The Ribbon of Hydrogen Bonds in the Three-Dimensional Structure of Globular Proteins

We report quantum mechanical computations and experimental evidence which suggest that the backbone conformation of globular proteins depends generally on the conservation of that part of the hydrogen bond network or ribbon which is joined, in general, directly to the backbone and is largely independent of the remainder of this whole network of hydrogen bonds. The familiar hydrogen bonds of the helix and the sheet form about one-half of this ribbon of hydrogen bonds. Both water molecules and hydrogen bonding side chain groups are involved in the formation of the ribbon.This view of the three-dimensional structure of globular proteins in terms of the `molecule' allows us to deal with the non-secondary structure as well as with the familiar secondary structure. It also suggests that the ribbon contains approximately the same number of hydrogen bonds within all three structures – the helix, the sheet and the coil – and that this is the reason for the ease of interconversion of these three structures.The quantum mechanical computations on hydrogen bonding suggest that delocalised water molecules which have substantial mobility are an essential part of the ribbon. This situation arises because the hydrogen bonding groups of the protein molecule are not free to move to optimise the hydrogen bonding geometries as are the oxygen atoms in the waters and ices. Such delocalised water molecules either have high B values or are invisible in the X-ray data and yet are able to form a structure which is as strong as a normal hydrogen bond.The experimental data on the point mutations of the THRI57 residue of the T4 phage lysome provides an initial test of this model. Both the local backbone conformation and the ribbon of hydrogen bonds are conserved throughout all the mutations of residue 157,providing that the delocalised water molecules are accepted as a genuine part of the structure. These mutations include the introduction of hydrocarbon side chains at position 157 when water molecules or other side chain groups take over the formation of the hydrogen bonds.We suggest that, provided steric effects are not important, many point mutations succeed because they leave the ribbon of hydrogen bonds (and so the backbone conformation) largely unchanged.     

Three-dimensional structure of the Hck SH2 domain in solution

The hematopoietic cellular kinase (Hck) is a member of the Srcfamily of non-receptor protein-tyrosine kinases that is expressedpredominantly in granulocytes, monocytes and macrophages. Recentobservations suggest that Hck may be activated in HIV-infected macrophagesand in chronic myelogenous leukemia cells that express Bcr-Abl. In order toincrease our understanding of the structural basis for regulation of Hckactivity under normal and pathological conditions, we have solved thesolution structure of the uncomplexed Hck SH2 domain using NMR spectroscopy.A novel procedure that uses intraresidueH^NH distances as references forconverting NOE intensities into distance restraints has been described. Atotal of 1757 significant experimental restraints were derived from NMRspectroscopic data including 238 medium-range and 487 long-range distancerestraints and 177 torsion angle restraints. These restraints were used in asimulated annealing procedure to generate 20 structures with the programDYANA. Superimposition of residues 5–104 upon the mean coordinate setyielded an average atomic rmsd values of 0.42 ± 0.08 Å for theN,C,C atoms and 0.81 ± 0.08 Å forall heavy atoms. Rmsd values for those residues in the regions of orderedsecondary structure were 0.27 ± 0.04 Å for theN,C,C atoms and 0.73 ± 0.06 Å forall heavy atoms.     

The difference between protein structures that are obtained by X-ray analysis and magnetic resonance spectroscopy

We have analyzed the proteins whose structures were determined both by X-ray analysis (X-ray) and nuclear magnetic resonance (NMR) on condition that these structures do not differ greatly when spatially superimposed on each other (61 pairs of protein structures). Atom-atomic contacts (contact distances varied from 2 to 8 A) have been analyzed and it has been found that NMR structures (in comparison with X-ray ones) have more contacts in the range below 3.5 A and above 5.5 A. In the case of residue-residue contacts NMR structures have more contacts below 3 A and between 4.5 and 6.5 A. At all the other contact distances analyzed the X-ray structures have more contacts. The difference in the number of atom-atomic and residue-residue contacts is greater for internal residues, that are concealed from water, as compared to the surface residues. The other, not less important difference deals with the number of hydrogen bonds in the main chain: it is larger for the X-ray structures. The correlation between the hydrogen bonds identified in the structures obtained by both methods is no more than 32%. The consideration of a complete set of protein structures obtained by NMR results in the fact that the number of hydrogen bonds grows 1.2 times as compared to those obtained with the X-ray analysis, whereas the correlation increases only by 65%. We have also demonstrated that alpha-helices in the NMR structures are more distorted in comparison with the ideal alpha-helix, than alpha-helices in the X-ray structures.     

The Three-Dimensional Solution Structure of the Src Homology Domain-2 of the Growth Factor Receptor-Bound Protein-2

A set of high-resolution three-dimensional solution structures of the Src homology region-2 (SH2) domain of the growth factor receptor-bound protein-2 was determined using heteronuclear NMR spectroscopy. The NMR data used in this study were collected on a stable monomeric protein solution that was free of protein aggregates and proteolysis. The solution structure was determined based upon a total of 1439 constraints, which included 1326 nuclear Overhauser effect distance constraints, 70 hydrogen bond constraints, and 43 dihedral angle constraints. Distance geometry-simulated annealing calculations followed by energy minimization yielded a family of 18 structures that converged to a root-mean-square deviation of 1.09 Å for all backbone atoms and 0.40 Å for the backbone atoms of the central -sheet. The core structure of the SH2 domain contains an antiparallel -sheet flanked by two parallel -helices displaying an overall architecture that is similar to other known SH2 domain structures. This family of NMR structures is compared to the X-ray structure and to another family of NMR solution structures determined under different solution conditions.     

Comparison of X‐ray and NMR structures: Is there a systematic difference in residue contacts between X‐ray‐ and NMR‐resolved protein structures?

We have compared structures of 78 proteins determined by both NMR and X-ray methods. It is shown that X-ray and NMR structures of the same protein have more differences than various X-ray structures obtained for the protein, and even more than various NMR structures of the protein. X-ray and NMR structures of 18 of these 78 proteins have obvious large-scale structural differences that seem to reflect a difference of crystal and solution structures. The other 60 pairs of structures have only small-scale differences comparable with differences between various X-ray or various NMR structures of a protein; we have analyzed these structures more attentively. One of the main differences between NMR and X-ray structures concerns the number of contacts per residue: (1) NMR structures presented in PDB have more contacts than X-ray structures at distances below 3.0 A and 4.5-6.5 A, and fewer contacts at distances of 3.0-4.5 A and 6.5-8.0 A; (2) this difference in the number of contacts is greater for internal residues than for external ones, and it is larger for beta-containing proteins than for all-alpha proteins. Another significant difference is that the main-chain hydrogen bonds identified in X-ray and NMR structures often differ. Their correlation is 69% only. However, analogous difference is found for refined and rerefined NMR structures, allowing us to suggest that the observed difference in interresidue contacts of X-ray and NMR structures of the same proteins is due mainly to a difference in mathematical treatment of experimental results.     

Organization of α-chain genes among Hb G-Philadelphia heterozygotes in association with Hb S, β-thalassemia,and α-thalassemia-2

The percentages of the -chain variant Hb G-Philadelphia (Hb G) or ₂ 68 AsnLys₂ were evaluated in 84 adult and 18 newborn heterozygotes. These included members of three families who were studied in more detail by nucleic acid hybridization techniques. The adult heterozygotes fell in two categories, one with a higher proportion of Hb G [46.5±1.0% (SD), N=21] and another with lower values (33.9±3.4%, N=63). Among the newborn heterozygotes, two babies fell in the category with the higher proportion of Hb G while 16 babies gave values between 25 and 34%. Studies of -chain gene organization on the parents of one neonate with a Hb G level of 27% at birth and 37% at 8 months excluded the presence of chromosomes with triplicated -chain genes which could lead to the ^0G/ genotype. Rather, these studies on five Hb G heterozygotes from three families confirmed the linkage between Hb G and a specific type of -thalassemia-2 associated with the presence of a 16-kbp Bgl II fragment which most probably carries the ^G locus since it has been found in 19 Hb G heterozygotes studied to date. The presence of an -thal-2 heterozygosity and three -chain genes (^0G/) was confirmed among Hb G heterozygotes with lower proportions of this variant. It is likely that the even lower values found in some newborn could arise through defective assembly of ^G- dimers. The presence of an -thal-2 homozygosity and two active -chain genes, one on each chromosome (^0G/⁰), was confirmed among heterozygotes with the higher proportion of Hb G. One of each of these categories was present in each of the three families investigated. This type of variability in the number of active -chain genes due to a heterozygosity or a homozygosity for -thalassemia-2 explains the trimodality of Hb S percentages among heterozygotes and the atypical hematological or biosynthetic features among patients with -thalassemia and sickle-cell syndromes.This research was supported by USPHS Research Grants HLB-05168 and HLB-15158 and by designated research funds of the Veterans Administration. This is Contribution No. 0693 of the Department of Cell and Molecular Biology, Medical College of Georgia, Augusta.     

An elongated segment of DNA observed between two human α globin genes

Summary Detailed restriction enzyme analysis of the DNA from a Chinese female showed that one of her chromosomes had a >17.5 kb deletion of DNA, including the , 2, and 1 globin genes, which is present in many Southeast Asians with an -thalassemia-1 chromosome. Her normal chromosome had the expected cluster of -like globin genes (5----2-1-3), but the segment of DNA between the two globin genes was elongated by some 0.5–0.7 kb. Analyses of various restriction sites suggested that this normal variant of the human globin gene complex is due to a crossover between a normal chromosome with () and a chromosome with an -thalassemia-2 (–^3.7) and an -21-hybrid gene.     

Solution structure of porcine pancreatic phospholipase A2 complexed with micelles and a competitive inhibitor

Summary The three-dimensional structure of porcine pancreatic PLA₂ (PLA₂), present in a 40 kDa ternary complex with micelles and a competitive inhibitor, has been determined using multidimensional heteronuclear NMR spectroscopy. The structure of the protein (124 residues) is based on 1854 constraints, comprising 1792 distance and 62 torsion angle constraints. A total of 18 structures was calculated using a combined approach of distance geometry and restrained molecular dynamics. The atomic rms distribution about the mean coordinate positions for residues 1–62 and 72–124 is 0.75±0.09 Å for the backbone atoms and 1.14±0.10 Å for all atoms. The rms difference between the averaged minimized NMR structures of the free PLA₂ and PLA₂ in the ternary complex is 3.5 Å for the backbone atoms and 4.0 Å for all atoms. Large differences occur for the calcium-binding loop and the surface loop from residues 62 through 72. The most important difference is found for the first three residues of the N-terminal -helix. Whereas free in solution Ala¹, Leu² and Trp³ are disordered, with the -amino group of Ala¹ pointing out into the solvent, in the ternary complex these residues have an -helical conformation with the -amino group buried inside the protein. As a consequence, the important conserved hydrogen bonding network which is also seen in the crystal structures is present only in the ternary complex, but not in free PLA₂. Thus, the NMR structure of the N-terminal region (as well as the calcium-binding loop and the surface loop) of PLA₂ in the ternary complex resembles that of the crystal structure. Comparison of the NMR structures of the free enzyme and the enzyme in the ternary complex indicates that conformational changes play a role in the interfacial activation of PLA₂.     

The monosaccharide binding site of lentil lectin: an X-ray and molecular modelling study

The X-ray crystal structure of lentil lectin in complex with -d-glucopyranose has been determined by molecular replacement and refined to anR-value of 0.20 at 3.0 Å resolution. The glucose interacts with the protein in a manner similar to that found in the mannose complexes of concanavalin A, pea lectin and isolectin I fromLathyrus ochrus. The complex is stabilized by a network of hydrogen bonds involving the carbohydrate oxygens O6, O4, O3 and O5. In addition, the -d-glucopyranose residue makes van der Waals contacts with the protein, involving the phenyl ring of Phe123. The overall structure of lentil lectin, at this resolution, does not differ significantly from the highly refined structures of the uncomplexed lectin.Molecular docking studies were performed with mannose and its 2-O and 3-O-m-nitro-benzyl derivatives to explain their high affinity binding. The interactions of the modelled mannose with lentil lectin agree well with those observed experimentally for the protein-carbohydrate complex. The highly flexible Me-2-O-(m-nitro-benzyl)--d-mannopyranoside and Me-3-O-(m-nitro-benzyl)--d-mannopyranoside become conformationally restricted upon binding to lentil lectin. For best orientations of the two substrates in the combining site, the loss of entropy is accompanied by the formation of a strong hydrogen bond between the nitro group and one amino acid, Gly97 and Asn125, respectively, along with the establishment of van der Waals interactions between the benzyl group and the aromatic amino acids Tyr100 and Trp128.RL and FC are joint first authors.     

G proteins,adenylyl cyclase and related phosphoproteins in the developing rat heart

The postnatal alterations of the composition of a subunit isoforms (G_ic, G _i3 G_o, and _Gq of G proteins, the adenylyl cyclase activity as well as of cAMP-regulated phosphoproteins e.g. troponin and phospholamban were investigated in the ventricular tissue of 1, 7, 30 days old rats. Quantitative immunodetection revealed a 5.7-fold decrease in G_i3 at 30th postnatal day compared with the postnatal day 1 and up to 15-fold at 4 months. The amounts of G_q and G as well as the G subunits were found to be higher in the earlier life period compared to the adult. In contrast, the content of G_s was uneffected by the developmental state. Basal adenylyl cyclase activity (pmoles cAMP/min × mg protein) increased from 30.9 ± 5.0, 36.8 ± 5.0 to 63.9 ± 5.9 at 1st, 7th and 30th postnatal day, respectively. Isoprenaline (100 M) enhanced the activity of adenylyl cyclase from day 1, 7–30 from 46.2 ± 7.0, 79.1 ± 9.2 to 120.5 ± 7.2, respectively. The effects of forskolin and NaF on adenylyl cyclase activity was found to be not influenced within the first postnatal month. Furthermore, a developmentally controlled expression of cardiac troponin I was observed (6-fold from the first to the 28th postnatal day) whereas the level of phospholamban was found to be age-independent.In conclusion, there is an increase in the efficiency of the -adrenergic signal transfer mainly caused by a reduction of the inhibitiory G proteins and a dominance of the G_s-linked pathway in the postnatal rat heart. Furthermore the developmentally controlled expression of troponin I might be of functional importance in the cAMP-supported relaxation. Additionally, altered G_q, G_o and G pattern of the developing rat ventricle may play a role in the observed change of -adrenerg-mediated heart contractility as well as in cardiac differentiation and growth processes.     

Tight-junction protein ZO-1 isoforms (α+ and α−) show differential extractability and epidermal-growth-factor-induced tyrosine phosphorylation in A431 cells

Summary ZO-1, a cytoplasmic plaque protein of tight junctions, exists in vivo as two major isoforms which are defined by the presence or absence of an 80 amino acid domain termed . The ZO-1 (+) isoform is expressed in most epithelial cells while ZO-1(–) isoform expression is restricted to endothelial cells and some highly specialized epithelial cells, suggesting that the isoforms serve different functions. We had previously demonstrated that both ZO-1 isoforms are expressed in A 431 cells and are tyrosine phosphorylated in response to epidermal-growth-factor treatment. In the present study, we found that the (-) isoform of ZO-1 was more tightly associated with the cytoskeleton than was the (+) isoform, based on extraction in nonionic detergent. In addition, the ZO-1(-) was preferentially tyrosine phosphorylated in response to epidermal-growth-factor treatment. However, both isoforms became more tightly associated with the cytoskeleton after A 431 cells were exposed to epidermal growth factor. Immunofluorescence analysis of A 431 cells with isoform-specific antibodies demonstrated that functional differences in ZO-1 isoform behavior were not due to differences in their subcellular locations. The coincident localization of these isoforms does not rule out different affinities for interacting proteins related to the presence or absence of the domain, and it is these interactions that are likely to explain functional differences between the isoforms.     

Structure of theEscherichia coli ATP synthase and role of the γ and ε subunits in coupling catalytic site and proton channeling functions

The structure of theEscherichia coli ATP synthase has been studied by electron microscopy and a model developed in which the and subunits of the F₁ part are arranged hexagonally (in top view) alternating with one another and surrounding a central cavity of around 35 Å at its widest point. The and subunits are interdigitated in side view for around 60 Å of the 90 Å length of the molecule. The F₁ narrows and has three-fold symmetry at the end furthest from the F₀ part. The F₁ is linked to F₀ by a stalk approximately 45 Å long and 25–30 Å in diameter. The F₀ part is mostly buried in the lipid bilayer. The subunit provides a domain that extends into the central cavity of the F₁ part. The and subunits are in a different conformation when ATP+Mg²⁺ are present in catalytic sites than when ATP+EDTA are present. This is consistent with these two small subunits switching conformations as a function of whether or not phosphate is bound to the enzyme at the position of the phosphate of ATP. We suggest that this switching is the key to the coupling of catalytic site events with proton translocation in the F₀ part of the complex.     

Exposure of tryptophanyl residues inα-lactalbumin and lysozyme

Summary The effect of iodide ion on the tryptophyl fluorescence of the homologous proteins lysozyme and-lactalbumin in their native form, as well as in their modified structures and in fragments from these proteins was studied. By assessing the contribution to the total fluorescence of the exposed and buried Trp residues, and of the respective fluorescence quantum yields, the quantization of the number of Trp exposed to the solvent for all the species studied was possible. Both native proteins show an important increase in the number of Trp residues exposed to the solvent when treated with denaturing agents. The peptides L-II (aa 13-105) and-I (aa 1-90) from lysozyme and-lactalbumin, respectively, showed Trp residues with different degree of exposure, whereas the smaller fragments, L-III (aa 106-129) and-II (aa 91–123), had all their Trp residues exposed to the solvent.     

The α1 and α2 domains of H-2 class I molecules interact to form unique epitopes

Mouse class I antigens are the major targets of cytolytic T lymphocytes in both major histocompatibility complex (MHC)-restricted and allogeneic responses. Considerable evidence has recently accumulated demonstrating that MHC class I molecules encoded by genes whose 1 and 2 coding exons were interchanged are not recognized by T lymphocytes specific for parental class I products. Along with the loss of T -cell reactivity, there is a loss of recognition by some, but not all monoclonal antibodies. In this communication we report that the loss of reactivity by monoclonal antibodies is accompanied by the gain of new epitopes caused by the interaction of 1 and 2 domains. These epitopes are immunodominant. They are the major determinant recognized by polyclonal antisera raised by immunization with L cells transfected with exon-shuffled class I genes. Four new monoclonal antibodies have been produced which recognize at least two separate epitopes caused by the interaction of the 1^P and 2^d domains.     

Heterogeneity of the hemoglobin of the Ohrid trout (Salmo L. typicus)

We have analyzed the hemoglobins of five individual trout from the Ohrid Lake (Salmo L. typicus) by electrophoretic methods, by reversed-phase high-performance liquid chromatography, and by limited structural analyses. The two major classes of hemoglobin are type I (35% of total) and type IV (65%). Type IV is the major oxygen-transporting hemoglobin; it consists of three types of chain (in about equal quantities) and three types of chain (one major and two minor types). Several structural differences have been observed between these three (IV) chains and between the three (IV) chains, suggesting a complex genetic system governing the synthesis of these proteins. Moreover, a few amino acid substitutions occur at positions involved in contacts between chains, which suggests that differences in oxygen affinity may exist between these various type IV hemoglobins. Type I hemoglobin is less complex because it contains one type of chain and two chains; the latter two differ in numerous positions, suggesting duplications of the (I)-globin gene. The and chains of type I hemoglobin differ considerably from the and chains of type IV hemoglobin, indicating the existence of (I)- and (I)-globin genes separate from the (IV)- and (IV)- globin genes.This study was supported in part by the Yugoslav-American Joint Funds, pp 812 (to G.D.E.), and by United States Public Health Service Research Grant HLB-05168 (to T.H.J.H.).     

Amide proton temperature coefficients as hydrogen bond indicators in proteins

Correlations between amide proton temperature coefficients (_HN/T) and hydrogen bonds were investigated for a data set of 793 amides derived from 14 proteins. For amide protons showing temperature gradients more positive than –4.6 ppb/K there is a hydrogen bond predictivity value exceeding 85%. It increases to over 93% for amides within the range between –4 and –1 ppb/K. Detailed analysis shows an inverse proportionality between amide proton temperature coefficients and hydrogen bond lengths. Furthermore, for hydrogen bonds of similar bond lengths, values of temperature gradients in -helices are on average 1 ppb/K more negative than in -sheets. In consequence, a number of amide protons in -helices involved in hydrogen bonds shorter than 2 Å show _HN/T < –4.6 ppb/K. Due to longer hydrogen bonds, 90% of amides in 3₁₀ helices and 98% in -turns have temperature coefficients more positive than –4.6ppb/K. Ring current effect also significantly influences temperature coefficients of amide protons. In seven out of eight cases non-hydrogen bonded amides strongly deshielded by neighboring aromatic rings show temperature coefficients more positive than –2 ppb/K. In general, amide proton temperature gradients do not change with pH unless they correspond to conformational changes. Three examples of pH dependent equilibrium showing hydrogen bond formation at higher pH were found. In conclusion, amide proton temperature coefficients offer an attractive and simple way to confirm existence of hydrogen bonds in NMR determined structures.     

Desensitization of prostaglandin F2α receptor-mediated phosphoinositide hydrolysis in cultured rat astrocytes

Desensitization of prostaglandin (PG) F₂ receptor-mediated phosphoinositide (PI) hydrolysis was investigated in cultured rat astrocytes. Prolonged exposure of astrocytes differentiated by dibutyryl cyclic AMP-treatment to PGF₂ caused the desensitization of subsequent PGF₂-induced PI hydrolysis. The desensitization was time- and PGF₂ dose-dependent; maximal decrease in the PI hydrolysis was observed after exposure to 10 M PGF₂ for 4 h and the degree of the desensitization was 31.7±2.7% of control. Pretreatment with either PGD₂ or PGE₂ also induced the desensitization of subsequent PGF₂-stimulated PI hydrolysis and conversely pretreatment of PGF₂ decreased the PI responses to PGD₂ and PGE₂. The desensitization prevented by phloretin and was reversible upon removal of the agonist. Protein synthesis inhibitors blocked the recovery of the desensitization. Treatment of the cells with phorbol 12-myristate 13-acetate had no effect on the desensitization. These results suggest that prolonged exposure of the astrocytes to PGF₂ caused the desensitization of the receptors.     

Oxidation of polycyclic aromatic hydrocarbons by laccase of Coriolus hirsutus

The oxidation of five polycyclic aromatic hydrocarbons; anthracene, benzo()pyrene, fluoranthene, phenanthrene and pyrene was catalyzed by laccase from Coriolus hirsutus in the presence of the redox mediators, 2,2-azinobis(3-ethylbenzthiazoline-6-sulfonate) (ABTS) and 1-hydroxybenzotriazole (HBT). In the ABTS-mediated system, benzo()pyrene was the most rapidly oxidized substrate, with anthracene being the most rapidly oxidized in the HBT-mediated system. There was no clear relationship between the ionization potential and the oxidation of the substrates. ABTS increased the oxidation of benzo()pyrene more than HBT but the oxidation of the other PAHs tested were the opposite. The mediators used in conjunction increased the oxidation of benzo()pyrene compared to using the mediators alone.     

Crystallographic structure of a helical lipopeptaibol antibiotic analogue

An X-ray diffraction analysis of the [Fmoc⁰,TOAC^4,8, Leu-OMe¹¹] analogue of thelipopeptaibol antibiotic trichogin A IV shows that the undecapeptide isfolded in a right-handed, mixed /3₁₀-helix. The helicalmolecules are connected in a head-to-tail arrangement along the b-axisthrough C=O···H-N intermolecular H-bonding. Thispacking mode generates a hydrophobic cavity where the FmocN-protecting groups are accommodated. The distances andangles between the nitroxide groups of the two TOAC residues, separated byone turn of the -helix, have been determined.