Polypeptide sheet

The unit cell in a polypeptide sheet structure (Fig. 10.4) contains four peptide groups (Fig. 10.5), giving four phase possibilities for the transition moments corresponding to the two choices which come from each of the chains. The four frequencies related to these transitions may be written as follows ... 

Section 27 19 Two secondary structures of proteins are particularly prominent The pleated sheet is stabilized by hydrogen bonds between N—H and C=0 groups of adjacent chains The a helix is stabilized by hydrogen bonds within a single polypeptide chain... 

Fig. 5. Protein folding. The unfolded polypeptide chain coUapses and assembles to form simple stmctural motifs such as -sheets and a-hehces by nucleation-condensation mechanisms involving the formation of hydrogen bonds and van der Waal s interactions. Small proteins (eg, chymotrypsin inhibitor 2) attain their final (tertiary) stmcture in this way. Larger proteins and multiple protein assembhes aggregate by recognition and docking of multiple domains (eg, -barrels, a-helix bundles), often displaying positive cooperativity. Many noncovalent interactions, including hydrogen bonding, van der Waal s and electrostatic interactions, and the hydrophobic effect are exploited to create the final, compact protein assembly. Further stmctural...

Fig. 2. Protein secondary stmcture (a) the right-handed a-helix, stabilized by intrasegmental hydrogen-bonding between the backbone CO of residue i and the NH of residue t + 4 along the polypeptide chain. Each turn of the helix requires 3.6 residues. Translation along the hehcal axis is 0.15 nm per residue, or 0.54 nm per turn and (b) the -pleated sheet where the polypeptide is in an extended conformation and backbone hydrogen-bonding occurs between residues on adjacent strands. Here, the backbone CO and NH atoms are in the plane of the page and the amino acid side chains extend from C ...

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 2.14 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... 

The hairpin motif is a simple and frequently used way to connect two antiparallel p strands, since the connected ends of the p strands are close together at the same edge of the p sheet. How are parallel p strands connected If two adjacent strands are consecutive in the amino acid sequence, the two ends that must be joined are at opposite edges of the p sheet. The polypeptide chain must cross the p sheet from one edge to the other and connect the next p strand close to the point where the first p strand started. Such CTossover connections are frequently made by a helices. The polypeptide chain must turn twice using loop regions, and the motif that is formed is thus a p strand followed by a loop, an a helix, another loop, and, finally, the second p strand. 

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. 

Pauling, L., Corey, R.B. Configurations of polypeptide chains wifh favored orienfafions around single bonds two new pleated sheets. Proc. Natl. Acad. Sd. USA 37 729-740, 1951. 

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.)...

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.

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. 

The side of the p sheet that faces away from DNA is covered by two long a helices. One of these helices contains a number of basic residues from the middle segment of the polypeptide chain while the second helix is formed by the C-terminal residues. Residues from these two helices and from the short loop that joins the two motifs (red in Figure 9.4) are likely candidates for interactions with other subunits of the TFIID complex, and with specific transcription factors. 

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.)...

Figure 14.8 Proposed model of p sheet helix of the fibrous form of transthyretin. The repeating unit of the P helix comprises 24 P strands with an average twist of 15° between each strand giving a complete turn of 360°. Four transthyretin polypeptide chains contribute to the repeat unit and are shown here in different colors. (Adapted from C. Blake and L. Serpell, Structure 4 989-998, 1996.)...

Progress in deducing more structural details of these fibers has instead been achieved using NMR, electron microscopy and electron diffraction. These studies reveal that the fibers contain small microcrystals of ordered regions of the polypeptide chains interspersed in a matrix of less ordered or disordered regions of the chains (Eigure 14.9). The microcrystals comprise about 30% of the protein in the fibers, are arranged in p sheets, are 70 to 100 nanometers in size, and contain trace amounts of calcium ions. It is not yet established if the p sheets are planar or twisted as proposed for the amyloid fibril discussed in the previous section. 

Figure 14.9 Spicier fibers are composite materials formed by large silk fibroin polypeptide chains with repetitive sequences that form p sheets. Some regions of the chains participate in forming 100-nm crystals, while other regions are part of a less-ordered mesh-work in which the crystals are embedded. The diagram shows a model of the current concepts of how these fibers are built up, which probably will be modified and extended as new knowledge is gained. (Adapted from F. Vollrath, Sci. Am. p. 54-58, March 1992 and A.H. Simmons, Science 271 84-87, 1996. Photograph courtesy of Science Photo Library.)...

Silk fibers, which have incredible strength, comprise well-ordered microcrystals of P-sheets that make up about 30% of the protein mass, interspersed in a matrix of polypeptide chains without order. The p strands of the sheets are oriented parallel to the fiber axis. 

Figure 16.17 The subunit structure of the bacteriophage MS2 coat protein is different from those of other sphericai viruses. The 129 amino acid polypeptide chain is folded into an up-and-down antiparallei P sheet of five strands, P3-P7, with a hairpin at the amino end and two C-terminai a helices. (Adapted from a diagram provided by L. Liijas.)...

Figure 17.3 The polypeptide chain of lysozyme fiom hacteiiophage T4 folds into two domains. The N-terminal domain is of the a + P type, built up from two a helices (red) and a four-stranded antiparallel P sheet (green). The C-terminal domain comprises seven short a helices (brown and blue) in a rather irregular arrangement. (The last half of this domain is colored blue for clarity.)...

These results indicate that is it possible to change the fold of a protein by changing a restricted set of residues. They also confirm the validity of the rules for stability of helical folds that have been obtained by analysis of experimentally determined protein structures. One obvious impliction of this work is that it might be possible, by just changing a few residues in Janus, to design a mutant that flip-flops between a helical and p sheet structures. Such a polypeptide would be a very interesting model system for prions and other amyloid proteins. 

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