DNA Ligation
Ligation of DNA is a critical step in many modern molecular biology workflows. The sealing of nicks between adjacent residues of a single-strand break on a double-strand substrate and the joining of double-strand breaks are enzymatically catalyzed by DNA ligases. The formation of a phosphodiester bond between the 3' hydroxyl and 5' phosphate of adjacent DNA residues proceeds in three steps: Initially, the ligase is self-adenylated by reaction with free ATP. Next, the adenyl group is transferred to the 5'-phosphorylated end of the "donor" strand. Lastly, the formation of the phosphodiester bond proceeds after reaction of the adenylated donor end with the adjacent 3' hydroxyl acceptor and the release of AMP. In living organisms, DNA ligases are essential enzymes with critical roles in DNA replication and repair. In the lab, DNA ligation is performed for both cloning and non-cloning applications.
Choose Type:
- Electroporation Protocol (C2989)
- NEBNext Quick Ligation Module Protocol (E6056)
- Removal of Single-Stranded Extension Protocol using Mung Bean Nuclease (M0250)
- Transformation Protocol (M0367)
- Transformation Protocol (M0370)
- Ligation Protocol for Cloning with Instant Sticky-end Ligase Master Mix (M0370)
- Ligation Protocol for Cloning with Blunt/TA Ligase Master Mix (M0367)
- Protocol for ssDNA/RNA Ligation (NEB #M0319)
- Optimizing Restriction Endonuclease Reactions
- Ligation Protocol with T3 DNA Ligase (M0317)
- Ligation Protocol with T7 DNA Ligase (M0318)
- E. coli DNA Ligase Protocol (M0205)
- Protocol for 9°N DNA Ligase (M0238)
- Protocol for Taq DNA Ligase (M0208)
- Please see manual (NEB #E7445) for protocols
- Protocol for the Quick Blunting Kit (E1201)
- HiFi Taq DNA Ligase (M0647) Protocol
- Ligation Protocol with T4 DNA Ligase (NEB# M0202)
- Molecular Cloning Technical Guide
- Properties of DNA and RNA Ligases
- Troubleshooting Guide for Cloning
- Troubleshooting Tips for Ligation Reactions
- Troubleshooting Guide for Ligases
- Traditional Cloning Quick Guide
- Tips for Maximizing Ligation Efficiencies
Brochures
Selection Tools
Troubleshooting Guides
Usage Guidelines
- Anton, B.P., Morgan, R.D., Ezraty, B., Manta, B., Barras, F., Berkmen, M. (2019) Complete genome sequence of Escherichia coli BE104, an MC4100 drivative lacking the methionine reductive pathway Microbiol Resour Announc; 8 (29), e00721-19. PubMedID: 31296691, DOI: 10.1128/MRA.00721-19
- Potapov, V., Ong, J.L., Kucera, R.B., Langhorst, B.W., Bilotti, K., Pryor, J.M., Cantor, E.J., Canton, B., Knight, T.F., Evans, T.C., Lohman, G.J.S. (2018) Comprehensive profiling of four base overhang ligation fidelity by T4 DNA ligase and application to DNA assembly ACS Synth Biol; 7 (11), PubMedID: 30335370, DOI: 10.1021/acssynbio.8b00333
Products and content are covered by one or more patents, trademarks and/or copyrights owned or controlled by New England Biolabs, Inc (NEB). The use of trademark symbols does not necessarily indicate that the name is trademarked in the country where it is being read; it indicates where the content was originally developed. All other trademarks are the property of their respective owners. The use of this product may require the buyer to obtain additional third-party intellectual property rights for certain applications. For more information, please email busdev@neb.com.
This product is intended for research purposes only. This product is not intended to be used for therapeutic or diagnostic purposes in humans or animals.
