Recombination-based DNA assembly and mutagenesis methods for metabolic engineering.

In recent years there has been a growing interest in the precise and concerted assembly of multiple DNA fragments of diverse sizes, including chromosomes, and the fine tuning of gene expression levels and protein activity. Commercial DNA assembly solutions have not been conceived to support the cloning of very large or very small genetic elements or a combination of both. Here we summarize a series of protocols that allow the seamless, simultaneous, flexible, and highly efficient assembly of DNA elements of a wide range of sizes (up to hundred thousand base pairs). The protocols harness the power of homologous recombination and are performed either in vitro or within the living cells. The DNA fragments may or may not share homology at their ends. An efficient site-directed mutagenesis protocol enhanced by homologous recombination is also described.

Genetic assembly tools for synthetic biology.

With the completion of myriad genome sequencing projects, genetic bioengineering has expanded into many applications including the integrated analysis of complex pathways, the construction of new biological parts and the redesign of existing, natural biological systems. All these areas require the precise and concerted assembly of multiple DNA fragments of various sizes, including chromosomes, and the fine-tuning of gene expression levels and protein activity. Current commercial cloning products are not robust enough to support the assembly of very large or very small genetic elements or a combination of both. In addition, current strategies are not flexible enough to allow further modifications to the original design without having to undergo complicated cloning strategies. Here, we present a set of protocols that allow the seamless, simultaneous, flexible, and highly efficient assembly of genetic material, designed for a wide size dynamic range (10s to 100,000s base pairs). The assembly can be performed either in vitro or within the living cells and the DNA fragments may or may not share homology at their ends. A novel site-directed mutagenesis approach enhanced by in vitro recombineering is also presented.

A dynamic RecA filament permits DNA polymerase-catalyzed extension of the invading strand in recombination intermediates.

Recombination-dependent replication is an essential housekeeping function in prokaryotes and eukaryotes, serving, for example, to restart DNA replication after the repair of a double-strand break. Little is known about the interplay between the recombination and replication machinery when recombination intermediates are used as substrates for DNA replication. We show here that recombination intermediates formed between linear duplex and supercoiled plasmid DNAs are substrates for a generalized strand displacement DNA synthesis reaction in which the 3'-OH of the invading strand in the recombination intermediate is used as a primer. DNA synthesis is driven by negative superhelicity and is inhibited if disassembly of the RecA filament is prevented. Thus, assembly and disassembly of RecA filaments in the same direction facilitates filament clearance from the 3'-end of the invading strand, allowing DNA synthesis to occur from recombination intermediates.

PriA mediates DNA replication pathway choice at recombination intermediates.

We report the reconstitution of the initial steps of the double-strand break-repair pathway where joint molecule formation between a duplex DNA fragment and a circular template by the combined action of RecA, RecBCD, and the single-stranded DNA binding protein provides the substrate for replication fork formation by the restart primosome and the DNA polymerase III holoenzyme. We show that PriA dictates the pathway of replication from the recombination intermediate by inhibiting a nonspecific, strand displacement DNA synthesis reaction and favoring the formation of a bona fide replication fork. Furthermore, we find that RecO and RecR significantly stimulate this recombination-directed DNA replication reaction, and that this stimulation is modulated by the presence of RecF, suggesting that the latter protein may also act as a regulator of the pathway of resolution of the recombination intermediate.