In Vivo RNA Chemical Footprinting Analysis in Archaea

In vivo structure probing of RNA in Archaea: novel insights into the ribosome structure of Methanosarcina acetivorans

Structure probing combined with next-generation sequencing (NGS) has provided novel insights into RNA structure-function relationships. To date, such studies have focused largely on bacteria and eukaryotes, with little attention given to the third domain of life, archaea. Furthermore, functional RNAs have not been extensively studied in archaea, leaving open questions about RNA structure and function within this domain of life. With archaeal species being diverse and having many similarities to both bacteria and eukaryotes, the archaea domain has the potential to be an evolutionary bridge. In this study, we introduce a method for probing RNA structure in vivo in the archaea domain of life. We investigated the structure of ribosomal RNA (rRNA) from Methanosarcina acetivorans, a well-studied anaerobic archaeal species, grown with either methanol or acetate. After probing the RNA in vivo with dimethyl sulfate (DMS), Structure-seq2 libraries were generated, sequenced, and analyzed. We mapped the reactivity of DMS onto the secondary structure of the ribosome, which we determined independently with comparative analysis, and confirmed the accuracy of DMS probing in M. acetivorans Accessibility of the rRNA to DMS in the two carbon sources was found to be quite similar, although some differences were found. Overall, this study establishes the Structure-seq2 pipeline in the archaea domain of life and informs about ribosomal structure within M. acetivorans.

Structural Probing with MNase Tethered to Ribosome Assembly Factors Resolves Flexible RNA Regions within the Nascent Pre-Ribosomal RNA

The synthesis of ribosomes involves the correct folding of the pre-ribosomal RNA within pre-ribosomal particles. The first ribosomal precursor or small subunit processome assembles stepwise on the nascent transcript of the 35S gene. At the earlier stages, the pre-ribosomal particles undergo structural and compositional changes, resulting in heterogeneous populations of particles with highly flexible regions. Structural probing methods are suitable for resolving these structures and providing evidence about the architecture of ribonucleoprotein complexes. Our approach used MNase tethered to the assembly factors Nan1/Utp17, Utp10, Utp12, and Utp13, which among other factors, initiate the formation of the small subunit processome. Our results provide dynamic information about the folding of the pre-ribosomes by elucidating the relative organization of the 5′ETS and ITS1 regions within the 35S and U3 snoRNA around the C-terminal domains of Nan1/Utp17, Utp10, Utp12, and Utp13.

Determination of RNA Structure with In Vitro SHAPE Experiments

The structure of an RNA molecule is often critical for its correct functioning, post-transcriptional regulation, and/or translation. Predicting RNA secondary structures with in silico tools is relatively straightforward with the large array of software and webservers available. However, for long RNAs and RNA at high temperatures, in silico predictions are less accurate and require experimental validation. To this end, a variety of structural probing reagents are commonly used, both for in vitro and in vivo mapping of RNA structure. Selective 2'-hydroxyl acylation analyzed by primer extension (SHAPE) experiments make use of a nonbase-specific modifying reagent, acylating all conformationally flexible (mainly single-stranded or unpaired) nucleotides and have been employed both for in vitro and in vivo modification of RNA. Here, we describe a protocol for an in vitro SHAPE experiment, starting from in vitro transcribed RNA using a T7 polymerase system. This RNA is folded and subsequently modified in vitro with the SHAPE-reagent N-methyl isatoic anhydride (NMIA). Primer extension employing a radioactive ³²P-labeled primer that binds the RNA downstream of the structure of interest will generate cDNA until the reverse transcriptase enzyme is halted by the introduced SHAPE modifications. Denaturing acrylamide gel electrophoresis of the pool of ³²P-labeled cDNAs and the corresponding sequencing ladders, followed by autoradiography, will expose these stops in reverse transcription (RT) and will therefore enable to identify single-stranded nucleotides in the RNA of interest. These RT stops and NMIA-modification efficiencies can be quantified with ImageJ software and can be used to validate or increase the accuracy of RNA secondary structure predictions.

Insights into synthesis and function of KsgA/Dim1-dependent rRNA modifications in archaea

Ribosomes are intricate molecular machines ensuring proper protein synthesis in every cell. Ribosome biogenesis is a complex process which has been intensively analyzed in bacteria and eukaryotes. In contrast, our understanding of the in vivo archaeal ribosome biogenesis pathway remains less characterized. Here, we have analyzed the in vivo role of the almost universally conserved ribosomal RNA dimethyltransferase KsgA/Dim1 homolog in archaea. Our study reveals that KsgA/Dim1-dependent 16S rRNA dimethylation is dispensable for the cellular growth of phylogenetically distant archaea. However, proteomics and functional analyses suggest that archaeal KsgA/Dim1 and its rRNA modification activity (i) influence the expression of a subset of proteins and (ii) contribute to archaeal cellular fitness and adaptation. In addition, our study reveals an unexpected KsgA/Dim1-dependent variability of rRNA modifications within the archaeal phylum. Combining structure-based functional studies across evolutionary divergent organisms, we provide evidence on how rRNA structure sequence variability (re-)shapes the KsgA/Dim1-dependent rRNA modification status. Finally, our results suggest an uncoupling between the KsgA/Dim1-dependent rRNA modification completion and its release from the nascent small ribosomal subunit. Collectively, our study provides additional understandings into principles of molecular functional adaptation, and further evolutionary and mechanistic insights into an almost universally conserved step of ribosome synthesis.