Solution Structure of an Antibody-Bound HIV-1<sup>IIIB</sup>V3 Peptide: A Cis Proline Turn Linking Two β-hairpin Strands

Tugarinov, Vitali; Anglister, Jacob

doi:10.1080/07391102.2000.10506604

Journal of Biomolecular Structure and Dynamics

2000

DOI: 10.1080/07391102.2000.10506604

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Solution Structure of an Antibody-Bound HIV-1^IIIBV3 Peptide: A Cis Proline Turn Linking Two β-hairpin Strands

Vitali Tugarinov

Jacob Anglister

Abstract: The refined solution structure of a peptide representing the full epitope of the HIV-1(IIIB) V3 loop in complex with the anti-gp120 antibody Fv fragment was determined using isotope-filtered and isotope-edited NMR. Both the (15)N-labeled peptide in complex with the unlabeled Fv and the unlabeled peptide complexed with the uniformly (15)N,(13)C-labeled Fv were investigated. The backbone of the bound peptide adopts a well defined β-hairpin conformation with two twisted anti-parallel β-strands linked by a type VI… Show more

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Intrinsic protein geometry with application to non-proline cis peptide planes

Hou

Dai

et al. 2018

J Math Chem

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A protein is traditionally visualised as a piecewise linear discrete curve, and its geometry is conventionally characterised by the extrinsically determined Ramachandran angles. However, a protein backbone has also two independent intrinsic geometric structures, due to the peptide planes and the side chains. Here we adapt and develop modern 3D virtual reality techniques to scrutinize the atomic geometry along a protein backbone, in the vicinity of a peptide plane. For this we compare backbone geometry-based (extrinsic) and structure-based (intrinsic) coordinate systems, and as an example we inspect the trans and cis peptide planes. We reveal systematics in the way how a cis peptide plane deforms the neighbouring atomic geometry, and we develop a virtual reality based visual methodology that can identify the presence of a cis peptide plane from the arrangement of atoms in its vicinity. Our approach can easily detect exceptionally placed atoms in crystallographic structures. Thus it can be employed as a powerful visual refinement tool which is applicable also in the case when resolution of the protein structure is limited and whenever refinement is needed. As concrete examples we identify a number of crystallographic protein structures in Protein Data Bank (PDB) that display exceptional atomic positions around their cis peptide planes.

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Intrinsic protein geometry with application to non-proline cis peptide planes

Hou

Dai

et al. 2018

J Math Chem

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show abstract

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Solution Structure of an Antibody-Bound HIV-1^IIIBV3 Peptide: A Cis Proline Turn Linking Two β-hairpin Strands

Cited by 1 publication

References 49 publications

Intrinsic protein geometry with application to non-proline cis peptide planes

Intrinsic protein geometry with application to non-proline cis peptide planes

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Solution Structure of an Antibody-Bound HIV-1IIIBV3 Peptide: A Cis Proline Turn Linking Two β-hairpin Strands

Cited by 1 publication

References 49 publications

Intrinsic protein geometry with application to non-proline cis peptide planes

Intrinsic protein geometry with application to non-proline cis peptide planes

Contact Info

Product

Resources

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Solution Structure of an Antibody-Bound HIV-1^IIIBV3 Peptide: A Cis Proline Turn Linking Two β-hairpin Strands