The occurrence of 2'-5' oligoadenylates in Escherichia coli

Probing the Backbone Topology of DNA: Synthesis and Properties of 7',5'-Bicyclo-DNA

We describe the synthesis and pairing properties of the novel DNA analogue 7',5'-bicyclo(bc)-DNA. In this analogue, the point of attachment of the connecting phosphodiester group is switched from the 3' to the 7' position of the underlying bicyclic sugar unit and is thus in a topological position that is inaccessible in natural DNA. The corresponding phosphoramidite building blocks carrying all natural nucleobases were synthesized and incorporated into oligonucleotides. From T_m experiments of duplexes with complementary DNA and RNA we find that single modifications are generally well tolerated with some variability as to the nature of the nucleobase. Fully modified oligonucleotides show low affinity for RNA and DNA complements. However, they form antiparallel homo-duplexes with similar thermal stability as DNA. CD spectra of the homo-duplexes show distinct changes in the helix conformation compared to natural DNA. A conformational analysis at the ab initio level of the mononucleosides revealed two minimal energy structures which primarily deviate in the conformation of the cyclopentane ring. Molecular dynamics simulation of a 7',5'-bc-DNA homo-duplex revealed a right-handed structure with a smaller helical rise and a significantly wider minor groove compared to DNA. Interestingly, this duplex is characterized by an atypical, alternating 6'-endo/6'-exo conformational pattern of consecutive nucleotides which seems to be responsible for the poor binding to natural nucleic acids.

Structural aspects of nucleotide ligand binding by a bacterial 2H phosphoesterase

The 2H phosphoesterase family contains enzymes with two His-X-Ser/Thr motifs in the active site. 2H enzymes are found in all kingdoms of life, sharing little sequence identity despite the conserved overall fold and active site. For many 2H enzymes, the physiological function is unknown. Here, we studied the structure of the 2H family member LigT from Escherichia coli both in the apo form and complexed with different active-site ligands, including ATP, 2′-AMP, 3′-AMP, phosphate, and NADP⁺. Comparisons to the well-characterized vertebrate myelin enzyme 2′,3′-cyclic nucleotide 3′-phosphodiesterase (CNPase) highlight specific features of the catalytic cycle and substrate recognition in both enzymes. The role played by the helix α7, unique to CNPases within the 2H family, is apparently taken over by Arg130 in the bacterial enzyme. Other residues and loops lining the active site groove are likely to be important for RNA substrate binding. We visualized conformational changes related to ligand binding, as well as the position of the nucleophilic water molecule. We also present a low-resolution model of E. coli LigT bound to tRNA in solution, and provide a model for RNA binding by LigT, involving flexible loops lining the active site cavity. Taken together, our results both aid in understanding the common features of 2H family enzymes and help highlight the distinct features in the 2H family members, which must result in different reaction mechanisms. Unique aspects in different 2H family members can be observed in ligand recognition and binding, and in the coordination of the nucleophilic water molecule and the reactive phosphate moiety.

An essential role for the antiviral endoribonuclease, RNase-L, in antibacterial immunity

Type I IFNs were discovered as the primary antiviral cytokines and are now known to serve critical functions in host defense against bacterial pathogens. Accordingly, established mediators of IFN antiviral activity may mediate previously unrecognized antibacterial functions. RNase-L is the terminal component of an RNA decay pathway that is an important mediator of IFN-induced antiviral activity. Here, we identify a role for RNase-L in the host antibacterial response. RNase-L(-/-) mice exhibited a dramatic increase in mortality after challenge with Bacillus anthracis and Escherichia coli; this increased susceptibility was due to a compromised immune response resulting in increased bacterial load. Investigation of the mechanisms of RNase-L antibacterial activity indicated that RNase-L is required for the optimal induction of proinflammatory cytokines that play essential roles in host defense from bacterial pathogens. RNase-L also regulated the expression of the endolysosomal protease, cathepsin-E, and endosome-associated activities, that function to eliminate internalized bacteria and may contribute to RNase-L antimicrobial action. Our results reveal a unique role for RNase-L in the antibacterial response that is mediated through multiple mechanisms. As a regulator of fundamental components of the innate immune response, RNase-L represents a viable therapeutic target to augment host defense against diverse microbial pathogens.

Expression of interferon-inducible recombinant human RNase L causes RNA degradation and inhibition of cell growth in Escherichia coli

Interferon-inducible ribonuclease L (RNase L) is a unique ankyrin-repeat containing endoribonuclease activated by 2',5'-oligoadenylate (2-5A) cofactor leading to RNA degradation and apoptosis during antiviral response in mammalian cells. We report that expression of recombinant human RNase L (1-741 a.a.) caused RNA degradation and inhibition of cell growth in Escherichia coli in absence of exogenous 2-5A. On the contrary, expression of a homologous but dominant negative form of murine RNase L (1-656 a.a.), lacking the RNA binding and ribonuclease domain, did not show RNA degradation, rather it stimulated cell growth. Upon computational analysis by pBLAST search, a putative transcription factor (yahD, F64758, and NP_414852) from the E. coli genome showed highest homology (E value=1e(-17)) with 90-259 a.a. region of human RNase L due to ankyrin repeats with conserved GKT motifs. Ankyrin repeats 6-9 of RNase L are involved in 2-5A binding, dimerization, and activation of the ribonuclease. Thus, a biochemically active human RNase L in E. coli strongly suggests for a prokaryotic cell growth-inhibitory mechanism possibly through ankyrin-ankyrin interaction of YahD and RNase L leading to RNA degradation. The mammalian interferon-inducible RNase L and E. coli yahD protein may have common origin for the ankyrin repeats with 2-5A binding sites. Thus, RNA degradation and cell growth inhibition by recombinant human RNase L biochemically reconstituted mammalian cellular response to interferon in E. coli. RNase L has prokaryotic evolutionary history, it is not only an antiviral but also an antibacterial gene.

Natural 2',5'-phosphodiester bonds found at the ligation sites of peach latent mosaic viroid

Peach latent mosaic viroid (PLMVd) is a circular RNA pathogen that replicates in a DNA-independent fashion via a rolling circle mechanism. PLMVd has been shown to self-ligate in vitro primarily via the formation of 2',5'-phosphodiester bonds; however, in vivo the occurrence and necessity of this nonenzymatic mechanism are not evident. Here, we unequivocally report the presence of 2', 5'-phosphodiester bonds at the ligation site of circular PLMVd strands isolated from infected peach leaves. These bonds serve to close the linear conformers (i.e., intermediates), yielding circular ones. Furthermore, these bonds are shown to stabilize the replicational circular templates, resulting in a significant advantage in terms of viroid viability. Although the mechanism responsible for the formation of these 2',5'-phosphodiester bonds remains to be elucidated, a hypothesis describing in vivo nonenzymatic self-ligation is proposed. Most significantly, our results clearly show that 2',5'-phosphodiester bonds are still present in nature and that they are of biological importance.

Peach latent mosaic viroid is locked by a 2',5'-phosphodiester bond produced by in vitro self-ligation

Although some viroid-like satellite RNAs possess self-cleavage and self-ligation activities, we show that the peach latent mosaic viroid (PLMVd) is unique among all known viroids since it also has such activities. These catalytic activities should have important roles in the rolling circle replication of PLMVd. According to this proposed mechanism, self-cleavage of the multimeric strands occurs via hammerhead structures producing monomers possessing 2',3'-cyclic phosphate and 5'-hydroxyl termini. In the most stable predicted secondary structure for PLMVd these two extremities are juxtaposed, in order for self-ligation to occur. To establish the nature of the phosphodiester bond produced by self-ligation, we followed the classical procedure of complete enzymatic RNA hydrolysis coupled with thin layer chromatography fractionation. Using this procedure, we report that the self-ligation of PLMVd transcripts produces almost exclusively the 2',5' isomer (>96%). Primer extension assays also revealed that reverse transcriptase can read througth this 2', 5' linkage, suggesting that it does not prevent further replication of the viroid. Moreover, we have observed that this 2',5' linkage is resistant to the debranching activity contained in nuclear extracts, as well as being capable of preventing further viroid self-cleavage. Thus, if viroids do indeed self-ligate in vivo, the resulting 2', 5'-phosphodiester bond could contribute to the stability of these RNA species. Finally, an analysis of both the sequence and the structural requirements for hammerhead self-cleavage and self-ligation suggests that these two RNA processes may be interrelated. We hypothesize that the intramolecular self-ligation which produces circular conformers may contribute to the circularization step of the rolling circle replication, while the intermolecular non-enzymatic ligation is a potential mechanism for the sequence reassortment of viroids and viroid-like species.

The 2'-5' RNA ligase of Escherichia coli. Purification, cloning, and genomic disruption

An RNA ligase previously detected in extracts of Escherichia coli is capable of joining Saccharomyces cerevisiae tRNA splicing intermediates in the absence of ATP to form a 2'-5' phosphodiester linkage (Greer, C., Javor, B., and Abelson, J. (1983) Cell 33, 899-906). This enzyme specifically ligates tRNA half-molecules containing nucleoside base modifications and shows a preference among different tRNA species. In order to investigate the function of this enzyme in RNA metabolism, the ligase was purified to homogeneity from E. coli lysate utilizing chromatographic techniques and separation of proteins by SDS-polyacrylamide gel electrophoresis. A single polypeptide of approximately 20 kilodaltons exhibited RNA ligase activity. The amino terminus of this protein was sequenced, and the open reading frame (ORF) encoding it was identified by a data base search. This ORF, which encodes a novel protein with a predicted molecular mass of 19.9 kDa, was amplified from E. coli genomic DNA and cloned. ORFs coding for highly similar proteins were detected in Methanococcus jannaschii and Bacillus stearothermophilus. The chromosomal gene encoding RNA ligase in E. coli was disrupted, abolishing ligase activity in cell lysates. Cells lacking ligase activity grew normally under laboratory conditions. However, moderate overexpression of the ligase protein led to slower growth rates and a temperature-sensitive phenotype in both wild-type and RNA ligase knockout strains. The RNA ligase reaction was studied in vitro using purified enzyme and was found to be reversible, indicating that this enzyme may perform cleavage or ligation in vivo.