Organotypic three-dimensional assays based on human leiomyoma-derived matrices

Alongside cancer cells, tumours exhibit a complex stroma containing a repertoire of cells, matrix molecules and soluble factors that actively crosstalk between each other. Recognition of this multifaceted concept of the tumour microenvironment (TME) calls for authentic TME mimetics to study cancer in vitro. Traditionally, tumourigenesis has been investigated in non-human, three-dimensional rat type I collagen containing organotypic discs or by means of mouse sarcoma-derived gel, such as Matrigel (R). However, the molecular compositions of these simplified assays do not properly simulate human TME. Here, we review the main properties and benefits of using human leiomyoma discs and their matrix Myogel for in vitro assays. Myoma discs are practical for investigating the invasion of cancer cells, as are cocultures of cancer and stromal cells in a stiff, hypoxic TME mimetic. Myoma discs contain soluble factors and matrix molecules commonly present in neoplastic stroma. In Transwell, IncuCyte, spheroid and sandwich assays, cancer cells move faster and form larger colonies in Myogel than in Matrigel (R). Additionally, Myogel can replace Matrigel (R) in hanging-drop and tube-formation assays. Myogel also suits three-dimensional drug testing and extracellular vesicle interactions. To conclude, we describe the application of our myoma-derived matrices in 3D in vitro cancer assays. This article is part of the discussion meeting issue 'Extracellular vesicles and the tumour microenvironment'.Peer reviewe

Matrix metalloproteinase 9 inhibits the motility of highly aggressive HSC-3 oral squamous cell carcinoma cells

Pro-tumorigenic activities of matrix metalloproteinase (MMP) 9 have been linked to many cancers, but recently the tumour-suppressing role of MMP9 has also been elucidated. The multifaceted evidence on this subject prompted us to examine the role of MMP9 in the behaviour of oral tongue squamous cell carcinoma (OTSCC) cells. We used gelatinase-specific inhibitor, CTT2, and short hairpin (sh) RNA gene silencing to study the effects of MMP9 on proliferation, motility and invasion of an aggressive OTSCC cell line, HSC-3. We found that the migration and invasion of HSC-3 cells were increased by CTT2 and shRNA silencing of MMP9. Proliferation, in turn, was decreased by MMP9 inhibition. Furthermore, arresten-overexpressing HSC-3 cells expressed increased levels of MMP9, but exhibited decreased motility compared with controls. Interestingly, these cells restored their migratory capabilities by CTT2 inhibition of MMP9. Hence, although higher MMP9 expression could give rise to an increased tumour growth in vivo due to increased proliferation, in some circumstances, it may participate in yet unidentified molecular mechanisms that reduce the cell movement in OTSCC.Peer reviewe

Arresten, a Collagen-Derived Angiogenesis Inhibitor, Suppresses Invasion of Squamous Cell Carcinoma

Peer reviewe

The microenvironment is essential for OTSCC progression

Abstract The tumor microenvironment (TME) is critically important for tumor development. The microenvironment consists of fibroblasts, endothelial and immune cells as well as extracellular matrix (ECM), proteases and various other soluble factors produced by the cells. It is challenging to develop methods that appropriately mimic the human microenvironment, but this effort is essential in order to reliably elucidate the properties of potential anti-tumor drugs. The aim of this study was to create new 3D organotypic invasion models based on human tissue that would be used to study the effects of the anti-angiogenic molecules arresten and endostatin on tongue squamous carcinoma cells. The classic way to study cancer invasion has been to use a collagen invasion model that is created by mixing rat type I collagen, matrix produced by mouse EHS tumor cells and human fibroblasts. Our research group has developed a novel human myoma tissue based invasion model, which is composed of several different cell types and molecules that are normally present in the human TME. We show how this model is suitable for invasion studies, not only for oral cancer, but for other invasive cell lines as well. There are several matrix-derived fragments that have been shown to possess anti-angiogenic activity. Arresten is a 26 kDa fragment that is cleaved from type IV collagen and is known to inhibit angiogenesis, the formation of new capillaries and tumor growth in vivo. However, its effect on the tumor microenvironment in addition to endothelial cells has not been studied. We show that arresten also directly affects oral cancer cells by decreasing their migration and invasion as well as tumor size, invasion and angiogenesis in in vivo mouse xenografts. Another inhibitor of angiogenesis, endostatin, is cleaved from type XVIII collagen. It has been shown to suppress angiogenesis and tumor growth without toxicity or side effects in mouse models. Our studies show that endostatin directly affects tongue squamous carcinoma cells by reducing their invasion and spreading in organotypic 3D assays and mouse tumor models. In summary, arresten and endostatin are anti-angiogenic as well as anti-invasive molecules and therefore potential cancer drugs. They seem to have a direct effect on carcinoma cells making the cells less invasive. The myoma model allows us to study the effects of anti-cancer molecules with a new prospective.Tiivistelmä Syövän mikroympäristö on erittäin tärkeä syövän kehittymisen kannalta. Se koostuu fibroblasteista, endoteeli- ja immuunisoluista, soluväliaineesta, proteaaseista ja monista muista solujen tuottamista liukoisista molekyyleistä. On haastavaa kehittää uusia menetelmiä, jotka jäljittelisivät oikeaa ihmisen syövän mikroympäristöä, mutta se on välttämätöntä uusien syöpälääkkeiden tutkimiseksi. Väitöstutkimuksen tavoitteena oli kehittää kolmiulotteinen ihmisen myoomakudokseen perustuvan invaasiomalli, jonka avulla voisimme tutkia verisuonten kasvua estävien arresten ja endostatin molekyylien vaikutusta kielisyöpäsoluihin. Aiemin syövän invaasiota on tutkittu käyttämällä klassista kollageeni-invaasiomallia, joka tehdään sekoittamalla rotan tyypin I kollageeniä, hiiren sarkoomasolujen tuottamaa matriksia ja ihmisen fibroblasteja. Tutkimuksissamme kehitimme uuden invaasiomallin, joka perustuu ihmisen myoomakudokseen. Tutkimuksessa sen todettiin sisältävän monia erilaisia soluja ja molekyylejä, joita on normaalistikkin syövän mikroympäristössä. Lisäksi osoitimme, että se sopii invaasiotutkimuksiin monille syöpätyypeille. Soluvälitilamatriksista pilkotaan useita erilaisia molekyylejä joilla on osoitettu olevan angiogeneesia hillitseviä ominaisuuksia. Arresten on 26 kDa kokoinen polypeptidi, jota pilkotaan tyypin IV kollageenista. Sen tiedetään vähentävän angiogeneesia – uusien verisuonten muodostumista ja syövän kasvua in vivo. Sen vaikutuksia muihin kuin endoteelisoluihin ei ole kuitenkaan tutkittu. Tutkimuksissamme se vaikutti suoraan kielisyöpäsoluihin vähentäen niiden liikkumista ja invaasiota kolmiulotteisissa organotyyppisisssä malleissa ja hiirimallissa. Toinen tutkimamme angiogeneesin inhibiittori on endostatin, jota pilkotaan tyypin XVIII kollageenista. Sen tiedetään vähentävän angiogeneesia hiirimalleissa ilman toksisia sivuvaikutuksia. Me osoitimme tutkimuksissamme, että se vaikuttaa suoraan kielisyöpäsoluihin vähentäen niiden invaasiota ja leviämistä 3D organotyyppisissä malleissa sekä hiirikokeissa. Koska arresten ja endostatin ovat anti-angiogeenisiä ja anti-invasiivisia molekyylejä, ne ovat täten potentiaalisia syöpälääkkeitä. Ne näyttäisivät vaikuttavan suoraan syöpäsoluihin vähentämällä niiden invaasiota. Myoomainvaasiomalli mahdollistaa syöpää ehkäisevien molekyylien tutkimisen uudella ja todenmukaisemmalla tavalla

Endostatin Induces Proliferation Of Oral Carcinoma Cells But Its Effect On Invasion Is Modified By The Tumor Microenvironment

The turnover of extracellular matrix liberates various cryptic molecules with novel biological activities. Endostatin is an endogenous angiogenesis inhibitor that is derived from the non-collagenous domain of collagen XVIII. Although there are a large number of studies on its anti-tumor effects, the molecular mechanisms are not yet completely understood, and the reasons why endostatin has not been successful in clinical trials are unclear. Research has mostly focused on its anti-angiogenic effect in tumors. Here, we aimed to elucidate how endostatin affects the behavior of aggressive tongue HSC-3 carcinoma cells that were transfected to overproduce endostatin. Endostatin inhibited the invasion of HSC-3 cells in a 3D collagen-fibroblast model. However, it had no effect on invasion in a human myoma organotypic model, which lacks vital fibroblasts. Recombinant endostatin was able to reduce the Transwell migration of normal fibroblasts, but had no effect on carcinoma associated fibroblasts. Surprisingly, endostatin increased the proliferation and decreased the apoptosis of cancer cells in organotypic models. Also subcutaneous tumors overproducing endostatin grew bigger, but showed less local invasion in nude mice xenografts. We conclude that endostatin affects directly to HSC-3 cells increasing their proliferation, but its net effect on cancer invasion seem to depend on the cellular composition and interactions of tumor microenvironment. (C) 2015 Elsevier Inc. All rights reserved.3361130140Health Sciences Council of the Academy of Finland [128259, 115256, 251314]Finnish Cancer OrganizationsFinnish Cultural FoundationFinnish Dental Society ApolloniaBiocenter Oulu Graduate SchoolGraduate School of In Vitro DiagnosticsFINDOS graduate schoolFoundation for Laboratory MedicineMaud Kuistila Memorial FoundationCancer Foundation of Northern Finlan

Organotypic three-dimensional assays based on human leiomyoma–derived matrices

Abstract Alongside cancer cells, tumours exhibit a complex stroma containing a repertoire of cells, matrix molecules and soluble factors that actively crosstalk between each other. Recognition of this multifaceted concept of the tumour microenvironment (TME) calls for authentic TME mimetics to study cancer in vitro. Traditionally, tumourigenesis has been investigated in non-human, three-dimensional rat type I collagen containing organotypic discs or by means of mouse sarcoma-derived gel, such as Matrigel®. However, the molecular compositions of these simplified assays do not properly simulate human TME. Here, we review the main properties and benefits of using human leiomyoma discs and their matrix Myogel for in vitro assays. Myoma discs are practical for investigating the invasion of cancer cells, as are cocultures of cancer and stromal cells in a stiff, hypoxic TME mimetic. Myoma discs contain soluble factors and matrix molecules commonly present in neoplastic stroma. In Transwell, IncuCyte, spheroid and sandwich assays, cancer cells move faster and form larger colonies in Myogel than in Matrigel®. Additionally, Myogel can replace Matrigel® in hanging-drop and tubeformation assays. Myogel also suits three-dimensional drug testing and extracellular vesicle interactions. To conclude, we describe the application of our myoma-derived matrices in 3D in vitro cancer assays. This article is part of the discussion meeting issue ‘Extracellular vesicles and the tumour microenvironment’

Arresten inhibits migration of HSC-3 cells.

<p><b>A.</b> 30 000 Ctrl-HSC and Arr-HSC cells were allowed to migrate through Transwell inserts and the number of migrated cells was counted under a microscope at 50×magnification. Mann-Whitney U-test, ***p<0.001, (n = total number of fields analyzed, 2–4 fields per Transwell insert). <b>B.</b> 30 000 HSC-3 cells were allowed to migrate through Transwell inserts in the presence of human recombinant purified arresten (5 and 20 µg/ml) and the number of migrated cells was counted as described above. Mann-Whitney U-test, **p<0.01, (n = total number of fields analyzed, 3–5 fields per Transwell insert). <b>C.</b> Scratch wound healing assay with Ctr-HSC and Arr-HSC clones in which the closure of the wound was measured at 0, 16 and 48 h. Scale bar 50 µm<b>. </b><b>E.</b> Quantification of scratch wound healing in the Ctrl-HSC and Arr-HSC clones. Mann-Whitney U-test, ***p<0.001, (n = 70 fields at 0, 16 and 48 h per clone).</p