars is to be made possible, detoxifying the soil of perchlorate is a necessity.

When we dug deeper, we stumbled on the work of Davila et al <a href = "https://www.researchgate.net/publication/242525435_Perchlorate_on_Mars_A_chemical_hazard_and_a_resource_for_humans">[1]</a>who proposed that the toxic concentration of ClO4⁻in Martian soil was actually a resource that could be exploited both as a source of rocket fuel and O2, while remediating the soil in the process. It can be broken down further into perchlorite (ClO2⁻), chlorine (Cl-), and oxygen (O2) using two already sequenced enzymes, perchlorate reductase and chlorite dismutase.

Ideonella dechloratans

Ideonella dechloratans, one of the many perchlorate reducing microorganisms, is the species in which we focused our investigations on. I. dechloratans utilizes two enzymes, Perchlorate Reductase (Pcr) and Chlorite Dismutase (Cld), to convert perchlorate ions to chloride ions and oxygen gas (http://aem.asm.org/content/78/12/4380.full). I. dechloratans actually has a negative feedback loop which limits the amount of oxygen produced, when the bacteria's required quantities are met. As of now, only Cld has been successfully expressed by other scientists. Throughout the summer, we focused on taking the latter half of this perchlorate reducing pathway, the one involving Chlorite Dismutase, and transforming it into E. coli to explore its effectiveness towards the biodegradation of martian perchlorate as an effective tool for oxygen production. <p>

Our Goal

<p>The purpose of this project is to show that Chlorite Dismutase can be expressed by E. coli and that it is enzymatic action can produce oxygen gas. Our ultimate aim is to show that this solution based on synthetic biology is a viable option for future colonization initiatives on Mars as a proof of concept.

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