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Hydrogen in proteins

Figure 1,3 Hydrogens in proteins. The schematic of peptide (Cly-Asn-Asp-Ser-Cys-Lys-Pro) illustrates the exchangeable backbone amide hydrogens (red/black) and side-chain hydrogens (blue/gray). Carbon-bound hydrogens (white, indicated here only for part of the peptide backbone) virtually do not exchange. Adapted from Ref [17], (See insert for color representation of the figure.)... Figure 1,3 Hydrogens in proteins. The schematic of peptide (Cly-Asn-Asp-Ser-Cys-Lys-Pro) illustrates the exchangeable backbone amide hydrogens (red/black) and side-chain hydrogens (blue/gray). Carbon-bound hydrogens (white, indicated here only for part of the peptide backbone) virtually do not exchange. Adapted from Ref [17], (See insert for color representation of the figure.)...
In addition to testing predictions of tire patlrway model in proteins, experiments have also examined tire prediction tlrat tire decay across a hydrogen bond (from heteroatom to heteroatom) should be about as costly as tire decay across two covalent bonds. Indeed, by syntlresizing a family of hydrogen bonded aird covalently bonded systems witlr equal bond counts (according to this recipe), it was demonstrated tlrat coupling across hydrogen bonded... [Pg.2978]

Brunger, A. T., Karplus, M. Polar hydrogen positions in proteins Empirical energy placement and neutron diffraction comparison. Proteins Struct. Func. Genet. 4 (1988) 148-156. [Pg.194]

Iron Sulfur Compounds. Many molecular compounds (18—20) are known in which iron is tetrahedraHy coordinated by a combination of thiolate and sulfide donors. Of the 10 or more stmcturaHy characterized classes of Fe—S compounds, the four shown in Figure 1 are known to occur in proteins. The mononuclear iron site REPLACE occurs in the one-iron bacterial electron-transfer protein mbredoxin. The [2Fe—2S] (10) and [4Fe—4S] (12) cubane stmctures are found in the 2-, 4-, and 8-iron ferredoxins, which are also electron-transfer proteins. The [3Fe—4S] voided cubane stmcture (11) has been found in some ferredoxins and in the inactive form of aconitase, the enzyme which catalyzes the stereospecific hydration—rehydration of citrate to isocitrate in the Krebs cycle. In addition, enzymes are known that contain either other types of iron sulfur clusters or iron sulfur clusters that include other metals. Examples include nitrogenase, which reduces N2 to NH at a MoFe Sg homocitrate cluster carbon monoxide dehydrogenase, which assembles acetyl-coenzyme A (acetyl-CoA) at a FeNiS site and hydrogenases, which catalyze the reversible reduction of protons to hydrogen gas. [Pg.442]

Fig. 1. The two principal elements of secondary stmcture in proteins, (a) The a-helix stabilized by hydrogen bonds between the backbone of residue i and i + 4. There are 3.6 residues per turn of helix and an axial translation of 150 pm per residue. represents the carbon connected to the amino acid side chain, R. (b) The P sheet showing the hydrogen bonding pattern between neighboring extended -strands. Successive residues along the chain point... Fig. 1. The two principal elements of secondary stmcture in proteins, (a) The a-helix stabilized by hydrogen bonds between the backbone of residue i and i + 4. There are 3.6 residues per turn of helix and an axial translation of 150 pm per residue. represents the carbon connected to the amino acid side chain, R. (b) The P sheet showing the hydrogen bonding pattern between neighboring extended -strands. Successive residues along the chain point...
Simplified models for proteins are being used to predict their stmcture and the folding process. One is the lattice model where proteins are represented as self-avoiding flexible chains on lattices, and the lattice sites are occupied by the different residues (29). When only hydrophobic interactions are considered and the residues are either hydrophobic or hydrophilic, simulations have shown that, as in proteins, the stmctures with optimum energy are compact and few in number. An additional component, hydrogen bonding, has to be invoked to obtain stmctures similar to the secondary stmctures observed in nature (30). [Pg.215]

Molecular dynamics simulations have also been used to interpret phase behavior of DNA as a function of temperature. From a series of simulations on a fully solvated DNA hex-amer duplex at temperatures ranging from 20 to 340 K, a glass transition was observed at 220-230 K in the dynamics of the DNA, as reflected in the RMS positional fluctuations of all the DNA atoms [88]. The effect was correlated with the number of hydrogen bonds between DNA and solvent, which had its maximum at the glass transition. Similar transitions have also been found in proteins. [Pg.448]

Figure 2.2 The a helix is one of the major elements of secondary structure in proteins. Main-chain N and O atoms ate hydrogen-bonded to each other within a helices, (a) Idealized diagram of the path of the main chain in an a helix. Alpha helices are frequently illustrated in this way. There are 3.6 residues per turn in an a helix, which corresponds to 5.4 A (1.5 A pet residue), (b) The same as (a) but with approximate positions for main-chain atoms and hydrogen bonds Included. The arrow denotes the direction from the N-terminus to the C-termlnus. Figure 2.2 The a helix is one of the major elements of secondary structure in proteins. Main-chain N and O atoms ate hydrogen-bonded to each other within a helices, (a) Idealized diagram of the path of the main chain in an a helix. Alpha helices are frequently illustrated in this way. There are 3.6 residues per turn in an a helix, which corresponds to 5.4 A (1.5 A pet residue), (b) The same as (a) but with approximate positions for main-chain atoms and hydrogen bonds Included. The arrow denotes the direction from the N-terminus to the C-termlnus.
Figure 2.5 Schematic illustrations of antiparallel (3 sheets. Beta sheets are the second major element of secondary structure in proteins. The (3 strands are either all antiparallel as in this figure or all parallel or mixed as illustrated in following figures, (a) The extended conformation of a (3 strand. Side chains are shown as purple circles. The orientation of the (3 strand is at right angles to those of (b) and (c). A p strand is schematically illustrated as an arrow, from N to C terminus, (bj Schematic illustration of the hydrogen bond pattern in an antiparallel p sheet. Main-chain NH and O atoms within a p sheet are hydrogen bonded to each other. Figure 2.5 Schematic illustrations of antiparallel (3 sheets. Beta sheets are the second major element of secondary structure in proteins. The (3 strands are either all antiparallel as in this figure or all parallel or mixed as illustrated in following figures, (a) The extended conformation of a (3 strand. Side chains are shown as purple circles. The orientation of the (3 strand is at right angles to those of (b) and (c). A p strand is schematically illustrated as an arrow, from N to C terminus, (bj Schematic illustration of the hydrogen bond pattern in an antiparallel p sheet. Main-chain NH and O atoms within a p sheet are hydrogen bonded to each other.
Figure 10.6 One sequence-specific interaction occurs more frequently than others in protein-DNA complexes two hydrogen bonds form between an arginine side chain of the protein and a guanine base of the DNA, as shown in this diagram. Figure 10.6 One sequence-specific interaction occurs more frequently than others in protein-DNA complexes two hydrogen bonds form between an arginine side chain of the protein and a guanine base of the DNA, as shown in this diagram.
Histidine is one of the 20 naturally occurring amino acids commonly found in proteins (see Chapter 4). It possesses as part of its structure an imidazole group, a five-membered heterocyclic ring possessing two nitrogen atoms. The pAl for dissociation of the imidazole hydrogen of histidine is 6.04. [Pg.51]

FIGURE 5.8 Two structural motifs that arrange the primary structure of proteins into a higher level of organization predominate in proteins the a-helix and the /3-pleated strand. Atomic representations of these secondary structures are shown here, along with the symbols used by structural chemists to represent them the flat, helical ribbon for the a-helix and the flat, wide arrow for /3-structures. Both of these structures owe their stability to the formation of hydrogen bonds between N—H and 0=C functions along the polypeptide backbone (see Chapter 6). [Pg.117]

Several different kinds of noncovalent interactions are of vital importance in protein structure. Hydrogen bonds, hydrophobic interactions, electrostatic bonds, and van der Waals forces are all noncovalent in nature, yet are extremely important influences on protein conformations. The stabilization free energies afforded by each of these interactions may be highly dependent on the local environment within the protein, but certain generalizations can still be made. [Pg.159]

There are several other far less common types of helices found in proteins. The most common of these is the Sjq helix, which contains 3.0 residues per turn (with 10 atoms in the ring formed by making the hydrogen bond three residues up the chain). It normally extends over shorter stretches of sequence than the a-helix. Other helical structures include the 27 ribbon and the 77-helix, which has 4.4 residues and 16 atoms per turn and is thus called the 4.4ig helix. [Pg.168]


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See also in sourсe #XX -- [ Pg.363 , Pg.364 , Pg.365 , Pg.366 , Pg.367 , Pg.368 , Pg.369 , Pg.370 , Pg.374 , Pg.375 , Pg.376 , Pg.377 , Pg.378 , Pg.379 , Pg.476 , Pg.477 , Pg.478 ]




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