Baltimore classification of RT ssRNA viruses
•RT ssRNAviruses (retroviruses) belong to Class VI, according to the Baltimore classification of viruses
Introduction to RT dsDNAviruse
- Retroviruses are RNA viruses that must copy their genome into DNA in the course of transcription.
- Reverse transcription is one unique features among the classes VI and VII (dsDNA) viruses.
- Retroviruses can infect all vertebrate classes such as fish, birds, amphibians and mammals.
- Important examples of retroviruses are HIV-1 and HIV-2.
- Most retroviruses are important agents of canc
Classification of retroviruse
ssRNA RT into two groups
simple and complex retroviruses
simple retroviruses
Simple retroviruses: Viruses that possess only the major genes (gag, pol, env) or may have an additional gene known as an oncogene (whose expression can result in tumor cells in the host). An example is the srconcogene in the genome of Rous sarcoma virus, known to infect chickens
ssRNA RT
complex retroviruses
Complex retroviruses: Possess multiple genes which perform various roles in the virus. An example is the HIV which has auxiliary genes such as, virioninfectivity factor (vif), viral protein R (vpr), viral protein U (vpu).
ssRNA RT
How is the retrovirus virion unique
- The virionof a retrovirus is unique in that it has two copies of the genome.
- Thus, both RNA molecules form a dimer, by base pairing between complementary sequences.
- Incorporation of host molecules in retrovirus genome: During virionassembly and exit, retroviruses incorporates host cell RNA molecules in its genome
tRNAin virionof Retroviruses
- Primer binding site (PBS): Contains sequence of virus RNA which binds with host-cell-derived tRNA.
- Binding of virus RNA to host tRNAis specific for each retrovirus
Important proteins in the virionof Retroviruses
- Nucleocapsid(NC): It coats the virus RNA, thus forms the most abundant protein in retroviruses. Other proteins are present in trace amount and mostly functions as enzymes
- RNA-Dependent DNA polymerase (reverse transcriptase; RT).
- DNA-dependent DNA polymerase
- RibonucleaseH (RNaseH)
- Integrase
- Proteas
The capsid of retroviruse
- Retrovirus capsid may have the shape of a cylinder, sphereor a coneand varies among virionspecies.
- Capsid proteins (CP): The capsid is composed of CP which surrounds the virionRNA (genome).
- Matrix(MA): A layer of protein which lies between the capsid and envelope.
- Envelope (env):is associated with two proteins which are bound non-covalently to each other.
- Transmembrane(TM) protein:
- glycosylated surface (SU) protein
The genome of ssRNA retroviruses
3 genes
- The gene of retroviruses encodes virus proteins which are arranged in three distinct regions of the genome.
- gag(group specific antigen) encodes internal structural protein
- pol (polymerase) encodes enzymes
- Env(envelope) encodes envelope protei
Replication in Retroviruses
steps
The steps in replication are: •Attachment and Entry•Reverse transcription•Transcription and Genome replication•Translation•Assembly•Exi
attachment of ssRNA retroviruses
- Attachment: occurs through binding of the surface (SU) protein on the virionenvelope with host cell receptors.
- The binding results in a conformational change in the transmembraneprotein (TM) permitting a hydrophobic fusion sequence to bind the virionmembrane and a cell plasma membran
Entry of retroviruses
•Cell entry: Majority of retroviruses enter host cells by fusion of virionmembrane with host cell membrane, while some gain entrance through endosome-mediated endocytosi
Formation of reverse transcription complex in ssRNA RT viruses
- Formation of reverse transcription complex: Is formed upon virionentry into the cell cytoplasm which results in the loss of some proteins.
- The synthesis of both the (+) DNA and (-) DNA strands starts at the 3’-OH of a primer RNA (tRNA).
- While the primer for synthesis of (-) DNA is the tRNAbound to the genome, the primer for synthesis of (+) DNA is a polypurinetract (PPT) in the virus genom
Figure 3 : Reverse transcription in retroviruses ssRNA
- A copy of the virus genome with a tRNAbound at the PBS.
- The reverse transcriptase begins (–) DNA synthesis at the 3′ end of the tRNA.
- The RNaseH digests the RNA from the RNA–DNA duplex. The (–) DNA attaches atthe 3′ end of either the same RNA strand or the second copy of the genome.
- Elongation of the (–) DNA continues, while the RNaseH degrades the template RNAfrom the 3′ end as far as the PPT.
- Synthesis of (+) DNA begins.
- The remaining RNA is degraded.
- The (+) DNA detaches from the 5′ end of the (–) DNA template and attaches at the 3′end.
- Synthesis of both DNA strands is completed.
The dsDNAresulting from the reverse transcrip
Transport of the ssRNA RT
provirus into the nucleus
- Formation of pre-integration complex: Prior to entry of the provirus into the nucleus, it forms an association with some virionproteins.
- Proteins associated with the pre-integration complex are: reverse transcriptase, matrix proteinand integrase(bound to each end of the DNA).
- Transportation of the integration complex in some retroviruses (e.g. HIV) to the nucleus is mediated by microtubule complex.
- Entry of most retroviruses into the nucleus usually occur during mitosis as it requires breakdown of the nuclear envelope.
- Implication for these viruses is that productive infection can only occur during cell division.
- Note that the pre-integration complexes of HIV and related viruses can initiate productive infection at any phase of the cell cycle as they can enter an intact nucleus. Thus, do not require the cell to be in a phase of cell division prior to entry
Figure 4: Transport of the ssRNA RT provirus into the nucleus and integration into cell DNA
The result of entry of pre-integration complex into the nucleus is as follows:
i. Integrasecuts the DNA of the cell chromosome in two and insert the provirus gene in between.
ii. Integration of provirus gene with cell DNA is mediated by cell DNA repair machinery.
iii. Integration could result in productive infection(immediate virus gene expression) or latent infection(delayed virus gene expression).
iv. When host cells with latent infection divide, the provirus gene is retained along with cell genome i
Transcription and genome replication in ssRNA retroviruses
- Each termini of the dsDNAof the provirus has a long terminal repeats (LTRs) denoted by U3-R-U5, having a U3 sequence at one end and U5 sequence on the other end.
- Both LTRs of the provirus have identical sequences, but possess different functions as transcription in triggered in one and terminated at the othe
Figure 6: Transcription and genome replication in retroviruses
- Transcription is initiated through binding of transcription factors to a promoter in upstream LTR
- Cell RNA polymerase II begins transcription at the U3-R
- Transcription proceeds into the downstream LTR and terminates at the R-U5 end which is polyadenylatedat the R region.
- Each transcript is capped and polyadenylatedat each end.
- Some transcript will serve as genome for progeny virion, while others will function as mRNA, and a portion become splice
Translation and post-translational modification in retroviruses in the envelope
- Envelope: This is coded for in the envgene and translated from spliced mRNA.
- Translation of envelope proteins occurs in the rough endoplasmic reticulum, where post-translational modification (glycosylation) is also initiated.
- The translated envelope proteins are then transferred to the Golgi apparatus, where they are cleaved into SU and TM by host proteolyticenzymes.
- Both cleaved SU and TM proteins remain closely linked, undergo further glycosylation before transported to the plasma membrane
Figure 7: Translation and post-translational
Spliced mRNA are transported from the nucleus to the rough endoplasmic reticulum where translation into envelope proteins occurs and glycosylation is initiated.
Envelope proteins are transported to the Golgi complex where they are cleaved into TM and SU proteins and undergo further glycosylation.
Both products are transported to the plasma membrane
Whole genome mRNA (transcribed from gag and pol genes) are translated into Gag and Gag-Pol polyproteins, for which the former is needed in large quantity than the latter
Assembly and release of virionsin retroviruses
- Most retroviruses assembly their components at the inner side of the plasma membrane.
- However, some form pre-mature nucleocapsidwhich are transferred to the plasma membrane.
- Base pairing of complementary sequences between two copies of genome RNA results a dimer, whose interaction forms a ‘’kissing loop complex’’.
Figure 7: Early-phase assembly in retroviruses:
Assembly of viriongene and proteins accumulate at the inner side of the plasma membrane.
A genome dimer is linked to cell-derived tRNAalong with Gag and Gag-Pol proteins.
Gag and Gag-Pol proteins become attached to the plasma membrane by the myristylgroups at their N termini
The matrix (MA) domain binds to the cytoplasmic tail of TM proteins in the membra
Figure 8: Late-phase assembly and exit in retroviruses:Immature virionderives its envelope through budding from the plasma membrane
Gag and Gag-Pol polyproteinare cleaved by virus protease during and after budding of the virion.
Cleavage of Gag protein result in the capsid, the matrix and protein component of the nucleocapsid.
Cleavage of the Pol results in the virionenzymes (polymerase, intergrase, RNase, protease).
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Introduction To Virology34
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Virus Classificaiton and Evolutionary Orgins28
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Virus Transmission and Host Outcomes42
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Virus Replication in Host Cells36
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Methods in Virology49
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Plus Strand RNA Viruses32
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Minus Stranded RNA Viruses29
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dsRNA Viruses25
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ssDNA viruses27
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ds DNA viruses34
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(RT) dsDNA Viruses36
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ssRNA RT viruses30
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Genome-endogenated viruses10
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Viriods, Virophages, and Prions62
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Bacteria Viruses51
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Intrinsic, innate and adaptive host defenses0
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Viruses and cancer27
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virus pathogenicity, symptoms and disease91
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Anti-viral vaccines and chemotherapy0
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"class" directed review118
