Cryo-EM structure of Mycobacterium tuberculosis 50S ribosomal subunit bound with clarithromycin reveals dynamic and specific interactions with macrolides.
Wen ZhangZhiFei LiYufan SunPeng CuiJianhua LiangQinghe XingJing WuYanhui XuWenhong ZhangYing ZhangLin HeNing GaoPublished in: Emerging microbes & infections (2022)
Tuberculosis (TB) is the leading infectious disease caused by Mycobacterium tuberculosis ( Mtb ). Clarithromycin (CTY), an analog of erythromycin (ERY), is more potent against multidrug-resistance (MDR) TB. ERY and CTY were previously reported to bind to the nascent polypeptide exit tunnel (NPET) near peptidyl transferase center (PTC), but the only available CTY structure in complex with D. radiodurans ( Dra ) ribosome could be misinterpreted due to resolution limitation. To date, the mechanism of specificity and efficacy of CTY for Mtb remains elusive since the Mtb ribosome-CTY complex structure is still unknown. Here, we employed new sample preparation methods and solved the Mtb ribosome-CTY complex structure at 3.3Å with cryo-EM technique, where the crucial gate site A2062 ( E. coli numbering) is located at the CTY binding site within NPET. Two alternative conformations of A2062, a novel syn -conformation as well as a swayed conformation bound with water molecule at interface, may play a role in coordinating the binding of specific drug molecules. The previously overlooked C-H hydrogen bond (H-bond) and π interaction may collectively contribute to the enhanced binding affinity. Together, our structure data provide a structural basis for the dynamic binding as well as the specificity of CTY and explain of how a single methyl group in CTY improves its potency, which provides new evidence to reveal previously unclear mechanism of translational modulation for future drug design and anti-TB therapy. Furthermore, our sample preparation method may facilitate drug discovery based on the complexes with low water solubility drugs by cryo-EM technique.
Keyphrases
- mycobacterium tuberculosis
- pulmonary tuberculosis
- structural basis
- drug discovery
- helicobacter pylori
- infectious diseases
- escherichia coli
- dna binding
- emergency department
- binding protein
- stem cells
- helicobacter pylori infection
- gene expression
- machine learning
- genome wide
- molecularly imprinted
- bone marrow
- hepatitis c virus
- adverse drug
- crystal structure
- mass spectrometry
- single cell
- smoking cessation