P structure parallel

Insects and arachnoids produce well-known amyloids. Silk and spider webs, like P-keratin, also differ from amyloids in being fibrous P-sheet proteins composed of peptide strands that are parallel, rather than perpendicular, to the direction of the fibril axis. For the process of silk formation by spiders, it has been proposed that fibrils in the silk gland have an initial cross-P structure (Kenney et al. 2002 Table 3) that, when stretched, assume parallel P-structures. However, X-ray diffraction for a peptide derived from the central domain of the A class of chorion proteins, derived frovaAntheraea polyphemus eggshells, displayed P-sheets perpendicular to the fibril axis, the same cross-P structure that occurs in amyloid proteins (Iconomidou et al. 2000 Table 3). The stability and strength of the amyloid fibres provides mechanical and biological protection for the oocyte and developing embryo from a variety of environmental and predatory hazards. 

Parallel p structures are typically buried on both sides, so that they appear hydrophobic near the center of a strand and hydrophilic near each end of the strand. 

This motif is called a beta-alpha-beta motif (Figure 2.17) and is found as part of almost every protein structure that has a parallel p sheet. For example, the molecule shown in Figure 2.10b, triosephosphate isomerase, is entirely built up by repeated combinations of this motif, where two successive motifs share one p strand. Alternatively, it can be regarded as being built up from four consecutive p-a-p-a motifs. 

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 2.21 Two sequentially adjacent hairpin motifs can be arranged in 24 different ways into a p sheet of four strands, (a) Topology diagrams for those arrangements that were found in a survey of all known structures in 1991. The Greek key motifs in (1) and (v) occurred 74 times, whereas the arrangement shown in (viii) occurred only once, (b) Topology diagrams for those 16 arrangements that did not occur in any structure known at that time. Most of these arrangements contain a pair of adjacent parallel P strands.

The p-a-P motif, which consists of two parallel p strands joined by an a helix, occurs in almost all structures that have a parallel p sheet. Four antiparallel p strands that are arranged in a specific way comprise the Greek key motif, which is frequently found in structures with antiparallel p sheets. 

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. 

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. 

The packing interactions between a helices and p strands are dominated by the residues Val (V), He (I), and Leu (L), which have branched hydrophobic side chains. This is reflected in the amino acid composition these three amino acids comprise approximately 40% of the residues of the P strands in parallel P sheets. The important role that these residues play in packing a helices against P sheets is particularly obvious in a/P-barrel structures, as shown in Table 4.1. 

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).

Table 4.1 The amino acid residues of the eight parallel p strands in the barrel structure of the enzyme triosephosphate isomerase from chicken muscle...

Each repeat forms a right-handed P-loop-a structure similar to those found in the two other classes of a/p structures described earlier. Sequential p-loop-a repeats are joined together in a similar way to those in the a/P-bar-rel stmctures. The P strands form a parallel p sheet, and all the a helices are on one side of the P sheet. However, the P strands do not form a closed barrel instead they form a curved open stmcture that resembles a horseshoe with a helices on the outside and a p sheet forming the inside wall of the horseshoe (Figure 4.11). One side of the P sheet faces the a helices and participates in a hydrophobic core between the a helices and the P sheet the other side of the P sheet is exposed to solvent, a characteristic other a/p structures do not have. 

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 4.19 Schematic and topological diagrams for the structure of the enzyme carboxypeptidase. The central region of the mixed p sheet contains four adjacent parallel p strands (numbers 8, 5, 3, and 4), where the strand order is reversed between strands 5 and 3. The active-site zinc atom (yellow circle) is bound to side chains in the loop regions outside the carboxy ends of these two p strands. The first part of the polypeptide chain is red, followed by green, blue, and brown. (Adapted from J. Richardson.)...

In this structure the loop regions adjacent to the switch point do not provide a binding crevice for the substrate but instead accommodate the active-site zinc atom. The essential point here is that this zinc atom and the active site are in the predicted position outside the switch point for the four central parallel p strands, even though these p strands are only a small part of the total structure. This sort of arrangement, in which an active site formed from parallel p strands is flanked by antiparallel p strands, has been found in a number of other a/p proteins with mixed p sheets. 

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.)...

Upha/beta (a/p) structures are the most frequent and most regular of the pro-kein structures. They fall into three classes the first class comprises a central core of usually eight parallel p strands arranged close together like the staves pf a barrel, surrounded by a helices the second class comprises an open twisted parallel or mixed p sheet with a helices on both sides of the p sheet and Ihe third class is formed by leucine-rich motifs in which a large number of parallel p strands form a curved p sheet with all the a helices on the outside bfthis sheet. 

The a/p-barrel structure is one of the largest and most regular of all domain structures, comprising about 250 amino acids. It has so far been found in more than 20 different proteins, with completely different amino acid sequences and different functions. They are all enzymes that are modeled on this common scaffold of eight parallel p strands surrounded by eight a helices. They all have their active sites in very similar positions, at the bottom of a funnel-shaped pocket created by the loops that connect the carboxy end of the p strands with the amino end of the a helices. The specific enzymatic activity is, in each case, determined by the lengths and amino acid sequences of these loop regions which do not contribute to the stability of the fold. 

Easters, I., et al. Structural principles of parallel p barrels in proteins. Proc. Natl. Acad. Sci. USA 85 3338-3342, 1988. 

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.)...

In these p-helix structures the polypeptide chain is coiled into a wide helix, formed by p strands separated by loop regions. In the simplest form, the two-sheet p helix, each turn of the helix comprises two p strands and two loop regions (Figure 5.28). This structural unit is repeated three times in extracellular bacterial proteinases to form a right-handed coiled structure which comprises two adjacent three-stranded parallel p sheets with a hydrophobic core in between. 

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. 

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

Jurnak, E, et al. Parallel p domains a new fold in protein structures. Curr. Opin. Struct. Biol. 4 802-806, 1994. 

Figure 11.13 Schematic diagram of the three-dimensional structure of subtilisin viewed down the central parallel p sheet. The N-terminal region that contains the a/p stmcture is blue.

Figure 13.4 Schematic diagram (a) and topology diagram (b) of the polypeptide chain of cH-ras p21. The central p sheet of this a/p structure comprises six p strands, five of which are parallel a helices are green, p strands are blue, and the adenine, ribose, and phosphate parts of the GTP analog are blue, green, and ted, respectively. The loop regions that are involved in the activity of this protein are red and labeled Gl-GS. The Gl, G3, and G4 loops have the consensus sequences G-X-X-X-X-G-K-S/T, D-X-X-E, and N-K-X-D, respectively. (Adapted from E.R Pai et al., Nature 341 209-214, 1989.)...

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