1. What
is a virus: A very small organism, which can grow and multiply, only
inside of a cell. It requires the content of the cell to manufacture
the various components of the virus. These components are; i) DNA or
RNA nucleic acids. These are the genes of the virus. Viral particles
contain either RNA or DNA but not both, whereas bacteria and cells have
both RNA and DNA. The amount of DNA or RNA in a virus varies depending
on the type of virus. Small viruses, e.g. papillomavirus have about
9,000 nucleotide molecules strung in a row. Big viruses, e.g. a herpesvirus
can have 150,000 nucleotides. ii) A protein (or proteins) which associate
with the DNA or RNA and provides some protection as the virus passes
between cells. The proteins make up the capsid of the virus. iii) Some
viruses also have an outer protective layer of proteins in lipid envelope,
and sometimes also between the capsid and the envelope (termed tegument
proteins).
2. Viruses
are classified in several ways, for example. i) Whether the viral particles
contain RNA or DNA. Some RNA viruses convert to DNA after they enter
a cell and are called retroviruses. ii) Whether the genome is single
(ss) or double stranded (ds). iii) For single stranded RNA viruses,
the sequence may directly code for its protein (positive, +ve, stranded),
or consist of the opposite or negative, -ve, strand. iv) The genome
may be linear or circular and may be in a single segment, or in multiple
segments. iv) The genome size and overall shape of the virus and whether
an envelope is present are also major criteria used for classification.
v) Finally, the kinds of diseases produced can distinguish different
viruses. Related viruses are successively grouped into species, genera,
families and orders (see Table).
3. Viruses
which can cause disease are termed pathogenic. Examples of virus induced
diseases include; influenza, the common cold, chickenpox, measles, mumps,
rubella, hepatitis, infectious mononucleosis, polio, etc. Some viruses
are thought to cause cancer. A retrovirus called human immunodeficiency
virus (HIV) causes Acquired Immunodeficiency Syndrome (AIDS).
4. Some
viruses can directly damage cells by usurping the cells metabolic resources
and/or by producing toxic components which interfere with the cells'
normal functions. These viruses will generally induce a cytopathic effect
(CPE) in tissue culture cells. Viruses can also cause cells to express
viral and/or altered cellular components which become targets for anti-cellular
immunity. Finally, HIV directly attacks the immune system leaving the
infected host vulnerable to secondary infections by other pathogens.
5. Certain
types of cellular proteins have the peculiar property that when in an
abnormal configuration, they will induce the corresponding normal protein
to assume the same abnormal configuration. These set up a chain reaction
leading to the progressive accumulation of abnormally configured proteins.
Such proteins have been termed "prions" for "proteinaceous
infectious particles". Certain humans and animals inherit genetically
altered normal protein with an enhanced tendency to "spontaneously"
generate the small quantity of the abnormally configured protein to
begin the process. If other individuals become exposed to these proteins,
e.g. by ingestion with food, disease can occur along with the potential
of further transmission.
Prion
diseases include scrapie in sheep, bovine spongiform encephalopathy
or mad cow disease in cows and both Creutzfeldt-Jakob disease and kuru
in humans.
An assay
based on the detection of a neuronal protein 14-3-3 in cerebrospinal
fluid of patients with Creutzfeldt-Jakob disease was recently described
by Dr. Micael Harrington and his colleagues.
LABORATORY
DIAGNOSIS OF VIRAL INFECTIONS
Serological,
molecular biological and tissue culture methods are used to diagnose
viral infections and to accertain the extent of viral damage and the
quality and intensity of the body's immune response.
The antibody
response to a viral infection normally starts with the relatively transient
production of IgM followed by a long lasting production of IgG. For
this reason, a specific IgM antibody response can generally be taken
as a sign of early infection. The serological detection of free viral
antigen can precede the earliest serological response and this type
of assay can be useful for certain infections, e.g. parvovirus B19,
HIV, hepatitis B virus (HBV) and human herpesvirus-6 (HHV-6). Antigen
assays can also be used to distinguish persisting infection, in spite
of IgG response, from a cured infection. Again, this type of approach
has been employed with HIV and HHV-6.
The quality
and intensity of the anti-viral cellular immune responses can be assessed
using lymphocyte subset analyses, natural killer cell mediated cytotoxicity,
and measurements of cytokine production including IL2, IL4, interferon,
etc.
For some
infections, actual culture of the virus can provide conclusive evidence
of active infection, as well as the isolate for susceptibility studies.
Active infection can also be inferred from the results of molecular
probe based assays, including the use of polymerase chain reaction and
branched DNA procedures.
Individuals
can harbor multiple viral infections which may potentiate each other
and lead to atypical manifestations.
The extent
of organ damage can be assessed directly using tissue biopsies, or measured
indirectly by assaying for various components released from the infected
organ. For example 14-3-3 protein in Creutzfeldt-Jakob disease.
Finally,
sequential measurements can provide a means to determine natural outcome
as well as response to specific intervention.
Additional Viruses
Read
about other viruses that are being researched for neuropsychiatric illnesses.
Click Here!
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