Fluoroquinolones: Mechanisms of Action and Resistance

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Uploaded by MechanismsMedicine on Mar 29, 2011

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Animation Description: In this animation, we demonstrate the biology of DNA replication leading to bacterial cell division in a gram positive bacterium, such as S. pneumoniae.
The DNA is shown as a circular double strand within the bacterial cell. Like the DNA of all living organisms, it contains the unique genetic code for all of the proteins required for bacterial survival. Bacteria replicate by a process known as binary fission whereby one bacterium separates into 2 new daughter cells. However, before this can occur, the bacterium must make an identical copy of its complete circular DNA.
DNA replication requires that the two strands of DNA separate so that the genetic code of the bacterium can be read and a new complimentary strand can be created for each of the original strands. To accomplish this, various enzymes known as helicases break the hydrogen bonds between the bases in the two DNA strands, unwind the strands from each other, and stabilize the exposed single strands, preventing them from joining back together.
The points at which the two strands of DNA separate to allow replication of DNA are known as replication forks.
The enzymes DNA polymerase then move along each strand of DNA, behind each replication fork synthesizing new DNA strands (in red) complementary to the original ones.
As the replication forks move forward, positive superhelical twists in the DNA begin to accumulate ahead of them. In order for DNA replication to continue, these superhelical twists must be removed.
The bacterial enzyme, DNA gyrase, which is also known as topoisomerase II, is responsible for removing the positive superhelical twists so that DNA replications can procede. DNA gyrase is an essential bacterial enzyme composed of two A and two B subunits which are products of the gyrA and gyrB genes. This enzyme has other important functions which affect the initiation of DNA replication and transcription of many genes.
With the combined involvement of these enzymes, an entire duplicate copy of the bacterial genome is produced as the 2 replication forks move in opposite directions around the circular DNA genome.
Eventually, as the 2 replication forks meet, 2 new complete chromosomes have been made, each consisting of 1 old and 1 new strand of DNA. This is referred to as semi-conservative replication.
In order to allow the 2 new interlinked chromosomes to come apart, another bacterial enzyme is needed which is known as topoisomerase IV. This enzyme is structurally related to DNA gyrase and is coded for by the parC and parE genes.
Topoisomerase IV allows for the 2 new inter-linked chromosomes to separate so that they can be segregated into 2 new daughter bacterial cells.
Complete separation of bacterial cells
Fluoroquinolones. First mechanism of action -- inhibition of DNA gyrase.
Fluoroquinolones act by inhibiting the activity of both the DNA gyrase and the topoisomerase IV enzymes. For most gram negative bacteria, DNA gyrase is the primary fluoroquinolone target. Fluoroquinolones have been shown to bind specifically to the complex of DNA gyrase and DNA rather than to DNA gyrase alone.
As a result of this binding, quinolones appear to stabilize the enzyme-DNA complexes which in turn results in breaks in the DNA that are fatal to the bacterium.
A second mechanism of fluoroquinolone action is shown here. With some exceptions, topoisomerase IV is the primary target of fluoroquinolone action in most gram positive bacteria such as Staphylococci and Streptococci, with DNA gyrase being a secondary target.
The separation of 2 new interlinked daughter strands of circular DNA is disrupted.
The final result on the bacteria, however, is the same. Bacterial replication is disrupted and the bacterium breaks apart.
The relative potency of different fluoroquinolone antibiotics (and thus their spectrum of activity) is dependent in part on their affinity for either DNA gyrase or topoisomerase IV or both.
One of the most common mechanisms by which bacteria acquire resistance to fluoroquinolones is by spontaneously occurring mutations in chromosomal genes that alter the target enzymes -- DNA gyrase and topoisomerase IV or both. The frequency with which these spontaneous mutations occurs may be in the range of 10-6. The effect of mutations on the activity of an individual fluoroquinolone will vary depending on the number of mutations, the location of the mutations and which target enzyme is affected.
If a mutation occurs (either in the gyrA or gyrB gene) that alters DNA gyrase and results in a reduced affinity of the fluoroquinolone antibiotic for this enzyme, the organism will become resistant.
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Uploader Comments (MechanismsMedicine)

Can anyone write what the guy says?... please.. i'm learning english and can't understand what he says... he speaks too fast for me... PLEASE

laex114 7 months ago
@laex114 Most of the narrative text is provided in the "Animation Description" section (click on "Show more" link under the video to expand)

MechanismsMedicine 7 months ago 3
Adorable video, thank you so much. Bless.

moadpt 10 months ago 2
@moadpt thank you. Your opinion as a physician is particularly valuable.

MechanismsMedicine 10 months ago
amazing videos by MechanismsMedicine, thanx a lot for uploading these videos

sarmad10 10 months ago
It's really inspiring to receive your positive feedback and thank you for the subscription! We look forward to see you on our channel again.

MechanismsMedicine 10 months ago 2

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All Comments (29)

Thank you, it makes studying so much easier....

ps07857 2 weeks ago
hope al you people who are "Medical" take a REAL GOOD LOOK at the HEINOUS effects of these drugs ! It's shocking ! If you get your rocks off in excitement at how it works TAKE A LONG LOOK at what it does to people. Its criminal CRIMINAL!!!!! And if you still go ahead using this stuff -- YOU"RE GUILTY and should take whatever the consequences are ! I guess this is exactly why the MAnufacturers don't care AND THEY KNOW and DID KNOW ALL THE TIME. ---EVIL

Xpozethcorupt 2 months ago
Helps me understand a bit more how my life ended because of FQs... The side effects are not rare, rather they are rarely reported by practitioners who blindly disbelieve the fact without full knowledge of the process that occurs in the body.

GBelair 2 months ago
@magusfire31 Do me a favor though, if oen day someone comes to you and reports the life ending side effects of this drug, please listen to them and take them seriously and be sure to report it.

GBelair 2 months ago
Very nice video. Really helped me understand how Fluoroquinolones work. I am a second year pharmacy student and was referred to this video by my Pharmacotherapy professor during our Infectious Disease module.

magusfire31 3 months ago
Great one!

i've spent hours on understanding the same mechanism through my lecture note, and this vid sums it all up in less than 10 minutes!!

tarfah21 4 months ago
FANTASTIC VIDEO

MrIshaq89 4 months ago
these videos are really helpful.........keep upoading such videos...thanx

vaibushi 5 months ago
Best video ever . it was complete .

mehrshadpiano 5 months ago
@laex114 For bacteria to replicate, they need to duplicate their DNA. As this is helical, and the process separates strands, it gets super coils. These need to be relived by enzymes (DNA gyrase). As they are circular, it ends up as 2 linked rings, that get separated by something similar to DNA gyrase. These involve cutting the DNA and rejoining it. Fluroquinalones act by making the broken DNA-DNA gyrase complex stable, resulting in broken strands, killing the bacteria.

blackjeffrey1 6 months ago

Fluoroquinolones: Mechanisms of Action and Resistance

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