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The ability to precisely engineerAgrobacteriumstrains is crucial for advancing their utility in plant biotechnology. We recently implemented the CRISPR RNA-guided transposase system, INTEGRATE, as an efficient tool for genetic modification inAgrobacterium. Despite its promise, the practical application of INTEGRATE inAgrobacteriumstrain engineering remains underexplored. Here, we present a standardized and optimized workflow that enables researchers to harness INTEGRATE for targeted genome modifications. By addressing common challenges, such as crRNA design, transformation efficiency, and vector eviction, this protocol expands the genetic toolkit available forAgrobacterium, facilitating both functional genomics and strain development for plant transformation. As a demonstration, we domesticatedAgrobacterium rhizogenesK599 strain by deleting the 15-kb T-DNA region from its root-inducing plasmid pRi2659 and inactivating a thymidylate synthase gene to render the strain auxotrophic for thymidine. The protocol provides detailed guidance for each step, including target site selection, crRNA spacer cloning,Agrobacteriumtransformation, screening for targeted insertion and Cre/loxP-mediated deletion, and vector removal. This resource will empower new users to perform efficient and reproducible genome engineering inAgrobacteriumusing the INTEGRATE system, paving the way for broader adoption and innovation in plant biotechnology. 

Chromosome architecture plays a crucial role in bacterial adaptation, yet its direct impact remains unclear. Different bacterial species and even strains within the same species exhibit diverse chromosomal configurations, including a single circular or linear chromosome, two circular chromosomes, or a circular-linear combination. To investigate how these architectures shape bacterial behavior, we generated near-isogenic strains representing each configuration inAgrobacterium tumefaciensC58, an important soil bacterium widely used for plant genetic transformation. Strains with a single-chromosome architecture, whether linear or circular, exhibited faster growth, enhanced stress tolerance, and greater interstrain competitiveness. In contrast, bipartite chromosome strains showed higher virulence gene expression and enhanced transient plant transformation efficiency, suggesting a pathogenic adaptation. Whole-transcriptome analysis revealed architecture-dependent gene expression patterns, underscoring the profound impact of chromosome organization onAgrobacteriumfitness and virulence. These findings highlight how chromosome structure influences bacterial adaptation and shapes evolutionary trajectories. 

Agrobacterium-mediated transformation is an essential tool for functional genomics studies and crop improvements. Recently developed ternary vector systems, which consist of a T-DNA vector and a compatible virulence (vir) gene helper plasmid (ternary helper), demonstrated that including an additionalvirgene helper plasmid into disarmedAgrobacteriumstrains significantly improves T-DNA delivery efficiency, enhancing plant transformation. Here, we report the development of a new ternary helper and thymidine auxotrophicAgrobacteriumstrains to boostAgrobacterium-mediated plant transformation efficiency. AuxotrophicAgrobacteriumstrains are useful in reducingAgrobacteriumovergrowth after the co-cultivation period because they can be easily removed from the explants due to their dependence on essential nutrient supplementation. We generated thymidine auxotrophic strains from publicAgrobacteriumstrains EHA101, EHA105, EHA105D, and LBA4404. These strains exhibited thymidine-dependent growth in the bacterial medium, and transientGUSexpression assay using Arabidopsis seedlings showed that they retain similar T-DNA transfer capability as their original strains. Auxotrophic strains EHA105Thy- and LBA4404T1 were tested for maize B104 immature embryo transformation using our rapid transformation method, and both strains demonstrated comparable transformation frequencies to the control strain LBA4404Thy-. In addition, our new ternary helper pKL2299A, which carries thevirAgene from pTiBo542 in addition to othervirgene operons (virG,virB,virC,virD,virE, andvirJ), demonstrated consistently improved maize B104 immature embryo transformation frequencies compared to the original version of pKL2299 (33.3% vs 25.6%, respectively). Therefore, our improvedAgrobacteriumsystem, including auxotrophic disarmedAgrobacteriumstrains and a new ternary helper plasmid, can be useful for enhancing plant transformation and genome editing applications. 

Summary Agrobacterium tumefaciens, the causal agent of plant crown gall disease, has been widely used to genetically transform many plant species. The inter‐kingdom gene transfer capability madeAgrobacteriuman essential tool and model system to study the mechanism of exporting and integrating a segment of bacterial DNA into the plant genome. However, many biological processes such asAgrobacterium‐host recognition and interaction are still elusive. To accelerate the understanding of this important plant pathogen and further improve its capacity in plant genetic engineering, we adopted a CRISPR RNA‐guided integrase system forAgrobacteriumgenome engineering. In this work, we demonstrate thatINsertion ofTransposableElements byGuideRNA–AssistedTargEting (INTEGRATE) can efficiently generate DNA insertions to enable targeted gene knockouts. In addition, in conjunction with Cre‐loxPrecombination system, we achieved precise deletions of large DNA fragments. This work provides new genetic engineering strategies forAgrobacteriumspecies and their gene functional analyses.