Directed evolution of the rRNA methylating enzyme Cfr reveals molecular basis of antibiotic resistance

Autor: Adam Frost, Iris D. Young, Kleinman J, James S. Fraser, Stojković, Stephen N. Floor, K. Tsai, Dan S. Tawfik, Danica Galonić Fujimori, Palla A, Alexander G. Myasnikov, Lianet Noda-García
Rok vydání: 2022
Předmět:
Peptidyl transferase
Adenosine
antibiotic resistance
Structural Biology and Molecular Biophysics
Antibiotics
Drug Resistance
Ribosome
Microbial
structural biology
directed evolution
Biology (General)
Genetics
biology
Escherichia coli Proteins
General Neuroscience
Drug Resistance
Microbial
Methylation
General Medicine
Anti-Bacterial Agents
peptidyl transferase center
cryoEM
Infectious Diseases
Medicine
Infection
Research Article
Cfr
medicine.drug_class
QH301-705.5
Science
chemical biology
RRNA methylation
General Biochemistry
Genetics and Molecular Biology
Vaccine Related
Antibiotic resistance
RNA modifications
Biochemistry and Chemical Biology
molecular biophysics
medicine
Escherichia coli
biochemistry
Ribosomal
Binding Sites
General Immunology and Microbiology
E. coli
Methyltransferases
Ribosomal RNA
biology.organism_classification
coli
RNA
Ribosomal
biology.protein
RNA
Biochemistry and Cell Biology
Antimicrobial Resistance
Directed Molecular Evolution
Bacteria
Zdroj: eLife, Vol 11 (2022)
eLife
ISSN: 2050-084X
DOI: 10.7554/elife.70017
Popis: Alteration of antibiotic binding sites through modification of ribosomal RNA (rRNA) is a common form of resistance to ribosome-targeting antibiotics. The rRNA-modifying enzyme Cfr methylates an adenosine nucleotide within the peptidyl transferase center, resulting in the C-8 methylation of A2503 (m8A2503). Acquisition of cfr results in resistance to eight classes of ribosome-targeting antibiotics. Despite the prevalence of this resistance mechanism, it is poorly understood whether and how bacteria modulate Cfr methylation to adapt to antibiotic pressure. Moreover, direct evidence for how m8A2503 alters antibiotic binding sites within the ribosome is lacking. In this study, we performed directed evolution of Cfr under antibiotic selection to generate Cfr variants that confer increased resistance by enhancing methylation of A2503 in cells. Increased rRNA methylation is achieved by improved expression and stability of Cfr through transcriptional and post-transcriptional mechanisms, which may be exploited by pathogens under antibiotic stress as suggested by natural isolates. Using a variant that achieves near-stoichiometric methylation of rRNA, we determined a 2.2 Å cryo-electron microscopy structure of the Cfr-modified ribosome. Our structure reveals the molecular basis for broad resistance to antibiotics and will inform the design of new antibiotics that overcome resistance mediated by Cfr.
eLife digest Antibiotics treat or prevent infections by killing bacteria or slowing down their growth. A large proportion of these drugs do this by disrupting an essential piece of cellular machinery called the ribosome which the bacteria need to make proteins. However, over the course of the treatment, some bacteria may gain genetic alterations that allow them to resist the effects of the antibiotic. Antibiotic resistance is a major threat to global health, and understanding how it emerges and spreads is an important area of research. Recent studies have discovered populations of resistant bacteria carrying a gene for a protein named chloramphenicol-florfenicol resistance, or Cfr for short. Cfr inserts a small modification in to the ribosome that prevents antibiotics from inhibiting the production of proteins, making them ineffective against the infection. To date, Cfr has been found to cause resistance to eight different classes of antibiotics. Identifying which mutations enhance its activity and protect bacteria is vital for designing strategies that fight antibiotic resistance. To investigate how the gene for Cfr could mutate and make bacteria more resistant, Tsai et al. performed a laboratory technique called directed evolution, a cyclic process which mimics natural selection. Genetic changes were randomly introduced in the gene for the Cfr protein and bacteria carrying these mutations were treated with tiamulin, an antibiotic rendered ineffective by the modification Cfr introduces into the ribosome. Bacteria that survived were then selected and had more mutations inserted. By repeating this process several times, Tsai et al. identified ‘super’ variants of the Cfr protein that lead to greater resistance. The experiments showed that these variants boosted resistance by increasing the proportion of ribosomes that contained the protective modification. This process was facilitated by mutations that enabled higher levels of Cfr protein to accumulate in the cell. In addition, the current study allowed, for the first time, direct visualization of how the Cfr modification disrupts the effect antibiotics have on the ribosome. These findings will make it easier for clinics to look out for bacteria that carry these ‘super’ resistant mutations. They could also help researchers design a new generation of antibiotics that can overcome resistance caused by the Cfr protein.
Databáze: OpenAIRE
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