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P sheet folds

The answer to successful p-sheet folding lies in knowing how residues on the hydrophobic surface of one amphipathic dimer pack with the hydrophobic surface of another. Optimal side-chain packing relates to fold stability and compactness. Currently, restrained molecular dynamcis and simulated annealing are being used to model the folding of the p-sheet sandwich tetramer to help answer this question. [Pg.806]

Sheet packings. Parallel P sheets usually have both faces covered by a helices. Antiparallel P sheets are usually folded against one another, p Strands are packed in different ways, which allow P sheets to twist, coil and bend (e.g. chymotrypsin, immuno-globin). Three distinct classes of P sheet folds are observed ... [Pg.123]

Orthogonal P packing in which P sheets folds upon themselves to form layer stractures with an inclination of -90° between the two layers. [Pg.123]

Deechongkit, S., Naguen, H., and Powers, E. T. et al. 2004. Context-dependent contributions of backbone hydrogen bonding to P-sheet folding energetics. Nature 430 101-105. [Pg.48]

Figure 2.14 shows examples of both cases, an isolated ribbon and a p sheet. The isolated ribbon is illustrated by the structure of bovine trypsin inhibitor (Figure 2.14a), a small, very stable polypeptide of 58 amino acids that inhibits the activity of the digestive protease trypsin. The structure has been determined to 1.0 A resolution in the laboratory of Robert Huber in Munich, Germany, and the folding pathway of this protein is discussed in Chapter 6. Hairpin motifs as parts of a p sheet are exemplified by the structure of a snake venom, erabutoxin (Figure 2.14b), which binds to and inhibits... [Pg.26]

Polypeptide chains are folded into one or several discrete units, domains, which are the fundamental functional and three-dimensional structural units. The cores of domains are built up from combinations of small motifs of secondary structure, such as a-loop-a, P-loop-p, or p-a-p motifs. Domains are classified into three main structural groups a structures, where the core is built up exclusively from a helices p structures, which comprise antiparallel p sheets and a/p structures, where combinations of p-a-P motifs form a predominantly parallel p sheet surrounded by a helices. [Pg.32]

The most frequent of the domain structures are the alpha/beta (a/P) domains, which consist of a central parallel or mixed P sheet surrounded by a helices. All the glycolytic enzymes are a/p structures as are many other enzymes as well as proteins that bind and transport metabolites. In a/p domains, binding crevices are formed by loop regions. These regions do not contribute to the structural stability of the fold but participate in binding and catalytic action. [Pg.47]

Figure 4.2 A p-a-p motif is a right-handed structure. Two such motifs can be joined into a four-stranded parallel p sheet in two different ways. They can be aligned with the a helices either on the same side of the p sheet (a) or on opposite sides (b). In case (a) the last p strand of motif I (red) is adjacent to the first p strand of motif 2 (blue), giving the strand order 1 2 3 4. The motifs are aligned in this way in barrel structures (see Figure 4.1a) and in the horseshoe fold (see Figure 4.11). In case (b) the first p strands of both motifs are adjacent, giving the strand order 4 3 12. Open twisted sheets (see Figure 4.1b) contain at least one motif alignment of this kind. In both cases the motifs ate joined by an ct helix (green). Figure 4.2 A p-a-p motif is a right-handed structure. Two such motifs can be joined into a four-stranded parallel p sheet in two different ways. They can be aligned with the a helices either on the same side of the p sheet (a) or on opposite sides (b). In case (a) the last p strand of motif I (red) is adjacent to the first p strand of motif 2 (blue), giving the strand order 1 2 3 4. The motifs are aligned in this way in barrel structures (see Figure 4.1a) and in the horseshoe fold (see Figure 4.11). In case (b) the first p strands of both motifs are adjacent, giving the strand order 4 3 12. Open twisted sheets (see Figure 4.1b) contain at least one motif alignment of this kind. In both cases the motifs ate joined by an ct helix (green).
Figure S.6 Schematic and topological diagrams of the folding motif in neuraminidase from influenza virus The motif is built up from four antiparallel P strands joined by hairpin loops, an up-and-down open P sheet. Figure S.6 Schematic and topological diagrams of the folding motif in neuraminidase from influenza virus The motif is built up from four antiparallel P strands joined by hairpin loops, an up-and-down open P sheet.
In addition to the antiparallel p-structures, there is a novel fold called the P helix. In the p-helix structures the polypeptide chain is folded into a wide helix with two or three p strands for each turn. The p strands align to form either two or three parallel p sheets with a core between the sheets completely filled with side chains. [Pg.86]

Figure 6.6 Schematic diagram of the structure of the enzyme lysozyme which folds into two domains. One domain is essentially a-helical whereas the second domain comprises a three stranded antiparallel p sheet and two a helices. There are three disulfide bonds (green), two in the a-helical domain and one in the second domain. Figure 6.6 Schematic diagram of the structure of the enzyme lysozyme which folds into two domains. One domain is essentially a-helical whereas the second domain comprises a three stranded antiparallel p sheet and two a helices. There are three disulfide bonds (green), two in the a-helical domain and one in the second domain.
The setpin fold comprises a compact body of three antiparallel p sheets, A, B and C, which ate partly coveted by a helices (Figure 6.22). In the structure of the uncleaved form of ovalbumin, which can be regarded as the canonical structure of the serpins, sheet A has five strands. The flexible loop starts at the end of strand number 5 of p sheet A (plS in Figure 6.22), then... [Pg.111]

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 6,22 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,...
The C-terminal domain of phosducin is a five-stranded mixed p sheet with a helices on both sides, similar to the thioredoxin fold of disulfide iso-merase DsbA described in Chapter 6. Despite significant sequence homology to thioredoxin, the phosducin domain, unlike other members of this family. [Pg.265]

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See also in sourсe #XX -- [ Pg.123 ]



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