A microscale platform for the comprehensive analysis of bacterial translation initiation

In prokaryotes translation initiation orchestrates protein synthesis through a network of dynamic interactions among the ribosome, mRNA, initiator tRNAfMet, and initiation factors (IFs). Traditional approaches that rely on radioactive labeling or surface immobilization are hindered by inherent safety risks and methodological constraints. We present a fluorescence-based analytical platform that integrates microscale thermophoresis (MST) to investigate translation initiation at the molecular level. Employing fluorescently labeled molecules including the initiator tRNAfMet, mRNA, and Ifs, enabled a detailed characterization of initiation complex assembly as it progresses from bimolecular to higher-order multicomponent states. To expand the fluorescent toolbox for translation studies we established a novel BODIPY-labeling protocol for 70S ribosomes and confirmed their conformational integrity using nano differential scanning fluorimetry (nanoDSF). Our microscale fluorescent system facilitates probing initiation at a variety of steps, since the role of magnesium ions and initiation factors upon 30S initiation complex formation. The same platform can be applied to investigate the effects of different compounds on translation initiation, as demonstrated for a number of antibiotics, aptamers, and antimicrobial peptides. Using this approach, we determined the antibiotic streptomycin dissociation constant for both 30S and 70S ribosomes, which proved identical at 0.3{+/-}0.1 M, and demonstrated the effect of the antimicrobial peptide rumicidin-1 on translation initiation. Offering a cost-effective and high-sensitivity alternative to conventional methods, this approach advances mechanistic understanding of prokaryotic translation and provides a versatile framework for the discovery of novel protein synthesis inhibitors.