Ecto-5’-Nucleotidase Overexpression Reduces Tumor Growth in a Xenograph Medulloblastoma Model

Background Ecto-5’-nucleotidase/CD73 (ecto-5’-NT) participates in extracellular ATP catabolism by converting adenosine monophosphate (AMP) into adenosine. This enzyme affects the progression and invasiveness of different tumors. Furthermore, the expression of ecto-5’-NT has also been suggested as a favorable prognostic marker, attributing to this enzyme contradictory functions in cancer. Medulloblastoma (MB) is the most common brain tumor of the cerebellum and affects mainly children. Materials and Methods The effects of ecto-5’-NT overexpression on human MB tumor growth were studied in an in vivo model. Balb/c immunodeficient (nude) 6 to 14-week-old mice were used for dorsal subcutaneous xenograph tumor implant. Tumor development was evaluated by pathophysiological analysis. In addition, the expression patterns of adenosine receptors were verified. Results The human MB cell line D283, transfected with ecto-5’-NT (D283hCD73), revealed reduced tumor growth compared to the original cell line transfected with an empty vector. D283hCD73 generated tumors with a reduced proliferative index, lower vascularization, the presence of differentiated cells and increased active caspase-3 expression. Prominent A1 adenosine receptor expression rates were detected in MB cells overexpressing ecto-5’-NT. Conclusion This work suggests that ecto-5’-NT promotes reduced tumor growth to reduce cell proliferation and vascularization, promote higher differentiation rates and initiate apoptosis, supposedly by accumulating adenosine, which then acts through A1 adenosine receptors. Therefore, ecto-5’-NT might be considered an important prognostic marker, being associated with good prognosis and used as a potential target for therapy.


Introduction
Ecto-5'-nucleotidase/CD73 (ecto-5'-NT) is expressed by various human tissues and considered the main producer of extracellular adenosine [1]. Adenosine activates P1 metabotropic receptors, subdivided into A 1 , A 2A , A 2B and A 3 receptors, which participate in the control of intracellular cAMP levels [2]. Ecto-5'-NT influences cancer progression in different types of tumors, including bladder and breast cancer, melanomas and gliomas [1]. Sadej and co-workers (2006) [3] demonstrated that ecto-5'-NT expression increased with the degree of malignancy of human melanoma cell lines, where higher expression levels were measured in a metastatic melanoma cell line. In breast cancer, the involvement of ecto-5'-NT in invasiveness and its interaction with extracellular matrix proteins were demonstrated [4]. Previous studies from our laboratory have shown a role of ecto-5'-NT in glioma progression and tissue invasiveness events. First, different glioma cell lines expressed prominent levels of ecto-5'-NT compared to normal astrocytes [5]. Second, increased cellular confluence was accompanied by enhanced ecto-5'-NT expression and activity [6]. Third, diminished ecto-5'-NT activity affected glioma cell adhesion and reduced cell proliferation [7,6], suggesting the importance of ecto-5'-NT enzymatic activity for glioma cell survival.
However, immunohistochemistry and microarray analysis of human breast cancer samples revealed that ecto-5'-NT overexpression, which was observed in 74% of analyzed tissues, was correlated with the disease-free state and overall survival, suggesting that the expression of this enzyme is associated with good prognosis [8]. Ecto-5'-NT expression levels in medulloblastoma (MB) cell lines were reported in our previous paper. While the primary MB cell lines (Daoy and ONS76) expressed this enzyme, the metastatic MB cell line (D283) did not [9]. This difference was attributed to the regulation of ecto-5'-NT expression by β-catenin nuclear immunoreactivity [10], which has been suggested to predict a favorable prognostic for MB [11]. Unlike gliomas, MB mainly affects children with a median age of 9 years, and the median survival of the patient is approximately 5 years [12]. These tumors occur preferentially in the cerebellum and are considered the most common brain tumors in children, classified by the World Health Organization (WHO) as fourth degree tumor the highest malignant grade [13]. Considering the supposed crucial and contradictory functions of ecto-5'-NT in tumor growth, we investigated the role of ecto-5'-NT in MB progression. The enzyme was overexpressed in the D283 human MB cell line in order to evaluate its participation in tumor growth in an in vivo nude mice model. Here, we demonstrated that the overexpression of ecto-5'-NT promotes a reduction of tumor growth; interferes with Ki67, CD31 and caspase-3 immunolabeling; and promotes an increase in differentiated tumor cells. In addition, we showed that the expression of A1 adenosine receptor was enhanced, suggesting the participation of adenosine signaling in MB tumor progression.

Cell culture
Daoy (representative of a human primary MB) and D283 (representative of a secondary or metastatic human MB) cell lines (generated by American Type Culture Collection, ATCC) were kindly donated by the Laboratório de Pesquisa em Câncer Infantil of Hospital de Clínicas de Porto Alegre in Rio Grande do Sul, Brazil. The cells were cultured in low glucose Dulbeccó s Modified Eagle´s Medium (DMEM), supplemented with 10% fetal bovine serum (FBS) and 0.5 U/mL penicillin/streptomycin antibiotics. The cells were kept at 37°C in an incubator with a minimum relative humidity of 95% and 5% of CO 2 .

RT-PCR and Real-Time PCR
Total RNA from MB cell lines was isolated with Trizol 1 Reagent (Invitrogen by Life Technologies-Carlsbad, CA, United States). The cDNA was synthesized with RevertAid reverse transcriptase (Fermentas by Life Technologies-Carlsbad, CA, United States) from 3 μg of total RNA in a final volume of 20 μL in the presence of oligo dT primer. The following PCR reaction was performed in a total volume of 25 μL, which included 1 μL of each forward and reverse primers to ecto-5'-NT coding sequences (S1 Table) and 1 μL of Taq DNA polymerase enzyme (Fermentas by Life Technologies-Carlsbad, CA, United States). The PCR products were analyzed on a 2.0% agarose gel containing ethidium bromide and visualized under ultraviolet light. The plasmid containing the sequences for ecto-5'-NT was used as a positive expression control for this enzyme. A negative control reaction was performed by substituting the templates for DNase/RNase-free distilled water.
Real-time PCR analysis was performed in the ABI Step One Plus Instrument using the SYBR Green amplification System (Applied Biosystems, Foster City, CA). Each reaction was performed with 0.25 μL of each forward and reverse primer (10 μM) (S1 Table). Because the efficiency of all of the reactions was >95%, the ΔΔCt parameter was used to determine the relative expression levels, using GAPDH gene expression as an endogenous control for normalization.

Flow Cytometry
Ecto-5'-NT. For flow cytometry analysis, one million cells were washed twice with phosphate buffered saline (PBS) plus 1% fetal calf serum (FCS) and centrifuged. The pellets were resuspended and incubated for 1 h with purified mouse anti-human CD73 antibody (1:10, BD Pharmingen TM) for 1 h at 4°C. Next, all of the samples were washed and incubated for 1 h with Alexa Fluor 555 rabbit anti-mouse (1:100) at room temperature. Then, the labeled cells were washed with PBS and immediately analyzed by flow cytometry (Beckman Coulter Fc500).
Fifty thousand events in the cell gate were collected and further analyzed using the FlowJo 1 7.6.3 software.
Active caspase-3 measurement. To evaluate caspase 3 immunolabeling, MB cell lines were seeded and cultivated until 70% confluence. For sequencing, the cells were washed twice and then resuspended in BD Cytofix/Cytoperm™ solution at a concentration of 3 × 10 5 cells per 150 μL and incubated for 20 min at 4°C. Afterward, the cells were washed twice with BD Perm/ Wash™ buffer (1×) at room temperature. Finally, the cells were incubated in BD Perm/Wash™ buffer (1×) containing an antibody against active caspase-3 for 30 min at room temperature in the dark and then analyzed by flow cytometry (FACS Caliber, BD Biosciences, San Jose, CA, USA). The data were analyzed using FlowJo 1 software (USA).

Ecto-5'-NT enzymatic assay and protein determination
For the determination of AMP hydrolysis, MB tumor cells were incubated for 10 min with 2 mM AMP diluted in incubation buffer, followed by the determination of the released inorganic phosphate (Pi) [9]. The specific activity was expressed as nmol Pi released/min/mg of protein (nmol Pi/min/mg). The protein concentration was determined by the Coomassie blue method using bovine serum albumin (BSA) as a standard. To determine the effect of APCP on AMPase activity, the cell lines were pre-incubated for 10 min with different APCP concentrations (1, 5, 10, 20 and 50 μM) diluted in incubation buffer. At sequencing, MB tumor cells were incubated with 2 mM AMP diluted in incubation buffer plus the respective APCP concentrations, and the protocols were performed as described above.

Cell counting
Cells were washed twice with PBS, and 100 μL of 0.25% trypsin/EDTA solution was added to detach the cells prior to counting them with a hemocytometer. According to specific protocols, the cells were prepared as follows: to evaluate the transfection effects on cell proliferation, 10 4 cells per well were seeded in 24-well plates and allowed to grow for 5 days. A cell count was performed daily. To determine the APCP effect of cell line proliferation, the cells were seeded, and when they reached 60% confluence, the cells were treated. After 24 and 48 h of treatment, cell counting was performed. After the first tumor of each group reached approximately 18 mm at the largest diameter of the tumor mass, all the animals in the group were euthanized by cervical dislocation. The tumors were excised, and their weights and sizes were determined. Tumor masses were fixed with formalin for posterior analysis. To maintain the physical integrity of animals after tumor development, pain signals were monitored, as well as weight loss and apathy. In the case of any of these symptoms, the animals were euthanized. The observation of the animals did not showed that any of them became severely ill or injured during the course of the study. These parameters were established in accordance with the Tumor Policy for Mice and Rats, as described by Boston University Research Compliance-Research Committees, which is accepted by IACUC (Institutional Animal Care and Use Committee), and analyzed and approved by the local Committee as described above.

In vivo nude mice imaging
Nude mice received an injection containing IRDYE 1 800 CW PEG Contrast Agent (1.5 nmol) into the tail artery. After 24 h, the animals were anesthetized with flank injections of ketamine and xylazine (6.67 μL/g) and imaged using the Odyssey 1 CLx Infrared Imaging System plus Mou-sePOD in vivo Imaging Accessory. The images were analyzed by the Odyssey 1 CLx software.

Histopathology and immunohistochemical staining
For histopathological analysis, samples of MB tumors were formalin-fixed, paraffin-embedded and sectioned at a 5-μm thickness. For each sample, a section was stained using standard hematoxylin and eosin (H&E) protocols. Other sections of these samples were used for immunohistochemistry protocols. For this, sections of 5 μm thickness were processed using antigenic Tris/EDTA recuperation at pH 9.0 and high temperature and blocked with methanol (3%) and FBS (5%), followed by overnight incubation at 4°C with the following specific antibodies: antihuman CD31, anti-synaptophysin, anti-enolase, anti-Ki67 (Cell Marque, Rocklin, CA), antihuman CD73 (Santa Cruz Biotechnology, INC.-Dallas, Texas) and polyclonal rabbit antibody against active Caspase 3 (Abcam, Cambridge, MA). Next, tissue sections were incubated with the Reveal Complement secondary antibody (Spring Bioscience). The H&E and Immunoblotting slides were analyzed by a pathologist in a blind manner. Each positive endothelial cell cluster of immunoreactivity in contact with the selected field was considered an individual vessel. For all of the antigens analyzed here, the expression and localization were considered positive only when the cells were clearly immunoreactive. Pathological evaluations were performed for ten randomly chosen fields (× 200) per tumor, using an Olympus BH-2 microscope. Blind quantitative analyses of five randomly chosen images of each tumor sample were performed for Ki67 and CD31 immunolabeling, using ImageJ as the image analysis program.
The Daoy MB cell line was used as a positive control for ecto-5'-NT expression and D283 as a cell line expressing low levels of this enzyme [9]. Gene expression analysis revealed that the D283hCD73 MB cell ecto-5'-NT expression levels are low in D283ev cells (Fig 1A), in agreement with the flow cytometry results (Fig 1B). Daoy and D283hCD73 cells were positive for anti-ecto-5'-NT immunofluorescence staining, with no significant differences ( Fig 1B). The obtained expression profiles were in agreement with the enzymatic activity levels, revealing the enhanced functionality of ecto-5'-NT in the D283hCD73 cell line in converting AMP into adenosine (Fig 1C). Ecto-5'-NT overexpression and the transfection process per se did not affect the in vitro proliferation of MB cells (Fig 1D).

Evaluation of AMPase activity and cell proliferation after ecto-5'-NT inhibition
First, we determined the optimal concentration of APCP, a specific ecto-5'-NT inhibitor that inhibits the enzymatic activity in the cell lines Daoy, D283, D283ev and D283hCD73 (Fig 2). We could observe that D283 and D283ev demonstrated a very low enzymatic activity, corresponding to the low ecto-5'-NT expression that is presented by these cell lines. Thus, it is possible to infer that APCP did not alter this behavior. Daoy and D283hCD73 presented a prominent AMP hydrolysis, and APCP efficiently inhibited ecto-5'-NT activity at all of the tested concentrations (Fig 2). During sequencing, to determine the influence of ecto-5'-NT on MB cell proliferation, we used 5 μM APCP for 24 and 48 h. After 48 h, APCP stimulated the cell proliferation in the Daoy (54%) and D283hCD73 (41%) cell lines (Fig 3). These data suggest that the inhibition of ecto-5'-NT promotes cell proliferation in MB cell lines that express this enzyme. No difference was observed in D283ev cell proliferation at any time evaluated. D283 was not tested because it does did show a significant difference compared to D283ev, the transfection control cell line.

The effect of ecto-5'-NT overexpression on the MB xenograph in vivo model
The effects of ecto-5'-NT overexpression on in vivo MB growth were assessed after the subcutaneous injection of Daoy, D283ev or D283hCD73 cells in a nude mouse xenograph model. No changes in the body weight of the animals were noted during tumor growth (S1 Fig). Measurements of the maximal and minimal diameters showed that the D283ev cell line produced larger tumors compared to the other transplanted tumor type (Fig 4A and 4B and S2 Fig)   was obtained in this work was the reduction of the tumor growth presented by the D283hCD73 cell line (Fig 4A and 4B and S2 Fig)  demonstrate the evident effect of ecto-5'-NT overexpression on promoting tumor reduction compared to the D283ev control. At the same time of tumor growth, Daoy cells with elevated endogenous ecto-5'-NT expression generated a smaller tumor mass. In addition, the immunoreactivity levels for ecto-5'-NT confirmed the differences between ecto-5'-NT expression rates, in accordance with the produced tumor mass, where the tumors that originated by D283hCD73 showed the most prominent reactivity for ecto-5'-NT expression, while the D283ev tumors were negative (Fig 4C).

The characterization of xenograph human MB tumors and histopathological analysis
The pathological analysis of the implanted tumors demonstrated that all of the samples presented characteristics of MB (Fig 5; Table 1). The histopathological analysis showed that Daoyimplanted tumors presented areas of nodularity, accompanied by accentuated cellular atypia and moderate cellularity. Additionally, these tumors presented a low mitotic index and poor vascularization of the tumor tissue. On the other hand, D283ev and D283hCD73-transplanted animals showed augmented cellular atypia and cellularity with extensive necrosis areas. The  Table 1. The images were obtained using an inverted fluorescence microscope (Nikon Eclipse TE 300). doi:10.1371/journal.pone.0140996.g005 Ecto-5'-Nucleotidase Reduces Medulloblastoma Growth mitotic index that was presented by D283hCD73 MB tumor samples was lower than that of D283ev ( Table 1). The reduced proliferation and size of the tumors generated by this cell line correlate with the enhanced expression of ecto-5'-NT.
Implanted tumors represented human MB, as revealed by immunohistochemical staining for the specific markers enolase and synaptophysin. In addition, Ki67 and CD31 characterize this tumor type (Fig 6 and Table 2). Intensive and diffuse reactivity to enolase was present in D283ev and D283hCD73 tumor samples. Furthermore, D283ev tumor samples did not present immunoreactivity for synaptophysin, a marker of differentiated cells. The absence of this marker in D283ev demonstrates that this tumor was highly undifferentiated. On the other hand, synaptophysin expression, as observed in D283hCD73 samples, revealed an expressive population of differentiated cells, characterizing it as less aggressive. In agreement, D283hCD73-originated tumors showed less staining for the proliferation antigen Ki67 than did D283ev tumors (Fig 6, Table 2 and S3 Fig). The immunoreactivity for CD31, a vessel marker, was less evident in D283hCD73 tumor samples, indicating that this tumor is also less vascularized than the tumor originated by D283ev (Fig 6, Table 2 and S3 Fig).
In addition, we evaluated the immunolabeling to active caspase-3 in MB cell lines by flow cytometry and in MB tumor samples by immunohistochemistry. We observed that Daoy and D283hCD73 cell lines presented the highest staining for active caspase-3, where D283hCD73 showed a significant difference (Fig 7A). Although the values represented the basal levels of caspase-3 expression, the significant difference presented by D283hCD73 in relation to D283ev reflects elevated apoptosis levels and might be related to the reduced tumor growth. In agreement, with immunohistochemistry labeling for active caspase-3, D283hCD73 and Daoy tumor samples presented the prominent expression of this protein in relation to D283ev ( Fig  7B). Given these data, we suggest that the expression of ecto-5'-NT by MB tumor cells can promote alterations in basal apoptosis levels, favoring the reduction of the tumor throughout its growth.

P1 receptor gene expression in human MB cell lines
The expression levels of the A 1 adenosine receptor were higher in Daoy cells than in the D283 cell line (Fig 8). D283ev and D283hCD73 cells also revealed diminished A 1 receptor expression levels compared to Daoy cells. On the other hand, D283 cells showed the most prominent expression of the A 2A adenosine receptor. All of the other cell lines presented low expression rates of A 2B adenosine receptors. A 3 adenosine receptor expression could not be detected in these cell lines. The altered expression of P1 receptors as observed in transfected cells might be related to the transfection process because A 1 and A 2A expression were not different in D283ev and D283hCD73 cells. D283ev (n = 10) Accentuated (10/10) Accentuated (10/10) Present (10/10) 79.8 D283hCD3 (n = 9) Accentuated (8/9) Accentuated (8/9) Present (8/9) 64.7 The slides of H&E were analyzed by a pathologist in a blinded manner. Analysis was performed using ten randomly chosen fields (x 200) per tumor (Olympus BH-2 microscope). doi:10.1371/journal.pone.0140996.t001 Ecto-5'-Nucleotidase Reduces Medulloblastoma Growth

Discussion
To investigate the role of ecto-5'-NT in MB tumor progression, we overexpressed this enzyme in D283 MB cells, generating novel tools for investigating the participation of this enzyme in the process: D283ev was used as a transfection control, and D283hCD73 were the cells that received the ecto-5'-NT human sequence. First, we performed experiments to evaluate the Immunohistochemical labeling was performed as described in the Materials and Methods. Antisynaptophysin and enolase immunostaining were used to evaluate whether the tumor samples were representative of human MB. The proliferation profile was determined using the anti-human Ki67 antibody. Tissue vascularization was visualized with an anti-human CD31 antibody. Labeling is indicated by arrows. Additional analyses are described in Table 2  Ecto-5'-Nucleotidase Reduces Medulloblastoma Growth efficiency of transfection. The obtained results showed that D283hCD73 expressed higher levels of ecto-5'-NT mRNA and translated protein (Fig 1A and 1B). Moreover, this transfected cell line showed higher AMPase activity than did D283 wild type and D283ev cells (Fig 1C), confirming that the ecto-5'-NT transfection was successful. At sequencing, we could see that APCP in vitro could efficiently inhibit ecto-5'-NT activity (Fig 2A and 2D) and promote cell proliferation in Daoy and D283hCD73 (Fig 3A and 3C). The most important result was that the inhibition of ecto-5'-NT in vitro promotes cell proliferation, while in vivo, its overexpression promotes the reduction of tumor growth, demonstrating that the modulation of this enzyme can promote alterations in the MB cell proliferation levels, where its expression and activity can reduce this cell event. Immunoreactivity for ecto-5'-NT presented by D283hCD73 tumor slices confirms its overexpression in the tumor mass that presented reduced tumor growth (Fig 4). The pharmacological modulation of ecto-5'-NT promotes increased activity and a reduction of glioma cell proliferation in vitro [15,
doi:10.1371/journal.pone.0140996.t002 . Indomethacin, in addition to activating ecto-5'-NT, also promotes the expression of A 3 adenosine receptor, which induces cell death [16]. In this way, knowing that the main function attributed to ecto-5'-NT is the extracellular production of adenosine [1], which make its function by activation of P1 adenosine receptors, we also determined the expression profile of P1 receptors in human MB cell lines. Daoy, D283ev and D283hCD73 preferentially expressed A 1 , and D283 expressed prominent levels of the A 2A adenosine receptor (Fig 8). Of note, the cell transfection process appeared to increase the expression of all of the adenosine receptors in both the D283hCD73 and D283ev cell lines; nevertheless, in our tumor model, only Daoy and D283hCD73 were exposed to high adenosine levels, due to ecto-5'-NT expression. In pathological environments, ecto-5'-NT presents an important function to modulate the action of adenosine in tumor progression [1]. This nucleoside, by sensitizing P1 receptors, may favor tumor growth by stimulating angiogenesis, cell proliferation and immune response suppression [2]. However, adenosine is capable of generating different cellular behaviors depending on the expression profile of P1 receptors and the cell type expressing these receptors. It has been suggested that adenosine promotes tumor cell apoptosis by intrinsic [17] and extrinsic pathways [18]. Adenosine is taken up by cells into the intracellular medium, where it activates AMP-activated protein kinase (AMPK) and thus promotes apoptosis by caspase-3/-8, as shown for human hepatoma cells [17]. Saito and co-workers (2010) have shown that adenosine suppresses the growth of CW2 human colonic tumor cells by inducing apoptosis, which is mediated by A 1 receptors [19]. The RCR-1 astrocytoma cell line contains high levels of extracellular adenosine, promoting apoptosis mediated by A 1 receptor-stimulated caspase-9/-3 activation [18]. In addition, the selective agonism of the A 1 adenosine receptor reduced cell proliferation in different tumor human cell lines [20]. Given these data, and knowing that the overexpression of ecto-5'-NT promotes an increase in active caspase-3 immunolabeling in MB cell lines (Fig 7), we suggest that this enzyme can induce apoptosis in MB cell lines to activate the A 1 adenosine receptor to produce adenosine in the extracellular medium. In addition, D283hCD73 generated a tumor with more differentiated cells, as demonstrated by the enhanced synaptophysin immunoreactivity (Fig 6). In agreement with the results reported here, the samples of patients with prostate carcinoma revealed less ecto-5'-NT expression in tumor tissues compared to normal differentiated prostatic tissue [21]. Furthermore, enhanced ecto-5'-NT expression levels may be related to good prognosis, as suggested by the increased survival rates of these patients. Furthermore, ovarian cancer patients with good prognosis also presented high tumor differentiation levels and ecto-5'-NT expression [22]. Together, these data suggest that the overexpression of ecto-5'-NT in the D283 MB cell line makes it less aggressive and favors the reduction of tumor growth. In agreement with the increased number of differentiated cells, D283hCD73 showed a lower proliferative index, corroborated by a reduced mitotic index and the lowest frequency of Ki67 labeling, as well increased active caspase-3 immunolabeling, which is indicative of apoptosis. This tumor also presented less CD31 immunoreactivity than did D283ev, indicating decreased tumor mass vascularization, which is associated with reduced tumor growth. Thus, taken together, these results could justify the reduced tumor growth presented by the D283hCD73 MB cell line.
All MB types are considered by the WHO (World Health Organization) to be highly malignant tumors [13]. However, we suggested that MB tumor progression depends on ecto-5'-NT expression levels. Animals that were injected with Daoy MB cells generated a large tumor only after four months of growth (S4 Fig), in contrast to the tumors generated by the D283ev cell line, which achieved their maximum size following 45 days of inoculation. Because the Daoy MB cell line was also able to generate a malignant tumor (S2 Table), the results presented here suggest that ecto-5'-NT expression may not be related to the degree of malignancy but rather to decreased tumor growth, making it slower and thus increasing the survival time. Ecto-5'-NT expression is supposedly regulated by the Wnt/β-catenin canonic pathway, which has been considered a good prognostic marker for MB patients [9,11]. Thus, although all MB are malignant, these data suggest that the expression of ecto-5'-NT by this type of childhood tumor can be associated with good prognosis, where these tumors present a slower growth and become susceptible to therapy.
In view of the data presented here and the literature review, we suggest that the reduction of the tumor growth after ecto-5'-NT overexpression can be attributed to two possible events: 1) an increase of differentiated cells in the tumor mass generated by D283hCD73 that makes the tumor cells less proliferative and 2) the activation of A 1 adenosine receptors expressed by D283hCD73 cells, which can promote apoptosis and slow tumor growth.
Finally, ecto-5'-NT positively affects the cancer progression of different types of adult tumors (breast and bladder cancer, melanoma and glioma) [1]. In specific childhood tumors, such as MB, this enzyme is involved with a subtype that presents a profile with good prognosis [9]. Adult tumors can present behaviors different from those of childhood tumors, and the literature emphasizes that a comparison between these behaviors cannot be routinely performed [23,24]. This factor could also be considered important in explaining why ecto-5'-NT expression in MB is involved in a reduction of tumor growth. In conclusion, these data suggest ecto-5'-NT is an important target for controlling MB progression, suggesting a novel diagnostic tool and a target for therapeutic intervention. Additional studies are necessary to demonstrate the relationship between ecto-5'-NT and P1 adenosine receptors in MB progression.