Changes in the Structure of Potato Virus A Virions after Limited in situ Proteolysis According to Tritium Labeling Data and Computer Simulation

Changes in the Structure of Potato Virus A Virions after Limited in situ Proteolysis According to Tritium Labeling Data and Computer Simulation

Coat proteins (CP) of the potato virus A virions (PVA) contain partially disordered N-terminal domains, which are necessary for performing vital functions of the virus. Comparative analysis of the structures of coat proteins (CPs) in the intact PVA virions and in the virus particles lacking N-termin...

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Veröffentlicht in:Biochemistry (Moscow) 2023-12, Vol.88 (12-13), p.2146-2156
Hauptverfasser: Ksenofontov, Alexander L., Baratova, Ludmila A., Semenyuk, Pavel I., Fedorova, Natalia V., Badun, Gennadii A.
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Amino acids
Analysis
Atomic structure
Biochemistry
Biomedical and Life Sciences
Biomedicine
Bioorganic Chemistry
Comparative analysis
Computer simulation
Computer viruses
Computer-generated environments
Diseases and pests
Identification and classification
Labels
Life Sciences
Microbiology
Peptides
Plant viruses
Potatoes
Proteins
Proteolysis
Structure
Tritium
Trypsin
Virions
Virus diseases of plants
Viruses
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container_issue 12-13
container_start_page 2146
container_title Biochemistry (Moscow)
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creator Ksenofontov, Alexander L.
Baratova, Ludmila A.
Semenyuk, Pavel I.
Fedorova, Natalia V.
Badun, Gennadii A.
description Coat proteins (CP) of the potato virus A virions (PVA) contain partially disordered N-terminal domains, which are necessary for performing vital functions of the virus. Comparative analysis of the structures of coat proteins (CPs) in the intact PVA virions and in the virus particles lacking N-terminal 32 amino acids (PVAΔ32) was carried out in this work based on the tritium planigraphy data. Using atomic-resolution structure of the potato virus Y potyvirus (PVY) protein, which is a homolog of the CP PVA, the available CP surfaces in the PVY virion were calculated and the areas of intersubunit/interhelix contacts were determined. For this purpose, the approach of Lee and Richards [Lee, B., and Richards, F. M. (1971) J. Mol. Biol. , 55 , 379-400] was used. Comparison of incorporation profiles of the tritium label in the intact and trypsin-degraded PVA∆32 revealed position of the ΔN-peptide shielding the surface domain (a.a. 66-73, 141-146) and the interhelix zone (a.a. 161-175) of the PVA CP. Presence of the channels/cavities was found in the virion, which turned out to be partially permeable to tritium atoms. Upon removal of the ∆N-peptide, decrease in the label incorporation within the virion (a.a. 184-200) was also observed, indicating possible structural transition leading to the virion compactization. Based on the obtained data, we can conclude that part of the surface ∆N-peptide is inserted between the coils of the virion helix thus increasing the helix pitch and providing greater flexibility of the virion, which is important for intercellular transport of the viruses in the plants.
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subjects Amino acids
Analysis
Atomic structure
Biochemistry
Biomedical and Life Sciences
Biomedicine
Bioorganic Chemistry
Comparative analysis
Computer simulation
Computer viruses
Computer-generated environments
Diseases and pests
Identification and classification
Labels
Life Sciences
Microbiology
Peptides
Plant viruses
Potatoes
Proteins
Proteolysis
Structure
Tritium
Trypsin
Virions
Virus diseases of plants
Viruses
title Changes in the Structure of Potato Virus A Virions after Limited in situ Proteolysis According to Tritium Labeling Data and Computer Simulation
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