Mapping and role of T cell response in SARS-CoV-2–infected mice

Virus-specific T cells play essential roles in protection against multiple virus infections, including SARS-CoV and MERS-CoV. While SARS-CoV-2–specific T cells have been identified in COVID-19 patients, their role in the protection of SARS-CoV-2–infected mice is not established. Here, using mice sensitized for infection with SARS-CoV-2 by transduction with an adenovirus expressing the human receptor (Ad5-hACE2), we identified SARS-CoV-2–specific T cell epitopes recognized by CD4+ and CD8+ T cells in BALB/c and C57BL/6 mice. Virus-specific T cells were polyfunctional and were able to lyse target cells in vivo. Further, type I interferon pathway was proved to be critical for generating optimal antiviral T cell responses after SARS-CoV-2 infection. T cell vaccination alone partially protected SARS-CoV-2–infected mice from severe disease. In addition, the results demonstrated cross-reactive T cell responses between SARS-CoV and SARS-CoV-2, but not MERS-CoV, in mice. Understanding the role of the T cell response will guide immunopathogenesis studies of COVID-19 and vaccine design and validation.

The Mysterious, and Potentially Revolutionary, Immunological Properties of Transfer Factor: A Review

Transfer factor is the name given to material derived from activated lymphocytes that is probably composed of a complex of a peptide and a short segment of RNA and which has the reported ability to transfer specific T cell immunity to uncommitted lymphocytes. Many independent groups around the world reported isolating transfer factors between 1955 and 1990 and demonstrating their ability to transfer passive immunity from one animal or individual to another, often within 24 hours of inoculation. Such activity is potentially revolutionary both in making T cell vaccines readily manufacturable and also because the existence of transfer factors would undermine the basic assumptions of the clonal selection theory, which currently dominates immunological theory. Unfortunately, lack of the microanalytical and synthetic techniques required to properly identify transfer factors, combined with safety factors associated with it derivation from blood sources susceptible to HIV and prion infections, put an end to transfer factor research after 1990. This paper reviews the evidence supporting transfer factor activity and suggests that this potentially revolutionary concept be resurrected and subjected to renewed scrutiny in light of CRISPR-Cas mechanisms and because of its potential to make possible T cell vaccination and provide a novel basis for understanding immunological function.

Rapid Generation of Medical Countermeasure Candidates Via Computational Variation Analysis

Rapid responses to emerging infectious diseases are needed for viral and bacterial pathogens. For some pathogens, no medical countermeasures (MCMs) yet exist. Pathogen heterogeneity and antigenic variation lead to immune response escape mutations for some pathogens (e.g., influenza) limiting the effectiveness of medical countermeasures. High throughput sequencing enables characterization of large numbers of pathogen isolates to which residue variation analysis can be applied to identify low variability targets. Multiple approaches are proposed that leverage these low variability targets as the first step of medical countermeasure development. Classes of MCMs informed by this approach include the following: DNA or RNA vaccines, both B-cell and T-cell vaccination strategies, anti-viral RNA targeting, antibody therapeutics, and aptamer targeting of viral protein complex interfaces as potential treatment strategies for infected individuals. Variation analysis-designed countermeasures targeting the Ebola glycoprotein are presented to illustrate the concepts for the proposed multiple targeted countermeasures.

CD8+ T-cell responses in vaccination: reconsidering targets and function in the context of chronic antigen stimulation

Cytotoxic CD8 T cells play important roles in eliminating infected and transformed cells. Owing to their potential for therapeutic applications, significant efforts are dedicated toward developing CD8 T cell–based vaccines. Thus far, CD8 T-cell vaccination strategies have had limited success therapeutically in contrast to those targeting antibody-based immunity. However, if the current challenges and gaps in the understanding of T-cell biology are overcome, the full potential of rational CD8 T-cell vaccine design might be realized. Here, we review recent progress in this direction, focusing on target selection and maintenance of function in the settings of chronic infections and cancers.

Live attenuated oral Salmonella platform for effective T- and B-cell targeting of PD-L1.

74 Background: Significant progresses have been recently achieved in cancer vaccines, yet novel immunization solutions to deliver efficiently tumor-associated antigens to professional antigen-presenting cells, and to overcome the peripheral tolerance and the immunosuppressive tumor microenvironment that prevent the eradication of cancer in most of patients, are urgently needed. VAXIMM is developing a unique and versatile oral T-cell vaccination platform based on the FDA-approved live-attenuated Salmonella Typhi strain Ty21a vaccine Vivotif, capable of delivering tumor-associated antigens encoded in DNA expression construct to the gut-associated lymphoid tissue, breaking immune tolerance and inducing effective anti-tumor immunity. Methods: This study summarizes the immunogenicity and antileukemia efficacy of VXM10 vaccines based on the live-attenuated Salmonella Typhimurium strain SL7207, transformed with a eukaryotic expression plasmid encoding different variants of the murine PD-L1 protein. Results: The antileukemia activity of VXM10 was evaluated in the FBL-3 disseminated model of leukemia, in which the tumor cells strongly express PD-L1. Multiple oral administrations of VXM10 vaccines produced a strong anti-tumor effect, with 100% of surviving animals 80 days after challenge with FBL3 leukemia in the highest dose groups. Moreover, 100% of long-term surviving mice resisted re-challenge with FBL-3 cells, demonstrating that vaccination with VXM10 generated a potent memory T cell response against the leukemia. Importantly, full leukemia control was achieved in both prophylactic and therapeutic settings. Upon immunization with VXM10 vaccines, T cell response was raised against PD-L1 epitopes after in vitro restimulation of the splenocytes, and anti-PD-L1 antibodies were detected in the serum. The precise mechanism of action of VXM10 vaccines is currently being investigated. Conclusions: This study provides further evidence that VAXIMM’s oral T-cell vaccination platform can be employed to stimulate anti-tumor immunity against antigens of the immune checkpoint regulatory protein PD-L1. These data paved the way for advancing the development of VXM10 into clinical development.

The Impact of T Cell Vaccination in Alleviating and Regulating Systemic Lupus Erythematosus Manifestation

Objective. Systemic lupus erythematosus (SLE) is an autoimmune disease identified by a plethora of production of autoantibodies. Autoreactive T cells may play an important role in the process. Attenuated T cell vaccination (TCV) has proven to benefit some autoimmune diseases by deleting or suppressing pathogenic T cells. However, clinical evidence for TCV in SLE is still limited. Therefore, this self-controlled study concentrates on the clinical effects of TCV on SLE patients. Methods. 16 patients were enrolled in the study; they accepted TCV regularly. SLEDAI, clinical symptoms, blood parameters including complements 3 and 4 levels, ANA, and anti-ds-DNA antibodies were tested. In addition, the side effects and drug usage were observed during the patients’ treatment and follow-up. Results. Remissions in clinical symptoms such as facial rash, vasculitis, and proteinuria were noted in most patients. There are also evident reductions in SLEDAI, anti-ds-DNA antibodies, and GC dose and increases in C3 and C4 levels, with no pathogenic side effects during treatment and follow-up. Conclusions. T cell vaccination is helpful in alleviating and regulating systemic lupus erythematosus manifestation.