Correspondence to Caetano Reis e Sousa; [email protected]

What is already known on this topic

• Type 1 conventional dendritic cells (cDC1) play a non-redundant role in anticancer immunity.

• DNGR-1 is a dedicated cDC1 receptor that facilitates cross-presentation of dead-cell associated antigens.

• Secreted gelsolin (sGSN) is a physiological barrier to DNGR-1-dependent cross-presentation and dampens anticancer immunity.

• Some cancer therapies may induce an antitumor immune response by triggering immunogenic cell death.

What this study adds

• Loss of sGSN enhances therapeutic response to several immunogenic anticancer therapies in preclinical models including chemotherapy, targeted therapy and radiotherapy.

How this study might affect research, practice or policy

• Therapeutic inhibition of sGSN function, to unleash DNGR-1-dependent cross-presentation, could be explored as a component of more effective treatment regimens.

Background

Type 1 conventional dendritic cells (cDC1) perform non-redundant functions in anticancer immunity.^{1 2} Mice deficient in cDC1s (eg, Batf3^–/–) display lower spontaneous rejection of immunogenic tumors and decreased responses to T cell based immunotherapies.¹ In humans, a cDC1 gene signature positively correlates with improved overall survival (OS) in patients with cancer and with responses to checkpoint blockade immunotherapy.^{1 2} A key role of cDC1 is to prime tumor antigen-specific CD8⁺ T cells. It is thought that this partly involves internalization by cDC1 of dead cancer cell remnants and subsequent MHC class I (cross-)presentation to CD8⁺ T cells of antigens derived from the debris.

DNGR-1 (a.k.a. CLEC9A) is a C-type lectin receptor ubiquitously expressed on cDC1 that binds to F-actin exposed on dead cell corpses and signals to enhance cross-presentation of dead-cell associated antigens.^3–6 We recently found that secreted gelsolin (sGSN), an extracellular protein found in the plasma of all vertebrates,^{7 8} forms a natural barrier to DNGR-1-mediated cross-presentation.⁹ sGSN promotes cancer immune escape by competing with DNGR-1 for binding to extracellular F-actin and inhibiting DNGR-1-dependent tumor control.⁹ In humans, high expression of CLEC9A (encoding DNGR-1) in the tumor microenvironment is associated with greater survival and correlates with gene signatures of immune-mediated cancer control.¹⁰ In mice, DNGR-1 can contribute to CD8⁺ T cell-dependent control of transplantable tumors in animals deficient in sGSN.⁹

For decades, chemotherapy, radiotherapy and, more recently, targeted therapy, have been the mainstay of treatment for most patients with cancer. There is an increasing evidence that these therapies work not only by directly killing cancer cells but also by inducing or boosting antitumor immune responses.^11–13 We; therefore, hypothesized that therapy-induced cell death would increase the antigenic visibility of tumors, augmenting DNGR-1 triggering by F-actin in sGsn^–/– mice and resulting in improved anticancer immunity. Here, we show that mice deficient in sGsn display enhanced DNGR-1-dependent responsiveness to chemotherapy, radiotherapy and targeted therapy of tumors, highlighting sGSN as an attractive target for combinatorial cancer treatments that engage immunity.

Methods

Mice

Batf3^–/–, Clec9a^gfp/gfp, sGsn^–/–, sGsn^–/– Clec9a^gfp/gfp, Rag1^–/– and WT (wildtype) mice on a C57BL/6 background were bred and maintained in specific-pathogen free conditions in the Biological Research Facility (BRF) at The Francis Crick Institute. In all experiments, male and female mice were used. Experiments were initiated when mice were between 6 and 14 weeks. In all experiments comparing groups of mice of different genotypes, they were co-housed with sex-matched and age-matched WT controls for at least 3 weeks to eliminate any microbiota-dependent effects. Alternatively, in some experiments where WT littermate controls were used, this is indicated in the figure legends. All animal experiments were performed on prospective approval of a study plan by the BRF at The Francis Crick Institute and adhered to the UK Animals (Scientific Procedures).⁷

Transplantable tumors

Transplantable tumor cell lines used include MCA-205 fibrosarcoma (kind gift from George Kassiotis), 5555 Braf^V600E melanoma,¹⁴ and B16-F10 LifeAct (LA)-ovalbumin (OVA)-mCherry.⁹ All cell culture procedures were performed in a sterile condition in a laminar flow hood. Cultured syngeneic tumor cells were dissociated with trypsin (0.25%) (Gibco) and washed for three times in PBS (Gibco). The final cell pellet was resuspended in PBS for the required concentration of cells accordingly and injected subcutaneously (s.c.) in a volume of 100 µl in the shaved right flank of each mouse. Mice were monitored for tumor growth at least two to three times per week. The values of the longest (l) and perpendicular shortest (w) tumor diameters were measured using digital Vernier calipers (Mitutoyo), and tumor volume calculated using the formula: 0.5 x (l x w²),¹⁵ expressed in the standard metric units mm³. Mice-bearing tumors were monitored until the predetermined humane endpoint (eg, mean tumor diameter reaching ≥15 mm, weight loss ≥15%, or tumor ulceration) or for at least 30 days following tumor transplantation.

Chemotherapy model

For in vivo chemotherapy, mice were inoculated s.c. with 0.5×10⁶ cells/100 µlμ MCA-205 fibrosarcoma. Doxorubicin (Sigma-Aldrich) was administered at a dose of 2.5 mg/kg in a final volume of 50 µl sterile PBS intratumorally. Treatment was administered when tumors became palpable, usually on day 6 or 7, when the mean tumor diameter reached 6–8 mm.

Radiotherapy model

For radiotherapy, mice were inoculated s.c. with 0.2×10⁶ cells/100 µl of B16-F10 LA-OVA-mCherry melanoma. On day 7, mice received a single fraction of 10 Gy X-ray irradiation delivered in an X-ray irradiator cabinet (Xstrahl RS320 Research System). The machine was calibrated immediately prior to every use, and radiation was delivered at a consistent dose rate of 1.5–1.6 Gy/min (200kV, 16mA) at a field source distance of 20 cm. Radiation was targeted to the right flank tumor, precisely positioned using laser beams, through a 15 mm aperture at the center of an overlying customized lead shield (2 mm thickness). The shielded portion of the body received a maximum of 0.3 Gy radiation whereas 10 Gy was delivered to target tumor area. Mice received reversible general anesthesia throughout the duration of the procedure using a ‘sleep mix’ of fentanyl 0.05 mg/kg, midazolam 5 mg/kg and medetomidine 0.5 mg/kg, and reversed with a ‘wake mix’ of naloxone 1.2 mg/kg, flumazenil 0.5 mg/kg and atipam 2.5 mg/kg, administered intraperitoneally and dosed according to weight per mouse. Mice were kept in a warming chamber (35°C–37°C) (Datesand Thermacage) during anesthesia, both in preparation for administration of radiation and also for recovery. Mice receiving sham-irradiation were put through reversible anesthesia and recovery in the warming chamber for the same duration.

Targeted therapy model

Mice received 0.2×10⁶ cells/100 µl s.c. inoculation of 5555 Braf^V600E melanoma. When tumors were palpable, generally at day 6 after tumor cell inoculation, mice received Braf^V600E kinase inhibitor PLX4720 (MedKoo) suspension at a dose of 45 mg/kg in total volume of 200–250 µl by oral gavage (o.g.) daily for a total of 2 weeks, with 5% DMSO as vehicle control.

Statistics

Statistical analyses were performed using GraphPad Prism V.9 for Mac OS (V.9.3.0, updated 2021; San Diego, California, USA). Data are shown as mean±SE of the mean (SEM) unless otherwise stated. In general, for all tumor growth profiles, two-way analysis of variance was used to compare the means of two or more groups obtained at every single timepoint, and this was adjusted for multiple comparisons with post-hoc Bonferroni correction. The statistical differences annotated on the plots represent the comparison at the final timepoints within the respective follow-up period of each experiment. In all instances, p values are two tailed and p≤0.05 is considered the threshold for statistical significance. Where indicated in figures, the following scheme is used to represent the levels of statistical significance: *p≤0.05, **p<0.01, ***p<0.001, ****p<0.0001; ns, not significant.

Results

Loss of sGSN enhances response to immunogenic chemotherapy

First, we confirmed that chemotherapy with doxorubicin in the transplantable MCA-205 primary fibrosarcoma requires an immunocompetent host for full effectiveness. Consistent with that notion, intratumoral doxorubicin administration reduced tumor growth in WT mice but therapeutic benefit was reduced in Rag1^–/– mice which lack T and B cells (figures 1A,B). The efficacy of doxorubicin was similar in DNGR-1-deficient and WT mice, suggesting that DNGR-1 is dispensable in a sGSN-sufficient setting (online supplemental figure S1a). However, when tested in mice lacking sGSN, we observed that the administration of doxorubicin resulted in significantly greater tumor control compared with treated WT mice (figure 1A,C).

Enlarge this image.

Figure 1. Loss of sGSN enhances response to immunogenic chemotherapy, radiotherapy, and targeted therapy. (A) Graphical illustration of the chemotherapy model for data shown in (B, C). Mice were subcutaneously inoculated with MCA-205 fibrosarcoma cells, and on day 6 or 7, randomized to receive either chemotherapy with doxorubicin or PBS vehicle control (as indicated by the red arrows in the plots). (D) Tumor growth profile in mice receiving either doxorubicin (WT, n=8; Rag1 -/- , n=8), or vehicle control (WT, n=8; Rag1 -/- , n=8). (C) Doxorubicin was administered to n=9 sGsn -/- mice vs n=11 WT littermates, and compared with n=4 sGsn -/- mice vs n=7 WT littermates receiving vehicle control. (D) Graphical illustration of the radiotherapy model for data shown in (E, F). Tumors were derived from subcutaneous inoculation of B16-F10 LA-OVA-mCherry melanoma cells into the shaved right flanks of mice. Mice were then randomized to receive a single fraction of x-ray irradiation to the target tumor area or sham irradiation (untreated), on day 7 following tumor implantation (as indicated by the red arrows in the plots). (E) Growth profile of tumors in WT (X-ray, n=10; sham, n=8), Rag -/- (X-ray, n=10; sham, n=10) and Batf3 -/- (X-ray, n=10; sham, n=6) mice. (F) Growth profile of tumors in co-housed WT (X-ray, n=15; sham, n=12) and sGsn -/- (X-ray, n=14; sham, n=10) mice. (G) Graphical illustration of the targeted therapy model for data shown in (H, I). Mice were subcutaneously inoculated with 5555 BRAF V600E melanoma cells, and on day 6, randomized to receive treatment with either the Braf-inhibitor PLX4720 or 5% DMSO as vehicle control, for a total of 14 days (as indicated by the treatment bars below the x-axes in the plots). (H) Growth profile of tumors in Rag1 -/- mice (PLX4720, n=8; control, n=8) vs co-housed WT (PLX4720, n=7; control, n=6) mice. (I) Growth profile of tumors in co-housed WT (PLX4720, n=13; control, n=10) and sGsn -/- (PLX4720, n=14; control, n=12) mice. Data are represented as tumor volume (mm 3 ) +-SEM, and groups were compared using two-way ANOVA with post hoc Bonferroni correction. where indicated, *p<=0.05, **p<0.01, ***p<0.001, ****p<0.0001; NS, not significant. Error bars are depicted in all plots; when not visible, errors are small. Data are representative of one experiment respectively for (C, F, H); one of two independent experiments for (B, E); and one of three independent experiments for (I). The data in (C, F) are further replicated in figure 2A,B , respectively. ANOVA, analysis of variance; LA, LifeAct; PBS, phosphate-buffered saline; OVA, ovalbumin; sGSN, secreted gelsolin; WT, wild type.

Enlarge this image.

Figure 2. Enhanced therapeutic response in the loss of secreted gelsolin settings is dependent on DNGR-1. (A) Tumor growth profile in mice bearing MCA-205 fibrosarcoma receiving chemotherapy. Doxorubicin was administered to cohoused WT (n=10), sGsn -/- (n=10) and sGsn -/- Clec9a gfp/gfp (n=10) mice, and compared with cohoused WT (n=10), sGsn -/- (n=3) and sGsn -/- Clec9a gfp/gfp (n=3) mice receiving vehicle control. (B) Growth profile of B16-F10 LA-OVA-mCherry melanoma in co-housed WT (X-ray, n=14; sham, n=10), sGsn -/- (X-ray, n=11; sham, n=10) and sGsn -/- Clec9a gfp/gfp (X-ray, n=12; sham, n=11) mice. Data are plotted as tumor volume (mm 3 ) +-SEM, and mean tumor volumes were compared using two-way ANOVA with post hoc Bonferroni correction. Where indicated, *p<=0.05, **p<0.01, ***p<0.001, ****p<0.0001; NS, not significant. Error bars are depicted in all plots; when not visible, errors are small. Data are representative of one experiment respectively. ANOVA, analysis of variance; LA, LifeAct; OVA, ovalbumin; WT, wild type.

The efficacy of immunogenic radiotherapy is improved in the absence of sGSN

We next tested the effect of sGSN loss in tumor responses to radiotherapy (figure 1D). We used the poorly immunogenic B16-F10 melanoma cell line engineered to express the model antigen OVA fused to mCherry and a 17-amino acid LA F-actin binding peptide (B16-F10 LA-OVA-mCherry).⁹ We found that effective and sustained control of B16-F10 LA-OVA-mCherry tumors following a single fraction of X-ray irradiation was lost in Batf3^–/– mice lacking cDC1 or Rag1^–/– mice lacking T and B cells (figure 1E). As in the doxorubicin chemotherapy model, tumor control following radiotherapy was unaffected by deficiency in DNGR-1 (online supplemental figure S1b). However, it was significantly enhanced in sGSN-deficient hosts (figure 1F).

Targeted therapy induces immunogenic cell death and its efficacy is further enhanced in absence of sGSN

We also sought to investigate whether sGSN deficiency might benefit the response to targeted therapy with BRAF inhibitor in a mouse mutant-Braf melanoma model. Tumor-bearing mice implanted with 5555 Braf^V600E primary melanoma tumor cells were treated or not with PLX4720 (figure 1H). We found that the therapeutic effect of the drug was decreased in mice lacking T and B cells (figure 1H). Notably, 5555 Braf^V600E tumors were controlled to a greater extent in sGsn^–/– compared with WT mice even in the absence of treatment with PLX4720 (figure 1I). Importantly, however, tumor control by PLX4720 was further enhanced by sGSN-deficiency (figure 1 and online supplemental figure S1c), confirming the importance of sGSN as a barrier to dead cell-induced immunity.

The enhanced therapeutic response in sGsn^–/– mice is DNGR-1-dependent

The data so far suggest that maximal therapeutic efficacy of some forms of chemotherapy, radiotherapy and targeted therapy in vivo requires an intact adaptive immune system and is further augmented by loss of sGSN. In order to validate that enhanced tumor control in sGsn^–/– mice is DNGR-1-dependent, we tested some of the therapy models in mice deficient in both sGSN and DNGR-1. For both chemotherapy with intratumoral doxorubicin in MCA-205 and radiotherapy in B16-F10 LA-OVA-mCherry, mice deficient in both sGSN and DNGR-1 exhibited similar rate of tumor control to the respective treated WT controls, in contrast to the enhanced therapeutic responses observed in the treated sGsn^–/– subgroups (figure 2A,B). Thus, sGSN impairs DNGR-1-dependent anticancer immunity-induced by therapy.

Discussion

While much of the therapeutic effect of conventional anticancer therapies results from direct cytotoxicity to cancer cells, it is becoming clear that it can also include immune-dependent mechanisms. Specifically, it has been proposed that some cancer therapeutics can cause immunogenic cell death (ICD), allowing for sampling of tumor antigens by DCs that then prime or boost an antitumor T cell response.^{11 12} DNGR-1 is a receptor that marks the cDC1 subtype of DCs and plays a key role in coupling dead cell recognition to antitumor CD8⁺ T cell immunity.^{3–6 16} DNGR-1 activity is often masked by circulating sGSN such that the role of the receptor can be revealed only on loss of the latter protein.⁹ Here, we show that the immune-dependent efficacy of seemingly disparate therapies in a preclinical mouse model is increased by loss of sGSN. Notably, although DNGR-1 deficiency per se does not impact therapy efficacy, it curtails the therapeutic advantage conferred by loss of sGSN. Thus, these data implicate the sGSN-DNGR-1 axis in decoding ICD induced by cancer treatment.

The contribution of immunity to the effects of conventional cancer chemotherapy and radiotherapy is beginning to be appreciated in patients,¹⁷ but mechanistic insights have been primarily obtained in animal models. In mice, several chemotherapeutic agents, including the anthracycline doxorubicin, result in ICD and lead to antitumor responses that depend on DCs and CD8⁺ T cells.^{12 18} Similarly, both DCs and CD8⁺ T cells have been previously demonstrated to contribute to tumor control following radiotherapy.^{13 19} Our study provides further evidence for the immunogenicity of some anticancer therapies,^{11 12} showing that their potency is reduced in mice lacking T (and B) cells. We show that this immune benefit can be further enhanced in a DNGR-1 dependent manner on loss of sGSN, concordant with our previous work showing and increase in tumor-specific T cell responses in GSN-deficient animals.⁹ Thus, DNGR-1-dependent cross-presentation of dead cell-associated antigens can increase anticancer immunity and could be exploited clinically.

In addition to conventional chemotherapy and radiotherapy, a growing repertoire of therapies target driver mutations in cancer. An example is BRAF inhibitors, which have been used to treat BRAF-mutant melanoma.²⁰ However, clinical responses are variable and often curtailed by development of drug resistance. Improving clinical response by co-opting immunity may help tackle resistance to targeted therapy and potentially improve outcomes. Indeed, NK cells are essential for effective melanoma control in mice treated with the BRAF inhibitor PLX4720²¹ and, in human paired-biopsy studies, treatment with BRAF-inhibitor increases tumor infiltration by cytotoxic CD8⁺ T cells.²² Here, we show that melanoma control by targeted therapy with PLX4720 requires an immunocompetent host and reveal that efficacy can be enhanced in the absence of sGSN. Thus, sGSN blocking could be a potentially useful adjunct to targeted therapy.

Collectively, these data complement and extend our previous observations that sGSN-deficient mice display enhanced responses to immune checkpoint blockade cancer therapy,⁹ and that DNGR-1 expression within tumors is associated with greater OS in several human cancers.¹⁰ Further highlighting the sGSN-DNGR-1 axis as a novel checkpoint in anticancer immunity, we previously reported that in a small subset of patients with stomach adenocarcinoma, high expression of CLEC9A and low expression of sGSN in tumors conferred the best survival outcomes compared with the other stratified subgroups in retrospective analysis.⁹ These findings will need to be prospectively validated to identify patients who may benefit most from inhibition of sGSN function to unleash DNGR-1-dependent cross-presentation as a component of more effective treatment regimens.

We thank the Biological Research Facility at The Francis Crick Institute for their support throughout this project. We are very grateful for the advice provided by Neil Osborne (Head of Radiation Safety) for the initial set up and optimization of the in vivo radiotherapy models. We thank members of the Immunobiology Laboratory for helpful discussions and suggestions.

Data availability statement

Data are available on reasonable request. All data relevant to the study are included in the article or uploaded as online supplemental information.

Ethics statements

Patient consent for publication

Not applicable.

¹ Böttcher JP, Reis e Sousa C. The role of type 1 conventional dendritic cells in cancer immunity. Trends Cancer 2018; 4: 784–92. doi:10.1016/j.trecan.2018.09.001 http://www.ncbi.nlm.nih.gov/pubmed/30352680

² Wculek SK, Cueto FJ, Mujal AM, et al. Dendritic cells in cancer immunology and immunotherapy. Nat Rev Immunol 2020; 20: 7–24. doi:10.1038/s41577-019-0210-z http://www.ncbi.nlm.nih.gov/pubmed/31467405

³ Sancho D, Joffre OP, Keller AM, et al. Identification of a dendritic cell receptor that couples sensing of necrosis to immunity. Nature 2009; 458: 899–903. doi:10.1038/nature07750 http://www.ncbi.nlm.nih.gov/pubmed/19219027

⁴ Sancho D, Mourão-Sá D, Joffre OP, et al. Tumor therapy in mice via antigen targeting to a novel, DC-restricted C-type lectin. J Clin Invest 2008; 118: 2098–110. doi:10.1172/JCI34584 http://www.ncbi.nlm.nih.gov/pubmed/18497879

⁵ Canton J, Blees H, Henry CM, et al. The receptor DNGR-1 signals for phagosomal rupture to promote cross-presentation of dead-cell-associated antigens. Nat Immunol 2021; 22: 140–53. doi:10.1038/s41590-020-00824-x http://www.ncbi.nlm.nih.gov/pubmed/33349708

⁶ Ahrens S, Zelenay S, Sancho D, et al. F-Actin is an evolutionarily conserved damage-associated molecular pattern recognized by DNGR-1, a receptor for dead cells. Immunity 2012; 36: 635–45. doi:10.1016/j.immuni.2012.03.008 http://www.ncbi.nlm.nih.gov/pubmed/22483800

⁷ Kwiatkowski DJ, Stossel TP, Orkin SH, et al. Plasma and cytoplasmic gelsolins are encoded by a single gene and contain a duplicated actin-binding domain. Nature 1986; 323: 455–8. doi:10.1038/323455a0 http://www.ncbi.nlm.nih.gov/pubmed/3020431

⁸ Kwiatkowski DJ, Mehl R, Yin HL. Genomic organization and biosynthesis of secreted and cytoplasmic forms of gelsolin. J Cell Biol 1988; 106: 375–84. doi:10.1083/jcb.106.2.375 http://www.ncbi.nlm.nih.gov/pubmed/2828382

⁹ Giampazolias E, Schulz O, Lim KHJ, et al. Secreted gelsolin inhibits DNGR-1-dependent cross-presentation and cancer immunity. Cell 2021; 184: 4016–31. doi:10.1016/j.cell.2021.05.021 http://www.ncbi.nlm.nih.gov/pubmed/34081922

¹⁰ Böttcher JP, Bonavita E, Chakravarty P, et al. Nk cells stimulate recruitment of cdc1 into the tumor microenvironment promoting cancer immune control. Cell 2018; 172: 1022–37. doi:10.1016/j.cell.2018.01.004 http://www.ncbi.nlm.nih.gov/pubmed/29429633

¹¹ Kroemer G, Galluzzi L, Kepp O, et al. Immunogenic cell death in cancer therapy. Annu Rev Immunol 2013; 31: 51–72. doi:10.1146/annurev-immunol-032712-100008 http://www.ncbi.nlm.nih.gov/pubmed/23157435

¹² Galluzzi L, Buqué A, Kepp O, et al. Immunological effects of conventional chemotherapy and targeted anticancer agents. Cancer Cell 2015; 28: 690–714. doi:10.1016/j.ccell.2015.10.012 http://www.ncbi.nlm.nih.gov/pubmed/26678337

¹³ Wilkins AC, Patin EC, Harrington KJ, et al. The immunological consequences of radiation-induced DNA damage. J Pathol 2019; 247: 606–14. doi:10.1002/path.5232 http://www.ncbi.nlm.nih.gov/pubmed/30632153

¹⁴ Dhomen N, Reis-Filho JS, da Rocha Dias S, et al. Oncogenic BRAF induces melanocyte senescence and melanoma in mice. Cancer Cell 2009; 15: 294–303. doi:10.1016/j.ccr.2009.02.022 http://www.ncbi.nlm.nih.gov/pubmed/19345328

¹⁵ Faustino-Rocha A, Oliveira PA, Pinho-Oliveira J, et al. Estimation of rat mammary tumor volume using caliper and ultrasonography measurements. Lab Anim 2013; 42: 217–24. doi:10.1038/laban.254 http://www.ncbi.nlm.nih.gov/pubmed/23689461

¹⁶ Poulin LF, Reyal Y, Uronen-Hansson H, et al. DNGR-1 is a specific and universal marker of mouse and human Batf3-dependent dendritic cells in lymphoid and nonlymphoid tissues. Blood 2012; 119: 6052–62. doi:10.1182/blood-2012-01-406967 http://www.ncbi.nlm.nih.gov/pubmed/22442345

¹⁷ Sammut S-J, Crispin-Ortuzar M, Chin S-F, et al. Multi-Omic machine learning predictor of breast cancer therapy response. Nature 2022; 601: 623–9. doi:10.1038/s41586-021-04278-5 http://www.ncbi.nlm.nih.gov/pubmed/34875674

¹⁸ Casares N, Pequignot MO, Tesniere A, et al. Caspase-Dependent immunogenicity of doxorubicin-induced tumor cell death. J Exp Med 2005; 202: 1691–701. doi:10.1084/jem.20050915 http://www.ncbi.nlm.nih.gov/pubmed/16365148

¹⁹ Gupta A, Probst HC, Vuong V, et al. Radiotherapy promotes tumor-specific effector CD8+ T cells via dendritic cell activation. J Immunol 2012; 189: 558–66. doi:10.4049/jimmunol.1200563 http://www.ncbi.nlm.nih.gov/pubmed/22685313

²⁰ Subbiah V, Baik C, Kirkwood JM. Clinical development of BRAF plus MEK inhibitor combinations. Trends Cancer 2020; 6: 797–810. doi:10.1016/j.trecan.2020.05.009 http://www.ncbi.nlm.nih.gov/pubmed/32540454

²¹ Ferrari de Andrade L, Ngiow SF, Stannard K, et al. Natural killer cells are essential for the ability of BRAF inhibitors to control BRAFV600E-mutant metastatic melanoma. Cancer Res 2014; 74: 7298–308. doi:10.1158/0008-5472.CAN-14-1339 http://www.ncbi.nlm.nih.gov/pubmed/25351955

²² Frederick DT, Piris A, Cogdill AP, et al. Braf inhibition is associated with enhanced melanoma antigen expression and a more favorable tumor microenvironment in patients with metastatic melanoma. Clin Cancer Res 2013; 19: 1225–31. doi:10.1158/1078-0432.CCR-12-1630 http://www.ncbi.nlm.nih.gov/pubmed/23307859