SARS-CoV-2 Psychiatric Sequelae: A Review of Neuroendocrine Mechanisms and Therapeutic Strategies.

From the earliest days of the coronavirus disease 2019 (COVID-19) pandemic, there have been reports of significant neurological and psychological symptoms following Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) infection. This narrative review is designed to examine the potential psychoneuroendocrine pathogenic mechanisms by which SARS-CoV-2 elicits psychiatric sequelae as well as to posit potential pharmacologic strategies to address and reverse these pathologies. Following a brief overview of neurological and psychological sequelae from previous viral pandemics, we address mechanisms by which SARS-CoV-2 could enter or otherwise elicit changes in the CNS. We then examine the hypothesis that COVID-19-induced psychiatric disorders result from challenges to the neuroendocrine system, in particular the hypothalamic-pituitary-adrenal stress axis and monoamine synthesis, physiological mechanisms that are only further enhanced by the pandemic-induced social environment of fear, isolation, and socioeconomic pressure. Finally, we evaluate several FDA-approved therapeutics in the context of COVID-19-induced psychoneuroendocrine disorders.

Pathogenesis and treatment of HIV infection: the cellular, the immune system and the neuroendocrine systems perspective.

Infections with HIV represent a great challenge for the development of strategies for an effective cure. The spectrum of diseases associated with HIV ranges from opportunistic infections and cancers to systemic physiological disorders like encephalopathy and neurocognitive impairment. A major progress in controlling HIV infection has been achieved by highly active antiretroviral therapy (HAART). However, HAART does neither eliminate the virus reservoirs in form of latently infected cells nor does it completely reconstitute immune reactivity and physiological status. Furthermore, the failure of the STEP vaccine trial and the only marginal efficacies of the RV144 trial together suggest that the causal relationships between the complex sets of viral and immunological processes that contribute to protection or disease pathogenesis are still poorly understood. Here, we provide an up-to-date overview of HIV-host interactions at the cellular, the immune system and the neuroendocrine systems level. Only by integrating this multi-level knowledge one will be able to handle the systems complexity and develop new methodologies of analysis and prediction for a functional restoration of the immune system and the health of the infected host.

Elevated testosterone and reduced 5-HIAA concentrations are associated with wounding and hantavirus infection in male Norway rats.

Among rodents that carry hantaviruses, males are more likely to engage in aggression and to be infected than females. One mode of hantavirus transmission is via the passage of virus in saliva during wounding. The extent to which hantaviruses cause physiological changes in their rodent host that increase aggression and, therefore, virus transmission has not been fully documented. To assess whether steroid hormones and neurotransmitters contribute to the correlation between aggression and Seoul virus infection, Norway rats were trapped in Baltimore, Maryland and wounding, infection status, steroid hormones, and concentrations of neurotransmitters, including norepinephrine (NE), dopamine (DA), 3,4-dihydroxyphenol acetic acid (DOPAC), serotonin (5-HT), and 5-hydroxyindole-3-acetic acid (5-HIAA) in select brain regions were examined. Older males and males with high-grade wounds were more likely to have anti-Seoul virus IgG and viral RNA in organs than either juveniles or adult males with less severe wounds. Wounded males had higher circulating testosterone, lower hypothalamic 5-HIAA, and lower NE in the amygdala than males with no wounds. Infected males had higher concentrations of testosterone, corticosterone, NE in the hypothalamus, and DOPAC in the amygdala than uninfected males, regardless of wounding status. In the present study, wounded males that were infected with Seoul virus had elevated testosterone and reduced 5-HIAA concentrations, suggesting that these neuroendocrine mechanisms may contribute to aggression and the likelihood of transmission of hantavirus in natural populations of male Norway rats.

Androstenediol (AED) prevents neuroendocrine-mediated suppression of the immune response to an influenza viral infection.

The goal of these studies was to analyze the ability of androstenediol (AED) to counter-regulate the influences of stress on anti-viral immune responses. Male C57BL/6 mice, treated with 320 mg/kg AED were infected with influenza virus and subjected to repeated cycles of restraint (RST). AED blocked RST-mediated suppression of cell recruitment to the draining lymph node, lung NK cell activity, and CD4 + T cell activation. In addition, mice treated with AED had lower pre-corticosterone levels as compared to vehicle controls and the RST-mediated elevation of corticosterone was significantly blunted by AED treatment. These data suggest that AED functions to augment anti-viral immune responses by counter-regulating glucocorticoid function.

[Viruses and the neuroendocrine system: model of murine obesity induced by cerebral infection by canine distemper virus]. / Virus et système neuroendocrinien: modèle d'obésité murine induite après infection cérbrale par le virus de la maladie de Carré.

It is currently well established that the nervous, endocrine and immune systems inter-communicate using biologically active soluble factors, synthesised and produced by these three systems themselves (e.g. immunomodulator effect of hormones, effect of substances secreted by immune cells on endocrine function.). In addition, these systems jointly express receptors for hormones, peptides, growth factors and cytokines. Immuno-neuroendocrine interactions therefore underlie physiological processes and their deregulation can result in various pathological states. By entering into complex relationships with the specialized and differentiated cells of these three systems viruses can alter inter-cellular communication and result in the appearance of pathological processes directly linked to these disturbances. In order to understand the role of viruses in the genesis of neuroimmunoendocrine pathologies, we have developed a cerebral infection model using canine distemper virus (CDV). In infected mice, this paramyxovirus, closely related to the human measles virus, induces early neurological pathologies (encephalitis) which are associated with active viral replication. Mice surviving the acute phase of infection exhibit motor deficits (paralysis and turning behaviour) or obesity during the viral persistence phase, despite the fact that the virus is no longer detectable. The obesity is characterised by hyperinsulinaemia, hyperleptinaemia and hyperplasia of the adipocytes, associated with decreased expression of the OB-Rb hypothalamic leptin receptor and modulated expression of hypothalamic monoamines and neuropeptides. These results support the viral "hit and run" theory, since the initial viral impact in the hypothalamus may be the origin of the changes in later immunoneuroendocrine communication. Thus, certain human neurodegenerative or neuroendocrine diseases may have a previous viral infection aetiology without it being possible to clearly identify the agent responsible.

Rescue of HSV-1 neurovirulence is associated with induction of brain interleukin-1 expression, prostaglandin synthesis and neuroendocrine responses.

Several HSV-1 neurovirulence genes have been mapped but the mechanisms by which they affect host-virus interactions are not known. We have previously mapped HSV-1 neurovirulence to the UL53 gene region of the viral DNA by transfer of this gene from the neurovirulent R-19 strain to the non-neurovirulent R-15 strain in the generation of the p-71 recombinant, in which neurovirulence was rescued. In the present study we inoculated these strains into the paraventricular nucleus (PVN) of the hypothalamus of rats. We examined: (1) Clinical course of encephalitis. (2) Hypothalamic-pituitary-adrenocortical (HPA) axis function. (3) Brain cytokine gene mRNA expression and prostaglandin E2 (PGE2) production. (4) The relation of these parameters to viral replication and to cellular inflammation. In R-15 infected rats no signs of disease were observed. There was a temporary inflammatory reaction and IL-1 beta transcription in the PVN area. The function of the HPA axis was similar to control rats. Only slight increase in brain PGE2 production was found. In R-19 and p-71 infected rats, overt clinical signs of encephalitis and cellular inflammation in the PVN area were observed within 3 days post-infection (p.i). All rats died between 4-7 days p.i. These strains induced IL-1 beta transcription in the hypothalamus as well as in extra-hypothalamic brain regions in which no cellular inflammation was found. Basal serum ACTH and' CS were markedly elevated and hypothalamic CRF-41 content was significantly reduced as compared to R-15 infected rats. Both strains markedly increased brain PGE2 production. HSV-1 brain titers at 3 days p.i. were 100-fold lower than the inoculum titer although clinical signs of encephalitis were prominent. The results suggest that rescue of HSV-1 neurovirulence by the UL53 gene region of the viral genome is associated with enhancement of viral-induced brain IL-1 beta gene expression, increased brain PGE2 synthesis and hypersecretion of HPA axis hormones. Viral-induced brain derived cytokines and prostaglandins may contribute to the clinical syndrome of acute herpetic encephalitis in particular at early stages of the disease when virus load in the brain is low and cellular infiltrates are not widespread.