Talk:Team:GenetiX Tec CCM

From 2014hs.igem.org

Revision as of 02:40, 21 June 2014 by Heroghost (Talk | contribs)

GenetiX

Welcome to our wiki

We are high school students at Tecnológico de Monterrey, Mexico City Campus, a team with juniors and seniors working together. What made us a team was our passion for science, we all wanted to innovate, to create, to surprise and engine something useful. Our goal is to prove that if you plan on doing something, no matter what, you can achieve it with the right focus.

Biodetection of Anoxia in Lake Xochimilco

Lake Xochimilco in Mexico City faces a condition of extreme pollution which endangers the endemic species; many of which are nearing extinction. Oxygen levels depletion in the lake directly affect the fauna, making it less hospitable or even deadly. Our goal is to produce a biosensor that can easily and inexpensively detect anoxia in different regions of the lake. Using an oxygen promoter in addition with the biological markers RFP and GFP we could theoretically detect low dissolved oxygen levels in water samples. In addition, we intend to use a second construct with an Iron promoter to detect iron concentrations that also endanger the sustainability of living organisms in the lake. Once we identify critical regions of the Lake, our report could incentivize the Civil Council and authorities to propose concrete legal initiatives to reduce pollution in the identified areas and start remediation campaigns.

Contents

The Project

banner image

The main idea of our project is to achieve the detection of anoxia and Iron concentrations in water systems. What we propose is to construct an easy way of monitoring the levels of O2 and Fe in the lake by using biosensors. By using modified bacteria E. coli for this, we will try to find a cheaper, easier, and faster way to detect the problem of anoxia and iron concentration in some aquifers of Mexico City. We will have to analyze samples of water at different depths to know where the problem is worse and what probable native species could be more affected.


Our purpose is the identification of adequate dissolved oxygen levels for a stable support of life and the identification of iron concentration below threatening levels in order to know if the lake has the physical and chemical properties to support wild-life naturally. With the use of biosensors, specialized for detecting concentrations of oxygen above a 2% dissolution, we used modified E. coli with an oxygen promoter (BBa_K258005) that will detect the low concentrations and a reporter of (GFP or RFP) that will indicate the activation of our promoter (Figure 1). The Iron promoter reacts inside an environment with a concentration of iron ranging from 1 ppm and on (A. Quintero,2007). The acceptable levels of iron in drinkable water are lower than 0.5 ppm (WHO, 1996).

To achieve the objective using E. Coli we will construct different types of modified plasmids for our bacteria to express the biosensors based on iGem biobricks. The idea is to use sensitive promoters: one for oxygen, and another one for iron; those promoters will lead to an expression of GFP or mRFP. This will provide a visual signal to indicate the presence or absence of these elements. Biobrick parts BBa_K258005 (O₂ prom), BBa_I765000 (Fe prom), BBa_E1010 (GFP) and BBa_J04650 (mRFP) were selected for the construction of the biosensors (Figure 2). These were transformed into E. coli strands DH5-a, TOP 10, and NEB 10-b for storage and subsequent plasmid growth and isolation using a Zymo Research® DNA extraction kit.

Once we measure and identify critical regions of the Lake, our report could go directly to the Citizen Council for its consideration. The competent authorities should be able to propose concrete legal initiatives to reduce pollution in the identified areas and start remediation campaigns that re-establish the local aquatic environment to a stable, liveable, friendly ecosystem for the inhabitant species.

Biosensor

banner image

A biosensor is an instrument for the measurement of biological or chemical parameters. They usually combine biological and physical-chemical components.


Generally, they consist of three parts:

  • The biological sensor: It may be a tissue, a culture of microorganisms, enzymes, antibodies, nucleic acid chains, etc. The sensor can be taken from the wild or be a product of synthetic biology.
  • The transducer: Its function is to bind the other two elements and translate the signal emitted by the sensor.
  • The detector: It can be optical, piezoelectric, thermal, magnetic, etc.

The most common example is a biosensor that measures blood glucose. It uses an enzyme that processes glucose molecules, releasing an electron for each molecule. Said electron is collected at one electrode and the electron flow is used as a measure of the glucose concentration.


The caged canaries used by miners to detect the presence of lethal gases can be seen as an early example of biosensors (Wikipedia, 2014)


By using modified bacteria E. coli for this, we will try to find a cheaper, easier, and faster way to detect the problem of anoxia and heavy metals in some aquifers of Mexico City. We will have to analyze samples of water at different depths to know where the problem is worse and what probable native species could be more affected.


Some of the benefits of using biosensors instead of other sensing methods, as observed by Ajit Sadana and AzoSensors, are:

  • A fast response in time.
  • Fast and continuous measurement.
  • High specificity because of its shape-specific recognition.
  • Simplicity in its use.
  • Capability of measuring concentrations ranging from 10-18 to 10-19 M, so we need low sample requirements.
  • Capability of real time measurements.

Eutrophication

banner image

Eutrophication is the process by which the increased availability of one or more limiting growth factors needed for photosynthesis cause excessive plant and algal growth. Some of these factors are the amount of carbon dioxide, sunlight and nutrient fertilizers. The elements coming from the nutrient fertilizers that especially affect the photosynthesis rate are nitrogen and phosphorus. (Chislock , 2013)
Plants require many different nutrients or components for the realization of photosynthesis. Nitrogen and phosphorus are the first components depleted in the water even though there is a greater amount of other needed substances.  While performing photosynthesis about 8 times more nitrogen is needed than phosphorus. Thus, phosphorus limits eutrophication if nitrogen is more than 8 times abundant as phosphorus, while nitrogen is the limiting factor when its concentration is less than 8 times abundant as phosphorus. Erosion of surrounding areas is also an important cause of eutrophication because the nutrients of the ground are not retained by the roots of plants and trees that should be there. So deforestation is an environmental element that strongly affects this process.  (UNEP, 1)
The process of eutrophication of an aquifer occurs naturally over centuries as they are filled with sediments, abundant in nutrients (figure 1). However, this process has been recently much accelerated due to the contamination produced by human activities. The discharges into aquatic systems bring a lot of limiting nutrients for eutrophication, including nitrogen and phosphorus. These polluting human residues thrown up into water systems come from point and non-point pollution sources. (Chislock, 2013)


Figure 1. Natural eutrophication

     The term “point source” is referred to as any single, discernible source from where the polluting agent is originated, such as a discharge pipe from a factory, sewage plant. The other term “non-point source” means that the pollution does not come from a single determinate source. This type of pollution happens when water moves across the land and pick in its way human-made pollutants that can be deposited later on in water bodies. (Harvey, 1)    
There are different levels of eutrophication according to how severe or advanced the process is. The first and harmless classification of eutrophication is the oligotrophic, where there is a low concentration of nutrients in the water and thus less biologic production. Then we have the mesotrophic where there are intermediate levels of nutrient concentrations and there is a moderate biologic production that doesn´t affect severely the aquatic environment. The real problem begins when we get to the eutrophic level where there is an elevated concentration of nutrients and a very high biologic productivity.  Another classification is reserved for where the nutrient levels reach extremely dangerous concentrations that take the aquifer´s condition to a critical state; it is called hypertrophic and is almost always caused by the cultural eutrophication. An important indicator for the eutrophication level is chlorophyll. The total amount of chlorophyll represents about 1% of plant biomass, so in this way the total biomass can be estimated allowing the determination of the degree of eutrophication. (Mazzeo, 1)

Table expressing the characteristic values for each of the eutrophication classifications. (UNEP)
Eutrophication brings a lot of complications to aquifers. The enormous creation of dense blooms of noxious, foul-smelling phytoplankton reduces water clarity and harms water clarity. These blooms limit light penetration to the water body. This limiting of sunlight to littoral zones causes the die-offs of the great amount of plants and algae that grew up without control due to eutrophication. When these dense algal blooms eventually die, microorganisms start the decomposition of organic matter and severely deplete the available dissolved oxygen, causing hypoxia or even anoxia. These hypoxic environments are cause of dead zones for most of the inhabiting organisms for the lacking oxygen. (Chislock 2013)
The normal levels of dissolved oxygen in water for the maintenance of life are around 6mg/L. Environments are considered hypoxic when the concentration of dissolved oxygen goes below 2.8 mg/L. When the dissolved oxygen levels reach the hypoxic condition many species die. Depending on the size and other characteristics of the organisms, the limiting concentration for survival will have low variations. The hypoxic conditions can change in different lapses of time. They can occur just for a few moments (minutes/hours) or they can reach chronic states that last for weeks or even months, causing depletion of local species. (Cisterna 2008)
It is important to supervise aquatic environments conditions´ to prevent the initiation of eutrophic conditions. Eutrophication can kill all life in natural environments. If some symptoms of eutrophication are detected in time it is possible to attack the problem and control it, or even eliminate it. Some methods for controlling eutrophication are:

  • Covering sediments, preventing release of nutrients.
  • Biomanipulation
  • Using chemicals such as copper sulfate to kill excess of algae
  • Aerating the hypolimnion of a lake, reducing the release of nutrients from the sediments.

(UNEP)

Localization

banner image

First of all, we have to know what eutrophication is, well the  eutrophication is the process of excessive growth of algae and weeds water in the water, caused by phosphates and other pollutants discharged to waters. In a eutrophic aquatic ecosystem two things happen: more oxygen is required to break down and increases the population of organisms known as primary producers: organisms that make photosynthesis, as macroalgae and lilies. These can reach atrophy processes exchange of oxygen and water flow. The liquid is cloudy and the lack of oxygen can devastate populations of various organisms.

How does it affect the lake of Xochimilco?

In hydrological Xochimilco area that is located south of the metropolitan area of ​​Mexico City's 189 miles of canals that have been contaminated by the contribution of sewage, domestic waste, industrial, agricultural and drainage system leaks. This has affected different species of living beings that inhabit the area, causing a decline in biodiversity (Juárez-Figueroa et al., 2003).

It is estimated that close to urban centers or agricultural nutrient input to a lake can be accelerated by the activities human, a process known as cultural eutrophication, which is the case with Lake Xochimilco to be within the city of Mexico. This is precisely effluent mainly caused by plants sewage treatment, containing nitrates and phosphates runoff of fertilizers and waste animals and accelerated erosion of eutrophication .The eutrophication derived from crops by the recent addition of phosphates and nitrates, as a result of activities human, it is also a serious problem for lakes, especially Lake Xochimilco. During warm periods, the overhead produce dense growth nutrient vegetables such as algae, cyanobacteria, water lilies and duckweed. Oxygen dissolved in the surface layer of water is near die exhausted when large masses of algae, which fall to the bottom and are decomposed by aerobic bacteria. This can kill fish and other animals water they consume oxygen. If theexcess nutrients continue to flow a body of water, the water reaches the bottom be rotten and almost unusable for living things, because bacteria take over and produce anaerobic decomposing substances with poor odors, such as hydrogen sulfide and the methane.

Factors

The factors affecting the degree of eutrophication are:

  • Climate: warm climates favor the process.
  • Shallow bodies of water and / or low flow are more conducive to the development process
  •  Drainage Area: little tree cover subject to abundant rainfall tions favors erosion and entrainment of nutrients into the water body
  •  Geology: In drainage areas where sedimentary rocks predominate vapor no greater phosphorus runoff. Clay soils drain poorly and also favor runoff and result in nutrient supply.


The causes of eutrophication include:

a) Natural:

  •  atmospheric inputs: precipitation.
  •  resuspension of bottom sediments.
  •  release from anoxic sediments.
  •  breakdown and excretion of organisms.
  •  nitrogen-fixing microorganisms.

b) Anthropogenic:

  •  Discharges of industrial, agricultural, municipal and waste treatment plants.
  •  Deforestation increases erosion and reduces the recycling of nutrients in the watershed, increasing their income to the water body.
  • Fertilizer applied in excess.
  • Sewage farms (silos, drums).
  • Septic tanks.
  • Detergents with large amounts of phosphorus.
  • Contribution of pollutants from rainwater.
  • Sewer system of cities and towns do.
  • Measures to control eutrophication include:


Control of nutrient inputs:

  • Waste treatment before being poured into the body of water.
  • Restricting the use of phosphate detergents.
  • Control of land use.
  • Prepantanos: remove nutrients from waste water that are fixed in the biomass of algae and macrophytes.
  • Physical and chemical  waste water treatment: chemical precipitation and filtration.

What we found....

Elements found in the lake of Xochimilco

Sample 1 2 3 4 5 6 7 8
MO mg/LO 154 251 88 151 555 295 25 75
Phosphorus mg/L 5.8 5.6 7.6 6.7 23.0 17.1 15.0 14.2
pH 6.2 7.2 6.7 7.6 8.0 7.0 7.0 7.0
Temperature °C 3.8 3.8 4.8 3.8 6.9 7.0 7.0 7.0
Precipitation 21.0 20.0 22.0 23.0 21.5 19.8 21.0 54

Results

banner image

Construction of the proposed biosensors was not completed successfully due to what appear to be flawed ligations and/or low efficiency competent cells. The necessary methodology and procedures have been laid down for further work on construction, development and improvement of the biosensor system in the future. Further work include the completion of the biosensors, proof of concept growing bacteria in absence and presence of stimuli and application of biosensors to a range of samples from specific points distributed all along Xochimilco lake. Results of these tests could be then applied in the construction a map of the lake specifying the most critical points that need to be treated.

Figure 1. The agarose gel shows the unsuccesful ligations, represented on the right.

Human Practices

Travesuras 2014

banner image

GenetiX, as a student group, participated in the event Travesuras 2014, which had place the 26 of April 2014 inside the installations of Tecnologico de Monterrey, Campus Ciudad de Mexico. The GenetiX station was located in the high-school chemistry laboratory where 4 groups attended, composed around of 25 children each, with ages that ranged between 7 and 16 years. Inside the station there were nine of our members present involving children into science in a fun and enriching way for them. These experiments included de polymerization of “Slime” with color and “Silly Putty”.


Before initiating the experiment, a quick explanation of the process of polymerization was given. For the polymerization of the Slime, the kids had the opportunity of adding in plastic cups 10mL of polyvinyl alcohol and 3 mL of a borax solution in addition with a drop of colorant. Later, the children agitated the mixture with wooden sticks until it took the slimy consistence expected. This procedure was made in groups of between 2 and 3 kids who shared the slime.


A polymerization of the silly putty was made in the same way in which the slime was made. In this case, 10 mL of white glue (which contains the polyvinyl acetate) and 20 mL of saturated borax solution. The children agitated the mixture until it obtained the desired consistency. Later, they were able to play with it also in groups of 2 or 3 children. All the experiments were supervised by the members of GenetiX in order to prevent any accident and solve further doubts from the children regarding the experiment.


Finally a DNA demonstration took place. For such, a banana was cut into pieces and got liquefied in a blender with distilled water and 2.5 gr of NaCl. It was liquefied until a dense liquid was achieved and then poured into a coffee filter inside a glass flask. We left the mixture in filtration for about 10 min until the flask was half-full. Afterwards 5ml of liquid soap was added to the pulp in order to break the cell walls and membranes and free the DNA. Also 3 gr of meat tenderizer and another 3 grs of sodium bicarbonate were added into the mixture. Once the ingredients were added, the sufficient amount of cold ethanol was added in order to form a thin layer above the banana mixture. Since the DNA is insoluble in ethanol, a whitish layer appears above the banana mixture. Once the process ended, the final mixture was shown to the children and a brief explanation of what DNA is was given.

Travesuras 2013

banner image

GenetiX firstly participated in the Christmas themed Travesuras 2013. In this event, kids from other schools raging from Elementary schools to Middle Schools attended to be part of various activities made by us, students from the Tecnologico de Monterrey, surrounding the topic of Christmas.

We were mostly involved in helping prepare the decoration of the main stations. Some of the activities that we participated in was the making of cardboard spheres and decoration of said materials, including decorations such as Christmas trees, hanging colored paper in patterns and the working tables as well.

We also helped to cover the floor for decoration and prevent further stains in the real floor. We were tasked with watching and guarding the kids during the whole event and also to entertain them.

Conference

banner image

As part of our Human Practices, on June 14th 2014, we gave a presentation for students and teachers from Tecnológico de Monterrey, Colegio Lestonnac and other Middle School and High School level institutes. As students and teachers who are interested in Science were invited, their participation was very dynamic. There, we explained basic concepts of Synthetic Biology and Biotechnology to the audience.


Our main topic was Synthetic Biology and its present and future applications. But, in order to transmit our message clearly, we had to start from the basics; that is why, one of our contents (the first one to be presented), were the characteristics of living beings. In this point, we stated that a living being has complex and organized systems, have a metabolism, need to maintain homeostasis, can grow, can reproduce, respond to stimuli, and are adaptable.


We gave the definition of Synthetic Biology as the design and construction of biological parts, devices or systems, or the re-designing of existent natural biological systems in order for them to be useful, and we also explained the techniques for the creation of synthetic organisms, such as acceleration of heavy particles, electroporation or heat shock.  In order to complement the concepts, we presented some examples of synthetic organisms and their functions, such as water pollution-absorbing plants, trees that change their color in case of a chemical attack and goats that can produce spider web.


Afterwards, we explained our participation in the iGEM contest, described our project to the audience (who found it interesting and useful) and performed an experiment which consisted in extracting DNA from bananas to stimulate their scientific curiosity.

Data

Safety

 

Important Definition:

Biohazard: An agent of biological origin that has the capacity to produce deleterious effects on humans, i.e. microorganisms, toxins and allergens derived from those organisms; and allergens and toxins derived from higher plants and animals.

Biosafety: The containment principles, technologies and practices that are implemented to prevent the unintentional exposure to pathogens and toxins, or their accidental release

Biosecurity: Control of accidental and deliberate release of biohazardous material

Safety Questions.

  1. Would any of your project ideas raise safety issues in terms of
    1. Researcher Safety: All team members had to participate in a general health and safety induction, where we learned handling biological material, aspects on chemicals, guidance in waste disposal of sharps, trace chemicals, and biohazardous material and the general protocols of the lab we work in. At all times while working in the lab, we were supervised by our advisor, part of the High school Science Department, or lab technician from the university’s School of Life Sciences Laboratory.
      The lab we work in is classified as BSL 1 (biosafety level 1), according to the European Union Directive 2000/54/EG. Work inside a BSL 1 lab does not involve the use of potentially harmful materials to the researchers if they act corresponding to the general precautionary measures. Researcher should wear a lab coat, safety glasses and gloves and one must not drink, eat or smoke whilst working at the bench. The safety degree of the worn protection should depend on the chemicals and microorganisms handled. An important example is handling antibiotics and DNA coloring agents with gloves and safety googles. Most importantly, everybody should always be aware of what he is doing, with what kind of biological parts and chemicals he is working and how to handle them safely.
    2. Public Safety: We used different bacterial strains throughout our project. E. coli 10 beta, Top 10 and DH5 alpha; which are non-toxicogenic, disabled, non-pathogenic, non-colonising, laboratory-adapted K12 strains, which are widely used in research and present no hazard to human health.
  1. Environmental Safety:

In the lab, waste must be contained in a biohazard box with an autoclavable biohazard bag. Liquids must be inactivated either via chemical methods (e.g., with bleach) or using an autoclave. Solids that have been in contact with biohazardous materials should also be treated by autoclaving and then transfered into a different bag to indicate that the waste has been deactivated. Broken glass and needles should be disposed in a sharps container. Full and sealed sharps containers can be added to solid waste.

References:
Chart, et al (2000). An investigation into the pathogenic properties of Escherichia coli strains BLR, BL21, DH5a and EQ1. Journal of Applied Microbiology, 89, 1048-1058. URL: http://ors.uchc.edu/bio/resources/pdf/3.6.1.A_colipath.pdf
Escherichia coli K-12 Derivatives Final Risk Assessment. Biotechnology Program under the Toxic Substances Control Act (TSCA). URL: http://epa.gov/biotech_rule/pubs/fra/fra004.htm

  1. Do any of the new BioBrick parts (or devices) that you made this year raise safety issues?
  2. Did you document these issues in the Registry?
  3. How did you manage to handle the safety issue?
  4. How could other teams learn from your experience?

No extra safety issues were detected during the construction of our biosensor.  The secondary ecological consequences will have to be assessed once the system is applied.

  1. Is there a local biosafety group, committee, or review board at your institution?

What does your local biosafety group think about your project?
The school has a person in charge of Health and Safety for each of the Laboratories. The technician was in constant contact with the team, supervising that the rules were being followed.
We also adhered to our countries legislation in the Chamber of Deputies (the Law of Biosecurity for Genetically Modified Organisms, Nueva Ley DOF-18-03-2005 http://www.diputados.gob.mx/LeyesBiblio/pdf/LBOGM.pdf), the SAGARPA and the Law of Science and Technology from CONACyT.

  1. Do you have any other ideas how to deal with safety issues that could be useful for future iGEM competitions? How could parts, devices and systems be made even safer through biosafety engineering?

In the assembly and distribution kit the iGem could include safety equipment such as a Laboratory Health and Safety Manual, gloves and googles samples. In the case of our project, we could include two resistance markers so the bacteria, if accidentally released, had less probability of subsisting.

Notebook

 

Biobricks

The Team

Members

Sponsors