Virus-induced immunosuppression

CD8 memory T cells: cross-reactivity and heterologous immunity

Virus-specific memory T cell populations demonstrate plasticity in antigen recognition and in their ability to accommodate new memory T cell populations. The degeneracy of T cell antigen recognition and the flexibility of diverse antigen-specific repertoires allow the host to respond to a multitude of pathogens while accommodating these numerous large memory pools in a finite immune system. These cross-reactive memory T cells can be employed in immune responses and mediate protective immunity, but they can also induce life-threatening immunopathology or impede transplantation tolerance and graft survival. Here we discuss examples of altered viral pathogenesis occurring as a consequence of heterologous T cell immunity and propose models for the maintenance of a dynamic pool of memory cells.

Virus-induced immunosuppression: immune system-mediated destruction of virus-infected dendritic cells results in generalized immune suppression

Despite the clinical importance of virus-induced immunosuppression, how virus infection may lead to a generalized suppression of the host immune response is poorly understood. To elucidate the principles involved, we analyzed the mechanism by which a lymphocytic choriomeningitis virus (LCMV) variant produces a generalized immune suppression in its natural host, the mouse. Whereas adult mice inoculated intravenously with LCMV Armstrong rapidly clear the infection and remain immunocompetent, inoculation with the Armstrong-derived LCMV variant clone 13, which differs from its parent virus at only two amino acid positions, by contrast results in persistent infection and a generalized deficit in responsiveness to subsequent immune challenge. Here we show that the immune suppression induced by LCMV clone 13 is associated with a CD8-dependent loss of interdigitating dendritic cells from periarteriolar lymphoid sheaths in the spleen and, functionally, with a deficit in the ability of splenocytes from infected mice to stimulate the proliferation of naive T cells in a primary mixed lymphocyte reaction. Dendritic cells are not depleted in immunocompetent Armstrong-infected mice. LCMV Armstrong and clone 13 exhibit differences in their tropism within the spleen, with clone 13 causing a higher level of infection of antigen-presenting cells in the white pulp, including periarterial interdigitating dendritic cells, than Armstrong, thereby rendering these cells targets for destruction by the antiviral CD8+ cytotoxic T-lymphocyte response which is induced at early times following infection with either virus. Our findings illustrate the key role that virus tropism may play in determining pathogenicity and, further, document a mechanism for virus-induced immunosuppression which may contribute to the clinically important immune suppression associated with many virus infections, including human immunodeficiency virus type 1.

Inhibition of antigen-induced and interleukin-2-induced proliferation of bovine peripheral blood leukocytes by inactivated bovine herpes virus 1

The mechanism by which bovine herpesvirus 1 (BHV-1) predisposes cattle to bacterial pneumonia was investigated by using an in vitro system to demonstrate immunosuppression. At a multiplicity of infection of 0.001, live or inactivated BHV-1 induced a 50% inhibition of the proliferative response of peripheral blood mononuclear leukocytes to antigen (vaccinia virus in vaccinia virus-immunized cattle which were BHV-1 negative) or interleukin-2. At this same multiplicity of infection, the mitogen-induced proliferation of peripheral blood mononuclear leukocytes was unaffected. This inhibition of antigen and interleukin-2-induced proliferative responses could not be reversed by the addition of excess amounts of interleukin-2 and could not be prevented by the addition of indomethacin to block prostaglandin production. Antibodies to BHV-1, especially those specific for glycoproteins gI and gIV, were able to block the inhibitory effect of BHV-1 in these in vitro assays. These results showed that antibody to BHV-1 blocks the immunosuppressive effect of the virus in vitro and suggested that an appropriate antibody response to BHV-1 could protect cattle from virus-induced immunosuppression leading to secondary bacterial pneumonia.