A model for the three-dimensional structure of glucagon

A literature search on the structural aspects of glucagon in dilute aqueous solution has been undertaken. We have found that a compact, well-defined structure must exist and propose a model for that structure. In doing so, care was taken to distinguish between the raw data themselves and the interpretations drawn from them, and to bring about a model consistent with as much of the data as possible. The model building was performed on Corey-Pauling-Koltun (CPK) space-filling models using secondary structure prediction rules, experimental data such as fluorescence quenching, circular dichroism, NMR and high resolution dark field electron microscopy, and was guided by a hierarchy of intramolecular interactions which places hydrophobic bonding first and hydrogen bonding second. This last criterion places a strict requirement on the model-building to maximize contacts among complementary hydrophobic surfaces; this means that no empty spaces are allowed inside the folded molecule. The resultant model is consistent with all the relevant data. Furthermore, as demanded by any structure building exercise, the model suggests structure-function relationships. One of the predictions drawn from the structure—the binding of guanosine-5′-triphosphate (GTP)—has been confirmed by a preliminary experiment (reported elsewhere). Another aspect of the structure suggests a subtle mechanism for allostery.     

A revisit to the three-dimensional structure of B-type starch

A new three-dimensional structure of B-starch is proposed in which the unit cell contains 12 glucose residues located in two left-handed, parallel-stranded double helices packed in a parallel register; 36 water molecules are located between these helices. Chains are crystallized in the hexagonal space group P6₁, with lattice parameters a = b = 1.85 nm, c = 1.04 nm. The space group symmetry was derived from an exhaustive analysis of the large body of structural studies published so far. Diffraction data used in this work were taken from the previously reported x-ray fiber diffractogram [H.C. Wu and A. Sarko (1978), Carbohydrate Research, 61 , 7–25] after adequate reindexing. The final R factor is 0.145 for the three-dimensional data. The repeating unit consists of a maltose molecule where the glucose residues have the ⁴C₁ pyranose conformation and are α(1 → 4) linked. The conformation of the glycosidic linkage is characterized by torsion angles (Φ, Ψ) that take the values (83.8°, ?144.6°) and (84.3°, ?144.1°), whereas the valence angles at the glycosidic bridge have a magnitude of 115.8° and 116.5°, respectively. The primary hydroxyl groups exist in a gauche–gauche conformation. There is no intramolecular hydrogen bond. Within the double helix, interstrand stabilization is achieved without any steric conflict and through the occurrence of O(2)…O(6) type of hydrogen bonds. The model presented here, with an hydration around 27% w/w, corresponds to a well-ordered crystalline sample, since all the water molecules could be located with no apparent sign of a disorder. Half of the water molecules are tightly bound to the double helices; the remainder forms a complex network centered around the sixfold screw axis of the unit cell. The consistency of the present structural model, with both physicochemical and biochemical aspects of the crystalline component of tuber starch granules, is analyzed.     

A three-dimensional cryo-electron microscopy structure of the bacteriophage phiKZ head

The three-dimensional structure of the Pseudomonas aeruginosa bacteriophage phiKZ head has been determined by cryo-electron microscopy and image reconstruction to 18A resolution. The head has icosahedral symmetry measuring 1455 A in diameter along 5-fold axes and a unique portal vertex to which is attached an approximately 1800 A-long contractile tail. The 65 kDa major capsid protein, gp120, is organized into a surface lattice of hexamers, with T = 27 triangulation. The shape and size of the hexamers is similar to the hexameric building blocks of the bacteriophages T4, phi29, P22, and HK97. Pentameric vertices of the capsid are occupied by complexes composed of several special vertex proteins. The double-stranded genomic DNA is packaged into a highly condensed series of layers, separated by 24 A, that follow the contour of the inner wall of the capsid.     

The three-dimensional structure of ricin at 2.8 A

The x-ray crystallographic structure of the heterodimeric plant toxin ricin has been determined at 2.8-A resolution. The A chain enzyme is a globular protein with extensive secondary structure and a reasonably prominent cleft assumed to be the active site. The B chain lectin folds into two topologically similar domains, each binding lactose in a shallow cleft. In each site a glutamine residue forms a hydrogen bond to the OH-4 of galactose, accounting for the epimerimic specificity of binding. The interface between the A and B chains shows some hydrophobic contacts in which proline and phenylalanine side chains play a prominent role.     

Calculating three-dimensional molecular structure from atom-atom distance information: cyclosporin A

In recent years methods for deriving spatial molecular structure from atom-atom distance information have gained in importance due to the emergence of two-dimensional nuclear magnetic resonance (n.m.r) techniques, which make it possible to obtain such distance information for polypeptides, small proteins, sugars, and DNA fragments in solution. Distance geometry (DG) and restrained molecular dynamics (MD) refinement are applied to a cyclic polypeptide, the immunosuppressive drug cyclosporin A, and the results are compared. Two different procedures, DG followed by restrained MD, and straightforward restrained MD starting from the X-ray structure, both lead to a unique conformation that satisfies the 58 experimentally determined distance constraints. The results nicely show the relative merits of DG and restrained MD techniques for determining spatial molecular structure from distance information.     

Challenging the three-dimensional structure of ribosomes

A prerequisite for understanding the detailed mechanism of the intricate process of protein biosynthesis is the determination of the molecular structure of ribosomes. This may be obtained by crystallographic analysis. Although such studies, in general, provide static pictures, they do indicate how to design subsequent functional and dynamic experiments. Thus, investigating models obtained by three-dimensional image reconstruction have stimulated further biochemical as well as crystallographic studies.     

NMR three-dimensional solution structure of the serine protease inhibitor cyclotheonamide A

The nmr solution conformation of cyclotheonamide A (CtA) was determined in aqueous media. The data produced 15 distance and 10 torsional constraints which were used to generate conformations using restrained simulated annealing (SA) and distance geometry/simulated annealing (DG/SA) calculations. Two different calculation protocols were performed to ensure proper sampling of conformational space and even though the torsional restraints were input differently, both calculation methods yielded the same conformation of CtA. In the structure calculations, all solutions of the Karplus equation were sampled simultaneously using the restrained SA protocol and large ranges were used for the dihedral restraints in the DG/SA protocol because all solutions to the Karplus equation could not be sampled simultaneously. The solution conformation was also compared to the solid state x-ray conformations of CtA bound to thrombin and trypsin. The conformation of the residues important for active site binding (d -Phe, h-Arg, and Pro) are nearly identical in aqueous solution and solid state with largest differences at the a-Ala and v-Tyr residues. CtA appears to be preordered in structure and does not undergo a significant conformational change upon binding to the enzyme active site. © 1997 John Wiley & Sons, Inc.     

Cell-free synthesis and combinatorial selective N-labeling of the cytotoxic protein amoebapore A from Entamoeba histolytica

Amoebapore A is a pore-forming protein produced by the pathogenic parasite Entamoeba histolytica, which causes human amoebic dysentery. The pore-forming activity of amoebapore A is regulated by pH-dependent dimerization, a prerequisite for membrane insertion and pore formation. Understanding of these important processes has been hampered by the cytotoxicity of amoebapore A, which prevents the production of this protein in cell-based expression systems. In this study, a protocol for the cell-free production of active recombinant amoebapore A is presented. Protein yields of 500 μg/ml of cell-free reaction were achieved. Recombinant amoebapore A was purified using a three-step procedure. To facilitate the structural characterization of the dimeric and pore forms, we adapted the cell-free system to isotope label amoebapore A for NMR studies. The preliminary assignment of a 2D ¹H–¹⁵N HSQC spectrum of a uniformly ¹³C/¹⁵N-labeled sample was achieved using a combinatorial selective ¹⁵N-labeling approach coupled with available ¹H_N chemical shift data, resulting in the unambiguous assignment of resonances from 55 of the 77 residues. To confirm these results and obtain the full sequence-specific assignments of the 2D ¹H–¹⁵N HSQC spectrum, a 3D HNCA spectrum was recorded. These assignment data will be used to aid the characterization of amoebapore A dimer formation and membrane insertion.     

Probing the three-dimensional structure of human calreticulin

Calreticulin (CRT) is an abundant soluble protein of the endoplasmic reticulum lumen that functions as a molecular chaperone for nascent glycoproteins. We have probed the three-dimensional structure of human CRT using a series of biochemical and biophysical approaches in an effort to understand the molecular basis of its chaperone function. Sedimentation analysis and chemical cross-linking experiments showed that CRT is monodisperse and monomeric in solution with a molecular mass (MW) of 46 +/- 1 kDa. This MW value together with a sedimentation coefficient, s(o)(20,w), of 2.71 S yielded a frictional ratio, f/f(0), of 1.65. Assuming CRT to be a prolate ellipsoid, we calculated an apparent length of 29.8 nm and diameter of 2.44 nm consistent with an asymmetric elongated molecule. These hydrodynamic dimensions account for the apparent anomalous elution position of CRT on gel filtration columns. Far-UV circular dichroism experiments showed that CRT has a cooperative thermal denaturation transition with a midpoint temperature of 42.5 degrees C suggesting a marginally stable structure. Proteolysis experiments showed that the highly acidic segment at the C-terminus of CRT is most susceptible to digest, consistent with the absence of a well-defined polypeptide backbone structure in this region of the protein. Temperature-dependent proteolysis with thermolysin revealed a stable core region within the N- and P-domains. A stable fragment encompassing most of the P-domain was also identified in the thermolytic mixture. Collectively, our results suggest that CRT is likely to be a flexible molecule in solution which may be important for its chaperone function.     

A predicted three-dimensional structure for the carcinoembryonic antigen (CEA).

A three-dimensional model for the carcinoembryonic antigen (CEA) has been constructed by knowledge-based computer modelling. Each of the seven extracellular domains of CEA are expected to have immunoglobulin folds. The N-terminal domain of CEA was modelled using the first domain of the recently solved NMR structure of rat CD2, as well as the first domain of the X-ray crystal structure of human CD4 and an immunoglobulin variable domain REI as templates. The remaining domains were modelled from the first and second domains of CD4 and REI. Link conformations between the domains were taken from the elbow region of antibodies. A possible packing model between each of the seven domains is proposed. Each residue of the model is labelled as to its suitability for site-directed mutagenesis.     

Effect of the three-dimensional structure on the deamidation reaction of ribonuclease A.

Kinetic data on the deamidation reaction of Asn67 in RNase A and of Asn3 in the two peptides Ac-Cys-Lys-Asn-Gly-Gln-Thr-Asn-Cys-NH2 and Ac-Cys(Me)-Lys-Asn-Gly-Gln-Thr-Asn-Cys(Me)-NH2, whose sequences are similar to that of the deamidation site in the enzyme, have been determined in a wide range of pH and buffer concentrations. The values of the observed rate constant (k) for the enzyme are markedly lower than those for the peptides. However, the k dependence on pH and buffers is similar for all three substrates, indicating a similar reaction mechanism. The lower k-values for the enzyme have been quantitatively related to the thermal stability and the three-dimensional structure of the enzyme.     

Predicting protein three-dimensional structure

The current state of the art in modeling protein structure has been assessed, based on the results of the CASP (Critical Assessment of protein Structure Prediction) experiments. In comparative modeling, improvements have been made in sequence alignment, sidechain orientation and loop building. Refinement of the models remains a serious challenge. Improved sequence profile methods have had a large impact in fold recognition. Although there has been some progress in alignment quality, this factor still limits model usefulness. In ab initio structure prediction, there has been notable progress in building approximately correct structures of 40-60 residue-long protein fragments. There is still a long way to go before the general ab initio prediction problem is solved. Overall, the field is maturing into a practical technology, able to deliver useful models for a large number of sequences.     

A new stereophotographic technique for analyzing the three-dimensional structure of fish schools

Synopsis A technique using two downward-directed 35 mm cameras has been modified to measure the three-dimensional structure of fish schools. The resulting stereo pairs of photographs are analyzed, producing the 3-coordinate location of each fish's nose, after correction for lens distortion and refraction. Separation angles (bearing and elevation) and distance can then be determined for any pair of fish in the school. The technique's high level of accuracy is demonstrated for an underwater calibration field. It is then applied to the measurement of the 3-D structure of schools of coho salmon (Oncorhymchus kisutch) swimming in a hatchery trough. Although the fish were not organized in a rigid crystal lattice, the analysis provided some evidence of structure.     

iFoldRNA: three-dimensional RNA structure prediction and folding

Three-dimensional RNA structure prediction and folding is of significant interest in the biological research community. Here, we present iFoldRNA, a novel web-based methodology for RNA structure prediction with near atomic resolution accuracy and analysis of RNA folding thermodynamics. iFoldRNA rapidly explores RNA conformations using discrete molecular dynamics simulations of input RNA sequences. Starting from simplified linear-chain conformations, RNA molecules (<50 nt) fold to native-like structures within half an hour of simulation, facilitating rapid RNA structure prediction. All-atom reconstruction of energetically stable conformations generates iFoldRNA predicted RNA structures. The predicted RNA structures are within 2-5 A root mean squre deviations (RMSDs) from corresponding experimentally derived structures. RNA folding parameters including specific heat, contact maps, simulation trajectories, gyration radii, RMSDs from native state, fraction of native-like contacts are accessible from iFoldRNA. We expect iFoldRNA will serve as a useful resource for RNA structure prediction and folding thermodynamic analyses. AVAILABILITY: http://iFoldRNA.dokhlab.org.     

Rhodopsin-transducin heteropentamer: three-dimensional structure and biochemical characterization

The process of vision is initiated when the G protein-coupled receptor, rhodopsin (Rho), absorbs a photon and transitions to its activated Rho^∗ form. Rho^∗ binds the heterotrimeric G protein, transducin (G_t) inducing GDP to GTP exchange and G_t dissociation. Using nucleotide depletion and affinity chromatography, we trapped and purified the resulting nucleotide-free Rho^∗·G_t complex. Quantitative SDS–PAGE suggested a 2:1 molar ratio of Rho^∗ to G_t in the complex and its mass determined by scanning transmission electron microscopy was 221 ± 12 kDa. A 21.6 Å structure was calculated from projections of negatively stained Rho^∗·G_t complexes. The molecular envelope thus determined accommodated two Rho molecules together with one G_t heterotrimer, corroborating the heteropentameric structure of the Rho^∗·G_t complex.     

Phosphoenolpyruvate carboxylase: three-dimensional structure and molecular mechanisms

Phosphoenolpyruvate carboxylase (PEPC; EC 4.1.1.31) catalyzes the irreversible carboxylation of phosphoenolpyruvate (PEP) to form oxaloacetate and Pi using Mg2+ or Mn2+ as a cofactor. PEPC plays a key role in photosynthesis by C4 and Crassulacean acid metabolism plants, in addition to its many anaplerotic functions. Recently, three-dimensional structures of PEPC from Escherichia coli and the C4 plant maize (Zea mays) were elucidated by X-ray crystallographic analysis. These structures reveal an overall square arrangement of the four identical subunits, making up a "dimer-of-dimers" and an eight-stranded beta barrel structure. At the C-terminal region of the beta barrel, the Mn2+ and a PEP analog interact with catalytically essential residues, confirmed by site-directed mutagenesis studies. At about 20A from the beta barrel, an allosteric inhibitor (aspartate) was found to be tightly bound to down-regulate the activity of the E. coli enzyme. In the case of maize C4-PEPC, the putative binding site for an allosteric activator (glucose 6-phosphate) was also revealed. Detailed comparison of the various structures of E. coli PEPC in its inactive state with maize PEPC in its active state shows that the relative orientations of the two subunits in the basal "dimer" are different, implicating an allosteric transition. Dynamic movements were observed for several loops due to the binding of either an allosteric inhibitor, a metal cofactor, a PEP analog, or a sulfate anion, indicating the functional significance of these mobile loops in catalysis and regulation. Information derived from these three-dimensional structures, combined with related biochemical studies, has established models for the reaction mechanism and allosteric regulation of this important C-fixing enzyme.     

Digestive lipases: from three-dimensional structure to physiology

Human gastric lipase (HGL) is a lipolytic enzyme that is secreted by the chief cells located in the fundic part of the stomach. HGL plays an important role in lipid digestion, since it promotes the subsequent hydrolytic action of pancreatic lipase in duodenal lumen. Physiological studies have shown that HGL is able of acting not only in the highly acid stomach environment but also in the duodenum in synergy with human pancreatic lipase (HPL). Recombinant HGL (r-HGL) was expressed in the baculovirus/insect cell system in the form of an active protein with a molecular mass of 45 kDa. The specific activities of r-HGL were found to be similar to that of the native enzyme when tested on various triacylglycerol (TG) substrates. The 3-D structure of r-HGL was the first solved within the mammalian acid lipase family. This globular enzyme (379 residues) shows a new feature, different from the other known lipases structures, which consists of a core domain having the alpha/beta hydrolase fold and a cap domain including a putative 'lid' of 30 residues covering the active site of the lipase (closed conformation). HPL is the major lipolytic enzyme involved in the digestion of dietary TG. HPL is a 50 kDa glycoprotein which is directly secreted as an active enzyme. HPL was the first mammalian lipase to be solved structurally, and it revealed the presence of two structural domains: a large N-terminal domain (residues 1-336) and a smaller C-terminal domain (residues 337-449). The large N-terminal domain belongs to the alpha/beta hydrolase fold and contains the active site. A surface loop called the lid domain (C237-C261) covers the active site in the closed conformation of the lipase. The 3-D structure of the lipase-procolipase complex illustrates how the procolipase might anchor the lipase at the interface in the presence of bile salts: procolipase binds to the C-terminal domain of HPL and exposes the hydrophobic tips of its fingers at the opposite site of its lipase-binding domain. These hydrophobic tips help to bring N-terminal domain into close conformation with the interface where the opening of the lid domain probably occurs. As a result of all these conformational changes, the open lid and the extremities of the procolipase form an impressive continuous hydrophobic plateau, extending over more than 50 A. This surface might able to interact strongly with a lipid-water interface. The biochemical, histochemical and clinical studies as well as the 3-D structures obtained will be a great help for a better understanding of the structure-function relationships of digestive lipases.