The chemistry of viomycin

Streetman, William Edward

12 1900

No description available.

Viomycin

The chemistry of viomycin

Kellogg, Craig Kent

05 1900

No description available.

Viomycin

Viomycin: biosynthetic studies and the crystal structure of viomycidine

Floyd, Joseph Calvin

08 1900

No description available.

Viomycin

Biosynthesis

The chemistry and biosynthesis of viomycin

Carter, James Harrison

08 1900

No description available.

Viomycin

Biosynthesis

Activation, incorporation and modification of capreomycidine during viomycin biosynthesis /

Fei, Xiaobo.

January 1900

Thesis (M.S.)--Oregon State University, 2007. / Printout. Includes bibliographical references (leaves 79-87). Also available on the World Wide Web.

Viomycin Biosynthesis.

The structures of viocidic acid, 2-(2,3-dichloro-2-pyrrolin-1-yl)-1-pyrroline, and vicanicin

Suddath, Fred Leroy

05 1900

No description available.

Viomycin

X-ray crystallography

The chemistry of viomycin and the synthesis of some model pyrrolidine amino acids

Nassar, Riyad Farid

12 1900

No description available.

Viomycin

Amino acids

The chemistry of viomycin: the guanido compound

Hayes, Harold Bernard

08 1900

No description available.

Viomycin

Guanidino compounds

Viomycin: the structure of viomycidine

Miller, Edward Gifford

05 1900

No description available.

Viomycin

Guanidino compounds

A tale of two antibiotics : Fusidic acid and Viomycin

Holm, Mikael

January 2016

Antibiotics that target the bacterial ribosome make up about half of all clinically used antibiotics. We have studied two ribosome targeting drugs: Fusidic acid and Viomycin. Fusidic acid inhibits bacterial protein synthesis by binding to elongation factor G (EF-G) on the ribosome, thereby inhibiting translocation of the bacterial ribosome. Viomycin binds directly to the ribosome and inhibits both the fidelity of mRNA decoding and translocation. We found that the mechanisms of inhibition of these two antibiotics were unexpectedly complex. Fusidic acid can bind to EF-G on the ribosome during three separate stages of translocation. Binding of the drug to the first and most sensitive state does not lead to stalling of the ribosome. Rather the ribosome continues unhindered to a downstream state where it stalls for around 8 seconds. Dissociation of fusidic acid from this state allows the ribosome to continue translocating but it soon reaches yet another fusidic acid sensitive state where it can be stalled again, this time for 6 seconds. Viomycin inhibits translocation by binding to the pre-translocation ribosome in competition with EF-G. If viomycin binds before EF-G it stalls the ribosome for 44 seconds, much longer than a normal elongation cycle. Both viomycin and fusidic acid probably cause long queues of ribosomes to build up on the mRNA when they bind. Viomycin inhibits translational fidelity by binding to the ribosome during initial selection. We found that the concentration of viomycin required to bind to the ribosome with a given probability during decoding is proportional to the accuracy of the codon∙anticodon pair being decoded. This demonstrated that long standing models about ribosomal accuracy cannot be correct. Finally, we demonstrated that a common viomycin resistance mutation increases the drug binding rate and decreases its dissociation rate. Our results demonstrate that ribosome targeting drugs have unexpectedly complex mechanisms of action. Both fusidic acid and viomycin preferentially bind to conformations of the ribosome other than those that they stabilize. This suggests that determining the structures of stable drug-bound states may not give sufficient information for drug design.

Protein Synthesis

Antibiotics

Fusidic acid

Viomycin

Translocation

Accuracy