Structures of MLSBK antibiotics bound to mutated large ribosomal subunits provide a structural explanation for resistance. Export

@article{Tu:2005, abstract = {Crystal structures of {H}. marismortui large ribosomal subunits containing the mutation {G}2099{A} ({A}2058 in {E}. coli) with erythromycin, azithromycin, clindamycin, virginiamycin {S}, and telithromycin bound explain why eubacterial ribosomes containing the mutation {A}2058{G} are resistant to them. {A}zithromycin binds almost identically to both {G}2099{A} and wild-type subunits, but the erythromycin affinity increases by more than 10(4)-fold, implying that desolvation of the {N}2 of {G}2099 accounts for the low wild-type affinity for macrolides. {A}ll macrolides bind similarly to the {H}. marismortui subunit, but their binding differs significantly from what has been reported in the {D}. radioidurans subunit. {T}he synergy in the binding of streptogramins {A} and {B} appears to result from a reorientation of the base of {A}2103 ({A}2062, {E}. coli) that stacks between them. {T}he structure of large subunit containing a three residue deletion mutant of {L}22 shows a change in the {L}22 structure and exit tunnel shape that illuminates its macrolide resistance phenotype.}, annote = {For biochemical and biophysical methods}, author = {Tu, D. and Blaha, G. and Moore, P. B. and Steitz, T. A.}, citeulike-article-id = {579474}, journal = {Cell}, keywords = {antibiotic\_resistance, azithromycin, clindamycin, crystallography, erythromycin, ribosome, telithromycin, virginiamycin}, month = {Apr}, number = {2}, pages = {257--70}, posted-at = {2006-04-07 13:18:38}, priority = {0}, title = {Structures of {MLSBK} antibiotics bound to mutated large ribosomal subunits provide a structural explanation for resistance.}, volume = {121}, year = {2005} }

TY - JOUR ID - Tu:2005 L3 - citeulike-article-id:579474 N2 - Crystal structures of {H}. marismortui large ribosomal subunits containing the mutation {G}2099{A} ({A}2058 in {E}. coli) with erythromycin, azithromycin, clindamycin, virginiamycin {S}, and telithromycin bound explain why eubacterial ribosomes containing the mutation {A}2058{G} are resistant to them. {A}zithromycin binds almost identically to both {G}2099{A} and wild-type subunits, but the erythromycin affinity increases by more than 10(4)-fold, implying that desolvation of the {N}2 of {G}2099 accounts for the low wild-type affinity for macrolides. {A}ll macrolides bind similarly to the {H}. marismortui subunit, but their binding differs significantly from what has been reported in the {D}. radioidurans subunit. {T}he synergy in the binding of streptogramins {A} and {B} appears to result from a reorientation of the base of {A}2103 ({A}2062, {E}. coli) that stacks between them. {T}he structure of large subunit containing a three residue deletion mutant of {L}22 shows a change in the {L}22 structure and exit tunnel shape that illuminates its macrolide resistance phenotype. IS - 2 JF - Cell EP - 70 TI - Structures of {MLSBK} antibiotics bound to mutated large ribosomal subunits provide a structural explanation for resistance. VL - 121 SP - 257 KW - antibiotic_resistance KW - azithromycin KW - clindamycin KW - crystallography KW - erythromycin KW - ribosome KW - telithromycin KW - virginiamycin AU - Tu, D AU - Blaha, G AU - Moore, PB AU - Steitz, TA PY - 2005/Apr// ER -