1. Brief Historical Background

2. History 1
The existence of viruses became evident during the closing years of the 19th century, as a result of a newly acquired expertise in the handling of bacteria,
The infectious agents of numerous diseases, were being isolated.
For some infectious diseases, this proved to be an elusive task until it was realized that the agents causing them were smaller than bacteria.

3. History 2
Iwanowski (1892), was probably the first to record the transmission of an infection, “tobacco mosaic disease” by a suspension filtered through a bacteria- proof filter.
This was followed in by similar experiment of Loffler and Frosch concerning foot and mouth disease of cattle

4. History 3
Beijerinck (1898) considered the infectious agents in bacteria-free filtrates to be living but fluid, that is nonparticulate, and introduced the term “virus” (meaning poison in Latin) to describe them.
It quickly became clear, however, that viruses were particulate and the term “virus” became the operational definition of infectious agents smaller than bacteria and unable to multiply outside living cells

5. History 4
In 1911, Rous discovered a virus that produced malignant tumors in chickens,
During World War I (1915,1917) Twort and d’Herrelle independently discovered the viruses that multiply in bacteria, the bacteriophages.

6. Experimental approaches
During the next 25 years, the experimental approaches in the different areas of virology diverged
Plant viruses proved easy to obtain in large amounts, thus permitting extensive chemical and physical studies.
This work first led to the demonstration that plant viruses consist only of nucleic acid and protein and culminated in the crystallization of tobacco mosaic virus (TMV) by Stanely in 1935.
This feat evoked a great surprise since it cut across preconceived ideas concerning the attributes of living organisms and demonstrated that agents able to reproduce in living cells behaved under certain conditions as typical macromolecules.

7. Experimental approaches
Work with bacteriophages concentrated on their clinical applications.
It was hoped that bacteria could be destroyed inside the body by injecting appropriate bacteriophages.
Their activity, however, never matched their activity in vitro, most probably because they are eliminated efficiently from the bloodstream.

8. Breakthroughs Around the year 1940 came several breakthroughs:
First, the introduction of electronmicroscopy permitted visualization of viruses for the first time.
As will become evident, not only morphology an important criterion of virus classification, but the study of the morphology of viruses has also profound impact on our understanding of their behavior and function.
Second, techniques for purifying certain animal viruses were being perfected.

9. Breakthroughs
Third, Hirst(1941) discovered that influenza virus agglutinates chicken red blood cells.
This phenomenon, “hemagglutination” was rapidly developed into an accurate method for quantitating myxoviruses, as a result of which this group of viruses became in the 1940s the most intensively investigated group of animal viruses.
Finally, this period marked the beginning of the modern era of bacterial virology.

10. Virology and Advances in Molecular Biology
Indeed, during the last four decades of the previous century, many of the major advances in molecular biology have resulted from work in the bacteriophage field. Among these are:
The demonstration that initiation of virus infection involves the separation of viral nucleic acid and protein,
The demonstration that the virus genome can become integrated into the genome of the host cell,
The discovery of messenger RNA, and the elucidation of factors that control initiation and termination of both transcription and translation of genetic information.

11. In animal virology, rapid advances followed the development in the 1940s, of techniques for growing animal cells in vitro.
Strains of many types of mammalian cells can now be grown in media of defined composition.
As a result, animal cell-virus interactions can now be analyzed with the same techniques that have proved so powerful in the case of bacteriophages.
Many new techniques have been used for purification and identification of viruses
e.g density gradient ultracentrifugation,
labelling with isotopes
and molecular biology technology.

12. GENERAL PROPERTIES AND CLASSIFICATION OF VIRUSES

13. What are Viruses?
They are small, nanometer “nm” is the measuring unit.
Obligate intracellular parasites.
They possess only one species of nucleic acid, either DNA or RNA.
They have receptor-binding protein for attaching to host cells.
Viruses colonize most living beings, whether plant, animal, insect, or microbe.

14. Viruses
They are small, nanometer “nm” is the measuring unit ( nm)

15. Basic Components of Viruses
Viral particles consist of two or three parts:
Genome, “nucleic acid, DNA or RNA”
Protein coat called capsid which is made up of capsomeres.
Capsid protects the genome.
The nucleic acid core and the capsid are together known as nucleocapsid.
The complete virus particle is termed virion.
Envelope, composed of lipids and proteins.
Envelope is derived from plasma membrane of the host cell.
Spikes, may be present on the outer surface of the virus.
They mediate attachment to host cell receptors.

16. Basic Components of Viruses

17. Basic Components of Viruses
DNA
RNA or
Capsid protein
Naked capsid virus +
Nucleocapsid =
Lipid membrane, glycoproteins
Enveloped virus
Nucleocapsid +

18. Viruses Show Two Main Forms of Symmetry
Icosahedral
symmetry- capsomeres are arranged to form a solid with 20 equal triangular sides
Helical symmetry-
capsomeres are arranged like the steps in a spiral staircase around the central genome core

19. Complex Viruses Viruses with large genomes have complex architecture.
Poxviruses have lipids in both the envelopes and the outer membranes of the viruses;
they are neither icosahedral nor helical, and are referred to as complex viruses.

20. Five Basic Structural Forms of Viruses in Nature
Naked icosahedral
e.g. poliovirus, adenovirus, hepatitis A virus
Naked helical
e.g. tobacco mosaic virus. So far no human viruses with this structure are known
Enveloped icosahedral
e.g. herpes virus, yellow fever virus, rubella virus
Enveloped helical
e.g. rabies virus, influenza virus, parainfluenza virus, mumps virus, measles virus
Complex
e.g. Bacteriophage, poxvirus

21. One of the most famous types of poxviruses is the variola virus which causes smallpox.

22. Virus Genome Nucleic acid molecules may be: DNA or RNA
Double-stranded or single stranded
Linear, circular, continuous or segmented
Most DNA viruses are double-stranded
Most RNA viruses are single-stranded
Single-stranded RNA viruses are either:
positive stranded (“+” sense RNA); can act directly as mRNA,
or negative-stranded (“-“ sense RNA); must be transcribed by a virus-associated RNA transcriptase enzyme to a mirror-image (complementary) positive-stranded copy, which is then used as mRNA.

23. Virus Genome The size of viral genome varies;
the largest, e.g., poxviruses may contain several hundred genes
whereas, the smallest may have the equivalent of only 3 or 4 genes.

24. Classes of viruses There are three major classes of viruses:
Animal viruses,
Plant viruses, and
Bacterial viruses
T2 bacteriophage viruses (orange) attacking an Escherichia coli 

25. Classification of Viruses
Criteria used for classification
Nucleic acid type (DNA or RNA)
The number of strands of nucleic acid and their physical construction
(single-or double-stranded, linear or circular, circular with breaks, segmented).
Polarity of the viral genome; (+)-sense RNA or (-) -sense RNA.
The symmetry of the nucleocapsid.
The presence or absence of a lipid envelope.

26. Classification of Viruses

27. Classification of Viruses
According to the above-mentioned criteria, viruses are grouped into families (Tables 1 & 2), subfamilies, and genera.
Figures 4 represents types & forms of RNA & DNA virus genomes.
Further subdivision is based on the degree of antigenic similarity.

28. Figure 4: Types & forms of RNA & DNA virus genomes
segmented
Figure 4: Types & forms of RNA & DNA virus genomes

29. Nomenclature of Viruses
Some viruses are named according to the type of disease they cause,
e.g., poxviruses and herpesviruses
Other family names are based on acronyms,
e.g., papovaviruses “papilloma-polyoma- vacuolating agent” and picornaviruses “pico=small; rna= ribonucleic acid”.
Others are based on morphological features of the virion,
e.g., coronaviruses have a corona of spikes.

30. Nomenclature of Viruses
Some viruses are named after the place where they were first isolated,
e.g., Coxsackie and Marburg viruses.
Some viruses are named after their discoverers,
e.g., Epstein-Barr virus.

31. Nomenclature of Viruses
The official nomenclature of families and sub- families is Latinized
e.g., Picornaviridae, Poxviridae.
A few families are divided into subfamilies with the suffix – virinae,
e.g., chordopoxvirinae.
Genera are not latinized, and they have the suffix virus,
e.g., orthopoxvirus, parapoxvirus