1. CHARACTERISTICS OF VIRUSES by Dr Madekurozwa of university of Zimbabwe
AkshayPatel575461
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May 08, 2024
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About This Presentation
The characteristics of virus
Slide Content
GENERAL
VIROLOGY
CHARACTERISTICS OF VIRUSES
VIROLOGY
CHARACTERISTICS OF VIRUSES
PROPERTIES
Growth on
artificial
media
Division by
binary
fission
Have both
DNA &
RNA
Have
ribosomes
Have
muramic
acid
Sensitivity
to
antibiotics
Bacteria
Yes Yes Yes Yes Yes Yes
Mycoplasma
Yes Yes Yes Yes No Yes
Rickettsia
No Yes Yes Yes Yes Yes
Chlamydia
No Yes Yes Yes No Yes
Viruses
No No No No No No
Growth on
artificial
media
Division by
binary
fission
Have both
DNA &
RNA
Have
ribosomes
Have
muramic
acid
Sensitivity
to
antibiotics
Bacteria
Yes Yes Yes Yes Yes Yes
Mycoplasma
Yes Yes Yes Yes No Yes
Rickettsia
No Yes Yes Yes Yes Yes
Chlamydia
No Yes Yes Yes No Yes
Viruses
No No No No No No
VIRUSES
Virus structure & replication
fundamentally different from cellular
organisms
Viruses infect all major groups of
organisms
Some viruses have broader host range
than others
None can cross eukaryotic/prokaryotic
boundary
Virus structure & replication
fundamentally different from cellular
organisms
Viruses infect all major groups of
organisms
Some viruses have broader host range
than others
None can cross eukaryotic/prokaryotic
boundary
VIRUSES
NOTCELLS
NOTMICROORGANISMS
NOFUNCTIONAL ORGANELLES
DEPENDENT ON HOST MACHINERY
CONTAIN EITHER DNA OR RNA
TWO CLEARLY DEFINED PHASES:
METABOLICALLY INERT:-TRANSMISSION
METABOLICALLY ACTIVE:-REPLICATION
NOTCELLS
NOTMICROORGANISMS
NOFUNCTIONAL ORGANELLES
DEPENDENT ON HOST MACHINERY
CONTAIN EITHER DNA OR RNA
TWO CLEARLY DEFINED PHASES:
METABOLICALLY INERT:-TRANSMISSION
METABOLICALLY ACTIVE:-REPLICATION
VIRUS STRUCTURE
Range in size: less than 100nm diameter
to several hundred nanometers in length
All viruses contain nucleic acid genome
(RNAor DNA) & protective protein coat
(capsid)
Nucleic acid genome + capsid=
nucleocapsid
Nucleocapsidhave icosahedral, helical or
complex symmetry
Range in size: less than 100nm diameter
to several hundred nanometers in length
All viruses contain nucleic acid genome
(RNAor DNA) & protective protein coat
(capsid)
Nucleic acid genome + capsid=
nucleocapsid
Nucleocapsidhave icosahedral, helical or
complex symmetry
VIRAL GENOME
DNA or RNA
Double-stranded or single-stranded
Monopartite(all viral genes contained in
single molecule) or multipartite
(segmented: viral genes distributed in
segments)
All are haploid–contain only one copy
of each gene; except retrovirus (diploid)
DNA or RNA
Double-stranded or single-stranded
Monopartite(all viral genes contained in
single molecule) or multipartite
(segmented: viral genes distributed in
segments)
All are haploid–contain only one copy
of each gene; except retrovirus (diploid)
VIRAL PROTEINS
1 (simplest virus) to > 100 (complex)
Structural:-used to construct capsid&
other components of virion.
Non-structural:-not part of virion-
involved in viral replication processes or
in virionassembly e.g. enzymes
Proteins are virus coded including those
associated with envelope.
1 (simplest virus) to > 100 (complex)
Structural:-used to construct capsid&
other components of virion.
Non-structural:-not part of virion-
involved in viral replication processes or
in virionassembly e.g. enzymes
Proteins are virus coded including those
associated with envelope.
VIRAL PROTEINS
GLYCOPROTEINS
FUSION PROTEINS:-
ASSOCIATED WITH PEPLOMERS
INVOLVED IN VIRAL ENTRY & RELEASE
MATRIX PROTEINS:-
FOUND AS LAYER ON INSIDE OF
ENVELOPE
PROVIDE RIGIDITY TO VIRION
GLYCOPROTEINS
FUSION PROTEINS:-
ASSOCIATED WITH PEPLOMERS
INVOLVED IN VIRAL ENTRY & RELEASE
MATRIX PROTEINS:-
FOUND AS LAYER ON INSIDE OF
ENVELOPE
PROVIDE RIGIDITY TO VIRION
VIRAL GLYCOPROTEINS
Most occur as membrane-anchored
peplomers(spikes) extending outward
from envelope of enveloped viruses
Sugar component corresponds to that of
host cell membrane glycoproteins
Most occur as membrane-anchored
peplomers(spikes) extending outward
from envelope of enveloped viruses
Sugar component corresponds to that of
host cell membrane glycoproteins
Viral Envelope
Structurally similar to cell membrane
Lipid bilayerwith transmembraneviral
glycoproteins
Destroyed by ether or detergent
rendering enveloped viruses non-
infectious
Structurally similar to cell membrane
Lipid bilayerwith transmembraneviral
glycoproteins
Destroyed by ether or detergent
rendering enveloped viruses non-
infectious
Viral Envelope
Inner layer of membrane protein e.g.
matrix for myxoviruses–anchors
glycoprotein
Glycoproteinsarranged into groups of 2-
4 known as spikes -> observed under
electron microscope.
Envelopes are more pleomorphicthan
nucleocapsids
Inner layer of membrane protein e.g.
matrix for myxoviruses–anchors
glycoprotein
Glycoproteinsarranged into groups of 2-
4 known as spikes -> observed under
electron microscope.
Envelopes are more pleomorphicthan
nucleocapsids
Viral Envelope
The envelope is obtained as the
nucleocapsidbuds through cell
membrane
All animal viruses with helical
nucleocapsidcontain RNA & enveloped
Majority of animal virus families with
icosahedralsymmetry are unenveloped&
those with envelopes contain DNA
The envelope is obtained as the
nucleocapsidbuds through cell
membrane
All animal viruses with helical
nucleocapsidcontain RNA & enveloped
Majority of animal virus families with
icosahedralsymmetry are unenveloped&
those with envelopes contain DNA
VIRUS STRUCTURE
Viruses may or may not contain envelope
Enveloped viruses obtain envelope by
budding through host cell membrane e.g.
plasma membrane, Golgi body,
endoplasmic reticulum or nucleus
VIRION –complete virus particle
Viruses may or may not contain envelope
Enveloped viruses obtain envelope by
budding through host cell membrane e.g.
plasma membrane, Golgi body,
endoplasmic reticulum or nucleus
VIRION –complete virus particle
VIRUS STRUCTURE
Enveloped viruses do not necessarily kill
cell in order to be released –bud out of
cell => persistent infections
Enveloped viruses are infectious only if
envelope is intact (viral attachment
proteins)
Agents which damage envelope e.g.
alcohols & detergents destroy infectivity
Enveloped viruses do not necessarily kill
cell in order to be released –bud out of
cell => persistent infections
Enveloped viruses are infectious only if
envelope is intact (viral attachment
proteins)
Agents which damage envelope e.g.
alcohols & detergents destroy infectivity
Virion Nucleocapsid
Structures
Icosahedral symmetry
Helical symmetry
Complex symmetry
Structures
Icosahedral symmetry
Helical symmetry
Complex symmetry
ICOSAHEDRAL
SYMMETRY
Solid with twenty triangular faces & 5:3:2
rotational symmetry
Twelve corners or vertices & 5-fold
symmetry around vertices
Capsidshell is made of repeating
subunits of viral protein
All faces of icosahedronare identical
Nucleic acid is packaged inside capsid
shell & protected from environment
SYMMETRY
Solid with twenty triangular faces & 5:3:2
rotational symmetry
Twelve corners or vertices & 5-fold
symmetry around vertices
Capsidshell is made of repeating
subunits of viral protein
All faces of icosahedronare identical
Nucleic acid is packaged inside capsid
shell & protected from environment
ICOSAHEDRAL
SYMMETRY
Proteins associate into structural units
(observed in electron microscope) known
as capsomers
Capsomers may contain one or several
kinds of polypeptide chain
Capsomers at the 12 corners have 5-fold
symmetry & interact with 5 neighbouring
capsomers, known as pentonsor
pentamers
SYMMETRY
Proteins associate into structural units
(observed in electron microscope) known
as capsomers
Capsomers may contain one or several
kinds of polypeptide chain
Capsomers at the 12 corners have 5-fold
symmetry & interact with 5 neighbouring
capsomers, known as pentonsor
pentamers
ICOSAHEDRAL
SYMMETRY
Larger viruses contain more capsomers
Extra capsomers are arranged in a
regular array on the faces of the
icosahedrons
They have six neighbours, called hexons
or hexamers
The size of an icosahedron depends on
the size & number of capsomers: there
will always be 12 pentons but the number
of hexons increases with size
SYMMETRY
Larger viruses contain more capsomers
Extra capsomers are arranged in a
regular array on the faces of the
icosahedrons
They have six neighbours, called hexons
or hexamers
The size of an icosahedron depends on
the size & number of capsomers: there
will always be 12 pentons but the number
of hexons increases with size
HELICAL SYMMETRY
Protein subunits interact with each other
& with nucleic acid to form coiled ribbon-
like structure
Best studied virus is non-enveloped plant
virus tobacco mosaic virus
Enveloped helically symmetrical viruses
e.g. influenza viruses, rabies virus
Protein subunits interact with each other
& with nucleic acid to form coiled ribbon-
like structure
Best studied virus is non-enveloped plant
virus tobacco mosaic virus
Enveloped helically symmetrical viruses
e.g. influenza viruses, rabies virus
COMPLEX SYMMETRY
Regular structures
Examples include the poxviruses
Regular structures
Examples include the poxviruses
FIVE BASIC STRUCTURAL
FORMS OF VIRUSES
Naked icosahedrale.g. adenovirus
Naked helicale.g. tobacco mosaic virus
Enveloped icosahedrale.g. herpes
virus
Enveloped helicale.g. rabies virus,
influenza virus, parainfluenza virus
Complexe.g. poxvirus
FORMS OF VIRUSES
Naked icosahedrale.g. adenovirus
Naked helicale.g. tobacco mosaic virus
Enveloped icosahedrale.g. herpes
virus
Enveloped helicale.g. rabies virus,
influenza virus, parainfluenza virus
Complexe.g. poxvirus
Are viruses living or dead?
In some ways fulfils criteria use to define
life; in other ways, doesn’t.
Refer to number of infectious particles
rather than number of living particles
In some ways fulfils criteria use to define
life; in other ways, doesn’t.
Refer to number of infectious particles
rather than number of living particles
UNCONVENTIONAL
AGENTS
‘Unconventional viruses’ or ‘atypical
viruses’
Viroidsand prions
AGENTS
‘Unconventional viruses’ or ‘atypical
viruses’
Viroidsand prions
VIROIDS
Contain RNA only
Small (less than 400 nucleotides), single
stranded, circular RNAs
The RNA do not appear to code for any
proteins
Have only been associated with plant
disease
Contain RNA only
Small (less than 400 nucleotides), single
stranded, circular RNAs
The RNA do not appear to code for any
proteins
Have only been associated with plant
disease
PRIONS
Contain protein only (controversial)
Small proteinaceousparticles
Examples of prion-caused animal
disease is scrapiein sheep and “mad
cow disease” in cattle.
Contain protein only (controversial)
Small proteinaceousparticles
Examples of prion-caused animal
disease is scrapiein sheep and “mad
cow disease” in cattle.
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