A phase 1b single-arm trial of intratumoral oncolytic virus V937 in combination with pembrolizumab in patients with advanced melanoma: results from the CAPRA study

Background CAPRA (NCT02565992) evaluated Coxsackievirus A21 (V937) + pembrolizumab for metastatic/unresectable stage IIIB–IV melanoma. Methods Patients received intratumoral V937 on days 1, 3, 5, and 8 (then every 3 weeks [Q3W]) and intravenous pembrolizumab 2 mg/kg Q3W from day 8. Primary endpoint was safety. Results Median time from first dose to data cutoff was 32.0 months. No dose-limiting toxicities occurred; 14% (5/36) of patients experienced grade 3‒5 treatment-related adverse events. Objective response rate was 47% (complete response, 22%). Among 17 responders, 14 (82%) had responses ≥ 6 months. Among 8 patients previously treated with immunotherapy, 3 responded (1 complete, 2 partial). Responses were associated with increased serum CXCL10 and CCL22, suggesting viral replication contributes to antitumor immunity. For responders versus nonresponders, there was no difference in baseline tumor PD-L1 expression, ICAM1 expression, or CD3+ infiltrates. Surprisingly, the baseline cell density of CD3+CD8− T cells in the tumor microenvironment was significantly lower in responders compared with nonresponders (P = 0.0179). Conclusions These findings suggest responses to this combination may be seen even in patients without a typical “immune-active” microenvironment. Trial registration number NCT02565992. Supplementary Information The online version contains supplementary material available at 10.1007/s00262-022-03314-1.


Introduction
Oncolytic viruses represent a novel therapeutic modality for the treatment of cancer, and several have been or are currently being investigated as potential immunotherapies in patients with various types of cancers [1]. Oncolytic viruses are thought to mediate antitumor activity via two distinct mechanisms: direct cancer cell lysis and activation of a systemic antitumor immune response [2]. Talimogene laherparepvec, a genetically modified herpes simplex virus 1, was the first oncolytic virus to gain regulatory approval; it is indicated for the local treatment of unresectable lesions in patients with melanoma that recurred after initial surgery [3]. Coxsackievirus is an RNA virus that is associated with mild, common cold-like upper respiratory symptoms [4]. Coxsackievirus A21 (previously referred to as CVA21 or Cavatak; now referred to as V937) is a bioselected genetically unmodified strain that is oncolytic [5]. It enters cells via binding to intracellular adhesion molecule 1 (ICAM-1) and decay-accelerating factor (DAF) receptors [6], both of which are highly expressed on the surface of melanoma cells [7,8].
In preclinical studies, V937 demonstrated rapid oncolysis of in vitro melanoma cell cultures and in vivo melanoma xenografts in immunodeficient mice [7,8]. Notably, 1 3 antitumor activity was observed at sites distant from the site of intratumoral administration [7,8]. In the phase 2 CAvatak in Late-stage Melanoma (CALM) study [5], 57 patients with stage IIIC to IVM1c melanoma were treated with multiple doses of intratumoral V937. The 6-month progression-free survival (PFS) rate, the primary endpoint, and objective response rate (ORR) were both 38.6%, and 21.1% of patients achieved a durable complete or partial response lasting ≥ 6 months. Regression of melanoma was seen in injected lesions as well as noninjected lesions, consistent with induction of a systemic antitumor immune response. Treatment was well tolerated in the study, with no patients experiencing treatment-related adverse events (AEs) of grade ≥ 3.
Pharmacodynamic effects of oncolytic viruses in the tumor microenvironment, including increased interferon production, CD8 + T cells, and programmed death ligand 1 (PD-L1) expression [9] and reduced suppressor T-cell populations [10], suggest the potential for improved responses when combined with immune checkpoint inhibitors such as those targeting programmed death 1 (PD-1)/PD-L1 or cytotoxic T-lymphocyte antigen 4 (CTLA-4). Preliminary evidence from the phase 1b Melanoma Intra-Tumoral Cavatak and Ipilimumab (MITCI) study showed that the combination of intratumoral V937 and the anti-CTLA-4 monoclonal antibody ipilimumab was not associated with any dose-limiting toxicities (DLTs) in 23 patients with stage IIIC to IVM1c melanoma [11]. An ORR of 50% by investigator assessment was reported among the 18 patients evaluated for response, which suggests at least an additive effect with the combination. Similar to the V937 monotherapy experience, responses were seen in both injected and noninjected lesions [11].
The anti-PD-1 monoclonal antibody pembrolizumab is a standard-of-care therapy for patients with advanced melanoma. In the phase 3 KEYNOTE-006 study, which included 834 patients with metastatic melanoma (65% were stage IVM1c), pembrolizumab demonstrated superiority over ipilimumab with respect to the dual primary endpoints of PFS and overall survival (OS), with less high-grade toxicity [12]. The benefit of pembrolizumab was maintained over 5 years of follow-up [13]. The phase 1b CAvatak and PembRolizumab in Advanced melanoma (CAPRA) study (Protocol VLA-011; NCT02565992) evaluated the safety, efficacy, and correlative biomarker results associated with the combination of intratumoral V937 and intravenous pembrolizumab in patients with advanced melanoma.

Study design and patients
CAPRA was a phase 1b, multicenter, open-label, single-arm study. Eligible patients were ≥ 18 years old and had histologically confirmed metastatic or unresectable stage IIIB to IV melanoma, according to the American Joint Committee on Cancer 7th edition [14,15]. Patients also had ≥ 1 cutaneous or subcutaneous tumor or palpable lymph node amenable to intratumoral injection; an Eastern Cooperative Oncology Group (ECOG) performance status of 0 or 1; and adequate hematologic, hepatic, and renal function.
Prior T-cell checkpoint antibody therapy in the adjuvant or the metastatic setting was permitted. Use of chemotherapy, radiation therapy, hormonal treatment, or immunotherapy within 28 days before initiation of study treatment or previous receipt of V937 was prohibited. A complete list of the inclusion and exclusion criteria for the study can be found in the Supplementary Material (see Protocol). The protocol was approved by an appropriate institutional review board or independent ethics committee at each center, and the study was conducted in accordance with local laws, Good Clinical Practice guidelines, and the Declaration of Helsinki. All patients provided written informed consent.

Treatment
Patients were treated with intratumoral V937 on days 1, 3, 5, and 8 and then every 3 weeks for up to 19 sets of injections. At each injection visit, the maximum dose of V937 administered was 3 × 10 8 50% tissue culture infectious dose (TCID 50 ; approximately 4.5 × 10 6 TCID 50 per kg for a 70-kg patient) in a maximum volume of 4.0 mL. The volume could be reduced below 4 mL, with a consequent reduction in dose, if too few lesions of sufficient size were available to inject. Multiple lesions were injected at each injection visit if possible. Lesions > 25 mm in diameter were injected first (2.0 mL volume), followed by lesions 15 to 25 mm in diameter (1.0 mL volume) and then lesions 5 to < 15 mm in diameter (0.5 mL volume). After the initial injection of V937, any injected lesion that decreased to < 5 mm in diameter was injected with 0.1 mL volume. Tumor diameter was measured using a ruler/calipers or calipers on ultrasound. After administration of V937, the injection site was wiped with sterile tissue, and an occlusive dressing was applied to completely cover the injection site.
Patients also received intravenous pembrolizumab (2 mg/kg solution) starting on day 8 and continuing every 3 weeks for up to 2 years or until complete response, disease progression, or intolerable toxicity, whichever occurred first.
On days in which patients received both V937 and pembrolizumab, V937 was administered first.

Assessments and endpoints
Adverse events and DLTs were assessed based on the National Cancer Institute Common Terminology Criteria for Adverse Events, version 4.03. AEs were assessed from the time of initiating study treatment through 30 days after cessation of study treatment. DLTs were defined as any grade ≥ 3 toxicity related or possibly related to V937 with onset on or before the day 92 visit, except for lymphopenia, which was not considered a DLT.
Disease status was assessed every 6 weeks by computed tomography or magnetic resonance imaging. Response and progression were evaluated using immune-related response criteria derived from modified World Health Organization criteria, as previously described [16,17].
Optional melanoma tumor biopsy samples were obtained at screening by incisional, excisional, or punch biopsy; archival tissue could be used in place of a fresh biopsy sample. Tumors selected for biopsy could have been target or nontarget lesions; target lesions had to be > 20 mm in total size, and sample collection could not affect the longest diameter for purposes of tumor assessment. Biomarker analyses performed on these tumor samples included NanoStringbased interrogation of gene expression with the PanCancer IO 360™ Panel (NanoString, Seattle, WA, USA) and multiplex IHC (Supplementary Table S1). In addition, Luminex cytokine analysis was performed on day 1 and day 29 paired serum samples with a 48-plex human Cytokine/ Chemokine/Growth Factor Panel A (Millipore Sigma, Burlington, MA) analyzed on a Luminex 2000 analyzer (Luminex Corporation, Austin, TX). Serum V937 levels, based on polymerase chain reaction, were assessed during the first 2 years of treatment (at every study visit through week 46, at week 52, and every 12 weeks thereafter). Anti-V937 antibody titers were also evaluated during the first 2 years of treatment (at baseline, week 4, week 22, every 3 weeks through week 46, at week 52, and every 12 weeks thereafter).
The primary endpoints were the occurrence of AEs, serious AEs, and DLTs. Secondary endpoints were ORR, PFS, OS, and duration of response. Biomarkers were an exploratory endpoint.

Statistical analyses
As described in detail in the Supplementary Material (see Protocol), a Simon's 2-stage design was used for sample size justification for ORR. The historical response rate was assumed to be 28% [5]. With 45 patients, the design yielded a 1-sided α = 0.05 level of significance with 90% power to detect a difference when the true ORR was 50%. The total sample size was estimated to be 50 patients to account for those who may not complete the postbaseline lesion assessment. However, study enrollment was stopped early because of prioritization of sponsor resources.
Safety and efficacy analyses were performed in all patients who received treatment. Biomarker analyses, performed in all patients with data available, are exploratory; P values were based on Welch's t test (unequal variance). For ORR analysis, 95% CIs were based on the exact method for binomial data. PFS, OS, and duration of response were analyzed using the Kaplan-Meier method.  Table S2). All patients received the combination of V937 and pembrolizumab. Of the 36 patients enrolled, 7 (19%) completed and 29 (81%) discontinued the study. Progressive disease was the most common reason for discontinuation (n = 20), followed by death (n = 2), physician decision (n = 2), and other (n = 5; Supplementary Figure S1). Median time from first dose to data cutoff date was 32.0 (range, 10.7-45.3) months.

Safety and tolerability
Adverse events occurring during the study are summarized in Table 2. No DLTs occurred. Treatment-related AEs occurred in 28 (78%) patients with 5 (14%) patients experiencing grade 3-5 treatment-related AEs. The most frequently occurring treatment-related AEs were rash (n = 14, 39%), fatigue (n = 12, 33%), pruritus (n = 6, 17%), diarrhea (n = 5, 14%), dry mouth (n = 5, 14%), and hypothyroidism (n = 4, 11%). Serious treatment-related AEs were experienced by 3 (8%) patients and included grade 3 keratoacanthoma, grade 3 autoimmune hepatitis, grade 3 autoimmune encephalitis, and grade 5 septic shock (the latter 2 events occurring in 1 patient), all of which were considered related to pembrolizumab by the investigator. There was 1 other grade 5 AE (cardiac failure), which was not considered treatment related by the investigator. Treatment-related AEs that led to treatment discontinuation were grade 3 increased hepatic enzymes and the grade 5 septic shock, the latter of which was related to steroids that had been administered for grade 3 autoimmune encephalitis.
Immune-mediated AEs, regardless of relationship to treatment, occurred in 8 (22%) patients ( Table 2). The most common immune-mediated AE was hypothyroidism (n = 4, 11%); no other immune-mediated AEs occurred in more than 1 patient. Four (11%) patients experienced grade 3 immune-mediated AEs including encephalitis, hepatitis, colitis, and pneumonitis (n = 1 for each). There were no grade 4 or 5 immune-mediated AEs. No infusion reactions occurred during the study.

Efficacy
Efficacy results are summarized in Table 3. The best overall response based on immune-related response criteria was complete response in 8 (22%) patients and partial response in 9 (25%) patients, for an ORR of 47% (95% CI 30-65%).
Among the 8 patients who previously received immune checkpoint inhibitor therapy, the ORR was 38%.
Among patients with ≥ 1 postbaseline assessment of target lesions, a ≥ 50% tumor volume reduction from baseline was observed in the size of target-injected lesions for 21 of 34 (62%) patients and target-noninjected lesions for
No differences were observed between responders and nonresponders in baseline cell density of total T cells or CD3 + CD8 + T cells (both P > 0.05) by multiplex immunohistochemistry (IHC) analysis (Fig. 2b). Surprisingly, the baseline cell density of CD3 + CD8 − T cells in the tumor microenvironment was lower in responders compared with nonresponders (P = 0.0179; Fig. 2b).

Discussion
In the phase 1b CAPRA study, we evaluated the combination of intratumoral V937 and pembrolizumab in patients with advanced melanoma and demonstrated a manageable safety profile and encouraging antitumor activity. No new safety signals were identified; the types of treatment-related AEs reported were as anticipated for each drug, given prior history with V937 and pembrolizumab, and were mostly of grade 1 or 2 severity. No myocarditis events occurred. The most common immune-mediated AE, regardless of relationship to treatment, was hypothyroidism both with combination therapy in CAPRA (11%) and with pembrolizumab monotherapy in a pooled analysis (9.1%) [18]. Hypothyroidism was managed in our study with corticosteroids and/or hormone replacement therapy and did not result in treatment discontinuation.
Notwithstanding the limitations of cross-study comparisons, based on immune-related response criteria, median PFS with the combination of V937 and pembrolizumab in CAPRA (11.9 months) was numerically greater than with V937 monotherapy in CALM (5.7 months) [5] or with pembrolizumab monotherapy (8.4 months) in an exploratory analysis from the KEYNOTE-006 study [13]. The ORRs, based on immune-related response criteria, were 47% in CAPRA, 38.6% in CALM [5], and 42% in KEYNOTE-006  [13]. The ORR in CAPRA was comparable to the preliminary rate of 50% achieved with the combination of V937 plus ipilimumab in MITCI [11]. The response rate of 47% in our study was similar to that reported from the phase 3 MASTERKEY-265 study of talimogene laherparepvec in combination with pembrolizumab (49%), although it is important to note that the patients in that study were naive to anti-PD-(L)1 therapy [19]. Another difference was that we administered V937 first and delayed pembrolizumab until day 8 after the fourth injection, whereas both drugs were administered starting on day 1 in the MASTERKEY-265 study.
Biomarkers were explored in CAPRA to gain insight into the possible mechanism for the systemic clinical responses. Surprisingly, responses were not associated with an increased baseline expression of viral entry proteins (ICAM-1 and DAF), PD-L1, or viral signaling proteins (RIG-I, TLR7, and TLR8), nor were they associated with an inflamed baseline tumor microenvironment. In fact, levels of infiltrating CD3 + CD8 − T cells in pretreatment tumor samples were actually lower in responders compared with nonresponders. Although the reason for this finding is unknown, one hypothesis is that the pretreatment tumor samples of responders included fewer regulatory cells. We observed that V937 viral load was more often detectable in responders. Robust viral replication is a major determinant of effective oncolysis [8]. Another hypothesis to explain the finding that a lower number of tumor-infiltrating Fig. 1 a Waterfall plot showing the best percentage change from baseline in size of targetinjected (blue) and target-noninjected (maroon) lesions (all patients with ≥ 1 postbaseline assessment of target lesions). b Swimmer's plot demonstrating treatment duration and response evaluation (investigator assessment per immune-related response criteria). CR, complete response; PD, progressive disease; PR, partial response lymphocytes was associated with a higher rate of response is that fewer immune cells were immediately available in the tumor to combat the overwhelming coxsackievirus infection, which resulted in more robust viral replication locally and an increased circulating viral load. We also observed a significant increase in serum IP-10/CXCL10 in responding patients, and to a lesser extent, an increase in MDC/ CCL22. CXCL10 is a marker of the severity of viral infection and facilitates recruitment of T cells, natural killer cells, macrophages, and dendritic cells [20]. Evidence suggests that CXCL10 is necessary for recruitment of antitumoral T cells into melanoma tumors [21]. Furthermore, CXCL10 signaling through the CXCR3 receptor promotes the migration of lymphocytes to dendritic cells, which was necessary for response to PD-1 blockade in a transplantable mouse model [22]. Clinically, there is evidence that high pretreatment CXCL9 and CXCL10 levels are correlated with response to anti-PD-(L)1 therapy in patients with non-small-cell lung cancer [23], and CXCL9 and CXCL10 increase in the first few months of treatment in patients with melanoma responding to PD-1 inhibitor therapy [22]. Given our findings above and the supportive data in the literature, we hypothesize that V937 viral infection leads interferon-gamma-mediated secretion of CXCL10 by multiple cell types in the tumor microenvironment, especially macrophages [24], which promotes response to anti-PD-1 therapy through improving local guidance of activated lymphocytes to the dendritic cells [22]. Quantitatively and qualitatively greater migration of T cells, including those recognizing V937 and tumor-associated antigens, furthered by increased expression of PD-L1 within the tumor microenvironment after treatment initiation, may also have contributed to efficacy. Unfortunately, we lack postbaseline biopsies, T-cell migration assays, T-cell phenotyping, or tetramer assays to help substantiate this hypothesis. Lastly, V937 is known to be able to induce innate immunity by cytokine-mediated bystander killing and natural killer cell killing in the cells of cancer patients [25], but innate assays were not explored in the current study.
In conclusion, the combination of intratumoral V937 plus pembrolizumab had favorable safety and efficacy in patients with advanced melanoma. The ORR was 47%, and there was a high rate of complete responses (22%) not typically seen with pembrolizumab monotherapy. Thus, the addition of V937 to pembrolizumab appeared to improve efficacy with limited impact on tolerability. Biomarker analysis showed that responses were not associated with an inflamed baseline tumor microenvironment, indicating that a pre-existing tumor immune infiltrate is not required for response to this combination. Markers of the intensity of the viral infection (CXCL10, CCL22) were associated with response, suggesting that the downstream effects of viral replication contributed to antitumor immunity and potentiated the activity of pembrolizumab. Further evaluation of the combination of V937 plus pembrolizumab for the neoadjuvant treatment of stage III melanoma is being assessed in an ongoing phase 1/2, randomized, open-label study (KEYMAKER-U02 substudy 02C; NCT04303169).  Fig. 3 Increase in cytokine levels (day 29/day 1) from paired serum samples: a IP-10/CXCL-10 (P = 0.0143) and b MDC/ CCL22 (P = 0.0421). Maximum circulating levels of c V937 during days 3-8 for each patient and d anti-V937 antibody by best overall response (investigator assessment per immunerelated response criteria). In panels c and d, the dashed lines within the shapes represent the median and interquartile range. CR, complete response; PD, progressive disease; PR, partial response; SD, stable disease 1 3 CB-M, MG, JAV, and JMM performed acquisition of data. AWS, HLK, CW, AZ, BAF, YR, JAV, and JMM contributed to interpretation of data. AWS, CW, and JMM performed drafting of the manuscript. All authors performed reviewing or revising the manuscript for important intellectual content. AWS and MP contributed to provision of study materials/patients. AWS, EZ-A, BAF, and MG provided administrative, logistical or technical support. All authors contributed to final approval and accountability.
Funding This study was sponsored by Merck Sharp & Dohme LLC, a subsidiary of Merck & Co., Inc., Rahway, NJ, USA. Services, results, and/or products in support of the research project were generated by the Rutgers Cancer Institute of New Jersey Immune Monitoring Shared Resource, supported, in part, with funding from the NCI-CCSG P30CA072770-5920. Additionally, this research was supported in part by Gateway for Cancer Research (G-16-800).
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