Tristetraprolin expression and microRNA-mediated regulation during simian immunodeficiency virus infection of the central nervous system.

BACKGROUND: The RNA-binding protein tristetraprolin (TTP) participates in normal post-transcriptional control of cytokine and chemokine gene expression, dysregulation of which contributes to the HIV-associated neurocognitive disorders. Transcriptional and post-transcriptional regulation of TTP has been described, including regulation by microRNA-29a. In the simian immunodeficiency virus (SIV) model of HIV CNS disease, control of cytokine/chemokine expression coincides with the end of acute phase infection. This control is lost during progression to disease. In this study, we assessed TTP regulation and association with cytokine regulation in the brain during SIV infection. RESULTS: Quantitation of TTP expression over the course of SIV infection revealed downregulation of TTP during acute infection, maintenance of relatively low levels during asymptomatic phase, and increased expression only during late-stage CNS disease, particularly in association with severe disease. The ability of miR-29a to regulate TTP was confirmed, and evidence for additional miRNA targeters of TTP was found. However, increased miR-29a expression in brain was not found to be significantly negatively correlated with TTP. Similarly, increased TTP during late-stage disease was not associated with lower cytokine expression. CONCLUSIONS: TTP expression is regulated during SIV infection of the CNS. The lack of significant negative correlation of miR-29a and TTP expression levels suggests that while miR-29a may contribute to TTP regulation, additional factors are involved. Reduced TTP expression during acute infection is consistent with increased cytokine production during this phase of infection, but the increases in TTP observed during late-stage infection were insufficient to halt runaway cytokine levels. While antisense inhibitors of the post-transcriptional targeters of TTP identified here could conceivably be used further to augment TTP regulation of cytokines, it is possible that high levels of TTP are undesirable. Additional research is needed to characterize members of the miRNA/TTP/cytokine regulatory network and identify nodes that may be best targeted therapeutically to ameliorate the effects of chronic inflammation in retrovirus-associated CNS disease.

Herpesvirus infections of laboratory macaques.

Non-human primates (NHPs), primarily macaques, are commonly used as non-rodent species in pre-clinical safety assessment studies. The use of macaques in such studies is increasing largely due to the development of biopharmaceutical and immunomodulatory therapies that necessitates extensive safety testing. Macaques, commonly available for use in such studies, are infected by a rich flora of herpesviruses that cause persistent, latent, life-long infections. Primary infection of immune competent macaques is typically subclinical with very little associated morbidity and mortality only in very rare cases. A life-long consequence of herpesvirus infection is periodic stochastic and frequently asymptomatic recurrences from latency throughout an infected macaque's lifetime. With immune modulation or suppression, however, immune control of herpesvirus infections can be lost, resulting in significant disease and even death of the affected animals. Since macaques undergo primary infection with herpesviruses starting around 4-6 months-of-age when maternally-derived antibody begins to wane, it is difficult and costly to derive animals that are herpesvirus-free. Further, the herpesvirus flora and prevalence of infection in laboratory macaques mirrors that of the adult human population making the herpesvirus-infected macaque a reasonable model of the general human population. This review is intended to familiarize toxicologists performing preclinical drug safety studies with the basic biology, disease pathogenesis and consequences of immune suppression in herpesvirus-infected laboratory macaques.