Project

Part:BBa_K5477051

Designed by: Kate Escobar and Victor Bay   Group: iGEM24_UCopenhagen   (2024-09-29)
Revision as of 17:44, 1 October 2024 by Kateesc1700 (Talk | contribs) (Results)


Team UCopenhagen 2024: Parts Collection of MilkClear

Introduction

Our parts collection is a comprehensive and innovative toolkit designed to address critical environmental and health challenges, specifically focusing on the detection and detoxification of harmful contaminants such as polycyclic aromatic hydrocarbons (PAHs), dioxins, polychlorinated biphenyls (PCBs), and bisphenol A (BPA) . Leveraging synthetic biology, our collection includes an array of receptor modules, reporter modules, and detoxification enzymes, enabling the development of highly specialized biosensor devices. These devices not only detect contaminants but also actively detoxify them, making our parts both practical and forward-thinking solutions to address contamination in breast milk.

The importance of developing a biosensor that not only detects but also actively detoxifies contaminants in breast milk cannot be overstated. While detection is a crucial first step in identifying harmful substances, it only highlights the problem without offering a direct solution. By integrating a detoxification system, we take this innovation a step further, enabling immediate action to neutralize and remove dangerous compounds such as bisphenol A (BPA), polycyclic aromatic hydrocarbons (PAHs), and dioxins. These contaminants are known for their endocrine-disrupting effects, which pose serious health risks to infants, who are particularly vulnerable during their developmental stages. Our dual-function device called SUPERMOM not only provides mothers with peace of mind by ensuring that harmful substances are identified but also guarantees a practical and efficient solution to detoxify the milk before it reaches the baby, ensuring that the nutritional and health benefits of breastfeeding are preserved. This combination of detection and detoxification offers a comprehensive approach to safeguarding infant health in an increasingly contaminated world, setting a new standard in maternal and infant care.


Our contribution to the iGEM community

We have designed and submitted a collection of modular, well-characterized parts to the iGEM community, significantly expanding the toolkit for environmental sensing and detoxification. These parts are fully compatible with existing iGEM standards, enabling teams to incorporate them into a wide range of projects. Below are the key ways we contribute to the iGEM community:

1. Biosensor Modules : Our parts include receptor modules, such as pRET2-LexA-ERα(LBD), which allow teams to detect endocrine-disrupting chemicals like BPA. These receptor modules are engineered to bind to specific contaminants and initiate a measurable reporter response, using constructs like Lex6Op-pLEU2-NanoLuc to output luminescence when contaminants are present. This system provides a ready-to-use platform for teams aiming to detect environmental pollutants.

2. Detoxification Systems: In addition to detection, we offer detoxification modules, such as CYP1A1-pGAL1/10-POR and UGT2B15, which metabolize and neutralize harmful compounds like BPA, PAHs, and dioxins. These parts are especially useful for projects aiming to create solutions that go beyond detection to actively remove toxins from the environment.

3. Modularity and Flexibility: All parts in our collection are designed with modularity in mind, enabling teams to mix and match receptor modules, reporter modules, and detoxification enzymes to create customized biosensor systems. This flexibility makes our collection an essential resource for any iGEM team working on environmental sensing, bioremediation, or public health projects.

4. Cross-Project Usability: Our parts collection is adaptable to various chassis and biological systems, from Saccharomyces cerevisiae to other eukaryotic and prokaryotic hosts. This cross-compatibility ensures that iGEM teams from different domains can easily integrate our parts into their work, providing a universal toolset for detecting and managing environmental contaminants.


Showcasing the Impact of our Parts Collection

By contributing with this collection of receptor, reporter, and detoxification modules, we provide the iGEM community with tools that not only enhance current biosensing capabilities but also empower future teams to build more advanced, multifunctional systems. The potential applications of our parts extend from environmental monitoring to public health, making this collection a significant step forward in the fight against pollution and harmful chemicals. Our work encourages the iGEM community to explore synthetic biology as a practical solution for real-world environmental challenges, ensuring the well-being of future generations.


Devices

The Devices Table outlines the different biosensor devices developed for the detection and detoxification of various environmental contaminants. Each device incorporates specific receptor modules and reporter modules, tailored to detect particular compounds like polycyclic aromatic hydrocarbons (PAHs), dioxins, polychlorinated biphenyls (PCBs), and bisphenol A (BPA). For instance, devices BBa_K5477041 and BBa_K5477042 are biosensors designed to detect PAHs, dioxins, or dioxin-like PCBs, while devices BBa_K5477043 to BBa_K5477045 are specialized for BPA detection. Additionally, BBa_K5477046 introduces the SUPERMOM device, which integrates both detection and detoxification modules to simultaneously identify and neutralize BPA in breast milk. The final device, BBa_K5477047, is a detoxification device targeting PAHs, dioxins, and PCBs through the use of CYP1A1 and UGT enzymes, which metabolize these contaminants into safer, water-soluble compounds. This array of devices demonstrates the versatility of the biosensor platform in addressing diverse environmental and health-related issues.


Part Name Part Type Function
BBa_K5477041 BBa_K5477023: pSTE12-AhR - receptor module, BBa_K5477025: pRET2-ARNT receptor module, BBa_K5477026: pRET2-NCOA - receptor module, BBa_K5477030: XRE-pMEL1-NanoLuc reporter module Device Biosensor device for detection of PAHs, dioxin or dioxin-like PCBs
BBa_K5477042 BBa_K5477024: pRAD27-AhR - receptor module, BBa_K5477025: pRET2-ARNT receptor module, BBa_K5477026: pRET2-NCOA - receptor module, BBa_K5477030: XRE-pMEL1-NanoLuc reporter module Device Biosensor device for detection of PAHs, dioxin or dioxin-like PCBs
BBa_K5477043 BBa_K5477027: pRET2-LexA-ERα(LBD) - receptor module, BBa_K5477031: Lex6Op-pLEU2-NanoLuc reporter module Device Biosensor device for detection of BPA
BBa_K5477044 BBa_K5477028: pPOP6-LexA-ERα(LBD) - receptor module, BBa_K5477031: Lex6Op-pLEU2-NanoLuc reporter module Device Biosensor device for detection of BPA
BBa_K5477045 BBa_K5477029: pRET2-LexA-mERα(LBD) - receptor module, BBa_K5477031: Lex6Op-pLEU2-NanoLuc reporter module Device Biosensor device for detection of BPA
BBa_K5477046 BBa_K5477029: pRET2-LexA-mERα(LBD) - receptor module, BBa_K5477031: Lex6Op-pLEU2-NanoLuc reporter module, BBa_K5477040:UDPD-pPDC1-Lex6Op-pENO1-UGT2B15 Device SUPERMOM: Dual-Function Biosensor for BPA Detection and Detoxification
BBa_K5477047 BBa_K5477037: CYP1A1-pGAL1/10-POR detox module, BBa_K5477036: UDPD-pGAL1/10-UGT1A1 detox module Device Detoxification device against PAH, dioxin and PCBs
BBa_K5477048 pRET2-LexA-mERα(LBD) - receptor module, BBa_K5477031: Lex6Op-pLEU2-NanoLuc reporter module, BBa_K5477039: CYP3A4-MYC-pPDC1-Lex6Op-pENO1-POR Device SUPERMOM: Dual-Function Biosensor for BPA and Pharmaceuticals' Detection and Detoxification


Results

Findings on the pRET2-mERα biosensor

The engineered mERα biosensor demonstrates significant potential for detecting a range of environmental contaminants, including BPA, PCB3, PAH (benzanthracene), and Aroclor 1260. Its performance varies depending on the specific compound and the environmental matrix, such as the presence of milk. Across the experiments, several key findings were observed for each contaminant below. For more details, visit documentation for this device BBa_K5477045:

1. Response to BPA: The mERα biosensor exhibited a stronger response to BPA compared to the ERα biosensor, demonstrating higher specificity and selectivity towards BPA. A visual estimation suggested an EC50 of around 6500 luminescence units, though further validation is required to confirm this. The mERα system was able to produce a clear response to BPA, but showed a plateau in luminescence beyond 10 nM.

2. Response to BPA in Milk: The mERα biosensor showed a significant decline in luminescence as the proportion of milk in the assay increased, particularly at higher milk fractions. The biosensor maintained functionality in diluted milk, although the signal declined sharply at certain concentrations (e.g., 1/64 milk dilution). This suggests that the milk matrix may interfere with detection by either affecting yeast viability or luminescence measurement.

3. Comparison with ERα Biosensor: mERα was more selective to BPA than ERα and showed reduced activation by estradiol, supporting its potential for use in complex environments like milk, where background estrogen could be an issue. Despite a higher response to estradiol compared to ERα, mERα's strong response to BPA still suggests low background interference in milk.

4. Promoter Optimization: When comparing different promoters, the pPOP6-ERα biosensor showed higher potency in detecting BPA compared to pRET2-mERα. The findings suggest that mERα could potentially perform better if expressed under the pPOP6 promoter, indicating an opportunity for further optimization.

5. Response to PCB3: The mERα biosensor displayed a quasi-linear response to PCB3 at lower concentrations (0-50 nM), with minimal variation between replicates. However, at higher concentrations (e.g., 5 µM), the response varied significantly, indicating that more experiments are required to establish a definitive dose-response curve.

6. Response to PAH: The mERα biosensor produced a strong response to benzanthracene, though the resulting dose-response curve lacked consistency due to high variability. This promising trend suggests that the biosensor can detect PAH, but further experimentation is needed to confirm its reliability.

7. Response to PAH in Milk: In the presence of milk, mERα's response to PAH decreased gradually as milk concentration increased. However, the signal was more stable compared to the BPA-milk experiments, with approximately a 50% reduction in signal intensity between water and milk fractions, suggesting that PAH detection is less affected by milk.

8. Response to Aroclor 1260: The mERα biosensor exhibited a dynamic range of 7000-11,500 luminescence units when detecting Aroclor 1260. However, the sensitivity within the tested concentration range was low, and the variation between replicates was high, making it difficult to draw definitive conclusions about the biosensor's effectiveness for Aroclor 1260 detection.

9. Response to Aroclor 1260 in Milk: The response of mERα to Aroclor 1260 in milk followed a step-like decline, with a sharp decrease in luminescence at higher milk fractions. This behavior was consistent with the other milk experiments, highlighting the significant influence of milk on biosensor performance. The variation in response patterns to different contaminants suggests that mERα's performance is context-dependent.


Composites

The Composites Table showcases the various composite parts that make up the functional modules of each biosensor device. Each composite part consists of a combination of promoters, receptors, or detoxification modules designed for specific detection or detoxification tasks. For example, BBa_K5477023 and BBa_K5477024 feature receptor modules tailored to detect PAHs, dioxins, and dioxin-like PCBs, while BBa_K5477027 and BBa_K5477028 are optimized for BPA detection through engineered estrogen receptor modules. Additionally, the composite parts BBa_K5477035 to BBa_K5477039 focus on detoxification, containing enzymes such as UGT2B15, UGT1A1, and CYP1A1 that metabolize harmful chemicals into less toxic or more easily excretable forms. These composite parts serve as the building blocks of the devices, providing the necessary functionality to detect and detoxify environmental contaminants.

Part Name Part Type Length (bp)
BBa_K5477023 pSTE12-AhR - receptor module Composite Promoter and Receptor for detection of PAHs, dioxin or dioxin-like PCBs 3117
BBa_K5477024 pRAD27-AhR - receptor module Composite Promoter and Receptor for detection of PAHs, dioxin or dioxin-like PCBs 1900
BBa_K5477025 pRET2-ARNT receptor module Composite Promoter and nuclear translocator detection of PAHs, dioxin or dioxin-like PCBs 2155
BBa_K5477026 pRET2-NCOA - receptor module Composite Promoter and nuclear receptor co-activator for the detection of PAHs, dioxin or dioxin-like PCBs 5032
BBa_K5477027 pRET2-LexA-ERα(LBD) - receptor module Composite Promoter and Receptor for detection of BPA 2389
BBa_K5477028 pPOP6-LexA-ERα(LBD) - receptor module Composite Promoter and Receptor for detection of BPA 2389
BBa_K5477029 pRET2-LexA-mERα(LBD) - receptor module Composite Promoter and Receptor for detection of BPA 2389
BBa_K5477030 XRE-pMEL1-NanoLuc - reporter module Composite A xenobiotic response element, a promoter, and a luciferase reporter gene for the detection signal against PCBs, dioxins, and dioxin-like compounds 868
BBa_K5477031 Lex6Op-pLEU2-NanoLuc reporter module Composite DNA-binding domain, promoter, and luciferase reporter gene for the detection signal against BPA 880
BBa_K5477035 UDPD-pGAL1/10-UGT2B15 Composite Detoxification module against BPA 3724
BBa_K5477036 UDPD-pGAL1/10-UGT1A1 Composite Detoxification module against PAHs, dioxin and PCBs 3726
BBa_K5477037 CYP1A1-pGAL1/10-POR Composite Detoxification module against PAHs, dioxin and PCBs 4312
BBa_K5477038 CYP3A4-pGAL1/10-POR Composite Detoxification module against a wide array of contaminants 4250
BBa_K5477039 CYP3A4-MYC-pGAL1/10-POR Composite Detoxification module against a wide array of contaminants 4286
BBa_K5477040 UDPD-pPDC1-Lex6Op-pENO1-UGT2B15 Composite Detoxification module for the detoxification of BPA 3631
BBa_K5477032 CYP3A4-MYC-pPDC1-Lex6Op-pENO1-POR Composite Detoxification module for BPA 4193

Results

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Parts

The Parts Table lists individual genetic components, including promoters, coding sequences (CDS), and regulatory elements, that make up the biosensor and detoxification systems. Promoters such as pRET2 and pSTE12 are used to drive constitutive or inducible expression of the receptor and detoxification modules, ensuring that the biosensors are responsive under the desired conditions. The table also includes various coding sequences for receptors like AhR, ARNT, and LexA-ERα, which are central to detecting endocrine disruptors like BPA and other toxic chemicals. Detoxification enzymes such as CYP1A1, UGT2B15, and CYP3A4 are also featured, responsible for metabolizing and neutralizing harmful substances. These individual parts allow the biosensors to be highly modular, enabling customization for different contaminants while maintaining efficiency and compatibility with standard assembly methods.


Part Name Part Type Length (bp)
BBa_K5477000 pRET2 - Medium strong constitutive promoter in Saccharomyces cerevisiae Regulatory (Promoter) 700
BBa_K5477001 pSTE12 - Constitutive promoter in Saccharomyces cerevisiae Regulatory (Promoter) 557
BBa_K5477002 pRAD27 - Weak constitutive promoter in Saccharomyces cerevisiae Regulatory (Promoter) 694
BBa_K5477003 pMEL1 - Constitutive core promoter in Saccharomyces cerevisiae Regulatory (Promoter) 256
BBa_K5477004 pLEU2 - Constitutive core promoter in Saccharomyces cerevisiae Regulatory (Promoter) 130
BBa_K5477005 pGAL1/10 - Bidirectional inducible promoters from Saccharomyces cerevisiae Regulatory (Promoter) 664
BBa_K5477006 pPDC1-Lex6Op-pENO1 - Bidirectional synthetic promoters with Lex6Op Regulatory (Promoter) 571
BBa_K5477007 pPOP6 - Weak constitutive promoter in Saccharomyces cerevisiae Regulatory (Promoter) 700
BBa_K5477008 XRE - Xenobiotic Response Element Regulatory Binding Element 82
BBa_K5477009 Lex6Op - six tandem copies of LexA operator Regulatory Binding Element 220
BBa_K3793004 AhR - Aryl hydrocarbon Receptor CDS - receptor 2547
BBa_K3793005 ARNT - Aryl hydrocarbon Nuclear Transporter CDS - receptor 2370
BBa_K1680009 NanoLuc - NanoLuciferase reporter gene CDS - Reporter gene 516
BBa_K5477012 NCOA - Nuclear receptor coactivator CDS - receptor 4326
BBa_K5477013 LexA-ERα chimeric activator CDS - receptor 1683
BBa_K5477014 LexA-mERα chimeric activator CDS - receptor 1683
BBa_K5477015 LexA-ERRγ chimeric activator CDS - receptor 1602
BBa_K5477016 UGT2B15 CDS - enzyme 1593
BBa_K5477017 UGT1A1 CDS - enzyme 1602
BBa_K5477018 UDPD CDS - enzyme 1446
BBa_K5477019 CYP1A1 CDS - receptor 1575
BBa_K5477020 CYP3A4 CDS - enzyme 1512
BBa_K5477021 CYP3A4-MYC CDS - enzyme 1548
BBa_K5477022 POR CDS - enzyme 2061


Results

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