Site-specific Recombination Research Articles

Assay for Site-Specific Homologous Recombination Activity in Adherent Cells, Suspension Cells, and Tumor Tissues.

Homologous recombination (HR) is a major pathway to repair DNA double-strand breaks. Hereditary breast and ovarian cancer syndrome (HBOC) is caused by germline pathogenic variants of HR-related genes, such as BRCA1 and BRCA2 (BRCA1/2). Cancer cells with HR deficiency are sensitive to poly(ADP-ribose) polymerase (PARP) inhibitors. Therefore, accurate evaluation of HR activity is helpful to diagnose HBOC and predict the effects of PARP inhibitors. The direct-repeat GFP (DR-GFP) assay has been utilized to evaluate cellular HR activity. However, evaluation by the DR-GFP assay tends to be qualitative and requires the establishment of stable cell lines. Therefore, we developed an assay to quantitatively measure HR activity called Assay for Site-Specific HR Activity (ASHRA), which can be performed by transiently transfecting two plasmids. In ASHRA, we use Cas9 endonuclease to create DNA double-strand breaks at specific sites in the genome, enabling the targeting of any endogenous loci. Quantification of HR products by real-time PCR using genomic DNA allows HR activity evaluated at the DNA level. Thus, ASHRA is an easy and quantitative method to evaluate HR activity at any genomic locus in various samples. Here, we present the protocols for adherent cells, suspension cells, and tumor tissues. Key features • This assay quantitatively evaluates homologous recombination (HR) activity. • This assay can measure HR activity in adherent cells, suspension cells, and tumor tissues. • This real-time PCR-based assay does not require a flow cytometer or next-generation sequencer.

There and turn back again: the application of phage serine integrases in eukaryotic systems.

Serine integrases (Ints) have gained prominence and have been extensively used in Synthetic Biology due to their ability to modify DNA sequences. Ints are recombinases encoded by the phage genome and have been used to unidirectionally catalyze an insertion, excision, or inversion of a specific DNA sequence between the two attachment sites (att) attB (bacterial attachment site) and attP (phage attachment site). The entire process is highly specific and accurate; therefore, Ints are widely used in genetic engineering and have been extensively studied due to their unique site-specific recombination properties and potential genome editing applications. Furthermore, new recombinational factors (RDFs) and their determinants are constantly being discovered, underlining the need to update progress in research involving Ints in eukaryotic cells. In this way, this review aims to provide an overview of Ints in eukaryotic cells and highlight how Ints can be used in innovative ways to advance genetic engineering applications in health, agriculture, and environmental sciences.

Creation of a eukaryotic multiplexed site-specific inversion system and its application for metabolic engineering

The site-specific recombination system is a versatile tool in genome engineering, enabling controlled DNA inversion or deletion at specific sites to generate genetic diversity. The multiplexed inversion system, which preferentially facilitates inversion at reverse-oriented sites rather than deletion at same-oriented sites, has not been found in eukaryotes. Here, we establish a multiplexed site-specific inversion system, Rci51-5/multi-sfxa101, in yeast. Firstly, we develop a high-throughput screening system based on the on/off transcriptional control of multiple markers by DNA inversion. After two rounds of progressively stringent directed evolution, a mutant Rci51-5 shows an ability of multisite inversion and a ~ 1000-fold increase in total inversion efficiency against the wild-type Rci derived from Salmonella typhimurium. Subsequently, we demonstrate that the Rci51-5/multi-sfxa101 system exhibits significantly lower deletion rate than the Cre/multi-loxP system. Using the synthetic metabolic pathway of β-carotene as an example, we illustrate that the system can effectively facilitate promoter substitution in the metabolic pathway, resulting in a more than 7-fold increase in the yield of β-carotene. In summary, we develop a multiplexed site-specific inversion system in eukaryotes, providing an approach to metabolic engineering and a tool for eukaryotic genome manipulation.

Chromosomal domain formation by archaeal SMC, a roadblock protein, and DNA structure

In eukaryotes, structural maintenance of chromosomes (SMC) complexes form topologically associating domains (TADs) by extruding DNA loops and being stalled by roadblock proteins. It remains unclear whether a similar mechanism of domain formation exists in prokaryotes. Using high-resolution chromosome conformation capture sequencing, we show that an archaeal homolog of the bacterial Smc-ScpAB complex organizes the genome of Thermococcus kodakarensis into TAD-like domains. We find that TrmBL2, a nucleoid-associated protein that forms a stiff nucleoprotein filament, stalls the T. kodakarensis SMC complex and establishes a boundary at the site-specific recombination site dif. TrmBL2 stalls the SMC complex at tens of additional non-boundary loci with lower efficiency. Intriguingly, the stalling efficiency is correlated with structural properties of underlying DNA sequences. Our study illuminates a eukaryotic-like mechanism of domain formation in archaea and a role of intrinsic DNA structure in large-scale genome organization.

SCRaMbLE: a versatile tool for genome manipulation.

Genomic rearrangements play an important role in shaping genetic diversity, as they enable the generation of novel structural variations through specific genome manipulation tools. These variations contribute to phenotypic differences among individuals within a population, thereby serving as the foundation for natural selection and driving evolutionary processes. In recent years, Synthetic Chromosome Rearrangement and Modification by LoxP-mediated Evolution (SCRaMbLE) has emerged as a promising tool for studying genomic rearrangements. SCRaMbLE utilizes site-specific recombination mediated by loxPsym sites to induce targeted chromosomal rearrangements in yeast cells. In this review, we provide a comprehensive overview of recent advancements in optimization strategies of the SCRaMbLE system and discuss influential factors that affect its performance based on recent research findings. We demonstrate how the SCRaMbLE system can be employed for pathway engineering, phenotype improvement, genome minimization, and dissection of genotype-to-phenotype relationships. We highlight both the advantages and challenges associated with SCRaMbLE and envision its potential applications beyond yeast genetics.

Structural basis of directionality control in large serine integrases.

Large serine integrases (LSIs) catalyze unidirectional site-specific DNA recombination reactions, yet those reactions are reversed by the presence of a cognate recombination directionality factor (RDF). Mechanistic understanding of directionality control has been hampered by a lack of structural information. Here, we use cryo-electron microscopy (cryo-EM) to determine the structures of six SPbeta integrase-DNA complexes along the integrative (-RDF) and excisive (+RDF) reaction pathways, at 4.16-7.18Å resolution. Our findings reveal how RDF-mediated repositioning of an integrase subdomain (1) dictates which pairs of DNA sites can be assembled into a synaptic complex to initiate recombination and (2) dictates which product complexes will be conformationally locked, preventing the back reaction. These mechanistic insights provide a conceptual framework for engineering efficient and versatile genome editing tools.

Interplay between the Xer recombination system and the dissemination of antibioresistance in Acinetobacter baumannii.

Antibiotic-resistant infections are a pressing clinical challenge. Plasmids are known to accelerate the emergence of resistance by facilitating horizontal gene transfer of antibiotic resistance genes between bacteria. We explore this question in Acinetobacter baumannii, a globally emerging nosocomial pathogen responsible for a wide range of infections with a worrying accumulation of resistance, particularly involving plasmids. In this species, plasmids of the Rep_3 family harbor antibiotic resistance genes within variable regions flanked by potential site-specific recombination sites recognized by the XerCD recombinase. We first show that the Xer system of A. baumannii functions as described in Escherichia coli, resolving chromosome dimers at the dif site and recombining plasmid-carried sites. However, the multiple Xer recombination sites found in Rep_3 plasmids do not allow excision of plasmid fragments. Rather, they recombine to cointegrate plasmids, which could then evolve to exchange genes. Cointegrates represent a significant fraction of the plasmid population and their formation is controlled by the sequence of recombination sites, which determines the compatibility between recombination sites. We conclude that plasmids in A. baumannii frequently recombine by Xer recombination, allowing a high level of yet controlled plasticity in the acquisition and combination of antibiotic resistance genes.

Heterologous Production of Phenazines in the Biocontrol Agent Lysobacter enzymogenes C3.

Lysobacter enzymogenes, an environmental bacterium, holds promise as a biocontrol agent due to its ability to produce bioactive compounds effective against plant pathogens, such as fungi, oomycetes, and Gram-positive bacteria. However, it lacks activity against Gram-negative bacteria. To address this, we applied new genetic tools to manipulate the phenazine biosynthetic gene cluster (LaPhz) from L. antibioticus, converting L. enzymogenes to a robust producer of phenazine antibiotics. Through transcriptomics, we identified potent promoters and constructed the first ΦC31-mediated site-specific recombination system for Lysobacter. Engineered strains C3-cophz and C3-phz retained the ability to produce antifungal/antioomycete and anti-Gram-positive compounds while also synthesizing the well-known phenazine antibiotics such as phenazine dicarboxylic acid and phenazine carboxylic acid, along with new derivatives 1,6-dimethoxyphenazine and 1-hydroxy-6-methoxyphenazine-N10-oxide. These strains demonstrated potent activity against Gram-negative bacteria, showing promise for the development of versatile biopesticides. The new tools will facilitate the exploration of silent biosynthetic gene clusters in Lysobacter genomes.

Direct observation of subunit rotation during DNA strand exchange by serine recombinases

Serine recombinases are proposed to catalyse site-specific recombination by a unique mechanism called subunit rotation. Cutting and rejoining DNA occurs within an intermediate synaptic complex comprising a recombinase tetramer bound to two DNA sites. After double-strand cleavage at both sites, one half of the complex rotates 180° relative to the other, before re-ligation of the DNA ends. We used single-molecule FRET (smFRET) methods to provide compelling direct physical evidence for subunit rotation by recombinases Tn3 resolvase and Sin. Synaptic complexes containing fluorescently labelled DNA show FRET fluctuations consistent with the subunit rotation model. FRET changes were associated with the rotation steps, on a timescale of 0.4–1.1 s−1\\documentclass[12pt]{minimal} \\usepackage{amsmath} \\usepackage{wasysym} \\usepackage{amsfonts} \\usepackage{amssymb} \\usepackage{amsbsy} \\usepackage{mathrsfs} \\usepackage{upgreek} \\setlength{\\oddsidemargin}{-69pt} \\begin{document}$${{\\mbox{s}}}^{-1}$$\\end{document}, as well as opening and closing of the gap between the scissile phosphates during cleavage and ligation. Multiple rounds of recombination were observed within the ~25 s observation period, including frequent consecutive rotation events in the cleaved-DNA state without evidence of intermediate ligation.

Variable orthogonality of serine integrase interactions within the ϕC31 family

Serine integrases are phage- (or mobile element-) encoded enzymes that catalyse site-specific recombination reactions between a short DNA sequence on the phage genome (attP) and a corresponding host genome sequence (attB), thereby integrating the phage DNA into the host genome. Each integrase has its unique pair of attP and attB sites, a feature that allows them to be used as orthogonal tools for genome modification applications. In the presence of a second protein, the Recombination Directionality Factor (RDF), integrase catalyses the reverse excisive reaction, generating new recombination sites, attR and attL. In addition to promoting attR x attL reaction, the RDF inhibits attP x attB recombination. This feature makes the directionality of integrase reactions programmable, allowing them to be useful for building synthetic biology devices. In this report, we describe the degree of orthogonality of both integrative and excisive reactions for three related integrases (ϕC31, ϕBT1, and TG1) and their RDFs. Among these, TG1 integrase is the most active, showing near complete recombination in both attP x attB and attR x attL reactions, and the most directional in the presence of its RDF. Our findings show that there is varying orthogonality among these three integrases – RDF pairs. ϕC31 integrase was the least selective, with all three RDFs activating it for attR x attL recombination. Similarly, ϕC31 RDF was the least effective among the three RDFs in promoting the excisive activities of the integrases, including its cognate ϕC31 integrase. ϕBT1 and TG1 RDFs were noticeably more effective than ϕC31 RDF at inhibiting attP x attB recombination by their respective integrases, making them more suitable for building reversible genetic switches. AlphaFold-Multimer predicts very similar structural interactions between each cognate integrase – RDF pair. The binding surface on the RDF is much more conserved than the binding surface on the integrase, an indication that specificity is determined more by the integrase than the RDF. Overall, the observed weak integrase/RDF orthogonality across the three enzymes emphasizes the need for identifying and characterizing more integrase – RDF pairs. Additionally, the ability of a particular integrase’s preferred reaction direction to be controlled to varying degrees by non-cognate RDFs provides a path to tunable, non-binary genetic switches.

Recent Advances in Genetic Engineering Strategies of Sinorhizobium meliloti.

Sinorhizobium meliloti is a free-living soil Gram-negative bacterium that participates in nitrogen-fixation symbiosis with several legumes. S. meliloti has the potential to be utilized for the production of high-value nutritional compounds, such as vitamin B12. Advances in gene editing tools play a vital role in the development of S. meliloti strains with enhanced characteristics for biotechnological applications. Several novel genetic engineering strategies have emerged in recent years to investigate genetic modifications in S. meliloti. This review provides a comprehensive overview of the mechanism and application of the extensively used Tn5-mediated genetic engineering strategies. Strategies based on homologous recombination and site-specific recombination were also discussed. Subsequently, the development and application of the genetic engineering strategies utilizing various CRISPR/Cas systems in S. meliloti are summarized. This review may stimulate research interest among scientists, foster studies in the application areas of S. meliloti, and serve as a reference for the utilization of genome editing tools for other Rhizobium species.

Site-Specific Integration by Circular Donor Improves CRISPR/Cas9-Mediated Homologous Recombination in Human Cell Lines

The technology for obtaining the high-efficiency expression of target proteins through site-specific recombination has made progress. However, using the CRISPR/Cas9 system for site-specific integration of long fragments and the expression of active proteins remains a challenge. This study optimized the linear DNA circularization system, eliminated the prokaryotic plasmid backbone on the traditional foreign gene vector, and generated a homologous arm-free circular donor template with a single guide RNA target site (sgRNA TS). This strategy significantly increased the co-transfection efficiency of the 1.6 kb template and Cas9 plasmid by 1.15-fold, and the average knock-in (KI) efficiency of the 4.7 kb long-fragment template for the two target gene sites increased by 1.3-fold. Subsequently, we used rhBCHE as a reporter gene to efficiently integrate the 5.4 kb fragment containing the gene of interest (GOI) into specific sites in the HEK293T cell line to detect the expression of the circular template at different target sites. Overall, this study further verifies that the length of the circular donor is more conducive to non-homologous integration, and more importantly, we provide a simple and optimized strategy for the construction of long-fragment site integration cell lines.

N-methyl-D-aspartate Receptor Subunits 2A and 2B Mediate Connexins and Pannexins in the Trigeminal Ganglion Involved in Orofacial Inflammatory Allodynia during Temporomandibular Joint Inflammation.

Temporomandibular joint osteoarthritis (TMJOA) is a severe form of temporomandibular joint disorders (TMD), and orofacial inflammatory allodynia is one of its common symptoms which lacks effective treatment. N-methyl-D-aspartate receptor (NMDAR), particularly its subtypes GluN2A and GluN2B, along with gap junctions (GJs), are key players in the mediation of inflammatory pain. However, the precise regulatory mechanisms of GluN2A, GluN2B, and GJs in orofacial inflammatory allodynia during TMJ inflammation still remain unclear. Here, we established the TMJ inflammation model by injecting Complete Freund's adjuvant (CFA) into the TMJ and used Cre/loxp site-specific recombination system to conditionally knock out (CKO) GluN2A and GluN2B in the trigeminal ganglion (TG). Von-frey test results indicated that CFA-induced mechanical allodynia in the TMJ region was relieved in GluN2A and GluN2B deficient mice. In vivo, CFA significantly up-regulated the expression of GluN2A and GluN2B, Gjb1, Gjb2, Gjc2 and Panx3 in the TG, and GluN2A and GluN2B CKO played different roles in mediating the expression of Gjb1, Gjb2, Gjc2 and Panx3. In vitro, NMDA up-regulated the expression of Gjb1, Gjb2, Gjc2 and Panx3 in satellite glial cells (SGCs) as well as promoted the intercellular communication between SGCs, and GluN2A and GluN2B knocking down (KD) altered the expression and function differently. NMDAR regulated Gjb1 and Panx3 through ERK1/2 pathway, and mediated Gjb2 and Gjc2 through MAPK, PKA, and PKC intracellular signaling pathways. These findings shed light on the distinct functions of GluN2A and GluN2B in mediating peripheral sensitization induced by TMJ inflammation in the TG, offering potential therapeutic targets for managing orofacial inflammatory allodynia.

In vivo cloning of PCR product via site-specific recombination in Escherichia coli

Over the past years, several methods have been developed for gene cloning. Choosing a cloning strategy depends on various factors, among which simplicity and affordability have always been considered. The aim of this study, on the one hand, is to simplify gene cloning by skipping in vitro assembly reactions and, on the other hand, to reduce costs by eliminating relatively expensive materials. We investigated a cloning system using Escherichia coli harboring two plasmids, pLP-AmpR and pScissors-CmR. The pLP-AmpR contains a landing pad (LP) consisting of two genes (λ int and λ gam) that allow the replacement of the transformed linear DNA using site-specific recombination. After the replacement process, the inducible expressing SpCas9 and specific sgRNA from the pScissors-CmR (CRISPR/Cas9) vector leads to the removal of non-recombinant pLP-AmpR plasmids. The function of LP was explored by directly transforming PCR products. The pScissors-CmR plasmid was evaluated for curing three vectors, including the origins of pBR322, p15A, and pSC101. Replacing LP with a PCR product and fast-eradicating pSC101 origin-containing vectors was successful. Recombinant colonies were confirmed following gene replacement and plasmid curing processes. The results made us optimistic that this strategy may potentially be a simple and inexpensive cloning method.Key points•The in vivo cloning was performed by replacing the target gene with the landing pad.•Fast eradication of non-recombinant plasmids was possible by adapting key vectors.•This strategy is not dependent on in vitro assembly reactions and expensive materials.

Rational construction of a high-quality and high-efficiency biosynthetic system and fermentation optimization for A82846B based on combinatorial strategies in Amycolatopsis orientalis

BackgroundOritavancin is a new generation of semi-synthetic glycopeptide antibiotics against Gram-positive bacteria, which served as the first and only antibiotic with a single-dose therapeutic regimen to treat ABSSSI. A naturally occurring glycopeptide A82846B is the direct precursor of oritavancin. However, its application has been hampered by low yields and homologous impurities. This study established a multi-step combinatorial strategy to rationally construct a high-quality and high-efficiency biosynthesis system for A82846B and systematically optimize its fermentation process to break through the bottleneck of microbial fermentation production.ResultsFirstly, based on the genome sequencing and analysis, we deleted putative competitive pathways and constructed a better A82846B-producing strain with a cleaner metabolic background, increasing A82846B production from 92 to 174 mg/L. Subsequently, the PhiC31 integrase system was introduced based on the CRISPR-Cas12a system. Then, the fermentation level of A82846B was improved to 226 mg/L by over-expressing the pathway-specific regulator StrR via the constructed PhiC31 system. Furthermore, overexpressing glycosyl-synthesis gene evaE enhanced the production to 332 mg/L due to the great conversion of the intermediate to target product. Finally, the scale-up production of A82846B reached 725 mg/L in a 15 L fermenter under fermentation optimization, which is the highest reported yield of A82846B without the generation of homologous impurities.ConclusionUnder approaches including blocking competitive pathways, inserting site-specific recombination system, overexpressing regulator, overexpressing glycosyl-synthesis gene and optimizing fermentation process, a multi-step combinatorial strategy for the high-level production of A82846B was developed, constructing a high-producing strain AO-6. The combinatorial strategies employed here can be widely applied to improve the fermentation level of other microbial secondary metabolites, providing a reference for constructing an efficient microbial cell factory for high-value natural products.

Targeted insertion of conditional expression cassettes into the mouse genome using the modified i-PITT

BackgroundTransgenic (Tg) mice are widely used in biomedical research, and they are typically generated by injecting transgenic DNA cassettes into pronuclei of one-cell stage zygotes. Such animals often show unreliable expression of the transgenic DNA, one of the major reasons for which is random insertion of the transgenes. We previously developed a method called “pronuclear injection-based targeted transgenesis” (PITT), in which DNA constructs are directed to insert at pre-designated genomic loci. PITT was achieved by pre-installing so called landing pad sequences (such as heterotypic LoxP sites or attP sites) to create seed mice and then injecting Cre recombinase or PhiC31 integrase mRNAs along with a compatible donor plasmid into zygotes derived from the seed mice. PITT and its subsequent version, improved PITT (i-PITT), overcome disadvantages of conventional Tg mice such as lack of consistent and reliable expression of the cassettes among different Tg mouse lines, and the PITT approach is superior in terms of cost and labor. One of the limitations of PITT, particularly using Cre-mRNA, is that the approach cannot be used for insertion of conditional expression cassettes using Cre-LoxP site-specific recombination. This is because the LoxP sites in the donor plasmids intended for achieving conditional expression of the transgene will interfere with the PITT recombination reaction with LoxP sites in the landing pad.ResultsTo enable the i-PITT method to insert a conditional expression cassette, we modified the approach by simultaneously using PhiC31o and FLPo mRNAs. We demonstrate the strategy by creating a model containing a conditional expression cassette at the Rosa26 locus with an efficiency of 13.7%. We also demonstrate that inclusion of FLPo mRNA excludes the insertion of vector backbones in the founder mice.ConclusionsSimultaneous use of PhiC31 and FLP in i-PITT approach allows insertion of donor plasmids containing Cre-loxP-based conditional expression cassettes.

Tandem gene duplication selected by activation of horizontally transferred gene in bacteria

Horizontal gene transfer occurs frequently in bacteria, but the mechanism driving activation and optimization of the expression of horizontally transferred genes (HTGs) in new recipient strains is not clear. Our previous study found that spontaneous tandem DNA duplication resulted in rapid activation of HTGs. Here, we took advantage of this finding to develop a novel technique for tandem gene duplication, named tandem gene duplication selected by activation of horizontally transferred gene in bacteria (TDAH), in which tandem duplication was selected by the activation of horizontally transferred selectable marker gene. TDAH construction does not contain any reported functional elements based on homologous or site-specific recombination and DNA amplification. TDAH only contains an essential selectable marker for copy number selection and 9-bp-microhomology border sequences for precise illegitimate recombination. One transformation and 3 days were enough to produce a high-copy strain, so its procedure is simple and fast. Without subsequent knockout of the endogenous recombination system, TDAH could also generate the relatively stable high-copy tandem duplication for plasmid-carried and genome-integrated DNA. TDAH also showed an excellent capacity for increase gene expression and worked well in different industrial bacteria. We also applied TDAH to select the optimal high copy number of ribA for vitamin B2 production in E. coli; the yield was improved by 3.5 times and remained stable even after 12 subcultures. TDAH is a useful tool for recombinant protein production and expression optimization of biosynthetic pathways.Key points• We develop a novel and efficient technique (TDAH) for tandem gene duplication in bacterium. TDAH is based on the mechanism of HTG rapid activation. TDAH does not contain any reported functional elements based on homologous recombination and DNA amplification. TDAH only contains an essential selectable marker for copy number selection, so its construction and procedure are very simple and fast.• TDAH is the first reported selected and stable tandem-gene-duplication technique in which the selected high-copy plasmid-carried and genome-integrated DNA could remain stable without the subsequent knockout of recombination system.• TDAH showed an excellent capacity for regulating gene expression and worked well in different industrial bacteria, indicating it is a useful tool for recombinant protein production and expression optimization of biosynthetic pathways.• TDAH was applied to select the optimal high copy number of ribA for vitamin B2 production in E. coli; the yield was improved by 3.5-fold and remained stable even after 12 subcultures.

Conditional knockdown of OsMLH1 to improve plant prime editing systems without disturbing fertility in rice.

High-efficiency prime editing (PE) is desirable for precise genome manipulation. The activity of mammalian PE systems can be largely improved by inhibiting DNA mismatch repair by coexpressing a dominant-negative variant of MLH1. However, this strategy has not been widely used for PE optimization in plants, possibly because of its less conspicuous effects and inconsistent performance at different sites. We show that direct RNAi knockdown of OsMLH1 in an ePE5c system increases the efficiency of our most recently updated PE tool by 1.30- to 2.11-fold in stably transformed rice cells, resulting in as many as 85.42% homozygous mutants in the T0 generation. The high specificity of ePE5c is revealed by whole-genome sequencing. To overcome the partial sterility induced by OsMLH1 knockdown of ePE5c, a conditional excision system is introduced to remove the RNAi module by Cre-mediated site-specific recombination. Using a simple approach of enriching excision events, we generate 100% RNAi module-free plants in the T0 generation. The increase in efficiency due to OsMLH1 knockdown is maintained in the excised plants, whose fertility is not impaired. This study provides a safe and reliable plant PE optimization strategy for improving editing efficiency without disturbing plant development via transient MMR inhibition with an excisable RNAi module of MLH1.

Screening Key Sites of Class 2 Integron Integrase that Impact Recombination Efficiency.

By capturing and expressing exogenous resistance gene cassettes through site-specific recombination, integrons play important roles in the horizontal transfer of antimicrobial resistant genes among bacteria. The characteristics of integron integrase make it to be a potential gene editing tool enzyme. In this study, a random mutation library using error-prone PCR was constructed, and amino acid residues mutants that impact on attI2 × attC or attC × attC recombination efficiency were screened and analyzed. Thirteen amino acid mutations were identified to be critical impacted on site-specific recombination of IntI2, including the predicted catalyzed site Y301. Nine of 13 mutated amino acid residues that have critically impacted on IntI2 activity were relative concentrated and near the predicted catalyzed site Y301 in the predicted three-dimensional structure indicated the importance of this area in maintain the activity of IntI2. No mutant with obviously increased recombination activity (more than four-fold as high as that of wild IntI2) was found in library screening, except P95S, R100K slightly increased (within two-fold) the excision activity of IntI2, and S243T slightly increased (within two-fold) both excision and integration activity of IntI2. These findings will provide clues for further specific modification of integron integrase to be a tool enzyme as well as establishing a new gene editing system and applied practically.

Redefining the bacteriophage mv4 site-specific recombination system and the sequence specificity of its attB and core-attP sites.

Through their involvement in the integration and excision of a large number of mobile genetic elements, such as phages and integrative and conjugative elements (ICEs), site-specific recombination systems based on heterobivalent tyrosine recombinases play a major role in genome dynamics and evolution. However, despite hundreds of these systems having been identified in genome databases, very few have been described in detail, with none from phages that infect Bacillota (formerly Firmicutes). In this study, we reanalyzed the recombination module of Lactobacillus delbrueckii subsp. bulgaricus phage mv4, previously considered atypical compared with classical systems. Our results reveal that mv4 integrase is a 369 aa protein with all the structural hallmarks of recombinases from the Tn916 family and that it cooperatively interacts with its recombination sites. Using randomized DNA libraries, NGS sequencing, and other molecular approaches, we show that the 21-bp core-attP and attB sites have structural similarities to classical systems only if considering the nucleotide degeneracy, with two 7-bp inverted regions corresponding to mv4Int core-binding sites surrounding a 7-bp strand-exchange region. We also examined the different compositional constraints in the core-binding regions, which define the sequence space of permissible recombination sites.