Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Current Microscopy Contributions to Advances in Science and Technology (A. Méndez-Vilas, Ed.) Osteosarcoma treatment using the different bone growth factors D. Alcântara*1, S. E. A. L. Will1, P. Fratini 1, A. L. R. Franciolli 1, R. E. G. Rici1, D. K. Abreu1, R. M. Leandro1, F. M. O. Silva1, M. N. Rodrigues1 and M. A. Miglino1 1 Surgery Department, Faculty of Veterinary Medicine and Animal Science, University of São Paulo. Av. Dr. Orlando Marques de Paiva 87, São Paulo, SP, Brazil. CEP: 05508-270. Osteosarcoma is an extremely aggressive primary bone tumor characterized by rapid growth and highly metastatic potential. Pro-angiogenic factors are related to poor prognosis and disease progression. There are important factors which can be mediators for bone formation and repair. The aim of this study was to evaluate the association of cell derived from human osteossarcoma cells (MG63) with the bone growth factors (FGF, VEGF, rBMP2). MG63 were plated and cultured in DMEM-H supplemented with 10% bovine fetal serum, antibiotics (1%) and sodium pyruvate (1%) for 24 hours. The cells were treated with FGF (20nM), VEGF (20nM) e rBMP2 (1µg) for 48 hours. After 48 hours, the cells were fixed with 4% of pataformaldehyde and stained with Von Kossa. All the treatments showed decrease in the osteogenic potential in the MG63 cells. However, the best treatment was the rBMP2, which showed a high therapeutic potential for osteosarcoma in vitro and it can represent a new alternative to complement the current clinical treatments. Keywords osteosarcoma, rBMP2, bone growth factors. 1. Introduction Osteosarcoma is a primary bone tumor that occurs with most incidence in childhood and adolescence, representing 5% of malignancies in this group [1,2]. Although rare, is the most common bone cancer and main death cause by cancer in children, with the incidence peak corresponding to the period of rapid skeletal bone growth [3]. Osteosarcoma is locally invasive and potentially metastatic, which makes it particularly difficult to treat, being the metastatic disease the most common cause of patient‘s death . Metastases occur early and the lung is the preferentially affected organ , surrounding 90% of the cases [4,5]. The regions most affected by the tumor are areas of rapid bone growth as distal femur, proximal tibia and proximal humerus. In adults, there is a prevalence in the axial skeleton and in areas that were previously irradiated or that have underlying abnormalities such as Paget's disease [6]. Histologically, the osteosarcoma is malignant mesenchymal cells which appear in the extended and polygonal shapes and produce an osteoid matrix. The osteoid matrix is a distinguishing feature of osteosarcomas, non-osteogenic bone tumors do not produce this matrix [7,8]. The prognosis of osteosarcoma depends on many factors including age, gender, localized tumor or metastatic tumor site (axial or appendicular skeleton), surgical margins, tumor volume and necrosis after preoperative chemotherapy, type of treatment chosen, serum phosphatase alkaline and tumor subtypes [9]. Osteosarcoma arises from mesenchymal stem cells or osteoprogenitor cells due to a disruption in the osteoblast differentiation pathway [10, 11]. Chemotherapy combination along with limb-sparing surgery has been the main treatment for osteosarcoma [12]. Multimodality treatments have markedly improved the prognosis for patients with osteosarcoma and life expectancy is now 10 years for 50-70% of patients [13]. However, currently, osteosarcoma is the second leading cause of cancerrelated death for children and young adults [14]. Bone morphogenetic proteins are members of the transforming growth factor (TGF)-β superfamily, functionally induce bone and cartilage formation and are considered multifunctional cytokines [15]. Therefore, they can represent an important role in the treatment of osteosarcoma due to their inhibitory effects in the tumorigenesis [16, 17]. Tumor cell differentiation correlates with the prognosis and growth factor plays an important role in malignant bone tumor development. FGF is involved in proliferation, differentiation and cell migration of the skeletal tissues [18, 19]. Angiogenesis is essential for tumor growth and metastasis formation. The vascular endothelial growth factor (VEGF) is an important regulator of this process. The activation of the VEGF receptor pathway triggers a signaling process that promote endothelial cell growth, migration and maintenance of pre-existing vasculature. Due to its role in angiogenesis, this receptor has become an important focus on the development of antiangiogenic drugs [20]. Although the last two decades have been promising in the neoadjuvant treatment of osteosarcoma, and even that new therapeutic strategies give options and information to prolong survival and maintain a functional member without pain and without metastases, the expectations are still rare. So our goal was to test the therapeutic potential of several bone growth factors such as bone morphogenetic protein type 2 (rBMP2), fibroblast growth factor (FGF) and vascular endothelial growth factor (VEGF) in the osteosarcoma treatment. © 2012 FORMATEX 200 Current Microscopy Contributions to Advances in Science and Technology (A. Méndez-Vilas, Ed.) 2. Material and Methods 2.1 Cell Culture The osteosarcoma cell line MG-63 from ATCC (USA) was used and cultivated in DMEM-H containing 10% fetal bovine serum (FBS), 0,1 mg/mL streptomycin/penicillin and 1mM sodium pyruvate. Cells were cultured in a humidified incubator at 37o C and 5% CO2. 2.2 Osteosarcoma treatment After confluence, the MG63 cells were detached with trypsin/EDTA and subsequently replated in 12 wells plates. After 24 hours, cells were treated with different growth factors: FGF (20nM), VEGF (20nM) and rBMP2 (1µ) separately in duplicates. After 48 hours of treatment, the medium were removed, cells were washed with PBS and fixed with 4 % paraformaldehyde for 24 hours. Cells was examined using a light microscope (Nikon Eclipse E-800). 2.3 Von Kossa Staining MG63 cell were washed in distilled water and stained with 5% silver nitrate solution, in the dark, for 30 minutes. They were washed in distilled water and exposed to a 100W lamp for 60 minutes (Von Kossa staining), and then quickly washed with 5% sodium thiosulfate, counter-stained with Harris Hematoxylin, subject to the diaphanisation process and mounted in SP 15 Permount. Cells were examined using a inverted microscope (NIKON Eclipse TS100, Nikon Instruments Inc., Brazil), coupled to a NIKON image capture system. 2.4 Scanning Electron Microscopy Cells were grown in 3cm Petri dishes. After confluence, the medium was removed and used for washing with PBS, and then placed in 3% glutaraldehyde. After fixing, the plates were washed in PBS and distilled water, post-fixed in osmium tetroxide (1%) and dehydrated in a progressive ethanol series (70-100%). The material was drying at the critical point apparatus (PCD 020) by using CO2. After drying, the plates received a metal coating with gold by sputtering (EMITECH K550). Finally, the samples were analyzed by scanning electron microscope (LEO 435 VP). 2.5 Flow Cytometry The cells were washed with PBS and incubated with 1 µg of the antibodies STRO-1, OCT3/4, Ki-67, VEGF, and Caspase-3. Each sample was analyzed by flow cytometry to quantify antibody activity. The analysis was conducted by a FACSCalibur (Becton Dickinson, San Jose, California, USA) and analyzed by the WinMDI 2.9 software. The expression of markers was determined by comparison using an isotype control labeled with FITC fluorochrome nonspecific (Alexa Fluor 488). 3. Results 3.1 Osteosarcoma Treatment (inverted microscopy) The fotodocumentation by inverted microscopy showed cell density decreased in FGF e rBMP2 treatments. In addition, the MG63 cell treatment using rBMP2 showed changes in cell morphology, loss of adhesion to extracellular matrix and cell to cell comunication decreased. It showed that the treatment of human osteosarcoma cells with this protein leads to apoptosis. © 2012 FORMATEX 201 Current Microscopy Contributions to Advances in Science and Technology (A. Méndez-Vilas, Ed.) Fig 1 Histological aspects of MG63 cells by inverted microscopy. (A) MG63 cells control; (B) MG63 cells treated with VEGF; (C) MG63 cells treated with FGF and (D) MG63 cells treated with rBMP2. 3.1.2 Von Kossa Staining The analyses of the osteosarcoma treatment using different bone growth factors by osteogenic potencial showed a decreased in osteogenic potential, cell density and calcification areas in all treatments type, being the rBMP2 the best treatment. © 2012 FORMATEX 202 Current Microscopy Contributions to Advances in Science and Technology (A. Méndez-Vilas, Ed.) Fig. 2 Histological aspects of the MG63 cells stained with Von Kossa. (A, B) MG63 control; (C, D) MG63 treated with VEGF; (E, F) MG63 treated with FGF; (G, H) MG63 treated with rBMP2. 3.2 Scanning Electron Microscopy The treatment analyses by Scanning Eletron Microscopy showed apoptosis in the treatment with FGF e rBMP2 such as extracellular matrix degradation (rBMP2). © 2012 FORMATEX 203 Current Microscopy Contributions to Advances in Science and Technology (A. Méndez-Vilas, Ed.) Fig. 3 Morphological aspects, Scanning Electron Microscopy. (A) MG63 control. (B) MG63 treated with VEGF. (C) MG63 treated with FGF. (D, E) MG63 treated with rBMP2. 3.3 Flow Cytometry The flow cytometry analyzes showed that treatment with FGF MG63 cells induced an increase in the expression of markers Oct3 / 4, Stro-1, Caspase-3 and VEGF and a decreased Ki-67expression. Treatment with VEGF showed an increased expression of all markers compared to control. RBMP2 treatment induced a decrease in expression of the pluripotency markers (Oct3 / 4), osteogenic potential stem cell tumor (Stro-1), cellular proliferation (Ki-67), angiogenesis (VEGF) and increased the cell apoptosis (Caspase -3). Fig. 4 Flow cytometry analyses of the MG63 cells treatment. MG63 control (Co), MG63 treated with FGF, VEGF and rBMP2. © 2012 FORMATEX 204 Current Microscopy Contributions to Advances in Science and Technology (A. Méndez-Vilas, Ed.) 4. Discussion Osteosarcoma cells are derived from malignant bone tumors. These osteoblastic cells share some characteristics; however, they have chromosomal abnormalities that lead to abnormal cellular and molecular functions (PAUTKE et al., 2004). Blockage of stem cell differentiation may lead to tumorigenesis [21] and the BMP-2 has been acting as a potent inducer of osteogenic differentiation [22]. In studies related to cancer, tissue cultures have a key role with possible applications in the diagnosis and in the treatment conditioning of several cancer types [23]. We found that treatment of human osteosarcoma cells with rBMP2 was efficient confirmed by testing osteogenic potential and Von Kossa staining, highlighting the differences between the use of rBMP2 and other factors noted by a reduction of calcification area. The rBMP2 use is reported in other studies [11,12] as an important tumorigenesis inhibitor. Recent studies have reported that treatment osteosarcoma using bone marrow stem cells associated with rBMP2 was effective in reducing its osteogenic potential [24], suggesting a high therapeutic potential of the protein. In our study, the analysis by inverted microscopy and scanning electron microscopy showed that rBMP2 induced tumor cells apoptosis. BMPs are important in cell differentiation, proliferation, morphogenesis, cellular survival and apoptosis [25]. Apoptosis is defined as a cascade of biochemical events that lead to cell death and nuclear fragmentation. The cytotoxic effect of most chemotherapy agents "in vitro" and "in vivo" depend on the induction of apoptosis in susceptible tumor cells [26]. In flow cytometry analysis, the therapeutic activity of the protein was assessed using Caspase-3, Ki-67, Oct3 / 4, VEGF and Stro-1. In a result an increase in the phosphorylated Caspase-3 expression was observed confirming the induction of tumor cells apoptosis, also reported in other studies [24]. A decrease in the expression of cell proliferation (Ki-67), pluripotency (Oct 3/4), angiogenesis (VEGF) and osteogenic potential (Stro-1) markers was also observed. BMP-2 inhibits embryonic stem cell marker expression; it might prevent tumor formation and growth in vivo [27]. Oct3/4, Nanog and Sox-2 are important embryonic stem cell markers implicated in the tumorigenesis of several cancers. In addition, they are essential transcription factors regulating self-renewal and pluripotency of embryonic stem cells. Recent studies showed that these markers have also been implicated in tumorigenesis [28, 29]. Some studies have reported the presence of a small cell subpopulation expressing Stro-1, also known as tumor stem cells that can arise by stem cells transformation [30,31]. The increased expression of VEGF is an important factor involved in solid tumors growth, including osteosarcoma. Therefore, VEGF expression in osteosarcoma is related to a decrease in the survival time and presence of metastases [32,33]. All the treatments showed decrease in the osteogenic potential in MG63 cells. However, we concluded that the best treatment was the rBMP2, which showed a high therapeutic potential for osteosarcoma in vitro, whihc can represent a new alternative to complement the current clinical treatments. Acknowledgements: The funding support by CAPES is gratefully acknowledged. References [1] Rech C, Castro JR CG, Mattel J, Greglanin L, Di Leone L, David A, Rivero LF, Tarrago R, Abreu A, Brunetto AL. Características clínicas do osteossarcoma na infância e sua influência no prognóstico. Journal of Pediatrics. 2004; 80:65-70. [2] Van Den Berg H. Biology and therapy of solid tumors in childhood. Update on Cancer Therapeutics I. 2006; 1:367-383. [3] Ek ETH, Dass CR, Choong PFM. Commonly used mouse models of osteosarcoma. Clinical Reviews in Oncology/ Hematology. 2006; 60:1-8. [4] Spodnick GJ, Berg J, Rand WM. Prognosis for dogs with appendicular osteosarcoma treated by amputation alone: 162 cases (1978-1988). Jounal of the American Veterinary Association. 1992; 200:995-999. [5] Costa FS, Tostes RA, Farias MR, Sampaio RL, Perez JA. Metástase cutânea de osteossarcoma em um cão. relato de caso. Brazilian Journal Veterinary Research Animal Science. 2001; 38:240-242. [6] Hayden JB, Hoang HH. Osteosarcoma: basic science and clinical implications. Orthop Clin N Am. 2006; 37:1–7. [7] Straw RC, Withrow SJ, Powers BE. Management of canine appendicular osteosarcoma. Veterinary Clinics of North America: Small Animal Practice. 1990; 20:1141-1161. [8] Thompson KG, Poll RR. Tumors of bones. In: Meuten DJ. Tumors in domestic animals. 4. ed. EUA: Iowa State Press, 2002:245-317. [9] Longhi A, Errani C, Paolis M, Mercuri M, Bacci G. Primary bone osteossarcoma in the pediatric age: state of the art. Cancer Treatment Reviews. 2006; 32:423-436. [10] Mohseny AB, Szuhai K, Romeo S, Buddingh EP, Briaire-de Bruijn I, de Jong D, van Pel M, Cleton-Jansen AM, Hogendoorn PC. Osteosarcoma originates from mesenchymal stem cells in consequence of aneuploidization and genomic loss of Cdkn2. J Pathol. 2009; 219:294-305. [11] Tang N, Song WX, Luo J, Haydon RC, He TC. Osteosarcoma development and stem cell differentiation. Clin Orthop Relat Res. 2008; 466:2114-2130. [12] Wittig JC, Bickels J, Priebat D, Jelinek J, Kellar-Graney K, Shmookler B, Malawer MM. Osteosarcoma: a multidisciplinary approach to diagnosis and treatment. Am Fam Physician. 2002; 65:1123-1132. © 2012 FORMATEX 205 Current Microscopy Contributions to Advances in Science and Technology (A. Méndez-Vilas, Ed.) [13] Rossi B, Schinzari G, Maccauro G, Scaramuzzo L, Signorelli D, Rosa MA, Fabbriciani C, Carlo B. Neoadjuvant multidrug chemotherapy including High-Dose Methotrexate modifies VEGF expression in Osteosarcoma: an immunohistochemical analysis. BMC Musculoskeletal Disorders. 2010; 11:1-10. [14] Ek ET, Dass CR, Choong PF. Commonly used mouse models of osteosarcoma. Crit Rev Oncol Hematol. 2006; 60:1-8. [15] Hogan BL. Bone morphogenetic proteins: multifunctional regulators of vertebrate development. Genes Dev. 1996;10:15801594. [16] Beck SE, Jung BH, Fiorino A, Gomez J, Rosario ED, Cabrera BL, et al. Bone morphogenetic protein signaling and growth suppression in colon cancer. Am J Physiol Gastrointest Liver Physiol. 2006; 291:135-45. [17] Piccirillo SG, Reynolds BA, Zanetti N, Lamorte G, Binda E, Broggi G, et al. Bone morphogenetic proteins inhibit the tumorigenic potential of human brain tumour-initiating cells. Nature. 2006; 444:761-5. [18] Bodo M, Lilli C, Bellucci C, Carinci P, Calvitti M, Pezzetti F, Stabellini G, Bellocchio S, Balducci C, Carinci F, Baroni T. Basic Fibroblast Growth Factor Autocrine Loop Controls Human Osteosarcoma Phenotyping and Differentiation. Molecular Medicine. 2002; 8: 393–404. [19] Skjerpen CS, Nilsen T, Wesche J, Olsnes S. Binding of FGF-1 variants to protein kinase CK2 correlates with mitogenicity. The Embo Journal. 2002; 21:4058-4069. [20] Hicklin DJ, Ellis LM. Role of the vascular endothelial growth factor pathway in tumor growth and angiogenesis. Journal of Clinical Oncology. 2005; 23:1011-1027. [21] Reya T, Morrison SJ, Clarke MF, Weissman IL. Stem cells, cancer and cancer stem cells. Nature. 2001; 414:105-11. [22] Luo X, Chen J, Song WX, Tang N, Luo J, Deng ZL, et al. Osteogenic BMPs promote tumor growth of human osteosarcomas that harbor differentiation defects. Lab Invest. 2008; 88:1264-1277. [23] Shay JW, Tomlinson G, Piatszek MA, Gollahon LS. Spontaneous in vitro immortalization of breast epithelial cells from patient with Li-Fraumeni syndrome. Molecular and Cellular Biology. 1995; 15:425 - 432. [24] Rici REG, Alcântara D, Fratini P, Wenceslau CV, Ambrósio CE, Miglino MA, Maria DA. Mesenchymal stem cells with rhBMP-2 inhibits the growth of canine osteosarcoma cells. BMC Veterinary Research. 2012; 8:1-9. [25] Pautke C, Schieker M, Tischer T, Kolk A, Neth P, Mutschler W, Milz S. Characterization of osteosarcoma cell lines MG-63, Saos-2 and U-2 OS in comparison to human osteoblasts. Anticancer Research. 2004; 24:3743-3748. [26] Ciarcia R, Pagnini C, Fiorito F, Pellicane A, Montagnaro S, Russo R, Florio S. Effect of “All - trans ” retinoic acid in canine osteosarcoma chemotherapy. Veterinary Research Communications. 2008; 32:267-269. [27] Wang L, Park P, Zhang H, La Marca F, Claeson A, Valdivia J, Lin CY. rhBMP-2 inhibits the tumorigenicity of cancer stem cells in human osteosarcoma OS99-1 cell line. Cancer Biol Therapy. 2011; 11:457-463. [28] Ben-Porath I, Thomson MW, Carey VJ, Ge R, Bell GW, Regev A, et al. An embryonic stem cell-like gene expression signature in poorly differentiated aggressive human tumors. Nat Genet. 2008; 40:499-507. [29] Santagata S, Ligon KL, Hornick JL. Embryonic stem cell transcription factor signatures in the diagnosis of primary and metastatic germ cell tumors. Am J Surg Pathol. 2007; 31:836-45. [30] Shi S, Gronthos S. Perivascular niche of postnatal mesenchymal stem cells in human bone marrow and dental pulp. Journal of Bone and Mineral Research. 2003; 18:696-704. [31] Siclari V, Qin L. Targeting the osteosarcoma cancer stem cell. Journal of Orthopaedic Surgery and Research. 2012; 5:1-10. [32] Kaya M, Wada T, Akatsuka T, Kawaguchi S, Nagoya S, Shindoh M, Higashino F, Mezawa F, Okada F, Ishii S. Vascular endothelial growth factor expression in untreated osteosarcoma is predictive of pulmonary metastasis and poor prognosis. Clinical Cancer Research. 2000; 6:572-577. [33] Kaya M, Wada T, Kawaguchi S, Nagoya S, Shindoh M, Higashino F, Mezawa F, Okada F, Ishii S. Increased pre-therapeutic serum vascular endothelial growth factor in patients with early clinical relapse of osteosarcoma. British Journal of Cancer. 2002; 86:864–869. © 2012 FORMATEX 206