Lateral transfer of introns in the cryptophyte plastid genome

Cryptophytes are unicellular eukaryotic algae that acquired photosynthesis secondarily through the uptake and retention of a red-algal endosymbiont. The plastid genome of the cryptophyte Rhodomonas salina CCMP1319 was recently sequenced and found to contain a genetic element similar to a group II intron. Here, we explore the distribution, structure and function of group II introns in the plastid genomes of distantly and closely related cryptophytes. The predicted secondary structures of six introns contained in three different genes were examined and found to be generally similar to group II introns but unusually large in size (including the largest known noncoding intron). Phylogenetic analysis suggests that the cryptophyte group II introns were acquired via lateral gene transfer (LGT) from a euglenid-like species. Unexpectedly, the six introns occupy five distinct genomic locations, suggesting multiple LGT events or recent transposition (or both). Combined with structural considerations, RT–PCR experiments suggest that the transferred introns are degenerate ‘twintrons’ (i.e. nested group II/group III introns) in which the internal intron has lost its splicing capability, resulting in an amalgamation with the outer intron

Divalent Metal Ions Tune the Self-Splicing Reaction of the Yeast Mitochondrial Group II Intron Sc.ai5γ

Group II introns are large ribozymes, consisting of six functionally distinct domains that assemble in the presence of Mg2+ to the active structure catalyzing a variety of reactions. The first step of intron splicing is well characterized by a Michaelis–Menten-type cleavage reaction using a two-piece group II intron: the substrate RNA, the 5′-exon covalently linked to domains 1, 2, and 3, is cleaved upon addition of domain 5 acting as a catalyst. Here we investigate the effect of Ca2+, Mn2+, Ni2+, Zn2+, Cd2+, Pb2+, and [Co(NH3)6]3+ on the first step of splicing of the Saccharomyces cerevisiae mitochondrial group II intron Sc.ai5γ. We find that this group II intron is very sensitive to the presence of divalent metal ions other than Mg2+. For example, the presence of only 5% Ca2+ relative to Mg2+ results in a decrease in the maximal turnover rate k cat by 50%. Ca2+ thereby has a twofold effect: this metal ion interferes initially with folding, but then also competes directly with Mg2+ in the folded state, the latter being indicative of at least one specific Ca2+ binding pocket interfering directly with catalysis. Similar results are obtained with Mn2+, Cd2+, and [Co(NH3)6]3+. Ni2+ is a much more powerful inhibitor and the presence of either Zn2+ or Pb2+ leads to rapid degradation of the RNA. These results show a surprising sensitivity of such a large multidomain RNA on trace amounts of cations other than Mg2+ and raises the question of biological relevance at least in the case of Ca2+

Evidences for a catalytic activity of the DNA double helix in the reaction between DNA, platinum(II), and intercalators.

International audienc

Linkage isomerization reaction of intrastrand cross-links in trans-diamminedichloroplatinum(II)-modified single-stranded oligonucleotides.

The stability of trans-(Pt(NH3)2[d(CGAG)-N7-G,N7-G]) adducts, resulting from cross-links between two guanine residues at d(CGAG) sites within single-stranded oligonucleotides by trans-diamminedichloro-platinum(II), has been studied under various conditions of temperature, salt and pH. The trans-(Pt(NH3)2[d(C GAG)-N7-G,N7-G]) cross-links rearrange into trans-(Pt(NH3)2[d(CGAG)-N3-C,N7-G]) cross-links. The rate of rearrangement is independent of pH, in the range 5-9, and of the nature and concentration of the salt (NaCl or NaCIO4) in the range 10-400 mM. The reaction rate depends upon temperature, the t1/2 values for the disappearance of the (G,G) intrastrand cross-link ranging from 120 h at 30 degrees C to 70 min at 80 degrees C. The linkage isomerization reaction occurs in oligonucleotides as short as the platinated tetramer d(CGAG). Replacement of the intervening residue A by T has no major effect on the reaction. The C residue adjacent to the adduct on the 5' side plays a key-role in the reaction; its replacement by a G, A or T residue prevents the reaction occuring. No rearrangement was observed with the C residue adjacent to the adduct on the 3' side. It is proposed that the linkage isomerization reaction results from a direct attack of the base residue on the platinum(II) square complex

Towards a model for predicting Rho-dependent transcription termination sites

National audienc

Influence of substrate composition on the helicase activity of transcription termination factor Rho: reduced processivity of Rho hexamers during unwinding of RNA-DNA hybrid regions

Transcription termination factor Rho forms ring-shaped hexameric structures that load onto segments of the nascent RNA transcript that are C-rich and mostly single-stranded. This interaction converts Rho hexamers into active molecular motors that use the energy resulting from their ATP hydrolase activity to move towards the transcript 3'-end. Upon translocation along the RNA chain, Rho can displace physical roadblocks, such as those formed by RNA-DNA helices, a feature that is likely central to the transcription termination mechanism. To study this "translocase" (helicase) activity, we have designed a collection of Rho substrate chimeras containing an RNA-DNA helix located at various positions with respect to a short (47 nucleotides) artificial loading site. We show that these synthetic constructs represent interesting model substrates able to engage in a productive interaction with Rho and to direct NTP-dependent [5'-->3']-translocation of the hexamers. Using both single and multiple-cycle experimental set-ups, we have also found that Rho helicase activity is strongly dependent on the substrate composition and reaction conditions. For this reason, the rate-limiting step of the helicase reaction could not be identified unambiguously. Yet, the linear dependence of the reaction rate on the hybrid length suggests that helicase action on the RNA-DNA region could be controlled by a unique slow step such as Rho activation, conformational rearrangement, or DNA release. Moreover, removal of the DNA strand occurred at a significant cost for the Rho enzyme, inducing, on average, dissociation from the substrate for every 60-80 base-pairs of hybrid unwound. These results are discussed in relation to the known requirements for Rho substrates, general features of hexameric helicases, and current models for Rho-dependent transcription termination

Seeking Rho-dependent transcription termination sites within bacterial genomes

International audienc

Identification des sites de terminaison de transcription Rho-dépendantes dans les génomes bactériens

National audienc