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Coiled structure

Figure 3.1 Schematic diagram of the coiled-coil structure. Two a helices are intertwined and gradually coil around each other. Figure 3.1 Schematic diagram of the coiled-coil structure. Two a helices are intertwined and gradually coil around each other.
Figure 3.3 Schematic diagram showing the packing of hydrophobic side chains between the two a helices in a coiled-coil structure. Every seventh residue in both a helices is a leucine, labeled "d." Due to the heptad repeat, the d-residues pack against each other along the coiled-coil. Residues labeled "a" are also usually hydrophobic and participate in forming the hydrophobic core along the coiled-coil. Figure 3.3 Schematic diagram showing the packing of hydrophobic side chains between the two a helices in a coiled-coil structure. Every seventh residue in both a helices is a leucine, labeled "d." Due to the heptad repeat, the d-residues pack against each other along the coiled-coil. Residues labeled "a" are also usually hydrophobic and participate in forming the hydrophobic core along the coiled-coil.
Figure 3.S Schematic diagram of packing side chains In the hydrophobic core of colled-coll structures according to the "knobs In holes" model. The positions of the side chains along the surface of the cylindrical a helix Is pro-jected onto a plane parallel with the heUcal axis for both a helices of the coiled-coil. (a) Projected positions of side chains in helix 1. (b) Projected positions of side chains in helix 2. (c) Superposition of (a) and (b) using the relative orientation of the helices In the coiled-coil structure. The side-chain positions of the first helix, the "knobs," superimpose between the side-chain positions In the second helix, the "holes." The green shading outlines a d-resldue (leucine) from helix 1 surrounded by four side chains from helix 2, and the brown shading outlines an a-resldue (usually hydrophobic) from helix 1 surrounded by four side chains from helix 2. Figure 3.S Schematic diagram of packing side chains In the hydrophobic core of colled-coll structures according to the "knobs In holes" model. The positions of the side chains along the surface of the cylindrical a helix Is pro-jected onto a plane parallel with the heUcal axis for both a helices of the coiled-coil. (a) Projected positions of side chains in helix 1. (b) Projected positions of side chains in helix 2. (c) Superposition of (a) and (b) using the relative orientation of the helices In the coiled-coil structure. The side-chain positions of the first helix, the "knobs," superimpose between the side-chain positions In the second helix, the "holes." The green shading outlines a d-resldue (leucine) from helix 1 surrounded by four side chains from helix 2, and the brown shading outlines an a-resldue (usually hydrophobic) from helix 1 surrounded by four side chains from helix 2.
Figure 3.8 Schematic diagram of the dimeric Rop molecule. Each subunit comprises two a helices arranged in a coiled-coil structure with side chains packed into the hydrophobic core according to the "knobs in holes" model. The two subunits are arranged in such a way that a bundle of four a helices is formed. Figure 3.8 Schematic diagram of the dimeric Rop molecule. Each subunit comprises two a helices arranged in a coiled-coil structure with side chains packed into the hydrophobic core according to the "knobs in holes" model. The two subunits are arranged in such a way that a bundle of four a helices is formed.
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. [Pg.84]

The coiled-coil structure of the leucine zipper motif is not the only way that homodimers and heterodimers of transcription factors are formed. As we saw in Chapter 3 when discussing the RNA-binding protein ROP, the formation of a four-helix bundle structure is also a way to achieve dimerization, and the helix-loop-helix (HLH) family of transcription factors dimerize in this manner. In these proteins, the helix-loop-helix region is preceded by a sequence of basic amino acids that provide the DNA-binding site (Figure 10.23), and... [Pg.196]

Nonrepetitive but well-defined structures of this type form many important features of enzyme active sites. In some cases, a particular arrangement of coil structure providing a specific type of functional site recurs in several functionally related proteins. The peptide loop that binds iron-sulfur clusters in both ferredoxin and high potential iron protein is one example. Another is the central loop portion of the E—F hand structure that binds a calcium ion in several calcium-binding proteins, including calmodulin, carp parvalbumin, troponin C, and the intestinal calcium-binding protein. This loop, shown in Figure 6.26, connects two short a-helices. The calcium ion nestles into the pocket formed by this structure. [Pg.182]

Hydrogels Based on a-Helical Coiled-Coil Structures... [Pg.144]

Figure 13-12. Structureofstarch. A Amylose, showing helical coil structure. B Amylopectin, showing 1 - 6 branch point. Figure 13-12. Structureofstarch. A Amylose, showing helical coil structure. B Amylopectin, showing 1 - 6 branch point.
The availability of the purified transporter in large quantity has enabled investigation of its secondary structure by biophysical techniques. Comparison of the circular dichroism (CD) spectrum of the transporter in lipid vesicles with the CD spectra of water-soluble proteins of known structure indicated the presence of approximately 82% a-helix, 10% ) -turns and 8% other random coil structure [97]. No / -sheet structure was detected either in this study or in a study of the protein by the same group using polarized Fourier transform infrared (FTIR) spectroscopy [98]. In our laboratory FTIR spectroscopy of the transporter has similarly revealed that... [Pg.184]

Our strategy for the spontaneous dimerization of EGF was to incorporate an ot-helical oligopeptide with the ability to participate in forming a coiled-coil structure [99]. We implemented a heterodimerization system in which (KELASVK)5 (K5) and (EKLASVE)5 (E5) peptides could form stable coiled-coil heterodimers. We then synthesized two chimeric proteins that contained EGF attached to either the K5 (EGF-K5-His) or the E5 (EGF-E5-His). Both had the hexahistidine sequence added to the C-terminus for anchoring through coordination with Ni2+ ions fixed to a substrate. [Pg.185]

See other pages where Coiled structure is mentioned: [Pg.453]    [Pg.537]    [Pg.36]    [Pg.36]    [Pg.36]    [Pg.40]    [Pg.45]    [Pg.80]    [Pg.82]    [Pg.279]    [Pg.85]    [Pg.175]    [Pg.181]    [Pg.188]    [Pg.545]    [Pg.246]    [Pg.207]    [Pg.208]    [Pg.209]    [Pg.109]    [Pg.145]    [Pg.19]    [Pg.35]    [Pg.208]    [Pg.210]    [Pg.21]    [Pg.260]    [Pg.96]    [Pg.105]    [Pg.126]    [Pg.191]    [Pg.191]    [Pg.35]    [Pg.123]    [Pg.127]    [Pg.146]   
See also in sourсe #XX -- [ Pg.70 ]



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Coil structure

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