Cutaneous melanoma is a highly aggressive cancer with a propensity for distant metastasis to various organs. In contrast, melanoma arising in pigmented uveal layers of the eye metastasizes mostly in the liver. The mechanisms of these metastases, which are ultimately resistant to therapy, are still unclear. Metastasis via intravascular dissemination of tumour cells is widely accepted as a central paradigm. However, we have previously described an alternative mode of tumour dissemination, extravascular migratory metastasis, based on clinical and experimental data. This mechanism is characterised by the interaction of cancer cells with the abluminal vascular surface, which defines angiotropism. Here, we employed our 3D co-culture approach to monitor cutaneous and uveal human melanoma cells dynamics in presence of vascular tubules. Using time-lapse microscopy, we evaluated angiotropism, the migration of tumour cells along vascular tubules and the morphological changes occurring during these processes. Cutaneous and uveal melanoma cells were injected in zebrafish embryos in order to develop xenografts. Employing in vivo imaging coupled with 3D reconstruction, we monitored the interactions between cancer cells and the external surface of zebrafish vessels. Overall, our results indicate that cutaneous and uveal melanoma cells spread similarly along the abluminal vascular surfaces, in vitro and in vivo.
Metastasis is described as the spread of cancer cells from the original (primary) tumour to a different (secondary) site. Metastasis via intravascular or intralymphatic dissemination of tumour cells is widely accepted as a central paradigm. However, in our previous work, we have described an alternative mode of tumour dissemination without intravasation, namely extravascular migratory metastasis (EVMM), based on clinical1,2 and experimental3,4 data in cutaneous melanoma and on clinical data in uveal melanoma5. This mechanism is characterised by the interaction of tumour cells with the external vascular surface, which defines angiotropism. This process is described histologically by the presence of tumour cells disposed along the external surface of vascular structures in a ‘pericytic location’ without intravasation1. Since the very first description of angiotropism, it was stressed that angiotropic melanoma cells were connected to the endothelium thanks to an amorphous basement membrane containing laminin6. Interestingly, it is possible to identify angiotropism either at the invasive front of the tumoural mass or in neighbour tissues. Angiotropism promotes pericytic mimicry, the replacement of pericytes by tumour cells spreading along the abluminal surfaces of vessels, as exhibited in various in vitro and in vivo models3,4,6. Employing our 3D co-culture model of pericytic mimicry and angiotropism7, we have previously demonstrated that the interaction between endothelial cells and cutaneous melanoma cells triggered differentially-expressed genes linked to cancer progression; interestingly, ten of these genes were also associated with inflammation6. Notably, in a collaborative study we showed that UV-induced inflammation promotes pericytic mimicry, angiotropism and eventually metastasis in a genetically engineered murine melanoma model4. The current study corroborates the involvement of processes such as angiotropism and pericytic mimicry in cutaneous and uveal melanoma progression and metastasis.
Both cutaneous and uveal melanomas are derived from melanocytes, which originate from the neural crest. Despite this common origin, cutaneous and uveal melanomas show two distinct genetic profiles. Cutaneous melanoma is regarded as one of the most serious forms of skin cancer because it may metastasize to many distal organs, such as the lungs, liver and brain. Originally, it was considered as a homogeneous condition with a generally poor prognosis, but further and more detailed studies led to the description of a number of distinct subtypes with diverse clinicopathological peculiarities. In particular, four principal subtypes were identified, based on the preferred site of origin of the tumour, relative amount of ultraviolet (UV) light exposure and duration of pre-invasive growth. These are superficial spreading, nodular, lentigo maligna, and acral lentiginous melanomas8. BRAF and NRAS genes, which encode mitogen-activated protein kinase (MAPK) pathway constituents, are recurrently mutated in cutaneous melanoma. The frequency of BRAF and NRAS mutations differs among the cutaneous melanoma subtypes9.
Uveal melanoma is the most common intraocular malignancy and arises in the pigmented layers of the eye. Up to 50% of the patients develop metastasis, mostly in the liver (approximately 90%). Primary uveal melanoma can be cured by surgery (enucleation) or radiotherapy, but the metastatic setting is refractory to treatments10. Compared to other solid tumours such as cutaneous melanoma, uveal melanoma shows a remarkably low mutation burden; indeed, it does not display the UV radiation DNA-damage signature, observed in the majority of melanoma. Mutually exclusive mutations in GNAQ or in GNA11, the principal driver oncogenes in uveal melanoma, occur in approximately 85% of cases11,12,13. Moreover, inactivating mutations in the tumour suppressor BAP1 occur in ~85% of metastatic tumours and are associated with disease dissemination14 and poor prognosis.
In this study, employing our 3D co-culture approach7 and time-lapse microscopy, we evaluated angiotropism and migration of cutaneous and uveal melanoma cells along the vascular tubules and the morphological changes occurring during these processes.
Cutaneous or uveal melanoma cell lines were injected in 2-days-post-fertilization (dpf) zebrafish embryos in order to develop xenograft models of human cutaneous and uveal melanoma.
The zebrafish could be considered as an excellent model system for our purpose, due to various useful characteristics15. Specifically focusing on cancer, zebrafish has the benefit to show high conservation of tumour suppressor genes and (proto-) oncogenes with humans; for this reason, it is an ideal model to identify both novel therapeutic compounds and clinically relevant genes16,17. Moreover, zebrafish xenografts show histopathological and gene-profiling features similar to the ones of human tumours18. In addition, the adaptive immune system of zebrafish reaches maturity just after 4 weeks post fertilization19,20; therefore, the use of zebrafish at embryonic and larval stages permits to avoid graft rejections. This feature has been previously exploited to perform xenotransplantation with human cancer cells, including melanoma cells, without immunosuppression21,22,23. Moreover, the availability of different tissue-specific fluorescent reporter transgenic lines, combined to the optical transparency of zebrafish, permits the detection of tumour masses within one week and offers the possibility to perform high resolution, non-invasive live imaging of fluorescently labelled cancer cells24,25,26.
Employing in vivo imaging coupled with 3D reconstruction, we explored and monitored the interactions between cutaneous/uveal melanoma cells and the external surface of zebrafish vessels. Our work provides the first models of angiotropism and extravascular migratory metastasis of cutaneous and uveal melanoma in zebrafish.
Animal care and handling
In this study, we used the zebrafish transgenic line Tg(kdrl:Hsa.HRAS-mCherry), expressing mCherry in endothelial cells27. The animals were maintained according to standard protocols (http://ZFIN.org). All the experiments were performed in accordance to the European and the French National Regulation for the Protection of Vertebrate Animals used for Experimental and other Scientific Purposes (Directive 2010/63; French Decree 2013–118). According to this Directive, early life-stages of zebrafish are not protected as animals until the stage of being capable of independent feeding, namely after 5 days post fertilization, which is later than the endpoint of our experiments. This study was approved by the French Ministry of Higher Education and Research (Reference: APAFIS#6031-20 16070822342309 v2).
The cutaneous melanoma cell line C8161-GFP28 was a gift from Dr. D. Welch (University of Kansas, Medical Center, USA). The uveal melanoma cell lines OMM 2.3 and OMM 2.5 were kindly provided by Dr. P.A. Van Der Velden (Leiden University, The Netherlands). They were both established in the Schepens Eye Research Institute (The Massachusetts Eye and Ear Infirmary, Harvard Medical School, Boston) from a liver metastasis in the same patient29. C8161-GFP cells were cultured in Dulbecco’s modified Eagle’s medium (Gibco, 41965-039) with 10% fetal calf serum and 1% Pen-Strep (Gibco, 15140-122) at 37 °C and 5% CO2. Human umbilical vein endothelial cells (HUVEC, Lonza C2519A) were grown in EBM-2 Endothelial Growth Basal medium (Lonza, CC-3156), supplemented with EGM-2 SingleQuots Kit (Lonza, CC-4176), at 37 °C and 5% CO2. OMM 2.3 and OMM 2.5 were cultured in RPMI-1640 medium (Gibco, 21875-034), with 10% fetal calf serum and 1% Pen-Strep (Gibco, 15140-122), at 37 °C and 5% CO2.
The non-malignant human melanocyte cell line Hermes 2B30 was kindly provided by Prof. D. Bennett (St George’s, University of London, UK). Hermes 2B were cultured in RPMI-1640 medium (Gibco, 21875-034), supplemented with 10% fetal calf serum, 200 nm 12-O-Tetradecanoylphorbol 13-acetate (Sigma, P8139), 200 pM Cholera toxin (Sigma, C8052) and 10 nM Endothelin 1 (Bachem, 6995), at 37 °C and 5% CO2.
OMM 2.3, OMM 2.5 and Hermes 2B cells were infected with lentiviral particles expressing the Green Fluorescent Protein (GFP) and a Puromycin-resistance cassette. The particles were obtained via triple transfection of HEK-293T cells with lentiviral plasmid pLVX-EF1α-AcGFP1-N1 (Clontech, 631983), packaging plasmid psPAX2 (Addgene, 12260) and VSV-G envelope expressing plasmid pMD2.G (Addgene, 12259). After the infection, the cells were selected for 3 days in complete growth medium containing 1.5 μg/mL Puromycin for OMM 2.3, 1 μg/mL Puromycin for OMM 2.5 and 10 μg/mL Puromycin for Hermes 2B. Infection of cells with GFP-Puromycin viruses did not noticeably mutate the morphology and the growth properties of the cells. All our experiments in zebrafish were performed with respect to the restrictions of use of these cell lines.
3D co-culture matrigel assay
For the endothelial tubule model assay, 24 wells plates (TPP Z707791) were coated with 100 μl of basement membrane extract (Cultrex PathClear, Trevigen 3533-001-02) and incubated at 37 °C for 30 min to promote the polymerization of the gel. 40,000 human endothelial cells (HUVEC, Lonza C2519A) were added to each well and let form the tubular structures overnight. After 12-14 hours, 10,000 C8161-GFP, OMM 2.3-GFP, OMM 2.5-GFP or Hermes 2B-GFP cells were carefully plated on the endothelial tubules network. The co-cultures were then incubated approximately 2 hours at 37 °C and subsequently imaged up to 24 hours, using IncuCyte® S3 Live-Cell (ESSEN Bioscence), employing a dry 20 × objective. Images were then processed with the Incucyte, ImageJ and Adobe Illustratore software.
Human cancer cells injections in zebrafish embryos
Before injections, zebrafish embryos were kept at 28 °C and manually dechorionated few hours before the injection. Melanoma cells were grown to 80–90% confluency, washed one time with PBS and trypsinised (0.25% trypsin/0.53 mM EDTA) to obtain a single cell suspension. Cells were then centrifuged for 5 minutes at 1000 g and resuspended in RPMI-1640 (for uveal melanoma lines and Hermes 2B) or DMEM medium (for cutaneous melanoma lines), in order to reach a final concentration of 6,000–10,000 cells/μl. At 2 dpf, the larvae were anesthetised with 0.004% tricaine and positioned flanking on one side on a 10-cm Petri dish coated with 2% agarose. Cells were injected using glass capillary needles with an approximate opening equal to the dimension of one cell. 300 to 500 cells were injected into the yolk sac, using a pneumatic pico pump and a manipulator. The number of cells was determined by measuring the size of the drop of suspension injected. After the injection, embryos were incubated to recover for at least one hour at 28 °C and then maintained in egg fish water at 34 °C. This temperature was chosen as an intermediate temperature between 37 °C (optimal for cell lines) and 28 °C (optimal for zebrafish embryos and larvae), in order to permit a normal development of the larvae21, without impairing melanoma growth and migration.
Starting from 30 hours post injection (hpi), embryos showing melanoma cells that had migrated were selected using a Leica MZ FLIII stereomicroscope (Leica) equipped with a Leica DFC310FX digital camera (Leica). Zeiss LSM 700 confocal microscope or Zeiss LSM 880 microscope (Zeiss) were used, employing a 25 × oil, a 40 × water immersion or a 63 × water immersion objective. For confocal microscopy, larvae were anesthetised in egg fish water containing 0.02% tricaine, immobilised in 1.2% low-melting agarose and then imaged up to 12 hours (one acquisition every 15–25 minutes), using 488 and 568 nm lasers. Z-volumes were acquired with a 1- to 2-μm resolution and images were processed using ImageJ, Imaris-Bitplane, Zen Blue and Adobe Illustrator software.
Histopathology of human cutaneous and uveal melanoma samples
Formalin-fixed-paraffin-embedded (FFPE) 5-μm sections from primary cutaneous invasive melanoma and recurrent primary uveal melanoma were de-paraffinized and stained respectively with hematoxylyn eosin or with hematoxylin eosin saffron.
The cutaneous melanoma lesion was excised from the upper back of a 33-year-old woman. The histopathologic examination of this lesion revealed a primary cutaneous invasive melanoma of the superficial spreading type, with Breslow thickness of 0.84 mm, absence of ulceration and mitotic rate of 2 per mm2. By contrast, the uveal melanoma sample originated from the left eye of a 56-year-old woman, presenting a lesion of 16 mm in greatest diameter. Six years after radiation therapy the patient underwent enucleation for recurrent melanoma.
We confirm that all methods were performed in accordance with the relevant national guidelines and regulations. In accordance to the national law on the protection of individuals taking part in biomedical research, patients were informed by their referring oncologist that their biological samples could be used for research purposes and they gave their verbal informed consent. This study was approved by the institutional review board and ethics committee of the Institut Curie Hospital Group.
Data availability statement
The datasets generated during and/or analysed during the current study are available from the corresponding author upon request.
Angiotropism and extravascular migratory metastasis in cutaneous melanoma
A clinical example of primary cutaneous invasive melanoma with suspected angiotropism is shown in Fig. 1A,A’. Indeed, the melanoma cells were disposed in multi-layered aggregates along the external (abluminal) surface of a dermal microvascular channel at the advancing front of the primary tumour. The surrounding dermal collagen was stained in red (hematoxylin eosin staining). Melanoma cells (black arrowheads) directly aligned along the surfaces of the endothelial cells (identified by red arrows), showed a “pericytic” location. The remainder of melanoma cells displayed a concentric multi-layered appearance. Of note, intravasation of melanoma cells was not observed.
In order to characterise the capacity of cutaneous melanoma cells to spread along the external vascular surfaces, we monitored for up to 24 hours the behaviour of cutaneous melanoma C8161-GFP cells co-cultured in Basement Membrane Extracts (BME) with HUVEC. Real time imaging of this co-culture exhibited migration of cutaneous melanoma cells towards and along endothelial cells (Fig. 1B–F and Supplementary Video S1). Cutaneous melanoma cells began to attach to the tubular network just few hours after plating, as indicated by white arrows in Fig. 1B. Twenty-four hours after plating, 81.8% of tumour cells (27 out of 33) were distributed along the tubules, while only the 18.2% of them (6 out of 33) remained dispersed in the gel (yellow arrows, Fig. 1C). Notably, we also observed unique changes in the morphology of migrating melanoma, such as the formation of protrusions and the adoption of a more tapering shape (Fig. 1D–F and Supplementary Video S1). These morphological changes were not seen in stationary melanoma cells which remained rounded.
Angiotropism and extravascular migratory metastasis in uveal melanoma
A clinical case of a primary uveal melanoma with suspected angiotropism is shown in Fig. 2A,A’. Microscopic examination of the sample showed angiotropic melanoma cells (black arrowheads) aligned along the external (abluminal) surface of a vascular channel within the sclera of the ocular globe. This channel was lined by a single cellular layer of endothelium, identified by red arrows. The surrounding collagen-rich sclera of the ocular globe was stained in yellow-brown (hematoxylin eosin saffron staining). The melanoma cells positioned along the surfaces of the endothelial cells showed a “pericytic” location. As in the case of cutaneous melanoma, intravasation of melanoma cells was not detected.
In order to evaluate whether uveal melanoma cells could also migrate along the external vascular surfaces, we employed the 3D co-culture approach as described above. In line with what we observed for C8161-GFP cells, real time imaging of OMM 2.3-GFP or OMM 2.5-GFP cells co-cultured in BME with HUVEC cells, exhibited migration of uveal melanoma cells towards and along endothelial cells (Fig. 2B–M and Supplementary Videos S2 and S3). Indeed, the behaviour of both uveal melanoma cell lines was very similar to the one of cutaneous melanoma. Twenty-four hours after plating, the percentage of OMM 2.3-GFP and OMM 2.5-GFP cells disposed along the tubules was 77.8% (21 out of 27) and 81.2% (26 out of 32) respectively. Melanoma cells migrating on the tubular network showed an elongated and fusiform shape, as displayed in the zoomed-in images in Fig. 2D–F and Fig. 2I–M. As in the cutaneous melanoma case, the change of morphology was not observed in uveal melanoma cells, which remained stationary in the BME (yellow arrows, Fig. 2C,H).
Cutaneous and uveal melanomas show similar migration properties in vitro
We used IncuCyte S3 Live-Cell microscope to obtain several real-time videos of the 3D co-culture of melanoma cells/non-malignant melanocytes with endothelial cells. We then performed quantitative analysis of the migration properties of cutaneous, uveal melanoma and non-malignant melanocytes. First, we evaluated the percentage of tumour cells disposed along endothelial tubules 2, 12 and 24 hours after plating (Fig. 3A–D). For this purpose, at least 9 videos for each cell line were analysed. As shown in Fig. 3A, 2 hours after plating (starting time of all the videos), 38.13% of C8161-GFP cells were attached to the tubular structures, indicating high affinity between endothelial cells and melanoma cells. The percentage of cells disposed along the tubules was 66.96% at 12 hours and reached 76.58% 24 hours after plating (n = 16). These values are highly significant (P < 0.001) when compared to the percentage of cells attached to tubules during the first time-lapse of the video (2 hours). As shown in Fig. 3B, 40.73% of OMM 2.3-GFP cells were attached to the endothelial tubules after 2 hour, while 77.25% and 80.07% of cells were attached at 12 and 24 hours, respectively (n = 9).
Figure 3C shows the migration properties of a second uveal melanoma cell line, OMM 2.5-GFP. For this cell line, the fraction of melanoma cells distributed along the tubules at 2 hours was 39.48% and it increased up to 68.95% and 72.74% at 12 and 24 hours after plating, respectively (n = 13). In both uveal melanoma cell lines, the values obtained at later times were highly significant if compared with the first time-lapse (P < 0.001).
Figure 3D shows that the fraction distributed along the tubules of the non-malignant melanocytes Hermes 2B-GFP was 44.81% at 2 hours and increased up to 71.01% and 74.73% at 12 and 24 hours after plating, respectively (n = 10). Also in this case, the values obtained at later times were highly significant if compared with the first time-lapse (P < 0.001).
Therefore, the results obtained for cutaneous and uveal melanoma were comparable to the ones obtained for Hermes 2B-GFP, probably due to similar angiotropic properties of these cells.
We then quantified the velocity of melanoma cells involved in extravascular migration and compared it to the velocity of non-malignant melanocytes. For this purpose, the average velocity of at least 48 cells for each cell line was calculated, employing the Manual Tracking plug-in of the ImageJ software. As shown in Fig. 3E, the average values calculated for Hermes 2B-GFP, C8161-GFP, OMM 2.3-GFP and OMM 2.5-GFP cells were respectively 0.18 ± 0.056 µm/min (n = 48), 0.33 ± 0.1 µm/min (n = 73), 0.33 ± 0.12 µm/min (n = 50) and 0.29 ± 0.85 µm/min (n = 120). The migration velocities of melanoma cell lines were similar among each other and significantly different from the one of non-malignant melanocytes.
Angiotropism of cutaneous and uveal melanomas in zebrafish xenograft
We then wanted to compare the different migratory potential of melanoma cells and non-malignant melanocytes in vivo. For this purpose, C8161-GFP or Hermes 2B-GFP cells were injected in the yolk of zebrafish embryos two days post-fertilization (dpf), and the differential migration was evaluated via live imaging after 2–3 days post-injection (dpi). The experiment was performed 11 times using around 50 embryos each time, in the case of cutaneous melanoma, and 3 times injecting at least 60 embryos, in the case of non-malignant melanocytes. The strong migratory potential of uveal melanoma had already been evaluated in zebrafish embryos injected with OMM 2.3 or OMM 2.5 cells22. At 2/3-dpi only 50% of larvae injected with Hermes-GFP still displayed green fluorescence, while for the others no signal was detected. Additionally, migration outside the yolk cavity was not observed in larvae where green fluorescent cells were still detected. In striking contrast with what observed in non-malignant melanocyte xenotransplants, embryos injected with cutaneous melanoma showed cell migration, already after 30 hours from the injection.
A representative example of the comparison between a 3-dpi zebrafish larva injected with Hermes 2B-GFP melanocytes and a 2-dpi one injected with C8161-GFP cells is shown in Fig. 4. As displayed by the three images on the left (Fig. 4A-A”), non-malignant melanocytes remained confined in the yolk cavity, without spreading in the rest of the fish. By contrast, the images on the right (Fig. 4B-B”), show several cutaneous melanoma cells located in different parts of the embryo, such as for the eye, the heart and the tail fin.
We then wondered whether we could detect angiotropism and pericytic mimicry in embryos displaying C8161-GFP cells outside of the yolk sac. Therefore, the interactions between cutaneous melanoma cells and the external surface of zebrafish vessels were monitored via live imaging coupled with 3D reconstruction, starting from 30 hours after the injection. Figure 5 shows a representative example of a zebrafish larva displaying a striking angiotropic cell (indicated by the square). Indeed, this tumour cell was wrapped around the caudal vein of the larva, attached to the abluminal surface of the vessel. Interestingly, this cell showed unique changes in the morphology, such as the formation of pseudopodial protrusions and the adoption of a tapering shape. As displayed by the three time points presented (0, 4 h and 8 h) in Fig. 5B–D and the Videos S5 and S6, this cell exhibited cellular processes extending along the external surface of the caudal vein of the larva. During the 10-hour video, the angiotropic cell was slowly gliding on the surface of the vessel, without entering into the circulation. The 3D reconstruction of this video (Supplementary Video S7) confirmed the existence of a slow crawling movement of the melanoma cell on the vessel surface, implying pericytic mimicry and EVMM. Other examples of angiotropic cutaneous melanoma cells surrounding the zebrafish vessels are shown in Supplementary Fig. S4.
Intravascular tumour cell migration was also detected (Fig. 5A, white asterisk). This group of cells seems to adhere to the internal surface of the vessels, slowly crawling on it. Of note, the time-lapse frames showed in Supplementary Video S5 do not allow detecting tumour cells circulating within the blood flow.
We then investigated whether angiotropism could also be detected in 2-dpf zebrafish embryos injected with uveal melanoma cells. As in the case of cutaneous melanoma, interactions between uveal melanoma cells and the abluminal surface of zebrafish vessels were studied employing live imaging coupled with 3D reconstruction. The experiment was performed 5 times using around 50 embryos each time. A representative example of a larva displaying a micrometastasis formed by angiotropic uveal melanoma cells is shown in Fig. 6A (indicated by the square). Interestingly, this group of cells was located outside an intersegmental vessel of the injected embryo, adhering to the external surface of the vessel (Fig. 6B–D).
In line with what we observed for cutaneous melanoma cells, the uveal melanoma angiotropic cells exhibited lengthy and fine cellular protrusions extending on the abluminal surface of the vessel and in the surrounding microenvironment (indicated by white arrows in Fig. 6B–D). As displayed in these images and in Videos S8 and S9, the micrometastasis remained located outside the intersegmental vessel without entering in the circulation.
Putative intravascular uveal melanoma cells were also detected (Fig. 6A, white asterisk). Of note, the cell indicated by the yellow arrow remained trapped inside an intersegmental vessel of the embryo, promoting the sprouting of new small horizontal vessels (Supplementary Video S8). Also in this case, the time-lapse frames showed in the video do not allow the detection of tumour cells circulating within the blood flow.
Malignant cells use a variety of motility and invasion mechanisms, specifically hematogenous spread, angiotropism and extravascular migratory metastasis (EVMM). It is known that aberrant expression of embryonic epithelial-mesenchymal transition (EMT) factors triggers extensive plasticity of cancer cells, including melanoma cells31 via EMT plasticity, invading melanoma cells can use a broad spectrum of invasion strategies depending upon many environmental determinants32,33 leading to tumour resistance and metastasis. Despite a large number of studies analysing various factors responsible for triggering cancer cell progression34,35 the genetic and epigenetic basis for invasive cancer cell strategies remains poorly understood.
In the present study, we described the presence of angiotropism and EVMM in cutaneous and uveal melanoma spread both in vitro and in vivo. Indeed, not only we evaluated and characterised angiotropism and EVMM using our already established 3D co-culture approach, but we also studied these processes in vivo in zebrafish larvae, via live imaging. To our knowledge, this study is the first attempt to characterise this novel mode of metastatic dissemination in such a model.
Angiotropism and pericytic mimicry have been previously demonstrated in human biopsies of common malignancies of the skin36, pancreas37 and prostate38. Similar findings have been shown in other solid tumours, notably in the malignant brain tumour, glioblastoma multiform. In particular, invasive glioblastoma cells are known to follow peculiar anatomic structures in the central nervous system, including the abluminal surface of blood vessels, displaying the same phenotypic pericytic mimicry as angiotropic melanoma cells. For example, Cheng et al. suggested a role for glioma stem cells as pericyte progenitors and proposed that they might contribute to the formation of cancer vessels and to the progression of tumour growth39.
In the present study, we additionally documented the similarities in the migratory properties of cutaneous and uveal melanoma cells, despite their different genetic profiles. Indeed, they both showed angiotropism and pericytic mimicry in vivo and in vitro.
Curiously, we also reported that non-malignant immortalised human melanocytes Hermes 2B-GFP, showed a similar behaviour in vitro. Indeed, these cells attached to the tubules formed by HUVEC cells, cultured in basement membrane extracts, displaying angiotropism.
Nevertheless, despite their angiotropic properties in vitro, Hermes 2B-GFP cells displayed a significantly slower migration velocity along the endothelial tubules probably linked to the non-malignancy of these cells. The average velocity of cutaneous and uveal melanoma cells moving along the vascular tubules in 3D co-culture was comparable, around 0.3 µm/min. This value is within the range of both tumour cell and neural crest cell (NCC) migration average velocities, as previously reported7. The analogy of EVMM with the migration of NCC in the developing embryo has already been emphasized6. The embryonic pathways of highly migratory NCC and their regulation during development result in the establishment of melanocytes among other cell types40. Cancer cells with stem/embryonic properties may contribute to the formation of tumour vasculature, consistent with the tissue organization seen in angiotropism (or vascular co-option)3.
The angiotropic behaviour of Hermes 2B-GFP could be explained by the mesenchymal, neural crest origin of melanocytes, as reported also in another study of our group41. In this previous work, melanocytes from benign nevi were able to attach and spread along capillary-like structures in vitro, while they could not grow in vivo on the chick chorioallantoic membrane. In line with these findings, we showed that no Hermes 2B-GFP cells were detected 2–3 days after injection in around 50% of zebrafish larvae. In the remaining injected larvae, the transplanted cells showed no migration and stayed confined in the yolk sac.
Hence, despite angiotropic behaviour in vitro, Hermes 2B-GFP cells do not show any progressive growth in vivo. Indeed, malignant transformation is needed for cells to migrate and invade in response to challenging in vivo environmental conditions.
Concerning the mode of tumour migration, we observed cutaneous and uveal melanoma cells migrating individually as single cells and as small groups of cells, as we previously showed in the murine brain melanoma model3. These observations could correspond to what is described as single-cell and collective migrations32,42.
Consistently with what we had reported in our previous study43 and in analogy with cancer and NCC migration, here we observed unique changes in the morphology of angiotropic melanoma cells, both in vitro and in vivo. These alterations included the formation of protrusions, the adoption of a more tapering shape and the adhesion to endothelial tracks.
There is a wide range of pseudopodia that are needed to extend the leading edge of cells during migration on both 2D surfaces and in 3D extracellular matrix. The type of protrusion can be used to describe and define a peculiar mode of cell motility. In our case, we speculated that the finger-like protrusions characterising angiotropic melanoma cells observed in 3D co-culture and in zebrafish xenografts, could be filopodia. Indeed, filopodia are described as actin-rich finger-like pseudopodia at the leading edge of cells, which are able to sense the local microenvironment. They can operate alone or combined with other protrusions such as for example lobopodia or lamellipodia in 2D and 3D environments44. While in line with these reported results, our observations are only based on the morphology of the pseudopodia observed in the videos recorded and a more detailed characterisation of these protrusions is thus required.
In conclusion, here we provide evidence of angiotropism in two types of melanoma cells, for the first time in an in vivo model. This behaviour could contribute to the metastatic dissemination via a non-canonical pathway (EVMM), in addition to the classical intravascular pathway of cancer cells migration. These two mechanisms could act in vivo as non-mutually exclusive, but rather synergistic ways of tumour dissemination.
Barnhill, R. L. & Lugassy, C. Angiotropic malignant melanoma and extravascular migratory metastasis: description of 36 cases with emphasis on a new mechanism of tumour spread. Pathology 36(5), 485–490 (2004).
Barnhill, R. L. & Lugassy, C. Angiotropism in cutaneous melanoma: a prognostic factor strongly predicting risk for metastasis. J. Invest. Dermatol. 119(3), 705–706 (2002).
Bentolila, L. A. et al. Imaging of angiotropism/vascular co-option in a murine model of brain melanoma: implications for melanoma progression along extravascular pathways. Sci. Rep. 6, 23834 (2016).
Bald, T. et al. Ultraviolet-radiation-induced inflammation promotes angiotropism and metastasis in melanoma. Nature 507, 109–113 (2014).
Barnhill, R. L. et al. The biological and prognostic significance of angiotropism in uveal melanoma. Lab. Invest. 97, 746–759 (2017).
Lugassy, C., Péault, B., Wadehra, M., Kleinman, H. K. & Barnhill, R. L. Could pericytic mimicry represent another type of melanoma cell plasticity with embryonic properties? Pigment Cell Melanoma Res. 26(5), 746–754 (2013).
Zadran, S. et al Monitoring extra-vascular migratory metastasis (EVMM) of migrating cancer cells using an in vitro co-culture system. Protoc. Exch., 2867 (2013).
Barnhill R. L. Editor in Chief. Piepkorn M., Busam K. J., Co-Editors. Pathology of melanocytic nevi and melanoma. Third Edition. New York: Springer (2014).
Saldanha, G., Potter, L., DaForno, P. & Pringle, J. H. Cutaneous melanoma subtypes show different BRAF and NRAS mutation frequencies. Clin. Cancer Res. 12, 4499–4505 (2006).
Furney, S. J. et al. SF3B1 mutations are associated with alternative splicing in uveal melanoma. Cancer Discov. 3(10), 1122–1129 (2013).
Van Raamsdonk, C. D. et al. Frequent somatic mutations of GNAQ in uveal melanoma and blue naevi. Nature. 457(7229), 599–602 (2009).
Van Raamsdonk, C. D. et al. Mutations in GNA11 in uveal melanoma. N. Eng. J. Med. 363(23), 2191–2199 (2010).
Zuidervaart, W., van Nieuwpoort, F. & Stark, M. Activation of the MAPK pathway is a common event in uveal melanomas although it rarely occurs through mutation of BRAF or RAS. Br J Cancer. 92, 2032–2038 (2005).
Harbour, J. W. et al. Frequent mutation of BAP1 in metastasizing uveal melanomas. Science. 330(6009), 1410–1413 (2010).
Goessling, W., North, T. E. & Zon, L. I. New waves of discovery: modeling cancer in zebrafish. J. Clin Oncol. 25, 2473–2479 (2007).
Howe, K., Clark, M. D. & Torroja, C. F. The zebrafish reference genome sequence and its relationship to the human genome. Nature. 496, 498–503 (2013).
Mione, M. C. & Trede, N. S. The zebrafish as a model for cancer. Dis. Model Mech. 3(9-10), 517–23 (2010).
Amatruda, J. F., Shepard, J. L., Stern, H. M. & Zon, L. I. Zebrafish as a cancer model system. Cancer Cell. 1, 229–231 (2002).
Lieschke, G. J. & Trede, N. S. Fish immunology. Curr. Biol. 19, R678–R682 (2009).
Lam, S. H., Chua, H. L., Gong, Z., Lam, T. J. & Sin, Y. M. Development and maturation of the immune system in zebrafish, Danio rerio: a gene expression profiling, in situ hybridization and immunological study. Dev. Comp. Immunol. 28, 9–28 (2004).
Haldi, M., Ton, C., Seng, W. L. & McGrath, P. Human melanoma cells transplanted into zebrafish proliferate, migrate, produce melanin, form masses and stimulate angiogenesis in zebrafish. Angiogenesis. 9, 139–151 (2006).
Van der Ent, W. et al. Modeling of human uveal melanoma in zebrafish xenograft embryos. Invest Ophthalmol Vis Sci. 55(10), 6612–22 (2014).
Mercatali, L. et al. Development of a Patient-Derived Xenograft (PDX) of Breast Cancer Bone Metastasis in a Zebrafish Model. Int. J. Mol Sci. 17(8) (2016).
Konantz, M., Balci, T. B. & Hartwig, U. F. Zebrafish xenografts as a tool for in vivo studies on human cancer. Ann. N. Y. Acad. Sci. 1266, 124–137 (2012).
Stoletov, K. & Klemke, R. Catch of the day: zebrafish as a human cancer model. Oncogene. 27, 4509–4520 (2008).
Tang, Q. et al. Imaging tumor cell heterogeneity following transplantation into optically clear immune-deficient zebrafish. Nat. Commun. 7, 10358 (2016).
Lawson, N. D. & Weinstein, B. M. In vivo imaging of embryonic vascular development using transgenic zebrafish. Dev Biol. 248, 307–318 (2002).
Welch, D. R. et al. Characterization of a highly invasive and spontaneously metastatic human malignant melanoma cell line. Int. J. Cancer 47(2), 227–37 (1991).
Chen, P. W. et al. Expression of MAGE genes in ocular melanoma during progression from primary to metastatic disease. Clinical Exp. Metastasis. 5, 509–518 (1997).
Sviderskaya, E. V. et al. p16/cyclin-dependent kinase inhibitor 2A deficiency in human melanocyte senescence, apoptosis, and immortalization: possible implications for melanoma progression. J. Natl. Cancer Inst. 95, 723–732 (2003).
Caramel, J. et al. A switch in the expression of embryonic EMT-inducers drives the development of malignant melanoma. Cancer Cell. 24(4), 466–80 (2013).
Clark, A. G. & Vignjevic, D. M. Modes of cancer cell invasion and the role of the microenvironment. Curr Opin Cell Biol. 13(36), 13–22 (2015).
Friedl, P. & Wolf, K. Tumour-cell invasion and migration: diversity and escape mechanisms. Nat. Rev. Cancer 3(5), 362–74 (2003).
Orgaz, J. L. & Sanz-Moreno, V. Emerging molecular targets in melanoma invasion and metastasis. Pigment Cell Melanoma Res. 26(1), 39–57 (2013).
Thyagarajan, A., Shaban, A. & Sahu, R. P. MicroRNA-Directed Cancer Therapies: Implications in Melanoma Intervention. J Pharmacol Exp Ther. 364(1), 1–12 (2018).
Lugassy, C. et al. Pericytic-Like Angiotropism of Glioma and Melanoma Cells. Am. J. Dermatopathol. 24(6), 473–478 (2002).
Levy, M. J., Gleeson, F. C. & Zhang, L. Endoscopic Ultrasound Fine-Needle Aspiration Detection of Extravascular Migratory Metastasis Form a Remotely Located Pancreatic Cancer. Clin. Gastroenterol. Hepatol. 7, 246–248 (2009).
Lugassy, C. et al. Angiotropism of human prostate cancer cells: implication for extravascular migratory metastasis. BJU Int. 95(7), 1099–103 (2005).
Cheng, L. et al. Glioblastoma stem cells generate vascular pericytes to support vessel function and tumor growth. Cell. 153, 139–152 (2013).
Meulemans, D. & Bronner-Fraser, M. Gene-regulatory interactions in neural crest evolution and development. Dev Cell. 7, 291–9 (2004).
Lugassy, C. et al. Pericyte-Like Location of GFP-Tagged Melanoma Cells. Am. J. Pathol. 164(4) (2004).
Friedl, P. & Alexander, S. Cancer invasion and the microenvironment: plasticity and reciprocity. Cell. 147(5), 992–1009 (2011).
Lugassy, C. et al. Angiotropism, pericytic mimicry and extravascular migratory metastasis in melanoma: an alternative to intravascular cancer dissemination. Cancer Microenviron. 7(3), 139–52 (2014).
Petrie, R. J. & Yamada, K. M. At the leading edge of three-dimensional cell migration. J. Cell Sci. 125(24), 5917–5926 (2012).
We thank Philippe Herbomel for the zebrafish transgenic line Tg(kdrl:Hsa.HRAS-mCherry). We also thank Dorothy Bennett for the non-malignant human melanocyte cell line Hermes 2B. We thank Shahad Albadri and Karine Duroure for the technical help given respectively for the Live Imaging and zebrafish injections. We also thank Roberta Ragazzini and Aude Battistella for sharing reagents and protocols for the Lentivirus production and infection. We thank Marc Henri Stern, Manuel Rodrigues, all members of Del Bene’s laboratory and the ones of Alsafadi’s laboratory for fruitful discussions and suggestions. We thank Michele Scotto di Mase for the help with GraphPad Prism. We finally thank the Developmental Biology Curie imaging facility (PICT-IBiSA@BDD, Paris, France, UMR3215/U934) member of the France-BioImaging national research infrastructure for their help and advice with confocal microscopy and 3D reconstruction of videos. This work has been supported by ANGIOZUM PIC3i Curie grant.
The authors declare no competing interests.
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Fornabaio, G., Barnhill, R.L., Lugassy, C. et al. Angiotropism and extravascular migratory metastasis in cutaneous and uveal melanoma progression in a zebrafish model. Sci Rep 8, 10448 (2018). https://doi.org/10.1038/s41598-018-28515-6
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