A Dendritic Cell Vaccine Pulsed with Autologous Hypochlorous Acid-Oxidized Ovarian Cancer Lysate Primes Effective Broad Antitumor Immunity: From Bench to Bedside

Mouse DCs efficiently process HOCl-oxidized lysate

ID8 murine ovarian tumor cell line transduced with ovalbumin (ID8-ova) was used to compare the efficacy of mouse DCs pulsed with whole tumor lysate prepared in 3 different ways: (i) HOCl oxidation followed by freeze-thaw (HOCl-L); (ii) UVB irradiation followed by freeze-thaw (UVB-L); and (iii) 6 cycles of freeze-thaw (FTL). Ovalbumin is chosen as the model antigen because it is a well-characterized research tool, which is readily available to assess immune responses. Mouse bone marrow-derived DCs were cocultured with these different lysates and matured with LPS and IFN-γ. DCs (gated on CD11c and MHC class II) were analyzed for crosspresentation of the MHC-I–restricted immunodominant epitope OVA_257–264 (SIINFEKL) using a specific antibody which recognized the SIINFEKL peptide bound to H-2K^b. Unpulsed DCs and DCs pulsed with the SIINFEKL peptides were used as controls. DCs pulsed with HOCl-L (**, P = < 0.001) and UVB-L (**, P = < 0.001) efficiently processed and presented the peptide SIINFEKL compared with unpulsed DCs (Fig. 1A). DCs pulsed with HOCl-L or UVB-L were equally efficient in presenting the SIINFEKL peptide (NS, not significant; Fig. 1A). All lysate-pulsed DCs produced IL-12p70 (data not shown).

HOCl-oxidized lysates yield improved DC vaccines

To test the efficacy of DCs pulsed with the different lysates, C56BL/6 mice were inoculated intraperitoneally with live ID8-ova tumor cells and allowed 3 weeks for tumor establishment. Mice were then vaccinated with DCs pulsed with HOCl-L, UVB-L, FTL, or SIINFEKL peptide, whereas control mice received unpulsed mDCs or PBS only. Some mice were sacrificed 2 weeks after vaccination (i.e. 56 days posttumor inoculation) for immune analysis, whereas groups of mice were followed for survival.

To determine whether DCs pulsed with whole tumor lysate were able to crosspresent and elicit T-cell responses against tumor-associated antigens, we cocultured splenocytes from vaccinated mice with live target ID8-ova cells at a 10:1 effector to target ratio. Mice vaccinated with HOCl-L DCs exhibited the highest mean number of IFN-γ–secreting T cells specific for ID8-ova cells (∼300 spots/10⁶ splenocytes) compared with mice vaccinated with DCs pulsed with UVB-L (∼125 spots/10⁶ splenocytes; *, P = <0.05) or FTL (∼120 spots/10⁶ splenocytes; *, P = < 0.05), unpulsed DCs (∼7 spots/10⁶ splenocytes; **, P = < 0.001), or PBS only (∼18 spots/10⁶ splenocytes; **, P = < 0.001) (Fig. 1B). To test whether these tumor-reactive T cells were directed towards OVA epitopes and also to additional tumor epitopes, we cocultured splenocytes from these mice with parent ID8 cells at the same effector to target ratio. We found that most of the IFN-γ tumor-reactive responses from mice in the HOCl-L–pulsed DC group seemed to be directed against OVA with very little reactivity against ID8 epitopes (Fig. 1B).

To verify the presence of T cells specific to OVA epitopes, we pulsed splenocytes with the SIINFEKL peptide. We found that HOCl-L–pulsed DCs elicited a relatively high frequency of SIINFEKL-reactive IFN-γ–secreting CD8⁺ T cells, which was comparable with those elicited by SIINFEKL peptide-pulsed DCs (NS, not significant; Fig. 1B). UVB-L–pulsed DCs elicited a similar number of SIINFEKL-reactive IFN-γ–secreting CD8⁺ T cells as HOCl-L–pulsed DCs, but FTL-pulsed DCs yielded a smaller frequency of such cells (*, P = <0.05 when compared with HOCl-L–pulsed DCs), in agreement with the relative ability of DCs to crosspresent the SIINFEKL peptide. The superior ability of HOCl-L–pulsed DCs to elicit SIINFEKL-specific CD8⁺ T cells was confirmed by pentamer staining (Supplementary Fig. S1A).

Given that whole tumor lysate potentially contains large number of potential epitopes for priming CD4⁺ and CD8⁺ T-cell responses, we investigated whether CD4⁺ tumor-specific IFN-γ–secreting T cells were also being elicited by the DC–whole tumor lysate vaccines. Using intracellular staining, we found that mice that were vaccinated with DCs pulsed with HOCl-L developed a higher percentage of CD4⁺ T cells that recognized and secreted IFN-γ in response to live ID8-ova cells (0.31%) compared with mice that were vaccinated with DCs pulsed with UVB-L (0.14%) or FTL (0.13%; Supplementary Fig. S1B). Vaccination of mice with DCs pulsed with HOCl-L stimulated significantly higher percentage of CD4⁺ T cells compared with vaccination with unpulsed DCs or PBS only (*, P = <0.05). Interestingly, higher frequencies of SIINKEFL-specific CD8⁺ and overall tumor-specific IFN-γ T-cell responses were also elicited in the mice that received DCs pulsed with HOCl-L (Fig. 1B and Supplementary Fig. S1A), suggesting that the development of stronger antitumor CD4⁺ T-cell responses by the DCs pulsed with HOCl-L might help in stimulating stronger overall antitumor T_H1 responses in this tumor model. Mice vaccinated with HOCl-L–pulsed DCs showed the lowest mean level of splenic Treg cells (9.61%), whereas mice that received UVB-L- or FTL-pulsed DCs had 14.45% (*, P = < 0.05) and 14.34% (*, P = < 0.05) splenic Treg cells, respectively (Fig. 1C, left). In addition, mice vaccinated with HOCl-L–pulsed DCs had no detectable IL-10 in sera, whereas mice receiving UVB-L–pulsed DCs (mean of 173.22 pg/mL; *, P = < 0.05) or FTL-pulsed DCs (mean of 54.67 pg/mL; *, P = < 0.05) had detectable serum levels of IL-10 (Fig. 1C, right). Mice receiving only PBS exhibited a mean 15.35% of splenic Treg cells and had detectable serum IL-10 (mean of 97.3 pg/mL; *, P = < 0.05).

To test the efficacy of vaccination in vivo, mice were followed for survival. Mice vaccinated with HOCl-L–pulsed DCs showed the longest overall survival, with median survival not reached at 180 days (60% alive at 180 days), whereas the median survival of all other groups was 78.5 days or less (P = 0.014; log-rank test; Fig. 1F). Interestingly, although strong responses against SIINFEKL were detected in mice vaccinated with DCs pulsed with SIINFEKL peptide or with UVB-L (Fig. 1B and C), this was insufficient for tumor control, and 80% and 100% of the mice from these groups, respectively, succumbed to ascites and tumor progression (Fig. 1D). Thus, HOCl-L–pulsed DCs were able to crosspresent tumor-associated immunodominant epitopes, elicited the highest frequency of IFN-γ–secreting tumor-reactive CD8⁺ and CD4⁺ T-cells, and achieved the best tumor response in vivo. This was also associated with a lower frequency of detectable splenic Treg cells and absence of serum IL-10. These results were encouraging and worthy of further clinical translation.

HOCl oxidation enhances the uptake of tumor lysate by human DCs

To define the optimal whole tumor lysate for clinical application, we compared the above three methods of whole tumor lysate preparation for pulsing human DCs—i.e., HOCl-L, UVB-L, and FTL. Because of the limited availability of PBMCs from ovarian cancer subjects, we evaluated PBMC-derived immature (i)DCs from normal donors to take up the different lysate preparations. We cocultured iDCs with HOCl-L, UVB-L, or FTL of SKOV-3 cells. DCs took up more HOCl-L compared with UVB-L or FTL (*, P = < 0.05) by 4 hours at 37°C (Fig. 2A). Passive transfer of tumor fragments to DC surfaces at 4°C was negligible, confirming that lysate uptake was an active process.

Following lysate uptake, DCs matured within 16 hours of stimulation with LPS and IFN-γ, as assessed by upregulation of HLA-DR, CD40, CD80, CD86, ICAM-1, and CCR7 to levels similar to those of control unpulsed mature (m)DCs stimulated with LPS and IFN-γ (Supplementary Fig. S2), which were significantly higher than baseline expression in control unpulsed iDCs. There were no significant differences among DCs pulsed with the 3 different lysate types.

Human DCs pulsed with HOCl-L produce high levels of T_H1-priming cytokines and chemokines and primed strong responses to ovarian tumor-associated antigen

We further characterized the cytokine and chemokine profiles of DCs from normal donors pulsed with tumor lysates of 3 ovarian tumor lines (i.e. SKOV-3, A1847, and OVCAR5; used at 1:1:1 ratio for DC loading). Culture supernatants were evaluated 8 hours after treatment with LPS and IFN-γ. HOCl-L–pulsed DCs produced higher levels of IL-12, MIP-1α, and MIG (100-fold, 20-fold, and 15-fold higher, respectively) when compared with unpulsed mDCs (Fig. 2B). It was noted that HOCl-L–pulsed DCs produced significantly higher level of IL-12 compared with UVB-L or FTL (*P = < 0.05) pulsed DCs (Fig. 2B). More than 2-fold increases were also detected in IL-1Ra, IL-1β, IL-15, IFN-α, IP-10, and RANTES in the HOCl-L–pulsed DC supernantants when compared with unpulsed mDCs (Fig. 2B). IL-10 secretion from HOCl-L–pulsed DCs was increased by about 2-fold but was very low compared with the 100-fold increase observed with IL-12, which is a T_H1-polarizing cytokine (Fig. 2B). A 2-fold increase in IL-8 level was also observed from HOCl-L–pulsed DCs; however, it was very low compared with the 100-fold increase in IL-12. No increase was seen with IL-6 and T_H2-priming cytokines such as IL-4, IL-5, and IL-13 from HOCl-L–pulsed DCs (data not shown). We did not assess TGF-β in our Luminex analysis. Comparable robust mixed leukocyte reactions (MLRs) were observed from DCs pulsed with HOCl-L, UVB-L, or unpulsed mDCs (Fig. 2C). Poor MLRs were observed from DCs pulsed with FTL or unpulsed iDCs. We further observed that DCs pulsed with HOCl-L made from SKOV-3 cells were more potent than DCs pulsed with UVB-L or FTL of SKOV-3 (P = 0.030) in priming IFN-γ production in naïve autologous normal donor T cells after 10 days of coculture. These primed T cells efficiently recognized live MDA-231 breast and OVCAR2 ovarian tumor lines that overexpressed HER-2/neu as well as HER-2/neu_369–377 peptide pulsed onto HLA-A2–expressing T2 lymphoblasts (compared with T cells primed with UVB-L- or FTL-pulsed DCs: *, P = <0.05; Fig. 2D). Low IFN-γ production was observed in the presence of unpulsed T2. Unpulsed mDCs [i.e., media (no antigen)] were used as control. In summary, human DCs pulsed with HOCl-L exhibited favorable lysate uptake and cytokine/chemokine profiles, stimulated robust MLRs and ovarian tumor reactivity, and were therefore suitable for clinical translation.

Autologous HOCl-L–pulsed matured DCs are suitable for therapy

We tested HOCl-L–pulsed DCs for vaccine production in a pilot study for recurrent ovarian cancer. Elutriated monocytes were obtained from PBMCs of the subjects after leukapheresis and cultured in cell factories with GM-CSF and IL-4 as described in Materials and Methods and in Supplementary Fig. S3. On day 4 of culture, DCs were pulsed with HOCl-oxidized autologous tumor lysate for 16 to 20 hours, followed by treatment with LPS and IFN-γ for 6 to 8 hours. On day 5, matured OCDCs were harvested and cryopreserved until clinical use.

To test the functionality of OCDC, vaccine aliquots from 5 subjects (S1–S5; see Table 1 for demographics of the subjects) were rapidly thawed, washed, and cultured in fresh complete CellGenix DC media for 24 hours without GM-CSF and IL-4. Culture supernatants were then analyzed by Luminex cytokine and chemokine array. Similar to fresh HOCl-L–pulsed DCs of normal donors, thawed OCDC produced high levels of T_H1-priming cytokines and chemokines such as IL-1Ra, IL-12, MIP-α, MIP-β, MCP-1, MIG, IP-10, RANTES, and TNF-α, and low levels of T_H2 cytokines such as IL-4, IL-5, IL-10, and IL-13 (Fig. 3). These results also indicated that cryopreservation did not affect the ability of OCDC vaccine to produce strong T_H1 proinflammatory cytokines and chemokines. A complete cytokine and chemokine analysis of each subject was presented in Supplementary Table S1.

OCDC vaccine is safe and may offer clinical benefit in subjects with advanced recurrent ovarian cancer

Five subjects (aged 48–63 years) were enrolled in UPCC-19809. The OCDC vaccine was tested and found to be negative for mycoplasma, bacteria, and fungi, contained <5 EU/mL endotoxin, and >70% CD86⁺ HLA-DR⁺ (see Supplementary Materials and Methods). The OCDC vaccine was also found to be free from residual HOCl solution (data not shown). The HOCl-oxidized whole tumor lysate was nontoxic to the DCs of the subjects as the DCs remained highly viable after lysate-pulsing, cryopreservation, and thawing (Supplementary Fig. S2, last column). Thus, the vaccine product met release criteria in all subjects (Table 1) and the yield of DCs was correlated with monocyte count derived from the leukapheresis (Supplementary Table S2). OCDCs were administered through direct injection into 1 to 2 groin lymph nodes bilaterally under ultrasound guidance. All subjects completed 5 vaccinations (Fig. 4A), except S1 who withdrew after 3 vaccinations due to disease progression. A total of 45 intranodal vaccinations were carried out. All vaccines were well tolerated and most toxicities were ≤grade 2 (Supplementary Table S3). A common side effect was flu-like symptomatology (i.e. fatigue, fever, and chills), which was attributed to systemic cytokine activation induced by the vaccine (see below) and possibly by any residual LPS that remained in the OCDC vaccine.

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Figure 4.

A, OCDC vaccine schedule of subjects. B, line graph showed regression or stabilization of 6 of 13 tumor metastatic deposits at 128 days (i.e. at EOS II) in subject S4 and CT imaging showed 3 additional nodules with central necrosis/cavitation (enlarged picture) at 128 days. C, taking into account the entire salvage treatment sequence of surgery, adjuvant therapy and ODCD, subject S2 experienced a second progression-free survival (PFS) of 36 versus an initial PFS of 26 months.

Three subjects (S1, S4, and S5) entered the study with radiographically measurable disease, and 2 subjects (S1 and S5) progressed, whereas one subject (S4) showed a mixed response by RECIST criteria at EOS. Subject S4 showed radiographic progression in 13 lesions at EOS (day 86) via CT (Fig. 4B). However, 6 weeks later, in the absence of additional therapy, she underwent repeat CT imaging (day 128; i.e. EOS II) and showed regression or stabilization of 6 of 13 tumor metastatic deposits. Interestingly, 3 additional nodules, which were measured as increased, at this time showed central necrosis (cavitation; Fig. 4B; see enlarged CT).

Two subjects (S2 and S3) entered the study with no evidence of disease after tumor recurrence, debulking surgery, and adjuvant chemotherapy. These subjects experienced durable progression-free intervals of 36 and 44 months. Both subjects achieved remission inversion [i.e., subjects experienced a longer second progression-free survival (PFS2) after vaccine therapy compared with the PFS after previous chemotherapy (PFS1)] in response to OCDC vaccination. PFS is important in assessing studies of novel chemotherapy or immunologic treatment strategies for patients with relapsed disease and was first used by Lee and colleagues to predict PFS2 in patients with relapsed acute myeloid leukemia (ref. 23; Fig. 4C). As the historic remission inversion rate (PFS2 > PFS1) in ovarian cancer is 3% (24), these results are encouraging given the propensity of recurrent ovarian cancer to commonly recur in shorter intervals than the previous remission interval.

OCDC vaccine elicits a tangible T_H1 antitumor immune response

We quantified tumor-specific T cells in pre- and postvaccine peripheral blood lymphocytes (PBL) by 40 hours IFN-γ ELISpot using aliquots of OCDC vaccine (DCs pulsed with autologous tumor lysate) as the antigen-presenting platform presenting whole tumor antigen. Unpulsed autologous DCs, developed exactly as OCDC (with GM-CSF/IL-4 followed by LPS/IFN-γ, except for lysate pulsing), were used as controls. We detected a significant increase in the frequency of tumor-reactive T cells after vaccination at EOS in subjects S1 (P = 0.044), S2 (P = 0.025 at EOS and P = 0.018 at 6 months post-EOS), S3 (P = 0.005), and S4 (P = 0.031), whereas all except subject S1 exhibited clinical benefit (Fig. 5A). We did not detect a significant increase in tumor-reactive T cells in subject S5 after vaccination (P = 0.312; NS).

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Figure 5.

Tumor-specific T cells were elicited in subjects following OCDC vaccination. A, PBMCs of the subjects from prevaccine and EOS were evaluated for IFN-γ–secreting cells in response to autologous DCs pulsed with autologous HOCl-oxidized lysate or to unpulsed autologous DCs. PBMCs alone were used as specificity control. The results were expressed as number of IFN-γ spots per 1 × 10⁵ human PBLs. B, PBMCs of the subjects taken from prevaccine and EOS were assessed for T_H1 (IFN-γ), T_H2 cytokines (IL-10, IL4, and IL-5), and IL-17. C, ratio of tumor-reactive IFN-γ–secreting CD3⁺ cells and Treg cells in PBMCs of the subjects pre- and postvaccinations. D, measurement of serum IL-10 in subjects at prevaccination and EOS.

In similar experiments as above, we characterized the cytokine profile of T cells at EOS by ex vivo stimulation with OCDC vaccine for 24 hours. OCDC vaccination induced strong T_H1 responses as assessed by the high levels of IFN-γ secreted by EOS T cells over 24 hours (Fig. 5B, first panel). Importantly, these EOS T-cells did not exhibit features of T_H2, T_H3, or T_H17 cells, as judged by the almost undetectable IL-4, IL-5, and IL-10, and very low levels of IL-17, respectively. Very low or undetectable levels of IFN-γ, IL-4, IL-5, IL-10, and IL-17 were observed from OCDC vaccines alone that served as controls (Fig. 5B; diagonal bar). The above results also indicated that the OCDC vaccine generated ex vivo were robust antigen-presenting cells as shown by their ability to stimulate strong tumor-specific IFN-γ secretions from T cells of subjects at EOS.

Treg cells have been associated with poor outcome in ovarian cancer (25) and experimentally depleting them has shown to be critical for tumor suppression (26). We measured the effects of vaccination on peripheral Treg cells. We observed a reduction in peripheral blood Treg cells at EOS in subjects S3, S4, and S5 (Supplementary Fig. S4A). We also determined the tumor-reactive IFN-γ–secreting CD3⁺ cells to CD3⁺CD4⁺CD25⁺FOXP3⁺ Treg cells ratio in the peripheral blood and observed a 1.5- to 3.6-fold increase in the ratio in subjects S2, S3, S4, and S5 at EOS. Subject S1 showed no change in the ratio (Fig. 5C, left). For subject S2, we followed T cells beyond EOS during maintenance vaccination and observed that peripheral Treg cells were decreased to approximately 2% at 6 months after vaccination (Supplementary Fig. S4B). At the same time, the number of IFN-γ–secreting tumor-reactive T cells in subject S2 was increased by 1.7-fold (Fig. 5A), resulting in a 7.5-fold increase in the tumor-reactive IFN-γ–secreting CD3⁺ cells to total peripheral Treg cell ratio (Fig. 5C, right). In summary, peripheral Treg cells were reduced in subjects S2, S3, S4, and S5 after OCDC vaccinations and during maintenance.

Finally, we characterized the serum cytokine changes after intranodal administration of OCDC vaccine. We detected a potent systemic inflammatory activation with 0.5-fold or more increase in serum IL-1β, IL-2, IL-15, TNF-α, MCP-1, MIP-1α, MIG, and eotaxin in at least 2 of 5 subjects (Supplementary Fig. S4C). There was no increase in T_H2-associated cytokines, including IL-4, IL-5, and IL-13 in the sera of all the subjects (data not shown). In particular, we observed decreases in serum IL-10 levels ranging from 0.24 to 2.28 pg/mL in subjects S1–S4 at EOS (Fig. 5D) who also showed tumor-reactive IFN-γ responses after OCDC vaccinations.

OCDC vaccine efficiently crosspresents and elicits polyclonal CD8⁺ responses to common ovarian cancer antigens

Ovarian cancers express a variety of well-characterized tumor-associated antigens (TAAs; refs. 27). To test whether such response was directed towards any known TAAs, we took advantage of the finding that subjects S3 and S4 were HLA-A*02-positive. We detected a postvaccine increase in T cells directed against several HLA-A2–restricted epitopes of known ovarian-specific antigens, including a MHC class II-restricted HER-2/neu epitope (S4; P = 0.045), as well as MHC class I-restricted epitopes of MUC-1 (S4; P = 0.047), NY-ESO-1 (S3; P = 0.033 and S4; P = 0.02), WT1 (S4; P = 0.001), mesothelin (S4; P = 0.008), survivin (S4; P = 0.041), and hTERT (S4; P = 0.016; Fig. 6A). Detection of these polyclonal tumor-specific CD8⁺ T-cell responses thus indicated that the OCDC vaccine was highly efficient in crosspresentation of the ovarian TAAs. We confirmed the increase in HER-2/neu 369-specific CD8⁺ T cells in subjects S3 and S4 after vaccination by tetramer analysis, and we expanded these cells when PBMCs taken at EOS were pulsed with HER-2/neu_369–377 peptide (Fig. 6B). Expressions of HER-2/neu, mesothelin, and WT1 were further confirmed by immunohistochemistry on prevaccine tumor sample for subject S4 (Fig. 6C).

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Figure 6.

OCDC vaccines were T_H1 priming and primed HER-2/neu–specific T cells that could be expanded ex vivo. A, PBMCs from HLA-A2⁺ subjects S3 and S4 were further tested for recognition to various HLA-A2–restricted ovarian TAAs. B, five rounds of OCDC vaccinations were able to prime HER-2/neu 369–specific CD8⁺ T cells that could further be expanded in vitro after 10 days of stimulation with HER-2/neu_369–377 peptide, IL-7, and IL-15 (10 ng/mL each). C, expression of various ovarian TAAs was confirmed in the primary tumor of subject S4 with immunohistochemistry. Asterisks indicate results that were significant at P < 0.05.