Sandbox reserved 1753
From Proteopedia
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The structure of Glycosylase has a couple of different forms in terms of its general structure there is Adenine and Uracil Glycosylase. DNA Uracil-Glycosylase specifically looks for any Uracil in the double-stranded DNA. It looks for Uracil in dsDNA because uracil is only found in ssDNA. So if a Uracil is found in dsDNA then that means the strand has been damaged and needs repair. When Uracil-DNA Glycosylase finds the <scene name='92/927197/Uracil/3'>Uracil</scene> site it binds to it. The <scene name='92/927197/Active_site/1'>Active Site</scene> of Uracil Glycosylase; D145, Y147, F158, N204, H268, L272 is what binds to the double-stranded DNA with the damaged lesion. Then a nucleotide-flipping mechanism flips the site of repair out of the double helix. The dsDNA has a 10bp that contains a U G base pair mismatch. This is what allows Uracil Glycosylase to bind the DNA and flip the damaged site out of the double helix. When flipped out of the helix <scene name='92/927197/Arg_side_chain/1'>ARG 272 side chain</scene> takes its place in the minor groove since AP sites can be mutagenic. The Uracil is then replaced with a Thymine. This is because Uracil and Thymine have identical base pairing properties. Thymine happens to have greater resistance to photochemical mutations which is why we see it in dsDNA and not Uracil. | The structure of Glycosylase has a couple of different forms in terms of its general structure there is Adenine and Uracil Glycosylase. DNA Uracil-Glycosylase specifically looks for any Uracil in the double-stranded DNA. It looks for Uracil in dsDNA because uracil is only found in ssDNA. So if a Uracil is found in dsDNA then that means the strand has been damaged and needs repair. When Uracil-DNA Glycosylase finds the <scene name='92/927197/Uracil/3'>Uracil</scene> site it binds to it. The <scene name='92/927197/Active_site/1'>Active Site</scene> of Uracil Glycosylase; D145, Y147, F158, N204, H268, L272 is what binds to the double-stranded DNA with the damaged lesion. Then a nucleotide-flipping mechanism flips the site of repair out of the double helix. The dsDNA has a 10bp that contains a U G base pair mismatch. This is what allows Uracil Glycosylase to bind the DNA and flip the damaged site out of the double helix. When flipped out of the helix <scene name='92/927197/Arg_side_chain/1'>ARG 272 side chain</scene> takes its place in the minor groove since AP sites can be mutagenic. The Uracil is then replaced with a Thymine. This is because Uracil and Thymine have identical base pairing properties. Thymine happens to have greater resistance to photochemical mutations which is why we see it in dsDNA and not Uracil. | ||
| + | ==References== | ||
| + | <ref>PMID:25252105</ref> | ||
| + | <ref>PMID:8900285</ref> | ||
Revision as of 23:07, 9 October 2022
A NUCLEOTIDE-FLIPPING MECHANISM FROM THE STRUCTURE OF HUMAN URACIL-DNA GLYCOSYLASE BOUND TO DNA
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