Melanoma is described as a malignant tumor that originates from melanocytes, the melanin-producing cells. The tumors can be diagnosed on the skin, ocular membranes, retroperitoneal space, parenchymatous organs and different mucosa (1–3); however, 95% of all melanoma cases are located on the skin (4). Even if these tumors originate from the same cell, melanomas should be considered as a family of diseases instead of a single tumor, with a different etiology, pathogenesis, behavior and evolution, depending on the site of occurrence.

The genetic signature of melanomas comprises different profiles of somatic mutations engaged in tumorigenesis (5), and also multiple risk factors, including environmental, genetic and phenotypic factors (6), features that convert this pathology into an aggressive and a disorder with a poor prognosis; melanoma is considered one of the most lethal types of cancer, accounting for 75% of skin cancer-related mortalities (4). The high rate of mortality, which is characteristic of this aggressive disease is associated with a heterogeneous molecular pattern caused by multiple progressive mutations. The recent advances in the molecular therapy of mutant melanoma are considerable; however, this type of therapy is still confronted with secondary effects and is resistant to treatment (7–9). Despite considerable progress in the understanding of the mechanisms responsible for melanoma development and progression, mechanistic insights and in the discovery of alternative therapeutic approaches (10), the approved anti-melanoma agents have failed to enhance the survival rate of patients with melanoma, and there are still some gaps to fill concerning melanoma biology (11).

The resolution for the aforementioned issues can be achieved by using in vivo models that recreate the exact biological features of melanoma.

An alternative in vivo experimental model suitable for cancer studies is the chick embryo chorioallantoic membrane (CAM) assay (12), due to its capillary plexus characteristics, and to the fact that it is considered favorable to tumor grafting, enabling neovascularization and invasiveness. Hence the assay is applied in order to investigate the multiple steps of tumor progression, metastatic behavior and molecular deregulated pathways for a large number of cancer types, including sarcoma, lymphoma, ovarian cancer, breast cancer, hepatocellular carcinoma and melanoma (13–18).

Another important tool for understanding the fundamental molecular mechanisms involved in the development of cancer, in general, and melanoma in particular, and to ascertain new or improved procedures for the prevention, diagnosis and treatment of cancer is considered to be the use of animal models (19). Mouse models are by far the most widely employed animal models for melanoma studies due to the extensive genetic knowledge available at present, and due to their easy manipulation and availability (3,20). These models provide important data about the function of specific proteins in melanoma progression. Moreover, these types of assays play a major role in the evaluation of novel anticancer agents (21).

The A375 cell line is derived from a skin primary melanoma of a 54-year-old female and has an epithelioid morphology carrying two mutant genes, B-RAF and CDKN2. Both mutations are associated with melanoma of sun-damaged skin (6).

The present study was carried out with the aim: i) to present a well-established protocol that includes the steps for obtaining in vivo xenograft models of human melanoma using the A375 cell line on two hosts, namely CAM and immunocompromised Balb/c nude mice; ii) to offer a complete macroscopic and histological characterization; and iii) to highlight the inconveniences associated with model development.

The incidence of cutaneous melanoma has increased at an alarming rate worldwide over the past years. According to the World Cancer Research Fund International, GLOBOCAN 2012, there were an estimated 230,000 new cases of melanoma worldwide in 2012 (24), and the statistics offered by the WHO indicate that almost 132,000 cases of melanoma are being diagnosed each year globally (25). On the other hand, the incidence of mucosal and ocular melanomas seems to remain stable worldwide (1,2,26), with some racial and regional differences.

Even if the presence of skin melanoma in Asiatic individuals seems to be uncommon, the oral cavity melanomas are more often diagnosed in Japanese and Ugandan African populations, accounting 35% of all mucosal melanomas, compared to 3.6% in caucasions. Even so, a recent study demonstrated a higher prevalence of oral cavity melanomas, accounting 25% of all mucosal melanomas diagnosed during a period of 10 years, due to the habitual particularity of Romania's population (1,2).

There are also differences between ages at the time of diagnosis. Cutaneous melanomas are diagnosed at a young age, but the extra-cutaneous counterpart seems to be a disease affecting the elderly, with a peak of incidence in the 7th decade of life compared to the 3rd decade for the former. Moreover, the age at the time of diagnosis appears to decrease over the past years of life for skin melanomas (27), a fact that is not been observed for the extra-cutaneous counterpart.

Over the past years, an entire cascade of genetic abnormalities has been identified which is associated with melanoma. Studies have reported that 25 molecules/genes are associated with melanoma biology, namely progression, metastasis and prognosis, such as CDKN2A (cell cycle-related gene), PI3K and PTEN, N-RAS (15–20% of all cutaneous melanomas), B-RAF (50% of all cutaneous melanomas) and MITF (28–30). The B-RAF gene encodes a serine/threonine protein kinase that acts as a regulator of cell division, differentiation and secretion through the RAS-RAF-MEK-ERK-MAP kinase signaling pathway. The B-RAF mutation is represented by the substitution of valine with glutamic acid at codon 600, also known as V600E, and is responsible for the constitutive activation of the protein (30,31). Moreover, it has been demonstrated that the B-RAF^V600E pathway promotes vascular development by activating the autocrine secretion of VEGF (31). Mutations in the B-RAF gene have been diagnosed in up to 82% melanocytic nevi, concluding that B-RAF^V600 mutation cannot lead to cancer itself, and requires the presence of other mutated genes (32). Another study on B16 mouse melanomas, demonstrated that the inhibition of MITF reduces the proliferation of malignant melanocytes (28). Therefore, it can be concluded that MITF and B-RAF activation are necessary for melanocytes to acquire their malignant potential (28).

In the present study, we used the A375 melanoma cell line that maintains the characteristics of the human genitor and harbors B-RAF and CDKN2 mutations, typical of cutaneous melanoma, but with a morphology similar to that of mucosal melanomas. Even so, it represents an eligible candidate for the development of in vivo models.

It is well-known that melanoma progression occurs in several steps which include the formation of a primary tumor that develops horizontally through the epidermis, followed by the vertical growth phase initiated in the primary tumor that extends to dermis and the last phase, the invasion of tumor cells and formation of secondary tumors (33). Metastasis is a complex multi-stage process and a lethal feature of melanoma, causing also resistance to the existent treatment. The process of angiogenesis is a prominent feature in melanoma development, progression and metastasis, the newly formed vessels being the suppliers of oxygen and nutrients for cancer cells. Moreover, it is considered that the onset of angiogenesis is related to inflammation and the development of the melanoma vertical growth phase (33,34). On this basis, it is mandatory to develop proper in vitro and in vivo models that mimic the human pathogenesis concerning metastasis development, in order to fully elucidate the processes involved (35). However, even though multiple models have been employed, these processes are not yet fully elucidated.

The in vivo model using melanoma cells grafted on chick chorioallantoic membrane presented in this study demonstrated a 100% rate of tumor formation, and it could be applied as a pre-screening tool for the evaluation of the antitumor and anti-angiogenic potential of various agents, the results being obtained in a short period of time (4–8 days). The easily accessible, highly vascularized extraembryonic membrane of the chicken embryo is often used to assess tumor angiogenesis, since the discovery of tumor angiogenesis by Folkman and Cotran 4 decades ago (36). Several advantages of this technique recommend it as a pre-screening assay to the murine models. The procedure assets are in terms of costs, time, simplicity and reproducibility. The model does not require sophisticated technical equipment, and qualified surgical skills are not compulsory. The experimental setting takes up to 17 days, which implies a relatively short interval for tumor growth and metastasis, thus facilitating multiple assessments. Human tumor xenografts are applicable on the CAM surface due to immunological immaturity up to embryonic development day 18 (37,38). Moreover, the number of specimens that can be included in an experimental set is higher than in mouse studies, making it possible to investigate a greater number of therapeutic agents.

Another feature that can be investigated by assessing the melanoma CAM assay is the degree of angiogenesis by morphometric measurements, applying an arbitrary scale in correlation to the vessel density in areas surrounding the tumors. By performing this evaluation on the 4th day following the inoculation of cells, or the cell medium, respectively, there is no interference with the normal angiogenic status of the embryo. This moment represents the 14th EDD, when the normal angiogenic process of untreated specimens is normally already decreased. Intense angiogenesis occurs between the 7th and 11th EDD (22). Our results indicated that on day 4 post-inoculation, both primary and distant tumors were strongly vascularized, what indicates the bond between the tumor growth and angiogenesis.

We have previously used the CAM normal angiogenesis model to test certain natural compounds for their potential benefits in limiting the deregulated excessive angiogenic process (39,40). We have also previously tested the natural compounds in the melanoma model on CAM using A375 cells, providing new insight into the mechanisms of action (unpublished data).

Different melanoma cell lines have been used for models using the CAM assay, with the A375 cells being among the most frequently used (16,41). This has contributed to the molecular elucidation of this aggressive type of tumor behavior, in terms of invasiveness (16), brain metastasis (42), angiogenesis and lymphangiogenesis (41,42), or the evaluation of compounds with promising effects by modulating different targets (43).

The human melanoma model using A375 cells assessed on the CAM is also a useful alternative method for the study of melanoma cell behavior and tumor environment. The CAM protocol using melanoma cells is a suitable tool for in vivo tumor angiogenesis or lymphangiogenesis elucidations. Hence, further molecular investigations can be performed using the specimens obtained from the tumor CAM assay [e.g., polymerase chain reaction (PCR), in situ hybridization, immunohistochemistry, immunofluorescence, and positron emission tomography-computed tomography (PET-CT)] (38). The establishment of functional perfused tumors in only 4 days after inoculation and the ability of observing the tumor growth, progress, invasiveness and metastasis for approximately 4–5 days after tumor onset is a suitable protocol for pre-screening potential antitumor agents.

There are several drawbacks to the CAM model that can influence tumor research results. A limited number of reagents are applicable due to low compatibility. Non-specific inflammatory response, and various reactions of the membrane when exposed to the outer atmosphere can also affect tumor microenvironment assessment (44). In order to minimize the possible misevaluations of the tumor model, it is optimal to apply both the murine and CAM assays along with in vitro experiments.

The CAM data obtained in the present study validate the effectiveness of this assay as a short-term xenograft model for A375 cells, providing information about melanoma cell proliferation, metastatic behavior and angiogenic potential in vivo. This information was used as an additional background file for the development of human melanoma mouse model (a long-term assay).

The mouse melanoma model can be used to gain information about both early-and late-stage events in melanoma development, and furthermore, the antitumor and anti-metastatic effects of various therapeutic agents can be assessed. In order to obtain a proper mouse melanoma model, several aspects should be noted:

First, the in vivo melanoma models which are obtained by the engraftment of human cells require as host immunocompromised mice (SCID mice, which are both T-cell- and B-cell-deficient or nude mice, which are only T-cell-deficient) that do not reject the inoculated cells (3,45). An ideal animal model should exhibit similar molecular characteristics as human tumorigenesis and should also mimic natural tumor progression, from its burst and proliferation to invasion and metastasis (3). Balb/c nude mice have been proven to be an excellent host for the A375 mouse model (46–49). Immunodeficient mice are considered eligible hosts for the transplantation of human xenografts due to their specific mutations and immune background. SCID mice were the first severe immunocompromised strain of mice that presented a mutation at Prkdc^scid protein kinase, also known as Scid mutation responsible for the impairment of B- and T-cell production (50). Balb/c homozygote nude mice are characterized by the mutation of the Foxn1 gene associated with the lack of hair and of a functional thymus (deteriorated of removed). The immune profile of these mice comprises a small population of T-cells and an increased response of natural killer cells (more potent that in normal Balb/c mice), which makes them suitable for human xenografts. It has been observed that with age, the athymic mice gather a small number of lymphocytes (CD3, CD4, CD8 and Thy-1). In addition, it has been shown that these mice do not have an intrinsic defect of T-cell precursors, their function being activated with proper stimulation; however, B-lymphocytes, mononuclear cells (macrophages highly active) and a normal number of mast cells have also been detected (50,51).

Second, the area of xenograft inoculation is very important, as it should provide the anatomical morphology for tumor progression and the development of metastases. Most of the xenograft melanoma models are created by the subcutaneously inoculation of tumor cells, with the number and the volume of culture media/PBS/inoculum varying (47–49). Alternative parenteral pathways of tumor cell inoculation have also been described, such as intradermal (better mimics a primary melanoma, but tumor formation leads to skin ulcerations and mouse euthanasia is required) (35,45,46), tail vein (enforces the development of lung metastasis, but some steps in the normal process are missed) (3,45) and intracardiac (follows the metastatic spread) (52).

The xenograft melanoma model subcutaneously inoculated presents some advantages in that the tumor that develops is more comparable to skin metastasis and the experimental time is longer, allowing for human melanoma cells to interact with the murine stroma, lymphatic vessels, which makes the evaluation of tumor growth behavior possible; this is frequently used to evaluate the response of anticancer agents response in vivo (3,45). However, there are also some limitations to this model, in that the tumor dimensions cannot be measured by a caliper at lower limits and it cannot be applied to examine the efficacy of immune-based therapies, since the mice are immunocompromised (53).

Our results are in agreement with the data from the literature regarding the inoculation pathway (23,47–49), the animal host and the number of cells/inoculum/mice (23,49), this number being selected based on the fact that a palpable subcutaneous tumor was first detected after the injection of a minimum of 10⁶ cells/mouse (54). There were some differences between our data and the literature as regards the survival time post-inoculation of the tumor cells (from 21 to 90 days); these differences could be explained by the inoculation pathway, the number of cells/inoculum and also, the aim and the endpoints established for each experimental design (34,47–49).

As regards histopathological aspects, cutaneous melanomas can be classified as melanomas in situ, superficial spreading melanomas and nodular melanomas. Extra-cutaneous melanoma do not fit these categories due to zone particularities; mucosal melanomas are often diagnosed as nodular tumors with or without associated pagetoid spread in the covering epithelium nearby the melanoma. In our study, 14 mice developed tumors consistent with the diagnosis of nodular melanoma that occupied the dermis and subcutis. The cells composing melanoma can be classified as epithelioid and spindle, although the majority of cutaneous melanomas present a mixed cellularity, with epithelioid cells being more often observed in mucosal melanomas (2). In the present study, we used the A375 cell line, containing cells with epithelioid aspect obtained from a cutaneous lesion, and the induced tumors were all composed of epithelioid cells, better resembling mucosal melanoma cellularity. Moreover, even if, usually, cutaneous melanomas are pigmented, containing various amounts of melanin in the cytoplasm of tumor cells or in the melanophages of the tumor stroma, the tumors obtained in the present study were achromic, better resembling mucosal melanomas that are predominantly achromic. As we have already demonstrated, the tumor cells present a pagetoid spread in the epithelium nearby or overlying the tumor (1,2), a feature that was not observed in the present study, certainly due to the subcutaneous inoculation of the tumor cells; however, the tumor occupied the dermis and the subcutis, providing the tumor with direct access to the usual routes for metastasis, which resulted in the appearance of secondary tumors in almost 30% of the xenografted mice.

The evolution of both cutaneous and extra-cutaneous melanomas is dependent on the stage of disease at diagnosis. In a recent review, it was stated that in countries with the highest incidence of cutaneous melanoma, such as Australia, New Zealand, USA and Scandinavia, patients are diagnosed at an early stage, while in Central and Eastern European countries, diagnosis is usually made at an advanced stage, which leads to a higher number of deaths due to melanoma (55). It is well-known that cutaneous melanomas diagnosed at an early stage are in most cases curable, whereas the survival rate changes depending on the stage of the disease: stages I and II (localized tumor; 5-year survival, 98% of cases); stage III (regional spread; 63% of cases) and stage IV melanoma (metastasis beyond regional lymph nodes; 16% of cases) (25). Mucosal melanomas are always diagnosed in the late stages, with very low rates of curability. The prognosis is grim, the 5-year survival rate being only 40%.

The prognostic factors have been investigated for a number of years. From the beginning of the study of melanoma to date, the Clark level (the level of the skin affected by the tumor with level I, epidermis; level II, papillary dermis; level III, superficial blood plexus of the dermis; level IV, profound blood plexus of the dermis; and level V, subcutis) and the Breslow index (distance in mm from the granular layer of the epidermis to the most profound site of the tumor) are considered to be the most important for the prognostic. The epithelioid appearance of the cells was also noted as poor prognostic factor, together with the lack of melanin pigment from the cells (2). The quantity of inflammatory cells (lymphocytes, macrophages and plasma cells), varying from any (poor prognostic factor), to brisk, or to heavy and disposed in a band around the tumor (good prognostic feature), was also considered to have an impact on the prognosis of the tumor. Lately, only infiltrated plasma cells, those plasma cells that are found between malignant melanocytes, are considered important for a good prognosis, with no impact on survival if they are disposed in the tissues around the tumor. To date, only the Clark level and Breslow index remain as gold standards for prognosis, and are the only factors that could be appreciated in our study and could be associated with prognosis, as tumor size rapidly increased and reached the limits imposed for mouse euthanasia by the IACUC Guidelines regarding tumor production in rats and mice, as many metastases developed. At 30 days post-inoculation, the primary tumors of 3 mice reached the size limits and all these mice developed distance metastasis or showed signs of tumor migration (tumor thrombus in the large-sized arterial blood vessel). Maishi et al reported that on day 29 post-inoculation of 1×10⁶ cells into Balb/c nude mice, lung metastases and tumor cells disseminated in intra-blood vessels areas were detected (48), data that are consistent with our results.

In the second group (45 days post-inoculation), only one mouse developed a microscopic kidney metastasis and in the last group (60 days post-inoculation), the mice in which the tumor size slowly reach the limit showed no metastasis, only non-specific signs of tumor aggression as paraneoplastic symptoms (hemorrhagic alveolitis). As regards the epithelioid feature and intracytoplasmic melanin load, in the present study, the inoculated A375 cells had an achromic epithelioid aspect and all the primary and secondary tumors developed after inoculation were also composed by achromic epithelioid cells; thus, no remarks related to the differences in metastatic capacity between epithelioid and spindle cells, or pigmented and achromic cells, could be pronounced. Moreover, inflammatory cells were absent in the tumor and metastasis obtained using Balb/c nude mice, due to the immune system characteristics of the used mice. As we previously demonstrated (56) in SKH-1 hairless mice while studying experimental skin carcinogenesis, the only type of inflammatory cells present in the tissues around the tumor were mast cells. These cells were easy to observe even on morphologic H&E or trichrome stains, due to their microscopic appearance, as large cells with a thin cytoplasmic extension, that are usually filled with many rough basophilic granules. The present mouse model exhibited an increase in the number and size of mast cells from the control group to the mice sacrificed after 60 days of the experiment. From the facts noted in the present study, it can be concluded that the size of the tumor has an important impact on the appearance of metastasis. Due to the increasing number of mast cells around the tumor, it can be postulated that the immune system is probably involved in the evolution, progression and metastasis of the tumor. Of note, the host immune system is considered to be involved in tumor regression as a consequence of tumor cell destruction by the activation of inflammatory cells, vascular hyperplasia and fibrosis (27).

Even so, no other histological features noted on the primary tumor in the present study, could predict metastasis, the presence of metastases being a random event, an aspect already highlighted in humans, where it seems that the behavior of different melanomas does not correlate with the surgical option or histopathological type of the tumor cells.

In conclusion, the CAM assay indicated that the A375 cell line exhibited a great affinity and compatibility in the present framework, primary and secondary tumors being visible at day 4 post-inoculation and presenting a high angiogenic potential. The in vivo melanoma model obtained by inoculating A375 cells revealed that Balb/c nude mice are suitable hosts for human cancers, the degree of tumor development with similar characteristics being greater than 90%. Moreover, the histological analysis described tumor evolution in time, its progress being slow and its metastasis rate reduced, which can be considered an asset in therapeutic surveillance experiments. The standardization method for the development of melanoma models proposed in the present study proved to be a complex, reproducible process, albeit some small interferences, and the incriminated factor could be the genetic profile of both cell line and nude mice.