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To elaborate a high-performance system for expression of genes of G-protein coupled receptors (GPCR), methods of direct and hybrid expression of 17 GPCR genes in Escherichia coli and selection of strains and bacteria cultivation conditions were investigated. It was established that expression of most of the target GPCR fused with the N-terminal fragment of OmpF or Mistic using media for autoinduction provides high output (up to 50 mg/liter).

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The structural basis for the extraordinary stability of a triple-stranded oligonucleotide in which the third strand contains 2'-aminoethoxy-substituted riboses is investigated by NMR spectroscopy. The enhanced stability of the modified triplex in comparison to the unmodified DNA triplex of the same sequence can be attributed to strong interactions of the aminoethoxy groups of the third strand with the phosphate groups of the purine strand. In molecular dynamics calculations the aminoethoxy side chain was found to be rather flexible, allowing for the presence of hydrogen bonds between the aminoethoxy group of the third strand and two different phosphates of the backbone of the second strand. To investigate the conformational preference of the aminoethoxy side chain a new NMR method has been developed which relies on CH-CH dipolar-dipolar cross-correlated relaxation rates. The results indicate that the aminoethoxy side chains adopt mainly a gauche(+) conformation, for which only one of the two hydrogen bonds inferred by NMR and molecular dynamics simulations is possible. This demonstrates a highly specific interaction between the amino group of the third strand and one of the phosphate groups of the purine strand.

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Human neuropeptide Y (hNPY) and the Q34-->P34 mutant (P34-hNPY) have been characterized by CD spectroscopy. hNPY self-associates in aqueous solution with a dimerization constant in the micromolar range. The self-association correlates with an increase in secondary-structure content which was studied as a function of concentration, temperature and pH. The effects of temperature were measured in water (5-84 degrees C) and in ethanediol/water (2 : 1) (-90 degrees to +90 degrees C). A single-residue mutation, Q34-->P34, affects the pH, thermal and self-association properties of NPY. The CD results are correlated with photochemically induced dynamic nuclear polarization NMR experiments which show that the tyrosines at the interface between two monomer units present limited accessibility to a photoreactive dye. An equilibrium state is described, involving a PP-fold monomer form and a handshake dimer form, that accommodates the physicochemical properties of NPY.

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The beta-chain of human interleukin 12 (IL-12) contains at position 319-322, the sequence Trp-x-x-Trp. In human RNase 2 this is the recognition motif for a new, recently discovered posttranslational modification, i.e., the C-glycosidic attachment of a mannosyl residue to the side chain of tryptophan. Analysis of C-terminal peptides of recombinant IL-12 (rHuIL-12) by mass spectrometry and NMR spectroscopy revealed that Trp-319beta is (partially) C-mannosylated. This finding was extended by in vitro mannosylation experiments, using a synthetic peptide derived from the same region of the protein as an acceptor. Furthermore, human B-lymphoblastoid cells, which secrete IL-12, were found to contain an enzyme that carries out the C-mannosylation reaction. This shows that nonrecombinant IL-12 is potentially C-mannosylated as well. This is only the second report on a C-mannosylated protein. However, the occurrence of the C-mannosyltransferase activity in a variety of cells and tissues, and the presence of the recognition motif in many proteins indicate that more C-mannosylated proteins may be found.

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The production of recombinant leech-derived tryptase inhibitor (rLDTI) by two different strains of Saccharomyces cerevisiae resulted in the secretion of non-glycosylated and glycosylated rLTDI. Monosaccharide analysis and a-mannosidase treatment demonstrated that glycosylated rLDTI was exclusively alpha-mannosylated. A trypsin digest of reduced and S-carboxymethylated glycosylated rLDTI was separated on a reverse-phase HPLC column. Glycopeptides identified by a combination of matrix-assisted laser desorption mass spectrometry, amino acid sequence analysis, and monosaccharide analysis revealed the presence of different glycoforms. It was found that Ser24, Ser33 and Ser36 were partially glycosylated with a single mannose residue, whereas Thr42 in glycosylated rLDTI from both strains was fully occupied with manno-oligosaccharides with a degree of polymerization ranging over 1-3 and 1-13 depending on the yeast strain. In phosphorylated rLDTI a single phosphate group was predominantly located at the innermost Man residue of units of mannobiose, mannotriose, mannotetraose and mannopentaose at Thr42. Oligosaccharides released by alkaline treatment were reduced by sodium borohydride and separated by high-pH anion-exchange chromatography on a CarboPac MA1 column, and analyzed by one- and two-dimensional 1H-NMR spectroscopy. Besides the major oligosaccharide Man alpha1-2Man-ol, the (for yeast protein O-glycosylation) unusual Man alpha1-3Man alpha1-2Man-ol was determined. The solution conformation of glycosylated rLDTI was investigated by two-dimensional NMR spectroscopy. Structure calculations by means of distance geometry showed that glycosylated rLDTI is compactly folded and contained small secondary structure elements. Analysis of the chemical shifts showed that amino acids Val32-Ser33, Ser36-Ser39 and Thr42 were affected by the O-mannosylation. In addition, changes in chemical shift were observed within the beta-hairpin peptide regions Val13-Ser16 and Gly18-Tyr21 attributed to direct interactions of the mannose residue at Ser36. Furthermore, the protein-linked oligosaccharides were spatially grouped in a position opposite of the canonical binding loop.

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The main transcriptional regulator of the human immunodeficiency virus, the Tat protein, recognizes and binds to a small structured RNA element at the 5' end of every viral mRNA, termed TAR. On the basis of published structural data of the molecular interactions between TAR and Tat-related peptides, we defined requirements for potential low-molecular weight inhibitors of TAR recognition by the Tat protein. In accordance with the resulting concept, a series of compounds was synthesized. In vitro evaluation of their potential to directly interfere with Tat-TAR interaction was used to define a new chemical class of potent Tat antagonistic substances. The most active compound competed with Tat-TAR complexation with a competition dose CD50 of 22 nM in vitro and blocked HIV expression in a cellular Tat transactivation system with an IC50 of 1.2 microM. The close relation between structural features of the interaction between TAR and a new type of inhibitory agent, "In-PRiNts" (for inhibitor of protein-ribonucleotide sequences), such as CGP 40336A and those of the Tat-TAR complex was confirmed by RNase A footprinting and by two-dimensional NMR. Structural implications for the complex between this class of compounds and TAR RNA will be presented.

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The solution structure of an intramolecular triple helical oligonucleotide has been solved by NMR. The third strand of the pyrimidine x purine x pyrimidine triplex is composed of 2'-aminoethoxy-modified riboses, whereas the remaining part of the nucleic acid is DNA. The structure around the aminoethoxy modification was obtained with the help of selective isotope labeling in conjunction with isotope-editing experiments. Dinucleotide steps and interstrand connectivities, as well as the complete backbone conformation of the triplex, were derived from J-couplings, NOEs, and 31P chemical shifts. The structure of this triplex, solved by distance geometry, explains the extraordinary stability and increase in rate of triplex formation induced by 2'-aminoethoxy-modified oligonucleotides: apart from the formation of seven base triples, a well-defined hydrogen-bonding network is formed across the Crick-Hoogsteen groove involving the amino protons of the aminoethoxy moieties and the phosphates of the purine strand of the DNA. The modified strand adopts a conformation which is close to an A-type helix, whereas the DNA duplex conformation is best described as an unwound B-type helix. The groove dimensions and helical parameters of the 2'-aminoethoxy-modified rY x dRdY triplex are surprisingly well conserved in comparison with DNA triplexes.

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The C-terminal oligomerization domain of chicken cartilage matrix protein is a trimeric coiled coil comprised of three identical 43-residue chains. NMR spectra of the protein show equivalent magnetic environments for each monomer, indicating a parallel coiled coil structure with complete threefold symmetry. Sequence-specific assignments for 1H-, 15N-, and 13C-NMR resonances have been obtained from 2D 1H NOESY and TOCSY spectra, and from 3D HNCA, 15N NOESY-HSQC, and HCCH-TOCSY spectra. A stretch of alpha-helix encompassing five heptad repeats (35 residues) has been identified from intra-chain HN-HN and HN-H alpha NOE connectivities. 3JHNH alpha coupling constants, and chemical shift indices. The alpha-helix begins immediately downstream of inter-chain disulfide bonds between residues Cys 5 and Cys 7, and extends to near the C-terminus of the molecule. The threefold symmetry of the molecule is maintained when the inter-chain disulfide bonds that flank the N-terminus of the coiled coil are reduced. Residues Ile 21 through Glu 36 show conserved chemical shifts and NOE connectivities, as well as strong protection from solvent exchange in the oxidized and reduced forms of the protein. By contrast, residues Ile 10 through Val 17 show pronounced chemical shift differences between the oxidized and reduced protein. Strong chemical exchange NOEs between HN resonances and water indicate solvent exchange on time scales faster than 10 s, and suggests a dynamic fraying of the N-terminus of the coiled coil upon reduction of the disulfide bonds. Possible roles for the disulfide crosslinks of the oligomerization domain in the function of cartilage matrix protein are proposed.

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The manipulation of a single-stranded RNA target by forming different RNA/antisense hybrids demonstrates the possibility of cleaving the RNA strand within duplexes. This was achieved using the sequence composition of the antisense oligonucleotide, an approach that results in various bulges [unpaired base(s)] in the RNA target, which is then cleavable at these specific bulge sites under free metal ion or metal complex catalysis. RNA cleavages promoted by metal ions were performed under mild conditions and characterized by separating the RNA fragments carrying end label. The observed products result from intramolecular transesterification causing RNA strand scission. No detectable cleavage of the RNA was observed with either a fully complementary RNA/antisense hybrid or a bulged base in the antisense strand. A molecular modeling study of the RNA backbone suggests that the local conformation of the RNA backbone at a bulge in such hybrid duplexes greatly facilitates the metal-assisted catalytic cleavage. Endonucleolytic RNA cleavage within an RNA/antisense hybrid by metal complexes attached to the antisense oligonucleotide might lead to a new approach in antisense technology with artificial ribonucleases which operate with catalytic turnover.

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15N main-chain dynamics are compared in four forms of staphylococcal nuclease with different stabilities to unfolding: (1) SN-T, the ternary complex of the protein, Ca2+, and the inhibitor thymidine 3', 5'-bisphosphate; (2) SN, the protein in the absence of added ligands; (3) SN-OB, a folded fragment that corresponds to an "OB-fold" subdomain; (4) delta 131 delta, a denatured 131-residue fragment. SN-T exhibits very little internal motion on the nanosecond timescale. In SN, a moderate increase in flexibility is observed for the first three strands of the five-stranded beta-sheet, and for a loop between strands 4 and 5. In SN-OB, the loops between strands 3 and 4, and between strands 4 and 5, are extremely flexible on the nanosecond timescale. While the beta-sheets of SN-OB and SN have comparable dynamics on the nanosecond timescale, the beta-sheet in SN-OB experiences additional motion on a slower timescale of 330(+/-170) microseconds. We attribute the latter to interconversion between a major folded (> or = 98%) and a minor unfolded (> or = 2%) conformation. In delta 131 delta, the first three strands of beta-sheet experience conformational averaging on the millisecond timescale. Most of the remainder of the polypeptide chain is highly flexible on the nanosecond timescale. When all four forms of nuclease are considered, there is an increase in the proportion of residues with large amplitude internal motions (low order parameters) as the stability of the folded state is decreased. Residues with low order parameters cluster to distinct regions of the chain, and have H alpha chemical shifts and 3JHN-H alpha coupling constants that tend towards "random coil" values. Conversely, a trend towards uniformly high order parameters suggests a consolidation of structure with increasing stability to denaturation.

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To improve the convergence properties of 'embedding' distance geometry, a new approach was developed by combining the distance-geometry methodology with a genetic algorithm. This new approach is called DG-OMEGA (DG omega, optimised metric matrix embedding by genetic algorithms). The genetic algorithm was used to combine well-defined parts of individual structures generated by the distance-geometry program, and to identify new lower and upper distance bounds within the original experimental restraints in order to restrict the sampling of the metrisation algorithm to promising regions of the conformational space. The algorithm was tested on cyclosporin A, which is notorious for its intrinsic difficult sampling properties. A set of 58 distance restraints was employed. It was shown that DG omega resulted in an improvement of convergence behaviour as well as sampling properties with respect to the standard distance-geometry protocol.

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The effect of the replacement of the natural phosphodiester linkage -C3'-O-PO2-O-CH2-C4'- in the DNA strand of RNA.DNA hybrid duplexes by either of the two amide linkages -C3'-CH2-CO-NH-CH2-C4'- or -C3'-CH2-NH-CO-CH2-C4' has been investigated by molecular mechanics (MM) and molecular dynamics (MD) simulations. Conformational analysis has been used to assess various low-energy conformers of the amide-modified backbones. MD simulations have been carried out to study the dynamic behavior of the modified duplexes. The modified RNA.DNA hybrid double helices kept a conservative base pairing scheme during the MD simulations. Although the general behavior has been found to be similar to that of the corresponding wild-type hybrid duplexes, some notable differences, especially regarding the sugar puckering in the amide-modified DNA strands, have been observed. The behavior of the RNA strands in the hybrid duplexes has not been affected by the modified DNA strands and is similar to that in wild-type RNA.DNA duplexes.

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The backbone modification amide-3, in which -CH2-NH-CO-CH2- replaces -C5'H2-O5'-PO2-O3'-, is studied in the duplex d(G1-C2-G3-T4.T5-G6-C7-G8)*mr(C9-G10-C11-A12-A13-C14-G15+ ++-C16) where . indicates the backbone modification and mr indicates the 2'-OMe RNA strand. The majority of the exchangeable and non-exchangeable resonances have been assigned. The assignment procedure differs from standard methods. The methyl substituent of the 2'-OMe position of the RNA strand can be used as a tool in the interpretation. The duplex structure is a right-handed double helix. The sugar conformations of the 2'-OMe RNA strand are predominantly N-type and the 2'-OMe is positioned at the surface of the minor groove. In the complementary strand, only the sugar of residue T4 is found exclusively in N-type conformation. The incorporation of the amide modification does not effect very strongly the duplex structure. All bases are involved in Watson-Crick base pairs.

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The multiplet structure of cross peaks in double-quantum-filtered COSY NMR spectra is analysed for those resonances that include passive heteronuclear couplings. Interestingly, the cross peak involving the sugar-ring protons H2' and H3' in nucleic acids display an E. COSY-type appearance exclusively when the backbone torsion angle epsilon (C4'-C3'-O3'-P) adopts a gauche(-) conformation. This observation allows an unambiguous analysis of the conformation around epsilon, without the knowledge of 3JCP coupling constants.

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The effect of the substitution of a L-nucleoside for a D-nucleoside in the duplex d(G-C-G-T-G-C-G).d(C-G-C-A-C-G-C) was studied by UV and NMR spectroscopy. These unnatural oligonucleotides have potential for antisense DNA technology [Damha, M. J., Giannaris, P. A., & Marfey, P. (1994) Biochemistry (preceding paper in this issue)]. The thermal stability of such duplexes is lower than that of the natural one and is dependent on the nucleotide type and/or sequence. Interestingly, inversion of the chirality of thymidine but not adenosine coincides with a large stabilizing enthalpy change. The structure of the heterochiral duplex d(G1-C2-G3-(L)T4-G5-C6-G7).d(C8-G9-C10-A11-C12-G13- C14), where (L)T denotes the mirror image of the natural thymidine, has been determined by NMR spectroscopy. The sugar conformation was determined using the sum of coupling constants and the distances using a model free relaxation matrix approach. The torsion angles of the backbone follow from 3JHH, 3JHP, and 4JHP coupling constants. The structure of the duplex was calculated by metric matrix distance geometry followed by simulated annealing. The structure is close to that of B-DNA. The base pair formed by (L)T and A is of the Watson-Crick type. All sugars adopt an S-type pucker. The incorporation of the L-sugar in the duplex is accomplished by changes in the backbone torsion angles around the phosphates and the glycosidic torsion angle of (L)T. The modification induces changes in the natural strand as well. The structure exhibits an unusual interaction between the aromatic rings of the (L)T4.A11 and G3.C12 base pairs, which provides a plausible explanation of the unusual thermodynamic properties of the duplex.

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Unnatural L-2'-deoxyribonucleosides L-T, L-dC, L-dA and L-dG were prepared from L-arabinose and assembled, by solution or solid phase synthesis, to give L-oligonucleotides (L-DNAs), which contain all four natural bases. The affinity of these modified oligomers for complementary D-ribo- and D-deoxyribo-oligomers was studied with NMR, UV and CD spectroscopies and mobility shift assay on native PAGE. All experimental results indicate that L-DNAs do not, in general, recognize single-stranded, natural DNA and RNA. Hence, contrary to previous suggestions, it is not possible to envisage their use as wide scope antimessenger agents in the selective control of gene expression.

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The solution structure of the photodimer cis,syn-dUp[]dT is derived with the aid of the genetic algorithm. The conformational space available for the molecule is sampled efficiently using the computer program DENISE and tested against a set of constraints available from nmr experiments. The dominant conformation in solution found with this approach can be described by the following combinations of sugar-phosphate backbone torsion angles: epsilon(t), zeta(t), alpha(+), beta(-ac), and gamma(t). The conformation of the sugars and glycosidic torsion angles are S type and syn, respectively. The cyclobutane ring and pyrimidines are puckered. In addition, other conformations that exist in equilibrium with the first are found. It is concluded that the cyclobutane-pyrimidine system is rigid, whereas the sugar-phosphate backbone is flexible. The solution structures are compared with the crystal structure of the strongly related cyano-ethyl ester of cis,syn-dTp[]dT.

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The hairpin formed by d(ATCCTATTTATAGGAT) was studied by means of two-dimensional NMR spectroscopy and conformational analysis. Almost all 1H resonances of the stem region could be assigned, while the 1H and 31P spectra of the loop region were interpreted completely; this includes the stereospecific assignment of the H5' and H5" resonances. The derivation of the detailed loop structure was carried out in a stepwise fashion including some improved and new methods for structure determination from NMR data. In the first step, the mononucleotide structures were examined. The conformational space available to the mononucleotide was scanned systematically by varying the glycosidic torsion angle and pseudorotational parameters. Each generated conformer was tested against the experimental J coupling constants and NOE parameters. In the following stage, the structures of dinucleotides and longer fragments were derived. Inter-residue distances between protons were calculated by means of a procedure in which the simulated NOEs, obtained via a relaxation-matrix approach, were fitted to the experimental NOEs without the introduction of a molecular model. In addition, the backbone torsion angles beta, gamma and epsilon were deduced from homocoupling and heterocoupling constants. These data served as constraints in the next step, in which the loop sequence was subjected to a multi-conformer generation procedure. The resulting structures were tested against the mentioned constraints and disregarded if these constraints were violated. This yielded a family of structures for the loop region, confined to a relatively narrow conformational space. A representative conformation was subsequently docked on a B-type stem which fulfilled the structural constraints (derived from the NMR experiments for the stem region) to yield the hairpin structure. Results obtained from subsequent restrained-molecular-mechanics as well as free-molecular-mechanics calculations are in accordance with those obtained by means of the analysis described above. The structure of the hairpin loop is a compactly folded conformation and the first base of the central TTTA region forms a Hoogsteen T-A pair with the fourth base. This Hoogsteen base pair is stacked upon the sixth base pair of the B-type double-helical stem. The second base of the loop is folded into the minor groove, whereas the third base of the loop is partly stacked on the first and fourth bases. The phosphate backbone exhibits a sharp turn between the third and fourth nucleotides of the loop. The peculiar structure of this hairpin loop is discussed in relation to loop folding in DNA and RNA hairpins and in relation to a general model for loop folding.

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