Dario Benelli scite author profile

In this work, we have studied the in vitro translational features of a bicistronic mRNA of the extremely thermophilic Archaeon Sulfolobus solfataricus, with the aim of determining the nature of the cis-acting signals controlling the recognition of the translation initiation sites in the Archaea. We found that the most important feature for efficient initiation was the presence of a Shine-Dalgarno (SD)-like ribosome-binding motif, whose disruption entirely abolished the translation of the corresponding cistron. The influence of other features, such as the type of initiation codon, was variable and depended upon the gene and its position in the mRNA. However, the translational block caused by the disruption of the SD sequences could be removed by deleting the 5' untranslated region altogether, thereby creating a 'leaderless' mRNA. This suggests that 'leaderless' initiation operates by a default mechanism that does not require a specific mRNA-rRNA interaction and may be common to all three primary domains of life

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Two different mechanisms for ribosome/mRNA interaction in archaeal translation initiation

Benelli

Maone

Londei

2003

Molecular Microbiology

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SummaryIn this study, we have analysed the features of mRNA/ ribosome interaction in the thermophilic archeon Sulfolobus solfataricus . Leadered mRNAs endowed with Shine-Dalgarno (SD) motifs formed stable binary complexes with 30S subunits, optimally at high temperature (65-70 ∞ ∞ ∞ ∞ C) and without the aid of initiator tRNA (tRNAi) or any factor. 'Toeprinting' assays revealed that the SD motifs were necessary and sufficient to direct the 30S subunit to the translation initiation region. Leaderless mRNAs, i.e. mRNAs entirely lacking a 5 ¢ ¢ ¢ ¢ -untranslated region (UTR), did not interact directly with 30S subunits but required the presence of tRNAi, indicating that codon-anticodon pairing was required for positioning the ribosome on the initiation codon. The data suggest that archaea such as Sulfolobus routinely use two distinct mechanisms for translational initiation. SD-dependent initiation, resembling the pathway prevalent in presentday bacteria, would operate on distal cistrons of polycistronic mRNAs, whereas 'leaderless' initiation, reminiscent of the eukaryotic pathway, would operate on monocistronic mRNAs and on opening cistrons of polycistronic mRNAs.

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Begin at the beginning: evolution of translational initiation

Benelli

Londei

2009

Research in Microbiology

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Translation initiation in Archaea: conserved and domain-specific features

Benelli

Londei

2011

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Initiation is a critical step in translation, during which the ribosome lands on the start codon and sets the correct reading frame for mRNA decoding. The rate and efficiency of translation are largely determined by initiation, which is therefore the preferred target of translation regulation mechanisms. Initiation has incurred an extensive evolutionary divergence among the primary domains of cell descent. The Archaea, albeit prokaryotes, have an initiation mechanism and apparatus more complex than those of the Bacteria; the molecular details of archaeal initiation are just beginning to be unravelled. The most notable aspects of archaeal initiation are the presence of two, perhaps three, distinct mechanisms for mRNA-ribosome interaction and the presence of a relatively large set of IFs (initiation factors), several of which are shared exclusively with the Eukarya. Among these, the protein termed a/eIF2 (archaeal/eukaryotic IF2) and aIF6 (archaeal IF6) are of special interest, since they appear to play key regulatory roles in the Eukarya. Studies of the function of these factors in Archaea have uncovered new features that will help to elucidate their conserved and domain-specific functions.

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Function and ribosomal localization of aIF6, a translational regulator shared by archaea and eukarya

Benelli

Marzi

Mancone

et al. 2008

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The translation factor IF6 is shared by the Archaea and the Eukarya, but is not found in Bacteria. The properties of eukaryal IF6 (eIF6) have been extensively studied, but remain somewhat elusive. eIF6 behaves as a ribosome-anti-association factor and is involved in miRNA-mediated gene silencing; however, it also seems to participate in ribosome synthesis and export. Here we have determined the function and ribosomal localization of the archaeal (Sulfolobus solfataricus) IF6 homologue (aIF6). We find that aIF6 binds specifically to the 50S ribosomal subunits, hindering the formation of 70S ribosomes and strongly inhibiting translation. aIF6 is uniformly expressed along the cell cycle, but it is upregulated following both cold- and heat shock. The aIF6 ribosomal binding site lies in the middle of the 30-S interacting surface of the 50S subunit, including a number of critical RNA and protein determinants involved in subunit association. The data suggest that the IF6 protein evolved in the archaeal–eukaryal lineage to modulate translational efficiency under unfavourable environmental conditions, perhaps acquiring additional functions during eukaryotic evolution.

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Dario Benelli

Cis‐acting signals controlling translational initiation in the thermophilic archaeon Sulfolobus solfataricus

Two different mechanisms for ribosome/mRNA interaction in archaeal translation initiation

Begin at the beginning: evolution of translational initiation

Translation initiation in Archaea: conserved and domain-specific features

Function and ribosomal localization of aIF6, a translational regulator shared by archaea and eukarya

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