ATP-dependent DNA ligase from bacteriophage T7: Difference between revisions
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===ATP-DEPENDENT DNA LIGASE FROM BACTERIOPHAGE T7=== | ===ATP-DEPENDENT DNA LIGASE FROM BACTERIOPHAGE T7=== | ||
<StructureSection load='1a0i' size='350' side='right' caption='Structure of Bacteriophage T7 DNA Ligase(PDB entry [[1a0i]])' scene=''> | <StructureSection load='1a0i' size='350' side='right' caption='Structure of Bacteriophage T7 DNA Ligase(PDB entry [[1a0i]])' scene=''> | ||
Overview (General Function) | ==Overview (General Function)== | ||
ATP-dependent DNA ligase from bacteriophage T7 (Caudovirales Podoviridae) is used to catalyze a phosphodiester bond between single-strand nicks in double-stranded DNA. This occurs in replication (connecting okazaki fragments), DNA repair (excision repair), and recombination. DNA ligases require either ATP (eukaryotes and viruses) or NAD+ (prokaryotes) as a cofactor. All ligases require a divalent cation for function. Bacteriophage T7 DNA ligase uses Magnesium in vivo. A range of pH 7.2-7.7 is ideal for enzymatic activity. T7 ligase has a molecular weight of 41 kDa. | ATP-dependent DNA ligase from bacteriophage T7 (Caudovirales Podoviridae<ref>McGrath S, van Sinderen D. Bacteriophage: ''Genetics and Molecular Biology.'' Norfolk: Caister Academic Press, 2007. Print.</ref>) is used to catalyze a phosphodiester bond between single-strand nicks in double-stranded DNA. This occurs in replication (connecting okazaki fragments)<ref name="Berg">Berg, Jeremy M, Stryer, Lubert, Tymoczko, John L. ''Biochemistry.'' Sixth edition. New York: W.H. Freeman and Company, 2007: 796. Print.</ref>, DNA repair (excision repair), and recombination. DNA ligases require either ATP (eukaryotes and viruses) or NAD+ (prokaryotes) as a cofactor<ref name="Bacteriophage">PMID: 8626651</ref>. All ligases require a divalent cation for function. Bacteriophage T7 DNA ligase uses Magnesium in vivo. A range of pH 7.2-7.7 is ideal for enzymatic activity. T7 ligase has a molecular weight of 41 kDa<ref name="Crystal">PMID: 8653795</ref>. | ||
== Structure == | |||
ATP-dependent DNA ligase from bacteriophage T7 is monomeric, forming a tertiary structure consisting of two domains (domain 1 and domain 2). Domain 1 (residues 2:240) contains the ATP binding site. Domain 1 is composed of six alpha helices which surround three antiparallel Beta sheets. Domain 2 (residues 241:349) is composed of an antiparallel Beta sheet and an alpha helix. A groove is formed between the two domains; this groove allows ATP to bind with domain 1. The ribose ring of ATP forms hydrogen bonds with the side chains of <scene name='56/567310/Arg_39_arg_55_glu_93/1'>Arg-39, Arg-55, and Glu-93</scene>. Lys-232, Lys-238, and | ATP-dependent DNA ligase from bacteriophage T7 is monomeric, forming a tertiary structure consisting of two domains (domain 1 and domain 2). <scene name='56/567310/Domain_1/2'>Domain 1</scene> (residues 2:240) contains the ATP binding site. Domain 1 is composed of six alpha helices which surround three antiparallel Beta sheets. <scene name='56/567310/Domain_2/2'>Domain 2</scene> (residues 241:349) is composed of an antiparallel Beta sheet and an alpha helix<ref name="Crystal"/>. A groove is formed between the two domains; this groove allows ATP to bind with domain 1. The ribose ring of ATP forms hydrogen bonds with the side chains of <scene name='56/567310/Arg_39_arg_55_glu_93/1'>Arg-39, Arg-55, and Glu-93</scene>. <scene name='56/567310/Lys232_lys238_lys34/2'>Lys-232, Lys-238, and Lys-34</scene> (the catalytic residue) form hydrogen bonds with the three phosphoryl groups of ATP. The 6-amino group of the adenine ring creates hydrogen bonds with the <scene name='56/567310/Ile_33_glu_32/2'>main-chain carbonyl of Ile-33 and the side chain of Glu-32</scene>. This could account for the use of ATP rather than GTP. While consisting of 359 residues, residues 121-127, 307-316, and 350-359 are not easily deciphered from the crystalline structure, and are therefore left out of the diagram<ref name="Crystal"/>. Domain 1 contains the N terminus, while domain 2 contains the C terminus. Multiple N and C terminii are shown in the diagram due to the missing residues. | ||
main-chain carbonyl of Ile-33 and the side chain of Glu-32 | |||
==Catalytic function with DNA== | |||
ATP-dependent DNA ligase from bacteriophage T7 amends a fractured DNA strand through esterification of a 5'- phosphoryl to a 3'- hydroxyl group<ref name="Bacteriophage"/>. This mechanism occurs with the aid of ATP in several steps. First, the ligase is activated through a <scene name='56/567310/Amp_complex/1'>phosphoramidate bond with a lysine residue</scene> in the active site (Lys 34). A pyrophosphate leaves and the enzyme-AMP complex is formed. Next, the AMP is transferred to the 5' phosphate group at the nick in the DNA. Finally, T7 ligase creates the phosphodiester bond between the 5' -phosphoryl and the 3' – hydroxyl group, with AMP being freed<ref name="Crystal"/>. All ATP-dependent DNA ligases contain a conserved amino acid sequence of <scene name='56/567310/Residues_34-39/1'>KxDGxR</scene><ref name="Bacteriophage"/>. This includes the lysine residue which binds the ATP in the groove between the two domains. | |||
</StructureSection> | |||
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==References== | |||
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