Crystal structure of the dimeric beta-cyclodextrin complex with 1,12-dodecanediol

The structure of the complex of beta-cyclodextrin (beta-CD) with 1,12-dodecanediol has been determined at 173 K and refined to a final R=0.0615 based on 22,386 independent reflections. The complex crystallizes in the triclinic space group P1; with a=17.926(4), b=15.399(3), c=15.416(3) A, alpha=103.425(4), beta=113.404(4), gamma=98.858(4) degrees, D(c)=1.362 Mg cm(-3) and V=3651.4(13) A(3) for Z=1. One molecule of the diol is located as a guest in the hydrophobic cavity of a beta-CD-dimer, forming a [3]pseudorotaxane. The guest molecule shows a disorder over two positions. The hydroxyl groups of the diol emerge from the primary faces of the beta-CD dimer and form several hydrogen bonds with water molecules lying in the interstitial space, similarly to dimeric complexes of beta-CD with other alpha,omega-bifunctional guests.     

The crystal structure of the 1:1 inclusion complex of beta-cyclodextrin with squaric acid.

The crystal and molecular structure of the 1:1 inclusion complex of beta-cyclodextrin (cyclomaltoheptaose) with squaric acid (3,4-dihydroxycyclobutene-1,2-dione) was determined by X-ray diffraction. The complex crystallizes in the monoclinic P2(1) space group and belongs to the monomeric cage-type, characterized by a herringbone-like packing motif. Co-crystallized water molecules are present on seven sites, of which six are fully occupied. The guest molecule is placed inside the beta-cyclodextrin cavity, perpendicular to the plane defined by the glycosidic O-4n atoms, and held in place by direct and water-mediated hydrogen bonds mainly involving symmetry-related beta-cyclodextrin molecules. The accommodation of the planar guest molecule into the beta-cyclodextrin cavity determines a significant distortion of the latter from the sevenfold symmetry.     

Structure of inclusion complexes of cyclomaltoheptaose (cycloheptaamylose): crystal structure of the 1-adamantanemethanol adduct

Cyclomaltoheptaose (cycloheptaamylose) has been crystallized with 1-adamantanemethanol as the guest molecule. The complex crystallized in space group C222(1), with unit-cell dimensions a = 19.162 (13), b = 23.965 (17), and c = 32.597 (27) A. The structure was solved by rotation-translation search-methods. The cyclomaltoheptaose exists as a dimer in the crystal by means of extensive hydrogen-bonding across the secondary hydroxyl ends of two cyclomaltoheptaose molecules. The two halves of the dimer are related by a crystallographic two-fold axis. The primary hydroxyl ends of two adjacent cyclomaltoheptaose molecules are also related by a crystallographic two-fold axis, but do not directly hydrogen bond to one another. Instead, they are held in place by a strong hydrogen bond from the hydroxyl group of the 1-adamantanemethanol to a primary hydroxyl group on an adjacent cyclomaltoheptaose molecule. Other stabilizing hydrogen bonds are formed via three water molecules which are situated at the primary hydroxyl interface, and others that form parallel columns stabilizing the crystal structure. A unique feature of this complex is the presence of trapped water in the cavity at the secondary hydroxyl interface. This water is distributed over 3 disordered sites. Its presence blocks one possible site for the 1-adamantanemethanol, which, instead, binds near the primary hydroxyl end, with its hydroxyl group and part of the adamantane moiety protruding from the cyclomaltoheptaose.     

Crystal architecture and conformational properties of the inclusion complex, neohesperidin dihydrochalcone-cyclomaltoheptaose (beta-cyclodextrin), by X-ray diffraction

The crystal structure of the host-guest noncovalent complex of cyclomaltoheptaose (beta-cyclodextrin, betaCD) with the O-diglycosyl flavonoid neohesperidin dihydrochalcone [(3,5-dihydroxy-4-(3-hydroxy-4-methoxyhydrocinnamoyl)phenyl-2-O-(alpha-L-rhamnopyranosyl)-beta-D-glucopyranoside, NDC] has been determined from single-crystal X-ray diffraction data collected at low temperature (130 K), using synchrotron radiation. The crystal data are as follows: a =15.125(5), b =30.523(5), c =41.332(5) Angstroms, orthorhombic, space group C222(1). The structure contains 19 molecules of water, of which 11 appeared well positioned, whereas 9 are disordered over 23-positions. The betaCD-NDC complex is characterized by one aromatic part of NDC deeply inserted into the hydrophobic cavity of the betaCD through the primary OH rim, and it is present in the crystal as a dimer. The dimeric units, formed by head-to-head assemblies of CD molecules, each with its guest, are self-assembled in columns. The stability of the columns is provided by host-guest and guest-guest attractive interactions, thus showing a key role of the guest molecules in the crystal architecture. The guest conformation in the complex is different from that reported in the literature for uncomplexed NDC. The host-induced conformational changes on NDC provide the optimum geometry requirements for the assembly of the dimeric units.     

Structure of the complex of beta-cyclodextrin with beta-naphthyloxyacetic acid in the solid state and in aqueous solution

The structure of the complex of beta-cyclodextrin (cyclomaltoheptaose) with beta-naphthyloxyacetic acid was studied in solid state by X-ray diffraction and in aqueous solution by 1H NMR spectroscopy. The complex crystallizes in the channel mode, space group C2, with a stoichiometry of 2:1; two beta-cyclodextrin molecules related by a twofold crystal axis form dimers, in the cavity of which one guest molecule is found on average. The above stoichiometry indicates one guest per beta-CD dimer statistically oriented over two positions or two guest molecules in pi-pi interactions in half of the beta-CD dimers and the rest of the beta-CD dimers empty. In addition, occupancy of 0.5 for the guest per every beta-CD dimer is in accord with the occupancy of the two disordered primary hydroxyls. These two hydroxyl groups, to which the carboxylic oxygen atoms of the guest are hydrogen bonded, point towards the interior of the beta-CD cavity. In aqueous solution, the 1H NMR spectroscopic study indicated that there is a mixture of complexes with host-guest stoichiometries both 1:1 and 2:1.     

Crystal structure of a cyclomaltoheptaose-4-hydroxybiphenyl inclusion complex

The crystal structure of the inclusion complex of cyclomaltoheptaose (beta-cyclodextrin) with 4-hydroxybiphenyl was determined by single-crystal X-ray diffraction at 150K. The complex contains two cyclomaltoheptaose molecules, two 4-hydroxybiphenyl molecules, one ethanol molecule and fifteen water molecules in the asymmetric unit, and could be formulated as [2(C(42)H(70)O(35)).2(C(12)H(10)O).(C(2)H(6)O).15(H(2)O)]. It crystallized in the triclinic space group P1 with unit cell constants a=15.257(3), b=15.564(3), c=15.592(2)A, alpha=104.485(15) degrees , beta=101.066(14) degrees , gamma=104.330(17) degrees , V=3,343.6(10)A(3). In the crystal lattice, two beta-cyclodextrins form a head-to-head dimer jointed through hydrogen bonds. Two 4-hydroxybiphenyls were included in the dimer cavity with their hydroxyl groups protruding from two primary hydroxyl sides of the cyclodextrin molecules. The guest 4-hydroxybiphenyl molecules linked into a chain via a combination of an O-Hcdots, three dots, centeredO hydrogen bond and face-to-face pi-pi stacking of the phenyl rings. The crystal structure supports the calculation results indicating that the 2:2 inclusion complex formed by beta-cyclodextrin and 4-hydroxybiphenyl is the energetically favored structure.     

Crystal structure of a dimeric form of streptococcal pyrogenic exotoxin A (SpeA1)

Streptococcal pyrogenic exotoxin A (SpeA1) is a bacterial superantigen associated with scarlet fever and streptococcal toxic shock syndrome (STSS). SpeA1 is found in both monomeric and dimeric forms, and previous work suggested that the dimer results from an intermolecular disulfide bond between the cysteines at positions 90 of each monomer. Here, we present the crystal structure of the dimeric form of SpeA1. The toxin crystallizes in the orthorhombic space group P212121, with two dimers in the crystallographic asymmetric unit. The final structure has a crystallographic R-factor of 21.52% for 7248 protein atoms, 136 water molecules, and 4 zinc atoms (one zinc atom per molecule). The implications of SpeA1 dimer on MHC class II and T-cell receptor recognition are discussed.     

The crystal structure of the 1:1 complex of beta-cyclodextrin with trans-cinnamic acid

The crystal structure of the 1:1 complex of beta-cyclodextrin (cyclomaltoheptaose) with trans-cinnamic acid was studied by X-ray diffraction. Two beta-cyclodextrin molecules related by a twofold crystal axis form dimers in the hydrophobic cavity of which, two guest molecules are entirely buried. The complex crystallizes in the monoclinic C2 space group with channel-type molecular packing. The oxygen atoms of the carboxylate group of the trans-cinnamic acid molecule form strong hydrogen bonds with two water molecules lying in the interdimeric space of the hydrophobic channel.     

The dimeric complex of cyclomaltoheptaose with 1,14-tetradecanedioic acid. Comparison with related complexes

The structure of the complex of cyclomaltoheptaose (beta-cyclodextrin, betaCD) with 1,14-tetradecanedioic acid has been determined and refined to a final R=0.0693 based on 9824 observed reflections. Each diacid molecule threads through two betaCD monomers arranged in dimers thus, forming a [3]pseudorotaxane. The end carboxylic groups of adjacent dimers, far apart and fully hydrated, are associated indirectly through water molecules. The positioning of the carboxylic groups with respect to the betaCD dimer and the H-bonds with water molecules are very similar to these of the corresponding complexes of the diacids with 12 and 13 carbon atoms. The bending in the middle of the aliphatic chain is more prominent, compared to that of the corresponding guests with less carbon atoms, thus the end carboxylic groups stay in the same height of the primary faces of the betaCD dimeric complex. As a consequence of the present structure, more close contacts are observed between calculated H-atoms of the guest and O-atoms of the host inside the cavity. This bending is allowed by the width of the betaCD dimer cavity at the secondary interface region.     

Crystal structure of methionine-enkephalin

The crystal structure of methionine-enkephalin has been determined by X-ray crystallography. There are two independent pentapeptides in the asymmetric unit and both display extended backbone conformations with their side chains arranged alternately below and above the backbone plane. The two molecules form a hydrogen-bonded head-to-tail dimer similar in conformation to one dimeric pair of leucine-enkephalin molecules in a previously reported crystal structure.     

Domain-swapped structure of the potent antiviral protein griffithsin and its mode of carbohydrate binding

The crystal structure of griffithsin, an antiviral lectin from the red alga Griffithsia sp., was solved and refined at 1.3 A resolution for the free protein and 0.94 A for a complex with mannose. Griffithsin molecules form a domain-swapped dimer, in which two beta strands of one molecule complete a beta prism consisting of three four-stranded sheets, with an approximate 3-fold axis, of another molecule. The structure of each monomer bears close resemblance to jacalin-related lectins, but its dimeric structure is unique. The structures of complexes of griffithsin with mannose and N-acetylglucosamine defined the locations of three almost identical carbohydrate binding sites on each monomer. We have also shown that griffithsin is a potent inhibitor of the coronavirus responsible for severe acute respiratory syndrome (SARS). Antiviral potency of griffithsin is likely due to the presence of multiple, similar sugar binding sites that provide redundant attachment points for complex carbohydrate molecules present on viral envelopes.     

The refined crystal structure of dimeric phospholipase A2 at 2.5 A. Access to a shielded catalytic center

The 2.5-A crystal structure of the calcium-free form of the dimeric venom phospholipase A2 from the Western Diamondback rattlesnake Crotalus atrox, has been refined to an R-factor of 17.8% (I greater than 2 sigma) and acceptable stereochemistry. The molecule is a nearly perfect 2-fold symmetric dimer in which most of the catalytic residues of both subunits face an internal cavity. The restricted access to the putative catalytic sites is especially puzzling as the optimal substrates for this and most other phospholipase A2 are phospholipids condensed in micellar or lamellar aggregates. We point out that substrate access to the internal cavity may be aided by calcium binding which can alter the intersubunit contacts that shield the catalytic network. We also suggest that a system of hydrogen-bonded moieties exists on the surface of the dimer that links the amino terminus to the catalytic system, through an invariant Gln 4 side chain and the backbone of the active center residue, Tyr 73. This hydrogen-bonded network is on a highly accessible surface of the dimer and would appear to contribute to the enzyme's (as opposed to the proenzyme's) special capacity to attack aggregated rather than monomeric substrate.     

Crystal structure and site-directed mutagenesis of a bleomycin resistance protein and their significance for drug sequestering.

The antibiotic bleomycin, a strong DNA cutting agent, is naturally produced by actinomycetes which have developed a resistance mechanism against such a lethal compound. The crystal structure, at 2.3 A resolution, of a bleomycin resistance protein of 14 kDa reveals a structure in two halves with the same alpha/beta fold despite no sequence similarity. The crystal packing shows compact dimers with a hydrophobic interface and involved in mutual chain exchange. Two independent solution studies (analytical centrifugation and light scattering) showed that this dimeric form is not a packing artefact but is indeed the functional one. Furthermore, light scattering also showed that one dimer binds two antibiotic molecules as expected. A crevice located at the dimer interface, as well as the results of a site-directed mutagenesis study, led to a model wherein two bleomycin molecules are completely sequestered by one dimer. This provides a novel insight into antibiotic resistance due to drug sequestering, and probably also into drug transport and excretion.     

C.P.-M.A.S. 13C-N.M.R. study of some solid-state inclusion complexes of cyclomalto-oligosaccharides with para-substituted benzenes

Cross polarisation—magic-angle sample spinning ¹³C-n.m.r. spectral have been measured in the solid state for p-nitrophenol, p-iodophenol, and their inclusion complexes with cyclomaltohexaose, cyclomaltoheptaose, and methylated cyclomaltohexaose. Analysis of the line-shapes of the resonances and the dipolar-dephasing experiments indicate that the guest molecules undergo motion in the host cavities, whereas the host molecules are almost static. The mode and rate of guest motion depend on the size of the cavity.     

Structure of yeast hexokinase. 3. Low resolution structure of a second crystal form showing a different quaternary structure, heterologous interaction of subunits and substrate binding

A 7 Å resolution electron density map of a second crystal form (called BII) of yeast hexokinase B has been obtained. This crystal form, unlike the first crystal form (BI), binds nucleotide and sugar substrates. While the overall tertiary structure of each subunit appears to be largely the same in both crystal forms, the quaternary structure of the dimer is completely different in the two crystals. The two subunits in the crystallographic asymmetric unit of form BII are related by a molecular screw axis; that is, the two subunits are related by a 160 ° rotation and a 13 Å translation of one subunit relative to the other along the symmetry axis resulting in non-equivalent environments for the two chemically identical subunits. A deep cleft divides each subunit into two domains or lobes of roughly equal size. The helical regions which are clearly visible as rods of electron density in this map constitute at least 40 to 50% of the polypeptide chain and 70 to 80% of one of the lobes. At this resolution the molecule does not appear to be homologous in detail to other kinases such as phosphoglycerate kinase and adenylate kinase. Sugar substrates and inhibitors bind deeply in the cleft which separates the two lobes and produce substantial alterations in the protein structure.     

Crystal structure of the low-humidity form of aspartame sweetener.

The low-humidity IB crystal form of aspartame (L-alphaaspartyl-L-phenylalanine methyl ester) is prepared via humidity-induced transition from the highly hydrated IA crystal form and is used widely as a sweetener. The crystal structure of the low-humidity IB form is determined at 1.05 A resolution (0.476 A(-1) in maximum sintheta/lambda) from an extremely fine fibrous crystal using synchrotron radiation. There are three aspartame molecules and two water molecules in the asymmetric unit of the monoclinic space group P2(1). Each aspartame molecule adopts an almost identical extended conformation which is commonly observed in other crystal forms of aspartame. Three aspartame molecules are assembled into a triangular trimer, and trimer units are stacked along the b-axis via hydrogen-bonding and electrostatic interactions in the main chains and also via hydrophobic contacts in the phenyl side-chains. Six trimer units are related by pseudo 6(1)-screw axis symmetry and form a hydrophilic channel at their center. The hydrophilic channel in the IB form contains only four water molecules in the unit cell, compared with 16 in the IA form. Although the IB form exhibits a trimer structure similar to that of the IA form, one aspartame molecule is rotated by approximately equals 20 degrees from the orientation in the IA form. This arrangement of the molecule implies that the humidity-induced transition is accompanied by a flapping motion of its methyl ester group. These structural differences may imply the stepwise transition from the IA to the IB forms.     

2.9 A resolution structure of the N-terminal domain of a variant surface glycoprotein from Trypanosoma brucei

The variant surface glycoprotein (VSG) of Trypanosoma brucei forms a coat on the surface of the parasite; by the expression of a series of antigenically distinct VSGs in the surface coat the parasite escapes the host immune response. The 2.9 A resolution crystal structure of the N-terminal domain of one variant, MITat 1.2, has been determined. The structure was solved using data collected from two crystal forms. Initially a partial model was built into an electron density map based on multiple isomorphous replacement phases and improved by phase combination methods. Subsequently this model was used to obtain the molecular replacement solution for a second crystal form, providing starting phases which were refined using 2-fold non-crystallographic symmetry averaging. The current model includes 362 residues and has been refined using X-PLOR to an R value of 0.22 for data between 7 and 2.9 A. The molecule is a dimer, approximately 100 A long, having an asymmetrical cross section with maximum dimensions of approximately 40 A x 60 A. Two long, approximately 70 A, alpha-helices from each monomer pack together to form, with several other helices, a core helix bundle that extends nearly the full length of the molecule. The "top" of the protein, which in the surface coat may be exposed to the external environment, is formed from the ends of the two long helices, a short three-stranded beta-sheet, and a strand having irregular conformation that packs above these secondary structure elements. Two conserved disulfide bridges are in this part of the molecule. Several elements of the MITat 1.2 sequence, which contribute to the formation of the helix bundle structure, have been identified. These elements can be found in the sequences of several different VSGs, suggesting that to some extent the VSG structure is conserved in those variants.     

Crystal structure of the inclusion complex of the antibacterial agent triclosan with cyclomaltoheptaose and NMR study of its molecular encapsulation in positively and negatively charged cyclomaltoheptaose derivatives

The inclusion complexes of triclosan with native cyclomaltoheptaose (beta-cyclodextrin, betaCD) as well as with negatively and positively charged derivatives are studied. The structure of the inclusion complex betaCD/triclosan in the crystalline state [P1, a=15.189(5), b=15.230(6), c=16.293(6), alpha=91.07(4), beta=91.05(3) gamma=100.71(3)] comprises two crystallographically independent host macrocycles A and B. The packing results in betaCD dimers that align head-to-head and form infinite channels along the c-axis. Only one guest molecule statistically disordered over two positions, (the dichlorophenyl ring in the cavities of either A or B) corresponds to each dimer (a 2:1 host/guest complex). The enclosed dichlorophenyl ring enters the dimer through the primary side, whereas the hydrophilic chlorophenol ring extends in the space between dimers. Water molecules in five positions are also enclosed in the intradimer region, arranged on a plane perpendicular to the sevenfold axis of betaCD. The NMR spectroscopic studies in aqueous solution show the presence of both 1:1 and 2:1 betaCD/triclosan complexes. In the first case, two different 1:1 complexes are simultaneously present, each with either ring entering the narrow primary side of one betaCD molecule. In the 2:1 complex both rings of triclosan are included in two independent betaCD hosts, a precursor to the supramolecular arrangement found in the crystalline form. In the case of the negatively charged sodium heptakis[6-deoxy-6-(3-thiopropionate)]-betaCD, the NMR studies at pH 7.9 show a complete inclusion of triclosan inside the host in two orientations, one for the non-ionized (phenol) and reverse for the ionized (phenolate) form. Finally, for the positively charged heptakis(6-aminoethylamino-6-deoxy)-betaCD, inclusion of triclosan is possible only when the pH is raised to 10 and it is concluded that both aromatic rings are alternatively inside the cavity. However in that case also, inclusion of the entire guest in the elongated cavity is suggested.     

The crystal structure of phosphorylase beta at 6 A resolution

The determination of the crystal structure of phosphorylase b in the presence of IMP at 6 Å resolution is described. The structure determination is based on two heavy-atom isomorphous derivatives and their anomalous contributions. The molecular boundary is clearly distinguishable in the electron density map, except in the region of subunit-subunit contact about the crystallographic dyad axis, which is the symmetry axis of the dimer. The dimer molecule is roughly ellipsoidal in shape with dimensions 63 Å × 63 Å × 116 Å. There is a pronounced cavity on the enzyme surface but it is not yet known if this is a substrate binding site.     

Structure of cycloheptaamylose inclusion-complexes: crystal structure of substituted benzoic acid and phenol derivatives

Cycloheptaamylose has been crystallized with 2,5-diiodobenzoic acid as guest. The X-ray crystal structure at 1.2-Å resolution with space group C2 and cell dimensions a  19.192 (13), b  24.759 (20), c  15.739 (13) Å, and β  109.6 (3)° was solved by using rotation-translation functions. Complexes of other meta-substituted guests were found to be isomorphous, and were solved by using the phases of the cycloamylose of the 2,5-diiodobenzoic acid complex. The complex with 2-bromo-5-tert-butylphenol having a  19.235 (11), b  24.662 (17), c  16.018 (11) Å, and β  108.9 (2)° was determined at 1.0 Å resolution, and the complexes with m-bromobenzoic acid, m-iodobenzoic acid, m-iodophenol, m-toluic acid, and 2-bromo-4-tert-butylphenol were determined at 2.0-Å resolution. In all cases, the guest molecule was disordered. However, by using information from all the structures, it may be concluded that the functionally important carboxylic acid group lies in the primary-hydroxyl end of the cycloheptaamylose molecule. As studies in solution have shown that the hydrogen-bonding groups of guest molecules interact with the secondary-hydroxyl end of the cycloheptaamylose molecule, it is concluded that the structure seen in the crystals here does not correspond to a catalytically active species. Cyclo-heptaamylose exists as a dimer in the crystal by means of extensive hydrogen bonding across the secondary-hydroxyl ends of two cycloheptaamylose molecules. A continuous channel throughout the crystal is achieved by the stacking of these dimer units.