Host Defense Evasion Mechanisms of Rabies Virus: Difference between revisions

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==References==
==References==


[1] WHO Fact Sheet 99: Rabies. (2014, September 1). Retrieved November 10, 2014.
[1] [http://www.who.int/mediacentre/factsheets/fs099/en/ WHO Fact Sheet 99: Rabies. (2014, September 1). Retrieved November 10, 2014.]


[2] Schnell, M. McGettigan, J.P., Wirblich C., Papaneri, A. (2010). The cell biology of rabies virus:
[2][http://www.nature.com/nrmicro/journal/v8/n1/full/nrmicro2260.html Schnell, M. McGettigan, J.P., Wirblich C., Papaneri, A. (2010). The cell biology of rabies virus:using stealth to reach the brain. <i>Nature Rev Micro</i>, 8: 51-61.]
using stealth to reach the brain. <i>Nature Rev Micro</i>, 8: 51-61.


[3] Lafon, M. (2011) Evasive strategies in Rabies Virus Infection. In Jackson A.C (Ed.), <i>Advances in Virus Research</i> (pp. 33-55). Burlington, MA: Academic Press.
[3] [http://www.sciencedirect.com/science/article/pii/B9780123870407000032 Lafon, M. (2011) Evasive strategies in Rabies Virus Infection. In Jackson A.C (Ed.), <i>Advances in Virus Research</i> (pp. 33-55). Burlington, MA: Academic Press.]


Chai, Q., He, W.Q., Zhou, M., Lu, H., Fu, Z.F. (2014). Enhancement of Blood-Brain Barrier Permeability and Reduction of Tight Junction Protein Expression Are Modulated by Chemokines/Cytokines Induced by Rabies Virus Infection. JVI 88(9): 4698-4710.  
Chai, Q., He, W.Q., Zhou, M., Lu, H., Fu, Z.F. (2014). Enhancement of Blood-Brain Barrier Permeability and Reduction of Tight Junction Protein Expression Are Modulated by Chemokines/Cytokines Induced by Rabies Virus Infection. JVI 88(9): 4698-4710.  

Revision as of 20:53, 13 December 2014

Rabies Virus


Rabies virus (RABV) is a prototypical neurotropic virus and is often counted as one of the most deadly zoonotic diseases. Both wild and domestic animals can be afflicted with the disease and it is most commonly spread to humans via the saliva of an infected animal entering a bite wound or scratch. In Asia, most rabies infections are caused by rabid dogs. However in the Americas, and recently Australia and Western Europe, bat rabies has become a public health threat. Rabies is present on all continents except Antarctica, but the majority of rabies related deaths occur in Asia and Africa [1].

Figure 1. Rabies Risk Level assessed by the World Health Organization. Rabies has been found on all continents except Antarctica, but is mostly prevalent in Asia and Africa. (WHO fact sheet 99). Red areas are the levels with highest risk.Image taken from http://www.who.int/rabies/Global_Rabies_ITH_2008.png?ua=1 .

RABV infections occur mainly in remote, rural communities where measures such as vaccinating dogs to prevent animal to human transmission have not occurred. Due to lack of resources and preventative measures, 95% of rabies related human deaths occur in Africa and Asia. Most at risk populations generally do not have the ability to access nor the money for the rabies vaccine or post-exposure prophylaxis, turning a rabies infection into a death sentence [1]. Most patients survive for seven days after the onset of symptoms [2].

There are two main phylogroups of RABV which cause two distinct types of symptoms. Classical rabies, also known as furious rabies, causes 70% of animal and human infections while non-classical or paralytic rabies causes the remaining 30% of cases. Classical rabies is the more well-known strain and is characterized by symptoms such as hydrophobia, hallucinations, excited behavior, hyperactivity, and occasionally aerophobia. Paralytic rabies is less dramatic, as the patient’s muscles slowly become paralyzed with the paralysis radiating from the infection site. The patient eventually falls into a coma and dies. This non-classical form of rabies is often misdiagnosed, leading to an underrepresentation of the incidences of rabies [1][2]. Both forms of rabies cause death through cardiorespiratory arrest [1].

Great progress has been made in developing new rabies vaccines and preventative measures, but much of the molecular mechanisms of rabies virus remain a mystery. Improved genetic techniques that allow for direct manipulation of the rabies viral genome have given researchers a more detailed picture of rabies pathogenesis and a greater insight into virus-host cell interactions [2]. Understanding viral-host cell interactions are key to understanding how rabies virus is able to evade the host’s immune response and make its way from the site of infection to the central nervous system and the brain. A better understanding of these mechanisms could help improve neuronal labeling and nuerotracer studies and treatments for other central nervous system diseases [2].


Host Cell Mediated T-Cell Apoptosis

Figure 2. Expression of B7-H1 gene and protein in the mouse NS inthe course of RABV infection. A, Expression of B7-H1 (solid line) and RABV N (dotted line) transcripts were analyzed in noninfected (day 0) and day 5 and 10 RABV-infected spinal cord and brain by real time PCR. Results are given as mean SD of relative fold increase of transcripts detected in samples of two or three mice. In this experiment, a gene (Insulin Like Growth factor), whose expression was barely not modified by RABV infection, had the following relative fold increases in the spinal cord: x1 at day 0; x2 at day 5, and x1 at day 7; and in the brain: x1 at day 0 and 5, and x1.7 at day 7. B, Immunohistochemistry was performed in day-7 brain section. B7-H1 (red) was expressed by noninfected cells and by infected (green) neurons (arrows). A total of 70% of infected neurons were B7-H1 positive. Bars represent 10 um. (Lafon et al 2008)


T cells are the host’s method of controlling infections in the nervous system (NS). However, the T cell response in rabies victims is insufficient as it is inactivated by the virus [3].This inactivation was identified through immunohistochemical studies demonstrating that the host’s T cells were dying instead of the RABV infected neurons (cited in [3]). Infiltrating T cells have a difficult time in the NS as several neuropeptides and nuerotransmitters downregulate T cell activity [4]. Using attenuated RABV, it has been observed that infected brains upregulate expression of molecules such as somatostatin that are involved in limiting T cell activity in the NS [5]. However, it is important to note that attenuated and fatal strains of RABV act in different ways so whether the wild type encephalitic RABV elicits this response is uncertain.

Studies done in vitro and in vivo have shown that RABV uses an evasive strategy similar to that of tumor cells by upregulating certain surface molecules such as FasL and HLGA that trigger apoptosis in T cells [6][7]. It has been found that in mice lacking the functioning FasL ligand, there was a lower level of T-cell apoptosis in the NS compared to control mice. This reduction in T cell apoptosis is possibly a contributing factor to the lower rates of RABV morbidity and mortality in these mice.

In silico experiments lead Lafon et al. to believe that B7-H1 is also involved in RABV’s immunoevasive strategy [8]. B7-H1 is a ligand of programmed cell death 1 (PD-1) and ligation of these two proteins inhibits T cell proliferation and cytokine production, leading to a lower immune response (cited in [8]). In human neuroblastoma cell cultures, RT-PCR was used in conjunction with flow cytometry to demonstrate that not only is B7-H1 upregulated in RABV infected cells versus non-infected cells, but that the upregulation of B7-H1 also leads to more surface expression [8]. RT-PCR and immunohistochemistry performed using samples from RABV infected mouse models, provide an in vivo example in upregulation of B7-H1 in the NS (Fig 2). Figure 2A shows a correlation between a relative fold increase of B7-H1 and relative fold increase of RABV genome in both the spinal cord and brain of infected mice [8]. Transcripts were measured at day 0, 5, and 7, post infection to get an accurate representation of expression levels in non-infected (day 0), early stage (day 5), and late stage (day 7) infected cells. In the immunohistochemistry experiment, it was discovered that B7-H1 (red) was expressed not only by infected neurons (green), but by non-infected cells as well (Figure 2B). This allows for an even greater immunoevasive environment.

Lafon et al. also went on to find that without B7-H1, RABV mortality drops significantly [8]. B7-H1 knockout mice were created and infected with either a viral dose of 100 or 50. Viral doses were determined by the amount of virus needed to reach 100% or 50% mortality in wild type mice. Wild type mice behaved according to expectations, while B7-H1 knockouts had a 50% mortality rate with a viral dose of 100 and a 0% mortality rate at a viral dose of 50 [8]. Additionally, B7-H1 mice were spared some of the symptoms of encephalitis such as hunchback. These results suggest that RABV nueroevasiveness was hindered with the absence of B7-H1 [8].

Strikingly, B7-H1 expression is only activated by innate immune responses such as interferons (IFNs), tumor necrosis factor alpha (TNF-alpha), and Toll-like receptors (TLRs) [8]. Therefore, neural B7-H1 should require activation of the innate immune system to be upregulated. This seems slightly paradoxical, as an immune response is required to increase expression of a protein that is used to kill T cells, another aspect of immune response. RABV has been shown to induce a strong type I IFN response in addition to a robust chemoattractive and inflammatory response [9]. This response is likely the cause for upregulation of B7-H1 in non-infected astrocytes and neurons. However, the INF response is quickly dampened, making it seem more like a quick burst [8]. RABV is able to evade and subvert this response as it likely that it uses this opportunity to establish B7-H1 production to ward off T-cell in later stages of the infection.

RABV uses the immunosubversive molecules FasL and B7-H1 to protect against the host’s T-cells. Cells expressing FasL and B7-H1 trigger apoptosis pathways in T-cells expressing the Fas and PD-1 ligands upon binding. When the upregulation of these immunosubversive molecules is blocked, RABV virulence is drastically attenuated. However, these pathways cannot be turned on without an IFN response. Essentially, RABV hijacks systems already in place to create a more immunoevasive environment.

Prevention of Neuronal Apoptosis

Figure 3. Cells infected with VIR or ATT RABVs are characterized by attenuation-apoptosis or virulence neurosurvivalphenotypes, respectively. (A) Six 6-week-old female OF1 Swiss mice were injected in the hind limbs with VIR or ATT RABVs (1 × 107 PFU per 100 ml). Mortality was recorded daily and the Kaplan-Meier survival curves were established (P = 0.001 by log rank Mantel-Cox test). (B) Membrane permeation as a marker of apoptosis was measured in RABV-infected human neuroblastoma cells 48 hours after infection. Cell death is represented as a percentage of that in ATT-infected cells that represents 100% death.**P = 0.003, analysis of variance (ANOVA). N.I., not infected. (C to E) Assessment of neuronal survival in RABV-infected human neuroblastoma cells. (C) Measurement of the abundance of pAkt in cells 48 hours after infection. *P=0.001, Student t test. (D) The ability of RABV-infected cells (24 hours after infection) to undertake neurite growth was revealed by confocal microscopy analysis in which cells were labeled with an antibody against RABV nucleocapsid (green), an antibody against bIII neuronal tubulin (red), andHoechst 33342 to stain the nuclei. Top row, VIR-infected cells; bottom row, ATT-infected cells. (E) Sustained neurite outgrowth was assessed by measurement of the average length of neurites quantified at 24 hours after infection. *P < 0.0001, ANOVA. The data shown are representative of at least triplicate experiments. (Prehaud et al 2010)


While some neurotropic viruses such as West Nile virus or polio virus effectively kill motor neurons, RABV actively seeks to prevent neuronal degradation. RABV enters the NS through a neuromuscular junction or by passing through a synapse and utilizes the central nervous system as a transport system to the brain. Neuronal cell bodies, and possibly dendrites, are used for viral propagation and the virions travel in a retrograde direction towards the brain. Due to its dependence on neurons and the neuronal network, it would suggest that the virulence of RABV correlates to the survival of neurons (Lafon 2011). In fact, motor neurons of non-human primates infected with RABV showed no signs of degradation four days post infection (cited in Lafon 2011).

This prevention of apoptosis and axonal degradation is caused by the cytoplasmic form of the glycoprotein (G). In vitro RABV induced neuronal death is rare, however many laboratory created, attenuated strains induce neuronal apoptosis (Lafon 2011). The survival of the neuron and continued axonal growth depend on signaling cascades within the cell. PDZ domains are used in signal transferring and assemble and or regulate certain protein networks (Prehaud et al 2010, Lafon et al 2011). The RAVB G protein contains a PDZ-binding cite (PDZ-BS) in its C terminus. The only difference between two laboratory RABV strains, VIR and ATT, is in their G protein sequence. However, VIR is more virulent strain causing fatal encephalitis in mice and ATT is an attenuated strain. It has been suggested that the Gln to Glu mutation in the C terminus PDZ-BS in the ATT G protein is what causes the attenuated phenotype by inducing neuronal apoptosis. In vitro, VIR was able to prevent nueronal apoptosis and maintain axon and dendritic growth while ATT was not (Fig 4). Instead, ATT actually triggered apoptosis in infected cells (Fig4) (Prehaud et al 2010).

The different phenotypes stem from the different binding specificities of the two PDZ-BS. The G protein of the virulent strain only interacts with microtubule associated serine-threonine kinase 1 and 2 (MAST1 and MAST2 respectively) while the mutated G protein interacts with three unrelated PDZ binding partners, the most interesting of which is non-receptor protein tyrosine phosphate 4 (PTPN4). PTPN4 silencing has been suggested to trigger apoptosis, and it has been demonstrated that ATT G protein silences PTPN4. However, un-mutated G protein binding to MAST2 causes nuerite outgrowth (Prehaud et al 2010). The specificity of the G protein suggests that RABV walks a fine line de-activating some signaling cascades while leaving others intact.

Neuroinflammation and the Blood Brain Barrier


The NS intrinsically limits the inflammation response following injury; however inflammation is still triggered in the NS by most infections. In contrast to most encephalitic viruses, RABV triggers a more limited inflammation response. In fact the more pathogenic the strain is, the smaller the inflammatory response (Baloul and Lafon 2003). It is unclear how exactly RABV is able to limit the inflammatory response, but it has been suggested that the ability correlates to the differences between classical and non-classical strains. By comparing the amount of viral RNA and 18 cytokine mRNAs in twelve different brain regions of dogs infected with classical and non-classical rabies, Laothamatas et al (2008) was able to determine key differences in the inflammatory response triggered. The differences were found early on in infection, with non-classical RABV infected dogs having higher levels of interleukin-1beta and interferon-gamma and lower levels of viral RNA. Dogs infected with classical RABV had much higher levels of viral mRNA in brain tissue. Later in infection, there wasn’t much difference between the viral RNA and cytokine mRNA levels in dogs infected with the different strains (Laothamatas et al 2008). The increased nueroinvasiveness of the classical strain probably correlates to the decreased immune response in comparison with the non-classical strain. Strength of the nueroinflammitory response might also correlate to the permeability of the blood brain barrier (BBB).

Figure 4. Ingenuity pathway analysis of the immune response, regulatory networks, and pathways mediated by infection with CVS-B2c or DRV-Mexico. Data generated by the Luminex assay were analyzed with IPA software. One network of genes expressed in the brains of mice infected with CVS-B2c (A) and one network of genes expressed in the CNSs of mice infected with DRV-Mexico (B) were established. Nodes represent genes; their shapes represent the functional classes of the gene products (C); and arrows indicate the biological relationships between the nodes. The intensity of the node color indicates the degree of upregulation (red) in mice inoculated with either RABV. White (noncolored) nodes are nonfocus genes that are biologically relevant to the pathways but were not identified as differentially expressed by our Luminex analysis (Chai et al 2014)


The permeability of the BBB in rabies infection is important as permeability relates to host cell survival. A more permeable membrane leads to an increased chance of host survival as it allows for passage of more immune cells into the NS. It has been shown that BBB permeability is increased in laboratory attenuated strains of RABV but until Chai et al (2014) the underlying mechanisms were a mystery. By comparing expression of tight junction proteins in the brain microvascular tissue of mice infected with either wild type or lab attenuated RABV, Chai et al (2014) were able to determine that the enhancement of BBB permeability was associated more with the differences in chemokine/cytokine expression rather than the virus itself. Figure 4 shows the network of inflammatory chemokines and cytokines triggered by each strain. The network induced by attenuated strain (Fig4 A) contains 26 focus molecules while the wild type strain network (Fig 4B) only has 12. IFN-gamma is at the center of the network, which corresponds to the findings of Laothamatas et al (2008) and their non-classical strain induction of INF-gamma. Upon further investigation of INF-gamma’s role in BBB permiability, Chai et al. (2014) found that INF-gamma silencing causes a decrease in TJ and an increased permeability of the BBB.

Conclusion


RABV is has a two pronged strategy to in evading the immune system. First, RABV uses the host’s natural defense of the NS from excessive immune response to its advantage by upregulating the expression of surface proteins like B7-H1 that kill migratory T-cells that would bind to the neuron and trigger a large immune response and by keeping the blood brain barrier intact to prevent an overwhelming immune response. Secondly, RABV is able to protect infected neurons against premature apoptosis or dendrite/axonal degradation through signaling induced by its G protein. However, this strategy relies heavily on binding specificity of the G protein and most likely other viral proteins. If the fine balance created by the virus is thrown off, attenuation occurs and pathogenesis is reduced. Therefore, current research is focused more on the laboratory attenuated strains and what causes the attenuation. If cheaper more efficient vaccines and treatments can be created, then the threat of rabies can be diminished world-wide.

References

[1] WHO Fact Sheet 99: Rabies. (2014, September 1). Retrieved November 10, 2014.

[2]Schnell, M. McGettigan, J.P., Wirblich C., Papaneri, A. (2010). The cell biology of rabies virus:using stealth to reach the brain. Nature Rev Micro, 8: 51-61.

[3] Lafon, M. (2011) Evasive strategies in Rabies Virus Infection. In Jackson A.C (Ed.), Advances in Virus Research (pp. 33-55). Burlington, MA: Academic Press.

Chai, Q., He, W.Q., Zhou, M., Lu, H., Fu, Z.F. (2014). Enhancement of Blood-Brain Barrier Permeability and Reduction of Tight Junction Protein Expression Are Modulated by Chemokines/Cytokines Induced by Rabies Virus Infection. JVI 88(9): 4698-4710. Baloul, L., and Lafon, M. (2003). Apoptosis and rabies virus neuroinvasion. Biochimie 85(8):777–788.

Lafon, M., Megret, F., Meuth, S. G., Simon, O., Velandia Romero, M. L., Lafage, M., Chen, L., Alexopoulou, L., Flavell, R. A., Prehaud, C., and Wiendl, H. (2008). Detrimental contribution of the immuno-inhibitor b7-h1 to rabies virus encephalitis. J. Immunol. 180(11): 7506–7515.

Lafon, M., Prehaud, C., Megret, F., Lafage, M., Mouillot, G., Roa, M., Moreau, P., Rouas- Freiss, N., and Carosella, E. D. (2005). Modulation of HLA-G expression in human neural cells after neurotropic viral infections. J. Virol. 79(24):15226–15237.

Megret, F., Prehaud, C., Lafage, M., Moreau, P., Rouas-Freiss, N., Carosella, E. D., and Lafon, M. (2007). Modulation of HLA-G and HLA-E expression in human neuronal cells after rabies virus or herpes virus simplex type 1 infections. Hum. Immunol. 68 (4):294–302.

Niederkorn, J. Y. (2006). See no evil, hear no evil, do no evil: The lessons of immune privilege. Nat. Immunol. 7(4):354–359.

Prehaud, C., Wolff, N., Terrien, E., Lafage, M., Megret, F., Babault, N., Cordier, F., Tan, G. S., Maitrepierre, E., Menager, P., Chopy, D., Hoos, S., et al. (2010). Attenuation of rabies virulence: Takeover by the cytoplasmic domain of its envelope protein. Sci. Signal. 3(105):ra5.



Edited by Alexandra Gonzales, student of Joan Slonczewski for BIOL 375 Microbiology, 2014, Kenyon College.