The SARS-CoV-2 Omicron variant has more than 15 mutations in the receptor binding domain of the Spike protein enabling increased transmissibility and viral escape from antibodies in vaccinated individuals. It is unclear how vaccine immunity protects against Omicron infection. Here we show that vaccinated participants at a super-spreader event have robust recall response of humoral and pre-existing cellular immunity induced by the vaccines, and an emergent de novo T cell response to non-Spike antigens. Individuals with Omicron SARS-CoV-2 breakthrough infections have significantly increased activated SARS-CoV-2 wild type Spike-specific cytotoxic T cells, activated follicular helper (TFH) cells, functional T cell responses, boosted humoral responses, and rapid release of Spike and RBD-specific IgG+ B cell plasmablasts and memory B cells into circulation. Omicron breakthrough infection affords significantly increased de novo memory T cell responses to non-Spike viral antigens. Concerted T and B cell responses may provide durable and broad immunity.
The new SARS-CoV-2 variant of concern (VOC) Omicron has more than 30 mutations in the receptor binding domain (RBD) of the Spike protein enabling viral escape from antibodies in vaccinated individuals and increased transmissibility. It is unclear how vaccine immunity protects against Omicron infection. Here we show that vaccinated participants at a superspreader event had robust recall response of humoral and pre-existing cellular immunity induced by the vaccines, and an emergent de novo T cell response to non-Spike antigens. We compared cases from a Christmas party where 81 of 110 (74%) developed Omicron breakthrough COVID-19, with Delta breakthrough cases and vaccinated non-infected controls. Omicron cases had significantly increased activated SARS-CoV-2 wild type Spike-specific (vaccine) cytotoxic T cells, activated follicular helper (TFH) cells, functional T cell responses, boosted humoral responses, activated anti-Spike plasmablasts and anti-RBD memory B cells compared to controls. Omicron cases had significantly increased de novo memory T cell responses to non-Spike viral antigens compared to Delta breakthrough cases demonstrating development of broad immunity. The rapid release of Spike and RBD-specific IgG+ B cell plasmablasts and memory B cells into circulation suggested affinity maturation of antibodies and that concerted T and B cell immunity may provide durable broad immunity.
Background Patients with high‐risk prostate cancer (PC) can experience biochemical relapse (BCR), despite surgery, and develop noncurative disease. The present study aimed to reduce the risk of BCR with a personalized dendritic cell (DC) vaccine, given as adjuvant therapy, after robot‐assisted laparoscopic prostatectomy (RALP). Methods Twelve weeks after RALP, 20 patients with high‐risk PC and undetectable PSA received DC vaccinations for 3 years or until BCR. The primary endpoint was the time to BCR. The immune response was assessed 7 weeks after surgery (baseline) and at one‐time point during the vaccination period. Results Among 20 patients, 11 were BCR‐free over a median of 96 months (range: 84–99). The median time from the end of vaccinations to the last follow‐up was 57 months (range: 45–60). Nine patients developed BCR, either during (n = 4) or after (n = 5) the vaccination period. Among five patients diagnosed with intraductal carcinoma, three experienced early BCR during the vaccination period. All patients that developed BCR remained in stable disease within a median of 99 months (range: 74–99). The baseline immune response was significantly associated with the immune response during the vaccination period (p = 0.015). For patients diagnosed with extraprostatic extension (EPE), time to BCR was longer in vaccine responders than in non‐responders (p = 0.09). Among 12 patients with the International Society of Urological Pathology (ISUP) grade 5 PC, five achieved remission after 84 months, and all mounted immune responses. Conclusion Patients diagnosed with EPE and ISUP grade 5 PC were at particularly high risk of developing postsurgical BCR. In this subgroup, the vaccine response was related to a reduced BCR incidence. The vaccine was safe, without side effects. This adjuvant first‐in‐man Phase I/II DC vaccine study showed promising results. DC vaccines after curative surgery should be investigated further in a larger cohort of patients with high‐risk PC.
AML is frequently diagnosed in elderly patients, with a median age of 69. Many older patients cannot tolerate intensive chemotherapy and/or stem cell transplantation, making curative treatment difficult and rates of early relapse high. Immunotherapy with dendritic cell (DC) vaccines after chemotherapy was shown by others to provide clinical benefit to some AML patients (van Tendeloo et al. 2010). Here we report results in four AML patients receiving DC vaccines targeting the antigens Wilm's tumor-1 (WT-1) and preferentially expressed antigen in melanoma (PRAME), applied in compassionate use, employing new generation monocyte-derived fast DCs, matured with a cocktail containing the TLR7/8 ligand R848. The mature DCs show high expression of CD83, strong up-regulation of HLA-DR and co-stimulatory molecules, down-regulation of CD14 and polarized release of IL-12p70, with no or low IL-10 secretion, upon T cell encounter. After informed consent and hematopoietic recovery from chemotherapy, mononuclear cells were collected by apheresis and mature DC vaccines were prepared to separately express full length mRNA encoding the two target antigens (Subklewe et al. Cancer Immunol. Immunother. 2014). DCs were administered intradermally, once weekly for 4 wks, at wk6 and then on a monthly basis. Blood and bone marrow (BM) samples were collected throughout treatment. Minimal residual disease (MRD) was measured in BM and blood by quantitative PCR of WT-1 expression and BM was monitored by morphology. Table 1 summarizes the salient features of the patients, treatment parameters, MRD monitoring and initial immune response assessment. DTH reactions were detected in all patients challenged with DCs at wk6. Immune responses of CD4 and CD8 T cells demonstrating intracellular interferon gamma (IFNg) expression were assessed by flow cytometry of PBL stimulated overnight with peptides spanning WT-1, PRAME, and hTERT and survivin as vaccine-unrelated antigens. Responses were scored positive when two-fold or greater frequencies of IFNg-expressing T cells were found compared to unstimulated controls. Patient (Pt.)CU030 and Pt.CU031 showed CD4 and CD8 responses to different test antigens. Pt.CU030 displayed strong and persistent CD8 responses to PRAME and a surprising increase in hTERT reactivity, potentially representing epitope spreading. The pt. continues to receive monthly vaccination and displays a low fluctuating WT-1 PCR signal in BM but no signal is seen in blood at wk61 after start of vaccination. Pt.CU031 displayed WT-1-specific immune responses until wk37 when responses decreased and WT-1 PCR signals increased in BM. The pt. developed Bell's palsy and immune responses were no longer detected after cortisone therapy. WT-1 signals then increased strongly in BM, accompanied by an increase of blasts. Pt. CU033 had no significant T cell response during 9 months (m) of vaccination. WT-1 signals now increase slowly in BM but relapse cannot be confirmed by morphology and WT-1 PCR remains negative in blood. Pt.CU040 has only received DC vaccines for 5 m, remains in morphological remission and immune response and MRD monitoring are ongoing. These results show that fast, TLR-polarized DCs induce or enhance specific T cell responses in elderly and undertreated AML patients, with individual strengths and specificities. Preliminary assessments suggest that changes in MRD are related to increase or loss of vaccine-associated immune responses. Table 1. Characteristics of AML patients receiving DC vaccines Patient CU030 CU031 CU033 CU040 Age 57 50 68 73 Sex f m f f AML Classification M4 M2 M1 M1 Risk Classification intermed intermed intermed good Chemotherapy cycles Induction/Consolidation 2/0 2/4 2/0 2/0 Time between chemo-therapy and vaccination 5 m 8 m 3 m 7 m Months of vaccination as of (08/2015) 16 m 10 m 9 m 5 m DTH responses at w6 toWT-1/PRAME DC challenge pos/pos pos/pos pos/pos pos/pos IFNg-positive T cell responses to overlapping peptides of WT-1, PRAME, hTERT, and Survivin Strong and persistent CD8 responses to PRAME and hTERT Early CD4 & CD8 responses to WT-1; decrease at wk37; full loss after cortisone therapy No significant responses detected up to wk33 To be done after acquisition of further samples MRD (WT-1 PCR) in BM/blood fluctuating low /neg rapid increase after cortisone /pos slow increase /neg ongoing BM morphology (most recent test) neg pos neg neg Time since completion of chemotherapy 21 m 18 m 12 m 12 m Disclosures Eckl: Medigene Immunotherapies GmbH: Employment. Schendel:Medigene Immunotherapies GmbH: Employment, Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties: for DC maturation cocktail. Kvalheim:Medigene Immunotherapies GmbH: Other: Scientific collaboration.
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