Abstract
BackgroundProteins involved in mammalian mitochondrial translation, when compared to analogous bacterial proteins, frequently have additional sequence regions whose structural or functional roles are not always clear. For example, an additional short insert sequence in the bovine mitochondrial initiation factor 2 (IF2mt) seems sufficient to fulfill the added role of eubacterial initiation factor IF1. Prior to our recent cryo-EM study that showed IF2mt to structurally occupy both the IF1 and IF2 binding sites, the spatial separation of these sites, and the short length of the insert sequence, posed ambiguity in whether it could perform the role of IF1 through occupation of the IF1 binding site on the ribosome.ResultsThe present study probes how well computational structure prediction methods can a priori address hypothesized roles of such additional sequences by creating quasi-atomic models of IF2mt using bacterial IF2 cryo-EM densities (that lack the insert sequences). How such initial IF2mt predictions differ from the observed IF2mt cryo-EM map and how they can be suitably improved using further sequence analysis and flexible fitting are analyzed.ConclusionsBy hypothesizing that the insert sequence occupies the IF1 binding site, continuous IF2mt models that occupy both the IF2 and IF1 binding sites can be predicted computationally. These models can be improved by flexible fitting into the IF2mt cryo-EM map to get reasonable quasi-atomic IF2mt models, but the exact orientation of the insert structure may not be reproduced. Specific eukaryotic insert sequence conservation characteristics can be used to predict alternate IF2mt models that have minor secondary structure rearrangements but fewer unusually extended linker regions. Computational structure prediction methods can thus be combined with medium-resolution cryo-EM maps to explore structure-function hypotheses for additional sequence regions and to guide further biochemical experiments, especially in mammalian systems where high-resolution structures are difficult to determine.
Highlights
Ribosomes have to interact with a variety of translation factors and ligands to accurately polymerize amino acids into a protein based on the mRNA codon sequence [1]
Translation initiation in bacteria requires the formation of the 30S initiation complex with the initiator fMet-tRNA in the peptidyl-tRNA binding (P) site
This study provides an example of how specific hypotheses about structure-function relationships of mammalian macromolecular complexes could be initially probed by combining computational modeling with cryo-EM maps of bacterial or mitochondrial complexes
Summary
Ribosomes have to interact with a variety of translation factors and ligands to accurately polymerize amino acids into a protein based on the mRNA codon sequence [1]. Many mitochondrial ribosomal proteins have no homology with known bacterial ribosomal proteins, but even amongst those that do, many have additional sequence regions whose role is not clear [8,10]. There are only two initiation factors required for initiating protein translation in mitoribosomes (IF2mt and IF3mt) [11] as compared to three initiation factors in bacteria (IF1, IF2, IF3) [12]. Translation initiation in bacteria requires the formation of the 30S initiation complex with the initiator fMet-tRNA (fMet-tRNAiMet) in the peptidyl-tRNA binding (P) site Proteins involved in mammalian mitochondrial translation, when compared to analogous bacterial proteins, frequently have additional sequence regions whose structural or functional roles are not always clear. Prior to our recent cryo-EM study that showed IF2mt to structurally occupy both the IF1 and IF2 binding sites, the spatial separation of these sites, and the short length of the insert sequence, posed ambiguity in whether it could perform the role of IF1 through occupation of the IF1 binding site on the ribosome
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