ABSTRACT
Background: The kinetics and functional profiles (granzyme-B production) of HIV-specific T-cell responses support that those targeting the early viral gene product Nef disproportionately recognize residual antigen expression during long-term antiretroviral therapy (ART). Here, we leveraged this insight to test whether SARS-CoV2 mRNA vaccines-which activate TLR and inflammatory signaling pathways-would reactivate latent HIV, stimulating T-cell responses with these characteristics. Methods: T-cell responses to individual HIV gene products were measured by IFN-g or granzyme B ELISPOT, and by activation induced marker (AIM) assays at baseline and ∼2 weeks after SARS-CoV-2 mRNA vaccine prime and boost, in 13 long-term ART treated adults. Total and unspliced HIV mRNA, as well as intact and defective (IPDA) HIV DNA were measured in parallel by digital droplet PCR (ddPCR). Results: We observed transient increases Nef-specific T-cell responses following vaccine prime by granzyme B ELISPOT (3.1-fold increase, p=0.002) and a trend by AIM assay (1.5-fold increase, p=0.06). Such increases were not observed in granzyme B responses to late gene products nor in any IFN-g responses. Both unspliced and total HIV mRNA decreased significantly across the study, unspliced-1.6-fold decrease p = 0.03;total-1.5-fold decrease p = 0.05. Changes in total HIV mRNA correlated inversely with Nef-specific granzyme B-producing (spearman's ρ =-0.73, p = 0.006) and Nef-specific CD8+ AIM T-cell responses (ρ =-0.76, p = 0.006) following vaccine prime. These reductions in HIV RNA were not accompanied by significant changes in total or intact HIV DNA. Conclusion: Consistent with our hypothesis, a restricted profile of HIV-specific T-cell responses showed significant increases following SARS-CoV-2 vaccine prime, each of which were then correlated with reductions in HIV RNA. This supports that vaccination promoted productive interactions between Nef-specific CTL and HIV-infected cells in vivo. We propose three scenarios for why this was not reflected in reductions in intact or total HIV DNA: i) meaningful depletions in inducible proviruses occurred but were lost against the background of non-inducible proviruses ii) interactions with CTL involved only a fraction of inducible proviruses, or iii) substantive proviral depletions occurred, but were counterbalanced by clonal expansion of HIV-infected cells.
ABSTRACT
Background: The coronavirus-19-disease (COVID-19) pandemic caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has spread to >200 countries and surpassed 7 million cases. There is a broad range of COVID-19 illness, ranging from milder disease to a rapidly progressive respiratory disease and ARDS. The causes of this different clinical course and the drivers for severe disease are currently unknown. A fulminant increase of pro-inflammatory cytokines is thought to play a role in causing a rapid disease evolution, however the immune correlates of severe COVID-19 remain unclear. Methods: To gain insight into relationship between immune responses and disease severity we built a longitudinal cohort of 40 adult patients with known COVID- 19. Samples were collected at diagnosis and every 7 days until hospital discharge or death. As controls we also included a group of convalescent patients, and subjects who tested negative for COVID-19 by PCR. Clinical and laboratory data and were also collected. Multicolor flow cytometry was used to determine the presence and phenotype of B, T and natural killer (NK) cells. We also identified specific sub-populations (Tfh, activated/cytotoxic CD8 and NK) and assessed lymphoid exhaustion of different cell types such as naïve, memory T cells, or NK over time. Anti-Sars-CoV2 IgG and IgM antibody were detected using lateral flow method. Results: We found that the absolute number of lymphocytes and monocytes was decreased starting at diagnosis and correlated with disease severity. Disease severity correlated with decreased NK and T cell. In severe COVID-19 cases, NK cell populations were strongly decreased over time in intubated patients while they recovered in patients who improved and were discharged. CD8+ were also decreased at disease onset and seemed to correlate with disease severity. A high percentage of CD4+ and CD8+ T cells showed an exhausted phenotype. All patients tested at admission had IgM antibody responses irrespective of the course of the disease. Further analyses are ongoing. Conclusion: The characterization and role of the immune responses in COVID- 19 evolution is still under investigation. Further characterization of viral and immune factors will help in identifying subjects at high risk of severe disease and targets for intervention.