Indications for a moonlighting function of translation factor aIF5A in the crenarchaeum Sulfolobus solfataricus

Translation factor a/eIF5A is highly conserved in Eukarya and Archaea. The eukaryal eIF5A protein is required for transit of ribosomes across consecutive proline codons, whereas the function of the archaeal orthologue remains unknown. Here, we provide a first hint for an involvement of Sulfolobus solfataricus (Sso) aIF5A in translation. CRISPR-mediated knock down of the aif5A gene resulted in strong growth retardation, underlining a pivotal function. Moreover, in vitro studies revealed that Sso aIF5A is endowed with endoribonucleolytic activity. Thus, aIF5A appears to be a moonlighting protein that might be involved in protein synthesis as well as in RNA metabolism.

The SmAP2 RNA binding motif in the 3'UTR affects mRNA stability in the crenarchaeum Sulfolobus solfataricus

Sm and Sm-like proteins represent an evolutionarily conserved family with key roles in RNA metabolism in Pro- and Eukaryotes. In this study, a collection of 53 mRNAs that co-purified with Sulfolobus solfataricus (Sso) SmAP2 were surveyed for a specific RNA binding motif (RBM). SmAP2 was shown to bind with high affinity to the deduced consensus RNA binding motif (SmAP2-cRBM) in vitro. Residues in SmAP2 interacting with the SmAP2-cRBM were mapped by UV-induced crosslinking in combination with mass-spectrometry, and verified by mutational analyses. The RNA-binding site on SmAP2 includes a modified uracil binding pocket containing a unique threonine (T₄₀) located on the L3 face and a second residue, K₂₅, located in the pore. To study the function of the SmAP2-RBM in vivo, three authentic RBMs were inserted in the 3′UTR of a lacS reporter gene. The presence of the SmAP2-RBM in the reporter-constructs resulted in decreased LacS activity and reduced steady state levels of lacS mRNA. Moreover, the presence of the SmAP2-cRBM in and the replacement of the lacS 3′UTR with that of Sso2194 encompassing a SmAP2-RBM apparently impacted on the stability of the chimeric transcripts. These results are discussed in light of the function(s) of eukaryotic Lsm proteins in RNA turnover.

sRNA154 a newly identified regulator of nitrogen fixation in Methanosarcina mazei strain Gö1

Trans-encoded sRNA₁₅₄ is exclusively expressed under nitrogen (N)-deficiency in Methanosarcina mazei strain Gö1. The sRNA₁₅₄ deletion strain showed a significant decrease in growth under N-limitation, pointing toward a regulatory role of sRNA₁₅₄ in N-metabolism. Aiming to elucidate its regulatory function we characterized sRNA₁₅₄ by means of biochemical and genetic approaches. 24 homologs of sRNA₁₅₄ were identified in recently reported draft genomes of Methanosarcina strains, demonstrating high conservation in sequence and predicted secondary structure with two highly conserved single stranded loops. Transcriptome studies of sRNA₁₅₄ deletion mutants by an RNA-seq approach uncovered nifH- and nrpA-mRNA, encoding the α-subunit of nitrogenase and the transcriptional activator of the nitrogen fixation (nif)-operon, as potential targets besides other components of the N-metabolism. Furthermore, results obtained from stability, complementation and western blot analysis, as well as in silico target predictions combined with electrophoretic mobility shift-assays_, argue for a stabilizing effect of sRNA₁₅₄ on the polycistronic nif-mRNA and nrpA-mRNA by binding with both loops. Further identified N-related targets were studied, which demonstrates that translation initiation of glnA₂-mRNA, encoding glutamine synthetase2, appears to be affected by sRNA₁₅₄ masking the ribosome binding site, whereas glnA₁-mRNA appears to be stabilized by sRNA₁₅₄. Overall, we propose that sRNA₁₅₄ has a crucial regulatory role in N-metabolism in M. mazei by stabilizing the polycistronic mRNA encoding nitrogenase and glnA₁-mRNA, as well as allowing a feed forward regulation of nif-gene expression by stabilizing nrpA-mRNA. Consequently, sRNA₁₅₄ represents the first archaeal sRNA, for which a positive posttranscriptional regulation is demonstrated as well as inhibition of translation initiation.

Discovery of a Previously Unrecognized Ribonuclease from Escherichia coli That Hydrolyzes 5'-Phosphorylated Fragments of RNA

TrpH or YciV (locus tag b1266) from Escherichia coli is annotated as a protein of unknown function that belongs to the polymerase and histidinol phosphatase (PHP) family of proteins in the UniProt and NCBI databases. Enzymes from the PHP family have been shown to hydrolyze organophosphoesters using divalent metal ion cofactors at the active site. We found that TrpH is capable of hydrolyzing the 3'-phosphate from 3',5'-bis-phosphonucleotides. The enzyme will also sequentially hydrolyze 5'-phosphomononucleotides from 5'-phosphorylated RNA and DNA oligonucleotides, with no specificity toward the identity of the nucleotide base. The enzyme will not hydrolyze RNA or DNA oligonucleotides that are unphosphorylated at the 5'-end of the substrate, but it makes no difference whether the 3'-end of the oligonucleotide is phosphorylated. These results are consistent with the sequential hydrolysis of 5'-phosphorylated mononucleotides from oligonucleotides in the 5' → 3' direction. The catalytic efficiencies for hydrolysis of 3',5'-pAp, p(Ap)A, p(Ap)4A, and p(dAp)4dA were determined to be 1.8 × 10(5), 9.0 × 10(4), 4.6 × 10(4), and 2.9 × 10(3) M(-1) s(-1), respectively. TrpH was found to be more efficient at hydrolyzing RNA oligonucleotides than DNA oligonucleotides. This enzyme can also hydrolyze annealed DNA duplexes, albeit at a catalytic efficiency approximately 10-fold lower than that of the corresponding single-stranded oligonucleotides. TrpH is the first enzyme from E. coli that has been found to possess 5' → 3' exoribonuclease activity. We propose to name this enzyme RNase AM.

Translation initiation in the crenarchaeon Sulfolobus solfataricus: eukaryotic features but bacterial route

The formation of the translation initiation complex represents the rate-limiting step in protein synthesis. Translation initiation in the crenarchaeon Sulfolobus solfataricus depends on several translation IFs (initiation factors), some of which have eukaryal but no bacterial counterparts. In the present paper, we review the current knowledge of the structure, function and evolution of the IFs in S. solfataricus in the context of eukaryotic and bacterial orthologues. Despite similarities between eukaryotic and S. solfataricus IFs, the sequence of events in translation initiation in S. solfataricus follows the bacterial mode.