Multiple segmental and selective isotope labeling of large RNA for NMR structural studies

Multiple segmental and selective isotope labeling of RNA with three segments has been demonstrated by introducing an RNA segment, selectively labeled with ¹³C₉/¹⁵N₂/²H_{(1′, 3′, 4′, 5′, 5′′)}-labeled uridine residues, into the central position of the 20 kDa ε-RNA of Duck Hepatitis B Virus. The RNA molecules were produced via two efficient protocols: a two-step protocol, which uses T4 DNA ligase and T4 RNA ligase 1, and a one-pot protocol, which uses T4 RNA ligase 1 alone. With T4 RNA ligase 1 all not-to-be-ligated termini are usually protected to prevent formation of side products. We show that such labor-intensive protection of termini is not required, provided segmentation sites can be chosen such that the segments fold into the target structure or target-like structures and thus are not trapped into stable alternate structures. These sites can be reliably predicted via DINAMelt. The simplified NMR spectrum provided evidence for the presence of a U28 H₃-imino resonance, previously obscured in the fully labeled sample, and thus of the non-canonical base pair U28:C37. The demonstrated multiple segmental labeling protocols are generally applicable to large RNA molecules and can be extended to more than three segments.     

Polynucleotide 3′-terminal Phosphate Modifications by RNA and DNA Ligases

RNA and DNA ligases catalyze the formation of a phosphodiester bond between the 5′-phosphate and 3′-hydroxyl ends of nucleic acids. In this work, we describe the ability of the thermophilic RNA ligase MthRnl from Methanobacterium thermoautotrophicum to recognize and modify the 3′-terminal phosphate of RNA and single-stranded DNA (ssDNA). This ligase can use an RNA 3′p substrate to generate an RNA 2′,3′-cyclic phosphate or convert DNA3′p to ssDNA^3′pp^5′A. An RNA ligase from the Thermus scotoductus bacteriophage TS2126 and a predicted T4 Rnl1-like protein from Thermovibrio ammonificans, TVa, were also able to adenylate ssDNA 3′p. These modifications of RNA and DNA 3′-phosphates are similar to the activities of RtcA, an RNA 3′-phosphate cyclase. The initial step involves adenylation of the enzyme by ATP, which is then transferred to either RNA 3′p or DNA 3′p to generate the adenylated intermediate. For RNA ^3′pp^5′A, the third step involves attack of the adjacent 2′ hydroxyl to generate the RNA 2′,3′-cyclic phosphate. These steps are analogous to those in classical 5′ phosphate ligation. MthRnl and TS2126 RNA ligases were not able to modify a 3′p in nicked double-stranded DNA. However, T4 DNA ligase and RtcA can use 3′-phosphorylated nicks in double-stranded DNA to produce a 3′-adenylated product. These 3′-terminal phosphate-adenylated intermediates are substrates for deadenylation by yeast 5′Deadenylase. Our findings that classic ligases can duplicate the adenylation and phosphate cyclization activity of RtcA suggests that they have an essential role in metabolism of nucleic acids with 3′-terminal phosphates.     

Kinetic mechanism of nick sealing by T4 RNA ligase 2 and effects of 3′-OH base mispairs and damaged base lesions

T4 RNA ligase 2 (Rnl2) repairs 3′-OH/5′-PO₄ nicks in duplex nucleic acids in which the broken 3′-OH strand is RNA. Ligation entails three chemical steps: reaction of Rnl2 with ATP to form a covalent Rnl2–(lysyl-Nζ)–AMP intermediate (step 1); transfer of AMP to the 5′-PO₄ of the nick to form an activated AppN– intermediate (step 2); and attack by the nick 3′-OH on the AppN– strand to form a 3′–5′ phosphodiester (step 3). Here we used rapid mix-quench methods to analyze the kinetic mechanism and fidelity of single-turnover nick sealing by Rnl2–AMP. For substrates with correctly base-paired 3′-OH nick termini, k_step2 was fast (9.5 to 17.9 sec⁻¹) and similar in magnitude to k_step3 (7.9 to 32 sec⁻¹). Rnl2 fidelity was enforced mainly at the level of step 2 catalysis, whereby 3′-OH base mispairs and oxoguanine, oxoadenine, or abasic lesions opposite the nick 3′-OH elicited severe decrements in the rate of 5′-adenylylation and relatively modest slowing of the rate of phosphodiester synthesis. The exception was the noncanonical A:oxoG base pair, which Rnl2 accepted as a correctly paired end for rapid sealing. These results underscore (1) how Rnl2 requires proper positioning of the 3′-terminal ribonucleoside at the nick for optimal 5′-adenylylation and (2) the potential for nick-sealing ligases to embed mutations during the repair of oxidative damage.     

Male-Specific Coliphages as Indicators of Thermal Inactivation of Pathogens in Biosolids

Male-specific (F⁺) coliphages have been proposed as a candidate indicator of fecal contamination and of virus reduction in waste treatment. However, in this and earlier work with a laboratory thermophilic anaerobic digester, a heat-resistant fraction of F⁺ coliphage populations indigenous to municipal wastewater and sludge was evident. We therefore isolated coliphages from municipal wastewater sludge and from biosolid samples after thermophilic anaerobic digestion to evaluate the susceptibility of specific groups to thermal inactivation. Similar numbers of F⁺ DNA and F⁺ RNA coliphages were found in untreated sludge, but the majority of isolates in digested biosolids were group I F⁺ RNA phages. Separate experiments on individual isolates at 53°C confirmed the apparent heat resistance of group I F⁺ RNA coliphages as well as the susceptibility of group III F⁺ RNA coliphages. Although few F⁺ DNA coliphages were recovered from the treated biosolid samples, thermal inactivation experiments indicated heat resistance similar to that of group I F⁺ RNA phages. Hence, F⁺ DNA coliphage reductions during thermophilic anaerobic digestion are probably related to mechanisms other than thermal inactivation. Further studies should focus on the group III F⁺ RNA coliphages as potential indicators of reductions of heat-resistant pathogens in thermal processes for sludge treatment.     

2′-Phosphate cyclase activity of RtcA: a potential rationale for the operon organization of RtcA with an RNA repair ligase RtcB in Escherichia coli and other bacterial taxa

RNA terminal phosphate cyclase catalyzes the ATP-dependent conversion of a 3′-phosphate RNA end to a 2′,3′-cyclic phosphate via covalent enzyme-(histidinyl-Nϵ)-AMP and RNA(3′)pp(5′)A intermediates. Here, we report that Escherichia coli RtcA (and its human homolog Rtc1) are capable of cyclizing a 2′-phosphate RNA end in high yield. The rate of 2′-phosphate cyclization by RtcA is five orders of magnitude slower than 3′-phosphate cyclization, notwithstanding that RtcA binds with similar affinity to RNA_3′p and RNA_2′p substrates. These findings expand the functional repertoire of RNA cyclase and suggest that phosphate geometry during adenylate transfer to RNA is a major factor in the kinetics of cyclization. RtcA is coregulated in an operon with an RNA ligase, RtcB, that splices RNA 5′-OH ends to either 3′-phosphate or 2′,3′-cyclic phosphate ends. Our results suggest that RtcA might serve an end healing function in an RNA repair pathway, by converting RNA 2′-phosphates, which cannot be spliced by RtcB, to 2′,3′-cyclic phosphates that can be sealed. The rtcBA operon is controlled by the σ⁵⁴ coactivator RtcR encoded by an adjacent gene. This operon arrangement is conserved in diverse bacterial taxa, many of which have also incorporated the RNA-binding protein Ro (which is implicated in RNA quality control under stress conditions) as a coregulated component of the operon.     

Characterization of the coat protein mRNA of southern bean mosaic virus and its relationship to the genomic RNA

RNA isolated from southern bean mosaic virions contains, in small amount, a subgenomic RNA (molecular weight, 0.38 × 10⁶) that serves in vitro as an mRNA for southern bean mosaic virus coat protein. The RNA has a 5′-linked protein indistinguishable from the protein linked to the 5′ end of full-length genomic RNA. Its base sequence, determined to 91 bases from the 3′ end, is identical to the 3′-terminal sequence of the genomic RNA. The results suggest that the coat protein messenger sequence exists as a “silent” cistron near the 3′ end of the genomic RNA.     

The crystal structure of an alternating RNA heptamer r(GUAUACA) forming a six base-paired duplex with 3'-end adenine overhangs

The crystal structure of an alternating RNA heptamer r(GUAUACA) has been determined to 2.0 Å resolution and refined to an R_work of 17.1% and R_free of 18.5% using 2797 reflections. The heptamer crystallized in the space group C222 with a unit cell of a = 25.74, b = 106.58, c = 30.26 Å and two independent strands in the asymmetric unit. Each heptamer forms a duplex with its symmetry-related strand and each duplex contains six Watson–Crick base pairs and 3′-end adenosine overhangs. Therefore, two kinds of duplex (duplex 1 and duplex 2) are formed. Duplexes 1 stack on each other forming a pseudo-continuous column, which is typical of the RNA packing mode, while duplex 2 is typical of A-DNA packing with its termini in abutting interactions. Overhang adenine residues stack within the duplexes with C3′-endo sugar pucker and C2′-endo sugar pucker in duplexes 1 and 2, respectively. A Na⁺ ion in the crystal lattice is water bridged to two N1 atoms of symmetry-related A7 bases.     

Crystal Structure of the Dengue Virus Methyltransferase Bound to a 5′-Capped Octameric RNA

The N-terminal domain of the flavivirus NS5 protein functions as a methyltransferase (MTase). It sequentially methylates the N7 and 2′-O positions of the viral RNA cap structure (GpppA→^7meGpppA→^7meGpppA_2′-O-me). The same NS5 domain could also have a guanylyltransferase activity (GTP+ppA-RNA→GpppA). The mechanism by which this protein domain catalyzes these three distinct functions is currently unknown. Here we report the crystallographic structure of DENV-3 MTase in complex with a 5′-capped RNA octamer (G_pppAGAACCUG) at a resolution of 2.9 Å. Two RNA octamers arranged as kissing loops are encircled by four MTase monomers around a 2-fold non-crystallography symmetry axis. Only two of the four monomers make direct contact with the 5′ end of RNA. The RNA structure is stabilised by the formation of several intra and intermolecular base stacking and non-canonical base pairs. The structure may represent the product of guanylylation of the viral genome prior to the subsequent methylation events that require repositioning of the RNA substrate to reach to the methyl-donor sites. The crystal structure provides a structural explanation for the observed trans-complementation of MTases with different methylation defects.     

Structure–activity relationships in human RNA 3′-phosphate cyclase

RNA 3′-phosphate cyclase (Rtc) enzymes are a widely distributed family that catalyze the synthesis of RNA 2′,3′ cyclic phosphate ends via an ATP-dependent pathway comprising three nucleotidyl transfer steps: reaction of Rtc with ATP to form a covalent Rtc-(histidinyl-N)-AMP intermediate and release PP_i; transfer of AMP from Rtc1 to an RNA 3′-phosphate to form an RNA(3′)pp(5′)A intermediate; and attack by the terminal nucleoside O2′ on the 3′-phosphate to form an RNA 2′,3′ cyclic phosphate product and release AMP. Here we used the crystal structure of Escherichia coli RtcA to guide a mutational analysis of the human RNA cyclase Rtc1. An alanine scan defined seven conserved residues as essential for the Rtc1 RNA cyclization and autoadenylylation reactions. Structure–activity relationships were clarified by conservative substitutions. Our results are consistent with a mechanism of adenylate transfer in which attack of the Rtc1 His320 nucleophile on the ATP α phosphorus is facilitated by proper orientation of the PP_i leaving group via contacts to Arg21, Arg40, and Arg43. We invoke roles for Tyr294 in binding the adenine base and Glu14 in binding the divalent cation cofactor. We find that Rtc1 forms a stable binary complex with a 3′-phosphate terminated RNA, but not with an otherwise identical 3′-OH terminated RNA. Mutation of His320 had little impact on RNA 3′-phosphate binding, signifying that covalent adenylylation of Rtc1 is not a prerequisite for end recognition.     

The nature of actinomycin D binding to d(AACCAXYG) sequence motifs

Earlier studies by others had indicated that actinomycin D (ACTD) binds well to d(AACCATAG) and the end sequence TAG-3′ is essential for its strong binding. In an effort to verify these assertions and to uncover other possible strong ACTD binding sequences as well as to elucidate the nature of their binding, systematic studies have been carried out with oligomers of d(AACCAXYG) sequence motifs, where X and Y can be any DNA base. The results indicate that in addition to TAG-3′, oligomers ending with XAG-3′ and XCG-3′ all provide binding constants ≥1 × 10⁷ M^–1 and even sequences ending with XTG-3′ and XGG-3′ exhibit binding affinities in the range 1–8 × 10⁶ M^–1. The nature of the strong ACTD affinity of the sequences d(A1A2C3C4A5X6Y7G8) was delineated via comparative binding studies of d(AACCAAAG), d(AGCCAAAG) and their base substituted derivatives. Two binding modes are proposed to coexist, with the major component consisting of the 3′-terminus G base folding back to base pair with C4 and the ACTD inserting at A2C3C4 by looping out the C3 while both faces of the chromophore are stacked by A and G bases, respectively. The minor mode is for the G to base pair with C3 and to have the same A/chromophore/G stacking but without a looped out base. These assertions are supported by induced circular dichroic and fluorescence spectral measurements.     

Structure and mechanism of E. coli RNA 2′,3′-cyclic phosphodiesterase

2H (two-histidine) phosphoesterase enzymes are distributed widely in all domains of life and are implicated in diverse RNA and nucleotide transactions, including the transesterification and hydrolysis of cyclic phosphates. Here we report a biochemical and structural characterization of the Escherichia coli 2H protein YapD, which was identified originally as a reversible transesterifying “nuclease/ligase” at RNA 2′,5′-phosphodiesters. We find that YapD is an “end healing” cyclic phosphodiesterase (CPDase) enzyme that hydrolyzes an _HORNA>p substrate with a 2′,3′-cyclic phosphodiester to a _HORNAp product with a 2′-phosphomonoester terminus, without concomitant end joining. Thus we rename this enzyme ThpR (two-histidine 2′,3′-cyclic phosphodiesterase acting on RNA). The 2.0 Å crystal structure of ThpR in a product complex with 2′-AMP highlights the roles of extended histidine-containing motifs ⁴³HxTxxF⁴⁸ and ¹²⁵HxTxxR¹³⁰ in the CPDase reaction. His43-Nε makes a hydrogen bond with the ribose O3′ leaving group, thereby implicating His43 as a general acid catalyst. His125-Nε coordinates the O1P oxygen of the AMP 2′-phosphate (inferred from geometry to derive from the attacking water nucleophile), pointing to His125 as a general base catalyst. Arg130 makes bidentate contact with the AMP 2′-phosphate, suggesting a role in transition-state stabilization. Consistent with these inferences, changing His43, His125, or Arg130 to alanine effaced the CPDase activity of ThpR. Phe48 makes a π–π stack on the adenine nucleobase. Mutating Phe28 to alanine slowed the CPDase by an order of magnitude. The tertiary structure and extended active site motifs of ThpR are conserved in a subfamily of bacterial and archaeal 2H enzymes.     

Hydration of short DNA, RNA and 2'-OMe oligonucleotides determined by osmotic stressing

Studies on hydration are important for better understanding of structure and function of nucleic acids. We compared the hydration of self-complementary DNA, RNA and 2′-O-methyl (2′-OMe) oligonucleotides GCGAAUUCGC, (UA)₆ and (CG)₃ using the osmotic stressing method. The number of water molecules released upon melting of oligonucleotide duplexes, Δn_W, was calculated from the dependence of melting temperature on water activity and the enthalpy, both measured with UV thermal melting experiments. The water activity was changed by addition of ethylene glycol, glycerol and acetamide as small organic co-solutes. The Δn_W was 3–4 for RNA duplexes and 2–3 for DNA and 2′-OMe duplexes. Thus, the RNA duplexes were hydrated more than the DNA and the 2′-OMe oligonucleotide duplexes by approximately one to two water molecules depending on the sequence. Consistent with previous studies, GC base pairs were hydrated more than AU pairs in RNA, whereas in DNA and 2′-OMe oligonucleotides the difference in hydration between these two base pairs was relatively small. Our data suggest that the better hydration of RNA contributes to the increased enthalpic stability of RNA duplexes compared with DNA duplexes.     

Covalent linkage between ribonucleic Acid primer and deoxyribonucleic Acid product of the avian myeloblastosis virus deoxyribonucleic Acid polymerase

Initiation of deoxyribonucleic acid (DNA) synthesis by the avian myeloblastosis virus DNA polymerase was previously suggested to involve a ribonucleic acid (RNA) primer, the initial product being a DNA molecule joined by a phosphodiester bond to the RNA primer. The existence and nature of such an RNA-DNA joint was investigated by assaying for transfer of a ³²P atom from an α-³²P-deoxyribonucleotide to a 2′(3′)-ribonucleotide after alkaline hydrolysis of the polymerase product. Such a transfer was observed, but only from α-³²P-deoxyadenosine triphosphate and only to 2′(3′)-adenosine monophosphate. This same transfer was observed in both the endogenous DNA polymerase reaction of purified virions and the reconstructed reaction of purified DNA polymerase plus purified 60 to 70S viral RNA. These results indicate a high level of specificity for the initiation process and support the idea of a low-molecular-weight initiator RNA as part of the 60 to 70S RNA complex.     

The naturally trans-acting ribozyme RNase P RNA has leadzyme properties

Divalent metal ions promote hydrolysis of RNA backbones generating 5′OH and 2′;3′P as cleavage products. In these reactions, the neighboring 2′OH act as the nucleophile. RNA catalyzed reactions also require divalent metal ions and a number of different metal ions function in RNA mediated cleavage of RNA. In one case, the LZV leadzyme, it was shown that this catalytic RNA requires lead for catalysis. So far, none of the naturally isolated ribozymes have been demonstrated to use lead to activate the nucleophile. Here we provide evidence that RNase P RNA, a naturally trans-acting ribozyme, has leadzyme properties. But, in contrast to LZV RNA, RNase P RNA mediated cleavage promoted by Pb²⁺ results in 5′ phosphate and 3′OH as cleavage products. Based on our findings, we infer that Pb²⁺ activates H₂O to act as the nucleophile and we identified residues both in the substrate and RNase P RNA that most likely influenced the positioning of Pb²⁺ at the cleavage site. Our data suggest that Pb²⁺ can promote cleavage of RNA by activating either an inner sphere H₂O or a neighboring 2′OH to act as nucleophile.     

Highly efficient catalytic RNA cleavage by the cooperative action of two Cu(II) complexes embodied within an antisense oligonucleotide

Based on our recent studies of RNA cleavage by oligonucleotide–terpyridine·Cu(II) complex 5′- and/or 3′-conjugates, we designed 2′-O-methyloligonucleotides with two terpyridine-attached nucleosides at contiguous internal sites. To connect the 2′-terpyridine-modified uridine residue at the 5′-side to the 5′-O-terpyridyl nucleoside residue at the 3′-side, a dimethoxytrityl derivative of 5-hydroxypropyl-5′-O-terpyridyl-2′-deoxyuridine-3′-phosphoramidite was newly synthesized. Using this unit, we constructed two terpyridine conjugates, with either an unusual phophodiester bond or the bond extended by a propanediol(s)-containing linker. Cleavage reactions of the target RNA oligomer, under the conditions of conjugate excess in the presence of Cu(II), indicated that the conjugates precisely cleaved the RNA at the predetermined site and that one propanediol-containing linker was the most appropriate for inducing high cleavage activity. Furthermore, a comparison of the activity of the propanediol agent with those of the control conjugates with one complex confirmed that the two complexes are required for efficient RNA cleavage. The reaction of the novel cleaver revealed a bell-shaped pH–rate profile with a maximum at pH ~7.5, which is a result of the cooperative action of the complexes. In addition, we demonstrated that the agent catalytically cleaves an excess of the RNA, with the kinetic parameter k_cat/K_m = 0.118 nM^–1 h^–1.     

Structures of Bacterial Polynucleotide Kinase in a Michaelis Complex with Nucleoside Triphosphate (NTP)-Mg2+ and 5′-OH RNA and a Mixed Substrate-Product Complex with NTP-Mg2+ and a 5′-Phosphorylated Oligonucleotide

Clostridium thermocellum polynucleotide kinase (CthPnk), the 5′-end-healing module of a bacterial RNA repair system, catalyzes reversible phosphoryl transfer from a nucleoside triphosphate (NTP) donor to a 5′-OH polynucleotide acceptor, either DNA or RNA. Here we report the 1.5-Å crystal structure of CthPnk-D38N in a Michaelis complex with GTP-Mg²⁺ and a 5′-OH RNA oligonucleotide. The RNA-binding mode of CthPnk is different from that of the metazoan RNA kinase Clp1. CthPnk makes hydrogen bonds to the ribose 2′-hydroxyls of the 5′ terminal nucleoside, via Gln51, and the penultimate nucleoside, via Gln83. The 5′-terminal nucleobase is sandwiched by Gln51 and Val129. Mutating Gln51 or Val129 to alanine reduced kinase specific activity 3-fold. Ser37 and Thr80 donate functionally redundant hydrogen bonds to the terminal phosphodiester; a S37A-T80A double mutation reduced kinase activity 50-fold. Crystallization of catalytically active CthPnk with GTP-Mg²⁺ and a 5′-OH DNA yielded a mixed substrate-product complex with GTP-Mg²⁺ and 5′-PO₄ DNA, wherein the product 5′ phosphate group is displaced by the NTP γ phosphate and the local architecture of the acceptor site is perturbed.     

Change of RNase P RNA function by single base mutation correlates with perturbation of metal ion binding in P4 as determined by NMR spectroscopy

The solution structures of two 27 nt RNA hairpins and their complexes with cobalt(III)-hexammine [Co(NH₃)₆³⁺] were determined by NMR spectroscopy. The RNA hairpins are variants of the P4 region from Escherichia coli RNase P RNA: a U-to-A mutant changing the identity of the bulged nucleotide, and a U-to-C, C-to-U double mutant changing only the bulge position. Structures calculated from NMR constraints show that the RNA hairpins adopt different conformations. In the U-to-C, C-to-U double mutant, the conserved bulged uridine in the P4 wild-type stem is found to be shifted in the 3′-direction by one nucleotide when compared with the wild-type structure. Co(NH₃)₆³⁺ is used as a spectroscopic probe for Mg(H₂O)₆²⁺ binding sites because both complexes have octahedral symmetry and have similar radii. Intermolecular NOE crosspeaks between Co(NH₃)₆³⁺ and RNA protons were used to locate the site of Co(NH₃)₆³⁺ binding to both RNA hairpins. The metal ion binds in the major groove near a bulge loop in both mutants, but is shifted 3′ by about one base pair in the double mutant. The change of the metal ion binding site is compared with results obtained on corresponding mutant RNase P RNA molecules as reported by Harris and co-workers (RNA, 1, 210–218).     

Characterization of the 2',3' cyclic phosphodiesterase activities of Clostridium thermocellum polynucleotide kinase-phosphatase and bacteriophage lambda phosphatase

Clostridium thermocellum polynucleotide kinase-phosphatase (CthPnkp) catalyzes 5′ and 3′ end-healing reactions that prepare broken RNA termini for sealing by RNA ligase. The central phosphatase domain of CthPnkp belongs to the dinuclear metallophosphoesterase superfamily exemplified by bacteriophage λ phosphatase (λ-Pase). CthPnkp is a Ni²⁺/Mn²⁺-dependent phosphodiesterase-monoesterase, active on nucleotide and non-nucleotide substrates, that can be transformed toward narrower metal and substrate specificities via mutations of the active site. Here we characterize the Mn²⁺-dependent 2′,3′ cyclic nucleotide phosphodiesterase activity of CthPnkp, the reaction most relevant to RNA repair pathways. We find that CthPnkp prefers a 2′,3′ cyclic phosphate to a 3′,5′ cyclic phosphate. A single H189D mutation imposes strict specificity for a 2′,3′ cyclic phosphate, which is cleaved to form a single 2′-NMP product. Analysis of the cyclic phosphodiesterase activities of mutated CthPnkp enzymes illuminates the active site and the structural features that affect substrate affinity and k_cat. We also characterize a previously unrecognized phosphodiesterase activity of λ-Pase, which catalyzes hydrolysis of bis-p-nitrophenyl phosphate. λ-Pase also has cyclic phosphodiesterase activity with nucleoside 2′,3′ cyclic phosphates, which it hydrolyzes to yield a mixture of 2′-NMP and 3′-NMP products. We discuss our results in light of available structural and functional data for other phosphodiesterase members of the binuclear metallophosphoesterase family and draw inferences about how differences in active site composition influence catalytic repertoire.     

Tuning of conformational preorganization in model 2',5'- and 3',5'-linked oligonucleotides by 3'- and 2'-O-methoxyethyl modification

Conformational properties of trimeric and tetrameric 2′,5′-linked oligonucleotides, 3′-MOE-A₃^2′,5′ (1) and 3′-MOE-A₄^2′,5′ (2), and their 3′,5′-linked analogs, 2′-MOE-A₃^3′,5′ (3) and 2′-MOE-A₄^3′,5′ (4), were examined with the use of heteronuclear NMR spectroscopy. The temperature-dependent ³J_HH, ³J_HP and ³J_CP coupling constants, acquired in the range of 273–343 K, gave insight into the conformation of sugar rings in terms of a two-state North ↔ South (N ↔ S) pseudorotational equilibrium and into the conformation of the sugar–phosphate backbone in the model antisense oligonucleotides 1–4. 2′,5′-linked oligomers 3′-MOE-A₃^2′,5′ (1) and 3′-MOE-A₄^2′,5′ (2) show preference for N-type conformers and indication of A-type conformational features, which is prerequisite for antisense hybridization. The drive of N ↔ S equilibrium in 1–4 has been rationalized with the competing gauche effects of 2′/3′-phosphodiester and 3′/2′-MOE groups, anomeric and steric effects. Furthermore, the pairwise comparisons of 3′-MOE with 3′-OH and 3′-deoxy 2′,5′-linked adenine trimers emphasized the fine tuning of N ↔ S equilibrium in 3′-MOE-A₃^2′,5′ (1) and 3′-MOE-A₄^2′,5′ (2) by the steric effects of 3′-MOE group and the possibility of water-mediated H-bonds with vicinal phosphodiester functionality. In full correspondence, the drive of N ↔ S equilibrium towards N by 2′-MOE in 3′,5′-linked analogs 2′-MOE-A₃^3′,5′ (3) and 2′-MOE-A₄^3′,5′ (4) is weaker in comparison with 3′-OH group in the corresponding ribo analogs. β^t, γ⁺ and ε^– rotamers are preferred in both 2′,5′- and in 3′,5′-linked oligonucleotides 1–4.