Abstract
Very late antigen-4 (VLA-4; also known as integrin α4β1) is expressed at high levels in aggressive and metastatic melanoma tumors and may provide an ideal target for imaging and targeted radionuclide therapy (TRT). 177Lu-DOTA-PEG4-LLP2A (177Lu-LLP2A) is a TRT that shows high affinity for VLA-4 and high uptake in B16F10 mouse melanoma tumors in vivo. Here, we report efficacy studies of 177Lu-LLP2A, alone and combined with immune checkpoint inhibitors (ICIs) (anti-PD-1, anti-PD-L1, and anti-CTLA-4 antibodies), in B16F10 tumor–bearing mice. Methods: Tumor cells (1 × 106) were implanted subcutaneously in C57BL/6 mice. After 8–10 d, the mice were randomized into 8 groups. 177Lu-LLP2A was injected intravenously on day 8 or 9 (single dose), and ICI antibodies were administered intraperitoneally in 3 doses. Tumor growth was monitored over time via calipers. Terminal deoxynucleotidyl transferase dUTP nick-end labeling (TUNEL) staining for apoptosis was performed on fixed tumors. In a separate study, Cy3-LLP2A or Cy3–scrambled LLP2A was injected in tumor-bearing mice, and tumors were collected 4 h after injection and then analyzed by flow cytometry and immunofluorescence microscopy using different immune cell markers. Results: TRT alone showed efficacy comparable to the dual-ICI anti-PD-1 + anti-CTLA-4 or anti-PD-L1 + anti-CTLA-4, whereas TRT + ICIs significantly enhanced survival. TUNEL staining showed that the highest levels of apoptosis were in the TRT + ICI groups. In addition to targeting tumor cells, TRT also bound immune cells in the tumor microenvironment. Flow cytometry data showed that the tumors consisted of about 77% tumor cells and fibroblasts (CD45-negative/CD49d-positive) and about 23% immune cells (CD45-positive/CD49d-positive) and that immune cells expressed higher levels of VLA-4. Cy3-LLP2A and CD49d colocalized with macrophages (CD68), T cells (CD8, CD4), and B cells (CD19). Immunohistochemical analysis identified a significant colocalization of Cy3-LLP2A and CD68. Conclusion: Combination treatment with TRT + ICIs targets both tumor cells and immune cells and has potential as a therapeutic agent in patients with metastatic melanoma.
Melanoma is one of the most serious types of skin cancer and can develop from pigmented cells in the skin, eyes, and mucosal organs, causing high morbidity and mortality in patients (1). Surgical excision is usually curative for early-stage melanoma; however, aggressive melanomas may quickly metastasize to distal organs (2). Over the past decade, immunotherapy with immune checkpoint inhibitors (ICIs) (anti-CTLA-4, anti-PD-1, and anti-PD-L1 antibodies) has demonstrated dramatic therapeutic efficacy in many patients with metastatic melanoma, and there are now several Food and Drug Administration–approved ICI-based drugs (3). However, the therapeutic response in patients is uneven because of the many molecular mechanisms regulating antitumor immune responses in cancer patients (4). Novel therapeutic approaches, including combination therapies (5,6), are needed to improve overall survival rates. It was reported that combining anti-PD-1 + anti-CTLA-4 or anti-PD-L1 + anti-CTLA-4 dual-ICI therapy with external-beam irradiation improved efficacy in melanoma-bearing mice when compared with treatment with dual-ICI therapy alone (5). Radiation is not ideal, however, for treating patients with disseminated melanomas, as it cannot be applied to microscopic metastatic disease and can damage normal tissues or organs surrounding the tumors. Therefore, a systemically targeted radionuclide therapy (TRT) would be preferred to enhance the combined antitumor efficacy of radiation with ICI therapy.
Very late antigen-4 (VLA-4; also known as integrin α4β1) plays an important role in tumor growth, angiogenesis, and metastasis by promoting adhesion and migration of cancer cells. VLA-4 is expressed in many types of cancer, including melanoma, lymphoma, and multiple myeloma (7,8). VLA-4 also plays a crucial role in lymphocyte differentiation and trafficking (9) and has been a highly studied therapeutic target because of its immunomodulatory activity (10,11).
Very high affinity and specificity for activated VLA-4 has been shown by the peptidomimetic LLP2A (N-[[4-[[[(2-ethylphenyl) amino]carbonyl]amino]phenyl]acetyl]-Nε-6-[(2E)-1-oxo-3-(3-pyridinyl-2-propenyl)]-l-lysyl-l-2-aminohexanedioyl-(1-amino-1-cyclohexane)carboxamide; Supplemental Fig. 1 [supplemental materials are available at http://jnm.snmjournals.org]) (12). LLP2A has been labeled with the β-emitter 177Lu (half-life, 6.7 d; maximum β− energy, 0.49 MeV) and the positron emitter 68Ga (half-life, 68 min; maximum β+ energy, 1.92 MeV) for therapy and PET imaging, respectively. 177Lu is an attractive radionuclide for TRT, as it has a moderate β− energy that is effective for treatment of smaller metastatic tumors. The half-life of 68Ga is amenable to imaging with peptides and small molecules. We previously reported that 68Ga- and 177Lu-labeled LLP2A have high uptake in B16F10 mouse melanoma tumors (13).
The primary objective of this study was to investigate the antitumor efficacy of combining the TRT 177Lu-LLP2A with ICIs in B16F10 tumor–bearing mice versus using either as a single-modality treatment. We also identified VLA-4–expressing cell types within the tumor microenvironment (TME) and determined expression levels of VLA-4 in immune cells in the TME, with a particular interest in those known to have a strong impact on tumor progression and metastasis (14).
MATERIALS AND METHODS
Reagents
All chemicals were purchased from Sigma-Aldrich unless otherwise specified. Aqueous solutions were prepared using ultrapure water (resistivity, 18.2 MΩ·cm). Rink amide 4-methylbenzhydrylamine resin (loading, 0.77 mmol/g) and all fluorenylmethyloxycarbonyl-protecting-group (Fmoc)–protected amino acids were purchased from Chem-Impex International, Inc. DOTA was purchased from Chematech. Fmoc-polyethylene glycol (PEG4) carboxylic acid was purchased from ChemPep Inc. Cy3 carboxylic acid was purchased from Lumiprobe. All flow cytometry antibodies were obtained from BD Biosciences. 177LuCl3 was purchased from the University of Missouri Research Reactor. Anti-PD-L1 (clone, 10F.9G2), anti-PD-1 (clone, RMP1–14), and anti-CTLA-4 (clone, 9H10) antibodies were obtained from BioXCell. C57BL/6 mice were purchased from Charles River Laboratories.
Instrumentation
Analytic and semipreparative reversed-phase high-performance liquid chromatography was performed on a Waters 1525 Binary Pump with a Waters 2489 UV/Vis detector and a model 106 Bioscan radioactivity detector. LLP2A analogs were purified on a semipreparative Jupiter C18 column (Phenomenex). Radiochemistry reaction progress and purity were monitored on a Jupiter C18 column. Radioactive samples were counted using either an automated Packard Cobra II γ-counter or a PerkinElmer 2470 Wizard2 automatic γ-counter. PET/CT data were acquired on an Inveon Preclinical Imaging Station (Siemens Medical Solutions). Microscopy images were acquired by immunofluorescence (Zeiss Microscopy) and analyzed with ZEN 2009 software (Zeiss Microscopy). Tumor cells and immune cells were analyzed with an LSRII flow cytometer (BD Biosciences) and FlowJo software (BD Biosciences).
Peptide Synthesis and Radiolabeling Studies
DOTA-PEG4-LLP2A (12,13), scrambled LLP2A (sLLP2A) (12), and Cy3-PEG4-conjugated LLP2A and sLLP2A (15) were synthesized as previously described. 177Lu- and 68Ga-labeled DOTA-PEG4-LLP2A (177Lu-LLP2A; 68Ga-LLP2A) were prepared in greater than 99% purity as previously described (13).
In Vivo TRT
All animal studies were conducted under protocols approved by the University of Pittsburgh Institutional Animal Care and Use Committee. B16F10 tumor cells (1 × 106) were injected subcutaneously in the left flank of female and male C57BL/6 mice (4–6 wk old). Therapy studies commenced when tumors were palpable (8–10 d after tumor injection). Mice receiving single- or dual-ICI therapy without TRT were injected intraperitoneally with anti-CTLA-4, anti-PD-L1, or anti-PD-1 antibodies (200 μg) on days 9, 12, and 15 after tumor cell injection. Mice receiving TRT were injected intravenously with 30 MBq of 177Lu-LLP2A either alone or before ICI therapy.
The dose scheduling for all groups of mice is summarized in Figure 1. Body weight and tumor volume were measured every 2 d until 13 d after the start of therapy. After day 13, the tumors were measured daily. The tumor volumes were based on caliper measurements and estimated using the equation [volume = (π ÷ 6) × L × W × H], where L is the longest axis, W is the axis perpendicular to L, and H is the axis perpendicular to the L and W planes. The mice were sacrificed when the tumor ulcerated or reached a volume of 1.5 cm3 in the longest axis. The mice showed no signs of pain, distress, or morbidity (scruffy coat, diarrhea, lethargy, 20% weight loss).
PET/CT Imaging
Tumor-bearing mice were injected intravenously with 68Ga-LLP2A (200 μCi; 7.4 MBq) and anesthetized with 2% isoflurane, and static PET/CT images were obtained at 1 and 2 h after injection. The PET and CT images were coregistered and analyzed with Inveon Research Workstation software as previously described (13).
Immunofluorescence Microscopy
Tumor-bearing mice were injected intravenously with either Cy3-LLP2A or Cy3-sLLP2A (50 μg; n = 2 for each group). At 4 h after injection, the mice were euthanized, and the tumors were collected and frozen. Sections (6 μm) were obtained, and nonspecific blocking was performed (2% bovine serum albumin). Sections were then stained with antimouse CD49d-FITC (clone, R12), antimouse CD68-APC (clone, FA-11), and 4′,6-diamino-2-phenylindole (DAPI). After washing in phosphate-buffered saline, coverslips were mounted using Prolong Diamond Antifade Mountant (Thermo Fisher). The slides were imaged with a Zeiss Apotome system equipped with a Zeiss plan Apochromat ×63 high-performance objective with an oil immersion lens (numeric aperture, 1.4–0.6).
Terminal Deoxynucleotidyl Transferase dUTP Nick-End Labeling (TUNEL) Staining
At the time of euthanasia after therapy, tumors from 6 treatment groups (1. Control [nontreated]; 2. 177Lu-LLP2A [TRT alone]; 3. anti-PD-1 and anti-CTLA-4 [ICI dual]; 4. anti-PD-L1 and anti-CTLA-4 [ICI dual]; 5. 177Lu-LLP2A + anti-PD-L1 and anti-CTLA-4 [combination TRT+ICI]; and 6. 177Lu-LLP2A + anti-PD-1 and anti-CTLA-4 [combination TRT+ICI]) were excised and fixed in 4% formaldehyde (in phosphate-buffered saline) for 30 min at room temperature, followed by embedding in paraffin. The paraffin blocks were sectioned (5 μm), and apoptotic cell death was assessed via TUNEL staining (Sigma Aldrich) on the Apotome system. Nuclei were counterstained with DAPI. For analysis, the DAPI-counterstained cells (representing total cells) for an entire ×10 field of view were counted using ZEN software, followed by counting of TUNEL-positive cells. The percentage of apoptotic cells in the field was based on the ratio of TUNEL-positive and DAPI-counterstained cells. Scores were averaged for 3 fields of view for control, TRT alone, dual ICI (anti-PD-1 + anti-CTLA-4 or anti-PD-L1 + anti-CTLA-4), and TRT + ICI (TRT + anti-PD-1 + anti-CTLA-4 or TRT + anti-PD-L1 + anti-CTLA-4).
Flow Cytometry
Cy3-LLP2A (50 μg) or Cy3-sLLP2A (50 μg) was injected intravenously into tumor-bearing mice (n = 2 per group). At 4 h after injection, the mice were euthanized, and the tumors were collected, incubated with a mixture of collagenase D (2 mg/mL) and DNase-I (1/100, stock solution at 1 mg/mL) in RPMI 1640/fetal bovine serum (2%) for 45 min at 37°C, and passed through a mesh filter (70 μm) to create a single-cell suspension. Red blood cells were lysed with ammonium-chloride-potassium buffer (Thermo Fisher), and nucleated cells were washed with phosphate-buffered saline. The cells were then labeled with a mixture of the following antimouse fluorescein isothiocyanate (FITC)–conjugated antibodies for 30 min at room temperature: CD49d FITC (clone, R12), CD45 PE (clone, 104), CD4 PE (clone, RM4-5), CD8 FITC (clone, 53-6.7), CD11c FITC (clone, 6D5), CD68 FITC (clone, FA-11), FoxP3 FITC, PD-1 FITC (clone, CD279), PD-L1 FITC (clone, 10F.9G2), and NK FITC (clone, 29A1.4). The cells were analyzed by flow cytometry using LSRFortessa (BD Biociences). Gating first was done on the forward-light-scatter/side-scatter characteristics of the cells and then was based on VLA-4 expression. For all Cy3-LLP2A–positive live cells, tumor cells were identified as CD45-negative/CD49d-positive. Immune cells were identified as CD45-positive/CD49d-positive and were then stained with the antibodies listed above.
Human Dosimetry
177Lu-LLP2A (5–6 MBq/nmol) was injected intravenously into ICR non–tumor-bearing mice, and biodistribution was measured from 1 h to 7 d after injection (n = 5 per group). Time–activity curves weighted by organ masses (to facilitate scaling to human values (16)) per the injected dose for 20 organs (Table 1) were determined and integrated to determine organ residence times. Mouse organ residence times were rescaled to human values (16) and then used as input data to OLINDA/EXM, version 1.0, to estimate male and female human absorbed radiation doses. Fat and blood are not source organs in OLINDA/EXM, and surveyed activity for these components was treated as “remainder,” assumed to be distributed throughout the body. It was assumed that for each time point, 95% of the actual activity present was accounted for in the organ assay; the remaining 5% was added to the remainder. Conversion of mouse to human remainder assumed that the ratio of mouse remainder to activity in OLINDA source organs was constant between humans and mice. Although activity in bone as a whole was surveyed, the distribution of activity between bone marrow, trabecular bone, and cortical bone was not determined. In the conversion to human values, it was assumed that activity was distributed among these components on the basis of their relative masses in humans.
Statistics
SAS/STAT software, version 9.4 (SAS Institute, Inc.), and Prism software, version 7 (GraphPad), were used for statistical analysis. Average survival from the first day of treatment (day after palpation for control groups) was compared between treatment groups using a linear mixed-effects regression model with log(survival days) as outcome, days from injection to palpation as a covariate, treatment group as the covariate of interest, and random experiment effects. Multiple comparisons were adjusted using the Dunnett test, separately for comparison of each group to the control group, to the TRT + anti-PD-1 + anti-CTLA-4 group, and to the TRT + anti-PD-L1 + anti-CTLA-4 group. Biodistribution was performed using the unpaired 2-tailed t test. Two-sided P values (≤0.05) were considered significant.
RESULTS
Radiolabeling Chemistry
The radiochemical yields of 177Lu-LLP2A and 68Ga-LLP2A were 99% and showed greater than 98% stability in phosphate-buffered saline at 37°C for 6 h.
Therapeutic Efficacy
The TRT (30 MBq), either alone or in combination with ICIs, was administered to tumor-bearing mice in 4 series of experiments (Fig. 1). The mice were monitored for tumor size (Fig. 2) and for overt toxicity (scruffy coat, diarrhea, lethargy). All sacrifice times were determined by tumor size or ulceration rather than morbidity criteria.
The 3 single-agent ICI groups (anti-CTLA-4, anti-PD-1, and anti-PD-L1) did not show improved survival compared with the control group (Fig. 2; adjusted P > 0.9). Combination TRT + ICI using TRT + anti-PD-1 + anti-CTLA-4 and using TRT + anti-PD-L1 + anti-CTLA-4 had a median survival time of 22 and 23 d, respectively, from tumor cell injection (Table 2). Survival from combination TRT + ICI was superior to that from other treatments (adjusted P ≤ 0.002), except for dual-ICI (anti-PD-1 + anti-CTLA-4 or anti-PD-L1 + anti-CTLA-4) versus TRT + ICI using TRT + anti-PD-1 + anti-CTLA-4 (adjusted P = 0.29). Those 2 treatment groups were part of the same experiment, and the animals assigned to dual-ICI had inherently more indolent tumors, with 9 d from injection to palpation compared with 7 for the animals receiving TRT + ICI. 68Ga-LLP2A imaging (2 h after injection) of tumor-bearing mice 6 d after dual-ICI using TRT + anti-PD-L1 + anti-CTLA-4 showed high tumor uptake (Fig. 3).
Immune Cell Targeting by Immunohistochemistry Using Cy3-LLP2A
To determine the immune cell types targeted by 177Lu-LLP2A, 2 mice were injected in vivo with Cy3-LLP2A, and 2 were injected in vivo with Cy3-sLLP2A as a negative control (Supplemental Fig. 1). Frozen sections of the tumors isolated from these mice were stained with DAPI and showed antibodies reactive against CD68 and CD49d. The CD68 pattern of staining correlated well with that of Cy3-LLP2A and CD49d (Fig. 4). Macrophages are known to express VLA-4 on their cell surface, and these cells are a likely target of 177Lu-LLP2A. Notably, Cy3-sLLP2A exhibited negligible binding to immune cells in the TME of melanomas (Supplemental Figs. 2 and 3).
TUNEL staining was performed on tumors collected from euthanized mice. Tumors after TRT alone, ICI alone, or TRT + ICI showed greater staining than control tumors (P < 0.001 for each, with Dunnett adjustment). The percentage of apoptotic cells in the control tumors was about 6% ± 4%, compared with 36%–44% after TRT alone or ICI alone (±12%–14%) and 81% after TRT + anti-PD-L1 + anti-CTLA-4 (±4%) and TRT + anti-PD-1 + anti-CTLA-4 (±8%) (Fig. 5).
Immune Cell Targeting by Flow Cytometry Using Cy3-LLP2A
Flow cytometry was used to identify cells coexpressing Cy3-LLP2A and CD49d, as well as alternate immune cell subpopulation–specific markers in the TME (Supplemental Fig. 4). Cells that stained positively for Cy3-LLP2A (60.1% sorted by live cells in the TME) comprised 23% immune cells (CD45-positive/CD49d-positive) and 75% tumor cells or fibroblasts (CD45-negative/CD49d-positive) (Fig. 6A). The largest populations of Cy3-LLP2A–positive cells costained for expression of PD-1 (40%), CD68 (35%), and PD-L1 (35%) (Fig. 6B). However, B cells (CD19), macrophages (CD68), and T cells (CD8 and CD4) stained most strongly with Cy3-LLP2A, suggesting that these cell types have the highest levels of VLA-4 expressed on a per-cell basis. Only 1.6% of the isotype control agent, Cy3-sLLP2A, was taken up in tumor cells in vivo (n = 12), compared with 58% of Cy3-LLP2A (n = 12) (Supplemental Fig. 2).
Equivalent Radiation Dose to Humans Estimated from Mouse Biodistribution
The estimated equivalent doses of radiation from 177Lu-LLP2A to normal organs in humans were calculated on the basis of the normal biodistribution in mice (Table 1). The human models provided by OLINDA/EXM are hermaphroditic in that the male model contains female organs. These data are similar to the estimated human dosimetry of 177Lu-DOTATATE based on rat biodistribution (17). The equivalent dose to the spleen was higher for 177Lu-LLP2A (female, 0.41 mSv/MBq; male, 0.32 mSv/MBq) than for 177Lu-DOTATATE (0.02 mSv/MBq). However, the equivalent doses to the red marrow (female, 0.083 mSv/MBq; male, 0.085 mSv/MBq), adrenals (female, 0.020 mSv/MBq; male, 0.015 mSv/MBq), and kidneys (female, 0.048 mSv/MBq; male, 0.037 mSv/MBq) were lower for 177Lu-LLP2A than for 177Lu-DOTATATE (red marrow, 0.097 mSv/MBq; adrenals, 1.4 mSv/MBq; kidneys, 0.68 mSv/MBq). However, the red marrow dose determined in the present study was an estimate.
DISCUSSION
Metastatic melanoma is challenging to treat with standard chemotherapy and radiation therapy (18). Recently, dual-ICI therapy (anti-PD-1 + anti-CTLA-4 or anti-PD-L1 + anti-CTLA-4) has exhibited enhanced efficacy in patients with metastatic melanoma compared with single-ICI therapy (3,19). However, the responses to these ICIs remain uneven, and only a subset of patients receives durable clinical benefit from ICIs (20,21). To overcome these limitations, combination protocols, such as ICIs + radiation, have emerged as second-line or co–first-line treatment option (5). Combining PD-1 or PD-L1 blockade with radiation was shown to yield improved treatment benefit versus radiation alone (22–24), putatively by promoting the expansion and recruitment of tumor-reactive T cells to tumor sites, thereby facilitating antitumor responses in vivo (25,26). Although the mechanisms have not been fully elucidated, studies have shown that surface PD-L1 expression on some cancers is upregulated after a single high dose of radiation (23) or after lower doses of fractionated radiation (22,27). Here, we investigated combinations of TRT + ICIs against melanoma in mice to determine whether survival benefits might be equivalent to or exceed those for radiation + ICIs.
The B16F10 melanoma model is highly resistant to ICI monotherapy; however, therapeutic synergy was observed in this model when a single 20-Gy dose of radiation was combined with ICIs (5). Our current data do not show as dramatic a benefit for TRT + ICIs, likely because the number of tumor cells implanted previously (5) was 20-fold less than currently (5 × 104 vs. 1 × 106 cells). Additionally, radiation therapy was performed on day 8 in the previous study, when there most likely was a nonpalpable tumor, whereas here we started therapy after a tumor nodule had formed. The survival benefit of 3 or more days for TRT + ICIs compared with other therapies (Table 2) is modest; however, it reflects the impact of only single doses of each therapy. Additionally, the levels of apoptosis between TRT alone and TRT + ICIs is consistent with improved survival (Fig. 5).
Although radiation is often used to treat a range of localized tumors, it is not applicable for the treatment of disseminated, micrometastatic disease that cannot be visualized by standard radiologic techniques. TRT may represent an alternative systemic treatment for metastatic disease (28–30). Miao et al. investigated a 177Lu-DOTA–labeled α-melanocyte–stimulating hormone peptide in B16/F1 tumor–bearing mice (31). With a single dose of 37 MBq, they saw only modest improvement in survival (mean of 16.2 d, vs. 13.3 d for the control). We hypothesized that when TRT targeting VLA-4–positive melanoma and immune cells within the TME was combined with ICI, efficacy against B16 melanomas in mice would improve. In this regard, the presence of activated VLA-4 on melanoma cells correlates strongly with an aggressive, metastatic phenotype (32), as does expression of the VLA-4 integrin with melanoma progression or metastasis (32–35). Furthermore, 177Lu-LLP2A, a high-affinity peptidomimetic ligand, displays selective targeting in mouse models of melanoma (13), and therapeutic efficacy is enhanced when this agent is combined with ICI therapy.
On the basis of flow cytometry data, the B16F10 tumors consisted of 75% tumor cells and fibroblasts (CD45-negative/CD49d-positive) and 23% immune cells (CD45-positive/CD49d-positive), and the immune cells showed higher levels of VLA-4 expression in vivo (Fig. 6). These experiments support the high avidity and specificity of LLP2A within the TME, targeting macrophages, T cells, and B cells. Although the percentage of B cells in the tumor is lower than that of T cells and macrophages, B cells have a high binding capacity for Cy3-LLP2A based on flow cytometry data. Immunofluorescence microscopy data from tumors in mice injected in vivo with Cy3-LLP2A suggest that CD68-positive cells are most commonly CD49d-positive (α4 integrin subunit) and bind Cy3-LLP2A (Fig. 6A). The high numbers of tissue-associated macrophages correlate with strong Cy3-LLP2A staining, suggesting colocalization in macrophages, consistent with results reported for tuberculosis granulomas in a macaque model (15).
The immune response appears critical in protecting the host against the development, progression, and metastasis of tumors and is responsible for immunoediting and immune surveillance (36). Studies have also shown that certain immune cells in the TME can promote tumor progression and metastasis, suggesting dual roles for immune cells in the TME (37,38). CD8-positive T cells and natural killer cells are both well appreciated for their abilities to prevent or limit cancer metastasis (39,40). Conversely, regulatory (VLA-4–positive) immune cell populations may facilitate tumor metastasis through their immunosuppressive and proangiogenic activities (14,41). Indeed, VLA-4–positive myeloid cells have been reported to play a crucial role in mediating protumorigenic signals in nearly every aspect of cancer progression (42). In this regard, our data advance the field by providing important information on the types of VLA-4–positive immune cells found in the progressive TME, as well as on the relative abundance of VLA-4 expression among the various types of immune cell infiltrates.
VLA-4–targeted TRT to immune-cell–rich tissues (spleen, thymus, bone marrow) elicits concern about a collateral negative impact on the targeting of T cells. We moved forward with these studies despite this issue, as immune cells will regenerate, and in cases of extreme tumor burden in metastatic melanoma, damage to organs such as the spleen can be tolerated to save the patient. Conversely, transient ablation of VLA-4–positive T cells has the positive impact of allowing for their compensatory homeostatic expansion and the development of a more effective, less exhausted antitumor immune response, such as has been reported for nonmyeloablative, lymphodepletion regimens (43). Future studies will determine the extent to which 177Lu-LLP2A damages protective versus regulatory immune cells in the TME as well as damage to normal tissues such as spleen, thymus, and bone marrow.
CONCLUSION
The data presented here suggest a therapeutic advantage (and no discernable toxicity) to combining TRT and ICIs in mice with well-established B16F10 melanomas. We believe that systemically delivered TRT may have advantages over external-beam irradiation in treating disseminated disease, leading to improved overall survival in patients with metastatic melanoma. However, further preclinical studies are warranted to determine the optimum dose regimen (single vs. multiple doses of TRT) and the timing of the 2 therapies.
DISCLOSURE
This work was funded by National Institute of Health grants R01 CA204018 (Carolyn Anderson) and P50 CA121973 (Skin and Melanoma SPORE, John Kirkwood, principal investigator) and used the UPMC Hillman Cancer Center Animal Facility, In Vivo Imaging Facility, and Biostatistics Facility (NCI P30 CA047904). No other potential conflict of interest relevant to this article was reported.
Acknowledgments
We acknowledge Kathryn Day and Joseph Latoche for assistance with preclinical PET/CT imaging, Solomon Johnson for apoptosis data analysis, Jessie Nedrow for assistance with the initial therapy studies, and John Kirkwood for helpful discussions.
Footnotes
Published online Jun. 29, 2018.
- © 2018 by the Society of Nuclear Medicine and Molecular Imaging.
REFERENCES
- Received for publication February 6, 2018.
- Accepted for publication May 31, 2018.