Osteosarcoma pathophysiology: Difference between revisions

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{{CMG}};{{AE}} {{PSK}}
{{CMG}}; {{AE}} [[User:DrMars|Mohammadmain Rezazadehsaatlou[2]]].
{{Osteosarcoma}}
{{Osteosarcoma}}
==Overview==
==Overview==
The osteosarcomas may be localized at the end of the [[Long bone|long bones]] (commonly in the [[metaphysis]]). Most often osteosarcoma affects the upper end of the [[tibia]], [[humerus]], or lower end of the [[femur]]. On [[gross pathology]], areas of bone formation, [[hemorrhage]], [[fibrosis]], and cystic [[degeneration]] on cut surface are characteristic findings of osteosarcoma. On microscopic [[histopathological]] analysis, presence of [[osteoid]] within the [[tumor]], [[pleomorphic]] cells, [[anaplastic]] cells, and atypical [[mitoses]] are characteristic findings of osteosarcoma. Osteosarcoma may be associated with hereditary syndromes such as [[Li-Fraumeni syndrome]] and [[Rothmund-Thomson Syndrome]].
The main cause of [[osteosarcoma]] is not well-known, yet. However, a number of [[risk factors]] have been identified in this regard. [[Osteosarcoma]] can involve any [[bone]] but it usually affects the [[extremities]] of long bones near [[metaphyseal]] growth plates. The most common sites include
*[[Femur]] 42% of cases ( the [[distal]] femur had around 75% of involvement).
*[[Tibia]] 19% of cases ( the [[proximal]] tibia had around 80% of involvement).
*[[Humerus]] 10% of cases  ( the [[proximal]] humerus had around 90% of involvement).
*[[Skull]] and jaw 8% of cases.
*[[Pelvis]] 8% of cases.


==Pathophysiology==
==Pathophysiology==
The osteosarcomas may be localized at the end of the [[long bones]] (commonly in the [[metaphysis]]). Most often osteosarcoma affects the upper end of the [[tibia]], [[humerus]], or lower end of the [[femur]]. Osteosarcomas tend to occur at the sites of bone growth, presumably because proliferation makes [[Osteoblastic osteosarcoma|osteoblastic cells]] in this region prone to acquire mutations that could lead to transformation of cells (the ''RB'' gene and [[P53 gene|''p53'' gene]] are commonly involved).


==Gross Pathology==
* Traditionally, our knowledge about [[osteosarcoma]] has been mostly anatomical but it should be noted that [[osteosarcoma]] arises most commonly in the [[metaphyseal]] region of long [[bones]], especially within the [[medullary]] cavity, then [[Osteosarcoma|it]] involves the bone [[cortex]]; consequently a pseudocapsule forms around the penetrating [[tumor]]. [[Osteosarcoma]] is characterised as a highly cellular tumor consisted of: [[pleomorphic]] spindle-shaped cells responsible for the producing an [[osteoid]] matrix. However, recent developments in the field of medical sciences and the [[molecular]] biology have provided huge insights regarding the molecular [[pathogenesis]] of [[osteosarcoma]]<ref name="pmid19915470">{{cite journal |vauthors=Kim HJ, Chalmers PN, Morris CD |title=Pediatric osteogenic sarcoma |journal=Curr. Opin. Pediatr. |volume=22 |issue=1 |pages=61–6 |date=February 2010 |pmid=19915470 |doi=10.1097/MOP.0b013e328334581f |url=}}</ref><ref name="pmid25070231">{{cite journal |vauthors=Moore DD, Luu HH |title=Osteosarcoma |journal=Cancer Treat. Res. |volume=162 |issue= |pages=65–92 |date=2014 |pmid=25070231 |doi=10.1007/978-3-319-07323-1_4 |url=}}</ref><ref name="pmid20179183">{{cite journal |vauthors=Ilaslan H, Schils J, Nageotte W, Lietman SA, Sundaram M |title=Clinical presentation and imaging of bone and soft-tissue sarcomas |journal=Cleve Clin J Med |volume=77 Suppl 1 |issue= |pages=S2–7 |date=March 2010 |pmid=20179183 |doi=10.3949/ccjm.77.s1.01 |url=}}</ref><ref name="pmid21037356">{{cite journal |vauthors=Wu PK, Chen WM, Lee OK, Chen CF, Huang CK, Chen TH |title=The prognosis for patients with osteosarcoma who have received prior manipulative therapy |journal=J Bone Joint Surg Br |volume=92 |issue=11 |pages=1580–5 |date=November 2010 |pmid=21037356 |doi=10.1302/0301-620X.92B11.24706 |url=}}</ref><ref name="pmid29980176">{{cite journal |vauthors=Obiedat H, Alrabadi N, Sultan E, Al Shatti M, Zihlif M |title=The effect of ERCC1 and ERCC2 gene polymorphysims on response to cisplatin based therapy in osteosarcoma patients |journal=BMC Med. Genet. |volume=19 |issue=1 |pages=112 |date=July 2018 |pmid=29980176 |pmc=6035436 |doi=10.1186/s12881-018-0627-4 |url=}}</ref>:
*Macroscopically, osteosarcomas are [[solid]], hard, and bulky tumors.
*[[Heterogeneous]] cut surface demonstrates areas of [[hemorrhage]], [[fibrosis]] and cystic [[degeneration]].
*Areas of bone formation are characteristic of osteosarcomas, with the degree of bone formation varying widely.
*The tumor is irregular ("fir-tree" or "sun-burst" appearance on X-ray examination) due to the tumor spicules of calcified bone radiating in right angles. These right angles form what is known as [[Codman's triangle]], which is characteristic but not diagnostic of osteosarcoma. Surrounding tissues are infiltrated.


{| align=""
=== Growth Factors ===
|- valign="top"
| [[Image:Osteosarcoma (2).jpg|thumb|350px|Osteosarcoma-distal femur-pathology<ref name="radio">Image courtesy of  Dr Frank Gaillard. [http://www.radiopaedia.org Radiopaedia] (original file [http://radiopaedia.org/cases/osteosarcoma-distal-femur-pathology]). [http://radiopaedia.org/licence Creative Commons BY-SA-NC</ref>]]
|}


==Microscopic Pathology==
* Impaired expression of [[growth factors]] leads to the accelerated proliferation of [[Cells (biology)|cells]]. Most important growth factor include:<ref name="pmid30881341">{{cite journal |vauthors=Sergi C, Shen F, Liu SM |title=Insulin/IGF-1R, SIRT1, and FOXOs Pathways-An Intriguing Interaction Platform for Bone and Osteosarcoma |journal=Front Endocrinol (Lausanne) |volume=10 |issue= |pages=93 |date=2019 |pmid=30881341 |pmc=6405434 |doi=10.3389/fendo.2019.00093 |url=}}</ref><ref name="pmid30873026">{{cite journal |vauthors=Colombo M, Platonova N, Giannandrea D, Palano MT, Basile A, Chiaramonte R |title=Re-establishing Apoptosis Competence in Bone Associated Cancers via Communicative Reprogramming Induced Through Notch Signaling Inhibition |journal=Front Pharmacol |volume=10 |issue= |pages=145 |date=2019 |pmid=30873026 |pmc=6400837 |doi=10.3389/fphar.2019.00145 |url=}}</ref><ref name="pmid30777054">{{cite journal |vauthors=Weinman MA, Fischer JA, Jacobs DC, Goodall CP, Bracha S, Chappell PE |title=Autocrine production of reproductive axis neuropeptides affects proliferation of canine osteosarcoma in vitro |journal=BMC Cancer |volume=19 |issue=1 |pages=158 |date=February 2019 |pmid=30777054 |pmc=6379937 |doi=10.1186/s12885-019-5363-4 |url=}}</ref><ref name="pmid30591452">{{cite journal |vauthors=Haralambiev L, Wien L, Gelbrich N, Kramer A, Mustea A, Burchardt M, Ekkernkamp A, Stope MB, Gümbel D |title=Effects of Cold Atmospheric Plasma on the Expression of Chemokines, Growth Factors, TNF Superfamily Members, Interleukins, and Cytokines in Human Osteosarcoma Cells |journal=Anticancer Res. |volume=39 |issue=1 |pages=151–157 |date=January 2019 |pmid=30591452 |doi=10.21873/anticanres.13091 |url=}}</ref><ref name="pmid30042132">{{cite journal |vauthors=Boulay G, Volorio A, Iyer S, Broye LC, Stamenkovic I, Riggi N, Rivera MN |title=Epigenome editing of microsatellite repeats defines tumor-specific enhancer functions and dependencies |journal=Genes Dev. |volume=32 |issue=15-16 |pages=1008–1019 |date=August 2018 |pmid=30042132 |pmc=6075149 |doi=10.1101/gad.315192.118 |url=}}</ref>
*On microscopic [[histopathological]] analysis, a characteristic feature of osteosarcoma is presence of [[osteoid]] (bone formation) within the tumor.
**[[Transforming growth factor]] (TGF)
*[[Tumor cell|Tumor cells]] are [[pleomorphic]], [[anaplastic]], giant, and display numerous atypical [[mitoses]].
**[[Insulin-like growth factor]] ([[Insulin-like growth factor|IGF]])
*These cells produce [[osteoid]] describing irregular [[trabeculae]] ([[amorphous]], [[eosinophilic]]/pink) with or without central [[calcification]] ([[hematoxylinophilic]]/blue, granular) - tumor bone.
** Connective tissue growth factor ([[CTGF]])
*[[Tumor cell|Tumor cells]] are included in the [[osteoid]] matrix. Depending on the features of the [[Tumor cell|tumor cells]] present (whether they resemble [[bone cells]], [[cartilage]] cells or [[fibroblast]] cells), the tumor can be sub classified. The presence of immature blood vessels (sarcomatous vessels lacking endothelial cells) favors bloodstream metastasis.
**[[Parathyroid hormone]] ([[Parathyroid hormone|PTH]])


<gallery>
=== TGF-β ===


Osteosarcoma-conventional-histology (1).jpg|Histology of conventional osteosarcoma<ref name=radio>Image courtesy of Dr Frank Gaillard. [http://www.radiopaedia.org Radiopaedia] (original file [http://radiopaedia.org/cases/osteosarcoma-conventional-histology]). http://radiopaedia.org/licence Creative Commons BY-SA-NC</ref>
* These [[proteins]] are a large family of [[dimeric]] proteins and they influence a wide variety of cell process such as [[differentiation]], [[proliferation]], [[apoptosis]], and [[matrix]] production.  
Osteoid formation.jpg|High-magnification micrograph showing osteoid formation in an osteosarcoma H&E stain
* Bone morphogenic [[proteins]] ([[Basic metabolic panel|BMPs]]) build a large component of the [[TGF-β|TGF]]-β families.
</gallery>
* Expression of the [[TGF-β]]1 is significantly higher in high-grade [[Osteosarcoma|osteosarcomas]].
* Recent studies revealed an association between increased susceptibility and [[metastasis]] of [[osteosarcoma]] with TGFR1 variants, [[TGFBR1]]*6A, and Int7G24A.


*Characteristic features on microscopic analysis are variable depending on the osteosarcoma subtype:
=== IGF ===


{| style="border: 0px; font-size: 90%; margin: 3px; width: 1000px" align="center"
* [[Insulin-like growth factor-I|IGF-I]] and IGF-II are growth factors usually overexpressed by [[Osteosarcoma|osteosarcomas]].  
| valign="top" |
* [[Insulin-like growth factor|IGF]] families bind corresponding receptors such as IGF-1R, causing the activation of the [[Phosphoinositide 3-kinase|PI3K]] and [[Mitogen-activated protein kinase|MAPK]] transduction pathways.  
|+
* Consequently they supports the cell proliferation and inhibition of [[apoptosis]]. Meanwhile, the Lentivirus-mediated [[Small nuclear RNA|snRNA]] targeting IGF-R1 increases the chemosensitivity and the anti-tumor response of [[osteosarcoma]] cells to [[Docetaxel (patient information)|docetaxel]] and [[cisplatin]].
! style="background: #4479BA; width: 200px;" | {{fontcolor|#FFF|Subtype}}
! style="background: #4479BA; width: 400px;" | {{fontcolor|#FFF|Features on Histopathological Microscopic Analysis}}
|-
| style="padding: 5px 5px; background: #DCDCDC; font-weight: bold" |
:Telangiectatic osteosarcoma
| style="padding: 5px 5px; background: #F5F5F5;" |
*Most osteosarcomas have a small telangiectatic component but in order to be classified as a telangiectatic osteosarcoma the telangiectatic component should comprise more than 90%.<ref name="radio2">Osteosarcoma. Dr Yuranga Weerakkody◉ et al. Radiopaedia.org 2015. http://radiopaedia.org/articles/telangiectatic-osteosarcoma</ref>
*Most of the tumor comprises of large blood filled spaces separated by thin bony septations.
*Microscopically, the tumor consists of vascular sinusoids surrounded by thin septae, osteoid matrix and cells with significant pleomorphism and high mitotic rate.
|-
| style="padding: 5px 5px; background: #DCDCDC;font-weight: bold" |
:Low grade osteosarcoma
| style="padding: 5px 5px; background: #F5F5F5;" |
*Histologically it is a low grade tumor which occurs in the medullary canal of long bones.<ref name="radio2">Osteosarcoma.Dr Yuranga Weerakkody◉ and Dr Prashant Mudgal et al. Radiopaedia.org 2015. http://radiopaedia.org/articles/low-grade-osteosarcoma</ref>
*It contains osseous matrix with fibrous stroma and there is variable amount of bone production.
*Histologic pattern is similar to [[fibrous dysplasia]] and low grade parosteal osteosarcoma.
|-
| style="padding: 5px 5px; background: #DCDCDC;font-weight: bold" |
:Periosteal osteosarcoma
| style="padding: 5px 5px; background: #F5F5F5;" |
*Periosteal osteosarcoma arise from the inner germinative layer of [[periosteum]].<ref name="radio2">Osteosarcoma. Dr Henry Knipe◉ and Dr Sam Kyle et al.Radiopaedia.org 2015. http://radiopaedia.org/articles/periosteal-osteosarcoma</ref>
*The cytologic grade of this tumor is higher than parosteal osteosarcoma and lower than conventional osteosarcomas.
*Periosteal osteosarcoma is considered as intermediate grade osteosarcoma (grade 2).
*It predominantly contains chondroid matrix.
|-
| style="padding: 5px 5px; background: #DCDCDC;font-weight: bold" |
:Intracortical osteosarcoma
| style="padding: 5px 5px; background: #F5F5F5;" |
*Intracortical osteosarcoma is a low grade tumor of cortical bones and it typically does not extend into [[medullary canal]] and surrounding soft tissue until late stage of the disease.<ref name="radio2">Osteosarcoma. Dr Prashant Mudgal et al. Radiopaedia.org 2015. http://radiopaedia.org/articles/intracortical-osteosarcoma</ref>
*Histologically characterazied as a sclerosing variant of the osteosarcoma.
*Intracortical osteosarcoma contains [[osteoid]] matrix with few fibroblastic foci within and mild degree of cellular atypia.
|-
| style="padding: 5px 5px; background: #DCDCDC;font-weight: bold" |
:Parosteal osteosarcoma
| style="padding: 5px 5px; background: #F5F5F5;" |
*Parosteal osteosarcoma originates from the outer fibrous layer of [[periosteum]].<ref name="radio2">Osteosarcoma.Dr Frank Gaillard◉ et al.Radiopaedia.org 2015. http://radiopaedia.org/articles/parosteal-osteosarcoma-1</ref>
*They are composed of a dense osteoid component attached to the outer cortex over a narrow zone.
*It exhibits extensive bone matrix and minimal fibroblastic cellular atypia, and as such is considered to be a low grade tumor.
|-
| style="padding: 5px 5px; background: #DCDCDC;font-weight: bold" |
:Extraskeletal osteosarcoma
| style="padding: 5px 5px; background: #F5F5F5;" |
*Microscopically, it is typically a high grade [[spindle cell]] malignancy with [[osteoid]] and chondroid matrix.<ref name="radio2">Osteosarcoma.Dr Amir Rezaee◉ and Dr Prashant Mudgal et al. Radiopaedia.org 2015. http://radiopaedia.org/articles/extra-skeletal-osteosarcoma-1</ref>
*The histologic appearance of extraskeletal osteosarcoma resembles malignant [[fibrous histiocytoma]], osteoblastic osteosarcoma and chondroblastic osteosarcoma.
|-
|}


==Genetics==
=== CTGF ===
Hereditary syndromes of osteosarcoma include:<ref>Wang LL. Biology of osteogenic sarcoma.  Cancer J 11:294-305, 2005.</ref>
*''RECQL4'' gene mutations
*''[[RB1]]'' gene mutations (also implicated in [[retinoblastoma]])
*[[Li-Fraumeni syndrome]]
*[[Rothmund-Thomson Syndrome]]


These syndromes are extremely rare within the osteosarcoma diagnosis and probably represent less than 0.5% of those diagnosed.
*[[CTGF]] related to a number of proteins in the CCN family ([[CTGF]]/Cyr61/Cef10/NOVH).
<gallery perrow="3">
*[[CTGF]] act through the [[integrin]] signaling pathways.
Image:Osteosarcoma case 009.jpg|This high-power photomicrograph demonstrates the cellular growth pattern. Note that the cells are fusiform and they grow in sheets.<ref name=UAB Pathology education instructional resource> Osteosarcoma.peir.path.uab.edu/wiki.http://peir.path.uab.edu/wiki/IPLab:Lab_7:Osteosarcoma</ref>
*Like [[TGF beta|TGF-β]] which was mentioned before the [[CTGF]] has a diverse range of functions which includes the following:
Image:Osteosarcoma case 010.jpg|This high-power photomicrograph demonstrates the growth pattern and the cell morphology.<ref name=UAB Pathology education instructional resource> Osteosarcoma.peir.path.uab.edu/wiki.http://peir.path.uab.edu/wiki/IPLab:Lab_7:Osteosarcoma</ref>
**[[Adhesion]]
Image:Osteosarcoma case 011.jpg|This is a high-power photomicrograph of the tumor cell morphology and the periosteum (arrow).<ref name=UAB Pathology education instructional resource> Osteosarcoma.peir.path.uab.edu/wiki.http://peir.path.uab.edu/wiki/IPLab:Lab_7:Osteosarcoma</ref>
**Migration
Image:Osteosarcoma case 012.jpg|This high-power photomicrograph of the tumor demonstrates the fusiform morphology of the cells. Note the marked variability in size and staining intensity of the nuclei.<ref name=UAB Pathology education instructional resource> Osteosarcoma.peir.path.uab.edu/wiki.http://peir.path.uab.edu/wiki/IPLab:Lab_7:Osteosarcoma</ref>
**[[Proliferation]]
Image:Osteosarcoma case 013.jpg|This is a high-power photomicrograph of the tumor demonstrating the anaplastic cell morphology.<ref name=UAB Pathology education instructional resource> Osteosarcoma.peir.path.uab.edu/wiki.http://peir.path.uab.edu/wiki/IPLab:Lab_7:Osteosarcoma</ref>
**Survival
Image:Osteosarcoma case 014.jpg|This is a high-power photomicrograph of the tumor demonstrating the anaplastic cell morphology.<ref name=UAB Pathology education instructional resource> Osteosarcoma.peir.path.uab.edu/wiki.http://peir.path.uab.edu/wiki/IPLab:Lab_7:Osteosarcoma</ref>
**[[Angiogenesis]]
Image:Osteosarcoma case 015.jpg|This is a high-power photomicrograph of the tumor demonstrating the anaplastic cell morphology and multiple mitotic figures (arrows).<ref name=UAB Pathology education instructional resource> Osteosarcoma.peir.path.uab.edu/wiki.http://peir.path.uab.edu/wiki/IPLab:Lab_7:Osteosarcoma</ref>
**[[Differentiation]]
</gallery>
 
=== Parathyroid hormone (PTH) ===
 
* [[Parathyroid hormone]] ([[Parathyroid hormone|PTH]]), and its related peptide ([[Parathyroid hormone-related protein|PTHrP]]) and receptor (PTHR1) play important roles in the progression and [[metastasis]] of [[osteosarcoma]]. 
* [[Parathyroid hormone-related protein|PTHrP]] associated with tumor metastasis and [[hypercalcemia]]. 
* [[Parathyroid hormone-related protein|PTHrP]] leads to chemoresistance by downregulated expression of proapoptotic [[Bax (biochemistry)|Bax]] and PUMA and upregulated anti-[[Apoptosis|apoptotic]] [[Bcl-2]] and Bcl-xl and by blocking signaling via the p53, death-receptor and [[mitochondrial]] pathways of [[apoptosis]].
 
=== Chromosomal Abnormalities ===
 
* A various amount of [[chromosomal]] and [[Genetics|genetic]] syndromes are known to be linked to the [[osteosarcoma]] [[pathophysiology]].<ref name="pmid28494505">{{cite journal |vauthors=Smida J, Xu H, Zhang Y, Baumhoer D, Ribi S, Kovac M, von Luettichau I, Bielack S, O'Leary VB, Leib-Mösch C, Frishman D, Nathrath M |title=Genome-wide analysis of somatic copy number alterations and chromosomal breakages in osteosarcoma |journal=Int. J. Cancer |volume=141 |issue=4 |pages=816–828 |date=August 2017 |pmid=28494505 |doi=10.1002/ijc.30778 |url=}}</ref><ref name="pmid28489060">{{cite journal |vauthors=Liu G, Wang H, Zhang F, Tian Y, Tian Z, Cai Z, Lim D, Feng Z |title=The Effect of VPA on Increasing Radiosensitivity in Osteosarcoma Cells and Primary-Culture Cells from Chemical Carcinogen-Induced Breast Cancer in Rats |journal=Int J Mol Sci |volume=18 |issue=5 |pages= |date=May 2017 |pmid=28489060 |pmc=5454939 |doi=10.3390/ijms18051027 |url=}}</ref><ref name="pmid26626558">{{cite journal |vauthors=Bishop MW, Janeway KA, Gorlick R |title=Future directions in the treatment of osteosarcoma |journal=Curr. Opin. Pediatr. |volume=28 |issue=1 |pages=26–33 |date=February 2016 |pmid=26626558 |pmc=4761449 |doi=10.1097/MOP.0000000000000298 |url=}}</ref><ref name="pmid24631100">{{cite journal |vauthors=Regueiro García A, Saborido Fiaño R, González Calvete L, Vázquez Donsión M, Couselo Sánchez JM, Fernández Sanmartín M |title=[Osteosarcoma and ATR-16 syndrome: association or coincidence?] |language=Spanish; Castilian |journal=An Pediatr (Barc) |volume=82 |issue=1 |pages=e189–91 |date=January 2015 |pmid=24631100 |doi=10.1016/j.anpedi.2014.02.008 |url=}}</ref><ref name="pmid25551557">{{cite journal |vauthors=Both J, Krijgsman O, Bras J, Schaap GR, Baas F, Ylstra B, Hulsebos TJ |title=Focal chromosomal copy number aberrations identify CMTM8 and GPR177 as new candidate driver genes in osteosarcoma |journal=PLoS ONE |volume=9 |issue=12 |pages=e115835 |date=2014 |pmid=25551557 |pmc=4281204 |doi=10.1371/journal.pone.0115835 |url=}}</ref>
* Specific chromosomal abnormalities are known to be associated with [[osteosarcoma]] include: loss of [[chromosome 9]], [[chromosome 10]], [[chromosome 13]], and [[chromosome 17]] as well as gain of [[chromosome 1]].
* Meanwhile, a recent studies demonstrated that the [[Amplification|amplifications]] of [[Chromosome 6|chromosome 6p21]], chromosome 8q24, and chromosome 12q14, as well as [[loss of heterozygosity]] of 10q21.1, are the most common [[genomic]] alterations in [[osteosarcoma]]
* It should be noted that  patients carrying these [[alleles]] had a poorer [[prognosis]].
* Meanwhile, [[Osteosarcoma]] had been reported in patients with the below mentioned genetic disorders:
**[[Bloom syndrome]]: Characterised by [[genetic]] defects in the [[RecQ helicase|RecQ]] helicase family
**[[Rothmund-Thomson syndrome|Rothmund-Thompson syndrome]]: Characterised by genetic defects in the RecQ helicase family
**[[Werner syndrome]]: Characterised by genetic defects in the [[RecQ helicase|RecQ]] helicase family
**[[Li-Fraumeni syndrome]]
**[[Hereditary]] [[retinoblastoma]].
 
* [[DNA helicase|DNA-helicases]] are responsible for the [[Double-stranded DNA helix|double-stranded DNA]] prior to the [[replication]] separation process. [[Mutations]] in these [[genes]] increase higher risk of multiple [[malignancies]].
 
== Genetics ==
 
* Genes involved in the pathogenesis of [[Osteosarcoma|osteosarcomas]] include:
 
=== Transcription Factors  ===
 
* [[Transcription (genetics)|Transcription]] is the process of forming single-stranded messenger RNA ([[Messenger RNA|mRNA]]) sequences in cell from double-stranded [[DNA]]. <ref name="pmid28663539">{{cite journal |vauthors=Jiang Z, Zhang W, Chen Z, Shao J, Chen L, Wang Z |title=Transcription Factor 21 (TCF21) rs12190287 Polymorphism is Associated with Osteosarcoma Risk and Outcomes in East Chinese Population |journal=Med. Sci. Monit. |volume=23 |issue= |pages=3185–3191 |date=June 2017 |pmid=28663539 |pmc=5503230 |doi= |url=}}</ref><ref name="pmid28370690">{{cite journal |vauthors=Zhou Z, Li Y, Jia Q, Wang Z, Wang X, Hu J, Xiao J |title=Heat shock transcription factor 1 promotes the proliferation, migration and invasion of osteosarcoma cells |journal=Cell Prolif. |volume=50 |issue=4 |pages= |date=August 2017 |pmid=28370690 |doi=10.1111/cpr.12346 |url=}}</ref><ref name="pmid28260111">{{cite journal |vauthors=Heng L, Jia Z, Bai J, Zhang K, Zhu Y, Ma J, Zhang J, Duan H |title=Molecular characterization of metastatic osteosarcoma: Differentially expressed genes, transcription factors and microRNAs |journal=Mol Med Rep |volume=15 |issue=5 |pages=2829–2836 |date=May 2017 |pmid=28260111 |doi=10.3892/mmr.2017.6286 |url=}}</ref><ref name="pmid28810933">{{cite journal |vauthors=Ma C, Han J, Dong D, Wang N |title=MicroRNA-152 Suppresses Human Osteosarcoma Cell Proliferation and Invasion by Targeting E2F Transcription Factor 3 |journal=Oncol. Res. |volume=26 |issue=5 |pages=765–773 |date=June 2018 |pmid=28810933 |doi=10.3727/096504017X15021536183535 |url=}}</ref>
* [[Transcription (genetics)|Transcription]] factors simplify binding of promoter sequences for specific [[genes]] to initiate the process.
* The [[transcription]] is usually tightly regulated and the deregulation may leads to the [[malignancies]] like [[osteosarcoma]].
 
=== Activator protein 1 complex (AP-1) ===
 
* It is a regulator of [[Transcription (genetics)|transcription]] [[AP-1 (transcription factor)|AP-1]] is comprised of Fos (products of the [[C-Fos|c-fos]]) and Jun proteins ([[c-jun]] [[Proto oncogenes|proto-oncogenes]]).  
* [[AP-1 (transcription factor)|AP-1]] controls cell [[proliferation]], differentiation, and also bone [[metabolism]].
* Fos and Jun are found to be upregulated in high-grade [[Osteosarcoma|osteosarcomas]] than the low-grade and benign [[osteosarcoma]].
 
=== Myc ===
 
* It is a [[transcription factor]] that acts in the [[nucleus]] to stimulate both [[cell growth]] and division process.
* [[Myc]] [[amplification]] has been causes the occurrence and the resistance to [[Chemotherapeutic agent|chemotherapeutic]] in [[osteosarcoma]] [[pathogenesis]].
* Also, the down-regulation of [[Myc]] increased the [[therapeutic]] activity of [[methotrexate]] against the [[osteosarcoma]] cell.
 
=== Cell Adhesion and Migration ===
 
* [[Osteosarcoma]] is a highly [[metastatic]] tumor, and pulmonary [[metastases]] and known as the common cause of death. <ref name="pmid28965117">{{cite journal |vauthors=Lan H, Hong W, Fan P, Qian D, Zhu J, Bai B |title=Quercetin Inhibits Cell Migration and Invasion in Human Osteosarcoma Cells |journal=Cell. Physiol. Biochem. |volume=43 |issue=2 |pages=553–567 |date=2017 |pmid=28965117 |doi=10.1159/000480528 |url=}}</ref><ref name="pmid27331872">{{cite journal |vauthors=Tome Y, Kimura H, Kiyuna T, Sugimoto N, Tsuchiya H, Kanaya F, Bouvet M, Hoffman RM |title=Disintegrin targeting of an αvβ3 integrin-over-expressing high-metastatic human osteosarcoma with echistatin inhibits cell proliferation, migration, invasion and adhesion in vitro |journal=Oncotarget |volume=7 |issue=29 |pages=46315–46320 |date=July 2016 |pmid=27331872 |pmc=5216800 |doi=10.18632/oncotarget.10111 |url=}}</ref><ref name="pmid25339127">{{cite journal |vauthors=Park GB, Kim DJ, Kim YS, Lee HK, Kim CW, Hur DY |title=Silencing of galectin-3 represses osteosarcoma cell migration and invasion through inhibition of FAK/Src/Lyn activation and β-catenin expression and increases susceptibility to chemotherapeutic agents |journal=Int. J. Oncol. |volume=46 |issue=1 |pages=185–94 |date=January 2015 |pmid=25339127 |doi=10.3892/ijo.2014.2721 |url=}}</ref><ref name="pmid28323887">{{cite journal |vauthors=Diao F, Chen K, Wang Y, Li Y, Xu W, Lu J, Chen YX |title=Involvement of small G protein RhoB in the regulation of proliferation, adhesion and migration by dexamethasone in osteoblastic cells |journal=PLoS ONE |volume=12 |issue=3 |pages=e0174273 |date=2017 |pmid=28323887 |pmc=5360316 |doi=10.1371/journal.pone.0174273 |url=}}</ref>
* The [[metastatic]] sequence involves the detachment of [[osteosarcoma]] cells from the primary [[tumor]], [[adhesion]] to the extracellular [[matrix]], local migration and [[invasion]] through stromal tissue, [[intravasation]], and [[extravasation]].  
* The ability of [[osteosarcoma]] cells to metastasise by such a pathway completely depended on the complex cell-cell and cell-[[matrix]] interactions.
 
=== Osteoclast Function ===
 
* [[Osteosarcoma]] [[invasion]] of bone relies on interactions between the bone [[matrix]], [[osteosarcoma]] cells, [[osteoblasts]], and [[osteoclasts]].<ref name="pmid28263668">{{cite journal |vauthors=Kelleher FC, O'Sullivan H |title=Monocytes, Macrophages, and Osteoclasts in Osteosarcoma |journal=J Adolesc Young Adult Oncol |volume=6 |issue=3 |pages=396–405 |date=September 2017 |pmid=28263668 |doi=10.1089/jayao.2016.0078 |url=}}</ref><ref name="pmid21204734">{{cite journal |vauthors=Broadhead ML, Clark JC, Dass CR, Choong PF, Myers DE |title=Therapeutic targeting of osteoclast function and pathways |journal=Expert Opin. Ther. Targets |volume=15 |issue=2 |pages=169–81 |date=February 2011 |pmid=21204734 |doi=10.1517/14728222.2011.546351 |url=}}</ref><ref name="pmid22846337">{{cite journal |vauthors=Endo-Munoz L, Evdokiou A, Saunders NA |title=The role of osteoclasts and tumour-associated macrophages in osteosarcoma metastasis |journal=Biochim. Biophys. Acta |volume=1826 |issue=2 |pages=434–42 |date=December 2012 |pmid=22846337 |doi=10.1016/j.bbcan.2012.07.003 |url=}}</ref><ref name="pmid20823153">{{cite journal |vauthors=Endo-Munoz L, Cumming A, Rickwood D, Wilson D, Cueva C, Ng C, Strutton G, Cassady AI, Evdokiou A, Sommerville S, Dickinson I, Guminski A, Saunders NA |title=Loss of osteoclasts contributes to development of osteosarcoma pulmonary metastases |journal=Cancer Res. |volume=70 |issue=18 |pages=7063–72 |date=September 2010 |pmid=20823153 |doi=10.1158/0008-5472.CAN-09-4291 |url=}}</ref>
* In response to the [[hypoxic]] and [[Acidosis|acidotic]] conditions the osteosarcoma cells release molecules such as: [[Endothelin-1|endothelin]]-1 (ET-1), [[VEGF]] and [[PDGF]].
* [[Endothelin-1]] (ET-1), [[Vascular endothelial growth factor|VEGF]], and [[Platelet-derived growth factor|PDGF]] factors have predominantly osteoblast-stimulatory functions.  
* The [[Parathyroid hormone-related protein|PTHrP]] as an important [[Granuloma faciale|GF]] and the [[Interleukin 11|IL-11]] also act on [[osteoblasts]] enhancing the expression of receptor activator of nuclear factor κB ligand ([[RANKL]]).
* [[RANKL]] is a key mediator of osteoclast differentiation and activity. The activated osteoclasts release proteases to resorb the non mineralised components of bone.
*Consequently, the [[osteoclast]] pathways (differentiation, maturation, and activation) have potential as therapeutic effect.
*For example: Inhibition of bone [[resorption]] at the tumor-bone interface reduces the [[osteosarcoma]] local invasion.
 
=== Bone Growth and Tumorigenesis ===
 
* Previous studies have revealed a positive significant correlation between the [[osteosarcoma]] development and the rapid bone growth occurs during [[puberty]].<ref name="pmid27697093">{{cite journal |vauthors=Jiang F, Zhang D, Li G, Wang X |title=Knockdown of DDX46 Inhibits the Invasion and Tumorigenesis in Osteosarcoma Cells |journal=Oncol. Res. |volume=25 |issue=3 |pages=417–425 |date=March 2017 |pmid=27697093 |doi=10.3727/096504016X14747253292210 |url=}}</ref><ref name="pmid29229388">{{cite journal |vauthors=Zhou S, Yu L, Xiong M, Dai G |title=LncRNA SNHG12 promotes tumorigenesis and metastasis in osteosarcoma by upregulating Notch2 by sponging miR-195-5p |journal=Biochem. Biophys. Res. Commun. |volume=495 |issue=2 |pages=1822–1832 |date=January 2018 |pmid=29229388 |doi=10.1016/j.bbrc.2017.12.047 |url=}}</ref><ref name="pmid27983923">{{cite journal |vauthors=Yang L, Xie F, Li S |title=Downregulation of Homeobox B7 Inhibits the Tumorigenesis and Progression of Osteosarcoma |journal=Oncol. Res. |volume=25 |issue=7 |pages=1089–1095 |date=August 2017 |pmid=27983923 |doi=10.3727/096504016X14784668796788 |url=}}</ref><ref name="pmid28849077">{{cite journal |vauthors=Wang H, Xing D, Ren D, Feng W, Chen Y, Zhao Z, Xiao Z, Peng Z |title=MicroRNA‑643 regulates the expression of ZEB1 and inhibits tumorigenesis in osteosarcoma |journal=Mol Med Rep |volume=16 |issue=4 |pages=5157–5164 |date=October 2017 |pmid=28849077 |pmc=5647050 |doi=10.3892/mmr.2017.7273 |url=}}</ref><ref name="pmid28264040">{{cite journal |vauthors=Gill J, Connolly P, Roth M, Chung SH, Zhang W, Piperdi S, Hoang B, Yang R, Guzik H, Morris J, Gorlick R, Geller DS |title=The effect of bone morphogenetic protein-2 on osteosarcoma metastasis |journal=PLoS ONE |volume=12 |issue=3 |pages=e0173322 |date=2017 |pmid=28264040 |doi=10.1371/journal.pone.0173322 |url=}}</ref><ref name="pmid27894960">{{cite journal |vauthors=Brown HK, Tellez-Gabriel M, Heymann D |title=Cancer stem cells in osteosarcoma |journal=Cancer Lett. |volume=386 |issue= |pages=189–195 |date=February 2017 |pmid=27894960 |doi=10.1016/j.canlet.2016.11.019 |url=}}</ref><ref name="pmid28106543">{{cite journal |vauthors=Zhang XH, Zhang Y, Xie WP, Sun DS, Zhang YK, Hao YK, Tan GQ |title=Expression and significance of calreticulin in human osteosarcoma |journal=Cancer Biomark |volume=18 |issue=4 |pages=405–411 |date=2017 |pmid=28106543 |doi=10.3233/CBM-160266 |url=}}</ref><ref name="pmid28774797">{{cite journal |vauthors=Cortini M, Avnet S, Baldini N |title=Mesenchymal stroma: Role in osteosarcoma progression |journal=Cancer Lett. |volume=405 |issue= |pages=90–99 |date=October 2017 |pmid=28774797 |doi=10.1016/j.canlet.2017.07.024 |url=}}</ref><ref name="pmid28837148">{{cite journal |vauthors=Liu K, Ren T, Huang Y, Sun K, Bao X, Wang S, Zheng B, Guo W |title=Apatinib promotes autophagy and apoptosis through VEGFR2/STAT3/BCL-2 signaling in osteosarcoma |journal=Cell Death Dis |volume=8 |issue=8 |pages=e3015 |date=August 2017 |pmid=28837148 |pmc=5596600 |doi=10.1038/cddis.2017.422 |url=}}</ref><ref name="pmid28496199">{{cite journal |vauthors=Jiang ZH, Peng J, Yang HL, Fu XL, Wang JZ, Liu L, Jiang JN, Tan YF, Ge ZJ |title=Upregulation and biological function of transmembrane protein 119 in osteosarcoma |journal=Exp. Mol. Med. |volume=49 |issue=5 |pages=e329 |date=May 2017 |pmid=28496199 |pmc=5454443 |doi=10.1038/emm.2017.41 |url=}}</ref><ref name="pmid25929293">{{cite journal |vauthors=Wycislo KL, Fan TM |title=The immunotherapy of canine osteosarcoma: a historical and systematic review |journal=J. Vet. Intern. Med. |volume=29 |issue=3 |pages=759–69 |date=2015 |pmid=25929293 |pmc=4895426 |doi=10.1111/jvim.12603 |url=}}</ref>
* Accordingly the peak age of osteosarcoma development is slightly earlier for female population.
* And patients affected by the disease are taller compared to the normal population of the same age group.
* Also, the [[epiphyseal]] growth plates of the distal [[femur]] and proximal [[tibia]] are known to be responsible for the increase in height that occurs during puberty.
* Meanwhile, the [[Paget’s disease|Paget’s]] disease which is a disorder characterized by both excessive bone formation and breakdown leads to a higher incidence of [[osteosarcoma]] among the affected individuals.
 
* Environmental factors known as [[carcinogens]] for [[osteosarcoma]] include:
 
# Physical agents
#[[Chemical]] agents
#[[Biological agents]]
 
==== Physical agents ====
 
* Meanwhile, the [[ionising radiation]], implicated in only 2% of cases of [[osteosarcoma]], has the best established roll in this regard.
*Meanwhile, the [[radiotherapy]] treatment in children develop a secondary [[neoplasm]], and of these are sarcomas in  5.4% and  25% of cases, respectively.
 
==== Chemical agents ====
 
* The chemical agents responsible for the [[osteosarcoma]] formation include:
** [[Methylcholanthrene]]
** [[Chromium]] salts
**[[Beryllium oxide]]
**[[Zinc]] [[beryllium]] silicate
**[[Asbestos]]
**[[Aniline]] dyes
 
==== Biological agents ====
 
* Recent investigations suggested a viral origin for [[osteosarcoma]] which later got some controversies in this regard.
*It was stemmed from the detection of [[Simian virus 40|simian virus]] 40 ([[SV40]]) in [[osteosarcoma]] cells but later it was proposed that may in fact be due to laboratory contamination by [[plasmids]] containing [[SV40]] sequences.
 
=== Tumor Suppressor Gene Dysfunction ===
 
* Any type of exposure to previously-mentioned environmental insults causes a significant damages on the somatic [[DNA]].<ref name="pmid28882648">{{cite journal |vauthors=Liu K, Sun X, Zhang Y, Liu L, Yuan Q |title=MiR-598: A tumor suppressor with biomarker significance in osteosarcoma |journal=Life Sci. |volume=188 |issue= |pages=141–148 |date=November 2017 |pmid=28882648 |doi=10.1016/j.lfs.2017.09.003 |url=}}</ref><ref name="pmid25595191">{{cite journal |vauthors=Lo JY, Chou YT, Lai FJ, Hsu LJ |title=Regulation of cell signaling and apoptosis by tumor suppressor WWOX |journal=Exp. Biol. Med. (Maywood) |volume=240 |issue=3 |pages=383–91 |date=March 2015 |pmid=25595191 |pmc=4935227 |doi=10.1177/1535370214566747 |url=}}</ref><ref name="pmid28775781">{{cite journal |vauthors=Zhang W, Duan N, Song T, Li Z, Zhang C, Chen X |title=The Emerging Roles of Forkhead Box (FOX) Proteins in Osteosarcoma |journal=J Cancer |volume=8 |issue=9 |pages=1619–1628 |date=2017 |pmid=28775781 |pmc=5535717 |doi=10.7150/jca.18778 |url=}}</ref>
* Due to the tumor-suppressor mechanisms this [[DNA damage]] necessarily may not lead to [[malignant]] cell line process.
* These [[Tumor suppressor gene|tumor-suppressor]] mechanisms include:
 
=== Repair the DNA damage <ref name="pmid27989676">{{cite journal |vauthors=Irianto J, Xia Y, Pfeifer CR, Athirasala A, Ji J, Alvey C, Tewari M, Bennett RR, Harding SM, Liu AJ, Greenberg RA, Discher DE |title=DNA Damage Follows Repair Factor Depletion and Portends Genome Variation in Cancer Cells after Pore Migration |journal=Curr. Biol. |volume=27 |issue=2 |pages=210–223 |date=January 2017 |pmid=27989676 |pmc=5262636 |doi=10.1016/j.cub.2016.11.049 |url=}}</ref><ref name="pmid26108997">{{cite journal |vauthors=Li X, Tian J, Bo Q, Li K, Wang H, Liu T, Li J |title=Targeting DNA-PKcs increased anticancer drug sensitivity by suppressing DNA damage repair in osteosarcoma cell line MG63 |journal=Tumour Biol. |volume=36 |issue=12 |pages=9365–72 |date=December 2015 |pmid=26108997 |doi=10.1007/s13277-015-3642-5 |url=}}</ref><ref name="pmid25862479">{{cite journal |vauthors=Wojewoda M, Walczak J, Duszyński J, Szczepanowska J |title=Selenite activates the ATM kinase-dependent DNA repair pathway in human osteosarcoma cells with mitochondrial dysfunction |journal=Biochem. Pharmacol. |volume=95 |issue=3 |pages=170–6 |date=June 2015 |pmid=25862479 |doi=10.1016/j.bcp.2015.03.016 |url=}}</ref><ref name="pmid29317520">{{cite journal |vauthors=Lee JH, Mand MR, Kao CH, Zhou Y, Ryu SW, Richards AL, Coon JJ, Paull TT |title=ATM directs DNA damage responses and proteostasis via genetically separable pathways |journal=Sci Signal |volume=11 |issue=512 |pages= |date=January 2018 |pmid=29317520 |pmc=5898228 |doi=10.1126/scisignal.aan5598 |url=}}</ref><ref name="pmid28489060">{{cite journal |vauthors=Liu G, Wang H, Zhang F, Tian Y, Tian Z, Cai Z, Lim D, Feng Z |title=The Effect of VPA on Increasing Radiosensitivity in Osteosarcoma Cells and Primary-Culture Cells from Chemical Carcinogen-Induced Breast Cancer in Rats |journal=Int J Mol Sci |volume=18 |issue=5 |pages= |date=May 2017 |pmid=28489060 |pmc=5454939 |doi=10.3390/ijms18051027 |url=}}</ref><ref name="pmid24390088">{{cite journal |vauthors=Tang X, Yuan F, Guo K |title=Repair of radiation damage of U2OS osteosarcoma cells is related to DNA-dependent protein kinase catalytic subunit (DNA-PKcs) activity |journal=Mol. Cell. Biochem. |volume=390 |issue=1-2 |pages=51–9 |date=May 2014 |pmid=24390088 |doi=10.1007/s11010-013-1955-5 |url=}}</ref><ref name="pmid21036739">{{cite journal |vauthors=Chen HY, Lu HF, Yang JS, Kuo SC, Lo C, Yang MD, Chiu TH, Chueh FS, Ho HC, Ko YC, Chung JG |title=The novel quinolone CHM-1 induces DNA damage and inhibits DNA repair gene expressions in a human osterogenic sarcoma cell line |journal=Anticancer Res. |volume=30 |issue=10 |pages=4187–92 |date=October 2010 |pmid=21036739 |doi= |url=}}</ref>===
 
==== Apoptosis ====
 
* The [[p53]] and [[retinoblastoma]] ([[Rb]]) [[genes]] are the well-known tumor-suppressor genes in cellular system.
* However, sometimes these [[tumor suppressor genes]] may themselves become mutated causing the loss of their protective function effects.
* It's been reported that the mutations in both the p53 and Rb genes have been proven to be involved in [[osteosarcoma]] pathogenesis.
 
''[[DNA damage]] → phosphorylate [[p53]] → dissociation from [[Mdm2]]''
 
===== P53 : =====
 
* The [[p53]] gene mutation found in 50% and 22% all cancers and osteosarcomas respectively. 
* The expression of [[p53]] positively reduced [[metastatic]] disease and improved survival for these patients. 
* It is unclear whether [[p53]] [[mutation]] or loss may affect [[tumor]] behavior. But, using the [[p53]]-null SaOS-2 [[osteosarcoma]] cell line showed that the adenoviral-mediated gene transfer of wild-type [[p53]] reduced the cell viability and also increased the [[sensitivity]] to [[Chemotherapy|chemotherapeutic]] agents in affected cells. 
* For example: [[Li-Fraumeni syndrome]] is characterized by an [[autosomal dominant]] mutation of [[p53]] leading to the development of multiple cancers such as [[osteosarcoma]].  
 
===== Retinoblastoma =====
 
* The [[Rb|Rb gene]] is critical to cell-cycle control, inherited [[mutation]] of the [[Rb]] gene lead to the [[retinoblastoma]] syndrome which predisposes a patient to multiple [[malignancies]] such as [[osteosarcoma]].
* The [[Rb]] protein controls the cell cycle by binding the [[transcription factor]] [[E2F]]. [[E2F]] usually is held inactive by [[Rb]] until the [[Cyclin-dependent kinase 4|CDK4]]/[[cyclin D]] complex [[phosphorylates]] Rb.
* [[Mutation|Mutations]] of Rb allow for the continuous cycling of cells thus leads to the [[osteosarcoma]] occurance.
* It should be noted that both [[germline]] and [[somatic]] mutations of [[Rb]] increases the risk of [[osteosarcoma]].
 
=== Tumor Angiogenesis ===
 
* [[Tumor|Tumour]] [[angiogenesis]] is essential for sustained [[osteosarcoma]] growth and [[metastasis]].<ref name="pmid27028305">{{cite journal |vauthors=Hu F, Shang XF, Wang W, Jiang W, Fang C, Tan D, Zhou HC |title=High-level expression of periostin is significantly correlated with tumour angiogenesis and poor prognosis in osteosarcoma |journal=Int J Exp Pathol |volume=97 |issue=1 |pages=86–92 |date=February 2016 |pmid=27028305 |pmc=4840243 |doi=10.1111/iep.12171 |url=}}</ref><ref name="pmid25471534">{{cite journal |vauthors=Ségaliny AI, Mohamadi A, Dizier B, Lokajczyk A, Brion R, Lanel R, Amiaud J, Charrier C, Boisson-Vidal C, Heymann D |title=Interleukin-34 promotes tumor progression and metastatic process in osteosarcoma through induction of angiogenesis and macrophage recruitment |journal=Int. J. Cancer |volume=137 |issue=1 |pages=73–85 |date=July 2015 |pmid=25471534 |doi=10.1002/ijc.29376 |url=}}</ref><ref name="pmid28656259">{{cite journal |vauthors=Xie L, Ji T, Guo W |title=Anti-angiogenesis target therapy for advanced osteosarcoma (Review) |journal=Oncol. Rep. |volume=38 |issue=2 |pages=625–636 |date=August 2017 |pmid=28656259 |pmc=5562076 |doi=10.3892/or.2017.5735 |url=}}</ref><ref name="pmid29330051">{{cite journal |vauthors=Li X, Lu Q, Xie W, Wang Y, Wang G |title=Anti-tumor effects of triptolide on angiogenesis and cell apoptosis in osteosarcoma cells by inducing autophagy via repressing Wnt/β-Catenin signaling |journal=Biochem. Biophys. Res. Commun. |volume=496 |issue=2 |pages=443–449 |date=February 2018 |pmid=29330051 |doi=10.1016/j.bbrc.2018.01.052 |url=}}</ref>
* The most common sites for [[osteosarcoma]] spread include: [[Metastasis]] to the lungs and bone also relies on the formation and maintenance of blood vessels.  
* A [[hypoxic]] and [[Acidosis|acidotic]] microenvironment exists at the proliferated [[osteosarcoma]] area.
* While the [[osteosarcoma]] is a relatively vascular tumor, [[angiogenesis]] is regulated by the balance between pro-angiogenic and [[antiangiogenic]] factors.
* [[Antiangiogenic]] proteins such as [[thrombospondin]] 1, [[TGF beta|TGF]]-β, [[troponin]] I, pigment epithelial-derived factor ([[PEDF]]), and reversion-inducing cysteine rich protein with Kazal motifs ([[RECK]]) are downregulated in [[osteosarcoma]].
 
=== Tumor Invasion ===
 
* [[Invasive (medical)|Invasion]] of the surrounding tissues by [[osteosarcoma]] also involves degradation of the extracellular [[matrix]] using the [[Matrix metalloproteinases|Matrix metalloproteinases (]]MMPs).<ref name="pmid28965117" /><ref name="pmid29225166">{{cite journal |vauthors=Zheng B, Ren T, Huang Y, Guo W |title=Apatinib inhibits migration and invasion as well as PD-L1 expression in osteosarcoma by targeting STAT3 |journal=Biochem. Biophys. Res. Commun. |volume=495 |issue=2 |pages=1695–1701 |date=January 2018 |pmid=29225166 |doi=10.1016/j.bbrc.2017.12.032 |url=}}</ref><ref name="pmid28604772">{{cite journal |vauthors=Wu X, Yan L, Liu Y, Xian W, Wang L, Ding X |title=MicroRNA-448 suppresses osteosarcoma cell proliferation and invasion through targeting EPHA7 |journal=PLoS ONE |volume=12 |issue=6 |pages=e0175553 |date=2017 |pmid=28604772 |pmc=5467824 |doi=10.1371/journal.pone.0175553 |url=}}</ref><ref name="pmid28370690" />
 
* [[Matrix metalloproteinase|MMPs]] are a family of zinc-dependent [[endopeptidases]] that are involved in a range of physiological processes including inflammation, wound healing, [[embryogenesis]], and fracture healing.
* In normal healthy tissues, [[Matrix metalloproteinase|MMPs]] are regulated by natural inhibitors such as tissue inhibitors of [[Matrix metalloproteinase|MMPs]] ([[TIMP1|TIMPs]]), [[RECK]], and α2 [[macroglobulin]]. but in the [[malignancies]] such as osteosarcoma, the [[Matrix metalloproteinase|MMPs]] break down extracellular [[Collagen|collagens]], facilitating both tumor and [[endothelial cell]] [[Invasive (medical)|invasion]].
* The [[urokinase]] [[plasminogen]] activator ([[UPARAP|uPA]]) system an other [[osteosarcoma]] invasion regulator interacting with [[Matrix metalloproteinase|MMPs]].
* Accordingly, the downregulation of [[UPARAP|uPAR]] in an in vivo [[osteosarcoma]] model resulted in reduced primary [[tumor]] growth and fewer [[Metastasis|metastases]].
 
=== Osteosarcoma Cell Proliferation, Apoptosis, and Anchorage-Independent Growth ===
 
* [[Malignant]] cells such as [[osteosarcoma]] cells are mostly resistant to [[apoptosis]].<ref name="pmid23228048">{{cite journal |vauthors=Helmerick EC, Loftus JP, Wakshlag JJ |title=The effects of baicalein on canine osteosarcoma cell proliferation and death |journal=Vet Comp Oncol |volume=12 |issue=4 |pages=299–309 |date=December 2014 |pmid=23228048 |doi=10.1111/vco.12013 |url=}}</ref><ref name="pmid21034328">{{cite journal |vauthors=Wakshlag JJ, Balkman CE |title=Effects of lycopene on proliferation and death of canine osteosarcoma cells |journal=Am. J. Vet. Res. |volume=71 |issue=11 |pages=1362–70 |date=November 2010 |pmid=21034328 |doi=10.2460/ajvr.71.11.1362 |url=}}</ref><ref name="pmid20383567">{{cite journal |vauthors=Akiyama T, Choong PF, Dass CR |title=RANK-Fc inhibits malignancy via inhibiting ERK activation and evoking caspase-3-mediated anoikis in human osteosarcoma cells |journal=Clin. Exp. Metastasis |volume=27 |issue=4 |pages=207–15 |date=April 2010 |pmid=20383567 |doi=10.1007/s10585-010-9319-y |url=}}</ref><ref name="pmid25889105">{{cite journal |vauthors=Foley JM, Scholten DJ, Monks NR, Cherba D, Monsma DJ, Davidson P, Dylewski D, Dykema K, Winn ME, Steensma MR |title=Anoikis-resistant subpopulations of human osteosarcoma display significant chemoresistance and are sensitive to targeted epigenetic therapies predicted by expression profiling |journal=J Transl Med |volume=13 |issue= |pages=110 |date=April 2015 |pmid=25889105 |pmc=4419490 |doi=10.1186/s12967-015-0466-4 |url=}}</ref>
* [[Apoptosis]] consists of initiation phase and execution phase. Both intrinsic and extrinsic pathways regulate the initiation phase.
* The intrinsic pathway relies on increased [[mitochondrial]] permeability while extrinsic pathway is known as a death receptor-initiated pathway.
* [[Osteosarcoma]] cells are resistant to [[anoikis]] and [[proliferate]] despite deranged cell-cell and cell-[[matrix]] attachments.
* This resistance to [[anoikis]] called anchorage-independent growth ([[AIG1|AIG]]).


==References==
==References==

Latest revision as of 17:33, 14 October 2019


Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Mohammadmain Rezazadehsaatlou[2].

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Overview

The main cause of osteosarcoma is not well-known, yet. However, a number of risk factors have been identified in this regard. Osteosarcoma can involve any bone but it usually affects the extremities of long bones near metaphyseal growth plates. The most common sites include

  • Femur 42% of cases ( the distal femur had around 75% of involvement).
  • Tibia 19% of cases ( the proximal tibia had around 80% of involvement).
  • Humerus 10% of cases ( the proximal humerus had around 90% of involvement).
  • Skull and jaw 8% of cases.
  • Pelvis 8% of cases.

Pathophysiology

Growth Factors

TGF-β

IGF

  • IGF-I and IGF-II are growth factors usually overexpressed by osteosarcomas.
  • IGF families bind corresponding receptors such as IGF-1R, causing the activation of the PI3K and MAPK transduction pathways.
  • Consequently they supports the cell proliferation and inhibition of apoptosis. Meanwhile, the Lentivirus-mediated snRNA targeting IGF-R1 increases the chemosensitivity and the anti-tumor response of osteosarcoma cells to docetaxel and cisplatin.

CTGF

Parathyroid hormone (PTH)

Chromosomal Abnormalities

Genetics

Transcription Factors

Activator protein 1 complex (AP-1)

Myc

Cell Adhesion and Migration

Osteoclast Function

Bone Growth and Tumorigenesis

  • Previous studies have revealed a positive significant correlation between the osteosarcoma development and the rapid bone growth occurs during puberty.[28][29][30][31][32][33][34][35][36][37][38]
  • Accordingly the peak age of osteosarcoma development is slightly earlier for female population.
  • And patients affected by the disease are taller compared to the normal population of the same age group.
  • Also, the epiphyseal growth plates of the distal femur and proximal tibia are known to be responsible for the increase in height that occurs during puberty.
  • Meanwhile, the Paget’s disease which is a disorder characterized by both excessive bone formation and breakdown leads to a higher incidence of osteosarcoma among the affected individuals.
  1. Physical agents
  2. Chemical agents
  3. Biological agents

Physical agents

  • Meanwhile, the ionising radiation, implicated in only 2% of cases of osteosarcoma, has the best established roll in this regard.
  • Meanwhile, the radiotherapy treatment in children develop a secondary neoplasm, and of these are sarcomas in 5.4% and 25% of cases, respectively.

Chemical agents

Biological agents

  • Recent investigations suggested a viral origin for osteosarcoma which later got some controversies in this regard.
  • It was stemmed from the detection of simian virus 40 (SV40) in osteosarcoma cells but later it was proposed that may in fact be due to laboratory contamination by plasmids containing SV40 sequences.

Tumor Suppressor Gene Dysfunction

  • Any type of exposure to previously-mentioned environmental insults causes a significant damages on the somatic DNA.[39][40][41]
  • Due to the tumor-suppressor mechanisms this DNA damage necessarily may not lead to malignant cell line process.
  • These tumor-suppressor mechanisms include:

Repair the DNA damage [42][43][44][45][12][46][47]

Apoptosis

  • The p53 and retinoblastoma (Rb) genes are the well-known tumor-suppressor genes in cellular system.
  • However, sometimes these tumor suppressor genes may themselves become mutated causing the loss of their protective function effects.
  • It's been reported that the mutations in both the p53 and Rb genes have been proven to be involved in osteosarcoma pathogenesis.

DNA damage → phosphorylate p53 → dissociation from Mdm2

P53 :
Retinoblastoma

Tumor Angiogenesis

Tumor Invasion

Osteosarcoma Cell Proliferation, Apoptosis, and Anchorage-Independent Growth

References

  1. Kim HJ, Chalmers PN, Morris CD (February 2010). "Pediatric osteogenic sarcoma". Curr. Opin. Pediatr. 22 (1): 61–6. doi:10.1097/MOP.0b013e328334581f. PMID 19915470.
  2. Moore DD, Luu HH (2014). "Osteosarcoma". Cancer Treat. Res. 162: 65–92. doi:10.1007/978-3-319-07323-1_4. PMID 25070231.
  3. Ilaslan H, Schils J, Nageotte W, Lietman SA, Sundaram M (March 2010). "Clinical presentation and imaging of bone and soft-tissue sarcomas". Cleve Clin J Med. 77 Suppl 1: S2–7. doi:10.3949/ccjm.77.s1.01. PMID 20179183.
  4. Wu PK, Chen WM, Lee OK, Chen CF, Huang CK, Chen TH (November 2010). "The prognosis for patients with osteosarcoma who have received prior manipulative therapy". J Bone Joint Surg Br. 92 (11): 1580–5. doi:10.1302/0301-620X.92B11.24706. PMID 21037356.
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