Features of "All LNA" Duplexes Showing a New Type of Nucleic Acid Geometry.

"Locked nucleic acids" (LNAs) belong to the backbone-modified nucleic acid family. The 2'-O,4'-C-methylene-ß-D-ribofuranose nucleotides are used for single or multiple substitutions in RNA molecules and thereby introduce enhanced bio- and thermostability. This renders LNAs powerful tools for diagnostic and therapeutic applications. RNA molecules maintain the overall canonical A-type conformation upon substitution of single or multiple residues/nucleotides by LNA monomers. The structures of "all" LNA homoduplexes, however, exhibit significant differences in their overall geometry, in particular a decreased twist, roll and propeller twist. This results in a widening of the major groove, a decrease in helical winding, and an enlarged helical pitch. Therefore, the LNA duplex structure can no longer be described as a canonical A-type RNA geometry but can rather be brought into proximity to other backbone-modified nucleic acids, like glycol nucleic acids or peptide nucleic acids. LNA-modified nucleic acids provide thus structural and functional features that may be successfully exploited for future application in biotechnology and drug discovery.

Properties of an LNA-modified ricin RNA aptamer.

'Locked nucleic acids' (LNAs) are sugar modified nucleic acids containing the 2'-O-4'C-methylene-ß-D-ribofuranoses. The substitution of RNAs with LNAs leads to an enhanced thermostability. Aptamers are nucleic acids, which are selected for specific target binding from a large library pool by the 'SELEX' method. Introduction of modified nucleic acids into aptamers can improve their stability. The stem region of a ricin A chain RNA aptamer was substituted by locked nucleic acids. Different constructs of the LNA-substituted aptamers were examined for their thermostability, binding activity, folding and RNase sensitivity as compared to the natural RNA counterpart. The LNA-modified aptamers were active in target binding, while the loop regions and the adjacent stem nucleotides remained unsubstituted. The thermostability and RNase resistance of LNA substituted aptamers were enhanced as compared to the native RNA aptamer. This study supports the approach to substitute the aptamer stem region by LNAs and to leave the loop region unmodified, which is responsible for ligand binding. Thus, LNAs possess an encouraging potential for the development of new stabilized nucleic acids and will promote future diagnostic and therapeutic applications.

The Seryl-tRNA synthetase/tRNASer acceptor stem interface is mediated via a specific network of water molecules.

tRNAs are aminoacylated by the aminoacyl-tRNA synthetases. There are at least 20 natural amino acids, but due to the redundancy of the genetic code, 64 codons on the mRNA. Therefore, there exist tRNA isoacceptors that are aminoacylated with the same amino acid, but differ in their sequence and in the anticodon. tRNA identity elements, which are sequence or structure motifs, assure the amino acid specificity. The Seryl-tRNA synthetase is an enzyme that depends on rather few and simple identity elements in tRNA(Ser). The Seryl-tRNA-synthetase interacts with the tRNA(Ser) acceptor stem, which makes this part of the tRNA a valuable structural element for investigating motifs of the protein-RNA complex. We solved the high resolution crystal structures of two tRNA(Ser) acceptor stem microhelices and investigated their interaction with the Seryl-tRNA-synthetase by superposition experiments. The results presented here show that the amino acid side chains Ser151 and Ser156 of the synthetase are interacting in a very similar way with the RNA backbone of the microhelix and that the involved water molecules have almost identical positions within the tRNA/synthetase interface.

The crystal structure of an 'All Locked' nucleic acid duplex.

'Locked nucleic acids' (LNAs) are known to introduce enhanced bio- and thermostability into natural nucleic acids rendering them powerful tools for diagnostic and therapeutic applications. We present the 1.9 Å X-ray structure of an 'all LNA' duplex containing exclusively modified ß-D-2'-O-4'C-methylene ribofuranose nucleotides. The helix illustrates a new type of nucleic acid geometry that contributes to the understanding of the enhanced thermostability of LNA duplexes. A notable decrease of several local and overall helical parameters like twist, roll and propeller twist influence the structure of the LNA helix and result in a widening of the major groove, a decrease in helical winding and an enlarged helical pitch. A detailed structural comparison to the previously solved RNA crystal structure with the corresponding base pair sequence underlines the differences in conformation. The surrounding water network of the RNA and the LNA helix shows a similar hydration pattern.

Superposition of two tRNASer acceptor stem crystal structures: comparison of structure, ligands and hydration.

We solved the X-ray structures of two Escherichia coli tRNA(Ser) acceptor stem microhelices. As both tRNAs are aminoacylated by the same seryl-tRNA-synthetase, we performed a comparative structure analysis of both duplexes to investigate the helical conformation, the hydration patterns and magnesium binding sites. It is well accepted, that the hydration of RNA plays an important role in RNA-protein interactions and that the extensive solvent content of the minor groove has a special function in RNA. The detailed comparison of both tRNA(Ser) microhelices provides insights into the structural arrangement of the isoacceptor tRNA aminoacyl stems with respect to the surrounding water molecules and may eventually help us to understand their biological function at atomic resolution.

Crystallization and preliminary X-ray diffraction data of an LNA 7-mer duplex derived from a ricin aptamer.

Locked nucleic acids (LNAs) are modified nucleic acids which contain a modified sugar such as beta-D-2'-O,4'-C methylene-bridged ribofuranose or other sugar derivatives in LNA analogues. The beta-D-2'-O,4'-C methylene ribofuranose LNAs in particular possess high stability and melting temperatures, which makes them of interest for stabilizing the structure of different nucleic acids. Aptamers, which are DNAs or RNAs targeted against specific ligands, are candidates for substitution with LNAs in order to increase their stability. A 7-mer helix derived from the terminal part of an aptamer that was targeted against ricin was chosen. The ricin aptamer originally consisted of natural RNA building blocks and showed high affinity in ricin binding. For future stabilization of the aptamer, the terminal helix has been constructed as an ;all-locked' LNA and was successfully crystallized in order to investigate its structural properties. Optimization of crystal growth succeeded by the use of different metal salts as additives, such as CuCl(2), MgCl(2), MnCl(2), CaCl(2), CoCl(2) and ZnSO(4). Preliminary X-ray diffraction data were collected and processed to 2.8 A resolution. The LNA crystallized in space group P6(5), with unit-cell parameters a = 50.11, b = 50.11, c = 40.72 A. The crystals contained one LNA helix per asymmetric unit with a Matthews coefficient of 3.17 A(3) Da(-1), which implies a solvent content of 70.15%.

Crystallization and X-ray diffraction analysis of an 'all-locked' nucleic acid duplex derived from a tRNA(Ser) microhelix.

Modified nucleic acids are of great interest with respect to their nuclease resistance and enhanced thermostability. In therapeutical and diagnostic applications, such molecules can substitute for labile natural nucleic acids that are targeted against particular diseases or applied in gene therapy. The so-called 'locked nucleic acids' contain modified sugar moieties such as 2'-O,4'-C-methylene-bridged beta-D-ribofuranose and are known to be very stable nucleic acid derivatives. The structure of locked nucleic acids in single or multiple LNA-substituted natural nucleic acids and in LNA-DNA or LNA-RNA heteroduplexes has been well investigated, but the X-ray structure of an ;all-locked' nucleic acid double helix has not been described to date. Here, the crystallization and X-ray diffraction data analysis of an 'all-locked' nucleic acid helix, which was designed as an LNA originating from a tRNA(Ser) microhelix RNA structure, is presented. The crystals belonged to space group C2, with unit-cell parameters a = 77.91, b = 40.74, c = 30.06 A, beta = 91.02 degrees . A high-resolution and a low-resolution data set were recorded, with the high-resolution data showing diffraction to 1.9 A resolution. The crystals contained two double helices per asymmetric unit, with a Matthews coefficient of 2.48 A(3) Da(-1) and a solvent content of 66.49% for the merged data.

The 1.2A crystal structure of an E. coli tRNASer)acceptor stem microhelix reveals two magnesium binding sites.

tRNA identity elements assure the correct aminoacylation of tRNAs by the cognate aminoacyl-tRNA synthetases. tRNA(Ser) belongs to the so-called class II system, in which the identity elements are rather simple and are mostly located in the acceptor stem region, in contrast to 'class I', where tRNA determinants are more complex and are located within different regions of the tRNA. The structure of an Escherichia coli tRNA(Ser) acceptor stem microhelix was solved by high resolution X-ray structure analysis. The RNA crystallizes in the space group C2, with one molecule per asymmetric unit and with the cell constants a=35.79, b=39.13, c=31.37A, and beta=111.1 degrees . A defined hydration pattern of 97 water molecules surrounds the tRNA(Ser) acceptor stem microhelix. Additionally, two magnesium binding sites were detected in the tRNA(Ser) aminoacyl stem.

Crystal structure of the E. coli tRNA(Arg) aminoacyl stem isoacceptor RR-1660 at 2.0 A resolution.

Due to the redundancy of the genetic code there exist six mRNA codons for arginine and several tRNA(Arg) isoacceptors which translate these triplets to protein within the context of the mRNA. The tRNA identity elements assure the correct aminoacylation of the tRNA with the cognate amino acid by the aminoacyl-tRNA-synthetases. In tRNA(Arg), the identity elements consist of the anticodon, parts of the D-loop and the discriminator base. The minor groove of the acceptor stem interacts with the arginyl-tRNA-synthetase. We crystallized different Escherichia coli tRNA(Arg) acceptor stem helices and solved the structure of the tRNA(Arg) isoacceptor RR-1660 microhelix by X-ray structure analysis. The acceptor stem helix crystallizes in the space group P1 with the cell constants a=26.28, b=28.92, c=29.00 A, alpha=105.74, beta=99.01, gamma=97.44 degrees and two molecules per asymmetric unit. The RNA hydration pattern consists of 88 bound water molecules. Additionally, one glycerol molecule is bound within the interface of the two RNA molecules.

Crystal structure of the human tRNAGly microhelix isoacceptor G9990 at 1.18A resolution.

The tRNA(Gly)/Glycyl-tRNA synthetase system belongs to the so called 'class II' in which tRNA identity elements consist of relative few and simple motifs, as compared to 'class I' where the tRNA determinants are more complicated and spread over different parts of the tRNA, mostly including the anticodon. The determinants from 'class II' although, are located in the aminoacyl stem and sometimes include the discriminator base. There exist predominant structure differences for the Glycyl-tRNA-synthetases and for the tRNA(Gly) identity elements comparing eucaryotic/archaebacterial and eubacterial systems. We focus on comparative X-ray structure analysis of tRNA(Gly) acceptor stem microhelices from different organisms. Here, we report the X-ray structure of the human tRNA(Gly) microhelix isoacceptor G9990 at 1.18A resolution. Superposition experiments to another human tRNA(Gly) microhelix and a detailed comparison of the RNA hydration patterns show a great number of water molecules with identical positions in both RNAs. This is the first structure comparison of hydration layers from two isoacceptor tRNA microhelices with a naturally occurring base pair exchange.

Escherichia coli tRNA(Arg) acceptor-stem isoacceptors: comparative crystallization and preliminary X-ray diffraction analysis.

The aminoacylation of tRNA is a crucial step in cellular protein biosynthesis. Recognition of the cognate tRNA by the correct aminoacyl-tRNA synthetase is ensured by tRNA identity elements. In tRNA(Arg), the identity elements consist of the anticodon, parts of the D-loop and the discriminator base. The minor groove of the aminoacyl stem interacts with the arginyl-tRNA synthetase. As a consequence of the redundancy of the genetic code, six tRNA(Arg) isoacceptors exist. In the present work, three different Escherichia coli tRNA(Arg) acceptor-stem helices were crystallized. Two of them, the tRNA(Arg) microhelices RR-1660 and RR-1662, were examined by X-ray diffraction analysis and diffracted to 1.7 and 1.8 A resolution, respectively. The tRNA(Arg) RR-1660 helix crystallized in space group P1, with unit-cell parameters a = 26.28, b = 28.92, c = 29.00 A, alpha = 105.74, beta = 99.01, gamma = 97.44 degrees , whereas the tRNA(Arg) RR-1662 helix crystallized in space group C2, with unit-cell parameters a = 33.18, b = 46.16, c = 26.04 A, beta = 101.50 degrees .

X-ray diffraction analysis of a human tRNA(Gly) acceptor-stem microhelix isoacceptor at 1.18 A resolution.

Interest has been focused on comparative X-ray structure analyses of different tRNA(Gly) acceptor-stem helices. tRNA(Gly)/glycyl-tRNA synthetase belongs to the so-called class II system, in which the tRNA identity elements consist of simple and unique determinants that are located in the tRNA acceptor stem and the discriminator base. Comparative structure investigations of tRNA(Gly) microhelices provide insight into the role of tRNA identity elements. Predominant differences in the structures of glycyl-tRNA synthetases and in the tRNA identity elements between prokaryotes and eukaryotes point to divergence during the evolutionary process. Here, the crystallization and high-resolution X-ray diffraction analysis of a human tRNA(Gly) acceptor-stem microhelix with sequence 5'-G(1)C(2)A(3)U(4)U(5)G(6)G(7)-3', 5'-C(66)C(67)A(68)A(69)U(70)G(71)C(72)-3' is reported. The crystals belonged to the monoclinic space group C2, with unit-cell parameters a = 37.32, b = 37.61, c = 30.47 A, beta = 112.60 degrees and one molecule per asymmetric unit. A data set was collected using synchrotron radiation and data were processed within the resolution range 50.0-1.18 A. The structure was solved by molecular replacement.

tRNASer acceptor stem: conformation and hydration of a microhelix in a crystal structure at 1.8 A resolution.

The crystal structure of a serine-specific tRNA acceptor-stem microhelix, the binding site for the seryl-tRNA synthetase, was solved by X-ray analysis. This seven-base-pair tRNA(Ser) microhelix forms endless rows of helices in the crystal lattice, with two helices stacking 'head-to-head' onto each other, resulting in an intermolecular guanosine stacking of the first purine nucleotides at the 5'-strands of the tRNA(Ser) microhelices. A network of 75 water loci could be associated with each RNA duplex. Unusual local geometric backbone parameters could be detected in the region of the G4 phosphate located in the 5'-strand of the helix, which lead to a ;kink' in this region and to an irregularly bent helix. The role of the specific hydration pattern and of the irregular conformation of the tRNA(Ser) acceptor-stem helix is discussed and summarized.

Cocrystallizing natural RNA with its unnatural mirror image: biochemical and preliminary X-ray diffraction analysis of a 5S rRNA A-helix racemate.

Chemically synthesized RNAs with the unnatural L-configuration possess enhanced in vivo stability and nuclease resistance, which is a highly desirable property for pharmacological applications. For a structural comparison, both L- and D-RNA oligonucleotides of a shortened Thermus flavus 5S rRNA A-helix were chemically synthesized. The enantiomeric RNA duplexes were stochiometrically cocrystallized as a racemate, which enabled analysis of the D- and L-RNA enantiomers in the same crystals. In addition to a biochemical investigation, diffraction data were collected to 3.0 A resolution using synchrotron radiation. The crystals belonged to space group P3(1)21, with unit-cell parameters a = b = 35.59, c = 135.30 A, gamma = 120 degrees and two molecules per asymmetric unit.

Human tRNA(Gly) acceptor-stem microhelix: crystallization and preliminary X-ray diffraction analysis at 1.2 A resolution.

The major dissimilarities between the eukaryotic/archaebacterial-type and eubacterial-type glycyl-tRNA synthetase systems (GlyRS; class II aminoacyl-tRNA synthetases) represent an intriguing example of evolutionarily divergent solutions to similar biological functions. The differences in the identity elements of the respective tRNA(Gly) systems are located within the acceptor stem and include the discriminator base U73. In the present work, the human tRNA(Gly) acceptor-stem microhelix was crystallized in an attempt to analyze the structural features that govern the correct recognition of tRNA(Gly) by the eukaryotic/archaebacterial-type glycyl-tRNA synthetase. The crystals of the human tRNA(Gly) acceptor-stem helix belong to the monoclinic space group C2, with unit-cell parameters a = 37.12, b = 37.49, c = 30.38 A, alpha = gamma = 90, beta = 113.02 degrees, and contain one molecule per asymmetric unit. A high-resolution data set was acquired using synchrotron radiation and the data were processed to 1.2 A resolution.

Crystallization and preliminary X-ray diffraction analysis of an Escherichia coli tRNA(Gly) acceptor-stem microhelix.

The tRNA(Gly) and glycyl-tRNA synthetase (GlyRS) system is an evolutionary special case within the class II aminoacyl-tRNA synthetases because two divergent types of GlyRS exist: an archaebacterial/human type and an eubacterial type. The tRNA identity elements which determine the correct aminoacylation process are located in the aminoacyl domain of tRNA(Gly). To obtain further insight concerning structural investigation of the identity elements, the Escherichia coli seven-base-pair tRNA(Gly) acceptor-stem helix was crystallized. Data were collected to 2.0 A resolution using synchrotron radiation. Crystals belong to space group P3(1)21 or P3(2)21, with unit-cell parameters a = b = 35.35, c = 130.82 A, alpha = beta = 90, gamma = 120 degrees and two molecules in the asymmetric unit.

Comparative crystallization and preliminary X-ray diffraction studies of locked nucleic acid and RNA stems of a tenascin C-binding aptamer.

The pharmacokinetic properties of an aptamer against the tumour-marker protein tenascin-C have recently been successfully improved by the introduction of locked nucleic acids (LNAs) into the terminal stem of the aptamer. Since it is believed that this post-SELEX optimization is likely to provide a more general route to enhance the in vitro and in vivo stability of aptamers, elucidation of the structural basis of this improvement was embarked upon. Here, the crystallographic and X-ray diffraction data of the isolated aptamer stem encompassed in a six-base-pair duplex both with and without the LNA modification are presented. The obtained all-LNA crystals belong to space group P4(1)2(1)2 or P4(3)2(1)2, with unit-cell parameters a = b = 52.80, c = 62.83 angstroms; the all-RNA crystals belong to space group R32, with unit-cell parameters a = b = 45.21, c = 186.97 angstroms, gamma = 120.00 degrees.

Crystallization and preliminary X-ray diffraction analysis of a tRNASer acceptor-stem microhelix.

In order to understand elongator tRNA(Ser) and suppressor tRNA(Sec) identity elements, the respective acceptor-stem helices have been synthesized and crystallized in order to analyse and compare their structures in detail at high resolution. The synthesis, crystallization and preliminary X-ray diffraction results for a seven-base-pair tRNA(Ser) acceptor-stem helix are presented here. Diffraction data were collected to 1.8 A, applying synchrotron radiation and cryogenic cooling. The crystals belong to the monoclinic space group C2, with unit-cell parameters a = 36.14, b = 38.96, c = 30.81 A, beta = 110.69 degrees .

Gaining target access for deoxyribozymes.

Antisense oligonucleotides and ribozymes have been used widely to regulate gene expression by targeting mRNAs in a sequence-specific manner. Long RNAs, however, are highly structured molecules. Thus, up to 90% of putative cleavage sites have been shown to be inaccessible to classical RNA based ribozymes or DNAzymes. Here, we report the use of modified nucleotides to overcome barriers raised by internal structures of the target RNA. In our attempt to cleave a broad range of picornavirus RNAs, we generated a DNAzyme against a highly conserved sequence in the 5' untranslated region (5' UTR). While this DNAzyme was highly efficient against the 5' UTR of the human rhinovirus 14, it failed to cleave the identical target sequence within the RNA of the related coxsackievirus A21 (CAV-21). After introduction of 2'-O-methyl RNA or locked nucleic acid (LNA) monomers into the substrate recognition arms, the DNAzyme degraded the previously inaccessible virus RNA at a high catalytic rate even to completion, indicating that nucleotides with high target affinity were able to compete successfully with internal structures. We then adopted this strategy to two DNAzymes that we had found to be inactive in our earlier experiments. The modified DNAzymes proved to be highly effective against their respective target structures. Our approach may be useful for other ribozyme strategies struggling with accessibility problems, especially when being restricted to unique target sites.

Sequence requirements in the catalytic core of the "10-23" DNA enzyme.

A systematic mutagenesis study of the "10-23" DNA enzyme was performed to analyze the sequence requirements of its catalytic domain. Therefore, each of the 15 core nucleotides was substituted separately by the remaining three naturally occurring nucleotides. Changes at the borders of the catalytic domain led to a dramatic loss of enzymatic activity, whereas several nucleotides in between could be exchanged without severe effects. Thymidine at position 8 had the lowest degree of conservation and its substitution by any of the other three nucleotides caused only a minor loss of activity. In addition to the standard nucleotides (adenosine, guanosine, thymidine, or cytidine) modified nucleotides were used to gain further information about the role of individual functional groups. Again, thymidine at position 8 as well as some other nucleotides could be substituted by inosine without severe effects on the catalytic activity. For two positions, additional experiments with 2-aminopurine and deoxypurine, respectively, were performed to obtain information about the specific role of functional groups. In addition to sequence-function relationships of the DNA enzyme, this study provides information about suitable sites to introduce modified nucleotides for further functional studies or for internal stabilization of the DNA enzyme against endonucleolytic attack.