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Immunometabolic Circuits in Infection for Advancing Host Directed Therapies

作者: Shweta Khandibharad1, Shailza Singh1 1Systems Medicine Laboratory,Biotechnology Research and Innovation Council - National Centre for Cell Science (BRIC-NCCS)
简介:

Overview

This article presents a protocol for designing and delivering tetracycline-controlled inducible synthetic circuits. It explores the impact of these circuits on parasite elimination and cytokine expression, providing a valuable pipeline for researchers in synthetic circuit-based therapeutics for infectious diseases.

Key Study Components

Area of Science

  • Systems Biology
  • Synthetic Biology
  • Immunotherapy

Background

  • Exploration of immunometabolism in Leishmania major infection.
  • Potential of biosynthetic circuits for disease resolution.
  • Recent advancements in synthetic biology for Leishmaniasis treatment.
  • Engineering synthetic cytokines and CRISPR-Cas9 technologies.

Purpose of Study

  • To investigate the effects of synthetic circuits on both the host and parasite.
  • To develop innovative therapeutic strategies against Leishmaniasis.
  • To enhance understanding of host-parasite interactions.

Methods Used

  • Design and construction of synthetic circuits.
  • Delivery of tetracycline-controlled systems.
  • Assessment of cytokine expression.
  • Evaluation of parasite elimination efficacy.

Main Results

  • Demonstrated the modulation of host proteins by synthetic circuits.
  • Showed potential for improved therapeutic outcomes in Leishmaniasis.
  • Highlighted the dual impact on host and parasite dynamics.
  • Provided a novel approach to immunotherapeutics.

Conclusions

  • The protocol offers a framework for studying synthetic biology applications in infectious diseases.
  • Findings contribute to the development of targeted therapies.
  • Encourages further research into synthetic circuit technologies.

Frequently Asked Questions

What is the main focus of this study?
The study focuses on the design and application of synthetic circuits to enhance therapeutic strategies against Leishmaniasis.
How do synthetic circuits impact parasite elimination?
Synthetic circuits are engineered to modulate host responses, which can lead to enhanced elimination of parasites.
What are the potential applications of this research?
This research can lead to new immunotherapeutics and strategies for treating infectious diseases.
What technologies are being explored in this study?
Technologies include synthetic cytokines, CRISPR-Cas9, and synthetic peptides.
Why is immunometabolism important in this context?
Immunometabolism provides insights into how the immune system interacts with pathogens, influencing treatment strategies.
What is the significance of host-parasite interactions?
Understanding these interactions is crucial for developing effective therapies that target both the host and the parasite.

Here, a protocol for designing, constructing, and delivering tetracycline-controlled based inducible synthetic circuit is presented. The effect of the synthetic circuits on parasite elimination and cytokine expression can be studied by channelizing the presented pipeline. This protocol is relevant for researchers studying synthetic circuit-based therapeutics in infectious diseases.

标签: Immunometabolic Circuits,    Infection Therapy,    Host Directed Therapies,    Synthetic Biology,    Leishmania Major,    Biosynthetic Circuits,    Immunotherapeutics,    Synthetic Cytokines,    CRISPR-Cas9,    Synthetic Peptides,    Host Protein Modulation,    Orthogonality,    Modularity Function,    TinkerCell Software,    CMV Promoter,    Tetracycline Operator,    Genetic Components,    Succinate Dehydrogenase (SDHA),    Reporter Gene,    GFP,   
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