The BNT162b2 vaccine, containing lipid nanoparticles-formulated mRNA encoding the full-length spike protein of SARS-CoV-2, has been employed to immunize health care workers in Italy, administered in two doses 21 days apart. In this study, we characterized the antibody response induced by the BNT162b2 vaccine in a group of health care workers, tested at baseline, after the first dose and after the booster. Thirty-nine subjects without previous exposure to SARS-CoV-2 were vaccinated with the BNT162b2 vaccine. IgM, IgG, and IgA anti-receptor binding domain (RBD) were tested by ELISA. Neutralizing antibodies were evaluated testing the inhibition of RBD binding to ACE2. Antibody avidity was measured by urea avidity ELISA. IgM anti-RBD are produced after the first dose of vaccine and persist after the booster. IgG and IgA anti-RBD antibodies are detected in high amounts in all the subjects after the first dose and further increase after the booster. A few subjects, already after the first dose, produce antibodies inhibiting RBD interaction with ACE2. After the booster, high levels of inhibitory antibodies are detected in all the subjects. Affinity maturation takes place with boosting and IgG anti-RBD avidity increases with the number of immunizations. A less pronounced increase is observed with IgA. These data indicate that the BNT162b2 vaccine can induce high levels of protective antibodies of high avidity in vaccinated subjects; both IgG and IgA anti-RBD antibodies are produced. Further studies are needed to evaluate antibody persistence over time.
Several oncogenic viruses are profoundly immunosuppressive in vivo (1). The mechanism by which the suppression of immunocompetent cell function is brought about is not entirely clear. In view of the important role of suppressor cells in regulating normal immune response, attention has been focused recently on the possible role of suppressor cells in mediating oncornavirus-induced immunosuppression. In the Moloney sarcoma virus model, both B cells (2) and macrophages (3) have been ascribed a suppressor role. In the Friend virus (FV) ~ erythroleukemia model, it has been suggested that the leukemic cells themselves may act to suppress immune responses in vitro (4, 5).In the accompanying paper we presented evidence that FV, when added in yitro, can suppress the mitogenic response of T and B cells from mouse strains susceptible to FV leukemogenesis (6). Such mice are also extremely susceptible to the suppression ofT-and B-cell functions when infected by FV in vivo. Lymphoid cells from mice genetically resistant to FV leukemia and immunosuppression in vivo are resistant to FV-induced suppression of mitogenesis in vitro. This resistance has been shown to be abrogated when mice were treated with ~'Sr, which selectively destroys marrow-dependent (M) cells without affecting T-cell, B-cell, or macrophage functions (7,8).In this paper we have analyzed the mechanism by which FV suppresses T-and B-cell mitogenesis in vitro. We conclude that FV mediates its suppressive effect on T-and B-cell mitogenesis through a suppressor cell. The suppressor cell requires thymic influence for maturation, bears Thy-1 antigen, adheres to nylon wool, and is sensitive to lysis by cortisol. Such cells are present in the lymphoid tissues of mice susceptible to leukemogenesis in vivo and to in vitro suppression of mitogenesis induced by FV. In mice resistant to Friend leukemia, the suppressor cell function as tested in vitro seems to be lacking. Since treatment of resistant (Fv-2 rr) mice with s"Sr renders their lymphocyte mitogenesis suscepti-
ObjectivesIn patients with systemic autoimmune rheumatic disorders (SARDs), vaccination with SARS-CoV-2 mRNA vaccines has been proposed. The aim of this study is to evaluate the immune response elicited by vaccination with mRNA vaccine, testing IgM, IgA and IgG antibodies to SARS-CoV-2 receptor-binding domain (RBD) and measuring neutralising antibodies.MethodsIgG, IgM and IgA anti-RBD antibodies were measured in 101 patients with SARDs. Antibodies inhibiting the interaction between RBD and ACE2 were evaluated. Antibody avidity was tested in a chaotropic ELISA using urea. Twenty-one healthcare workers vaccinated with mRNA vaccine served as control group.ResultsAnti-RBD IgG and IgA were produced after the first dose (69% and 64% of the patients) and after the boost (93% and 83%). Antibodies inhibiting the interaction of RBD with ACE2 were detectable in 40% of the patients after the first dose and 87% after boost, compared with 100% in healthy controls (p<0.01). Abatacept and mycophenolate had an impact on the titre of IgG anti-RBD antibodies (p<0.05 and p<0.005, respectively) and on the amount of neutralising antibodies. No effect of other therapies was observed. Vaccinated patients produce high avidity antibodies, as healthy controls.ConclusionsThese data show that double-dose vaccination induced in patients with SARDs anti-RBD IgG and IgA antibodies in amounts not significantly different from controls, and, most interestingly, characterised by high avidity and endowed with neutralising activity.
Background Cancer patients are more vulnerable to COVID-19 and are thus given high priority in vaccination campaigns. In solid cancer patients treated with checkpoint inhibitors, we evaluated the amount of anti-RBD and neutralizing antibodies and antibody avidity after two or three doses of the vaccine. Methods Thirty-eight solid cancer patients, 15 untreated hematological patients and 21 healthy subjects were enrolled in the study. Blood was collected before the first dose (T0), 21 days after the second (T2) and in 18 solid cancer patients also 15 days after the third dose of vaccine (T3). IgG, IgM and IgA anti-RBD antibodies were detected by ELISA. Neutralizing antibodies were measured testing the inhibition of RBD binding to ACE2. Antibody avidity was evaluated in 18 patients by a urea avidity ELISA. Results IgG anti-RBD antibodies were produced in 65.8% of the cancer patients at T2, and in 60% of hematological patients at levels lower than healthy controls. IgM and IgA anti-RBD antibodies were also produced in 5.3% and 21% cancer patients, respectively. At T3, a significant increase in anti-RBD IgG levels was observed. Neutralizing antibodies were produced in 68.4% of cancer patients as compared with 93% of untreated hematological patients and 100% of controls, at titers lower than in healthy subjects. At T3, neutralizing antibodies and avidity of IgG anti-RBD increased; 6/18 patients negative at T2 developed neutralizing antibodies at T3. Conclusion The data indicate that in cancer patients mRNA vaccine induces high avidity anti-RBD antibodies and neutralizing antibodies that increase after the third dose. The process of induction and selection of high-affinity antibodies is apparently unaffected by the treatment with anti-PD-1 or anti-PD-L1 antibodies.
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