Medical Virology
Dept. of Medical Microbiology and Parasitology
Shanghai Second Medical University
Shanghai, China.
E.mail: ( xkguo@shsmu.edu.cn )
�General Virology
Conception
Viruses
Virion
Size and Shape
Structure
Replication
Viral Variation
Classification
�Conception
Virology is the bioscience for study of
viral nature,and the relationship
between viruses and hosts. Viruses
often cause serious diseases, relate to
some
cancers
and
congenital
deformities, also can be used as tool
for genetic engineering.
3000BC
�History
Smallpox was endemic in
China by 1000BC. In response,
the practice of variolation was
developed. Recognizing that
survivors of smallpox
outbreaks were protected from
subsequent infection,
variolation involved inhalation
of the dried crusts from
smallpox lesions like snuff, or
in later modifications,
inoculation of the pus from a
lesion into a scratch on the
forearm of a child.
�Definition of Virus
Viruses may be defined as acellular
organisms whose genomes consist of
nucleic acid, and which obligately
replicate inside host cells using host
metabolic machinery and ribosomes to
form a pool of components which assemble
into particles called VIRIONS, which serve
to protect the genome and to transfer it to
other cells
�Viral Properties
Viruses are inert (nucleoprotein ) filterable
Agents
Viruses are obligate intracellular parasites
Viruses cannot make energy or proteins
independent of a host cell
Viral genome are RNA or DNA but not both.
Viruses have a naked capsid or envelope with
attached proteins
Viruses do not have the genetic capability to
multiply by division.
Viruses are non-living entities
�Consequences of Viral Properties
Viruses are not living
Viruses must be infectious to endure in nature
Viruses must be able to use host cell processes
to produce their components (viral messenger
RNA, protein, and identical copies of the
genome)
Viruses must encode any required processes not
provided by the cell
Viral components must self-assemble
�Challenges the way we define life
viruses do not respire,
nor do they display irritability ;
they do not move
they do not grow
they do most certainly reproduce, and may
adapt to new hosts.
�Size and Shape
Methods
Size of Viruses
Shapes of Viruses
�Methods of Analysis
Electron microscopy :
The resolution is 5nm (1nm = 10-9 m)
X-ray crystallography
�Size of Viruses
A small virus has a diameter of
about 20nm.
Parvovirus
A large virus have a diameter of up
to 400nm.
Poxviruses
���Shape of Viruses
Spherical
Rod-shaped
Brick-shaped
Tadpole-shaped
Bullet-shaped
Filament
�Shapes of Viruses:Spherical
�Shapes of Viruses :Rod-shaped
�Shapes of Viruses :Brick-shaped
.
�Tadpole-shaped
�Shapes of Viruses
:Bullet-shaped
�Shapes of Viruses
:Filament
�Structure of Viruses
�Virion
the complete infectious
unit of virus particle
Structurally mature,
extracellular virus
particles.
�Virion
envelope
Capsid
Viral core
�Viral core
Viral core
The viral nucleic acid genome, In the
center of the virion, : Control the viral
heredity and variation, responsible for
the infectivity.
�Genome
The genome of a virus can be either DNA or
RNA
DNA-double stranded (ds): linear or circular
Single stranded (ss) : linear or
circular
RNA- ss:segmented or non-segmented
ss:polarity+(sense) or polarity
(non-sense)
ds: linear (only reovirus family)
�DNA
doublestranded
lin
ear
circular
RNA
singlestranded
lin
ear
circular
doublestranded
single-stranded
linear
linear (circular)
sin sin multi sin sin multi sin multi
gle gle ple gle gle ple gle ple
(+)sense
(-)sense
sin mult sin mult
gle iple gle iple
��Viral Capsid
The protein shell, or coat, that
encloses the nucleic acid genome.
Functions: a. Protect the viral
nucleic acid. b. Participate in the
viral infection. c. Share the
antigenicity
�Nucleocapsid
The core of a virus particle
consisting of the genome
plus a complex of proteins.
complex of proteins = Structural
proteins +Non- Structural
proteins (Enzymes &Nucleic
acid binding proteins)
�Symmetry of
Nucleocapsid
Helical
Cubic
/Icosahedral
Complex
�Helical symmetry
Helical symmetry
How to
assemble
�Helical
California Encephalitis Virus
Coronavirus
Hantavirus
Influenza Virus (Flu Virus)
Measles Virus ( Rubeola)
Mumps Virus
Parainfluenza Virus
Rabies Virus
Respiratory Syncytial Virus(RSV)
�Cubic or icosahedral symmetry
���Icosahedral
Adeno-associated Virus
(AAV)
Adenovirus
B19
Coxsackievirus - A
Coxsackievirus - B
Cytomegalovirus (CMV)
Eastern Equine Encephalitis
Virus (EEEV)
Echovirus
Epstein-Barr Virus (EBV)
Hepatitis A Virus (HAV)
Hepatitis B Virus (HBV)
Hepatitis C Virus (HCV)
Hepatitis Delta Virus (HDV)
Hepatitis E Virus (HEV)
Herpes Simplex Virus 1 (HHV1)
Herpes Simplex Virus 2 (HHV2)
Human Immunodeficiency
Virus (HIV)
Human T-lymphotrophic Virus
(HTLV)
Norwalk Virus
Papilloma Virus (HPV)
Polio virus
Rhinovirus
Rubella Virus
Saint Louis Encephalitis Virus
Varicella-Zoster Virus (HHV3)
Western Equine Encephalitis
Virus (WEEV)
Yellow Fever Virus
�Complex Virus Structures
A well known example is the tailed
bacteriophages such as T4.
The head of these viruses is cubic
with a triangulation number of 7. This
is attached by a collar to a contractile
tail with helical symmetry.
�T4 Bacteriophage
�Properties of naked viruses
Stable in hostile environment
Not damaged by drying, acid, detergent, and heat
Released by lysis of host cells
Can sustain in dry environment
Can infect the GI tract and survive the acid and
bile
Can spread easily via hands, dust, fomites, etc
Can stay dry and still retain infectivity
Neutralizing mucosal and systemic antibodies are
needed to control the establishment of infection
�Naked viruses( Non Enveloped )
Adeno-associated Virus
(AAV)
Adenovirus
B19
Coxsackievirus - A
Coxsackievirus - B
Echovirus
Hepatitis A Virus (HAV)
Hepatitis E Virus (HEV)
Norwalk Virus
�Envelope
A lipid-containing membrane that
surrounds some viral particles.
It is acquired during viral maturation by a
budding process through a cellular
membrane, Viruses-encoded
glycoproteins are exposed on the surface
of the envelope.
Not all viruses have the envelope, and
viruses can be divided into 2 kinds:
enveloped virus and naked virus.
�Functions of envelope
Antigenicity
some viruses possess
neuraminidase
Infectivity
Resistance
��Envelope
�Properties of enveloped viruses
Labile in dry , arid environment
Damaged by drying, acid, detergent,
and heat
Pick up new cell membrane during
multiplication
Insert new virus-specific proteins
after assembly
Virus is released by budding
�Consequences of Properties for
enveloped viruses
Must stay moist
Must not infect the GI tract for survival
Must be transmitted in the protective,
droplets, secretions, blood and body fluids
Must reinfect another host cell to sustain
Humoral and cell-mediated immunity are
needed to control the infection
��Enveloped
California Encephalitis Virus
Coronavirus
Cytomegalovirus (CMV)
Eastern Equine Encephalitis
Virus (EEEV)
Epstein-Barr Virus (EBV)
Hantavirus
Hepatitis B Virus (HBV)
Hepatitis C Virus (HCV)
Hepatitis Delta Virus (HDV)
Herpes Simplex Virus 1
(HHV1)
Rotavirus
Rubella Virus
Saint Louis Encephalitis Virus
Smallpox Virus (Variola)
Vaccinia Virus
Herpes Simplex Virus 2
(HHV2)
Human Immunodeficiency
Virus (HIV)
Human T-lymphotrophic
Virus (HTLV)
Influenza Virus (Flu Virus)
Molluscum contagiosum
Papilloma Virus (HPV)
Polio virus
Rhinovirus
Varicella-Zoster Virus
(HHV3)
Venezuelan Equine
Encephal. Vir. (VEEV)
Western Equine
Encephalitis Virus (WEEV)
Yellow Fever Virus
�Spike or Peplomere
��summarize
�Virion structure
Nucleocapsid(Naked Virus) = DNA or
RNA +Structural proteins +Enzymes
&Nucleic acid binding proteins
Enveloped Virus =Nucleocapsid+ Viral
specific glycoproteins and Host
Membrane
�Cubic
Helical
Naked
Virus
Enveloped
Virus
�CHEMICAL COMPOSITION
OF VIRUSES
Viral
Viral
Viral
Viral
Protein
Nucleic Acid
Lipids
carbohydrate
�Viral Nucleic Acid
DNA-double stranded (ds): linear or circular
Single stranded (ss) : linear or circular
RNA- ss:segmented or non-segmented
ss:polarity+(sense) or polarity (non-sense)
ds: linear (only reovirus family)
�Viral Protein
Structural protein (Capsomere)
Enzyme
glycoproteins (spike/viral
attachment protein, VAP)
�Culture of Viruses
�System for the propagation of
viruses
People
Animals : cows;chickens; mice; rats;
suckling mice
Embryonated eggs
Organ and tissue culture
Organ culture
primary tissue culture
cell lines: diploid
Tumor or immortalized cell line
Cytopathic effect, CPE
Inclusion Bodies
�CPE:Viral Cytopathological Effects
Cell death
Cell rounding/Degeneration/Aggregation
Lass of attachments to substrate
Inclusion bodies in the nucleus or
cytoplasm, margination of chromatin
Syncytia: multinucleated giant cells caused
by virus-induced cell-cell fusion
Cell surface changes
Viral antigen expression
Hemadsorption (hemagglutinin
expression)
�Normal cell and CPE
�Inclusions
Negri body
�TCD50,LD50,ID50
PFU: plaque forming units
�Replication of Viruses
�Replicative cycle
As obligate intracellular parasites, Virus
must enter and replicate in living cells in
order to reproduce themselves. This
growth cycle involves specific
attachment of virus, penetration and
uncoating, nucleic acid transcription,
protein synthesis, matureation and
assembly of the virions and their
subsequent release from the cell by
budding or lysis
����Initiation Phase
Attachment
Penetration
Uncoating
�Attachment/Adsorption
Virus attaches to the cell surface. Attachment is
via ionic interactions which are temperatureindependent.
Viral attachment protein recognizes specific
receptors on the cell surface (These may be
protein or carbohydrate or lipid components of
the cell surface).
Cells without the appropriate receptors are not
susceptible to the virus.
�PENETRATION
(Virus enters the cell)
Virions are either engulfed into vacuoles by
endocytosis or the virus envelope fuses
with the plasma membrane to facilitate entry
Enveloped viruses
Non-enveloped viruses
�Fusing
(A) Entry by fusing with
the plasma membrane.
Some enveloped viruses
fuse directly with the
plasma membrane. Thus,
the internal components of
the virion are immediately
delivered to the cytoplasm
of the cell.
�HIV
�Endocytosis
(B) Entry via endosomes at the cell surface
�influenza virus
�Enveloped viruses
Some enveloped viruses require an acid pH for
fusion to occur and are unable to fuse directly with
the plasma membrane. These viruses are taken up
by invagination of clathrin coated pits into
endosomes. As the endosomes become acidified,
the latent fusion activity of the virus proteins
becomes activated by the fall in pH and the virion
membrane fuses with the endosome membrane.
This results in delivery of the internal components
of the virus to the cytoplasm of the cell
�Non-enveloped viruses
Non-enveloped viruses may cross the plasma
membrane directly
may be taken up via clathrin-coated pits into
endosomes. They then cross (or destroy) the
endosomal membrane.
�un e nve lo p e d
�UNCOATING
Nucleic acid has to be sufficiently uncoated that virus
replication can begin at this stage. When the nucleic
acid is uncoated, infectious virus particles cannot be
recovered from the cell - this is the start of the
ECLIPSE phase - which lasts until new infectious
virions are made
Uncoating is usually achieved by
cellular proteases opening up the
capsid
�BIOSYNTHESIS
genome synthesis
mRNA production
protein synthesis
�Flow of events during the
replication of Hepadna
viruses
�Flow of events during the
replication of herpesviruses
�Flow of events during
the replication of
reoviruses.
�Flow of events during
the replication of
togaviruses
�Flow of events during the replication
of orthomyxoviruses and
paramyxoviruses.
�Flow of events during the replication
of retroviruses
�Maturation assembly
release
�Maturation
The stage of viral replication at which a virus
particle becomes infectious; nucleic acids and
capsids are assembled together.
�ASSEMBLY
The stage of replication during which all the
structural components come together at one
site in the cell and the basic structure of the
virus particle is formed.
�RELEASE
Disintegration : naked virus cause the host cell
lysis
Budding: enveloped viruses
Budding viruses do not necessarily kill the cell.
Thus, some budding viruses may be able to set
up persistence
�Assembly
��Products of viral replication
Virion
DEFECTIVE VIRUS
ABORTIVE INFECTION
integration
�DEFECTIVE VIRUS
deficiency in some aspects of replication, but
interfering the replication of normal viruses
ABORTIVE INFECTION
When a virus infects a cell (or host), but cannot
complete the full replication cycle ( not biosynthesize
their components or not assemble virions.), i.e. a nonproductive infection.
�INTERFERENCE
Interferon, IFN
Defective interfering particle, DIP
�Viral Genetics
�Genome
The genome of a virus can be
either DNA or RNA
DNA-double stranded (ds): linear or circular
Single stranded (ss) : linear or circular
RNA- ss:segmented or non-segmented
ss:polarity+(sense) or polarity (nonsense)
ds: linear (only reovirus family)
�Virus Genomes
�The Structure & Complexity of Virus
Genomes
The nucleic acid comprising the genome may be
single-stranded or double-stranded, & in a linear,
circular or segmented configuration. Singlestranded virus genomes may be:
positive (+)sense, i.e. of the same polarity
(nucleotide sequence) as mRNA
negative (-)sense
ambisense - a mixture of the two.
�The Structure & Complexity of Virus
Genomes
any virus genome will usually include the
following:
Composition - DNA or RNA, single-stranded
or double-stranded, linear or circular.
Size & number of segments.
Terminal structures.
Nucleotide sequence.
Coding capacity - open reading frames.
Regulatory signals - transcription enhancers,
promoters & terminators.
�The Structure & Complexity of Virus
Genomes
�Transfection
Infection of cells caused by nucleic
acid alone
�Variation
There are two important variation which
relate well with medical practices
Antigenicity variation: In most viruse the
antigenicity is stable but in some viruses
such as influenze virus the antigenicity
may vary and cause the disease to
epidemic.
Virulence variation(Virulent viruses):
Less virulent viruses always used in
prevention.
�Mutation
Mutant
Variant
temperature sensitive(ts)
mutant
�Interactions
when two genetically distinct viruses infect a cell
3 different phenomena can ensue
Recombination /Reassortment
Complementation
Phenotypic mixing
�Recombination
dsDNA viruses
Reassortment ( segmented
genomes)
RNA viruses: influenza
virus
�Complementation
�Phenotypic mixing
The genome of virus A can be
coated with the surface protein of
virus type B
�Classification of Viruses
��CLASSIFICATION OF VIRUSES
-------basis of classification
Virion morphology
Physicochemical properties of the virion
Virus genome properties
Virus protein proteries
Genome organization and replication
Antigenic properties
Biologic properties
�CLASSIFICATION OF VIRUSES
By 1995
--71 families, 11 subfamilies
--164 genera
For humans and animals
--24 families,
--DNA: 7; RNA: 17 for humans
�Survey of DNA-containing
Viruses
Parvoviruses: human parvovirus B
Papovaviruses: papillomaviruses
Adenoviruses: 47 types infect
19
humans
Herpesviruses:
human herpesvirus
1-8
Poxviruses: smallpox; vaccinia
Hepadnaviruses: HBV
����Survey of RNA-containing
Viruses
Picornaviruses
Astroviruses
Caliciviruses
Reoviruses
Arboviruses
Togaviruses
Flaviviruses
Arenaviruses
Coronaviruses:
Retroviruses
Bunyaviruses
Othomyxoviruses
Paramyxoviruses:
Rhabdoviruses:rabies
virus
SARS
Bornaviruses: BDV
Filoviruses
Other viruses
Viroids
������DNA and RNA Viruses
Headnasviridae
Retroviridae
�Viroids( )
Viroids are small (200-400nt), circular
RNA molecules with a rod-like
secondary structure which possess no
capsid or envelope which are
associated with certain plant diseases.
Their replication strategy like that of
viruses - they are obligate intracellular
parasites.
�Dependovirus /Virusoids
Viroids are small (200-400nt), circular RNA
molecules with a rod-like secondary structure
which possess no capsid or envelope which are
associated with certain plant diseases. Their
replication strategy like that of viruses - they
are obligate intracellular parasites.
� (Prions)
Prions are rather ill-defined infectious
agents believed to consist of a single type of
protein molecule with no nucleic acid
component. Confusion arises from the fact
that the prion protein & the gene which
encodes it are also found in normal
'uninfected' cells. These agents are
associated with diseases such as
Creutzfeldt-Jakob disease in humans,
scrapie in sheep & bovine spongiform
encephalopathy (BSE) in cattle.
