Acid schematic representation

Fig. 1 Separation of carboxylic acids (schematic representation). Citric acid (1), lactic acid (2), phthalic acid (3), sebacinic acid (4), salicylic acid (5), mixture (M).

Scheme 4.6. Schematic representation of the use of a coordinating auxiliary for Lewis-acid catalysis of a Diels-Alder reaction.

Several human receptors for the neurohypophyseal hormones have been cloned and the sequences elucidated. The human V2 receptor for antidiuretic hormone presumably contains 371 amino acids and seven transmembrane segments and activates cycHc AMP (76). The oxytocin receptor is a classic G-protein-coupled type of receptor with a proposed membrane topography also involving seven transmembrane components (84). A schematic representation of the oxytocin receptor stmcture within the membrane is shown in Eigure 4 (85). 

Figure 3.6 Four-helix bundles frequently occur as domains in a proteins. The arrangement of the a helices is such that adjacent helices in the amino acid sequence are also adjacent in the three-dimensional structure. Some side chains from all four helices are buried in the middle of the bundle, where they form a hydrophobic core, (a) Schematic representation of the path of the polypeptide chain in a four-helrx-bundle domain. Red cylinders are a helices, (b) Schematic view of a projection down the bundle axis. Large circles represent the main chain of the a helices small circles are side chains. Green circles are the buried hydrophobic side chains red circles are side chains that are exposed on the surface of the bundle, which are mainly hydrophilic.

P-form long chains giving crystals that cleave into laths parallel to the chain Figure 3.9 Schematic representation of the two forms of oxalic acid, (-C02H)2. 

Figure 12.17 Schematic representation of proton-switch conduction mechanism involving [U2PO4I phosphoric acid.

Fig. 1.4 Schematic representation of the reaction products formed on lead in sulphuric acid and their distribution over a range of anodic potentials (after Burbank...

Fig. 19.15 Schematic representation of range of corrosion potentials expected from various chemical tests for sensitisation in relation to the anodic dissolution kinetics of the matrix (Fe-l8Cr-IONi stainless steel) and grain boundary alloy (assumed to be Fe-lOCr-lONi) owing to depletion of Cr by precipitation of Cr carbides of a sensitised steel in a hot reducing acid (after Cowan and Tedmon )...

Fig. 19.39 Schematic representation of reactions during (a) controlled potential and (b) conventional corrosion tests in acidic chloride solutions. In (a) charge balance must be maintained by migration of Cl" ions, since the cathodic reaction occurs elsewhere at the counter-electrode. In (b) the anodic and cathodic sites are in close proximity, and charge balance is maintained without migration of Cl" ions from the bulk solution (after France and Greene )...

On increasing the acidity still further (>0.1 m H2S04, i.e., H0< 1), the rate of diazotization of aniline passes through a minimum and then increases rapidly (region B in Fig. 3-1). The plot in Figure 3-1 is a somewhat schematic representation of the minimum, the position of which depends very much on the concentration of nitrous acid. Moreover, with other aromatic amines the plot is not exactly the same, but it can be explained by analogous arguments. 

Figure 3.1 A schematic representation of the control mechanism that stimulates gastric acid secretion, and the intervention points used to treat ulcers. The parietal cells and gastric cells form part of the epithelial cell lining of the stomach. Histamine release is usually triggered as part ofthe enteric nervous system response to distension of the stomach when food is eaten.

Fig. 17 Detection of the photochemical cis/trans isomerization of butter yeliow after UV irradiation by using the SRS technique. (A) original chromatogram — treated with hydrochloric acid vapor for better recognition (yellow then turns red) — and (B) schematic representation.

Fig. 2.14 Formulae of /5-peptides 81 and 82 forming stable 3,4-helical structures in aqueous solution and schematic representation of the position of the amino acid side-chains looking down the 3,4-helix axis [128, 165]...

FIGURE 1 Schematic representation of the use of trifunctional amino acids as monomeric starting materials for the synthesis of pseudopoly-(amino acids), (a) Polymerization via the C terminus and the side chain R. (b) Polymerization via the N terminus and the side chain R. (c) Polymerization via the C terminus and the N terminus. The wavy line symbolizes any suitable nonamide bond. See text for details. ... 

FIGURE 3 Schematic representation of a pseudopoly (amino acid) derived from the side chain polymerization of a dipeptide carrying protecting groups X and Y. The wavy line symbolizes a nonamide bond. In this polymer, the amino acid side chains are an integral part of the polymer backbone while the termini have become pendant chains. In the backbone, amide and nonamide bonds strictly alternate. 

Figure 39-13. A schematic representation of the three-dimensional structure of Cro protein and its binding to DNA by its helix-turn-helix motif. The Cro monomer consists of three antiparallel p sheets (P1-P3) and three a-helices (a,-a3).The helix-turn-helix motif is formed because the aj and U2 helices are held at about 90 degrees to each other by a turn offour amino acids. The helix of Cro is the DNA recognition surface (shaded). Two monomers associate through the antiparallel P3 sheets to form a dimer that has a twofold axis of symmetry (right). A Cro dimer binds to DNA through its helices, each of which contacts about 5 bp on the same surface of the major groove. The distance between comparable points on the two DNA a-helices is 34 A, which is the distance required for one complete turn of the double helix. (Courtesy of B Mathews.)...

Fig. 14.—Schematic Representation of the Fragmentation Observed in the Positive F.a.b.-Mass Spectrum of a Permethylated Ganglioside Isolated from Granulocytes. [Other glyco-sphingolipids fragment in a similar way. Major cleavages are shown with solid lines, and minor cleavages with dotted lines. The masses of ions resulting from cleavages (a), (b), and (c) define the type of sphingosine and the type of fatty acid. In this example, (a) is 548, (b) is [M + H] minus 238, and (c) is [M + H] minus 533.]...

Figure 7.4 Comparative schematic representation of the Dj ( ) and D (—) dopamine receptor. The figure attempts to highlight the major differences between extra- and intracellular loops, especially the intracellular loops between transmembrane sections 5 and 6 and the much longer C terminal of the Dj compared with the D2 receptor. It is based on the proposed topography of Sibley and Monsma (1992). The thickened length of the D2 receptor represents the amino-acid sequence missing in the short form of the receptor. No attempt has been made to show differences in amino-acid sequencing or transmembrane topography...

Figure 18.5 Schematic representation of possible cleavage sites of APP by a, and y-secretase and the production of j5-amyloid protein. (I) This shows the disposition of APP molecules in 695, 751 and 770 amino-acid chain lengths. Much of it is extracellular. The /1-amyloid (A/I4) sequence is partly extracellular and partly in the membrane. (II) An enlargement of the /1-amyloid sequence. (Ill) Normal cleavage of APP by a-secretase occurs in the centre of A/I4 sequence to release the extracellular APP while the remaining membrane and intracellular chain is broken down by y-secretase to give two short proteins that are quickly broken down. (IV) In Alzheimer s disease ji rather than a-secretase activity splits off the extracellular APP to leave the full AP4 sequence remaining attached to the residual membrane and intracellular chain. 42/43 amino acid )S-amyloid sequence is then split off by y-secretase activity...

Figure 3. Schematic representation of the PGII, PGI, PGC [13] and PGE proteins from A. niger, indicating the putative processing sites for the signal peptide ( ) and the mono- and dibasic processing site for the propeptide ( ). The position of introns (lA, IB and IC) are indicated ( [) and variation of amino acids number is shown in different parts of protein. The putative N-glycosylation sites are marked ( ).

FIGURE 2.5 Schematic representation of hydrogen-bonded self-associative structures of higher fatty acids (a) cyclic associative dimer and (b) linear associative multimer. 

FIGURE 2.7 Schematic representation of the self-association of dicarboxylic acids as a result... 

Fig. 27. A schematic representation of the seven transmembrane helical peptide chains (A-G) viewed from inside the cell. The numbering denotes the first and last amino acid residues. The proton channel is believed to be the volume between helices C, D, F and G...

Figure4.14 Schematic representation ofthe proposed mechanism ofthe photocatalytic reforming of glucose on Pt-Ti02 involving the formation of various radicals, aldehydes, and carboxylic acids. Adapted from [170] (2008) with permission from Elsevier.

Schematic representation of log /c-pH profiles for various types of acid-base catalysis.

Fig. 11.2. Schematic representation of the primary structure of secreted AChE B of N. brasiliensis in comparison with that of Torpedo californica, for which the three-dimensional structure has been resolved. The residues in the catalytic triad (Ser-His-Glu) are depicted with an asterisk, and the position of cysteine residues and the predicted intramolecular disulphide bonding pattern common to cholinesterases is indicated. An insertion of 17 amino acids relative to the Torpedo sequence, which would predict a novel loop at the molecular surface, is marked with a black box. The 14 aromatic residues lining the active-site gorge of the Torpedo enzyme are illustrated. Identical residues in the nematode enzyme are indicated in plain text, conservative substitutions are boxed, and non-conservative substitutions are circled. The amino acid sequence of AChE C is 90% identical to AChE B, and differs only in the features illustrated in that Thr-70 is substituted by Ser.

Fig. 1.3 Schematic representation of the entrapped enzyme in a silica matrix (left side). Enzymatic activity, under extreme alkaline conditions, of acid phosphatase (A) immobilized in silica sol-gel matrices with or without CTAB, or (B) in solution. Reprinted with permission from [56]. Copyright 2005, American Chemical Society.

Fig. 1.16 Schematic representation of the nanofibrous poly (acrylonitrile-co-acrylic acid) membrane containing MWCNTs, as well as the promoted electron transfer from hydrogen peroxide to the immobilized catalase through the PANCAA/MWCNTs nanofiber. Reprinted from [209] (reproduced by permission ofWiley-VCH).

Figure 2.36(a) Schematic representation of the incommensurate close-packed overlayer of Cu on Au formed in the perchlorate electrolyte The open circles are the gold atoms. Only part of the monolayer is shown in order to exhibit the overlayer-underlayer orientation, (b) Schematic representation of the more open lattice formed in the sulphuric acid electrolyte. From Manne... 

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