Orthogonal Serine Integrases Enable Scalable Gene Storage Cascades in Bacterial Genome.

Genome integration enables host organisms to stably carry heterologous DNA messages, introducing new genotypes and phenotypes for expanded applications. While several genome integration approaches have been reported, a scalable tool for DNA message storage within site-specific genome landing pads is still lacking. Here, we introduce an iterative genome integration method utilizing orthogonal serine integrases, enabling the stable storage of multiple heterologous genes in the chromosome of Escherichia coli MG1655. By leveraging serine integrases TP901-1, Bxb1, and PhiC31, along with engineered integration vectors, we demonstrate high-efficiency, marker-free integration of DNA fragments up to 13 kb in length. To further simplify the procedure, we then develop a streamlined integration method and showcase the system's versatility by constructing an engineered E. coli strain capable of storing and expressing multiple genes from diverse species. Additionally, we illustrate the potential utility of these engineered strains for synthetic biology applications, including in vivo and in vitro protein expression. Our work extends the application scope of serine integrases for scalable gene integration cascades, with implications for genome manipulation and gene storage applications in synthetic biology.