Parts of this article (those related to number of pol III enzymes and how the replication fork moves (use DNA polymerase § Pol III, PMID 28002733, 30292863)) need to be updated. (December 2023) |
DNA polymerase III holoenzyme is the primary enzyme complex involved in prokaryotic DNA replication. It was discovered by Thomas Kornberg (son of Arthur Kornberg) and Malcolm Gefter in 1970. The complex has high processivity (i.e. the number of nucleotides added per binding event) and, specifically referring to the replication of the E.coli genome, works in conjunction with four other DNA polymerases (Pol I, Pol II, Pol IV, and Pol V). Being the primary holoenzyme involved in replication activity, the DNA Pol III holoenzyme also has proofreading capabilities that corrects replication mistakes by means of exonuclease activity reading 3'→5' and synthesizing 5'→3'. DNA Pol III is a component of the replisome, which is located at the replication fork.
Components
editThe replisome is composed of the following:
- 2 DNA Pol III enzymes, each comprising α, ε and θ subunits. (It has been proven that there is a third copy of Pol III at the replisome.[1])
- 2 β units (dnaN) which act as sliding DNA clamps, they keep the polymerase bound to the DNA.
- 2 τ units (dnaX) which act to dimerize two of the core enzymes (α, ε, and θ subunits).
- 1 γ unit (also dnaX) which acts as a clamp loader for the lagging strand Okazaki fragments, helping the two β subunits to form a unit and bind to DNA. The γ unit is made up of 5 γ subunits which include 3 γ subunits, 1 δ subunit (holA), and 1 δ' subunit (holB). The δ is involved in copying of the lagging strand.
- Χ (holC) and Ψ (holD) which form a 1:1 complex and bind to γ or τ. X can also mediate the switch from RNA primer to DNA.[2]
Activity
editDNA polymerase III synthesizes base pairs at a rate of around 1000 nucleotides per second.[3] DNA Pol III activity begins after strand separation at the origin of replication. Because DNA synthesis cannot start de novo, an RNA primer, complementary to part of the single-stranded DNA, is synthesized by primase (an RNA polymerase):[citation needed]
("!" for RNA, '"$" for DNA, "*" for polymerase)
--------> * * * * ! ! ! ! _ _ _ _ _ _ _ _ | RNA | <--ribose (sugar)-phosphate backbone G U A U | Pol | <--RNA primer * * * * |_ _ _ _| <--hydrogen bonding C A T A G C A T C C <--template ssDNA (single-stranded DNA) _ _ _ _ _ _ _ _ _ _ <--deoxyribose (sugar)-phosphate backbone $ $ $ $ $ $ $ $ $ $
Addition onto 3'OH
editAs replication progresses and the replisome moves forward, DNA polymerase III arrives at the RNA primer and begins replicating the DNA, adding onto the 3'OH of the primer:[citation needed]
* * * * ! ! ! ! _ _ _ _ _ _ _ _ | DNA | <--deoxyribose (sugar)-phosphate backbone G U A U | Pol | <--RNA primer * * * * |_III_ _| <--hydrogen bonding C A T A G C A T C C <--template ssDNA (single-stranded DNA) _ _ _ _ _ _ _ _ _ _ <--deoxyribose (sugar)-phosphate backbone $ $ $ $ $ $ $ $ $ $
Synthesis of DNA
editDNA polymerase III will then synthesize a continuous or discontinuous strand of DNA, depending if this is occurring on the leading or lagging strand (Okazaki fragment) of the DNA. DNA polymerase III has a high processivity and therefore, synthesizes DNA very quickly. This high processivity is due in part to the β-clamps that "hold" onto the DNA strands.[citation needed]
-----------> * * * * ! ! ! ! $ $ $ $ $ $ _ _ _ _ _ _ _ _ _ _ _ _ _ _| DNA | <--deoxyribose (sugar)-phosphate backbone G U A U C G T A G G| Pol | <--RNA primer * * * * * * * * * *|_III_ _| <--hydrogen bonding C A T A G C A T C C <--template ssDNA (single-stranded DNA) _ _ _ _ _ _ _ _ _ _ <--deoxyribose (sugar)-phosphate backbone $ $ $ $ $ $ $ $ $ $
Removal of primer
editAfter replication of the desired region, the RNA primer is removed by DNA polymerase I via the process of nick translation. The removal of the RNA primer allows DNA ligase to ligate the DNA-DNA nick between the new fragment and the previous strand. DNA polymerase I & III, along with many other enzymes are all required for the high fidelity, high-processivity of DNA replication.[citation needed]
See also
editReferences
edit- ^ Reyes-Lamothe R, Sherratt D, Leake M (2010). "Stoichiometry and Architecture of Active DNA Replication Machinery in Escherichia Coli". Science. 328 (5977): 498–501. Bibcode:2010Sci...328..498R. doi:10.1126/science.1185757. PMC 2859602. PMID 20413500.
- ^ Olson MW, Dallmann HG, McHenry CS (December 1995). "DnaX complex of Escherichia coli DNA polymerase III holoenzyme. The chi psi complex functions by increasing the affinity of tau and gamma for delta.delta' to a physiologically relevant range". J. Biol. Chem. 270 (49): 29570–7. doi:10.1074/jbc.270.49.29570. PMID 7494000.
- ^ Kelman Z, O'Donnell M (1995). "DNA polymerase III holoenzyme: structure and function of a chromosomal replicating machine". Annu. Rev. Biochem. 64: 171–200. doi:10.1146/annurev.bi.64.070195.001131. PMID 7574479.
External links
edit- Overview at Oregon State University
- DNA+Polymerase+III at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
- Clamping down on pathogenic bacteria – how to shut down a key DNA polymerase complex