Team:Colombia/Project

From 2014.igem.org

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<h4>Cholerae</h4>
<h4>Cholerae</h4>
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Cholera has been a scourge to civilizations the world over since ancient times. According to the World Health Organization’s estimates, there are 3-5 million cholera cases and 100,000-120,000 deaths every year worldwide. Caused by the bacterial pathogen <p><i>Vibrio cholerae</p></i>, the disease has been responsible for seven global pandemics in recorded history, plus countless localized outbreaks (World Health Organization, 2014). These outbreaks are triggered by <p><i>V. cholerae</p></i> when present in water sources or food even at very small cell densities, and can have devastating effects, with mortality rates reaching up to an alarming 50% and causing death in a matter of hours if left untreated (Public Health Vigilance Group, 2011). The disease is most prevalent in low-income populations with inadequate health services and water management infrastructure (Public Health Vigilance Group, 2011). Although no cases have been confirmed in Colombia for a decade, some of the greatest risk factors are widespread across the country’s rural–and even urban–areas (Public Health Vigilance Group, 2011). Proof of this vulnerability is the impact generated by the arrival of the deadly El Tor <p><i>V. cholerae  strain in 1991, which caused 30,000 cholera cases in two years.
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Cholera has been a scourge to civilizations the world over since ancient times. According to the World Health Organization’s estimates, there are 3-5 million cholera cases and 100,000-120,000 deaths every year worldwide. Caused by the bacterial pathogen <i>Vibrio cholerae</i>, the disease has been responsible for seven global pandemics in recorded history, plus countless localized outbreaks (World Health Organization, 2014). These outbreaks are triggered by <i>V. cholerae</i> when present in water sources or food even at very small cell densities, and can have devastating effects, with mortality rates reaching up to an alarming 50% and causing death in a matter of hours if left untreated (Public Health Vigilance Group, 2011). The disease is most prevalent in low-income populations with inadequate health services and water management infrastructure (Public Health Vigilance Group, 2011). Although no cases have been confirmed in Colombia for a decade, some of the greatest risk factors are widespread across the country’s rural–and even urban–areas (Public Health Vigilance Group, 2011). Proof of this vulnerability is the impact generated by the arrival of the deadly El Tor <i>V. cholerae</i> strain in 1991, which caused 30,000 cholera cases in two years.
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Due to the disease’s alarmingly quick onset upon infection and the fact that rapid access to medical care is often not available in affected areas, prevention is a key factor in combating cholera. Careful monitoring of water sources and food stocks in areas of potential contamination is vital, especially during outbreaks. In spite of this need, there currently is no cost-effective way of detecting <p><i>V. cholerae</p></i> easily in environmental samples (Wang et al., 2010). The most effective ways of detecting the pathogen are culturing environmental samples in selective enrichment media in the lab and real-time PCR, which require a lab, trained personnel, and enough time to grow cultures. Rapid detection systems such as immunomagnetic beads or DNA probe hybridization can be unspecific and are based on molecular techniques that can be expensive or difficult to use (Wang et al., 2010). Recent research in environmental cholera detection has focused on improving upon existing techniques, such as adapting immunochromatographic dipstick tests used for stool samples (Chakraborty et al., 2013). Although there have been interesting synthetic biology projects aimed at preventing V. cholerae infection by meddling with the pathogen’s quorum sensing mechanism (Duan & March, 2010), there have been no attempts to build an environmental cholera biosensor using synthetic biology to date.  
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Due to the disease’s alarmingly quick onset upon infection and the fact that rapid access to medical care is often not available in affected areas, prevention is a key factor in combating cholera. Careful monitoring of water sources and food stocks in areas of potential contamination is vital, especially during outbreaks. In spite of this need, there currently is no cost-effective way of detecting <i>V. cholerae</i> easily in environmental samples (Wang et al., 2010). The most effective ways of detecting the pathogen are culturing environmental samples in selective enrichment media in the lab and real-time PCR, which require a lab, trained personnel, and enough time to grow cultures. Rapid detection systems such as immunomagnetic beads or DNA probe hybridization can be unspecific and are based on molecular techniques that can be expensive or difficult to use (Wang et al., 2010). Recent research in environmental cholera detection has focused on improving upon existing techniques, such as adapting immunochromatographic dipstick tests used for stool samples (Chakraborty et al., 2013). Although there have been interesting synthetic biology projects aimed at preventing <i>V. cholerae</i> infection by meddling with the pathogen’s quorum sensing mechanism (Duan & March, 2010), there have been no attempts to build an environmental cholera biosensor using synthetic biology to date.  
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In light of this, our project aims to use synthetic biology to develop a <p><i>V. cholerae</p></i> sensor using a new technique. Instead of trying to detect the cholerae toxin, specific sequences of nucleic acid, or antigens, we propose detecting V. cholerae Autoinducer 1 (CAI-1), the bacteria’s species-specific quorum sensing molecule. If we rewire V. cholerae’s own quorum sensing mechanism –used in nature to gauge population levels and regulate pathogenicity– in a harmless E. coli chassis, we can build a cheap and easy-to-use biosensor that gives a color output when it senses the pathogen. This prototype can serve as a proof-of-concept for future quorum sensing-based pathogen biosensors.
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In light of this, our project aims to use synthetic biology to develop a <i>V. cholerae</i> sensor using a new technique. Instead of trying to detect the cholerae toxin, specific sequences of nucleic acid, or antigens, we propose detecting V. cholerae Autoinducer 1 (CAI-1), the bacteria’s species-specific quorum sensing molecule. If we rewire V. cholerae’s own quorum sensing mechanism –used in nature to gauge population levels and regulate pathogenicity– in a harmless <i>E. coli</i> chassis, we can build a cheap and easy-to-use biosensor that gives a color output when it senses the pathogen. This prototype can serve as a proof-of-concept for future quorum sensing-based pathogen biosensors.
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Revision as of 21:48, 15 August 2014

Example.jpg


Cholerae

Cholera has been a scourge to civilizations the world over since ancient times. According to the World Health Organization’s estimates, there are 3-5 million cholera cases and 100,000-120,000 deaths every year worldwide. Caused by the bacterial pathogen Vibrio cholerae, the disease has been responsible for seven global pandemics in recorded history, plus countless localized outbreaks (World Health Organization, 2014). These outbreaks are triggered by V. cholerae when present in water sources or food even at very small cell densities, and can have devastating effects, with mortality rates reaching up to an alarming 50% and causing death in a matter of hours if left untreated (Public Health Vigilance Group, 2011). The disease is most prevalent in low-income populations with inadequate health services and water management infrastructure (Public Health Vigilance Group, 2011). Although no cases have been confirmed in Colombia for a decade, some of the greatest risk factors are widespread across the country’s rural–and even urban–areas (Public Health Vigilance Group, 2011). Proof of this vulnerability is the impact generated by the arrival of the deadly El Tor V. cholerae strain in 1991, which caused 30,000 cholera cases in two years.

Due to the disease’s alarmingly quick onset upon infection and the fact that rapid access to medical care is often not available in affected areas, prevention is a key factor in combating cholera. Careful monitoring of water sources and food stocks in areas of potential contamination is vital, especially during outbreaks. In spite of this need, there currently is no cost-effective way of detecting V. cholerae easily in environmental samples (Wang et al., 2010). The most effective ways of detecting the pathogen are culturing environmental samples in selective enrichment media in the lab and real-time PCR, which require a lab, trained personnel, and enough time to grow cultures. Rapid detection systems such as immunomagnetic beads or DNA probe hybridization can be unspecific and are based on molecular techniques that can be expensive or difficult to use (Wang et al., 2010). Recent research in environmental cholera detection has focused on improving upon existing techniques, such as adapting immunochromatographic dipstick tests used for stool samples (Chakraborty et al., 2013). Although there have been interesting synthetic biology projects aimed at preventing V. cholerae infection by meddling with the pathogen’s quorum sensing mechanism (Duan & March, 2010), there have been no attempts to build an environmental cholera biosensor using synthetic biology to date.

In light of this, our project aims to use synthetic biology to develop a V. cholerae sensor using a new technique. Instead of trying to detect the cholerae toxin, specific sequences of nucleic acid, or antigens, we propose detecting V. cholerae Autoinducer 1 (CAI-1), the bacteria’s species-specific quorum sensing molecule. If we rewire V. cholerae’s own quorum sensing mechanism –used in nature to gauge population levels and regulate pathogenicity– in a harmless E. coli chassis, we can build a cheap and easy-to-use biosensor that gives a color output when it senses the pathogen. This prototype can serve as a proof-of-concept for future quorum sensing-based pathogen biosensors.

Design: Project Parts!

Glucocorticoid sensor

Our construct

lalalalalalalala

The Chassis

Lalalalalalala

Titulo

Lalalalalalalalalalala

Examplo.jpg
  1. Lalalalalalalalalala.

Results




References

  1. Chakraborty, S., Alam, M., Scobie, H. M., & Sack, D. A. (2013). Adaptation of a simple dipstick test for detection of Vibrio cholerae O1 and O139 in environmental water. Frontiers in microbiology, 4.


  2. Duan, F., & March, J. C. (2010). Engineered bacterial communication prevents Vibrio cholerae virulence in an infant mouse model. Proceedings of the National Academy of Sciences, 107(25), 11260-11264.


  3. Public Health Vigilance Group. (2011) Plan de contingencia del sector salud para la prevención y control de cólera en Colombia [Health sector contingency plan for the prevention and control of cholera in Colombia]. Ministry of Social Protection, Republic of Colombia. Accessed 8 june 2014 from


  4. Wang, D., Xu, X., Deng, X., Chen, C., Li, B., Tan, H., ... & Kan, B. (2010). Detection of Vibrio cholerae O1 and O139 in environmental water samples by an immunofluorescent-aggregation assay. Applied and environmental microbiology, 76(16), 5520-5525.


  5. World Health Organization. (2014) Cholera: Fact sheet No. 107. Media Center Fact Sheets. Retrieved 8 june 2014 from .