Difference between revisions of "Part:BBa K5477048"

Revision as of 11:11, 30 September 2024

Testing of the SUPERMOM Concept

Summary

This system provides the ability to detect and detoxify endocrine-disrupting chemicals (EDCs), with a particular focus on BPA and related compounds, by utilizing a sophisticated combination of ligand detection, signal transduction, and enzymatic detoxification.

1.) Ligand Detection: The receptor module (pRET2-LexA-mERα(LBD)) contains a mutant Estrogen Receptor Alpha (mERα), specifically modified to detect and bind to BPA and similar ligands. Once BPA binds, the receptor undergoes a conformational change, enabling transcriptional activation of the downstream modules.

2.) Signal Transduction: The activated LexA-mERα(LBD) fusion protein then binds to the Lex6Op operator sequences in the reporter module (Lex6Op-pLEU2-NanoLuc), triggering the expression of NanoLuc luciferase, which produces a bioluminescent signal. This signal provides a quantitative and real-time indication of ligand binding and detection.

3.) Detoxification: Concurrently, the Lex6Op sequences also control the detoxification module (CYP3A4-MYC-pGAL1/10-POR), which is responsible for metabolizing BPA or related EDCs. CYP3A4, in conjunction with POR (NADPH-cytochrome P450 reductase), functions to oxidize and detoxify the harmful compounds, converting them into less toxic or more readily excretable metabolites.

Usage and Biology

Usage and Biology

In this biosensor system, the combination of a mutant ERα receptor module, a reporter module, and a detoxification system provides a robust setup for detecting and detoxifying estrogen-like compounds, particularly bisphenol A (BPA). The integration of these modules allows for ligand detection, signal transduction, and metabolic detoxification all within a single yeast-based system.

Why BPA?

Detecting BPA (bisphenol A) in breast milk is important due to the potential health risks it poses to infants. BPA is an endocrine-disrupting chemical commonly found in plastics and can leach into food and liquids, including breast milk. Even at low levels, BPA can interfere with the hormonal systems of infants, potentially affecting their development, reproductive health, and neurological function. Infants are particularly vulnerable to BPA exposure because their bodies are still developing and they may not be able to effectively metabolize and eliminate the chemical. Monitoring BPA levels in breast milk helps ensure the safety and well-being of infants during this critical developmental period.

This figure illustrates the SUPERMOM biosensor in the absence of BPA. 1) In the absence of BPA, the LexA-mERα (LBD) complex remains bound to HSP90 in the cytoplasm, preventing its translocation into the nucleus. 2) No signal is generated as the complex does not reach the nucleus to bind with Lex60p. 3) Additionally, without the presence of BPA, no detoxification process (glucuronidation) occurs, and thus no BPA Glucuronide is produced.

Below is a figure of the whole device consisting of our composites.

Receptor Module

pRET2-LexA-mERα(LBD) | BBa_K5477029: This receptor module includes the pRET2 promoter, driving the expression of a LexA-mERα(LBD) fusion protein. The LexA DNA-binding domain (DBD) is fused to the ligand-binding domain (LBD) of a mutant Estrogen Receptor Alpha (mERα), which is engineered to exhibit high specificity towards BPA and related compounds. Upon ligand binding, the LexA-mERα(LBD) fusion protein undergoes a conformational shift, enabling it to bind to Lex6Op sequences in the reporter and detox modules, thus initiating the transcriptional response.

Reporter Module

Lex6Op-pLEU2-NanoLuc | BBa_K5477031: The reporter module contains Lex6Op operator sequences, which serve as binding sites for the activated LexA-mERα(LBD) protein. Binding of LexA to these sequences activates the pLEU2 promoter, leading to the expression of NanoLuc luciferase. NanoLuc, a highly efficient luciferase, emits bioluminescence in the presence of its substrate. The intensity of this signal correlates directly with the concentration of the ligand (BPA or similar compounds) bound to the mERα receptor, enabling real-time detection.

Detoxification Module

CYP3A4-MYC-pGAL1/10-POR | BBa_K5477039: The detoxification module incorporates the cytochrome P450 enzyme CYP3A4, which plays a key role in the oxidative metabolism of various EDCs, including BPA. CYP3A4 is regulated by the pGAL1/10 bidirectional promoter and is fused with a MYC tag for detection. The co-expression of NADPH-cytochrome P450 reductase (POR), driven by the same promoter, ensures efficient electron transfer to CYP3A4, facilitating its catalytic activity. This module enables the oxidation and detoxification of BPA, converting it into more hydrophilic and excretable metabolites, reducing its harmful effects.

Sequence and Features