Presentation is loading. Please wait.

Presentation is loading. Please wait.

Prediction of avian Influenza A binding preference to human receptor using conformational analysis of receptor bound to hemagglutinin Wanwimon Mokmak,

Published byCory Barton Modified over 9 years ago

Similar presentations

Presentation on theme: "Prediction of avian Influenza A binding preference to human receptor using conformational analysis of receptor bound to hemagglutinin Wanwimon Mokmak,"— Presentation transcript:

1 Prediction of avian Influenza A binding preference to human receptor using conformational analysis of receptor bound to hemagglutinin Wanwimon Mokmak, M.Sc. Biostatistics and Informatics Laboratory Genome Institute, BIOTEC, Thailand

2 TYR191 SER129 GLN222 TRP149 TYR91 SER133 Ha, Y., et al. Proc.Natl.Acad.Sci.USA 98: 11181-11186 Chain A of H5 HA (A/Duck/Singapore/3/97 HA) Avian influenza H5N1 Hemagglutinin protein Host cell receptor Introduction

3 Hemagglutinin Protein potentially changing the receptor binding preference HA Mutation Φ = 55 degree Cis conformation Φ = -55 degree Tran conformation Introduction Viseshakul N et al.Virology 2004, 328, 169-76 Avian Influenza A virus Mutated KAN-1 Mutated Sing-97 Avian receptor Human receptor

4 To predict the HA binding selectivity from different HA variants in receptor-based conformational analysis by measuring a single torsion angle (Φ) during molecular dynamic simulation Objectives

5 Material & Method X-ray crystal structures 1JSO template for Sing-97 and Kan1 variant 1RVZ template for Puerto 34 variant host cell receptorX-ray structure or 3D- homology models of HA protein HA complex MD simulation Binding preference Observed torsion angle of host cell receptor Known HA variants * : Sing-97 Puerto-34 (human flu virus) Sing-97 variant (Q222L, G224S, Q222L/G224S) Kan-1 Double KAN-1 mutant (L129V/A134V) Prediction for HA mutants Single Kan-1 HA : M226T, K189G, K218S and L109P Puerto-34 HA variants : Q222L, G224L, Q222L/G224S

6 Comparison of observed torsion angle from binding simulation Results & Discussion Puerto-34 Sing-97 Kan-1 tran cis tran cis tran cis Sing-97 bound better to Avian > human Q222L/G224L sing-97 bind preferentially with human type Kan-1 bind better to Avian > human L129V/A134V Kan-1 bind preferentially with human type Puerto-34 bind preferentially with human type Sing-97 Q222L Sing-97 G224S Sing-97 Q222L/G224S Sing-97 Kan-1 L129V/A134V KAN-1 * Harvey R et al. J Virol 2004, 78:502-507. Auewarakul P. et al. J Virol 2007, 81:9950-9955. * Human receptor Avian receptor *

7 Results & Discussion MD predicted receptor type selectivity of HAs compared with data from published experimental assays Order of binding selectivity to human receptor for flu viruses Puerto-34 > L129V/A134V Kan-1 ≅ Q222L/G224S Sing-97 > Sing-97 ≅ Kan-1 Tested HA variantsSimulationin vitro Puerto-34+++ Sing-97+++ Q222L Sing-97++ G224S Sing-97+++ Q222L/G224S Sing-97+++ Kan-1++ L129V/A134V Kan-1+++ +++ most preferred, ++ moderately preferred, + least preferred

8 Simulation results of four Kan-1 HA mutant variants binding to Human receptor Prediction of the Relative Binding Selectivity Results & Discussion Tran Cis

9 Simulation results of four Puerto-34 HA mutants Prediction of the Relative Binding Selectivity Results & Discussion Tran Cis

10 Human receptor associates with positive +Φ angle (Cis conformation) Avian-type receptor associates with negative -Φ angle (Tran conformation) Using Molecular dynamics simulation to observe torsion angles Conclusions

11 Dr. Sissades Tongsima Dr. Chak Sangma Ms.Nipa Jongkon Ms.Daungmanee Chuakheaw Mr. Anunchai Assawamakin Dr. Philip J. Shaw Dr. Jittima Piriyapongsa Acknowledgements National Center for Genetic Engineering and Biotechnology (BIOTEC) Kasetsart University

12 THANK YOU

13 X-ray structure to prepare HA variant for MD simulation: 1JSN & 1JSO template for Sing-97 and Kan1 variants 1RVX & 1RVZ template for Puerto 34 HA variants * : Sing-97 Mutated Singe-97 (Q222L, G224S, Q222L/G224S) KAN-1 mutated KAN-1 (L129V/A134V) Puerto-34 *available binding assay Prediction model: Kan-1 HA variant : M226T, K189G, K218S and L109P Puerto-34 HA variant : Q222L, G224L, Q222L/G224S HA variants and prediction HA variants used for simulation Material & Method Using the SANDER module in the AMBER9 program

14 Six nanosecond RMSD plots of three simulation HA system Results & Discussion

15 Molecular dynamic simulations Glycam04 parameters for receptor AMBER 2003 force field for protein using the TIP5P water model in the truncated octahedron box Using the SANDER module in the AMBER9 program To determine the binding preference Φ angle approximately -55 degreesΦ angle approximately +55 degrees Materials and Methods

16 Results & Discussion Figure 3. Comparison of observed torsion angle (Φ) from the binding simulation between HA variants and avian and human type receptor analog. Φ Was monitored and interpreted in term of the binding preference Siaα(2,3)GalSiaα(2,6)Gal Puerto-34 Results & Discussion

17 Siaα(2,3)GalSiaα(2,6)Gal Comparison of observed torsion angle (Φ) from the binding simulation between HA variants and avian and human type receptor analog. Sing-97 Results & Discussion

18 Figure 3. Comparison of observed torsion angle (Φ) from the binding simulation between HA variants and avian and human type receptor analog. Siaα(2,3)GalSiaα(2,6)Gal Kan-1 Results & Discussion

19 PDB code HA TypeLigand TypeSugar Units Torsion (Φ) Resolution (Å) 1JSIA/Swine/Hong Kong/9/98:H9 Siaα(2,6)Ga l Sia-Gal- GlcNAc- Gal-Glc 56.22.4 1JSOA/Duck/Singapore/3/97:H 5 Siaα(2,6)Ga l Sia-2.4 1RVTA/Swine/Iowa/15/30:H1Siaα(2,6)Ga l Sia-Gal- GlcNAc- Gal-Glc 69.72.4 1RVZA/Puerto Rico/8/34:H1Siaα(2,6)Ga l Sia-Gal- GlcNAc 67.62.25 1JSNA/Duck/Singapore/3/97:H 5 Siaα(2,3)Ga l Sia-Gal- GlcNAc -55.12.4 1RVXA/Puerto Rico/8/34:H1Siaα(2,3)Ga l Sia-Gal- GlcNAc -59.12.2 Torsion angles of selected glycosides from PDB Results & Discussion

Download ppt "Prediction of avian Influenza A binding preference to human receptor using conformational analysis of receptor bound to hemagglutinin Wanwimon Mokmak,"

Similar presentations

F INDINGS National Institutes of Health National Institute of General Medical Sciences Viral Voyages Structural Biologist Mavis Agbandje-McKenna: Understanding.

F INDINGS National Institutes of Health National Institute of General Medical Sciences Viral Voyages Structural Biologist Mavis Agbandje-McKenna: Understanding.
An Integrated Approach to Protein-Protein Docking

An Integrated Approach to Protein-Protein Docking
Influenza A Virus Pandemic Prediction and Simulation Through the Modeling of Reassortment Matthew Ingham Integrated Sciences Program University of British.

Influenza A Virus Pandemic Prediction and Simulation Through the Modeling of Reassortment Matthew Ingham Integrated Sciences Program University of British.
Molecular Mechanics, Molecular Dynamics, and Docking Michael Strong, PhD National Jewish Health 11/23/2010.

Molecular Mechanics, Molecular Dynamics, and Docking Michael Strong, PhD National Jewish Health 11/23/2010.
Laboratory Training for Field Epidemiologists Typing May 2007 Sequencing and Phylogeny.

Laboratory Training for Field Epidemiologists Typing May 2007 Sequencing and Phylogeny.
Molecular Mechanics, Molecular Dynamics, and Docking

Molecular Mechanics, Molecular Dynamics, and Docking
RExPrimer Pongsakorn Wangkumhang, M.Sc. Biostatistics and Informatics Laboratory, Genome Institute, National Center for Genetic Engineering and Biotechnology.

RExPrimer Pongsakorn Wangkumhang, M.Sc. Biostatistics and Informatics Laboratory, Genome Institute, National Center for Genetic Engineering and Biotechnology.
Empirical energy function Summarizing some points about typical MM force field In principle, for a given new molecule, all force field parameters need.

Empirical energy function Summarizing some points about typical MM force field In principle, for a given new molecule, all force field parameters need.
Molecular dynamics simulations reveal structural instability of human trypsin inhibitor upon D50E and Y54H mutations Surasak Chunsrivirot Biostatistics.

Molecular dynamics simulations reveal structural instability of human trypsin inhibitor upon D50E and Y54H mutations Surasak Chunsrivirot Biostatistics.
COMPARATIVE or HOMOLOGY MODELING

COMPARATIVE or HOMOLOGY MODELING
Interaction of Neurotropic Enterovirus-71 with Receptor PSGL-1 Matthew Makowski ¹, Josh Yoder ², Javier Cifuente ², Bob Ashley ², Jennifer Yoder ², Hyunwook.

Interaction of Neurotropic Enterovirus-71 with Receptor PSGL-1 Matthew Makowski ¹, Josh Yoder ², Javier Cifuente ², Bob Ashley ², Jennifer Yoder ², Hyunwook.
4th Year MPharm SRP: Introduction to Pseudotype Viruses

4th Year MPharm SRP: Introduction to Pseudotype Viruses
HOW DO VIRUSES CROSS THE SPECIES BARRIER? Rachel Rezabek.

HOW DO VIRUSES CROSS THE SPECIES BARRIER? Rachel Rezabek.
VarDetect: a nucleotide sequence variation exploratory tool VarDetect Chumpol Ngamphiw 1, Supasak Kulawonganunchai 2, Anunchai Assawamakin 3, Ekachai Jenwitheesuk.

VarDetect: a nucleotide sequence variation exploratory tool VarDetect Chumpol Ngamphiw 1, Supasak Kulawonganunchai 2, Anunchai Assawamakin 3, Ekachai Jenwitheesuk.
HOW DO VIRUSES CROSS THE SPECIES BARRIER? Rachel Rezabek.

HOW DO VIRUSES CROSS THE SPECIES BARRIER? Rachel Rezabek.
A DAPTING PUBLISHED RESEARCH DATA TO A BIOINFORMATICS MODULE IN A UNDERGRADUATE BIOLOGY MAJOR ’ S COURSE N ATURE. 2011 M AY 26;473(7348):519-22 L ONG -

A DAPTING PUBLISHED RESEARCH DATA TO A BIOINFORMATICS MODULE IN A UNDERGRADUATE BIOLOGY MAJOR ’ S COURSE N ATURE M AY 26;473(7348): L ONG -
Computer Simulation of Biomolecules and the Interpretation of NMR Measurements generates ensemble of molecular configurations all atomic quantities Problems.

Computer Simulation of Biomolecules and the Interpretation of NMR Measurements generates ensemble of molecular configurations all atomic quantities Problems.
Folding of Distinct Sequences into Similar Functional Topologies Hossein Mohammadiarani and Harish Vashisth (Advisor) Department of Chemical Engineering,

Folding of Distinct Sequences into Similar Functional Topologies Hossein Mohammadiarani and Harish Vashisth (Advisor) Department of Chemical Engineering,
Molecular Dynamics of the Avian Influenza Virus Team Members: Ashvin Srivatsa, Michael Fu, Ellen Chuang, Ravi Sheth Team Leader: Yuan Zhang.

Molecular Dynamics of the Avian Influenza Virus Team Members: Ashvin Srivatsa, Michael Fu, Ellen Chuang, Ravi Sheth Team Leader: Yuan Zhang.
Altman et al. JACS 2008, 130 6099-6113 Presented By Swati Jain.

Altman et al. JACS 2008, Presented By Swati Jain.

Similar presentations

Ads by Google