Broad Spectrum Algae Compounds Against Viruses

The pharmaceutical industry is currently trying to develop new bioactive compounds to inactivate both enveloped and non-enveloped viruses for therapeutic purposes. Consequently, microalgal and macroalgal bioactive compounds are being explored by pharmaceutical, as well as biotechnology and food industries. In this review, we show how compounds produced by algae include important candidates for viral control applications. We discuss their mechanisms of action and activity against enveloped and non-enveloped viruses, including those causing infections by enteric, parenteral, and respiratory routes. Indeed, algal products have potential in human and animal medicine.

B cell–derived IL-27 promotes control of persistent LCMV infection

Recent studies have identified a critical role for B cell–produced cytokines in regulating both humoral and cellular immunity. Here, we show that B cells are an essential source of interleukin-27 (IL-27) during persistent lymphocytic choriomeningitis virus (LCMV) clone 13 (Cl-13) infection. By using conditional knockout mouse models with specific IL-27p28 deletion in B cells, we observed that B cell–derived IL-27 promotes survival of virus-specific CD4 T cells and supports functions of T follicular helper (Tfh) cells. Mechanistically, B cell–derived IL-27 promotes CD4 T cell function, antibody class switch, and the ability to control persistent LCMV infection. Deletion of IL-27ra in T cells demonstrated that T cell–intrinsic IL-27R signaling is essential for viral control, optimal CD4 T cell responses, and antibody class switch during persistent LCMV infection. Collectively, our findings identify a cellular mechanism whereby B cell–derived IL-27 drives antiviral immunity and antibody responses through IL-27 signaling on T cells to promote control of LCMV Cl-13 infection.

Mild SARS-CoV-2 infection in rhesus macaques is associated with viral control prior to antigen-specific T cell responses in tissues

SARS-CoV-2 primarily replicates in mucosal sites, and more information is needed about immune responses in infected tissues. We used rhesus macaques to model protective primary immune responses in tissues during mild COVID-19. Viral RNA levels were highest on days 1-2 post-infection and fell precipitously thereafter. 18F-fluorodeoxyglucose (FDG)-avid lung abnormalities and interferon (IFN)-activated myeloid cells in the bronchoalveolar lavage (BAL) were found on days ~3-4. Virus-specific effector CD8 and CD4 T cells were detectable in the BAL and lung tissue on days ~7-10, after viral RNA, lung inflammation, and IFN-activated myeloid cells had declined. Notably, SARS-CoV-2-specific T cells were not detectable in the nasal turbinates, salivary glands, and tonsils on day 10 post-infection. Thus, SARS-CoV-2 replication wanes in the lungs prior to T cell responses, and in the nasal and oral mucosa despite the apparent lack of Ag-specific T cells, suggesting that innate immunity efficiently restricts viral replication during mild COVID-19.

Design, immunogenicity, and efficacy of a pan-sarbecovirus dendritic-cell targeting vaccine

The emergence of SARS-CoV-2 variants of concern (VOCs) that escape pre-existing antibody neutralizing responses increases the need for vaccines that target conserved epitopes and induce cross-reactive B- and T-cell responses. We used a computational approach and sequence alignment analysis to design a new-generation subunit vaccine targeting conserved sarbecovirus B- and T-cell epitopes from Spike (S) and Nucleocapsid (N) to antigen-presenting cells expressing CD40 (CD40.CoV2). We demonstrate the potency of CD40.CoV2 to elicit high levels of cross-neutralizing antibodies against SARS-CoV-2, VOCs, and SARS-CoV-1 in K18-hACE2 transgenic mice, associated with improved viral control and survival after challenge. In addition, we demonstrate the potency of CD40.CoV2 in vitro to recall human multi-epitope, functional, and cytotoxic SARS-CoV-2 S- and N-specific T-cell responses that are unaffected by VOC mutations and cross-reactive with SARS-CoV-1 and, to a lesser extent, MERS epitopes. Overall, these findings provide a framework for a pan-sarbecovirus vaccine.

Mathematical modeling suggests cooperation of plant-infecting viruses

Viruses are major pathogens of agricultural crops. Viral infections often start after the virus enters the outer layer of a tissue or surface and many successful viruses, after local replication in the infected tissue, are able to spread systemically. Quantitative details of virus dynamics in plants, however, have been poorly understood, in part, because of the lack of experimental methods allowing to accurately measure the degree of infection in individual plant tissues. Recently, by using flow cytometry and two different flourescently-labeled strains of the Tobacco etch virus (TEV), Venus and BFP, kinetics of viral infection of individual cells in leaves of {\it Nicotiana tabacum} plants was followed over time \cite{Tromas.pg14}. A simple mathematical model, assuming that viral spread occurs from lower to upper leaves, was fitted to these data. While the the original model could accurately describe the kinetics of viral spread locally and systemically, we also found that many alternative versions of the model, for example, if viral spread starts at upper leaves and progresses to lower leaves or when virus dissemination is stopped due to an immune response, provided fits of the data with reasonable quality, and yet with different parameter estimates. These results strongly suggest that experimental measurements of the virus infection in individual leaves may not be sufficient to identify the pathways of viral dissemination between different leaves and reasons for viral control; we propose experiments that may allow discrimination between the alternatives. By analyzing the kinetics of coinfection of individual cells by Venus and BFP strains of TEV we found a strong deviation from the random infection model, suggesting cooperation between the two strains when infecting plant cells. Importantly, we showed that many mathematical models on the kinetics of coinfection of cells with two strains could not adequately describe the data, and the best fit model needed to assume i) different susceptibility of uninfected cells to infection by two viruses locally in the leaf vs. systemically from other leaves, and ii) decrease in the infection rate depending on the fraction of uninfected cells which could be due to a systemic immune response. Our results thus demonstrate the difficulty in reaching definite conclusions from extensive and yet limited experimental data and provide evidence of potential cooperation between different viral variants infecting individual cells in plants.

The influence of the gut microbiota on influenza vaccine-induced immunity

<p>Currently, annual vaccination is widely considered the most effective method for preventing and controlling influenza virus infection. However, many individuals mount suboptimal immune responses to vaccination and the factors leading to poor immune responses are yet to be elucidated. Interestingly, it has been proposed that microorganisms that inhabit the intestinal tract, the gut microbiota, can profoundly influence many facets of the host immune system, including the strength of the immune response to influenza vaccination. In line with these observations, we observed that short-term administration of antibiotics drastically reduced influenza vaccine-specific antibody production. In particular, antibiotic treatment diminished the frequency and activation status of multiple myeloid cell subsets in the draining lymph nodes at steady-state and following vaccination, with associated impairments in B and TFH cell responses. Composition and function of gut microbiota communities can be rapidly altered through dietary changes. Therefore, the impact of potential prebiotic and probiotic nutritional interventions on the immune response to influenza vaccination and subsequent infection was assessed. No improvement in antibody responses to influenza vaccination was observed following the nutritional interventions studies. However, oral administration of a propolis formulation led to some improvement in viral control following infection. Collectively, this investigation indicates that alterations in microbial-associated signals leads to severe impairments in cellular responses crucial to humoral immunity and subsequent vaccine-induced antibody production. Furthermore, by altering the gut microbiota through dietary interventions, there is potential to improve immune responses to vaccination.</p>

The influence of the gut microbiota on influenza vaccine-induced immunity

<p>Currently, annual vaccination is widely considered the most effective method for preventing and controlling influenza virus infection. However, many individuals mount suboptimal immune responses to vaccination and the factors leading to poor immune responses are yet to be elucidated. Interestingly, it has been proposed that microorganisms that inhabit the intestinal tract, the gut microbiota, can profoundly influence many facets of the host immune system, including the strength of the immune response to influenza vaccination. In line with these observations, we observed that short-term administration of antibiotics drastically reduced influenza vaccine-specific antibody production. In particular, antibiotic treatment diminished the frequency and activation status of multiple myeloid cell subsets in the draining lymph nodes at steady-state and following vaccination, with associated impairments in B and TFH cell responses. Composition and function of gut microbiota communities can be rapidly altered through dietary changes. Therefore, the impact of potential prebiotic and probiotic nutritional interventions on the immune response to influenza vaccination and subsequent infection was assessed. No improvement in antibody responses to influenza vaccination was observed following the nutritional interventions studies. However, oral administration of a propolis formulation led to some improvement in viral control following infection. Collectively, this investigation indicates that alterations in microbial-associated signals leads to severe impairments in cellular responses crucial to humoral immunity and subsequent vaccine-induced antibody production. Furthermore, by altering the gut microbiota through dietary interventions, there is potential to improve immune responses to vaccination.</p>

Viral and Immunologic Factors Associated with Fatal Outcome of Patients with Severe Fever with Thrombocytopenia Syndrome in Korea

Significant progress has been made on the molecular biology of the severe fever with thrombopenia virus (SFTSV); however, many parts of the pathophysiological mechanisms of mortality in SFTS remain unclear. In this study, we investigated virologic and immunologic factors for fatal outcomes of patients with SFTS. We prospectively enrolled SFTS patients admitted from July 2015 to October 2020. Plasma samples were subjected to SFTSV RNA RT-PCR, multiplex microbead immunoassay for 17 cytokines, and IFA assay. A total of 44 SFTS patients were enrolled, including 37 (84.1%) survivors and 7 (15.9%) non-survivors. Non-survivors had a 2.5 times higher plasma SFTSV load than survivors at admission (p < 0.001), and the viral load in non-survivors increased progressively during hospitalization. In addition, non-survivors did not develop adequate anti-SFTSV IgG, whereas survivors exhibited anti-SFTSV IgG during hospitalization. IFN-α, IL-10, IP-10, IFN-γ, IL-6, IL-8, MCP-1, MIP-1α, and G-CSF were significantly elevated in non-survivors compared to survivors and did not revert to normal ranges during hospitalization (p < 0.05). Severe signs of inflammation such as a high plasma concentration of IFN-α, IL-10, IP-10, IFN-γ, IL-6, IL-8, MCP-1, MIP-1α, and G-CSF, poor viral control, and inadequate antibody response during the disease course were associated with mortality in SFTS patients.

An HLA-I signature favouring KIR-educated Natural Killer cells mediates immune control of HIV in children and contrasts with the HLA-B-restricted CD8+ T-cell-mediated immune control in adults

Natural Killer (NK) cells contribute to HIV control in adults, but HLA-B-mediated T-cell activity has a more substantial impact on disease outcome. However, the HLA-B molecules influencing immune control in adults have less impact on paediatric infection. To investigate the contribution NK cells make to immune control, we studied >300 children living with HIV followed over two decades in South Africa. In children, HLA-B alleles associated with adult protection or disease-susceptibility did not have significant effects, whereas Bw4 (p = 0.003) and low HLA-A expression (p = 0.002) alleles were strongly associated with immunological and viral control. In a comparator adult cohort, Bw4 and HLA-A expression contributions to HIV disease outcome were dwarfed by those of protective and disease-susceptible HLA-B molecules. We next investigated the immunophenotype and effector functions of NK cells in a subset of these children using flow cytometry. Slow progression and better plasma viraemic control were also associated with high frequencies of less terminally differentiated NKG2A+NKp46+CD56dim NK cells strongly responsive to cytokine stimulation and linked with the immunogenetic signature identified. Future studies are indicated to determine whether this signature associated with immune control in early life directly facilitates functional cure in children.

Two distinct mechanisms leading to loss of virological control in the rare group of antiretroviral therapy-naïve, transiently aviraemic children living with HIV

HIV-specific CD8+ T-cells play a central role in immune control of adult HIV, but their contribution in paediatric infection is less well-characterised. Previously, we identified a group of ART-naïve children with persistently undetectable plasma viraemia, termed ‘elite controllers’, and a second group who achieved aviraemia only transiently. To investigate the mechanisms of failure to maintain aviraemia, we characterized in three transient aviraemics (TAs), each of whom expressed the disease-protective HLA-B*81:01, longitudinal HIV-specific T-cell activity and viral sequences. In two TAs, a CD8+ T-cell response targeting the immunodominant epitope TPQDLNTML (‘Gag-TL9’) was associated with viral control, followed by viral rebound and the emergence of escape variants with lower replicative capacity. Both TAs mounted variant-specific responses, but only at low functional avidity, resulting in immunological progression. By contrast, in TA-3, intermittent viraemic episodes followed aviraemia without virus escape or a diminished CD4+ T-cell count. High quality and magnitude of the CD8+ T-cell response was associated with aviraemia. We therefore identify two distinct mechanisms of loss of viral control. In one scenario, CD8+ T-cell responses initially cornered low replicative capacity escape variants, but with insufficient avidity to prevent viraemia and disease progression. In the other, loss of viral control was associated neither with virus escape nor progression, but with a decrease in the quality of the CD8+ T-cell response, followed by recovery of viral control in association with improved antiviral response. These data suggest the potential for a consistently strong and polyfunctional antiviral response to achieve long-term viral control without escape. IMPORTANCE Very early initiation of antiretroviral therapy (ART) in paediatric HIV infection offers a unique opportunity to limit the size and diversity of the viral reservoir. However, only exceptionally is ART alone sufficient to achieve remission. Additional interventions are therefore required that likely include contributions from host immunity. The HIV-specific T-cell response plays a central role in immune control of adult HIV, often mediated through protective alleles such as HLA-B*57/58:01/81:01. However, due to the tolerogenic and type 2 biased immune response in early life, HLA-I-mediated immune suppression of viraemia is seldom observed in children. We describe a rare group of HLA-B*81:01-positive, ART-naïve children who achieved aviraemia, albeit only transiently, and investigate the role of the CD8+ T-cell response in the establishment and loss of viral control. We identify a mechanism by which the HIV-specific response can achieve viraemic control without viral escape, that can be explored in strategies to achieve remission.