Structure schematic diagram

Figure 6.3. High Tq cuprate superconductors (HTSC) as catalysts (a) structural schematic diagram of YBa2Cu307 ( 123 ) HTSC with Cu02 sheets (b) HRTEM atomic image of the 123 phase in [010] projection with ED pattern. The image is recorded near the Scherzer defocus. The positions of the Y, Ba and Cu atom columns are indicated. The layer separation is "- 1.18 nm and the unit cell is outlined. (After Gai and Thomas 1991.)...

Fig. 13 Schematic of the bottom-gate oiganic field-effect transistors (OFETs) with (a) top contact and (b) bottom contact structures. Schematic diagram of a (c) top-gate/bottom contact OFETs using a standard TFT device structures and (d) top-gate/top contact is also shovm. (Reproduced...

Fig. XI-4. Schematic diagram of the structure of an adsorbed polymer chain. Segments are distributed into trains directly attached to the surface and loops and tails extending into solution.

Figure Al.7.6. Schematic diagrams of the DAS model of the Si(l 11)-(7 x 7) surface structure. There are 12 adatoms per unit cell in the outennost layer, which each have one dangling bond perpendicular to the surface. The second layer, called the rest layer, also has six rest atoms per unit cell, each with a perpendicular dangling bond. The comer holes at the edges of the nnit cells also contain one atom with a dangling bond.

Figure 2.10 Examples of schematic diagrams of the type pioneered by Jane Richardson. Diagram (a) illustrates the structure of myoglobin in the same orientation as the computer-drawn diagrams of Figures 2.9b-d. Diagram (b), which is adapted from J. Richardson, illustrates the structure of the enzyme triosephosphate isomerase, determined to 2.5 A resolution in the laboratory of David Phillips, Oxford University. Such diagrams can easily be obtained from databases of protein structures, such as PDB, SCOP or CATH, available on the World Wide Web.

Figure 2.11 Beta sheets are usuaiiy represented simply by arrows in topology diagrams that show both the direction of each (3 strand and the way the strands are connected to each other along the polypeptide chain. Such topology diagrams are here compared with more elaborate schematic diagrams for different types of (3 sheets, (a) Four strands. Antiparallel (3 sheet in one domain of the enzyme aspartate transcarbamoylase. The structure of this enzyme has been determined to 2.8 A resolution in the laboratory of William Lipscomb, Harvard University, (b) Five strands. Parallel (3 sheet in the redox protein flavodoxin, the structure of which has been determined to 1.8 A resolution in the laboratory of Martha Ludwig, University of Michigan, (c) Eight strands. Antiparallel barrel in the electron carrier plastocyanln. This Is a closed barrel where the sheet is folded such that (3 strands 2 and 8 are adjacent. The structure has been determined to 1.6 A resolution in the laboratory of Hans Freeman in Sydney, Australia. (Adapted from J. Richardson.)...

Figure 2.17 Two adjacent parallel p strands are usually connected by an a helix from the C-termlnus of strand 1 to the N-termlnus of strand 2. Most protein structures that contain parallel p sheets are built up from combinations of such p-a-P motifs. Beta strands are red, and a helices are yellow. Arrows represent P strands, and cylinders represent helices, (a) Schematic diagram of the path of the main chain, (b) Topological diagrams of the P-a-P motif.

Figure 3.1 Schematic diagram of the coiled-coil structure. Two a helices are intertwined and gradually coil around each other.

Figure 3.3 Schematic diagram showing the packing of hydrophobic side chains between the two a helices in a coiled-coil structure. Every seventh residue in both a helices is a leucine, labeled "d." Due to the heptad repeat, the d-residues pack against each other along the coiled-coil. Residues labeled "a" are also usually hydrophobic and participate in forming the hydrophobic core along the coiled-coil.

Figure 3.S Schematic diagram of packing side chains In the hydrophobic core of colled-coll structures according to the "knobs In holes" model. The positions of the side chains along the surface of the cylindrical a helix Is pro-jected onto a plane parallel with the heUcal axis for both a helices of the coiled-coil. (a) Projected positions of side chains in helix 1. (b) Projected positions of side chains in helix 2. (c) Superposition of (a) and (b) using the relative orientation of the helices In the coiled-coil structure. The side-chain positions of the first helix, the "knobs," superimpose between the side-chain positions In the second helix, the "holes." The green shading outlines a d-resldue (leucine) from helix 1 surrounded by four side chains from helix 2, and the brown shading outlines an a-resldue (usually hydrophobic) from helix 1 surrounded by four side chains from helix 2.

Figure 3.8 Schematic diagram of the dimeric Rop molecule. Each subunit comprises two a helices arranged in a coiled-coil structure with side chains packed into the hydrophobic core according to the "knobs in holes" model. The two subunits are arranged in such a way that a bundle of four a helices is formed.

Fi re 3.9 Schematic diagram of the structure of one domain of a bacterial muramidase, comprising 450 amino acid residues. The structure is built up from 27 a helices arranged in a two-layered ring. The ring has a large central hole, like a doughnut, with a diameter of about 30 A. 

Figure 4.3 In most a/p-barrel structures the eight p strands of the barrel enclose a tightly packed hydrophobic core formed entirely by side chains from the p strands. The core is arranged in three layers, with each layer containing four side chains from alternate p strands. The schematic diagram shows this packing arrangement in the a/p barrel of the enzyme glycolate oxidase, the structure of which was determined by Carl Branden and colleagues in Uppsala, Sweden.

Figure 4.4 Schematic diagram of the structure of the a/p-barrel domain of the enzyme methylmalonyl-coenzyme A mutase. Alpha helices are red, and p strands are blue. The inside of the barrel is lined by small hydrophilic side chains (serine and threonine) from the p strands, which creates a hole in the middle where one of the substrate molecules, coenzyme A (green), binds along the axis of the barrel from one end to the other. (Adapted from a computer-generated diagram provided by P. Evans.)...

Figure 4.11 Schematic diagram of the structure of the ribonuclease inhibitor. The molecule, which is built up by repetitive P-loop-a motifs, resembles a horseshoe with a 17-stranded parallel p sheet on the inside and 16 a helices on the outside. The P sheet is light red, a helices are blue, and loops that are part of the p-loop-(x motifs are orange. (Adapted from B. Kobe et al.. Nature 366 7S1-756,...

Figure 4.12 Schematic diagram illustrating the role of the conserved leucine residues (green) in the leucine-rich motif in stabilizing the P-loop-(x structural module. In the ribonuclease inhibitor, leucine residues 2, 5, and 7 from the P strand pack against leucine residues 17, 20, and 24 from the a helix as well as leucine residue 12 from the loop to form a hydrophobic core between the P strand and the a helix.

The first structure, flavodoxin (Figure 4.14a), has one such position, between strands 1 and 3. The connection from strand 1 goes to the right and that from strand 3 to the left. In the schematic diagram in Figure 4.14a we can see that the corresponding a helices are on opposite sides of the p sheet. The loops from these two p strands, 1 and 3, to their respective a helices form the major part of the binding cleft for the coenzyme FMN (flavin mononucleotide). 

Figure 4.17 Schematic diagram of bound tyrosine to tyrosyl-tRNA synthetase. Colored regions correspond to van der Waals radii of atoms within a layer of the structure through the tyrosine ring. Red is bound tyrosine green is the end of P strand 2 and the beginning of the following loop region yellow is the loop region 189-192 and brown is part of the a helix in loop region 173-177.

Figure 4.21 The polypeptide chain of the arabinose-binding protein in E. coli contains two open twisted a/P domains of similar structure. A schematic diagram of one of these domains is shown in (a). The two domains are oriented such that the carboxy ends of the parallel P strands face each other on opposite sides of a crevice in which the sugar molecule binds, as illustrated in the topology diagram (b). [(a) Adapted from J. Richardson.)...

Figure S.3 Schematic diagram of the structure of human plasma retinol-binding protein (RBP), which is an up-and-down P barrel. The eight antiparallel P strands twist and curl such that the structure can also be regarded as two p sheets (green and blue) packed against each other. Some of the twisted p strands (red) participate in both P sheets. A retinol molecule, vitamin A (yellow), is bound inside the barrel, between the two P sheets, such that its only hydrophilic part (an OH tail) is at the surface of the molecule. The topological diagram of this stmcture is the same as that in Figure 5.2. (Courtesy of Alwyn Jones, Uppsala, Sweden.)...

Figure S.7 The subunit structure of the neuraminidase headpiece (residues 84-469) from influenza virus is built up from six similar, consecutive motifs of four up-and-down antiparallel fi strands (Figure 5.6). Each such motif has been called a propeller blade and the whole subunit stmcture a six-blade propeller. The motifs are connected by loop regions from p strand 4 in one motif to p strand 1 in the next motif. The schematic diagram (a) is viewed down an approximate sixfold axis that relates the centers of the motifs. Four such six-blade propeller subunits are present in each complete neuraminidase molecule (see Figure 5.8). In the topological diagram (b) the yellow loop that connects the N-terminal P strand to the first P strand of motif 1 is not to scale. In the folded structure it is about the same length as the other loops that connect the motifs. (Adapted from J. Varghese et al.. Nature 303 35-40, 1983.)...

Figure 5.9 The six four-stranded motifs in a single subunit of neuraminidase form the six blades of a propeller-like structure. A schematic diagram of the subunit structure shows the propeller viewed from its side (a). An idealized propeller structure viewed from the side to highlight the position of the active site is shown in (b). The loop regions that connect the motifs (red in b) in combination with the loops that connect strands 2 and 3 within the motifs (green in b) form a wide funnel-shaped active site pocket, [(a) Adapted from P. Colman et ah, Nature 326 358-363, 1987.]...

We can immediately discern from Figure 5.11 that the molecule is divided into two clearly separated domains that seem to be of similar size. For the next step we would need a stereopicture of the model or, much better, a graphics display where we could manipulate the model and look at it from different viewpoints. Here instead we have made a schematic diagram of one domain (Figure 5.12), which is normally not done until the analysis is completed and the structural principles are clear. 

Figure S.12 Schematic diagram of the path of the polypeptide chain In one domain (the blue region in Figure 5.11) of the y-crystallln molecule. The domain structure is built up from two P sheets of four antiparallel p strands sheet 1 from p strands 1, 2, 4, and 7 and sheet 2 from strands 3, 5, 6, and 8.

Figure S.28 Schematic diagrams of the two-sheet P helix. Three complete coils of the helix are shown in (a). The two parallel P sheets ate colored gieen and red, the loop regions that connect the P strands ate yellow, (b) Each stmctuial unit Is composed of 18 residues forming a P-loop-P-loop structure. Each loop region contains six residues of sequence Gly-Gly-X-Gly-X-Asp where X is any residue. Calcium Ions are bound to both loop regions. (Adapted from F. Jumak et al., Ciirr. Opin. Struct. Biol. 4 802-806, 1994.)...

Figure 5.30 Schematic diagrams of the structure of the enzyme pectate lyase C, which has a three-sheet parallel P-helix topology.

Figure 6.4 Schematic diagram of the structure of the enzyme barnase which is foided into a five stranded antiparallel p sheet (blue) and two a helices (red).

Figure 6.8 Schematic diagram of the enzyme DsbA which catalyzes disulfide bond formation and rearrangement. The enzyme is folded into two domains, one domain comprising five a helices (green) and a second domain which has a structure similar to the disulfide-containing redox protein thioredoxin (violet). The N-terminal extension (blue) is not present in thioredoxin. (Adapted from J.L. Martin et al.. Nature 365 464-468, 1993.)...

Figure 6.21 Schematic diagram of the conformational changes of calmodulin upon peptide binding, (a) In the free form the calmodulin molecule is dumhhell-shaped comprising two domains (red and green), each having two EF hands with bound calcium (yellow), (b) In the form with bound peptides (blue) the a helix linker has been broken, the two ends of the molecule are close together and they form a compact globular complex. The internal structure of each domain is essentially unchanged. The hound peptide binds as an a helix.

Figure 6,22 Schematic diagram of the structure of ovalbumin which illustrates the serpin fold. The structure is built up of a compact body of three antiparallel p sheets,...

Figure 6.23 Schematic diagram illustrating the active site loop regions (red) in three forms of the serpins. (a) In the active form the loop protrudes from the main part of the molecuie poised to interact with the active site of a serine proteinase. The first few residues of the ioop form a short p strand inserted between ps and pis of sheet A. (h) As a result of inhibiting proteases, the serpin molecules are cleaved at the tip of the active site ioop region, in the cleaved form the N-terminal part of the loop inserts itself between p strands 5 and 15 and forms a long p strand (red) in the middie of the p sheet, (c) In the most stable form, the latent form, which is inactive, the N-terminai part of the ioop forms an inserted p strand as in the cleaved form and the remaining residues form a ioop at the other end of the p sheet. (Adapted from R.W. Carreii et ai., Structure 2 257-270, 1994.)...

Figure 6.25 Schematic diagram of the structure of one dimer of phosphofructokinase. Each polypeptide chain is folded Into two domains (blue and red, and green and brown), each of which has an oi/p structure. Helices are labeled A to M and p strands 1 to 11 from the amino terminus of one polypeptide chain, and respectively from A to M and 1 to 11 for the second polypeptide chain. The binding sites of substrate and effector molecules are schematically marked In gray. The effector site of one subunit is linked to the active site of the other subunit of the dimer through the 6-F loop between helix F and strand 6. (Adapted from T. Schlrmer and P.R. Evans, Nature 343 140-145, 1990.)...

Figure 8.3 The DNA-binding protein Cro from bacteriophage lambda contains 66 amino acid residues that fold into three a helices and three P strands, (a) A plot of the Ca positions of the first 62 residues of the polypeptide chain. The four C-terminal residues are not visible in the electron density map. (b) A schematic diagram of the subunit structure. a helices 2 and 3 that form the helix-turn-helix motif ate colored blue and red, respectively. The view is different from that in (a), [(a) Adapted from W.F. Anderson et al., Nature 290 754-758, 1981. (b) Adapted from D. Ohlendorf et al., /. Mol. Biol. 169 757-769, 1983.]...

Figure 8.20 Schematic diagrams of docking the trp repressor to DNA in its inactive (a) and active (b) forms. When L-tryptophan, which is a corepressor, hinds to the repressor, the "heads" change their positions relative to the core to produce the active form of the repressor, which hinds to DNA. The structures of DNA and the trp repressor are outlined.

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