Golden Standard: a Complete Standard, Portable, and Interoperative MoClo Tool for Model and Non-model Proteobacteria

Overview

Journal Nucleic Acids Res

Publisher Oxford University Press

Specialty Biochemistry

Date 2023 Sep 18

PMID 37718823

Authors

Blas Blazquez

David San Leon

Jesus Torres-Bacete

Alvaro Gomez-Luengo

Ryan Kniewel

Igor Martinez

Sandra Sordon

Aleksandra Wilczak

Sergio Salgado

Ewa Huszcza

Jaroslaw Poplonski

Auxiliadora Prieto

Juan Nogales

Affiliations

Soon will be listed here.

Abstract

Modular cloning has become a benchmark technology in synthetic biology. However, a notable disparity exists between its remarkable development and the need for standardization to facilitate seamless interoperability among systems. The field is thus impeded by an overwhelming proliferation of organism-specific systems that frequently lack compatibility. To overcome these issues, we present Golden Standard (GS), a Type IIS assembly method underpinned by the Standard European Vector Architecture. GS unlocks modular cloning applications for most bacteria, and delivers combinatorial multi-part assembly to create genetic circuits of up to twenty transcription units (TUs). Reliance on MoClo syntax renders GS fully compatible with many existing tools and it sets the path towards efficient reusability of available part libraries and assembled TUs. GS was validated in terms of DNA assembly, portability, interoperability and phenotype engineering in α-, β-, γ- and δ-proteobacteria. Furthermore, we provide a computational pipeline for parts characterization that was used to assess the performance of GS parts. To promote community-driven development of GS, we provide a dedicated web-portal including a repository of parts, vectors, and Wizard and Setup tools that guide users in designing constructs. Overall, GS establishes an open, standardized framework propelling the progress of synthetic biology as a whole.

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