Positive stranded RNA viruses Flaviviridae Positive stranded RNA viruses

Flaviviridae Enveloped virions made up of a lipid bilayer with two or more types of envelope (E) glycoproteins surrounding a nucleocapsid. Single-stranded, positive-sense genome RNA complexed with multiple copies of a small, basic capsid (C) protein.

Life Cycle Binding and uptake involve receptor-mediated endocytosis via cellular receptors specific for viral envelope proteins. Low pH of the endosomal pathway induces fusion of the virion envelope with cellular membranes. Following uncoating of the nucleocapsid, the RNA genome is release into the cytoplasm. The viral genome serves three discrete roles within the life cycle: mRNA for translation of all viral proteins, template during RNA replication, and genetic material packaged within new virus particles. Viral proteins are produced as part of a single long polyprotein of more than 3,000 amino acids that is cleaved by a combination of host and viral proteases. The structural proteins are encoded in the N-terminal portion of the polyprotein with the nonstructural (NS) proteins in the remainder.

RNAreplication occurs in cytoplasmic replication complexes via synthesis of a genome-length minus strand RNA intermediate. Progeny virions are thought to assemble by budding into an intracellular membrane compartment, most likely the endoplasmic reticulum (ER), then transited through the host secretory pathway and released at the cell surface.

Examples Dengue virus Hepatitis C Virus

Attachment Flaviviruses can utilize multiple receptors for different cell types and in different host species. Infection of dendritic cells (DC) is particularly important because these intradermal cells can be primary targets early in infection. Other proteins identified as receptors include: αvβ3 integrin, GRP78 (BiP), and CD14 In addition, highly sulfated glycosaminoglycans (e.g., heparan sulfate) have been shown to play an important role in the initial attachment of several flaviviruses to target cells. Virus particles opsonized with immunoglobulins show enhanced binding and infection of cells expressing immunoglobulin Fc receptors. It is widely suspected that antibody-enhanced infection may be relevant to the pathogenesis of DF and DHF, which occur more frequently in people previously exposed to other DENV serotypes.

Entry Internalized via clathrin-coated pits and trafficked to a prelysosomal endocytic compartment where low pH induces fusion between the virus and host cell membranes to release the virus nucleocapsid It appears that viral genomes are directly accessible for translation after membrane fusion.

Dengue Virus Genomes consist of a single, positive-strand RNA of ≈11 kb (sedimentation, 42S) 5 ‘cap, m7GpppAmpN2 Additional methylation of the N2 residue (type II cap) has also been detected in RNA from infected cells. Unlike cellular messenger RNA (mRNA), flavivirus genomes lack a 3 polyadenylate tail. Genomes encode a single long open reading frame (ORF) flanked by 5 and 3 noncoding regions (NCR) of ≈100 nucleotide (nt) and 400 to 700 nt, respectively.

RNA Replication Replication begins with the synthesis of a genome-length minus strand RNA, which then serves as a template for the synthesis of additional plus strand RNA. Minus strand RNA has been detected as early as 3 hours after infection

Hepatitis C: Basic Facts Hepatitis C is a global health problem affecting over 170 million people worldwide. There is wide geographic variation in both prevalence and genotype distribution of hepatitis C virus on a global level. Transmitted: Body fluids Parenterally Hepatitis C is a leading cause of end-stage liver disease and hepatocellular carcinoma. Despite a declining incidence of new infections, the burden of disease, both in terms of mortality and in terms of cost, is expected to increase over the next decade.

Serologic Pattern of Acute HCV Infection with Recovery anti-HCV Symptoms +/- HCV RNA Titer ALT Normal 1 2 3 4 5 6 1 2 3 4 Months Years Time after Exposure

Serologic Pattern of Acute HCV Infection with Progression to Chronic Infection anti-HCV Symptoms +/- HCV RNA Titer ALT Normal 1 2 3 4 5 6 1 2 3 4 Months Years Time after Exposure

Burden of diseases in Pakistan Studies in Pakistan have found HCV: 60% among liver cancer patients (Ahmed et al., 1995) 51% among beta thalassemia major patients (Ahmed et al., 1995) 46% among chronic liver disease patients (Mujeeb et al., 1998) 18% among cirrhotic patients (Mujeeb et al., 1998) 20% among commercial blood donors (Mujeeb et al., 1998)

Hepatitis C Virus (HCV) The HCV genome is an uncapped, 9.6-kb RNA containing highly structured 5 and 3 ends. The 5 NCR is a well-conserved, 341-nt sequence element that folds into a complex structure consisting of four major domains and a pseudoknot. The first 120 nt serves as a minimal replication element, although nearly the entire 5 NCR is needed for efficient RNA replication.

Schematic diagram of the hepatitis C virus genome.5′UTR3′XR Liang T J et al. Ann Intern Med 2000;132:296-305 ©2000 by American College of Physicians

RNA Replication Translation and RNA replication are mutually exclusive processes, because they proceed in opposite directions on a given RNA template. Positive-strand RNA viruses regulate the rate of genome translation versus replication. Translation of the HCV genome occurs more frequently than replication. One way this could be regulated is via crosstalk between the determinants that control translation and genome replication. E.g the cellular PTB protein binds to the HCV 5 NCR and core coding region where it may modulate IRES activity and to the 3 end where it may repress replication.

It has been suggested that HCV translation can be autoregulated through product inhibition. Low levels of HCV core protein can enhance HCV IRES mediated translation, whereas high concentrations inhibits HCV translation Polycytidine-binding protein 2 (PCBP-2) binds to the HCV 5 NCR also noted in polioviruses that PCBP binds 5’ NCR and RdRP of poliovirus, to control the switch between translation and replication.

Location of Replication The HCV genome is recruited out of translation and into a membrane associated replication complex, or replicase. Specifically, NS proteins and HCV RNA associate with a membranous web.

HCV RNA replication is stimulated by increased availability of saturated and monounsaturated fatty acids, and inhibited by polyunsaturated fatty acids or inhibitors of fatty acid synthesis. HCV RNA is protected from nuclease degradation by a detergent-sensitive membrane suggesting that RNA synthesis may be enclosed within the membranous web. Similarly, replicase activity is insensitive to protease digestion unless solubilized by detergent, whereas most of the NS proteins are digested by this treatment . These data support the hypothesis that active replicase is bound by a limiting membrane and demonstrate that a vast excess of NS proteins are produced.