1. Introduction
Soft-tissue sarcomas (STS) represent approximately 1% of cancers in adults and 15% in children, and are among the most devastating of human malignancies. Indeed, despite adequate loco-regional treatment, up to 40% of patients will develop metastatic disease. Doxorubicin-based chemotherapy has been the mainstay of treatment in the advanced setting for many years; however, the median overall survival of patients is only 12–18 months. This poor outcome is in part explained by the limited sensitivity of STS to cytotoxic drugs [1]. Despite several attempts to identify new therapeutic strategies, there has been no significant improvement in the overall survival (OS) [2]. Therefore, there is an urgent need to assess new drugs with the potential to improve patient outcomes.
STS are characterized by high stromal content which may play a crucial role in resistance to chemotherapy. Several lines of evidence indicate that extracellular matrix (ECM) proteins produced by cancer-associated fibroblasts (CAF) impair chemotherapy delivery and create an immunosuppressive context that promotes progression of several solid tumors [3,4,5,6]. Therefore, the addition of anti-stroma therapies is expected to increase efficacy of chemotherapy and improve patient outcome.
LRRC15, a 581 amino acid type I membrane protein with no obvious intracellular signaling domains, has recently been reported as a marker of cancer-associated fibroblasts [7]. This protein has been found to be highly expressed on CAFs within the tumor stroma of many tumor types, as well as directly on cancer cells in tumors of mesenchymal origin such as sarcomas [7]. Moreover, ABBV-085, a monomethyl auristatin E (MMAE)-containing antibody–drug conjugate (ADC) designed to target against LRRC15, has shown significant anti-tumor activity in several LRRC15 stromal-positive or cancer-positive models [7].
We report here the first detailed evaluation of the expression and prognostic impact of LRRC15 in STS as well as the preclinical activity of ABBV-085 in patient-derived xenograft models of STS. 2. Materials and Methods 2.1. Study Reagents
ABBV-085 (therapeutic anti-LRRC15 ADC), Isotype-ADC, LRRC15 mAb-1 (anti-LRRC15 antibody for flow cytometry), Isotype antibody IgG1 (antibody control for cytometry), and LRRC15 mAb-5 (anti-LRRC15 antibody for IHC and Western Blot (WR) were supplied by AbbVie (Redwood City, CA, USA) [7].
2.2. Patients and Samples We analyzed the expression of LRCC15 by immunohistochemistry in three independent cohorts of primary STS: (i) one cohort comprising 410 patients with STS harboring complex genomic aberrancies (tissue microarray), (ii) one cohort of 87 patients with leiomyosarcoma (LMS) (tissue microarray), (iii) one cohort including 214 patients with different histotypes of STS (whole slide). All the cases were reviewed by a pathologist expert in the field of soft-tissue tumors. 2.3. Immunohistochemistry (IHC) IHC on cryosection xenograft tissues fixed with cold acetone was performed using Dako REALTM EnVisionTM Detection System, Peroxidase/DAB+, Rabbit/Mouse (K5007). Macrophages were stained with rat anti-mouse F4/80 (BD bioscience, BD 552958, 1/100 overnight). A fixative rabbit monoclonal [R18-2] anti-rat IgG Fc (ab125900, 1/2000, 1 h) was used before adding secondary antibody anti-rabbit IgG coupled with HRP (Horse Raddish Peroxydase). DAB (3,3′-Diaminobenzidine) was used to detect bound primary antibodies. Dako Hematoxylin was used to counter stain nuclei. Images were acquired on a Panoramic 250 Flash III Digital Slide Scanner (3DHISTECHTM). IHC for LRRC15 expression on human tumor samples (LRRC15 mAb-5, 1 µ/mL, 40 min) was performed with Ultraview/Ventana system after a CC1 light (cell conditioning 1 light) process (96 °C, 36 min). LRRC15 expression was assessed blindly by a soft tissue pathologist (P.R.) using the H-score. This score is obtained by multiplying the percentage of total positive cells by the predominant staining intensity (scored from 0 for “no signal” to 3 for “strong signal”), 300 values are therefore possible. The total tumor area and the stromal compartment (fibroblasts, endothelial cells, inflammatory cells, and extracellular matrix) within this surface was evaluated in all cases. 2.4. In Vivo Studies Patient derived xenografts: independent in vivo experiments were performed in two different animal facilities (Dana Farber Cancer Institute and Institut Bergonié) to verify the reproducibility of the efficacy results. Experiments were performed on NOD scid gamma (NSG™) mice, following approval of the Institutional Animal Care and Use Committee (IACUC) in an AAALAC-accredited vivarium and at the University of Bordeaux, respectively. The activity of ABBV-085 was tested in six sarcoma patient-derived xenograft models including liposarcoma (DDLPS), leiomyosarcoma and undifferentiated sarcomas (UPS) with varying LRRC15 expression. Surgical samples were obtained from patients following their consent according to the Institutional Review Board-approved protocol of Dana Farber Cancer Institute (IRB-23KN54) and Institut Bergonié (IRB-2018C4), respectively. Tumor fragments dipped in Matrigel (Fisher Scientific, NH) were maintained subcutaneously by serially passaging in NSG mice. For efficacy study, tumors were allowed to establish to 200 ± 50 mm3 in size before randomization into various treatment groups with 7–9 mice per group. Isotype-control, isotype-MMAE, and ABBV-085, diluted in PBS were administered at 6 mg/kg once every 4 days intraperitoneally for a total of six injections. Tumor volumes were determined from caliper measurements by using the formula V = (length × width2)/2. Tumor sizes and body weight were measured twice weekly. Mice were treated over 24 days, followed by measuring for re-growth of tumors. 2.5. Statistical Analysis The statistical analysis of baseline demographics and clinical outcomes is based on all data available up to the cut-off date of 31 December 2017. Survival rates were estimated with the Kaplan–Meier method. Differences between groups were evaluated by the χ2 test or Fisher’s exact tests for categorical variables and t-tests for continuous variables. Univariate and multivariate analyses with a Cox regression model were used to identify prognostic factors. Variables tested in univariate analysis included age; gender; tumor site (limb versus other); tumor location (deep versus superficial); histological grade; and tumor size. Variables associated with PFS at p < 0.05 in the univariate analysis were included in the multivariate regression. Analyses were performed using SPSS 19.0 statistical software (IPSS Inc., Chicago, IL, USA). All statistical tests were two-sided, and p < 0.05 indicated statistical significance. 3. Results 3.1. LRRC15 Is Highly Expressed in Several Histological Sarcomas Subtypes
We analyzed LRRC15 protein expression by IHC in 711 cases of STS, including gastrointestinal stromal tumors (GIST). The specificity of the antibody used was already extensively tested on several positive/negative tumor cell lines, and assessed by orthogonal methods (Western blotting/flow cytometry) and using CRISPR technology [7]. In contrast to the patterns observed in epithelial tumors, LRRC15 was expressed not only by normal stromal (predominantly fibroblasts) cells but also by cancer cells. Results are described in Table 1 and illustrated in Figure 1. The proportion of LRRC15-positive cases differed significantly according to histological subtypes with staining observed in 51%, 47%, and 36% of UPS, dedifferentiated liposarcomas and leiomyosarcomas, respectively (p = 0.003). UPS was the histological subtype with the highest proportion of strong expression (25%) followed by leiomyosarcomas (19%) and dedifferentiated liposarcomas (14%), p = 0.06. The proportion of LRRC15-positive cases among myxofibrosarcomas was significantly lower in comparison to other histological subtypes such as UPS (19%, p < 0.0001) (Table 1). A total of 424 cases have available histological grade data. LRRC15 expression was also correlated with histological grade. Additionally, 21% of grade 3 tumors are characterized by a high expression of LRRC15 versus only 10% of grade 2 tumors and 6% of grade 1 tumors, p < 0.001 (Supplementary Table S1).
3.2. High Expression of LRRC15 by Sarcomas Cells Is Associated with Adverse Outcome
By analyzing the LRRC15 expression profile of a series of 425 STS with available clinical data (Table S1), we found that high LRRC15 expression was significantly associated with worse metastases-free survival in multivariate analysis (Figure 2 and Table 2). As described in Figure 2, LRRC15 sarcoma cell expression provided extra information to further refine the prognosis of patients besides histological grade which is considered the most significant predictor of outcome.
3.3. ABBV-085 Has Anti-Tumor Activity in LRRC15-Positive Sarcoma Models
Given the high significant expression of LRRC15 by sarcoma cells and its prognostic impact, we assessed the efficacy of ABBV-085, the first-in-class antibody–drug conjugate (ADC) directed against LRRC15, in several patient-derived xenograft models of UPS, LMS, and DDLPS. As shown, in Figure 3, ABBV-085 demonstrated significant antitumor activity in multiple LRRC15 STS-positive models. For the UPS (Supplementary Figure S1) and LMS models, treatment with ABBV-085 resulted in significant tumor growth inhibition and tumor growth delay compared with isotype control and cytotoxic control groups. Interestingly, in the UPS models (where the highest LRRC15 expressions were observed), profound tumor regressions were observed, with complete tumor regression and no tumor regrowth during extended monitoring period, including one model (JR588) which was refractory to STS current therapies (doxorubicin, ifosfamide, gemcitabine) (Supplementary Figure S1). Tumor growth inhibition was associated with a dramatic reduction in the number of LRRC15-expressing tumor cells (Supplementary Figure S3). In models with no LRRC15 expression (0% positivity), minimal tumor growth inhibition and no significant differences were observed between any of the treatment arms in these groups.
4. Discussion
We report here the first large study assessing LRRC15 expression in mesenchymal malignancies (soft-tissue sarcomas) and its potential therapeutic application in this indication. LRRC15 has been shown to be highly expressed on CAFs within the tumor stroma of many epithelial tumors. By analyzing a small cohort of 39 STS, we have also observed that LRRC15 can also be directly expressed on cancer cells from mesenchymal tumors [7]. Consistent with these first results, we found LRRC15 to be expressed by cancer cells in up to 36% of STS with significant differences across histological subtypes (Table 1, Figure 1). For instance, 50% of UPS expressed LRRC15 versus 19% only for myxofibrosarcoma. Historically, MFS was considered a subset of UPS (“myxoid malignant fibrous histiocytoma”), but more recently, MFS and UPS have been classified as distinct tumor types based on their different clinico-pathologic characteristics [8]. MFS has prominent myxoid stroma and is often lower grade and prone to local relapse, while UPS is generally higher grade, more cellular, and prone to distant metastasis and worse outcome. The molecular determinants of such differences in expression between histological subtypes remains to be elucidated. However, this may be related to differential expression of transforming growth factor β (TGF-β) between histological subtypes. Indeed, LRRC15 expression is tightly regulated by TGF-β [7]. TGF-β is a multifunctional growth factor that variably affects proliferation, differentiation, and extracellular matrix formation, resulting in an immunosuppressive microenvironment. Although there is no large dataset describing the expression of this protein in STS, recent studies have shown a strong expression in UPS whereas expression is reported to be low in MFS [9,10]. Interestingly, we also found a differential expression of LRRC15 according to grade with a higher expression in grade 3 versus grade 1 or 2 tumors. Strikingly, high expression of LRRC15 has an independent prognostic value. Whether this adverse prognostic impact is linked to activation of cell-autonomous growth pathways and/or modification of the tumor microenvironment will require additional investigations.
We have demonstrated ABBV-085 monotherapy activity in all LRRC15 positive patient-derived xenograft (PDX) models of STS, even in highly chemo-refractive indications such as UPS (PDX; Supplementary Figure S1) with poor treatment options and survival [1]. Interestingly, we found in several models that tumors do not regrow even several weeks after the last administration of ABBV-085. Despite the obvious efficacy of ABBV-085 to reduce tumor growth in tumors with high expression of LRRC15, we could observe, in some STS PDX models, a similar activity with the non-binding control (hIgG-MMAE). This observation could be explained by the cross-reactivity of ABBV-085 in mice compared with the non-mouse cross reactive isotype-MMAE (resulting in a significantly shorter half-life of ABBV-085 compared with isotype = MMAE, ≈2–3 days vs. 10+days, respectively). However, previous studies suggest that tumor-associated macrophages (TAMs) are involved in the antitumor activity of ADC through FcγR interaction [11]. In order to test this hypothesis, we assessed the level of macrophage infiltration in the UPS JR588 PDX model by using IHC and found a strong infiltration (Supplementary Figure S2). This suggests that as reported for other ADCs, TAM may contribute to the anti-tumor activity of ABBV-085. We have recently reported the importance of TAM infiltration in STS, its prognostic impact as well as its role in primary resistance to PD1 inhibition [12,13]. ABBV-085 has been shown to increase immune infiltration in preclinical models [7]. Further studies should focus on the role of TME in the anti-tumor activity of LRRC15 targeting in sarcomas as well as the potential therapeutic values of strategies combining ABBV-085 with PD-1 or PD-L1 inhibition particularly in UPS, which appears to be one of the STS subtypes that is the most sensitive to such immune checkpoint inhibitors [14].
Recently, results of a phase 1, first-in-human, clinical trial of ABBV-085 monotherapy in patients (patients) with advanced solid tumors (NCT02565758) were presented [15]. A total of 78 patients were enrolled in this study, of which 27 patients with advanced sarcomas UPS (n = 10), osteosarcoma (n = 10), other sarcomas (n = 7) were treated in the dose-escalation (n = 8) or dose-expansion cohorts (n = 19). Overall, ABBV-085 was well tolerated, with grade ≥3 treatment-emergent adverse events reported in 56 (71.8%) patients (most commonly anemia (14.1%)), and dose-limiting toxicities of anemia (n = 1), hypertriglyceridemia (n = 1), and ileus and nausea (n = 2). Of the 27 sarcoma patients, four (14.8%) had confirmed partial response and eight (29.6%) had stable disease, with a median duration of response (confirmed responders) of 7.6 months.
In summary, LRRC15 represents a promising new therapeutic target in STS based on these data. ABBV-085 is a first-in-class stromal targeting ADC which was well-tolerated in a phase 1 study in patients with advanced sarcomas, with durable partial responses observed in these patients. Given its efficacy and safety profile, further combinations of ABBV-085 with immune checkpoint inhibitors are very intriguing, particularly in UPS, which appears to be one of the STS subtypes that is the most sensitive to ABBV-085 and PD-1/PD-L1 checkpoint inhibitors.
Enlarge this image.Figure 1. LRRC15 staining obtained by immunohistochemistry for different histological subtypes of soft-tissue sarcomas (STS) with different level of expression in cancer cells and stroma. (A) Examples of STS with a significant expression in cancer cells. (B) Examples of STS without expression of LRRC15 in cancer cells but with an expression in the surrounding stroma. Staining was predominantly seen in spindle cells (fibroblasts) and in the extracellular matrix. (C) Examples of STS without expression of LRRC15.
Enlarge this image.Figure 2. Kaplan-Meier curves of metastases-free survival according LRRC15 expression. (A) Kaplan-Meier curves of metastases-free survival according to LRRC15 expression score in a cohort of 425 patients with soft-tissue sarcoma (green line: LRRC15 H score > 160, blue line: LRRC15 H score ≤ 160). (B) Kaplan-Meier curves of metastases-free survival according to LRRC15 expression (green line: LRRC15 H score > 160, blue line: LRRC15 H score ≤ 160) in patients with grade 3 STS.
Enlarge this image.Figure 3. In vivo anti-tumor activity of ABBV-085 monotherapy in STS. (A,B) Tumor growth curves for liposarcoma models LPS15 (A: LRRC15 positive) and LPS28 (B: LRRC15 negative) treated with ABBV-085. (B) Tumor growth curves for leiomyosarcoma models LMS33 (C: LRRC15 cancer positive) and LMS20 (D: LRRC15 negative) treated with ABBV-085. A total of 7-9 mice/group of treatment. For each model, a figure indicating the level LRRC15 expression in the parental tumor from which the patient-derived xenograft (PDX) was derived is represented.
| Cancer Type | n | Cancer Cell Positivity: LRRC15 IHC Score (n = 711) | Cancer Cell and/or Stroma Positivity: LRRC15 IHC Score (n = 711) | |||||
|---|---|---|---|---|---|---|---|---|
| 0% cells | <2+ and/or ≤ 50% cells | ≥2+ and >50% cells | Strong Positivity (%) | 0+ | ≥1+ | Median Score | ||
| Soft-Tissue Sarcomas | 711 | 452 | 143 | 116 | 299 | 412 | ||
| UPS | 142 | 70 | 36 | 36 | 25 | 46 | 96 | 175 CI: 120–225 |
| Leiomyosarcoma | 288 | 184 | 48 | 56 | 19 | 124 | 164 | 270 CI: 195–290 |
| Liposarcoma | 72 | 38 | 24 | 10 | 14 | 29 | 43 | 60 CI: 45–80 |
| Myxofibrosarcoma | 68 | 55 | 8 | 5 | 7 | 36 | 32 | 110 CI: 80–140 |
| GIST | 76 | 68 | 8 | 0 | 0 | 48 | 28 | 80 CI: 70–100 |
| Rhabdomyosarcoma | 17 | 14 | 2 | 1 | 6 | 8 | 9 | 20 CI: 5–35 |
| Other | 48 | 23 | 17 | 8 | 17 | 8 | 40 | 150 CI: 110–175 |
CI: confidence interval, UPS: undifferentiated pleomorphic sarcomas, GIST: gastrointestinal stroma tumor.
| HR | p | |
|---|---|---|
| Tumor size < 5 cm | 0.49 | 0.0034 |
| Histological subtype | ||
| Leiomyosarcoma | 1.74 | 0.001 |
| FNCLCC grade | ||
| Grade 1 | 0.26 | 0.039 |
| Grade 2 | 0.67 | |
| LRRC15 IHC score | ||
| >160 (median score) | 0.66 | 0.043 |
Supplementary Materials
The following are available online at https://www.mdpi.com/2072-6694/12/3/757/s1, Figure S1: Preclinical activity of ABBV-085 in LRRC15-positive UPS patient derived xenograft models, Figure S2: Immunohistostaining of macrophages (F4/80) on PDX JR588 paraffin slices of treated mouse by (A) Vehicle, (B) Isotype ADC, (C) ABBV-085 antibody, Figure S3: LRRC15 expression on PDX JR588 paraffin slices of treated mouse by (A) ABBV-085, (B) Vehicle (C) Isotype. Table S1: LRRC15 expression according to grade.
Author Contributions
A.I., E.B.-A., G.D.D. and J.P. designed and coordinated the study. E.B.-A., Y.H., F.C., P.C.G., A.L.-C., B.K.E., M.-P.A. carried out the in vitro and in vivo experiments. R.P., V.V. and F.L.L. did the immunohistochemistry analysis. A.I., E.B. and J.P. drafted the manuscript. All authors read and approved the final manuscript.
Funding
This research was funded by the SIRIC BRIO
Conflicts of Interest
J.W.P. is employee of AbbVie. AbbVie participated in the interpretation of data, review, and approval of the publication. G.D.D. has received a research grant from AbbVie.
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Eytan Ben-Ami1, Raul Perret2, Ying Huang1, Félicie Courgeon3,4, Prafulla C. Gokhale1, Audrey Laroche-Clary3,4, Benjamin K. Eschle1, Valérie Velasco2, François Le Loarer2, Marie-Paule Algeo5, James Purcell6, George D. Demetri1,7,† and Antoine Italiano3,4,5,*,†
1Sarcoma Division, Department of Medical Oncology, Dana-Farber Cancer Institute, Boston, MA 02215, USA
2Department of Pathology, Institut Bergonié, 33000 Bordeaux, France
3Sarcoma Unit, Institut Bergonié, 33000 Bordeaux, France
4INSERMU1218, 33000 Bordeaux, France
5University of Bordeaux, 33400 Talence, France
6AbbVie Biotherapeutics, Redwood City, CA 94063, USA
7Ludwig Center at Harvard, Harvard Medical School, Boston, MA 02215, USA
*Author to whom correspondence should be addressed.
†These two authors contributed equally to the work.
© 2020. This work is licensed under http://creativecommons.org/licenses/by/3.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
Details
; Huang, Ying; Courgeon, Félicie; Gokhale, Prafulla C; Laroche-Clary, Audrey; Eschle, Benjamin K; Velasco, Valérie; François Le Loarer; Algeo, Marie-Paule; Purcell, James; Demetri, George D; Italiano, Antoine