T4 DNA Ligase (1 U/μL)

Citations & References (3)

Invitrogen™

T4 DNA Ligase (1 U/μL)

Name: T4 DNA Ligase (1 U/μL)
SKU: 15224025
Price: 506.80 USD

T4 DNA Ligase catalyzes the formation of phosphodiester bonds in the presence of ATP between double-stranded DNAs with 3´ hydroxylRead more

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Catalog Number	Quantity
15224025	500 U
15224017	100 U
15224090	4 x 500 U

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Catalog number 15224025

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506,80

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500 U

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506,80

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T4 DNA Ligase catalyzes the formation of phosphodiester bonds in the presence of ATP between double-stranded DNAs with 3´ hydroxyl and 5´ phosphate termini. The unique T4 DNA Ligase buffer optimizes ligation, which can be performed in 5 minutes. Single-stranded nucleic acids are not substrates for this enzyme.

Applications
Cloning (blunt-end or cohesive-end ligation) and adding linkers or adapters to blunt-ended DNA

Source
Purified from E. coli lambda lysogen NM989

Performance and quality testing
Endodeoxyribonuclease, 3´ and 5´ exodeoxyribonuclease assays; ligation efficiency tested

Unit definition
One unit catalyzes the exchange of 1 nmol ³²P-labeled pyrophosphate into ATP in 20 min at 37°C. One unit is equal to approximately 300 cohesive-end ligation units.

Unit reaction conditions
66 mM Tris-HCl (pH 7.6), 6.6 mM MgCl₂, 10 mM DTT, 66 μM ATP, 3.3 μM ³²P-labeled pyrophosphate, and enzyme in 0.1 mL for 20 min at 37°C.

For Research Use Only. Not for use in diagnostic procedures.

Specifications

Compatible Buffer5X Reaction Buffer

Product TypeT4 DNA Ligase

Quantity500 U

Shipping ConditionDry Ice

Concentration1 U/μL

EnzymeLigase

Unit SizeEach

Contents & Storage

T4 DNA Ligase is supplied with a vial of 5X reaction buffer [250 mM Tris-HCl (pH 7.6), 50 mM MgCl₂ , 5 mM ATP, 5 mM DTT, 25% (w/v) polyethylene glycol-8000]. Store at -20°C.

Frequently asked questions (FAQs)

What is the difference between T4 DNA Ligase and E.coli DNA Ligase?

The main difference between the 2 enzymes is that E. coli DNA Ligase cannot ligate blunt dsDNA fragments. Both ligases can be used to repair single stranded nicks in duplex DNA and to perform cohesive or sticky end ligations. E. coli DNA Ligase is generally used to seal nicks during second strand cDNA synthesis, since T4 DNA Ligase could result in formation of chimeric inserts.

How can I optimize my ligation reaction?

Please consider the following suggestions:
1– Try different molar ratios of insert to vector. Having an excess of insert is usually what will work, try 1:1 to 15:1 insert:vector.
2– Try increasing the time of the ligation at 37 degrees C.
3– Try performing the ligation at 16 degrees C overnight (you can set it up on your PCR machine).

I cannot transform my cells right away. Can I store my ligation reaction? If so, at what temperature should I store it?

Make sure you have inactivated the ligase and store the ligation reaction at 4 degrees C.

What kind of controls should I have for restriction cloning?

You can have all of the below controls or select the one you consider the most appropriate to the problem you are facing:
1– Transform the E. coli with circular plasmid to assess the competency of the cells (how well they are taking up DNA).
2– Transform and plate the dephosphorylated vector. It will help you assess how well the dephosphorylation worked and what proportion of colonies in your ligation transformation plate could be false positives (re-ligated vector or background).
3– Use T4 DNA igase to re-ligate your cut vector, or lambda DNA/Hind III marker. It will help you assess whether the ligase itself is working properly.

What are common inhibitors of the T4 DNA ligase?

dATP is a competitive inhibitor. Phosphate will reduce ligation efficiency. Detergents in your ligation buffer will likely not affect activity. High levels (0.2M) Na2+, K+, Cs+, Li+, and NH4+ inhibit the enzyme almost completely. Polyamines, spermine, and spermidine also serve as inhibitors.

View all T4 DNA Ligase (1 U/μL), 500 U FAQs

Citations & References (3)

Citations & References

Abstract

Identification of novel non-phosphorylated ligands, which bind selectively to the SH2 domain of Grb7.

Authors: Pero Stephanie C; Oligino Lyn; Daly Roger J; Soden Amy L; Liu Chen; Roller Peter P; Li Peng; Krag David N;

Journal:J Biol Chem

PubMed ID:11809769

'Grb7 is an adapter-type signaling protein, which is recruited via its SH2 domain to a variety of receptor tyrosine kinases (RTKs), including ErbB2 and ErbB3. It is overexpressed in breast, esophageal, and gastric cancers, and may contribute to the invasive potential of cancer cells. Molecular interactions involving Grb7 therefore provide ... More

Presteady-state Analysis of Avian Sarcoma Virus Integrase. I. A SPLICING ACTIVITY AND STRUCTURE-FUNCTION IMPLICATIONS FOR COGNATE SITE RECOGNITION.

Authors: Bao Kogan K; Skalka Anna Marie; Wong Isaac;

Journal:J Biol Chem

PubMed ID:11821409

'Integrase catalyzes insertion of a retroviral genome into the host chromosome. After reverse transcription, integrase binds specifically to the ends of the duplex retroviral DNA, endonucleolytically cleaves two nucleotides from each 3''-end (the processing activity), and inserts these ends into the host DNA (the joining activity) in a concerted manner. ... More

Binding of low affinity N-formyl peptide receptors to G protein. Characterization of a novel inactive receptor intermediate.

Authors: Prossnitz E R; Schreiber R E; Bokoch G M; Ye R D;

Journal:J Biol Chem

PubMed ID:7738006

G protein-coupled seven-transmembrane-containing receptors, such as the N-formyl peptide receptor (FPR) of neutrophils, likely undergo a conformational change upon binding of ligand, which enables the receptor to transmit a signal to G proteins. We have examined the functional significance of numerous conserved charged amino acid residues proposed to be located ... More