Haruhiko Tamaoki scite author profile

Neurotoxic peptides from venoms of scorpions and honey bees exhibit a consensus pattern in the two disulfide bridgings related to the sequence portions Cys-X-Cys and Cys-X-X-X-Cys. A revised three-dimensional structure of charybdotoxin, as determined by two-dimensional nmr spectroscopy, confirms that the consensus cystine dislocation generates in all these toxins a common structural element, i.e., the cystine-stabilized alpha-helical (CSH) motif, which may be correlated with their common ion channel blocking activity.

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Folding motifs induced and stabilized by distinct cystine frameworks

Tamaoki¹,

Miura²,

Kusunoki

et al. 1998

Protein Engineering Design and Selection

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Bioactive peptides of different sources and biological functionalities, like endothelins, sarafotoxins, bee and scorpion venom toxins, contain a consensus cystine framework, Cys-(X)1-Cys/Cys-(X)3-Cys, which has been found to induce and stabilize a homologous folding motif named the cystine-stabilized alpha-helix (CSH). This is composed of an alpha-helical segment spanning the Cys-(X)3-Cys sequence portion that is crosslinked by two disulfide bridges to the sequence portion Cys-(X)1-Cys, itself folded in an extended beta-strand type structure. Search for sequence homologies of peptides and proteins in the SWISS-PROT and PDB data banks provided additional multiple examples of this type of cystine framework in serine proteinase inhibitors, in insect and plant defense proteins, as well as in members of the growth factor family with the cystine-knot. A comparative analysis of the known 3D-structures of these peptides and proteins confirmed that the presence of this peculiar cystine framework leads in all cases to a high degree of local structural homology that consists of the CSH motif, except for the cystine-knot, of the superfamily of the growth factors. In this case the cyclic structure formed by the parallel cysteine connectivities of Cys-(X)1-Cys/Cys-(X)3-Cys framework is penetrated by a third disulfide bond with formation of a concatenated knot, and the two disulfide-bridged peptide chains Cys-(X)1-Cys and Cys-(X)3-Cys are located in beta-strands. Conversely, peptides and proteins containing Cys-(X)m-Cys/Cys-(X)n-Cys cystine frameworks that differ from m/n = 1/3 were found to fold only sporadically into local alpha-helical structures.

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Solution conformation of endothelin determined by means of ¹H-NMR spectroscopy and distance geometry calculations

Tamaoki

Kobayashi

Nishimura

et al. 1991

Protein Eng Des Sel

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The structure of endothelin-1 (ET-1), an endothelial cell-derived peptide with vasoconstricting activity, was determined in an aqueous solution by means of a combination of NMR and distance geometry calculations. The resulting structure is characterized by an alpha-helical conformation in the sequence region, Lys9-Cys15. Furthermore, an extended structure and a turn structure exist in the Cys1-Ser4 and Ser5-Asp8 regions respectively, and no preferred conformation was found for the C-terminal part of the peptide which was not uniquely constrained by the NMR data. These structural elements, the alpha-helical structure in the sequence portion, Cys-X-X-X-Cys, and the extended structure in Cys-X-Cys, are homologous to those found commonly in several neurotoxic peptides.

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Three-Dimensional Structure of the Flavoenzyme Acyl-CoA Oxidase-II from Rat Liver, the Peroxisomal Counterpart of Mitochondrial Acyl-CoA Dehydrogenase

Nakajima

Miyahara

Hirotsu

et al. 2002

Journal of Biochemistry

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Acyl-CoA oxidase (ACO) catalyzes the first and rate-determining step of the peroxisomal beta-oxidation of fatty acids. The crystal structure of ACO-II, which is one of two forms of rat liver ACO (ACO-I and ACO-II), has been solved and refined to an R-factor of 20.6% at 2.2-A resolution. The enzyme is a homodimer, and the polypeptide chain of the subunit is folded into the N-terminal alpha-domain, beta-domain, and C-terminal alpha-domain. The X-ray analysis showed that the overall folding of ACO-II less C-terminal 221 residues is similar to that of medium-chain acyl-CoA dehydrogenase (MCAD). However, the N-terminal alpha- and beta-domains rotate by 13 with respect to the C-terminal alpha-domain compared with those in MCAD to give a long and large crevice that accommodates the cofactor FAD and the substrate acyl-CoA. FAD is bound to the crevice between the beta- and C-terminal domains with its adenosine diphosphate portion interacting extensively with the other subunit of the molecule. The flavin ring of FAD resides at the active site with its si-face attached to the beta-domain, and is surrounded by active-site residues in a mode similar to that found in MCAD. However, the residues have weak interactions with the flavin ring due to the loss of some of the important hydrogen bonds with the flavin ring found in MCAD. The catalytic residue Glu421 in the C-terminal alpha-domain seems to be too far away from the flavin ring to abstract the alpha-proton of the substrate acyl-CoA, suggesting that the C-terminal domain moves to close the active site upon substrate binding. The pyrimidine moiety of flavin is exposed to the solvent and can readily be attacked by molecular oxygen, while that in MCAD is protected from the solvent. The crevice for binding the fatty acyl chain is 28 A long and 6 A wide, large enough to accommodate the C23 acyl chain.

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