X-ray studies on crystalline complexes involving amino acids and peptides: Part XVIII. Crystal structure of a new form of L-arginine D-glutamate and a comparative study of amino acid crystal structures containing molecules of the same and mixed chirality

The new form of L-arginine D-glutamate is monoclinic, P2₁, witha = 9.941(1),b = 4.668(2),c = 17.307(1) Å,β = 95.27(1)°, and Z = 2. In terms of composition, the new form differs from the old form in that the former is a monohydrate whereas the latter is a trihydrate. The structure has been solved by the direct methods and refined to R = 0.085 for 1012 observed reflections. The conformation of the arginine molecule is the same in both the forms whereas that of the glutamate ion is different. The change in the conformation of the glutamate ion is such that it facilitates extensive pseudosymmetry in the crystals. The molecules arrange themselves in double-layers stabilised by head-to-tail sequences involving main chains, in both the forms. However, considerable differences exist between the two forms in the interface, consisting of side chains and water molecules, between double-layers. A comparative study of the relationship between the crystal structures of L and DL amino acids on the one hand and that between the structures of LL and LD amino acid-amino acid complexes on the other, provides interesting insights into amino acid aggregation and the effect of chirality on it. The crystal structures of most hydrophobic amino acids are made up of double-layers and those of most hydrophilic amino acids contain single layers, irrespective of the chiralities of the amino acids involved. In most cases, the molecules tend to appropriately rearrange themselves to preserve the broad features of aggregation patterns when the chirality of half the molecules is reversed as in the structures of DL amino acids. The basic elements of aggregation in the LL and the LD complexes, are similar to those found in the crystals of L and DL amino acids. However, the differences between the LL and the LD complexes in the distribution of these elements are more pronounced than those between the distributions in the structures of L and DL amino acids.     

Variability in ionization state,stoichiometry and aggregation in histidine complexes with formic acid

The crystal structures of the complexes of L and DL histidine with formic acid have been determined as part of an effort to define biologically and evolutionarily important interactions and aggregation patterns. In terms of ionization state and stoichiometry they may be described as L-histidine formate formic acid and DL-histidine formate monohydrate respectively. In the L-histidine complex, amino acid molecules arranged in head-to-tail sequences centred around 2₁ screw axes are interconnected by formic acid molecules and formate ions. Histidine-formate interactions in the structure gives rise to a characteristic interaction pattern involving a linear array of alternating imidazole groups and formate ions. In DL-histidine formale monohydrate, head-to-tail sequences involving glide related molecules are interconnected through main chain-side chain interactions leading to amino acid layers. The layers are held together by formate ions and water molecules arranged in strings along which the ion and the molecule alternate. The patterns of amino acid aggregation in histidine complexes exhibit considerably higher variability than those in complexes involving arginine and lysine do. X-ray studies on crystalline complexes involving amino and peptides Part XXIX.     

X-ray studies on crystalline complexes involving amino acids and peptides. XV. Crystal structures of L-lysine D-glutamate and L-lysine D-aspartate monohydrate and the effect of chirality on molecular aggregation

L-Lysine D-glutamate crystallizes in the monoclinic space group P2(1) with a = 4.902, b = 30.719, c = 9.679 A, beta = 90 degrees and Z = 4. The crystals of L-lysine D-aspartate monohydrate belong to the orthorhombic space group P2(1)2(1)2(1) with a = 5.458, b = 7.152, c = 36.022 A and Z = 4. The structures were solved by the direct methods and refined to R values of 0.125 and 0.040 respectively for 1412 and 1503 observed reflections. The glutamate complex is highly pseudosymmetric. The lysine molecules in it assume a conformation with the side chain staggered between the alpha-amino and the alpha-carboxylate groups. The interactions of the side chain amino groups of lysine in the two complexes are such that they form infinite sequences containing alternating amino and carboxylate groups. The molecular aggregation in the glutamate complex is very similar to that observed in L-arginine D-aspartate and L-arginine D-glutamate trihydrate, with the formation of double layers consisting of both types of molecules. In contrast to the situation in the other three LD complexes, the unlike molecules in L-lysine D-aspartate monohydrate aggregate into alternating layers as in the case of most LL complexes. The arrangement of molecules in the lysine layer is nearly the same as in L-lysine L-aspartate, with head-to-tail sequences as the central feature. The arrangement of aspartate ions in the layers containing them is, however, somewhat unusual. Thus the comparison between the LL and the LD complexes analyzed so far indicates that the reversal of chirality of one of the components in a complex leads to profound changes in molecular aggregation, but these changes could be of more than one type.     

X-ray studies on crystalline complexes involving amino acids and peptides. XXIV. Different ionization states and novel aggregation patterns in the complexes of succinic acid with DL-and L-histidine

Diffusion of acetonitrile into an aqueous solution of DL -histidine and succinic acid in 1:3 molar proportions results in the crystals of DL -histidine hemisuccinate dihydrate [triclinic, P1 , a = 7.654(1), b = 8.723(1), c = 9.260(1) Å, α = 77.23(1), β = 72.37(1) and γ = 82.32 (1)°]. The replacement of DL -histidine by L -histidine in the crystallization experiment under identical conditions leads to crystals of L -histidine semisuccinate trihydrate [orthorhombic, P2₁2₁2₁, a = 7.030 (1), b = 8.773 (1), and c = 24.332 (3) Å]. The structures were solved using counter data and refined to R values of 0.056 and 0.054 for 2356 and 1778 observed reflections, respectively. Histidine molecules in both the complexes exist in open conformation I. Succinate and semisuccinate ions in them are planar, and exactly or nearly centrosymmetric. In the DL -histidine complex, the amino acid molecules form double ribbons and the succinate ions occupy voids left behind when the double ribbons aggregate, as in inclusion compounds. In the L -histidine complex, the amino acid molecules form columns; so do the semisuccinate ions and water molecules. The two columns interdigitate to form the complex crystal. There are similarities between the molecular aggregation in the complexes and that in the crystals of L - and DL -histidine. However, the presence of succinic acid has the effect of disrupting, partially or totally, head-to-tail sequences involving amino acid molecules. © 1993 John Wiley & Sons, Inc.     

X-Ray Studies on Crystalline Complexes Involving Amino Acids and Peptides XXXI. Effect of Chirality on Ionization State,Stoichiometry and Aggregation in the Complexes of Oxalic Acid with L-and DL-histidine

Abstract

Crystals of the oxalic acid complex of L-histidine (orthorhombic P2₁2₁2₁; a=5.535(4), b=6.809(4), c=26.878(3) Å) R= 3.6% for 1188 observed reflections) contain histidine molecules and semi-oxalate ions in the 1:1 ratio, while the ratio is 1:2 in the crystals of the DL-histidine complex (monoclinic P2₁ lc; a=6.750(7), b=10.139(2), c=19.352(2) Å, β= 90.8°; R= 3.7% for 3176 observed reflections). The histidine molecule in the latter has an unusual ionization state with positively charged amino and imidazole groups and a neutral carboxyl group. The molecule has the sterically least favourable allowed conformation with the side chain imidazole ring staggered between the α-amino and the α- carboxyl (carboxylate) groups, in both the structures. The unlike molecules aggregate into separate alternating layers in both of them. There are elements of similarity in the aggregation patterns in the semi-oxalate layers in the two complexes, but the patterns in the amino acid layers are entirely different. Interestingly, the crystal structure of L-histidine semi-oxalate has broad similarities with that of DL-histidine glycolate, demonstrating how broad features of aggregation could be retained inspite of changes in chirality and composition. The unusual ionization state of the amino acid molecule in the DL-histidine complex is reflected in a hitherto unobserved aggregation pattern in its crystal structure.     

X-Ray studies on crystalline complexes involving amino acids and peptides. XVII. Chirality and molecular aggregation: The crystal structures of DL-arginine DL-glutamate monohydrate and DL-arginine DL-aspartate

DL -Arginine DL -glutamate monohydrate and DL -arginine DL -aspartate, the first DL -DL amino acid–amino acid complexes to be prepared and x-ray analyzed, crystallize in the space group P1 with a = 5.139(2), b = 10.620(1), c = 14.473(2) Å, α = 101.34(1)°, β = 94.08(2)°, γ = 91.38(2)° and a = 5.402(3), b = 9.933(3), c = 13.881(2) Å, α = 99.24(2)°, β = 99.73(3)°, γ = 97.28(3)°, respectively. The structures were solved using counter data and refined to R values of 0.050 and 0.077 for 1827 and 1739 observed reflections, respectively. The basic element of aggregation in both structures is an infinite chain made up of pairs of molecules. Each pair, consisting of a L - and a D -isomer, is stabilized by two centrosymmetrically or nearly centrosymmetrically related hydrogen bonds involving the α-amino and the α-carboxylate groups. Adjacent pairs in the chain are then connected by specific guanidyl–carboxylate interactions. The infinite chains are interconnected through hydrogen bonds to form molecular sheets. The sheets are then stacked along the shortest cell translation. The interactions between sheets involve two head-to-tail sequences in the glutamate complex and one such sequence in the aspartate complex. However, unlike in the corresponding LL and DL complexes, head-to-tail sequences are not the central feature of molecular aggregation in the DL -DL complexes. Indeed, fundamental differences exist among the aggregation patterns in the LL , the LD , and the DL -DL complexes.     

X-ray studies on crystalline complexes involving amino acids and peptides. Part XX. Crystal structures of DL-arginine acetate monohydrate and DL-lysine acetate and a comparison with the corresponding L-amino acid complexes

Crystals of DL-arginine acetate monohydrate, C6H15N4O2+C2H3O2-.H2O, are monoclinic, P2(1)/c, with a = 13.552(2), b = 5.048(2), c = 18.837(3) A, beta = 101.34(2) degrees and Z = 4, and those of DL-lysine acetate, C6H15N2O2+.C2H3O2- are triclinic, P1, with a = 5.471(2), b = 7.656(2), c = 12.841(2) A, alpha = 94.48(1), beta = 94.59(2), gamma = 98.83(2) degrees and Z = 2. The structures have been solved by direct methods and refined to R = 0.058 and 0.077 for 1522 and 1259 observed reflections respectively. The difference in the number and the nature of proton donors leads to a difference in hydrogen bond density in the two structures. The basic elements of aggregation in both the structures are pairs of amino acid molecules, each pair stabilized by two centrosymmetrically related hydrogen bonds involving alpha-amino and alpha-carboxylate groups, stacked along the shortest dimension to form columns. The pairs are held together in each column by head-to-tail sequences. The columns stack along a crystallographic axis to form layers. Adjacent layers are bridged by acetate ions. The amino acid-acetate interactions are primarily through side chains and involve specific interactions and characteristic interaction patterns. The gross features of molecular aggregation are nearly the same in DL-arginine acetate monohydrate and L-arginine acetate whereas they are substantially different in the lysine complexes. In both cases, one of the two head-to-tail sequences in the L complex is replaced by a hydrogen bonded loop involving alpha-amino and alpha-carboxylate groups, in the DL complex. This may have implications for prebiotic condensation during chemical evolution.     

Differential changes in ornithine aminotransferase self-affinity produced by exposure to basic amino acids and the increases in the intrinsic electronegativity of the enzyme monomer

In a previous study we showed that ornithine aminotransferase (OAT) exhibits concentration-dependent self-association in two stages (45,000 M_r monomers aggregate to form 140,000–150,000 M_r trimers; the trimers then aggregate to form higher-molecular-weight complexes). In an attempt to characterize further the molecular mechanisms involved in OAT aggregation, the present study examined the effects of basic amino acids and keto acids on the aggregation process. These experiments showed that basic amino acids (ornithine and lysine) inhibit the association of monomers to form trimers, apparently by interaction with carboxyl groups on the surfaces of the monomers. The aggregation of trimers to form higher-molecular-weight assemblies is not affected by basic amino acids, and neither aggregation stage is affected by the keto acids, α-ketoglutarate, or oxaloacetate. We also found that two different OAT preparations (one fresh, the other 18 months old) differed in aggregation characteristics; the older preparation showed reduced self-affinity at both aggregation stages, but both preparations had similar catalytic efficiencies. Electrophoretic studies indicated that the older preparation contained variants of the enzyme monomer with greater electronegativity than did the fresh preparation. We conclude, therefore, that OAT purification exposes ionically labile but catalytically insignificant domains on the monomer surface, and the loss of positively charged groups from such regions diminishes the OAT aggregation potential.     

Synthesis,and crystal and molecular structure of the 310-helical α,β-dehydro pentapeptide Boc-Leu-Phe-Ala-ΔPhe-Leu-Ome

α,β-Dehydro amino acid residues are known to constrain the peptide backbone to the β-bend conformation. A pentapeptide containing only one α,β dehydrophenylalanine (ΔPhe) residue has been synthesized and crystallized, and its solid state conformation has been determined. The pentapeptide Boc-Leu-Phe-Ala-ΔPhe-Leu-OMe (C₃₉H₅₅N₅O₈, M_w = 721.9) was crystallized from aqueous methanol. Monoclinic space group was P2₁, a = 10.290(2)°, b = 17.149(2)°, c = 12.179(2) Å, β = 96.64(1)° with two molecules in the unit cell. The x-ray (Mo K_α, λ = 0.7107A) intensity data were collected using a CAD4 diffractometer. The crystal structure was determined by direct methods and refined using least-squares technique. R = 4.4% and R_w = 5.4% for 4403 reflections having |F₀| ≥ 3σ(|F₀|). All the peptide links are trans and the pentapeptide molecule assumes 3₁₀-helical conformation. The mean ?,ψ values, averaged over the first four residues, are ?64.4°, ?22.4° respectively. There are three 4 → 1 intramolecular hydrogen bonds, characteristic of 3₁₀,-helix. In the crystal, the peptide helices interact through two head-to-tail. N? H? O intermolecular hydrogen bonds. The peptide molecules related by 2₁, screw symmetry form a skewed assembly of helices. © 1995 John Wiley & Sons, Inc.     

On the mechanism of interaction between histone II B1 and DNA and histone II B2 and DNA

A mechanism is suggested at the molecular level whereby histone IIB₂ can act as a cross-link between two (or possibly three) adjacent and parallel strands of DNA double helix some 40 Å apart. Application of Prothero's rule and the Lewis probability functions indicate the probable locations of three a-helices and a number of β-turns. This, coupled with the requirement that the tertiary conformation of the histone be complementary to the DNA molecules and for as many basic groups as possible to bind to phosphate oxygens, allows us to suggest, on the basis of model building using accurate space-filling (CPK) models, a complex conformation that achieves this.A similar process applied to histone IIB₁, whose complete amino acid sequence is also known, shows the location of five probable a-helices, a number of β-turns, and a segment of β-pleated sheet. The basic amino acids are gathered in four groupings. Model building experiments suggest that histone IIB₁ forms a complex strut joining four parallel strands of DNA double helix that form a diamond with diameters 100 and 40 Å. In both these models the purpose and function of a fair proportion of the individual amino acids can be specified.This paper is the third and last of a series in this Journal in which models are presented for the tertiary conformation and function of all five histones of known (in whole or in part) amino acid sequence. This suggests that all five are concerned in packing the long DNA double helix, which may be in a “square helix” form, into the confined space of the chromosome. The hypotheses may be tested by a direct investigation of nucleoprotein in situ to see if these 40, 70, and 100 Å interhelical distances can be detected by biophysical methods.     

X-ray studies on crystalline complexes involving amino acids and peptides. X. Head-to-tail sequences in the crystal structure of L-lysine acetate

L-Lysine acetate crystallises in the monoclinic space group P21 with a = 5.411 (1), b = 7.562(1), c = 12.635(2) A and beta = 91.7(1) degrees. The crystal structure was solved by direct methods and refined to an R value of 0.049 using the full matrix least squares method. The conformation and the aggregation of lysine molecules in the structure are similar to those found in the crystal structure of L-lysine L-aspartate. A conspicuous similarity between the crystal structures of L-arginine acetate and L-lysine acetate is that in both cases the strongly basic side chain, although having the largest pK value, interacts with the weakly acidic acetate group leaving the alpha-amino and the alpha-carboxylate groups to take part in head-to-tail sequences. These structures thus indicate that electrostatic effects are strongly modulated by other factors so as to give rise to head-to-tail sequences which have earlier been shown to be an almost universal feature of amino acid aggregation in the solid state.     

X-ray fibre diffraction study of conformational changes in hyaluronate induced in the presence of sodium,potassium and calcium cations

Hyaluronate purified from all cations by ion exchange chromatography was introduced to the cations sodium, potassium and calcium in a controlled way. The conformations formed in the presence of these ions were studied as a function of ionic strength, hydrogen ion activity, humidity and temperature using X-ray fibre diffraction. In sodium hyaluronate above pH 4.0 a contracted helix is found which approximates to a four-fold helix with an axial rise per disaccharide of 0.84 nm. There is no requirement for water molecules in the unit cell as the Na⁺ can be coordinate by the hyaluronate chains alone. On crystallizing hyaluronate below pH 4.0 an extended 2-fold helix with an axial rise per disaccharide of 0.98 nm is formed. In the presence of potassium above pH 4.0 a conformation similar, but not identical, to that of sodium was found where the helix backbone is again four-fold with an axial rise per disaccharide h=0.90 nm. To maintain the coordination of the potassium ion, four water molecule/disaccharide are required and on removal of these the conformation is destabilized going to a new helix where n = 4 and h = 0.97 nm. Below pH 4.0 the conformation is a contracted 4-fold helix with h = 0.82 nm. In this structure two antiparallel chains intertwine to form a double helix. The packing of the double helical units is stabilized by water molecules, the unit cell requiring 8 water molecules/disaccharide. Formation of the calcium hyaluronate complex above pH 3.5 yields a three-fold helix with h = 0.95 nm. The requirement for water in the unit cell to maintain full crystallinity is high, at 9 water molecules/disaccharide; however, on removal of this water, though the crystallinity is disrupted, the conformation remains constant. The acid form of calcium-hyaluronate yields an equivalent conformation to that of sodium under the same condition, i.e. a helix with n = 2, h = 0.98 nm. The presence of small quantities of calcium in what are otherwise potassium or sodium solutions of hyaluronate yield the 3-fold conformation for hyaluronate. Thus calcium has an important role to play in deciding the dominating conformation present in hyaluronate. The variety of conformations yielded by the different cations indicates a subtle interaction between hyaluronate and its environment, in which the balance between the cations will control to some degree the interactions between hyaluronate chains and thus affect the mechanical properties of the matrix which they form. The conformations of individual chains are all stabilized in varying degrees by intra-chain hydrogen bonds.     

Partially Folded Aggregation Intermediates of Human γD-, γC-, and γS-Crystallin Are Recognized and Bound by Human αB-Crystallin Chaperone

Human γ-crystallins are long-lived, unusually stable proteins of the eye lens exhibiting duplicated, double Greek key domains. The lens also contains high concentrations of the small heat shock chaperone α-crystallin, which suppresses aggregation of model substrates in vitro. Mature-onset cataract is believed to represent an aggregated state of partially unfolded and covalently damaged crystallins. Nonetheless, the lack of cell or tissue culture for anucleate lens fibers and the insoluble state of cataract proteins have made it difficult to identify the conformation of the human γ-crystallin substrate species recognized by human α-crystallin. The three major human lens monomeric γ-crystallins, γD, γC, and γS, all refold in vitro in the absence of chaperones, on dilution from denaturant into buffer. However, off-pathway aggregation of the partially folded intermediates competes with productive refolding. Incubation with human αB-crystallin chaperone during refolding suppressed the aggregation pathways of the three human γ-crystallin proteins. The chaperone did not dissociate or refold the aggregated chains under these conditions. The αB-crystallin oligomers formed long-lived stable complexes with their γD-crystallin substrates. Using α-crystallin chaperone variants lacking tryptophans, we obtained fluorescence spectra of the chaperone-substrate complex. Binding of substrate γ-crystallins with two or three of the four buried tryptophans replaced by phenylalanines showed that the bound substrate remained in a partially folded state with neither domain native-like. These in vitro results provide support for protein unfolding/protein aggregation models for cataract, with α-crystallin suppressing aggregation of damaged or unfolded proteins through early adulthood but becoming saturated with advancing age.     

Crystal structure of Boc-Leu-Aib-Pro-Val-Aib-Aib-Glu(OBzl)-Gln-Phl × H2O,the C-terminal nonapeptide of the voltage-dependent ionophore alamethicin

Boc-L -Leu-Aib-Pro-Val-Aib-Aib-Glu(OBzl)-Gln-Phl (Boc = t-butyloxycarbonyl, Aib = α-aminoisobutyric acid, Bzl = benzyl, Phl = phenylalaninol), C₅₉H₉₀N₁₀O₁₄, the protected C-terminal nonapeptide with the sequence 12–20 of alamethicin, crystallizes in the orthorhombic space group P2₁2₁2₁ with a = 15.666, b = 16.192, c = 26.876 Å, and Z = 4. The molecular conformation is right-handed helical with three α-(5 → 1 hydrogen bonds) and three β-turns (4 → 1 hydrogen bonds). All but two of the hydrogen bonds are significantly longer than the usual value and show bifurcation to some extent. The α/3-helical nonapeptide molecules are arranged head-to-tail along the a direction. The resulting linear antiparallel chains are linked by a weak intermolecular hydrogen bridge, thus forming a two-dimensional layer structure in the ab plane. The conformation of this nonapeptide is almost identical with that of the corresponding C-terminal part found by x-ray crystallography of the eicosapeptide alamethicin.     

Use of β3-methionine as an amino acid substrate of Escherichia coli methionyl-tRNA synthetase

Polypeptides containing β-amino acids are attractive tools for the design of novel proteins having unique properties of medical or industrial interest. Incorporation of β-amino acids in vivo requires the development of efficient aminoacyl-tRNA synthetases specific of these non-canonical amino acids. Here, we have performed a detailed structural and biochemical study of the recognition and use of β³-Met by Escherichia coli methionyl-tRNA synthetase (MetRS). We show that MetRS binds β³-Met with a 24-fold lower affinity but catalyzes the esterification of the non-canonical amino acid onto tRNA with a rate lowered by three orders of magnitude. Accurate measurements of the catalytic parameters required careful consideration of the presence of contaminating α-Met in β³-Met commercial samples. The 1.45 Å crystal structure of the MetRS: β³-Met complex shows that β³-Met binds the enzyme essentially like α-Met, but the carboxylate moiety is mobile and not adequately positioned to react with ATP for aminoacyl adenylate formation. This study provides structural and biochemical bases for engineering MetRS with improved β³-Met aminoacylation capabilities.     

Crystal structure of trisodium β-d-fructofuranose 1,6-diphosphate octahydrate

Trisodium β-d-fructose 1,6-diphosphate octahydrate crystallises in the monoclinic space group P2₁ with unit-cell dimensions a = 13.289(2), b = 11.643(3), c = 7.092(1) Å, and β = 102.32(2)°. The unit cell contains two symmetry-related molecules. The structure has been determined by direct methods, and refined to an R value of 0.035 and an R_w value of 0.049. The puckering of the furanose ring is C-3-exo, corresponding to an E₃ conformation slightly distorted towards ⁴T₃. The sodium atoms are hexaco-ordinated. The crystal packing involves alternating charged layers and a network of hydrogen bonds which links the molecules belonging to the same layer and to adjacent layers.     

Immobilization of lipase on cotton cloth using the layer-by-layer self-assembly technique

Lipase from Thermomyces lanuginosus was assembled into multiple layers on polyethylenimine treated cotton flannel cloth, utilising the enzymes property of forming bimolecular aggregates via layer-by-layer (LBL) immobilization technique. An increase in lipase activity with increasing enzyme layers confirmed lipase aggregation. A study to compare the activity of enzyme bound by classical LBL technique, containing alternate layers of polyethylenimine and lipase and the modified approach indicated above, showed that more enzyme was bound to cloth in the modified approach. A total of 13 U/cm² of enzyme were bound to cloth till the fifth layer whereas only 10.2 U/cm² were bound till the fifth bilayer in the classical approach. The successful assembly of lipase molecules has shown that this modified technique is a promising approach to immobilize enzymes that aggregate through hydrophobic interactions as nano-films on cloth.     

Fibrinogen: a preliminary analysis of the amino acid sequences of the portion of the alpha, beta and gamma-chains postulated to form the interdomainal link between globular regions of the molecule

It has been suggested (Doolittle et al., 1977) that portions of the α-, β- and γ-chains of fibrinogen form a coiled-coil rope of α-helices and that this rope connects globular domains of the molecule. A fast Fourier transform analysis of the relevant amino acid sequences has shown that there is a significant 3.5-residue period in the linear disposition of the apolar residues in all three chains. This periodicity is characteristic of amino acid sequences of α-fibrous proteins, such as α-tropomyosin and α-keratin, where the tertiary structure is closely related to a coiled-coil of α-helices. However, a detailed study of the fibrinogen sequences shows that the structure is likely to contain several regions which do not have a simple secondary structure. The detailed conformation of the postulated rodlike region of fibrinogen is therefore complex and may approximate a coiled-coil only over relatively short lengths.An important question to emerge from this analysis is whether correct positioning of apolar residues in a pseudo-repeating heptad is sufficiently important to override low α-helix-favouring potential of other residues in the heptad.     

Conformation and packing properties of phosphatidic acid: The crystal structure of monosodium dimyristoylphosphatidate

The conformation and molecular packing of monosodium 1,2-dimyristoyl-sn-glycerophosphate (DMPA) has been determined by single crystal analysis (R = 0.107). The lipid crystallizes in the space group P2₁ with unit cell dimensions: $\text{a = 5.44, b = 7.95, c = 43.98}\text{A}\text{?}$ and β = 114.2°. The two molecules of the unit cell are related by a two-fold screw axis and pack tail-to-tail in a bilayer structure. The monosodium phosphate group packs with rather a small cross-section (24 Ų) relative to the two hydrocarbon chains. This unbalance in packing cross-section is overcome by an interdigitation of the phosphate head groups of adjacent bilayers and the formation of a single, common phosphate group layer at the bilayer interfaces. The phosphate groups are linked by hydrogen bonds to linear strands which laterally are separated by strands of sodium ions. The conformation of the molecules differs from that of other phospholipids. The glycerol chain is oriented parallel (instead of perpendicular) to the layer surface and the parallel stacking of the hydrocarbon chains is achieved by a bend of the γ-chain (instead of the β-chain). Otherwise the conformation of the glycerol dicarboxyl ester group displays the same preferred features as generally found in glycerophospholipids. The hydrocarbon chains pack according to the triclinic (T_∥) packing mode. The interaction and packing principles of the phosphate head group are discussed in relation to the structural behaviour of phosphatidic acid.     

Effects of End Group and Aggregation on Helix Conformation: Crystal Structure of Ac-(Aib-Val-Ala-Leu)2-Aib- OMe

The role of end groups in determining stereochemistry and packing in hydrophobic helical peptides has been investigated using an α-aminosobutyric acid (Aib) containing model nonapeptide sequence. In contrast to the Boc-analogue, Ac-(Aib-Val-Ala-Leu)₂-Aib-OMe crystallizes with two independent molecules in a triclinic cell. The cell parameters are: space group P1, a=10.100(2)Å, b=15.194(4) Å, c=19.948(5) Å, α=63.12(2)°, β=88.03(2)°, γ=88.61(2)°, Z=2, R=7.96% for 5140 data where |F_o|>3σ(F). The two independent molecules alternate in infinite columns formed by head-to-tail hydrogen bonding. The helices in the two independent molecules are quite similar to each other but one molecule is rotated ≈?123° about its helix axis with respect to the other. All the helical columns pack parallel to each other in the crystal. Replacement of the bulky Boc group does not lead to any major changes in conformation. Packing characteristics are also similar to those observed for similar helical peptides.