Your search keyword '"Recombineering"' showing total 1,094 results

1. Gap-repair recombineering for efficient retrieval of large DNA fragments from BAC clones and manipulation of large high-copy number plasmids.

Author

Dix, Thomas C., Lassota, Anna, Brauer, Ulrike, Haussmann, Irmgard U., and Soller, Matthias

Subjects

*DNA, *PLASMIDS, *CRISPRS, *GENE expression, *INVERTEBRATES

Abstract

Background: Bacterial high-copy number plasmids are the preferred DNA source for reporter constructs used in cell transfection experiments and making transgenic invertebrates to study gene expression, develop gene therapies and biotechnological application. They can be quickly validated from small cultures and easily generated in large quantities. However, manipulating plasmids above 10 kb can become very tedious. Method: Here, we devised simple and highly efficient gap-repair recombineering methodology in E. coli to manipulate high-copy number plasmids up to 20 kb with up to 100% efficiency. This method utilises rare cutting restriction enzymes to introduce a gap, which is then subsequently repaired through homologous recombination from a provided template. Unlike traditional cloning methods, large concentration differences among fragments are tolerated. Moreover, CRISPR-Cas9-mediated in vitro DNA scission can be sufficiently efficient to overcome limitations from finding rare cutting restriction enzymes. Discussion: Gap-repair recombineering provides a significant advancement in generating recombinant high-copy number DNA plasmids through enhancing efficiency, speed, and robustness. We validated this technology by generating reporter transgenes of the highly repetitive Drosophila Down Syndrome Cell Adhesion Molecule (Dscam) gene to analyse alternative splicing. [ABSTRACT FROM AUTHOR]

Published

2024

2. The tal gene of lactococcal bacteriophage TP901-1 is involved in DNA release following host adsorption.

Author

Ruiz-Cruz, Sofía, Garzon, Andrea Erazo, Cambillau, Christian, Charneco, Guillermo Ortiz, Lugli, Gabriele Andrea, Ventura, Marco, Mahony, Jennifer, and van Sinderen, Douwe

Subjects

*CELL envelope (Biology), *MUTANT proteins, *PROTEIN domains, *POLYSACCHARIDES, *TAPE measures

Abstract

Temperate P335 phage TP901-1 represents one of the best-characterized Gram-positive phages regarding its structure and host interactions. Following its reversible adsorption to the polysaccharidic side-chain of the cell wall polysaccharide of its host Lactococcus cremoris 3107, TP901-1 requires a glucosylated cell envelope moiety to trigger its genome delivery into the host cytoplasm. Here, we demonstrate that three distinct single amino acid substitutions in the Tal protein of TP901-1 baseplate are sufficient to overcome the TP901-1 resistance of three L. cremoris 3107 derivatives, whose resistance is due to impaired DNA release of the phage. All of these Tal alterations are located in the N-terminally located gp27-like domain of the protein, conserved in many tailed phages. AlphaFold2 predictions of the Tal mutant proteins suggest that these mutations favor conformational changes necessary to reposition the Tal fiber and thus facilitate release of the tape measure protein from the tail tube and subsequent DNA ejection in the absence of the trigger otherwise required for phage genome release. [ABSTRACT FROM AUTHOR]

Published

2024

3. Use of Cas9 Targeting and Red Recombination for Designer Phage Engineering.

Author

Choi, Shin-Yae, Romero-Calle, Danitza Xiomara, Cho, Han-Gyu, Bae, Hee-Won, and Cho, You-Hee

Abstract

Bacteriophages (phages) are natural antibiotics and biological nanoparticles, whose application is significantly boosted by recent advances of synthetic biology tools. Designer phages are synthetic phages created by genome engineering in a way to increase the benefits or decrease the drawbacks of natural phages. Here we report the development of a straightforward genome engineering method to efficiently obtain engineered phages in a model bacterial pathogen, Pseudomonas aeruginosa. This was achieved by eliminating the wild type phages based on the Streptococcus pyogenes Cas9 (SpCas9) and facilitating the recombinant generation based on the Red recombination system of the coliphage λ (λRed). The producer (PD) cells of P. aeruginosa strain PAO1 was created by miniTn7-based chromosomal integration of the genes for SpCas9 and λRed under an inducible promoter. To validate the efficiency of the recombinant generation, we created the fluorescent phages from a temperate phage MP29. A plasmid bearing the single guide RNA (sgRNA) gene for selectively targeting the wild type gp35 gene and the editing template for tagging the Gp35 with superfolder green fluorescent protein (sfGFP) was introduced into the PD cells by electroporation. We found that the targeting efficiency was affected by the position and number of sgRNA. The fluorescent phage particles were efficiently recovered from the culture of the PD cells expressing dual sgRNA molecules. This protocol can be used to create designer phages in P. aeruginosa for both application and research purposes. [ABSTRACT FROM AUTHOR]

Published

2024

4. Half a century after their discovery: Structural insights into exonuclease and annealase proteins catalyzing recombineering

Author

Lucy J. Fitschen, Timothy P. Newing, Nikolas P. Johnston, Charles E. Bell, and Gökhan Tolun

Subjects

Recombineering, Redβ, λExo, RecE, RecT, Protein structure, Biotechnology, TP248.13-248.65, Microbiology, QR1-502

Abstract

Recombineering is an essential tool for molecular biologists, allowing for the facile and efficient manipulation of bacterial genomes directly in cells without the need for costly and laborious in vitro manipulations involving restriction enzymes. The main workhorses behind recombineering are bacteriophage proteins that promote the single-strand annealing (SSA) homologous recombination pathway to repair double-stranded DNA breaks. While there have been several reviews examining recombineering methods and applications, comparatively few have focused on the mechanisms of the proteins that are the key players in the SSA pathway: a 5′→3′ exonuclease and a single-strand annealing protein (SSAP or “annealase”). This review dives into the structures and functions of the two SSA recombination systems that were the first to be developed for recombineering in E. coli: the RecET system from E. coli Rac prophage and the λRed system from bacteriophage λ. By comparing the structures of the RecT and Redβ annealases, and the RecE and λExo exonucleases, we provide new insights into how the structures of these proteins dictate their function. Examining the sequence conservation of the λExo and RecE exonucleases gives more profound insights into their critical functional features. Ultimately, as recombineering accelerates and evolves in the laboratory, a better understanding of the mechanisms of the proteins behind this powerful technique will drive the development of improved and expanded capabilities in the future.

Published

2024

5. Recent advances in genome-scale engineering in Escherichia coli and their applications

Author

Hui Gao, Zhichao Qiu, Xuan Wang, Xiyuan Zhang, Yujia Zhang, Junbiao Dai, and Zhuobin Liang

Subjects

Genome-scale engineering, E. coli, Recombineering, CRISPR-Cas, Biotechnology, TP248.13-248.65, Microbiology, QR1-502

Abstract

Owing to the rapid advancement of genome engineering technologies, the scale of genome engineering has expanded dramatically. Genome editing has progressed from one genomic alteration at a time that could only be employed in few species, to the simultaneous generation of multiple modifications across many genomic loci in numerous species. The development and recent advances in multiplex automated genome engineering (MAGE)-associated technologies and clustered regularly interspaced short palindromic repeats and their associated protein (CRISPR-Cas)-based approaches, together with genome-scale synthesis technologies offer unprecedented opportunities for advancing genome-scale engineering in a broader range. These approaches provide new tools to generate strains with desired phenotypes, understand the complexity of biological systems, and directly evolve a genome with novel features. Here, we review the recent major advances in genome-scale engineering tools developed for Escherichia coli, focusing on their applications in identifying essential genes, genome reduction, recoding, and beyond.

Published

2024

6. Identification of the EH CRISPR‐Cas9 system on a metagenome and its application to genome engineering

Author

Belen Esquerra‐Ruvira, Ignacio Baquedano, Raul Ruiz, Almudena Fernandez, Lluis Montoliu, and Francisco J. M. Mojica

Subjects

Cas9, CRISPR, genome editing, metagenome, recombineering, Biotechnology, TP248.13-248.65

Abstract

Abstract Non‐coding RNAs (crRNAs) produced from clustered regularly interspaced short palindromic repeats (CRISPR) loci and CRISPR‐associated (Cas) proteins of the prokaryotic CRISPR‐Cas systems form complexes that interfere with the spread of transmissible genetic elements through Cas‐catalysed cleavage of foreign genetic material matching the guide crRNA sequences. The easily programmable targeting of nucleic acids enabled by these ribonucleoproteins has facilitated the implementation of CRISPR‐based molecular biology tools for in vivo and in vitro modification of DNA and RNA targets. Despite the diversity of DNA‐targeting Cas nucleases so far identified, native and engineered derivatives of the Streptococcus pyogenes SpCas9 are the most widely used for genome engineering, at least in part due to their catalytic robustness and the requirement of an exceptionally short motif (5′‐NGG‐3′ PAM) flanking the target sequence. However, the large size of the SpCas9 variants impairs the delivery of the tool to eukaryotic cells and smaller alternatives are desirable. Here, we identify in a metagenome a new CRISPR‐Cas9 system associated with a smaller Cas9 protein (EHCas9) that targets DNA sequences flanked by 5′‐NGG‐3′ PAMs. We develop a simplified EHCas9 tool that specifically cleaves DNA targets and is functional for genome editing applications in prokaryotes and eukaryotic cells.

Published

2023

7. Comparison of phage-derived recombinases for genetic manipulation of Pseudomonas species

Author

Madison J. Kalb, Andrew W. Grenfell, Abhiney Jain, Jane Fenske-Newbart, and Jeffrey A. Gralnick

Subjects

recombineering, homologous recombination, SSAPs, Pseudomonas, plant growth promoting rhizobacteria, Microbiology, QR1-502

Abstract

ABSTRACT Several strains in the Pseudomonas genus are categorized as plant growth-promoting rhizobacteria (PGPR). Although several of these strains are strong candidates for applications as biofertilizers or biopesticides, genome editing approaches are generally limited and require further development. Editing genomes in PGPR could enable more robust agricultural applications, persistence, and biosafety measures. In this study, we investigate the use of five phage-encoded recombinases to develop a recombineering workflow in three PGPR strains: Pseudomonas protegens Pf-5, Pseudomonas protegens CHA0, and Pseudomonas putida KT2440. Using point mutations in the rpoB gene, we reach maximum recombineering efficiencies of 1.5 × 10−4, 3 × 10−4, and 5 × 10−5, respectively, in these strains using λ-Red Beta recombinase from Escherichia coli. We further examine recombineering efficiencies across these strains as a function of selected mutation, editing template concentration, and phosphorothiolate bond protection. This work validates the use of these tools across several environmentally and biotechnologically relevant strains to expand the possibilities of genetic manipulation in the Pseudomonas genus. IMPORTANCE The Pseudomonas genus contains many members currently being investigated for applications in biodegradation, biopesticides, biocontrol, and synthetic biology. Though several strains have been identified with beneficial properties, chromosomal manipulations to further improve these strains for commercial applications have been limited due to the lack of efficient genetic tools that have been tested across this genus. Here, we test the recombineering efficiencies of five phage-derived recombinases across three biotechnologically relevant Pseudomonas strains: P. putida KT2440, P. protegens Pf-5, and P. protegens CHA0. These results demonstrate a method to generate targeted mutations quickly and efficiently across these strains, ideally introducing a method that can be implemented across the Pseudomonas genus and a strategy that may be applied to develop analogous systems in other nonmodel bacteria.

Published

2023

8. RecT Recombinase Expression Enables Efficient Gene Editing in Enterococcus spp.

Author

Chen, Victor, Griffin, Matthew E, Maguin, Pascal, Varble, Andrew, and Hang, Howard C

Subjects

Enterococcus faecium, Streptococcus pyogenes, Recombinases, Bacterial Proteins, CRISPR-Cas Systems, Gene Editing, CRISPR-Associated Protein 9, CRISPR, E. faecium, Enterococcus, VRE, biotechnology, genetics, recombineering, Infectious Diseases, Emerging Infectious Diseases, Antimicrobial Resistance, Biotechnology, Prevention, Genetics, Infection, Microbiology

Abstract

Enterococcus faecium is a ubiquitous Gram-positive bacterium that has been recovered from the environment, food, and microbiota of mammals. Commensal strains of E. faecium can confer beneficial effects on host physiology and immunity, but antibiotic usage has afforded antibiotic-resistant and pathogenic isolates from livestock and humans. However, the dissection of E. faecium functions and mechanisms has been restricted by inefficient gene-editing methods. To address these limitations, here, we report that the expression of E. faecium RecT recombinase significantly improves the efficiency of recombineering technologies in both commensal and antibiotic-resistant strains of E. faecium and other Enterococcus species such as E. durans and E. hirae. Notably, the expression of RecT in combination with clustered regularly interspaced short palindromic repeat (CRISPR)-Cas9 and guide RNAs (gRNAs) enabled highly efficient scarless single-stranded DNA recombineering to generate specific gene-editing mutants in E. faecium. Moreover, we demonstrate that E. faecium RecT expression facilitated chromosomal insertions of double-stranded DNA templates encoding antibiotic-selectable markers to generate gene deletion mutants. As a further proof of principle, we use CRISPR-Cas9-mediated recombineering to knock out both sortase A genes in E. faecium for downstream functional characterization. The general RecT-mediated recombineering methods described here should significantly enhance genetic studies of E. faecium and other closely related species for functional and mechanistic studies. IMPORTANCE Enterococcus faecium is widely recognized as an emerging public health threat with the rise of drug resistance and nosocomial infections. Nevertheless, commensal Enterococcus strains possess beneficial health functions in mammals to upregulate host immunity and prevent microbial infections. This functional dichotomy of Enterococcus species and strains highlights the need for in-depth studies to discover and characterize the genetic components underlying its diverse activities. However, current genetic engineering methods in E. faecium still require passive homologous recombination from plasmid DNA. This involves the successful cloning of multiple homologous fragments into a plasmid, introducing the plasmid into E. faecium, and screening for double-crossover events that can collectively take up to multiple weeks to perform. To alleviate these challenges, we show that RecT recombinase enables the rapid and efficient integration of mutagenic DNA templates to generate substitutions, deletions, and insertions in the genomic DNA of E. faecium. These improved recombineering methods should facilitate functional and mechanistic studies of Enterococcus.

Published

2021

9. The emerging role of recombineering in microbiology

Author

Ruijuan Li, Aiying Li, Youming Zhang, and Jun Fu

Subjects

Recombineering, Natural products, Viral mutagenesis, Phage genome engineering, Bacterial metabolism, Biotechnology, TP248.13-248.65, Microbiology, QR1-502

Abstract

ABSTRACT: Recombineering is a valuable technique for generating recombinant DNA in vivo, primarily in bacterial cells, and is based on homologous recombination using phage-encoded homologous recombinases, such as Redαβγ from the lambda phage and RecET from the Rac prophage. The recombineering technique can efficiently mediate homologous recombination using short homologous arms (∼50 bp) and is unlimited by the size of the DNA molecules or positions of restriction sites. In this review, we summarize characteristics of recombinases, mechanism of recombineering, and advances in recombineering for DNA manipulation in Escherichia coli and other bacteria. Furthermore, the broad applications of recombineering for mining new bioactive microbial natural products, and for viral mutagenesis, phage genome engineering, and understanding bacterial metabolism are also reviewed.

Published

2023

10. Recombineering enables genome mining of novel siderophores in a non-model Burkholderiales strain

Author

Xingyan Wang, Haibo Zhou, Xiangmei Ren, Hanna Chen, Lin Zhong, Xianping Bai, and Xiaoying Bian

Subjects

Burkholderiales, Recombineering, Siderophore, Genome mining, Caribactins, Biotechnology, TP248.13-248.65, Microbiology, QR1-502

Abstract

Iron is essential for bacterial survival, and most bacteria capture iron by producing siderophores. Burkholderiales bacteria produce various types of bioactive secondary metabolites, such as ornibactin and malleobactin siderophores. In this study, the genome analysis of Burkholderiales genomes showed a putative novel siderophore gene cluster crb, which is highly similar to the ornibactin and malleobactin gene clusters but does not have pvdF, a gene encoding a formyltransferase for N-δ‑hydroxy-ornithine formylation. Establishing the bacteriophage recombinase Redγ-Redαβ7029 mediated genome editing system in a non-model Burkholderiales strain Paraburkholderia caribensis CICC 10960 allowed the rapid identification of the products of crb gene cluster, caribactins A-F (1–6). Caribactins contain a special amino acid residue N-δ‑hydroxy-N-δ-acetylornithine (haOrn), which differs from the counterpart N-δ‑hydroxy-N-δ-formylornithine (hfOrn) in ornibactin and malleobactin, owing to the absence of pvdF. Gene inactivation showed that the acetylation of hOrn is catalyzed by CrbK, whose homologs probably not be involved in the biosynthesis of ornibactin and malleobactin, showing possible evolutionary clues of these siderophore biosynthetic pathways from different genera. Caribactins promote biofilm production and enhance swarming and swimming abilities, suggesting that they may play crucial roles in biofilm formation. This study also revealed that recombineering has the capability to mine novel secondary metabolites from non-model Burkholderiales species.

Published

2023

11. A recombineering system for Bacillus subtilis based on the native phage recombinase pair YqaJ/YqaK

Author

Qingshu Liu, Ruijuan Li, Hongbo Shi, Runyu Yang, Qiyao Shen, Qingwen Cui, Xiuling Wang, Aiying Li, Youming Zhang, and Jun Fu

Subjects

Bacillus subtilis, Recombineering, YqaJK system, Genome editing, Biotechnology, TP248.13-248.65, Microbiology, QR1-502

Abstract

Bacillus subtilis plays an important role in fundamental and applied research, and it has been widely used as a cell factory for the production of enzymes, antimicrobial materials, and chemicals for agriculture, medicine, and industry. However, genetic manipulation tools for B. subtilis have low efficiency. In this work, our goal was to develop a simple recombineering system for B. subtilis. We showed that genome editing can be achieved in B. subtiliis 1A751 through co-expression of YqaJ/YqaK, a native phage recombinase pair found in B. subtilis 168, and the competence master regulator ComK using a double-stranded DNA substrate with short homology arms (100 bp) and a phosphorothioate modification at the 5′-end. Efficient gene knockouts and large DNA insertions were achieved using this new recombineering system in B. subtilis 1A751. As far as we know, this is the first recombineering system using the native phage recombinase pair YqaJ/YqaK in B. subtilis. In conclusion, this new recombineering system provides a simple and fast tool for genetic manipulation of B. subtilis, and it will promote studies of genome function, construction of production strains, and genome mining in B. subtilis.

Published

2023

12. Identification of the EH CRISPR‐Cas9 system on a metagenome and its application to genome engineering.

Author

Esquerra‐Ruvira, Belen, Baquedano, Ignacio, Ruiz, Raul, Fernandez, Almudena, Montoliu, Lluis, and Mojica, Francisco J. M.

Subjects

*GENOME editing, *RNA modification & restriction, *MOLECULAR biology, *NUCLEIC acids, *CRISPRS, *NUCLEOPROTEINS, *EUKARYOTIC cells

Abstract

Non‐coding RNAs (crRNAs) produced from clustered regularly interspaced short palindromic repeats (CRISPR) loci and CRISPR‐associated (Cas) proteins of the prokaryotic CRISPR‐Cas systems form complexes that interfere with the spread of transmissible genetic elements through Cas‐catalysed cleavage of foreign genetic material matching the guide crRNA sequences. The easily programmable targeting of nucleic acids enabled by these ribonucleoproteins has facilitated the implementation of CRISPR‐based molecular biology tools for in vivo and in vitro modification of DNA and RNA targets. Despite the diversity of DNA‐targeting Cas nucleases so far identified, native and engineered derivatives of the Streptococcus pyogenes SpCas9 are the most widely used for genome engineering, at least in part due to their catalytic robustness and the requirement of an exceptionally short motif (5′‐NGG‐3′ PAM) flanking the target sequence. However, the large size of the SpCas9 variants impairs the delivery of the tool to eukaryotic cells and smaller alternatives are desirable. Here, we identify in a metagenome a new CRISPR‐Cas9 system associated with a smaller Cas9 protein (EHCas9) that targets DNA sequences flanked by 5′‐NGG‐3′ PAMs. We develop a simplified EHCas9 tool that specifically cleaves DNA targets and is functional for genome editing applications in prokaryotes and eukaryotic cells. [ABSTRACT FROM AUTHOR]

Published

2023

13. Approaches for bacteriophage genome engineering.

Author

Mahler, Marina, Costa, Ana Rita, van Beljouw, Sam P.B., Fineran, Peter C., and Brouns, Stan J.J.

Subjects

*GENOME editing, *BACTERIOPHAGES, *GENE targeting, *CRISPRS, *BACTERIAL diseases, *NUMBERS of species

Abstract

In recent years, bacteriophage research has been boosted by a rising interest in using phage therapy to treat antibiotic-resistant bacterial infections. In addition, there is a desire to use phages and their unique proteins for specific biocontrol applications and diagnostics. However, the ability to manipulate phage genomes to understand and control gene functions, or alter phage properties such as host range, has remained challenging due to a lack of universal selectable markers. Here, we discuss the state-of-the-art techniques to engineer and select desired phage genomes using advances in cell-free methodologies and clustered regularly interspaced short palindromic repeats-CRISPR associated protein (CRISPR-Cas) counter-selection approaches. Clustered regularly interspaced short palindromic repeats-CRISPR associated protein (CRISPR-Cas) systems are efficient at counter-selecting mutant phages generated by homologous recombination-based approaches, but are still limited by spacer efficiency and CRISPR-evading strategies of phages. RNA-targeting CRISPR-Cas systems, such as type III and VI, can provide a more robust selection tool, especially for phages that evolved strategies to protect their DNA from targeting. Furthermore, these systems avoid the enrichment of CRISPR escape mutants. Ex vivo phage genome engineering strategies assemble and reboot synthetic phage genomes and allow for increased flexibility in the design of the phage genome. Rebooting of synthetic phage genomes is facilitated in cell-free systems by the exclusion of the cell membrane barrier, but it is currently restricted to a very small number of bacterial species. [ABSTRACT FROM AUTHOR]

Published

2023

14. The genome editing revolution.

Author

van der Oost, John and Patinios, Constantinos

Subjects

*GENOME editing, *REVOLUTIONS, *CRISPRS, *MOLECULAR biology, *DNA synthesis, *DNA structure

Abstract

Seventy years after deciphering the structure of DNA, we are experiencing a revolution in genome editing. Sequencing and synthesis of DNA is cheaper and faster than ever, leading to the rapid advancement of the fields of molecular biology and biotechnology. The development of DNA editing and engineering tools advanced our fundamental understanding of biology, which allowed us to develop societally relevant applications. CRISPR-Cas editing tools have revolutionized the field of genome editing due to their simplicity, accuracy, and efficiency across all forms of life. A series of spectacular scientific discoveries and technological advances in the second half of the 20th century have provided the basis for the ongoing genome editing revolution. The elucidation of structural and functional features of DNA and RNA was followed by pioneering studies on genome editing: Molecular biotechnology was born. Since then, four decades followed during which progress of scientific insights and technological methods continued at an overwhelming pace. Fundamental insights into microbial host-virus interactions led to the development of tools for genome editing using restriction enzymes or the revolutionary CRISPR-Cas technology. In this review, we provide a historical overview of milestones that led to the genome editing revolution and speculate about future trends in biotechnology. [ABSTRACT FROM AUTHOR]

Published

2023

15. Characterization of a novel Escherichia coli recombineering selection/counterselection cassette.

Author

Zhang, Guoyi, Zhang, Qiong, Wang, Junyu, Zhang, Jiao, and Shang, Guangdong

Subjects

ESCHERICHIA coli, MOLECULAR cloning, DNA, GENE targeting

Abstract

Recombineering is a highly efficient DNA cloning and modification technique by using the recombinase-mediated homologous recombination. Selection/counterselection cassette is often used in chromosomal DNA or large episomal DNA manipulation, in which the selection marker is used for the first step cassette selection while deleting the target gene via allelic exchange, and the counterselection marker is used for the second step replacement of the cassette by the foreign DNA fragment. A variety of selection/counterselection cassettes are reported, however, the cassettes suffer from the shortcomings of the requirement of pre-engineered strain or specific culture medium. Herein, we report a novel S-tetR- PtetA-ccdB-aacC1-S selection/counterselection cassette that sidesteps the disadvantages. As a proof-of-concept, one-step gene cloning (0.7, 1.7, and 4.2 kb) and two-step Escherichia coli chromosomal gene knock-in (0.7 and 4.2 kb) were performed. The gene cloning and gene knock-in efficiencies are high up to 90%. The novel selection/counterselection cassette adds a powerful tool to the recombineering repertoire. [ABSTRACT FROM AUTHOR]

Published

2023

16. High-yield production of FK228 and new derivatives in a Burkholderia chassis.

Author

Gong, Kai, Wang, Maoqin, Duan, Qiong, Li, Gang, Yong, Daojing, Ren, Cailing, Li, Yue, Zhang, Qijun, Wang, Zongjie, Sun, Tao, Zhang, Huanyun, Tu, Qiang, Wu, Changsheng, Fu, Jun, Li, Aiying, Song, Chaoyi, Zhang, Youming, and Li, Ruijuan

Subjects

*BURKHOLDERIA, *CUTANEOUS T-cell lymphoma, *CHROMOBACTERIUM violaceum, *SYNTHETIC biology, *ENGINEERS, *GENE clusters

Abstract

FK228 (romidepsin) is the only natural histone deacetylases (HDACs) inhibitor approved by FDA to treat cutaneous and peripheral T-cell lymphoma. However, the limited supply and severe cardiotoxicity of FK228 underscore the importance to develop an effective synthetic biology platform for the manufacturing and fine-tuning of this drug lead. In this work, we constructed a Burkholderia chassis for the high-yield production of FK228-family (unnatural) natural products. By virtue of the optimized Burkholderia -specific recombineering system, the biosynthetic gene cluster (BGC) encoding the FK228-like skeleton thailandepsins (tdp) in Burkholderia thailandensis E264 was replaced with an attB integration site to afford the basal chassis KOGC1. The tdp BGC directly captured from E264 was hybridized with the FK228-encoding BGC (dep) using the versatile Red/ET technology. The hybrid BGC (tdp-dep) was integrated into the attB site of KOGC1, resulting in the heterologous expression of FK228. Remarkably, the titer reached 581 mg/L, which is 30-fold higher than that of native producer Chromobacterium violaceum No. 968. This success encouraged us to further engineer the NRPS modules 4 or 6 of hybrid tdp-dep BGC by domain units swapping strategy, and eight new FK228 derivatives (1 – 8) varying in the composition of amino acids were generated. Especially, the titers of 2 and 3 in KOGC1 were up to 985 mg/L and 453 mg/L, respectively. 2 and 3 displayed stronger cytotoxic activity than FK228. All in all, this work established a robust platform to produce FK228 and its new derivatives in sufficient quantities for anticancer drug development. [Display omitted] • A Burkholderia chassis for the high-yield production of FK228 has been constructed based on the Burkholderia -specific recombineering. • The yield of FK228 in the chassis KOGC1 reaches 581 mg/L, 30-fold higher than the native producer Chromobacterium violaceum No. 968. • This research significantly enriches the chemical repertoire of FK228 through versatile combinatorial biosynthesis approach. • The yield of 2 in KOGC1 reaches 1 g/L, suggesting that the existing method for industrial production of FK228 derivatives could be revolutionized. [ABSTRACT FROM AUTHOR]

Published

2023

17. Editing of Phage Genomes—Recombineering-assisted SpCas9 Modification of Model Coliphages T7, T5, and T3.

Author

Isaev, A., Andriianov, A., Znobishcheva, E., Zorin, E., Morozova, N., and Severinov, K.

Subjects

*GENOME editing, *BACTERIAL genomes, *BACTERIOPHAGES, *GENOMES, *CRISPRS, *BACTERIAL cells

Abstract

Bacteriophages—viruses that infect bacterial cells—are the most abundant biological entities on Earth. The use of phages in fundamental research and industry requires tools for precise manipulation of their genomes. Yet, compared to bacterial genome engineering, modification of phage genomes is challenging because of the lack of selective markers and thus requires laborious screenings of recombinant/mutated phage variants. The development of the CRISPR-Cas technologies allowed to solve this issue by the implementation of negative selection that eliminates the parental phage genomes. In this manuscript, we summarize current methods of phage genome engineering and their coupling with CRISPR-Cas technologies. We also provide examples of our successful application of these methods for introduction of specific insertions, deletions, and point mutations in the genomes of model Escherichia coli lytic phages T7, T5, and T3. [ABSTRACT FROM AUTHOR]

Published

2022

18. Recombineering using RecET-like recombinases from Xenorhabdus and its application in mining of natural products.

Author

Huang, Xiyin, Sun, Yawei, Liu, Siqin, Li, Yaoguang, Li, Chen, Sun, Yunjun, Ding, Xuezhi, Xia, Liqiu, Hu, Yibo, and Hu, Shengbiao

Subjects

*OPERONS, *XENORHABDUS, *AMINO acid sequence, *RECOMBINASES, *NATURAL products, *NUCLEAR magnetic resonance

Abstract

Xenorhabdus can produce a large number of secondary metabolites with insecticidal, bacteriostatic, and antitumor activities. Efficient gene editing tools will undoubtedly facilitate the functional genomics research and bioprospecting in Xenorhabdus. In this study, BlastP analysis using the amino acid sequences of Redαβ or RecET recombinases as queries resulted in the identification of an operon (XBJ1_operon 0213) containing RecET-like recombinases encoding genes from the genome of Xenorhabdus bovienii strain SS-2004. Three proteins encoded by this operon was indispensable for full activity of recombineering, namely XBJ1-1173 (RecE-like protein), XBJ1-1172 (RecT-like protein), and XBJ1-1171 (single-strand annealing protein). Using this newly developed recombineering system, a gene cluster responsible for biosynthesis of a novel secondary metabolite (Min16) was identified from X. stockiae HN_xs01 strain. Min16 which exhibited antibacterial and cytotoxic activities was determined to be a cyclopeptide composed of Acyl-Phe-Thr-Phe-Pro-Pro-Leu-Val by using high-resolution mass spectrometry and nuclear magnetic resonance analysis, and was designated as changshamycin. This host-specific recombineering system was proven to be effective for gene editing in Xenorhabdus, allowing for efficient discovery of novel natural products with attractive bioactivities. Key points: • Screening and identification of efficient gene editing tools from Xenorhabdus • Optimization of the Xenorhabdus electroporation parameters • Discovery of a novel cyclopeptide compound with multiple biological activities [ABSTRACT FROM AUTHOR]

Published

2022

19. Investigating the role of human cytomegalovirus protein LUNA in regulating viral gene expression during latency

Author

Lau, Jonathan and Sinclair, John

Subjects

579.2, Cytomegalovirus, Herpesvirus, Virology, Molecular Virology, Human Cytomegalovirus, Herpesvirology, Immunology, Latency, Reactivation, Epigenetics, Bioinformatics, LUNA, Latency-associated, Transcriptional Regulation, Primary Cell, HCMV, CMV, Viruses, Infection, Infectious Diseases, Chronic infection, Medicine, Medical Sciences, Recombineering, SUMO, SUMOylation, DeSUMOylation, Protein, PML body, ND10, Myeloid, CD34, CD14, DNA Virus

Abstract

Human cytomegalovirus (HCMV) is a widespread human herpesvirus pathogen and prototypical member of the β-herpesvirus subfamily. Like all herpesviruses, the virus establishes a lifelong latent infection following host exposure, which has the potential to reactivate periodically and contribute to recurrent disease processes. In individuals with weak or compromised immune systems, such reactivation can lead to profound pathology. Understanding how latent infections are maintained is important for uncovering how HCMV causes disease. The study of viral genes that are expressed during latent infection grants insight into how latency is regulated and how it could be therapeutically targeted. To that end, this project has sought to evaluate the functional significance of one such viral gene termed LUNA in the context of latency. In models of experimental latent infection based on primary myeloid cells, levels of viral gene transcription were found to be significantly reduced following infection with LUNA deletion mutant viruses, consistent with corresponding observable changes in post-translational histone modifications over the viral promoters of latency-associated genes. Additionally, using luciferase reporter systems, latency-associated viral gene promoters became activated in response to the expression of wild-type LUNA. Together, these findings argue for a role of LUNA in regulating viral gene expression during latent HCMV infection. One possible mechanism by which LUNA may fulfil its role is by targeting cellular ND10 structures, known intrinsic inhibitors of herpesvirus gene expression, for disruption. In support of this, latently infected cells were found to be devoid of ND10, a phenotype that was recapitulated by the direct expression of wild-type LUNA. Furthermore, mutation studies confirmed the identification of a novel deSUMOylase activity encoded by LUNA that was responsible for mediating ND10 disruption. Use of a catalytically inactive LUNA mutant in transcriptional analyses of latent infection also generated similar results as with the LUNA deletion viruses. Overall, these data support the hypothesis that LUNA serves as an important regulator of viral gene expression during latency, which is likely linked to its ability to target ND10 structures for disruption, thus raising the possibility that inhibition of deSUMOylation may serve as a novel therapeutic strategy to target latent HCMV infection.

Published

2018

20. An Optimized CRISPR/Cas9 Adenovirus Vector (AdZ-CRISPR) for High-Throughput Cloning of sgRNA, Using Enhanced sgRNA and Cas9 Variants.

Author

Statkute, Evelina, Wang, Eddie C.Y., and Stanton, Richard J.

Subjects

*MOLECULAR cloning, *CRISPRS, *GENE therapy, *VIRUS isolation, *ADENOVIRUSES, *TRANSGENES

Abstract

Recombinant adenovirus vectors enable highly efficient gene delivery in vitro and in vivo. As a result, they are widely used in gene therapy, vaccination, and anticancer applications. We have previously developed the AdZ vector system, which uses recombineering to permit high-throughput cloning of transgenes into Adenovirus vectors, simplifies alteration of the vector backbone, and enables rapid recovery of infectious virus, even if a transgene is incompatible with vector replication. In this study, we adapt this vector system to enable high-throughput cloning of sequences for CRISPR/Cas9 editing. Vectors were optimized to ensure efficient cloning, and high editing efficiency using spCas9 and single guide RNA (sgRNA) sequences in a single vector. Using a multiplicity of infection of 50, knockout efficiencies of up to 80% could be achieved with a single sgRNA. Vectors were further enhanced by altering the spCas9 sequence to match that of SniperCas9, which has reduced off-target activity, but maintains on-target efficiency, and by applying modifications to the sgRNA sequence that significantly enhance editing efficiency. Thus, the AdZ-CRISPR vectors offer highly efficient knockout, even in hard to transfect cells, and enables large-scale CRISPR/Cas9 projects to be undertaken easily and quickly. [ABSTRACT FROM AUTHOR]

Published

2022

21. Past, Present, and Future of Genome Modification in Escherichia coli.

Author

Mori, Hirotada, Kataoka, Masakazu, and Yang, Xi

Abstract

Escherichia coli K-12 is one of the most well-studied species of bacteria. This species, however, is much more difficult to modify by homologous recombination (HR) than other model microorganisms. Research on HR in E. coli has led to a better understanding of the molecular mechanisms of HR, resulting in technical improvements and rapid progress in genome research, and allowing whole-genome mutagenesis and large-scale genome modifications. Developments using λ Red (exo, bet, and gam) and CRISPR-Cas have made E. coli as amenable to genome modification as other model microorganisms, such as Saccharomyces cerevisiae and Bacillus subtilis. This review describes the history of recombination research in E. coli, as well as improvements in techniques for genome modification by HR. This review also describes the results of large-scale genome modification of E. coli using these technologies, including DNA synthesis and assembly. In addition, this article reviews recent advances in genome modification, considers future directions, and describes problems associated with the creation of cells by design. [ABSTRACT FROM AUTHOR]

Published

2022

22. A Robust One-Step Recombineering System for Enterohemorrhagic Escherichia coli.

Author

Peng, Lang, Dumevi, Rexford Mawunyo, Chitto, Marco, Haarmann, Nadja, Berger, Petya, Koudelka, Gerald, Schmidt, Herbert, Mellmann, Alexander, Dobrindt, Ulrich, and Berger, Michael

Abstract

Enterohemorrhagic Escherichia coli (EHEC) can cause severe diarrheic in humans. To improve therapy options, a better understanding of EHEC pathogenicity is essential. The genetic manipulation of EHEC with classical one-step methods, such as the transient overexpression of the phage lambda (λ) Red functions, is not very efficient. Here, we provide a robust and reliable method for increasing recombineering efficiency in EHEC based on the transient coexpression of recX together with gam, beta, and exo. We demonstrate that the genetic manipulation is 3–4 times more efficient in EHEC O157:H7 EDL933 Δstx1/2 with our method when compared to the overexpression of the λ Red functions alone. Both recombineering systems demonstrated similar efficiencies in Escherichia coli K-12 MG1655. Coexpression of recX did not enhance the Gam-mediated inhibition of sparfloxacin-mediated SOS response. Therefore, the additional inhibition of the RecFOR pathway rather than a stronger inhibition of the RecBCD pathway of SOS response induction might have resulted in the increased recombineering efficiency by indirectly blocking phage induction. Even though additional experiments are required to unravel the precise mechanistic details of the improved recombineering efficiency, we recommend the use of our method for the robust genetic manipulation of EHEC and other prophage-carrying E. coli isolates. [ABSTRACT FROM AUTHOR]

Published

2022

23. Protocol for Construction of a Tunable CRISPR Interference (tCRISPRi) Strain for Escherichia coli.

Author

Li, Xin-Tian, Sou, Cindy, and Jun, Suckjoon

Subjects

Medical Microbiology, Biomedical and Clinical Sciences, Biological Sciences, Genetics, Biotechnology, CRISPR interference, Gene expression, Gene knockdown, Recombineering, Biological sciences, Biomedical and clinical sciences

Abstract

We present a protocol for construction of tunable CRISPR interference (tCRISPRi) strains for Escherichia coli. The tCRISPRi system alleviates most of the known problems of plasmid-based expression methods, and can be immediately used to construct libraries of sgRNAs that can complement the Keio collection by targeting both essential and nonessential genes. Most importantly from a practical perspective, construction of tCRISPRi to target a new gene requires only one-step oligo recombineering. Additional advantages of tCRISPRi over other existing CRISPRi methods include: (1) tCRISPRi shows significantly less than 10% leaky repression; (2) tCRISPRi uses a tunable arabinose operon promoter and modifications in transporter genes to allow a wide dynamic range with graded control by arabinose inducer; (3) tCRISPRi is plasmid free and the entire system is integrated into the chromosome; (4) tCRISPRi strains show desirable physiological properties.

Published

2017

24. Structural Basis for the Interaction of Redβ Single-Strand Annealing Protein with Escherichia coli Single-Stranded DNA-Binding Protein.

Author

Zakharova, Katerina, Liu, Mengqi, Greenwald, Jacelyn R., Caldwell, Brian C., Qi, Zihao, Wysocki, Vicki H., and Bell, Charles E.

Subjects

*DNA-binding proteins, *SINGLE-stranded DNA, *REPLICATION fork, *ESCHERICHIA coli, *GENOME editing, *RECOMBINANT DNA

Abstract

[Display omitted] • Single-strand annealing (SSAP) proteins can anneal oligonucleotides to the lagging strand to incorporate changes. • To do this, the SSAP must bind the C-terminal tail of the host SSB protein. • The crystal structure of the complex reveals the key residues of SSB that mediate the interaction. • Knowledge of the structure will increase the portability of SSAPs to different host strains. Redβ is a protein from bacteriophage λ that binds to single-stranded DNA (ssDNA) to promote the annealing of complementary strands. Together with λ-exonuclease (λ-exo), Redβ is part of a two-component DNA recombination system involved in multiple aspects of genome maintenance. The proteins have been exploited in powerful methods for bacterial genome engineering in which Redβ can anneal an electroporated oligonucleotide to a complementary target site at the lagging strand of a replication fork. Successful annealing in vivo requires the interaction of Redβ with E. coli single-stranded DNA-binding protein (SSB), which coats the ssDNA at the lagging strand to coordinate access of numerous replication proteins. Previous mutational analysis revealed that the interaction between Redβ and SSB involves the C-terminal domain (CTD) of Redβ and the C-terminal tail of SSB (SSB-Ct), the site for binding of numerous host proteins. Here, we have determined the x-ray crystal structure of Redβ CTD in complex with a peptide corresponding to the last nine residues of SSB (MDFDDDIPF). Formation of the complex is predominantly mediated by hydrophobic interactions between two phenylalanine side chains of SSB (Phe-171 and Phe-177) and an apolar groove on the CTD, combined with electrostatic interactions between the C-terminal carboxylate of SSB and Lys-214 of the CTD. Mutation of any of these residues to alanine significantly disrupts the interaction of full-length Redβ and SSB proteins. Structural knowledge of this interaction will help to expand the utility of Redβ-mediated recombination to a wider range of bacterial hosts for applications in synthetic biology. [ABSTRACT FROM AUTHOR]

Published

2024

25. Golden Gate-Assisted Gene Doctoring for Streamlined and Efficient Recombineering in Bacteria.

Author

Thomson NM

Subjects

Genetic Engineering methods, Bacteriophage lambda genetics, Homologous Recombination, Genetic Vectors genetics, Cloning, Molecular methods, Plasmids genetics, Escherichia coli genetics

Abstract

Gene Doctoring is a genetic modification technique for E. coli and related bacteria, in which the Red-recombinase from bacteriophage λ mediates chromosomal integration of a fragment of DNA by homologous recombination (known as recombineering). In contrast to the traditional recombineering method, the integrated fragment for Gene Doctoring is supplied on a donor plasmid rather than as a linear DNA. This protects the DNA from degradation, facilitates transformation, and ensures multiple copies are present per cell, increasing the efficiency and making the technique particularly suitable for strains that are difficult to modify. Production of the donor plasmid has, until recently, relied on traditional cloning techniques that are inflexible, tedious, and inefficient. This protocol describes a procedure for Gene Doctoring combined with Golden Gate assembly of a donor plasmid, using a custom-designed plasmid backbone, for rapid and simple production of complex, multi-part assemblies. Insertion of a gene for superfolder green fluorescent protein, with selection by tetracycline resistance, into E. coli strain MG1655 is used as an example but in principle the method can be tailored for virtually any modification in a wide range of bacteria., (© 2025. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2025

26. CRISPR/Cas9 advances engineering of microbial cell factories

Author

Jakočiūnas, Tadas, Jensen, Michael K, and Keasling, Jay D

Subjects

Biological Sciences, Industrial Biotechnology, Human Genome, Infectious Diseases, Biotechnology, Emerging Infectious Diseases, Genetics, Quality Education, CRISPR-Associated Proteins, CRISPR-Cas Systems, Clustered Regularly Interspaced Short Palindromic Repeats, Genetic Enhancement, Genome, Microbial, Metabolic Engineering, Metabolic Networks and Pathways, Genome editing, Metabolic engineering, CRISPR/Cas9, Recombineering, Yeast, Bacteria, Biochemistry and cell biology, Industrial biotechnology

Abstract

One of the key drivers for successful metabolic engineering in microbes is the efficacy by which genomes can be edited. As such there are many methods to choose from when aiming to modify genomes, especially those of model organisms like yeast and bacteria. In recent years, clustered regularly interspaced palindromic repeats (CRISPR) and its associated proteins (Cas) have become the method of choice for precision genome engineering in many organisms due to their orthogonality, versatility and efficacy. Here we review the strategies adopted for implementation of RNA-guided CRISPR/Cas9 genome editing with special emphasis on their application for metabolic engineering of yeast and bacteria. Also, examples of how nuclease-deficient Cas9 has been applied for RNA-guided transcriptional regulation of target genes will be reviewed, as well as tools available for computer-aided design of guide-RNAs will be highlighted. Finally, this review will provide a perspective on the immediate challenges and opportunities foreseen by the use of CRISPR/Cas9 genome engineering and regulation in the context of metabolic engineering.

Published

2016

27. Efficient and iterative retron-mediated in vivo recombineering in Escherichia coli.

Author

Ellington, Adam J and Reisch, Christopher R

Subjects

*ESCHERICHIA coli, *MICROBIAL genomes, *GENOME editing, *CLONING, *GENE expression

Abstract

Recombineering is an important tool in gene editing, enabling fast, precise and highly specific in vivo modification of microbial genomes. Oligonucleotide-mediated recombineering via the in vivo production of single-stranded DNA can overcome the limitations of traditional recombineering methods that rely on the exogenous delivery of editing templates. By modifying a previously reported plasmid-based system for fully in vivo single-stranded DNA recombineering, we demonstrate iterative editing of independent loci by utilizing a temperature-sensitive origin of replication for easy curing of the editing plasmid from recombinant cells. Optimization of the promoters driving the expression of the system's functional components, combined with targeted counterselection against unedited cells with Cas9 nuclease, enabled editing efficiencies of 90–100%. The addition of a dominant-negative mutL allele to the system allowed single-nucleotide edits that were otherwise unachievable due to mismatch repair. Finally, we tested alternative recombinases and found that efficiency significantly increased for some targets. Requiring only a single cloning step for retargeting, our system provides an easy-to-use method for rapid, efficient construction of desired mutants. Graphical Abstract [ABSTRACT FROM AUTHOR]

Published

2022

28. Rapid and Efficient BAC Recombineering: Gain & Loss Screening System.

Author

Kuk, Myeong Uk, Lee, Yun Haeng, Kim, Jae Won, Hwang, Su Young, Park, Ji Yun, Song, Eun Seon, Kwon, Hyung Wook, Oh, Sekyung, and Park, Joon Tae

Subjects

*BACTERIAL artificial chromosomes, *DNA sequencing

Abstract

Recombineering has been developed to modify bacterial artificial chromosome (BAC) via homologous recombination. Nevertheless, as a screening strategy to identify the correct clone was not properly developed, it was difficult to obtain a correct clone within a limited time period. To address these issues, we developed a new screening method (a gain & loss screening system) that enables the efficient identification of the recombineered clone. Simple inoculation of cells into LB medium with appropriate antibiotics visually revealed the positive clones within 24 h. DNA sequencing confirmed 100% accuracy of this screening method by showing that all positive clones exhibited recombinant sequences. Furthermore, our new method allowed us to complete the entire procedure consisting of 1st recombineering, flip-out and 2nd recombineering in just 13 days. Overall, our new strategy may provide a new avenue for BAC recombineering, as evidenced by markedly increased accuracy and subsequently shortened recombineering duration. [ABSTRACT FROM AUTHOR]

Published

2021

29. Creation of Golden Gate constructs for gene doctoring

Author

Nicholas M. Thomson, Chuanzhen Zhang, Eleftheria Trampari, and Mark J. Pallen

Subjects

Gene doctoring, Recombineering, Golden Gate assembly, Mutagenesis, Enterobacteria, Chromosome, Biotechnology, TP248.13-248.65

Abstract

Abstract Background Gene doctoring is an efficient recombination-based genetic engineering approach to mutagenesis of the bacterial chromosome that combines the λ-Red recombination system with a suicide donor plasmid that is cleaved in vivo to generate linear DNA fragments suitable for recombination. The use of a suicide donor plasmid makes Gene Doctoring more efficient than other recombineering technologies. However, generation of donor plasmids typically requires multiple cloning and screening steps. Results We constructed a simplified acceptor plasmid, called pDOC-GG, for the assembly of multiple DNA fragments precisely and simultaneously to form a donor plasmid using Golden Gate assembly. Successful constructs can easily be identified through blue-white screening. We demonstrated proof of principle by inserting a gene for green fluorescent protein into the chromosome of Escherichia coli. We also provided related genetic parts to assist in the construction of mutagenesis cassettes with a tetracycline-selectable marker. Conclusions Our plasmid greatly simplifies the construction of Gene Doctoring donor plasmids and allows for the assembly of complex, multi-part insertion or deletion cassettes with a free choice of target sites and selection markers. The tools we developed are applicable to gene editing for a wide variety of purposes in Enterobacteriaceae and potentially in other diverse bacterial families.

Published

2020

30. CRISPR/Cas9 recombineering‐mediated deep mutational scanning of essential genes in Escherichia coli

Author

Alaksh Choudhury, Jacob A Fenster, Reilly G Fankhauser, Joel L Kaar, Olivier Tenaillon, and Ryan T Gill

Subjects

CRISPR‐Cas9, deep mutational scanning, essential genes, genome editing, recombineering, Biology (General), QH301-705.5, Medicine (General), R5-920

Abstract

Abstract Deep mutational scanning can provide significant insights into the function of essential genes in bacteria. Here, we developed a high‐throughput method for mutating essential genes of Escherichia coli in their native genetic context. We used Cas9‐mediated recombineering to introduce a library of mutations, created by error‐prone PCR, within a gene fragment on the genome using a single gRNA pre‐validated for high efficiency. Tracking mutation frequency through deep sequencing revealed biases in the position and the number of the introduced mutations. We overcame these biases by increasing the homology arm length and blocking mismatch repair to achieve a mutation efficiency of 85% for non‐essential genes and 55% for essential genes. These experiments also improved our understanding of poorly characterized recombineering process using dsDNA donors with single nucleotide changes. Finally, we applied our technology to target rpoB, the beta subunit of RNA polymerase, to study resistance against rifampicin. In a single experiment, we validate multiple biochemical and clinical observations made in the previous decades and provide insights into resistance compensation with the study of double mutants.

Published

2020

31. An improved Xer-cise technology for the generation of multiple unmarked mutants in Mycobacteria

Author

Yves-Marie Boudehen, Maximilian Wallat, Philippe Rousseau, Olivier Neyrolles, and Claude Gutierrez

Subjects

dif site, excisable cassette, mutagenesis, Mycobacterium, recombineering, unmarked deletions, Biology (General), QH301-705.5

Abstract

Xer-cise is a technique using antibiotic resistance cassettes flanked by dif sites allowing spontaneous and accurate excision from bacterial chromosomes with a high frequency through the action of the cellular recombinase XerCD. Here, we report a significant improvement of Xer-cise in Mycobacteria. Zeocin resistance cassettes flanked by variants of the natural Mycobacterium tuberculosis dif site were constructed and shown to be effective tools to construct multiple unmarked mutations in M. tuberculosis and in the model species Mycobacterium smegmatis. The dif site variants harbor mutations in the central region and can therefore not recombine with the wild-type or other variants, resulting in mutants of increased genetic stability. The herein described method should be generalizable to virtually any transformable bacterial species.

Published

2020

32. Development of a Recombineering System for the Acetogen Eubacterium limosum with Cas9 Counterselection for Markerless Genome Engineering.

Author

Sanford PA and Woolston BM

Subjects

Metabolic Engineering methods, Recombination, Genetic genetics, Genome, Bacterial genetics, CRISPR-Associated Protein 9 genetics, CRISPR-Associated Protein 9 metabolism, Recombinases genetics, Recombinases metabolism, Genetic Engineering methods, Gene Editing methods, Multigene Family, Eubacterium genetics, CRISPR-Cas Systems genetics

Abstract

Eubacterium limosum is a Clostridial acetogen that efficiently utilizes a wide range of single-carbon substrates and contributes to metabolism of health-associated compounds in the human gut microbiota. These traits have led to interest in developing it as a platform for sustainable CO 2 -based biofuel production to combat carbon emissions, and for exploring the importance of the microbiota in human health. However, synthetic biology and metabolic engineering in E. limosum have been hindered by the inability to rapidly make precise genomic modifications. Here, we screened a diverse library of recombinase proteins to develop a highly efficient oligonucleotide-based recombineering system based on the viral recombinase RecT. Following optimization, the system is capable of catalyzing ssDNA recombination at an efficiency of up to 2%. Addition of a Cas9 counterselection system eliminated unrecombined cells, with up to 100% of viable cells encoding the desired mutation, enabling creation of genomic point mutations in a scarless and markerless manner. We deployed this system to create a clean knockout of the extracellular polymeric substance (EPS) gene cluster, generating a strain incapable of biofilm formation. This approach is rapid and simple, not requiring laborious homology arm cloning, and can readily be retargeted to almost any genomic locus. This work overcomes a major bottleneck in E. limosum genetic engineering by enabling precise genomic modifications, and provides both a roadmap and associated recombinase plasmid library for developing similar systems in other Clostridia of interest.

Published

2024

33. Identification of phage recombinase function unit in genus Corynebacterium.

Author

Chang, Yizhao, Wang, Qian, Su, Tianyuan, and Qi, Qingsheng

Subjects

*CORYNEBACTERIUM, *RECOMBINASES, *BACTERIOPHAGES, *GENETIC engineering, *SINGLE-stranded DNA

Abstract

Phage recombinase function unit (PRFU) plays a key role in the life cycle of phage. Repurposing this system such as lambda-Redαβ or Rac-RecET for recombineering has gained success in Escherichia coli. Previous studies have showed that most PRFUs only worked well in its native hosts but poorly in the distant species. Thus, identification of new PRFUs in specific species is necessary for the development of its corresponding genetic engineering tools. Here, we present a thorough study of PRFUs in the genomes of genus Corynebacterium. We first used a database to database searching method to facilitate accurate prediction of novel PRFUs in 423 genomes. A total number of 60 sets of unique PRFUs were identified and divided into 8 types based on evolution affinities. Recombineering ability of the 8 representative PRFUs was experimentally verified in the Corynebacterium glutamicum ATCC 13032 strain. In particular, PRFU from C. aurimucosum achieved highest efficiency in both ssDNA and dsDNA mediated recombineering, which is expected to greatly facilitate genome engineering in genus Corynebacterium. These results will provide new insights for the study and application of PRFUs. Key points: • First report of bioinformatic mining and systematic analysis of Phage recombinase function unit (PRFU) in Corynebacterium genomes. • Recombineering ability of the representative PRFUs was experimentally verified in Corynebacterium glutamicum ATCC 13032 strain. • PRFU with the highest recombineering efficiency at 10-2magnitude was identified from Corynebacterium aurimucosum. [ABSTRACT FROM AUTHOR]

Published

2021

34. Optimizing recombineering in Corynebacterium glutamicum.

Author

Li, Cheng, Swofford, Charles A., Rückert, Christian, and Sinskey, Anthony J.

Abstract

Owing to the increasing demand for amino acids and valuable commodities that can be produced by Corynebacterium glutamicum, there is a pressing need for new rapid genome engineering tools that improve the speed and efficiency of genomic insertions, deletions, and mutations. Recombineering using the λ Red system in Escherichia coli has proven very successful at genetically modifying this organism in a quick and efficient manner, suggesting that optimizing a recombineering system for C. glutamicum will also improve the speed for genomic modifications. Here, we maximized the recombineering efficiency in C. glutamicum by testing the efficacy of seven different recombinase/exonuclease pairs for integrating single‐stranded DNA and double‐stranded DNA (dsDNA) into the genome. By optimizing the homologous arm length and the amount of dsDNA transformed, as well as eliminating codon bias, a dsDNA recombineering efficiency of 13,250 transformed colonies/109 viable cells was achieved, the highest efficiency currently reported in the literature. Using this optimized system, over 40,000 bp could be deleted in one transformation step. This recombineering strategy will greatly improve the speed of genetic modifications in C. glutamicum and assist other systems, such as clustered regularly interspaced short palindromic repeats and multiplexed automated genome engineering, in improving targeted genome editing. [ABSTRACT FROM AUTHOR]

Published

2021

35. In vivo assembly of genetic constructs in filamentous fungus Talaromyces cellulolyticus.

Author

Orleneva, Alexandra P., Teslya, Petr N., and Serebrianyi, Vsevolod A.

Subjects

*FILAMENTOUS fungi, *TALAROMYCES, *HOMOLOGOUS recombination, *GENETIC engineering, *SACCHAROMYCES cerevisiae

Abstract

In the filamentous fungus Talaromyces cellulolyticus , similar to other filamentous fungi, non-homologous recombination predominates over homologous recombination. For instance, to achieve an acceptable integration frequency of a genetic construct into a target site on the intact chromosome, the flanking sequences directing this integration should be approximately 2.5 kb in length. However, despite the requirement of long flanks for integration into the intact chromosome, we found that homologous recombination between linear DNA fragments in T. cellulolyticus effectively occurs when these fragments overlap by just 50 bp. This allows for the assembly of full-sized genetic constructs in vivo from relatively small blocks, eliminating the need for in vitro assembly, similar to the approach previously developed for the yeast Saccharomyces cerevisiae. To validate this possibility, we replaced the native promoter of the target gene by transforming the recipient strain with five DNA fragments: two flanks for recombination with the target locus, two parts of the marker gene, and a donor promoter. This discovery significantly expedites the genetic engineering of T. cellulolyticus and potentially other fungi. • In Talaromyces cellulolyticus , non-homologous recombination predominates, as in other fungi. • Despite this, short homology provides homologous recombination between linear DNA fragments. • This allows for the assembly of full-sized genetic constructs in vivo from relatively small blocks. [ABSTRACT FROM AUTHOR]

Published

2024

36. Investigation of the methylerythritol 4-phosphate pathway for microbial terpenoid production through metabolic control analysis

Author

Daniel Christoph Volke, Johann Rohwer, Rainer Fischer, and Stefan Jennewein

Subjects

MEP pathway, Metabolic control analysis, Recombineering, Isoprene, E. coli, Microbiology, QR1-502

Abstract

Abstract Background Terpenoids are of high interest as chemical building blocks and pharmaceuticals. In microbes, terpenoids can be synthesized via the methylerythritol phosphate (MEP) or mevalonate (MVA) pathways. Although the MEP pathway has a higher theoretical yield, metabolic engineering has met with little success because the regulation of the pathway is poorly understood. Results We applied metabolic control analysis to the MEP pathway in Escherichia coli expressing a heterologous isoprene synthase gene (ispS). The expression of ispS led to the accumulation of isopentenyl pyrophosphate (IPP)/dimethylallyl pyrophosphate (DMAPP) and severely impaired bacterial growth, but the coexpression of ispS and isopentenyl diphosphate isomerase (idi) restored normal growth and wild-type IPP/DMAPP levels. Targeted proteomics and metabolomics analysis provided a quantitative description of the pathway, which was perturbed by randomizing the ribosome binding site in the gene encoding 1-deoxyxylulose 5-phosphate synthase (Dxs). Dxs has a flux control coefficient of 0.35 (i.e., a 1% increase in Dxs activity resulted in a 0.35% increase in pathway flux) in the isoprene-producing strain and therefore exerted significant control over the flux though the MEP pathway. At higher dxs expression levels, the intracellular concentration of 2-C-methyl-d-erythritol-2,4-cyclopyrophosphate (MEcPP) increased substantially in contrast to the other MEP pathway intermediates, which were linearly dependent on the abundance of Dxs. This indicates that 4-hydroxy-3-methylbut-2-en-1-yl diphosphate synthase (IspG), which consumes MEcPP, became saturated and therefore limited the flux towards isoprene. The higher intracellular concentrations of MEcPP led to the efflux of this intermediate into the growth medium. Discussion These findings show the importance of Dxs, Idi and IspG and metabolite export for metabolic engineering of the MEP pathway and will facilitate further approaches for the microbial production of valuable isoprenoids.

Published

2019

37. A Robust One-Step Recombineering System for Enterohemorrhagic Escherichia coli

Author

Lang Peng, Rexford Mawunyo Dumevi, Marco Chitto, Nadja Haarmann, Petya Berger, Gerald Koudelka, Herbert Schmidt, Alexander Mellmann, Ulrich Dobrindt, and Michael Berger

Subjects

enterohemorrhagic Escherichia coli, recombineering, SOS response, Biology (General), QH301-705.5

Abstract

Enterohemorrhagic Escherichia coli (EHEC) can cause severe diarrheic in humans. To improve therapy options, a better understanding of EHEC pathogenicity is essential. The genetic manipulation of EHEC with classical one-step methods, such as the transient overexpression of the phage lambda (λ) Red functions, is not very efficient. Here, we provide a robust and reliable method for increasing recombineering efficiency in EHEC based on the transient coexpression of recX together with gam, beta, and exo. We demonstrate that the genetic manipulation is 3–4 times more efficient in EHEC O157:H7 EDL933 Δstx1/2 with our method when compared to the overexpression of the λ Red functions alone. Both recombineering systems demonstrated similar efficiencies in Escherichia coli K-12 MG1655. Coexpression of recX did not enhance the Gam-mediated inhibition of sparfloxacin-mediated SOS response. Therefore, the additional inhibition of the RecFOR pathway rather than a stronger inhibition of the RecBCD pathway of SOS response induction might have resulted in the increased recombineering efficiency by indirectly blocking phage induction. Even though additional experiments are required to unravel the precise mechanistic details of the improved recombineering efficiency, we recommend the use of our method for the robust genetic manipulation of EHEC and other prophage-carrying E. coli isolates.

Published

2022

38. The genome editing revolution

Author

John van der Oost and Constantinos Patinios

Subjects

recombineering, Microbiologie, genome editing, BacGen, Bioengineering, CRISPR-Cas, Microbiology, biotechnology, VLAG, Biotechnology

Abstract

A series of spectacular scientific discoveries and technological advances in the second half of the 20th century have provided the basis for the ongoing genome editing revolution. The elucidation of structural and functional features of DNA and RNA was followed by pioneering studies on genome editing: Molecular biotechnology was born. Since then, four decades followed during which progress of scientific insights and technological methods continued at an overwhelming pace. Fundamental insights into microbial host-virus interactions led to the development of tools for genome editing using restriction enzymes or the revolutionary CRISPR-Cas technology. In this review, we provide a historical overview of milestones that led to the genome editing revolution and speculate about future trends in biotechnology.

Published

2023

39. Functional analysis of the ALS/FTD associated gene FUS using a novel in vitro genomic DNA expression system

Author

Thomas, Matthew Robert, Wade-Martins, Richard, and Ansorge, Olaf

Subjects

572.8, Transgenics, Biology (medical sciences), Motor neurone degenerative disease, Neurogenetics, Life Sciences, Cell Biology (see also Plant sciences), amyotrophic lateral sclerosis, frontotemporal dementia, bacterial artificial chromosome, recombineering

Abstract

Aggregations of fused in sarcoma (FUS), a multifunctional RNA processing protein, define a pathological subtype of both frontotemporal dementia (FTD) and amyotrophic lateral sclerosis (ALS), whilst mutations in the FUS gene are causative for ALS. To model the impact of FUS mutations, expression vectors containing the entire genomic sequence of FUS, up and downstream regions, and native promoter sequences have been generated. The constructs have been tagged with an mCherry fluorescent tag, and three separate pathological mutations (R244C, R521C, and P525L) have been separately inserted. Transgenic mice have been generated using the WT and P525L FUS vectors to provide a highly physiological model of FUS in disease. Within transfected HEK293 cells, insertion of the P525L and R521C FUS mutations leads to relocalisation of FUS from the nucleus to the cytoplasm. R521C and P525L mutant FUS incorporates into cytoplasmic aggregations of untranslated mRNA and RNA binding proteins known as stress granules. The strong relocalisation seen with P525L-FUS is associated with a gain of cytotoxicity. Reversal of this cytoplasmic relocalisation by demethylation of FUS rescues this cytotoxicity, suggesting a toxic gain of cytoplasmic function in the majority of FUS mutations. By contrast, insertion of the R244C mutation leads to neither relocalisation, stress granule association, nor cytotoxicity. Notably the R244C mutation, located away from the nuclear localization domain in which the majority of FUS mutations are found, leads to the presence of smaller FUS fragments in western blot analyses. These fragments appear not to be due to splicing defects in FUS but rather are due to post-translational modifications or aberrant protein cleavage. These data suggest an alternative pathway for FUS toxicity based upon a nuclear loss of function.

Published

2013

40. Genetic Dissection of a Prevalent Plasmid-Encoded Conjugation System in Lactococcus lactis

Author

Guillermo Ortiz Charneco, Philip Kelleher, Andrius Buivydas, Hugo Streekstra, Emiel Ver Loren van Themaat, Paul P. de Waal, Jennifer Mahony, and Douwe van Sinderen

Subjects

lactococci, starter culture, dairy fermentation, conjugative plasmid, recombineering, mutagenesis, Microbiology, QR1-502

Abstract

Plasmid pNP40, which was first identified nearly 40 years ago in Lactococcus lactis subsp. lactis biovar diacetylactis DRC3, encodes functions such as heavy metal-, bacteriophage-, and nisin-resistance, as well as plasmid transfer ability by conjugation. Here, we report an optimized conjugation protocol for this plasmid, yielding a transfer frequency that is approximately 4,000-fold higher than those previously reported in literature, while we also observed high-frequency plasmid co-mobilization. Individual mutations in 18 genes that encompass the presumed conjugation cluster of pNP40 were generated using ssDNA recombineering to evaluate the role of each gene in the conjugation process. A possible transcriptional repressor of this conjugation cluster, the product of the traR gene, was identified in this manner. This mutational analysis, paired with bioinformatic predictions as based on sequence and structural similarities, allowed us to generate a preliminary model of the pNP40 conjugation machinery.

Published

2021

41. Novel Technologies for Optimal Strain Breeding

Author

Bott, Michael, Eggeling, Lothar, Scheper, Thomas, Series editor, Belkin, Shimshon, Series editor, Bley, Thomas, Series editor, Bohlmann, Jörg, Series editor, Gu, Man Bock, Series editor, Hu, Wei-Shou, Series editor, Mattiasson, Bo, Series editor, Nielsen, Jens, Series editor, Seitz, Harald, Series editor, Ulber, Roland, Series editor, Zeng, An-Ping, Series editor, Zhong, Jian-Jiang, Series editor, Zhou, Weichang, Series editor, Yokota, Atsushi, editor, and Ikeda, Masato, editor

Published

2017

42. Genetic Dissection of a Prevalent Plasmid-Encoded Conjugation System in Lactococcus lactis.

Author

Ortiz Charneco, Guillermo, Kelleher, Philip, Buivydas, Andrius, Streekstra, Hugo, van Themaat, Emiel Ver Loren, de Waal, Paul P., Mahony, Jennifer, and van Sinderen, Douwe

Subjects

LACTOCOCCUS lactis, LACTOCOCCUS, SINGLE-stranded DNA, GENETIC mutation, PLANT genetics

Abstract

Plasmid pNP40, which was first identified nearly 40 years ago in Lactococcus lactis subsp. lactis biovar diacetylactis DRC3, encodes functions such as heavy metal-, bacteriophage-, and nisin-resistance, as well as plasmid transfer ability by conjugation. Here, we report an optimized conjugation protocol for this plasmid, yielding a transfer frequency that is approximately 4,000-fold higher than those previously reported in literature, while we also observed high-frequency plasmid co-mobilization. Individual mutations in 18 genes that encompass the presumed conjugation cluster of pNP40 were generated using ssDNA recombineering to evaluate the role of each gene in the conjugation process. A possible transcriptional repressor of this conjugation cluster, the product of the tra R gene, was identified in this manner. This mutational analysis, paired with bioinformatic predictions as based on sequence and structural similarities, allowed us to generate a preliminary model of the pNP40 conjugation machinery. [ABSTRACT FROM AUTHOR]

Published

2021

43. Genetic Manipulation of Non-tuberculosis Mycobacteria

Author

Nyaradzai Mitchell Chimukuche and Monique J. Williams

Subjects

non-tuberculosis mycobacteria (NTMs), mutagenesis, homologous recombination, recombineering, transposon mutagenesis, CRISPR/Cas, Microbiology, QR1-502

Abstract

Non-tuberculosis mycobacteria (NTMs) comprise a large group of organisms that are phenotypically diverse. Analysis of the growing number of completed NTM genomes has revealed both significant intra-genus genetic diversity, and a high percentage of predicted genes that appear to be unique to this group. Most NTMs have not been studied, however, the rise in NTM infections in several countries has prompted increasing interest in these organisms. Mycobacterial research has recently benefitted from the development of new genetic tools and a growing number of studies describing the genetic manipulation of NTMs have now been reported. In this review, we discuss the use of both site-specific and random mutagenesis tools in NTMs, highlighting the challenges that exist in applying these techniques to this diverse group of organisms.

Published

2021

44. Genetic Manipulation of Non-tuberculosis Mycobacteria.

Author

Chimukuche, Nyaradzai Mitchell and Williams, Monique J.

Subjects

SITE-specific mutagenesis, MYCOBACTERIA, GENES, GENOMES, GENETIC engineering

Abstract

Non-tuberculosis mycobacteria (NTMs) comprise a large group of organisms that are phenotypically diverse. Analysis of the growing number of completed NTM genomes has revealed both significant intra-genus genetic diversity, and a high percentage of predicted genes that appear to be unique to this group. Most NTMs have not been studied, however, the rise in NTM infections in several countries has prompted increasing interest in these organisms. Mycobacterial research has recently benefitted from the development of new genetic tools and a growing number of studies describing the genetic manipulation of NTMs have now been reported. In this review, we discuss the use of both site-specific and random mutagenesis tools in NTMs, highlighting the challenges that exist in applying these techniques to this diverse group of organisms. [ABSTRACT FROM AUTHOR]

Published

2021

45. CRISPR-derived genome editing technologies for metabolic engineering.

Author

Nishida, Keiji and Kondo, Akihiko

Subjects

*GENOME editing, *CHROMOSOMAL rearrangement, *GENE expression, *ENGINEERING, *CRISPRS

Abstract

In metabolic engineering, genome editing tools make it much easier to discover and evaluate relevant genes and pathways and construct strains. Clustered regularly interspaced palindromic repeats (CRISPR)-associated (Cas) systems now have become the first choice for genome engineering in many organisms includingindustrially relevant ones. Targeted DNA cleavage by CRISPR-Cas provides variousgenome engineering modes such as indels, replacements, large deletions, knock-in and chromosomal rearrangements, while host-dependent differences in repair pathways need to be considered. The versatility of the CRISPR system has given rise to derivative technologies that complement nuclease-based editing, which causes cytotoxicity especially in microorganisms. Deaminase-mediated base editing installs targeted point mutations with much less toxicity. CRISPRi and CRISPRa can temporarily control gene expression without changing the genomic sequence. Multiplex, combinatorial and large scale editing are made possible by streamlined design and construction of gRNA libraries to further accelerates comprehensive discovery, evaluation and building of metabolic pathways. This review summarizes the technical basis and recent advances in CRISPR-related genome editing tools applied for metabolic engineering purposes, with representative examples of industrially relevant eukaryotic and prokaryotic organisms. • Clustered regularly interspaced palindromic repeats (CRISPR)-associated (Cas) systems now have become the first choice for genome engineering in many organisms including industrially relevant ones for construction of cell factories as well as discovery and evaluation of relevant genes and pathways. • Targeted DNA cleavage by CRISPR-Cas provides various genome engineering modes such as indels, replacements, large deletions, knock-in and chromosomal rearrangements, while host-dependent differences in repair pathways need to be considered. • The versatility of the CRISPR system has given rise to derivative technologies that complement nuclease-based editing, which causes cytotoxicity especially in microorganisms. • Deaminase-mediated base editing is more reliable and applicable to a wider range of organisms because it introduces targeted point mutations with much less toxicity. • CRISPRi and CRISPRa can temporarily control gene expression without changing the genomic sequence, which is suitable for rapid identification and optimization of metabolic pathways. • Multiplex, combinatorial and large scale editing are made possible by streamlined design and construction of gRNA libraries to further accelerates comprehensive discovery, evaluation and building of metabolic pathways. • The technical basis and recent advances in CRISPR-related genome editing tools applied for metabolic engineering purposes and representative milestones of industrially relevant organisms are summarized. [ABSTRACT FROM AUTHOR]

Published

2021

46. Functional analysis of the Mospd gene family

Author

Buerger, Katrin, Forrester, Lesley., and Sharp, Matt

Subjects

591.35, Mospd1, gene targeting, recombineering, heart development

Abstract

Mospd3, a gene located on mouse chromosome 5, was identified in a gene trap screen in ES cells. The gene trap vector integration in multiple copies into the putative promoter of the gene, resulted in a loss of expression of Mospd3 at the trapped allele. In mice generated from ES cells carrying the vector integration it was found that the lack of Mospd3 expression resulted in the death of a proportion of the homozygote mutants within the first day after birth. Homozygote neonates exhibited a thinning of the right ventricular free heart wall which resembles other mouse mutant phenotypes as well as human congenital heart defects caused by a loss of desmosome and adherens junction mediated cell adhesion between cardiomyocytes. The protein encoded by Mospd3, contains an N-terminal Major Sperm Protein (MSP) domain implicated as a mediator of protein- protein interactions, as well as a two C-terminal transmembrane domains. Both, protein structure and phenotypic similarities with defects in desmosomal and adherens junction proteins suggests that Mospd proteins might play a role in cell adhesion and maintaining the structural integrity of the heart. The phenotype of Mospd3 mutants was highly dependent on genetic background, which led us to speculate that there might be genetic redundancy between Mospd3 and its closest family member the X-linked Mospd1. The aims of this thesis were to generate tools to better understand the function of the Mospd gene family in cardiac development as well as assessing genetic redundancy between Mospd1 and Mospd3. A conditional gene targeting strategy was designed for both Mospd genes. Large genomic regions of the Mospd1 and Mospd3 loci were subcloned from bacterial artificial chromosomes (BACs) and using a recombineering approach, loxP sites and a drug selection cassette (neomycin) were placed in precise locations surrounding the MSP domain of both genes. The conditional targeting vectors were electroporated into both CGR8 and E14 ES cells and homologous recombinant clones were identified at a frequency of 2% and 1.3% for Mospd1 and Mospd3 respectively. Five euploid targeted clones for both Mospd1 and Mospd3 have been generated. Transient expression of Cre recombinase in ES cells carrying the conditional Mospd1 allele was used to delete the one copy of this X-linked gene. Phenotypic characterisation of this null ES cell line revealed that Mospd1 is neither essential for ES cell viability and self-renewal, nor for the early differentiation of these cells towards a cardiac fate. In order to investigate the mechanism of action of Mospd proteins, specific polyclonal antibodies were generated to detect either Mospd1 or Mospd3. These antibodies were purified and tested by western blotting using COS7 cells overexpressing either Mospd protein as well as mouse tissue lysates. Whilst the antibodies were found to detect the proteins and differentiate between Mospd1 and Mospd3, they showed insufficient purification to be used in co-localisation and co-immunoprecipitation experiments to identify interacting proteins and determine whether Mospd proteins are involved in cell adhesion complexes. Monoclonal antibodies were subsequently generated and initial western blotting experiments showed promising results, indicating that these antibodies may be better suited for immunohistochemical analysis of Mospd proteins.

Published

2010

47. Bacterial Genetic Engineering by Means of Recombineering for Reverse Genetics

Author

Ursula Fels, Kris Gevaert, and Petra Van Damme

Subjects

bacterial genetics, enterobacteriaceae, (phage-based) homologous recombination, precise genome editing, recombineering, reverse genetics, Microbiology, QR1-502

Abstract

Serving a robust platform for reverse genetics enabling the in vivo study of gene functions primarily in enterobacteriaceae, recombineering -or recombination-mediated genetic engineering-represents a powerful and relative straightforward genetic engineering tool. Catalyzed by components of bacteriophage-encoded homologous recombination systems and only requiring short ∼40–50 base homologies, the targeted and precise introduction of modifications (e.g., deletions, knockouts, insertions and point mutations) into the chromosome and other episomal replicons is empowered. Furthermore, by its ability to make use of both double- and single-stranded linear DNA editing substrates (e.g., PCR products or oligonucleotides, respectively), lengthy subcloning of specific DNA sequences is circumvented. Further, the more recent implementation of CRISPR-associated endonucleases has allowed for more efficient screening of successful recombinants by the selective purging of non-edited cells, as well as the creation of markerless and scarless mutants. In this review we discuss various recombineering strategies to promote different types of gene modifications, how they are best applied, and their possible pitfalls.

Published

2020

48. Deciphering the Role of Holin in Mycobacteriophage D29 Physiology

Author

Varun Rakeshbhai Bavda and Vikas Jain

Subjects

phage infection, phage therapy, mycobacteria, transmission electron microscopy, recombineering, Microbiology, QR1-502

Abstract

In the era of antibiotic resistance, phage therapy is gaining attention for the treatment of pathogenic organisms such as Mycobacterium tuberculosis. The selection of phages for therapeutic purposes depends upon several factors such as the host range that a phage can infect, which can be narrow or broad, time required for the host cell lysis, and the burst size. Mycobacteriophage D29 is a virulent phage that has the ability to infect and kill several slow- and fast-growing mycobacterial species including the pathogenic M. tuberculosis. It, therefore, has the potential to be used in phage therapy against M. tuberculosis. D29 lytic cassette encodes three proteins viz. peptidoglycan hydrolase (LysA), mycolylarabinogalactan esterase (LysB), and holin, which together ensure host cell lysis in a timely manner. In this work, we have scrutinized the importance of holin in mycobacteriophage D29 physiology. Bacteriophage Recombineering of Electroporated DNA (BRED) approach was used to generate D29 holin knockout (D29Δgp11), which was further confirmed by the Deletion amplification detection assay (DADA)-PCR. Our results show that D29Δgp11 is viable and retains plaque-forming ability, although with reduced plaque size. Additionally, the host cell lysis governed by the mutant phage is significantly delayed as compared to the wild-type D29. In the absence of holin, D29 shows increased latent period and reduced burst size. Thus, our experiments show that while holin is dispensable for phage viability, it is essential for the optimal phage-mediated host cell lysis and phage propagation, which further points to the significance of the “clock” function of holin. Taken together, we show the importance of holin in governing timely and efficient host cell lysis for efficient progeny phage release, which further dictates its critical role in phage biology.

Published

2020

49. A Recombinant System and Reporter Viruses for Papiine Alphaherpesvirus 2

Author

Abdul Rahman Siregar, Sabine Gärtner, Jasper Götting, Philipp Stegen, Artur Kaul, Thomas F. Schulz, Stefan Pöhlmann, and Michael Winkler

Subjects

herpesvirus, Papiine alphaherpesvirus 2, fosmid, transformation-associated recombination, recombineering, reporter virus, Microbiology, QR1-502

Abstract

Primate simplex viruses, including Herpes simplex viruses 1 and 2, form a group of closely related herpesviruses, which establish latent infections in neurons of their respective host species. While neuropathogenic infections in their natural hosts are rare, zoonotic transmission of Macacine alphaherpesvirus 1 (McHV1) from macaques to humans is associated with severe disease. Human infections with baboon-derived Papiine alphaherpesvirus 2 (PaHV2) have not been reported, although PaHV2 and McHV1 share several biological properties, including neuropathogenicity in mice. The reasons for potential differences in PaHV2 and McHV1 pathogenicity are presently not understood, and answering these questions will require mutagenic analysis. Here, we report the development of a recombinant system, which allows rescue of recombinant PaHV2. In addition, we used recombineering to generate viruses carrying reporter genes (Gaussia luciferase or enhanced green fluorescent protein), which replicate with similar efficiency as wild-type PaHV2. We demonstrate that these viruses can be used to analyze susceptibility of cells to infection and inhibition of infection by neutralizing antibodies and antiviral compounds. In summary, we created a recombinant system for PaHV2, which in the future will be invaluable for molecular analyses of neuropathogenicity of PaHV2.

Published

2022

50. A useful gene cassette for conditional knock-down of essential genes by targeted promoter replacement in Mycobacteria

Author

Pauline Texier, Michèle Coddeville, Patricia Bordes, and Pierre Genevaux

Subjects

ClpP, Mycobacterium smegmatis, promoter replacement, recombineering, SecA1, tetracycline promoter, Biology (General), QH301-705.5

Abstract

A direct method to study essential genes is to construct conditional knock-down mutants by replacement of their native promoter by an inducible one. In Mycobacteria, replacement of an essential gene promoter with an anhydrotetracycline inducible one was successfully used but required a multi-step approach. In this work, we describe a gene cassette for the engineering of a conditional knock-down mutant, which allows the one-step targeted replacement of mycobacterial promoters by an anhydrotetracycline-inducible promoter. The functionality of this cassette was successfully tested by engineering conditional clpP and SecA1 mutants of Mycobacterium smegmatis.

Published

2018