Single-strand binding protein: Difference between revisions
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A single-strand binding protein is able to bind to single stranded [[DNA|DNA]] during the process of DNA [[Semi-conservative replication|semi-conservative replication.]] It prevents the two DNA strands that are being used as templates reannealing to one another. <ref>N. Campbell.(2005) Biology, 7th edition, USA: Pearson Education Inc</ref> | A single-strand binding protein is able to bind to single stranded [[DNA|DNA]] during the process of DNA [[Semi-conservative replication|semi-conservative replication.]] It prevents the two DNA strands that are being used as templates reannealing to one another. <ref>N. Campbell.(2005) Biology, 7th edition, USA: Pearson Education Inc</ref> | ||
Single-strand binding (SSB) proteins work together with DNA helicase to unwind the helix and expose the template bases. SSB proteins assist helicase by stabilising the unwound, single-strand conformation. They also prevent short hairpin helices from forming by straightening out single-stranded DNA on the lagging strand. <ref>Alberts, B. (2008). Molecular biology of the cell. New York: Garland Science. Pg 273.</ref> | Single-strand binding (SSB) proteins work together with DNA helicase to unwind the helix and expose the template bases. SSB proteins assist helicase by stabilising the unwound, single-strand conformation. They also prevent short hairpin helices from forming by straightening out single-stranded DNA on the lagging strand. <ref>Alberts, B. (2008). Molecular biology of the cell. New York: Garland Science. Pg 273.</ref> | ||
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Revision as of 01:45, 28 November 2014
A single-strand binding protein is able to bind to single stranded DNA during the process of DNA semi-conservative replication. It prevents the two DNA strands that are being used as templates reannealing to one another. [1]
Single-strand binding (SSB) proteins work together with DNA helicase to unwind the helix and expose the template bases. SSB proteins assist helicase by stabilising the unwound, single-strand conformation. They also prevent short hairpin helices from forming by straightening out single-stranded DNA on the lagging strand. [2]