Virus-Inducible Gene Expression Changes In Mouse Brain : Studies With Japanese Encephalitis & Rabies Viruses

Saha, Saugata

08 1900

One of the key events in a virus-infected host cell is the activation and repression of a large number of host genes. In recent years, such differentially expressed host genes have been identified for several viruses, bacteria and parasites. Such studies indicate that reprogramming of host transcriptome during infection by a pathogen is a major component of host response and many of the reprogrammed genes may promote or prevent pathogen infection or may contribute to pathogen-induced pathological changes. Host gene expression changes have been studied for a number of viruses in cell lines. However, in case of neurotropic viruses which infect nonrenewable populations of central nervous system (CNS), changes in the host gene expression need to be studied in the intact host rather than cells grown in culture. Since such studies are reported only for a few neurotropic viruses, an attempt has been made in this thesis to identify and characterize genes that are differentially expressed in the mouse brain during infection by Japanese encephalitis virus (JEV) and rabies virus. Using subtraction hybridization technique, subtraction cDNA libraries were generated representing mRNAs that are induced or repressed in the mouse brain during JEV infection. Sequence analysis of the 350 isolated clones resulted in the identification of 73 unique genes. Out of these, 66 were of forward library clones (upregulated genes) and 7 of reverse library clones (downregulated genes). The forward library clones was clustered in different functional groups such as, proteins involved in immune response and interferon-inducible proteins, GTPase and GTP binding proteins, transcriptional regulators, enzymes, ribosomal proteins, neuronal proteins, carrier proteins, DNA-binding proteins, miscellaneous and proteins of unknown function. The differential expression of all these genes was further validated by northern blot analysis of brain RNA isolated from normal and JEV-infected mice, which indicate that out of 66 forward library clones 33 were genuinely upregulated in JEV-infected mouse brain, whereas all 7 reverse library clones were repressed in JEV infection. Since vaccination is known to prevent virus replication in the brain, host gene expression changes in mice immunized with BIKEN JE vaccine was also examined. There was a good correlation between inhibition of JEV replication and reduced expression of JEV-inducible CNS genes in the vaccinated mice. To check whether JEV-induced CNS genes identified in this study are specific to JEV or can be induced by any other neurotropic virus, expression patterns of 15 randomly chosen genes were checked in RV infected mouse brain. Results indicated that all the chosen genes are modulated in the same way during RV infection as well. Comparison of JEV-induced gene expression changes with those induced by other neurotropic viruses indicated that 83% of the JEV-inducible mouse CNS genes are also induced by Sindbis virus, a neurotropic virus of the family alphaviridae, indicating that despite diverse life cycles, these two viruses may activate common host signaling pathways. This study also led to the identification of 9 unique JEV-inducible genes (LRG-21, VHSV induced gene1, Tpt1, SLC25A3, Olfm1, Ina/NF-66, Dst/Bpag1, Mdm2 and Gbp5) which are not reported to be activated by any other neurotropic virus. Since it is beyond the scope of this study to characterize all the JEV-induced and repressed genes, two genes were chosen for a detailed analysis. These are: JEV-inducible gene encoding GARG-39 protein which is a member of the glucocorticoid attenuated response gene family and an unannotated, JEV-repressible gene designated in this study as clone # 137. The gene encoding GARG-39 identified as a JEV-inducible gene in this study was originally discovered as lipopolysaccharide- and interferon-inducible gene in macrophages. This protein contains tetratricopeptide repeat (TPR) motifs that are known to be involved in protein-protein interactions. However, the function of this protein remains unknown till date. Therefore the gene was cloned and over-expressed in E. coli and antibodies were raised against the recombinant protein. Western blot analysis revealed that GARG-39 protein is detectable only in JEV-infected but not in the normal mouse brain. Surprisingly, immunoflourescence studies carried out in NIH3T3 cells revealed that GARG-39 is localized in the cytosol of normal cells and it colocalizes with α-tubulin in the mitotic spindle in a small fraction of cells which are in the mitotic stage. Further, in an in vitro assay, GARG-39 was found to interact with taxol-stabilized tubulin polymers. Since microtubules are known to play an important role in virus assembly, it is possible that GARG-39 may have a role in virus assembly and maturation. Alternatively, microtubule-associated proteins are implicated in several neurodegenerative disorders including Parkinson’s, Alzheimer’s and mental retardation and therefore, a role for GARG-39 in virus-induced neuropathogenesis cannot be ruled out. In addition, the expression of GARG-39 in normal dividing cells in the culture indicates a role for this protein in mitosis. In a normal mouse brain, mitotically active cells are very low in number and hence GARG-39 expression (both at the RNA and protein levels) is below the detection limits. JEV infection may trigger mitotic activity in brain leading to increased expression of GARG-39. One of the cDNA clones identified in this study, designated as clone # 137, hybridized to a ~2.6 kb transcript which was found to be down regulated in the mouse brain by JEV as well as rabies virus. A series of investigations led to the conclusion that clone #137 corresponds to the 3′ end of a ~2.6 kb transcript encoding mouse calcium calmodulin kinase inhibitor II α (mCaMKIINα). Interestingly, only the α isoform but not the β isoform of mCaMKIINα mRNA is down regulated in the mouse brain during JEV infection. Since the physiological function of mCaMKIINα is not known, the gene encoding 8 kDa mouse mCaMKIINα open reading frame was cloned into an E. coli expression vector and antibodies were raised against the purified recombinant protein. Surprisingly, antibodies raised against the ~8 kDa recombinant mouse CaMKIINα reacted with a ∼37 kDa mouse brain protein. This protein designated as CaMKIINα-immunoreactive protein (CaMKIINα-IRP) is also down regulated during JEV infection and is localized in the post synaptic density (PSD) of normal mouse brain. In addition, distinct changes are also observed in the subcellular localization and phosphorylation of CaMKIIα leading to an increase in cytosolic CaMKII activity in JEV-infected mouse brain. The differential regulation of CaMKIIα and CaMKIINα during JEV infection suggests a possible role for CaMKII signaling pathway in JEV infection and/or JEV-induced neuropathogenesis in the CNS. Conclusions: • A number of host genes whose expression is modulated in the mouse brain during JEV and/or rabies virus infection have been identified. • One of the JEV-inducible genes encoding the GARG-39 protein was shown to be a microtubule-associated protein with a possible role in mitosis. • One of the JEV-repressible genes was found to encode the mouse CaMKIINα mRNA. • A novel JEV-repressible ∼37 kDa protein immunoreactive to antibodies raised against the recombinant CaMKIINα was identified in the post synaptic density of the mouse brain.

Virogenomics

Pathogen

Mouse Brain

Gene expression

Japanese Encephalitis

Rabies Viruses

JEV

GARG-39

Biochemistry

Genetic analysis of rabies and rabies-related viruses in southern Africa, with emphasis on virus isolates associated with atypical infection patterns

Jacobs, Jeanette Antonio

11 November 2005

The lyssavirus genus of the Rhabdovirus family is divided into seven genotypes. Genotype 3, Mokola virus, has only been found on the African continent, and has been reported to infect rodents, cats, dogs and humans. The first Mokola virus identification in South Africa was made in 1970, on the east coast of the KwaZulu-Natal province. After 25 years, Mokola virus was again identified in three cats, 650 km south-west of the previous isolation. In 1997 two more Mokola infections were identified in Pinetown, only about 23 km south-west of the 1970 isolation. Phylogenetic analysis of the nucleic acid sequences of the nucleoprotein gene region of the Mokola genome, indicated that the Mokola viruses from the same geographical region were more closely related, irrespective of the time of isolation. The identification of these two distinct clusters of Mokola in South Africa leads i us to believe that this virus is more widespread than previously thought, but that the reservoir host species remains to be identified. Genotype 1 in the Rhabdovirus family, rabies virus, is found on all continents, except Australia, New Zealand, Papua New Guinea, Japan, Hawaii, Taiwan, United Kingdom, Ireland, etc. An ongoing rabies enzootic in southern Africa is associated with two genetically distinct groups of viruses, called the canid biotype (infecting carnivores of the family Canidae) and the viverrid biotype (infecting carnivores of the subfamily Viverrinae). We identified the first cases of spillover of canid biotype virus into viverrid hosts, using monoclonal antibody and nucleic acid sequence analysis. Genetic analysis of the G-L intergenic region of the rabies virus genome, showed that these spillover events do not bring about any significant change on this part of the virus genome. All of these spillover isolates maintained a typical canid virus phylogeny. Rabies viruses associated with the family Viverridae form a highly diverse group of viruses, which can be divided into four distinct phylogenetic groups, each associated with a specific geographical area in South Africa. The canid biotype of rabies virus is divided into three specific groups, based on geographic location and the associated reservoir species, namely KwaZulu-Natal province (with domestic dogs as its main vector), the western parts of South Africa (bat-eared foxes) and the northern parts of South Africa (black-backed jackals). In order to determine the degree of genetic change in the virus over a period of time, we identified two endemic canid rabies regions (KwaZulu-Natal and the northern parts of South Africa) and analysed the nucleic acid sequence variation 0f the viruses over 15 years. Phylogenetic analysis of the variable G-L intergenic region of t e virus genome indicated that the canid rabies biotype changed less than 1% over the period studied. This implies that the highly diverse viverrid biotype has been circulating in the southern African wildlife for a very long time. In order to obtain a faster, more economical, and reliable method for rabies virus biotype identification, a competitive, hemi-nested PCR assay was developed. In a single tube, two biotype specific oligonucleotides (developed by Jaftha, 1997), and a common downstream primer were -used in the biotype specific, second round amplification. The specific virus biotypes were identified on the basis of specific amplicon sizes for each biotype. A third biotype specific primer was designed to target a region of the Nucleoprotein gene, this primer was used in a second round hemi-nested reaction. Despite having been designed to specifically amplify canid biotype viruses, this primer amplified all rabies biotypes non¬specifically. We conclude that the nucleoprotein genes are too conserved to make this part of the genome a good target for a biotype-specific PCR diagnostic assay. / Dissertation (MSc (Agric) Microbiology)--University of Pretoria, 1997. / Microbiology and Plant Pathology / unrestricted

Rabies virus biotypes south africa

Mokola virus south africa

Rabies epidemiology south africa

Rabies viruses south africa

Rabies history

Rabies vaccines

Rabies candid biotype kwazulu-natal sa

UCTD