OriCiro® Cell-Free Cloning System/PASS V4.1.2 v1

OriCiro® Cell-Free Cloning System is a rapid and powerful tool replacing cumbersome DNA cloning (plasmid construction) process relying on E. coli. The system consists of two kits. OriCiro Assembly Kit allows seamless assembly of multiple overlapping DNA fragments. The assembly product can be added directly to OriCiro Amp Kit to get selective amplification of your target circular DNA (Figure 1). The amplified product is supercoiled DNA topologically identical to plasmid DNA isolated from E. coli. 1. OriCiro Assembly Kit: Multiple DNA fragments are assembled seamlessly at 42 ̊C for 30 minutes via ~40 bp overlapping ends (Figure 2). DNA fragments generated by PCR or restriction enzyme digestion are available. Our unique enzyme-based annealing mechanism allows powerful assembly up to 50 fragments simultaneously. 2. OriCiro Amp Kit: The reaction consists of 26 purified enzymes involved in chromosome replication of E. coli. The chromosome replication cycle repeats autonomously at around 30 ̊C, enabling exponential amplification of circular DNA having oriC with extremely high fidelity (10-8 error/base/cycle) (Figure 3). The kit yields up to 1 μg circular DNA per 10 μL reaction at 33 ̊C for 6 hr. The maximum amplification size is 50 kb in the current version of the kit. n.b. OriCiro Amp NEEDS oriC Cassette (0.4 kb) which can be inserted into circular DNA using OriCiro assembly kit. References: 1. T. Mukai, T. Yoneji, K. Yamada, H. Fujita, S. Nara, M. Su'etsugu, Overcoming the Challenges of Megabase-Sized Plasmid Construction in Escherichia coli, ACS Synthetic Biology, 2020, 9 (6), 1315- 1327 2. T. Hasebe, K. Narita, S. Hidaka, M. Su'etsugu, Efficient Arrangement of the Replication Fork Trap for In Vitro Propagation of Monomeric Circular DNA in the Chromosome-Replication Cycle Reaction. Life, 2018, 8 (43) 3. M. Su’etsugu, H. Takada, T. Katayama, H. Tsujimoto, Exponential propagation of large circular DNA by reconstitution of a chromosome-replication cycle, Nucleic Acids Research, 2017, 45 (20), 11525– 11534

Komagataeibacter tool kit (KTK): a modular cloning system for multigene constructs and programmed protein secretion from cellulose producing bacteria

Bacteria proficient at producing cellulose are an attractive synthetic biology host for the emerging field of Engineered Living Materials (ELMs). Species from the Komagataeibacter genus produce high yields of pure cellulose materials in a short time with minimal resources, and pioneering work has shown that genetic engineering in these strains is possible and can be used to modify the material and its production. To accelerate synthetic biology progress in these bacteria, we introduce here the Komagataeibacter tool kit (KTK), a standardised modular cloning system based on Golden Gate DNA assembly that allows DNA parts to be combined to build complex multigene constructs expressed in bacteria from plasmids. Working in Komagataeibacter rhaeticus, we describe basic parts for this system, including promoters, fusion tags and reporter proteins, before showcasing how the assembly system enables more complex designs. Specifically, we use KTK cloning to reformat the Escherichia coli curli amyloid fibre system for functional expression in K. rhaeticus, and go on to modify it as a system for programming protein secretion from the cellulose producing bacteria. With this toolkit, we aim to accelerate modular synthetic biology in these bacteria, and enable more rapid progress in the emerging ELMs community.

A GoldenBraid cloning system for synthetic biology in social amoebae

GoldenBraid is a rapid, modular, and robust cloning system used to assemble and combine genetic elements. Dictyostelium amoebae represent an intriguing synthetic biological chassis with tractable applications in development, chemotaxis, bacteria–host interactions, and allorecognition. We present GoldenBraid as a synthetic biological framework for Dictyostelium, including a library of 250 DNA parts and assemblies and a proof-of-concept strain that illustrates cAMP-chemotaxis with four fluorescent reporters coded by one plasmid.