DNA gyrase
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DNA gyrase, often referred to simply as gyrase, is a type II topoisomerase (EC 5.99.1.3) that introduces negative supercoils (or relaxes positive supercoils) into DNA by looping the template so as to form a crossing, then cutting one of the double helices and passing the other through it before releasing the break, changing the linking number by two in each enzymatic step. This process occurs in prokaryotes (particularly in bacteria), whose single circular DNA is cut by DNA gyrase and the two ends are then twisted around each other to form supercoils.
The unique ability of gyrase to introduce negative supercoils into DNA is what allows bacterial DNA to have free negative supercoils. The ability of gyrase to relax positive supercoils comes into play during DNA replication. The right-handed nature of the DNA double helix causes positive supercoils to accumulate ahead of a translocating enzyme, in the case of DNA replication, a DNA polymerase. The ability of gyrase (and topoisomerase IV) to relax positive supercoils allows superhelical tension ahead of the polymerase to be released so that replication can continue.
[edit] Mechanochemical model of gyrase activity
A single molecule study[1] that has characterized gyrase activity as a function of DNA tension (applied force) and ATP has proposed the mechanochemical model shown in the figure. Upon binding to DNA (the "Gyrase-DNA" state), there is a competition between DNA wrapping and dissociation, where increasing DNA tension increases the probability of dissociation. Upon wrapping and ATP hydrolysis, two negative supercoils are introduced into the template, providing opportunities for subsequent wrapping and supercoiling events.
[edit] Inhibition by antibiotics
Gyrase is present in both eukaryotes and prokaryotes but are not entirely similar in structure or sequence, and have different affinities for different molecules. This makes gyrase a good target for antibiotics. Two classes of antibiotics that inhibit gyrase are:
- The aminocoumarins (including novobiocin). Aminocoumarins work by competitive inhibition of energy transduction of DNA gyrase by binding to the ATPase active site located on the GyrB subunit.
- The quinolones (including nalidixic acid and ciprofloxacin). Quinolones bind these enzymes and prevent them from decatenating replicating DNA. Quinolone-resistant bacteria frequently harbor mutated topoisomerases that resist quinolone binding.
[edit] References
- ^ Gore J, Bryant Z, Stone MD, Nollmann M, Cozzarelli NR, Bustamante C, "Mechanochemical Analysis of DNA Gyrase Using Rotor Bead Tracking", Nature 2006 Jan 5 (Vol. 439): 100-104.
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