Jens P. Fürste

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.

Crystal structure of domain A of Thermus flavus 5S rRNA and the contribution of water molecules to its structure.

This is the first high resolution crystal structure of an RNA molecule made by solid phase chemical synthesis and representing a natural RNA. The structure of the domain A of Thermus flavus ribosomal 5S RNA is refined to R = 18% at 2.4 Å including 159 solvent molecules. Most of the 2′‐hydroxyl groups as well as the phosphate oxygens are involved either in specific hydrogen bonds in intermolecular contacts or to solvent molecules. The two U‐G and G‐U base‐pairs are stabilized by H‐bonds supplied via three water molecules to compensate for the lack of base‐pair hydrogen bonds. The structure shows for the first time in detail the importance of highly ordered internal water in stablizing an RNA structure.

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 β-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.

Crystallization and preliminary diffraction studies of the structural domain E of Thermus flavus 2S rRNA

The ribosomal 5S RNA is an essential constituent of the large ribosomal subunit. To overcome the difficulties of crystallizing large RNA molecules such as 5S rRNAs, we decided to divide the 5S rRNA in five domains A through E to determine their structure. Recently we determined the crystal structural of the helical domain A. Here we report the crystallization of the chemically synthesized domain E of the Thermus flavus 5S rRNA. The crystal form is trigonal with unit cell dimensions: and . Diffraction‐data to 2.8 Å have been recorded and the structure solution is currently underway by means of MIR and MAD techniques.

Synthesis and Analytical Characterization of RNA-Polyethylene Glycol Conjugates

Abstract Polyethylene glycols with degrees of polymerization from 5 to more than 100 were incorporated into synthetic oligoribonucleotides by automated solid phase synthesis at 3′-terminal, 5′-terminal and internal positions. The conjugates were characterized by chromatographic, electrophoretic and mass-spectrometric methods. The influence of coupling site, polymer size and number of coupled polymers per oligonucleotide on the molecular properties of the conjugates is investigated.

Initial analysis of 750 MHz NMR spectra of selectively 15N‐G,U labelled E. coli 5S rRNA

The overall folding of an RNA molecule is reflected in its base pairing pattern. The identification of that pattern provides a first step towards the determination of the structure of an RNA molecule. We show that the application of heteronuclear NMR methods at 750 MHz to E. coli 5S rRNA (120 nucleotides) selectively labelled with 15N in guanine and uridine allows observation of base pairing patterns for a larger RNA molecule. We also present evidence that the fold of the E‐domain of the 5S rRNA (nt 79–97) as a contiguous part of the 5S rRNA and as an isolated molecule is virtually the same.

Detection of Multiple Conformations of the E-Domain of 5S rRNA from Escherichia Coli in Solution and in Crystals by NMR Spectroscopy

NMR spectroscopy of the E-domain fragment of Escherichia coli 5S rRNA indicates that this molecule exists in solution as either a stem-loop or as a duplex with two U-U base pairs in the bulge region. At temperatures below 27 degrees C, interconversion between the monomeric and dimeric forms in solution occurs on a time scale of weeks and allows the preparation of samples on which NMR structure determinations can be carried out on predominantly monomeric or dimeric species. The NMR results obtained provide comparison data for the distinction between A- and B-form E.coli 5S rRNA and for the possible kinetics of conversion between these forms. NMR evidence is presented that the duplex form also exists in crystals and suggestions are made for means to obtain stem-loop conformations of E-domain and other small RNA stem-loop sequences in crystals.

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.

Human tRNAGly acceptor-stem microhelix: crystallization and preliminary X-ray diffraction analysis at 1.2 Å 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.

High pressure effects on conformation of homo- and heteroduplexes of nucleic acids

Four different chemically synthesized single stranded complementary oligonucleotides: DNA I, d(GCGCGCATATAT); RNA I, r(AUAUAUGCGCGC): RNA II, r(GGCCGGUUAAUU); and RNA III, r(AAUUAACCGGCC) were studied in order that the effects of high pressure on heteroduplex and homoduplex structures could be understood. The oligonucleotides were subjected to a high pressure at low and/or high salt buffer and analyzed by circular dichroism spectroscopy. In these conditions, both DNA-RNA and RNA-RNA duplexes with different purine-pyrimidine sequences change their conformation. The heteroduplex DNA I-RNA I with the complementary alternating purine-pyrimidine sequence, does not change its conformation of A type at high salt alone or at high salt and high pressure applied together. The homoduplex RNA II-RNA III with purine-purine-pyrimidine-pyrimidine sequence does not change strongly its. A-RNA conformation either. However, a structure of the homoduplex is affected by high pressure alone or with high salt as concluded from shifting the maximum of the CD spectrum to around 265 nm and inducing higher Cotton effect. These observations clearly suggest some conformational changes of the homoduplex. A single stranded oligonucleotide (RNA I) and oligodeoxynucleotide (DNA I) alone showed up a different conformation. The CD spectrum of RNA I is similar to that of A-RNA structure, out that of DNA I shows a very small Cotton effect and has not an ordered structure.