Presentation is loading. Please wait.

Presentation is loading. Please wait.

_________________________________________________________________________.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "_________________________________________________________________________."— Presentation transcript:

1 _________________________________________________________________________

2 Introduction – infection cycle

3 _________________________________________________________________________ Cell entry of enveloped viruses Steven AC and Spear PG. Science VOL 313, 2006 Binding of viral glycoprotein with cell surface receptor lead to the fusion of viral envelope with the plasma membrane Binding of viral glycoprotein with cell surface receptor triggers receptor mediated endocytosis (receptor/clathrin/caveolae)

4 _________________________________________________________________________ Cell entry of enveloped viruses Nature Reviews Microbiology 6, 143-155 (February 2008) low-pH mediated fusion receptor-triggered fusion

5 _________________________________________________________________________ Viral glycoprotein structure Viral surface glycoproteins essential for virus-cell membrane fusion (e.g. HIV (gp41/gp120) & Influenza HA1/HA2) structure of glycoprotein: - external domain (host interaction) - endodomain (internal part) - transmembrane domain (spans the viral envelope membrane; typically  -helix) Nature Reviews Microbiology 6, 143-155 (February 2008)

6 _________________________________________________________________________ Classes of virus fusion proteins Class I Class II Class III glycoprotein B of herpes simplex virus (HSV) gBgB glycoprotein G of vesicular stomatitis virus (VSV)

7 _________________________________________________________________________ Classes of virus fusion proteins priming step of fusion proteins during budding process: - proteolysis of precusrsor (e.g. HA0) or co-regulatory protein (e.g. p62) Trigger mechanisms (low pH or co-receptor binding) induce conformational change of fusion protein to a extended intermediate due to altered energy profile

8 _________________________________________________________________________ Main mechanism of membrane fusion Nature Reviews Microbiology 6, 143-155 (February 2008); Nat Struct Mol Biol. 2008 July, 15(7): 690–698.

9 _________________________________________________________________________ Class I membrane-fusion proteins (Influenza) cell virus Nat Struct Mol Biol. 2008 July, 15(7): 690–698 Metastable HA2 protein trimer with transmembrane domain, α-helical coiled coil stalk and buried fusion peptide conformational change and HA1 dissociation upon specific trigger mechanism (HIV -> CD4 receptor; Influenza -> sialic acid & low pH) Loop-to-helix transition, translocation of fusion peptide towards cell membrane and anchoring -> pre-hairpin intermediate (high energy) followed by hemifusion Folding-back bridge collapsing to stable α-helical coiled coil hairpin-trimer and fusion peptide capping of transmembrane domain -> irreversible hairpin fusion pore

10 _________________________________________________________________________ Class II membrane-fusion proteins (flavivirus and alphavirus) Nat Struct Mol Biol. 2008 July, 15(7): 690–698 folding with regulatory companion protein: flavivirus (p62); alphavirus (prM) β-sheet (red), fusion loop domain (yellow) and Ig-like (blue) domain connected with TM in metastable form: flavivirus (E) 2 homodimer; alphavirus (E1-E2) 3 heterodimer fusion peptides

11 _________________________________________________________________________ Class II membrane-fusion proteins (flavivirus) Nat Struct Mol Biol. 2008 July, 15(7): 690–698 Metastable E protein homodimer (alphavirus: heterodimer) linked to transmembrane domain, buried fusion peptide (black circle) Dimer dissociation upon specific trigger mechanism (H + binding at low pH) and trimerization to homotrimers upon fusion peptide contact to target membrane Extended intermediate and fusion peptide anchoring upon interaction of domains I and II -> pre-hairpin intermediate (high energy) followed by hemifusion Flipping-over (arrows) of domain III lead to back-zipping of stem, bringing fusion loop and transmembrane domain together -> irreversible hairpin fusion pore cell virus

12 _________________________________________________________________________ Class II membrane-fusion proteins (alphavirus)

13 _________________________________________________________________________ Class III membrane-fusion proteins (VSV) Nat Struct Mol Biol. 2008 July, 15(7): 690–698 G-protein fusion trimer with core domain (red) and fusion peptide (black circle) held away from target membrane Flipping over of fusion domain (arrow) upon specific trigger mechanism (pH) and fusion peptide contact to target membrane -> extended intermediate Post fusion conformation of the subunit (d) and the trimer (e) after back-folding and up-zipping of transmembrane domain bringing the membranes together cell virus

14 _________________________________________________________________________ Important factors that contribute to virus membrane fusion cholesterol and sphingolipid content of target cell membranes cooperative interaction of fusion peptides to cluster rings of five or six protein homotrimers -> enhancement of initial fusion pore formation (´dome like´) requirement of trimers for membran fusion: - Influnenza -> 8-9 - HIV -> 1 !!

15 _________________________________________________________________________ Summary I Dev Cell. 2008 Jan;14(1):11-21. Review.

16 _________________________________________________________________________ Summary II Modified from Nat Rev Microbiol. 2006 Jan;4(1):67-76. Review. Class III (VSV G) reversible trimer formation upon pH change α-helix + β-sheet No proteolytic process No companion Internal loop at fusion protein Trimer of hairpins

17 _________________________________________________________________________ Thank you for your attention

18 _________________________________________________________________________ Classes of virus fusion proteins Class I Found in othomyxoviruses, paramyxoviruses, retrovoruses, filoviruses and coronaviruses. Form trimers with triple coiled-coil stem which in the postfusion state gives a distinctive six-helix bundle. The active fusogenic form is obtained through a proteolytic cleavage which reveals the hydrophobic fusion peptide. Class II Found in flaviviruses and alphaviruses Initially are present in form of dimers but at low pH the dimers dissociate exposing the fusion loops. The fusion loops insert into host membrane which triggers trimerization of the glycoproteins. Class III Glycoprotein B of Herpes Simplex Virus (HSV) gBgB Glycoprotein G of Vesicular Stomatitis Virus (VSV)

19 _________________________________________________________________________

Download ppt "_________________________________________________________________________."

Similar presentations

The Art of Reconstruction.  In order to survive, viruses must be able to do the following: ◦ 1. Find a host cell it can replicate in ◦ 2. Bind to that.

The Art of Reconstruction.  In order to survive, viruses must be able to do the following: ◦ 1. Find a host cell it can replicate in ◦ 2. Bind to that.
Www.crp-sante.lu FLUTCORE project meeting: WP3- Immunogenicity studies I-Na Lu PhD, CRP-Santé Group Leader: Prof. Dr. Claude Muller Institute of Immunology.

FLUTCORE project meeting: WP3- Immunogenicity studies I-Na Lu PhD, CRP-Santé Group Leader: Prof. Dr. Claude Muller Institute of Immunology.
THE REPLICATION OF VIRUSES Virology Lecture 2 Three lectures dealing with (1) replication of DNA viruses (2) the culture, growth and recognition of virus.

THE REPLICATION OF VIRUSES Virology Lecture 2 Three lectures dealing with (1) replication of DNA viruses (2) the culture, growth and recognition of virus.
Lecture 18: Intracellular transport Flint et al., Chapter 12.

Lecture 18: Intracellular transport Flint et al., Chapter 12.
Lab of Immunoregulation

Lab of Immunoregulation
Class I and II Fusion Proteins To reproduce, enveloped viruses must enter a host cell by fusing their own membrane coat with that of the cell. Fusion is.

Class I and II Fusion Proteins To reproduce, enveloped viruses must enter a host cell by fusing their own membrane coat with that of the cell. Fusion is.
Assembly, Maturation, and Release (Getting it all together and leaving!)

Assembly, Maturation, and Release (Getting it all together and leaving!)
LJ-001.  Enveloped and Naked Viruses  Modes of Infection  LJ-001.

LJ-001.  Enveloped and Naked Viruses  Modes of Infection  LJ-001.
VIRUS ENTRY.

VIRUS ENTRY.
Transcription strategies of viruses

Transcription strategies of viruses
Vaccines and Antivirals. Clinical Use of Interferon Therefore they have been used in the treatment of cancers of various types. Therefore they have been.

Vaccines and Antivirals. Clinical Use of Interferon Therefore they have been used in the treatment of cancers of various types. Therefore they have been.
Attachment, Penetration, and Uncoating

Attachment, Penetration, and Uncoating
Cytoplasmic Membrane Systems: Structure, Function, and

Cytoplasmic Membrane Systems: Structure, Function, and
Human Viral Disease; Virus Replication Cycle. Human-Virus Interaction Virus extinction Clear virus, immunity Large number of deaths Small Population –Favors.

Human Viral Disease; Virus Replication Cycle. Human-Virus Interaction Virus extinction Clear virus, immunity Large number of deaths Small Population –Favors.
HIV and AIDS Retrovirus -> Primate Lentivirus Group.

HIV and AIDS Retrovirus -> Primate Lentivirus Group.
Virus Structure Tutorial Shuchismita Dutta, Ph.D. RCSB PDB, 2008.

Virus Structure Tutorial Shuchismita Dutta, Ph.D. RCSB PDB, 2008.
Apoptosis – mechanisms and role in cancer therapy

Apoptosis – mechanisms and role in cancer therapy
Previously Bio308 Hypotheses for molecular basis of bipolar disorder Suggest problem lies in protein targeting How are proteins targeted and delivered?

Previously Bio308 Hypotheses for molecular basis of bipolar disorder Suggest problem lies in protein targeting How are proteins targeted and delivered?
Virus binding and entry Virology lecture 3 Dr. Sadia Anjum.

Virus binding and entry Virology lecture 3 Dr. Sadia Anjum.
Viruses. Biology of Viruses Structure of Viruses: Size -Less then 0.2 microns Parts of the Virus 1)Capsid: -Made of protein subunits 2) Inner core: made.

Viruses. Biology of Viruses Structure of Viruses: Size -Less then 0.2 microns Parts of the Virus 1)Capsid: -Made of protein subunits 2) Inner core: made.

Similar presentations

Ads by Google