RESEARCH AND METHODOLOGIES

 

Molecular aspects of tumor cell migration and invasion

 

Aspetti molecolari della migrazione ed invasione delle cellule tumorali

 

 

Giuseppina Bozzuto; Paola Ruggieri; Agnese Molinari

Dipartimento di Tecnologie e Salute, Istituto Superiore di Sanità, Rome, Italy

Address for correspondence

 

 


SUMMARY

Cell migration and invasion are crucial steps in many physiological events. However, they are also implicated in the physiopathology of many diseases, such as cancer. To spread through the tissues, tumor cells use mechanisms that involve several molecular actors: adhesion receptor families, receptor tyrosine kinases, cytoskeleton proteins, adapter and signalling proteins interplay in a complex scenario. The balance of cellular signals for proliferation and survival responses also regulates migratory behaviours of tumor cells. To complicate the scene of crime drug resistance players can interfere thus worsening this delicate situation. The complete understanding of this molecular jungle is an impossible mission: some molecular aspects are reviewed in this paper.

Key words: neoplasms, neoplasm invasion, molecular markers.


RIASSUNTO

La migrazione e l'invasione cellulare rappresentano momenti cruciali in molti eventi fisiologici: questi due processi, tuttavia, sono anche implicati nella fisiopatologia di varie malattie, tra cui i tumori. Per diffondersi attraverso i tessuti, le cellule tumorali ricorrono a meccanismi che vedono il coinvolgimento di diversi componenti cellulari: famiglie di molecole di adesione, recettori tirosinchinasi, proteine del citoscheletro, proteine di segnalazione intracellulare intervengono in un complesso scenario molecolare. Le vie di segnalazione regolanti i processi di sopravvivenza e proliferazione cellulare giocano un ruolo importante anche nei comportamenti migratori delle cellule tumorali. A complicare la scena del crimine, marcatori proteici della farmacoresistenza contribuiscono al conferimento di un fenotipo maggiormente aggressivo, peggiorando in tal modo una situazione già di per sé delicata. La comprensione completa di questa "giungla molecolare" è una missione impossibile: in questa rassegna verranno presi in considerazione alcuni degli aspetti molecolari.

Parole chiave: neoplasie, invasione delle cellule tumorali, marcatori molecolari.


 

 

INTRODUCTION

Cell migration and invasion are crucial steps in many physiological events such as implantation of embryo, embryogenesis, morphogenesis, neurogenesis, angiogenesis, wound healing and inflammation [1, 2]. However, cell migration and invasion are also implicated in the pathophysiology of many diseases, such as cancer. Indeed, the capacity to produce metastases, very different among cancers, is the main features of malignant tumors and it is one of the main causes of death for cancer. This is due to the fact that metastases are constituted by cells much more resistant, aggressive and efficient than those forming the primary tumor.

In the last years, major efforts have been undertaken to understand the molecular mechanism underlying the distinct steps of metastasis, which are (i) detachment of tumor cells from the primary tumor, (ii) invasion into surrounding tissue, (iii) intravasation into blood or lymphatic vessels, (iv) dissemination in the blood stream or the lymphatic system and, finally, (v) extravasation and outgrowth at a secondary site. Each of these steps requires a distinct molecular program in which the modulation of the adhesive and migratory as well as the cytoskeletal properties of the disseminating tumor cells play essential roles.

Tumors can spread in a variety of channels/ways: the most common pathway is tumor extending in continuity beyond the organ or structure of origin, i.e. when it passes from the original organ to another organ or vessel or cavity by continuity. Dissemination for contiguity occurs when tumor infiltrates tissue spaces of non continuous adjacent structures.

The most common pathways for distant spread in the chest and abdomen are the lymphatics, blood vessels, and coelomic cavities. Cancer cells can disseminate from the primary site via lymphatic routes ("lymphatic metastases") and by haematogenous routes ("ab initio hematogeneous metastases"). Secondary haematogenous dissemination of lymphatic metastases also occurs from overt metastases to other distant sites. Coelomic cavities involved in tumor dissemination include the pleural space of the thoracic cavity and the peritoneal spaces of the abdomen and pelvis. The most commonly involved is the peritoneum, which carries tumor cells in ascitic fluid. The distribution of intraperitoneal metastases often corresponds to predictable flow patterns, the most classic example of which is seen with ovarian cancer. With this tumor, or any tumor demonstrating intraperitoneal spread, the paracolic gutters, cul-de-sac, omentum, and liver surface are common sites of metastases. In the chest, pleural dissemination typically spreads via gravitational forces and is often seen in the lower thoracic cavity [3].

Each phase involved in the metastatic process requires many specific molecular interactions between the tumor cells, the extracellular matrix (ECM) and the cells of the stroma. Liotta et al. [4] proposed the well-known three-steps theory for tumor cell invasion: in the first step tumor cell adhere to specific components of the matrix through cell surface receptors; in the second step, the anchored tumor cell secrets hydrolytic enzymes which can locally degrade the matrix. The third step is represented by the tumor cell migration through the matrix region modified by proteolysis.

To spread through the tissues, tumor cells use mechanisms that are similar but not identical to those used by normal cells during physiological processes such as morphogenesis and migration of immune cells [5]. Cell migration was firstly studied in fibroblasts, keratinocytes and myoblasts [6, 7]. Further studies showed that some basic strategies are also preserved in tumor cells.

The cell migration through the tissues results from a continuous cycle of coordinated and interdependent steps that involve the cytoskeletal machinery [7, 5]. Migration begins when a cell responds to an external signal that leads to the polarization and extension of a "leading front" in the direction of the movement. Then, the leading front binds to ECM proteins, and the cell body shrinks: a traction force is thus generated, which determines the slow sliding of the cell body behind the migrating front.

In the first phase of the migration process the extension of cell protrusions is driven by actin polymerization. This reaction may be increased by the actin monomer addition to existing filaments or by the nucleation of new actin filaments by Arp2/3 (ac-tin-related protein 2/3) [8]. Arp2/3 is predominantly regulated by the family of adapter proteins WASP (Wilscott-Aldrich syndrome protein) and WAVE (WASP-family verprolin-homologous protein), which act as a molecular platform for the formation of the complex responsible for actin nucleation. As described in the speculative model proposed by Rohatgi et al., [9] Cdc42 and lipids (PI(4,5)P2) may regulate actin assembly at membrane-proximal sites by recruitment and activation of the Arp2/3 complex via N-WASP-like proteins. Phosphoinositides bind and activate the guanosine-nucleotide-exchange factors (GEFs) that, in turn, regulate the activity of small GTPases [10] able to activate actin assembly regulatory proteins.

The cellular protrusions that initially recognize and bind to the ECM may be morphologically different: lamellipodia, filopodia, pseudopodia and invadopodia [11], all contain filamentous actin. Indeed, the propulsion and elongation of pseudopodia are driven by actin polymerization and by filament assembly [9, 12]. Growing cell protrusions reach and begin to bind to adjacent ECM by means of adhesion molecules such as integrins and cadherins: these molecules are involved in the formation of "focal contacts" complex composed of extracellular ligands, tyrosine kinase receptors and cytoskeletal proteins.

 

ADHESION MOLECULES

The high degree of specificity that characterizes both the cell recognition and the adhesion phenomena requires the interaction between molecules to constitute cell-cell or a ECM-cell bridges. These proteins are the so-named "adhesion molecules" or CAMs (cell-cell adhesion molecules), glycoproteins expressed on the cell surface. Most of CAMs belongs to six protein families: cadherins, integrins, immunoglobulin superfamily, selectins, lymphocyte homing receptors. CAMs are involved in many physiological and pathological processes, and it is now well known that they can assume a key role in the complex evolution of metastases [13].

Cadherins (calcium-dependent adhesion molecules) belong to a large family of transmembrane glycoproteins that mediate cell-cell adhesions in a calcium-dependent manner [14]. The epithelial cadherin (E-cadherin) has been the first adhesion molecules to be discovered and characterized. Thus, E-cadherin is the prototype member of cadherin family and plays a fundamental role in the development and maintenance of adhesion between epithelial cells [15]. E-cadherin consists of an extracellular domain, constituted of five cadherin repeats (EC1, EC2, EC3, EC4 and EC5), a transmembrane domain, and an intracellular domain that binds to both P120 catenin and beta-catenin. It has been well documented that tumors of epithelial origin partially, or totally, lose the expression of E-cadherin with the acquisition of a more aggressive phenotype [16]. On the other hand, several studies have also shown the strong anti-invasive and anti-metastatic role of E-cadherin [17-19].

The large family of integrins comprises a wide number of cellular receptors, heterodimeric transmembrane glycoproteins constituted of two subunits, the alfa chains associated with the beta chains through non-covalent bond [20]. Integrins are adhesion molecules essential in the intercellular interactions and in the integration (hence the name) of cells with the extracellular environment. Both alfa and beta chains penetrate into the cell membrane giving rise to the cytoplasmic domains essential for signal transduction. The molecular mass of alfa subunits varies between 120 and 180 kDa, whereas that of the beta subunits ranges from 90 to110 kDa. By different combinations of 18 alfa chains and 8 beta chains are generated 24 distinct integrins [21]. Outside of the plasma membrane the alfa and beta subunits protrude about 23 nm, and the NH2 terminal ends of each chain are used to link the ECM. The main role of these adhesion molecules, in fact, is to mediate cell-matrix and cell-cell interactions [22].

The integrins are involved in many physiological and pathological processes, including inflammation and wound repair [23], proliferation, differentiation and apoptosis [24]. In particular, they seem to have a crucial role in metastasis, by mediating the interaction of tumor cells with the ECM [25]. These roles are possible thanks to the physical bond of adhesive contacts with the actin cytoskeleton, with the consequent activation of cytoplasmic pathways mediated by different signal proteins such as Rho, Src, MAPKs and PKB [22]. Evidence of the connections with the cytoskeleton comes from a large number of studies conducted by electron microscopy and demonstrating the co-localization of integrins with the cytoskeletal structures [26]. The integrins bind to a wide range of matrix proteins, including laminin, fibronectin, trombospondin, vitronectin and various types of collagen [27-29].

A widely used classification of integrin superfami-ly is based on the type of chain constituting the heterodimer. VLAs are integrins belonging to the beta1 subfamily, and consist of six heterodimers. They are called "very late activation antigens" (VLAs) because the first glycoproteins identified (VLA-1 and VLA-2) were only expressed at a late stage after T-cell activation. The beta1 integrins are expressed on lymphocytes [20, 30], where they mediate the binding with the proteins of the ECM, playing an important role in the extravasation and migration in tissues during the immune response [31]. In this subfamily the beta1 subunit binds to 6 different alfa subunits, leading to the integrin classification VLA1, VLA2, VLA3, VLA4, VLA5, VLA6. VLA2 consists of the alfa 2 and beta 1 subunits, binds to different types of collagen (I-II-III-IV) and to laminin I. VLA5 (alfa5, beta1) binds to fibronectin and to the adhesion molecule L1CAM (L1 cell adhesion molecule).

Another adhesion molecule widely expressed on lymphocytes is CD44. This small molecule is a membrane glycoprotein of Class I of 85-95 kDa. CD44 is encoded by a single gene [32] but the heterogeneity of produced protein is partly generated by post-transcriptional modifications [33], that differ with respect to both cell type and growth conditions. This glycoprotein is able to bind to laminin, fibronectin, collagen and, particularly, to hyaluronic acid, an important ECM component [34]. The CD44 is a multifunctional receptor, not only important in the context of the immunological response. Similar to integrins discussed above, CD44 was initially detected on the membrane of the immune system cells. Its identification on other type of cells has expanded its function [35]. Gilcrease et al. [23] demonstrated that a high expression of VLA2 and CD44 was associated with a high capability of producing metastases by renal carcinoma. In fact, by analyzing the adhesion molecule expression in 37 cell lines, isolated from nephrectomies, and the relative behaviour in the extra-renal stroma, a positive correlation was observed between invasive capacity and level of expression of both the molecules on the cell membrane. A study published in 2006 also highlighted the correlation between VLA2, VLA5 and CD44 adhesion molecules, and tumor metastases in human osteosarcoma cells [36]. Very important is also the association of CD44 with ezrin, radixin, myosin (ERM) and merlin (moesin-ezrin-radixin-like protein) proteins [37-39]. In particular, ERM proteins are essential for the regulation of protein movements in the plasma membrane, cells shape and cell migration [40, 41].

 

INTERACTION WITH THE ECM AND FORMATION OF FOCAL CONTACTS

The integrin family of heterodymeric transmembrane receptors play a particularly important role in the interaction with ECM and formation of "focal contacts" [24, 42]. Cells adhere to ECM via integrin-mediated adhesions that link matrix to actin cytoskeleton. In cultured cells, integrin-based molecular complexes form discrete morphological entities of several types. Small (0.5-1 urn) "dot-like" or "point contacts" also known as "focal complexes" are localized at the edges of lamellipodia. Elongated (3-10 um in length) streak-like structures associated with actin- and myosin-containing filament bundles (stress fibers) are known as "focal contacts" or "focal adhesions" [43]. "Podosomes" and "invadopodia" are highly dynamic and specialized adhesive structures, rich in focal contacts. They contribute to remodel the cytoskeleton and the matrix by controlling both the local turnover of focal contacts and the degradation of ECM.

Following the contact with specific ECM ligands, integrins clusterize on the cell membrane, and recruit through their intracellular domain either adapter proteins or signal proteins. This leads to phosphorylation and dephosphorylation signals within the cell. In particular, cytoplasmic region of integrins directly interacts with adapter proteins such as alpha actinin, tensin, talin and the signal protein FAK (focal adhesion kinase). All these proteins can in turn bind to other adapter proteins to recruit in focal contacts actin ligands, such as vinculin, paxillin and alpha-actinin, which are all involved in the dynamic association with actin filaments. [43, 44].

Assembly of focal contacts is regulated through various signaling pathways that include the phosphatidylinositol 3-phosphate (PI3K), the protein kinase C (PKC) and Rho family GTPases [44, 45].

The dynamics of focal cell-ECM adhesions is determined by the cyclic formation and destruction of these structures, and both intracellular calpain proteinases and the ubiquitin-dependent proteasome system are involved in these regulatory mechanisms [46-48].

Focal adhesions allow the cell to acquire a "morphological polarization", which results in a directional motility. The generation of a protrusive force, produced by the asymmetric actin polymerization on the leading edge of the cell, and the generation of a contractility force within the cell, through the interaction between actin filaments and myosin motor system, contribute to the process of directional migration. In some cases, during the processes of migration and invasion, tumor cells are able to adopt an "ameboid" mechanism of propulsion, involving integrin-independent adhesions and actomyosin-dependent expansion/contraction cycles. These "ameboid" cells circumnavigate, rather than degrade, the ECM physical barrier [49]. In other cases, tumor cells actively invade different tissues through a turnover of adhesion molecules that allow the cell to form contractility structures and degradate the ECM [50].

 

CELL CONTRACTION: REGULATION OF ACTIN-MYOSIN COMPLEX

Actin-myosin contraction promotes the cell shortening along the long axis, and generate internal tension in the direction of the focal contacts located on the leading edge. Subsequently, the cell-substrate bonds preferentially dissolve at the rear edge of the cell, while the migration front, still attached, moves further forward [51, 52]. This induces the slow sliding of the cell rear edge forward. Organization, assembly and the tension of the actin-myosin skeleton are controlled by different regulatory enzyme systems. One of such systems directly controls the myosin contractility, by modulating the light chain (myosin light chain, MLC) through the MLC kinase activity (MLCK) and MLC phosphatase (MLCP) counteraction. The activity of these enzymes, in turn, is regulated by another set of enzymes, the Rho-GTPases, belonging to the group of small GTPases (guanosine triphosphatases). This group includes several members: Rho, Rac and CDC42 proteins [53-55].

Targets of Rho protein are mDia1 (mammalian Diaphanous 1), LIMKs (LIM kinases), and Rhoassociated kinase (ROCK). mDia1 is a mammalian homolog of Drosophila diaphanous and works as an effector of the small GTPase Rho. LIM kinase-1 (LIMK1) and LIM kinase-2 (LIMK2) are actinbinding kinases that phosphorylate members of the ADF/cofilin family of actin binding and filament severing proteins. Rho-associated kinase (Rho-kinase/ROCK/ROK) is a serine/threonine kinase and plays an important role in various cellular functions.

ROCK phosphorylates and inhibits the activity of MLCP: this inhibition in turn results in increased MLC phosphorylation and, consequently, in an increase of the actin-myosin complex contractility. ROCK in cooperation with mDia1 can also stimulate the formation of "stress fibers". ROCK phosphorylates and activates LIMK1 which in turn inhibits the depolymerisation of actin microfilaments [56]. Finally, mDia1 promotes actin polymerization and microtubule stabilisation. It has been suggested that mDia1 also increases the rate of cytoskeletal reorganization [57].

The increase of contractile tension induced by Rho results in the formation of numerous actin bundles associated with mature focal contacts. In contrast, ROCK and Rho inhibition leads to actin disassembly and focal contacts processing in small focal complexes: this transformation is probably the consequence of the decrease in actin-myosin tension [56].

Rho and MLCK allow cells to separately control the movements of cortical actin from the contraction of actin filaments, located in the deeper layers of the cytoplasm. Indeed, the contraction of actin filaments, controlled by myosin II, is induced primarily by Rho and its effector ROCK [58, 59]. In contrast, the cortical actin network seems to be regulated by MLCK and not by Rho [60, 61].

Therefore, the Rho protein family plays a central role in regulating the movement of the cytoskeleton: the level of action of these proteins is regulated by the balance between a state of activation mediated by the GEFs exchange factors (GTPase exchange factors), which facilitate the replacement of GDP with GTP, and a state of inactivation where GAPs (GTPase-activating proteins) operate by attenuating the signal through the stimulated hydrolysis of bound GTP [62].

Besides Rho, other proteins of the same group, Rac and CDC42, can play an important role in regulating actin movements in migrating cells. Activated Rac stimulates the "ruffling" of the membrane, which results in the formation of the actin-rich cellular protrusions lamellipodia, while activated CDC42 stimulates the actin polymerization and the formation of the thin membrane protrusions filopodia [62]. The activity of Rho GTPase also regulates other types of dynamic structures such as cadherin-dependent intercellular junctions, thus mediating the transition from epithelial to mesenchymal phenotype. The epithelial-mesenchymal transition (EMT) is a frequent event in the progression of various malignancies and is characterized by loss of expression of E-cadherin and acquisition of expression of N-cadherin and vimentin.

 

THE INVADOPODIA

The invadopodia are cellular protrusions rich in actin that can mediate the proteolysis of ECM [6365]. The molecular origin and the role of invadopodia in particularly aggressive tumors such as gliomas, breast carcinomas and melanomas have been recently discussed [63]. These subcellular organelles have been observed for the first time in fibroblasts, genetically modified by inserting v-Src oncogene, which encodes for a protein with tyrosine kinase activity. Following transformation, this protein is constitutively activated and cells, grown on fibronectin, form prominent protrusions with both adhesive and degradation properties [66, 67]. The invadopodia have a diameter varying between 0.1 and 0.8 mm and their length can be up to 2 mm. Several markers are used for their identification: F-actin (filamentous actin form), Arp2/3, N-WASP and cortactin, SH3-proteins involved in various tumors [69-73].

The maturation of invadopodia sees a four-steps process: (i) location of cortactin on the site of the protrusion formation; (ii) recruitment of MT1-MMP metalloproteinase (membrane-type type 1 MMP); (iii) degradation of the matrix; (iv) dissociation of the cortactin from the cell membrane [70].

Several proteins are involved in the molecular pathways responsible for the invadopodia formation, whose invasive properties are attributed mainly to integrin-ligand binding (Figure 1) [69]. The molecular cascade starts with the ECM-integrin linkage, together with the interaction of growth factors, such as the "epidermal growth factor" (EGF) and the "fibroblast growth factor" (FGF), with their receptors. The recruitment and the activation of other components occur downstream, outlining a complex molecular network in which many pathways are still unknown. Src is the first cytosolic protein involved, and it is activated by phosphorylation. Following the activation mediated by activated Src, cortactin binds to N-WASP, F-actin and Arp2/3 (these two molecules are also triggered by activated N-WASP), and inhibits actin depolimerization. This cooperative action is essential to allow the actin assembly, physiological process essential in invadopodia formation. Experiments with RNA interference, negative mutants or inhibitory antibodies show that proteins such as cortactin [70, 72, 74], N-WASP [73, 75], AMAP1/ASAP1 (protein belonging to Arf GAP family, and complexed with a peptidase acting as GTPase) [76] and Tks5/Fish (an anchor protein with SH3-domains) [77] are necessary for the degradation of ECM mediated by the invadopodia in various tumor cell lines. Tks5/Fish, thanks to its anchoring domains, binds to N-WASP, whereas AMAP1/ASAP1 binds to cortactin: these associations are important for the subsequent formation of invadopodia.

 

 

FOCUSED PROTEOLYSIS OF ECM: THE METALLOPROTEINASES

Degradation and remodeling of ECM are essential stages of migration, invasion and metastasis of cancer cells. These processes are primarily mediated by two types of proteolytic enzymes: the plasminogen activator system components and the matrix metalloproteinases (MMPs) [78].

The MMPs belong to a family of zinc-dependent endopeptidases, highly conserved and structurally related, capable of degrading many components of basement membrane and ECM [79]. The substrates of MMPs include a wide variety of proteins such as chemotactic molecules, adhesion molecules, proteinase inhibitors, cell surface receptors, blood coagulation factors, growth factors and growth factor-binding proteins. Studies on the activity of MMPs in various cells and tissues, demonstrated the importance of these enzymes in many physiological (e.g. embryonic development, bone resorption, angiogenesis) and pathological processes (e.g. rheumatoid arthritis, multiple sclerosis, tumor growth and metastasis) [80, 81].

Human MMPs generally contain a signal pep-tide, a N-terminal pro-peptide domain, a catalytic domain that includes highly conserved zinc-binding sites, and a hinge region followed by an hemopexinlike C-terminal domain (Figure 2a).

 


 

They can be divided into different classes according to their sequence homology, substrate specificity, cellular localization and structure (Figure 2b). MMP-2 and MMP-9 gelatinases present an additional domain inserted between the catalytic domain and the active site domain. MT-MMPs may have an additional transmembrane domain site, either a glycosylphosphatidylinositol anchor site (GPI) or a Ig-like domain that determines the localization on the cell surface.

According to substrate five MMP subclasses have been defined: collagenases (MMP-1, MMP-8, MMP-13), gelatinases (MMP-2, MMP-9), stromalysins (MMP-3, MMP-10, MMP-11), metalloelastases (MMP-12, MMP-18, MMP-19), matrilysins (MMP-7), membrane-type-MMPs (MT-MMPs) [82, 83].

The expression, secretion, and activity of MMPs are finely controlled in normal tissue. In particular, the expression of MMPs is regulated at both transcriptional and post-transcriptional level. Several factors influence the transcription of genes coding for these endopeptidases, including cytokines, growth factors, hormones, oncogenes and tumor promoters [84, 85]. cytokines and growth factors are able to regulate the expression of metalloproteinases through the MAPKs pathway that includes proteins such as ERK 1/2 (extracellular regulated kinase 1/2), JNK/SAPK1/2 (c-Jun N-terminal kinase 1/2) and p38MAPK. Thus, the activation of AP-1 and ETS transcription factors by the mitogen kinases is responsible of the maximum expression of MMPs [85].

At post-transcriptional level, the biological activity of MMPs is regulated by their state of activation. Many MMPs are secreted from cells in latent form as zymogens (pro-MMPs). The pro-MMPs conversion in a functionally active form requires a more specific multi-stage process known as "cysteine switch" and that leads to the proteolytic removal of parts of the molecule (Figure 3). A highly conserved cysteinerich domain, located in the prodomain, links to zinc ion in the active site (Figure 3a). The prodomain cleavage leads to the rupture of the zinc-cysteine (Zn-C) bond, followed by the amino-terminal prodomain loss (Figure 3b): in this way the active site becomes accessible. For many MMPs proteolytic activation begins in the extracellular space by serine proteases, or by other members of the family of MMPs [86]. On the cell surface, the MT-MMPs (membrane-type MMPs) have been identified as potent physiological activators of several MMPs [82, 87].

 

 

The activity of MMPs is modulated by the family of "tissue inhibitors of metalloproteinases" (TIMPs) that are able to inhibit active MMPs after binding in their catalytic domain. In addition, TIMP-1 and TIMP-2 regulate the activation of some pro-MMPs by binding to their carboxy-terminal domains. In particular, TIMP-1 inhibits the activation of pro-MMP-9, while TIMP-2 binds and regulates the activation of pro-MMP-2 [88]. As shown in Figure 4, MT1 -MMP can form a complex with TIMP-2, which subsequently serve as a receptor for pro-MMP-2. A second molecule of MT1-MMP adjacent to the complex, not inhibitor-linked can convert pro-MMP-2 in its active conformation [79, 89]. In particular, at low concentrations, TIMP-2 promotes the formation of a complex with pro-MMP-2 and MT1-MMP on the cell surface, thus leading to activation of MMP-2 (Figure 4a). However, at high concentrations TIMP-2 inhibits the activation (Figure 4b).

The active MMPs may remain localized on the cell surface through binding with membrane molecules, and this leads to a more focused ECM degradation. The expression of MMPs and TIMPs changes during the neoplastic transformation. A high secretion of MMPs by tumor cells has been demonstrated in many types of cancer [3, 90] and the imbalance between MMPs and their specific inhibitors seem to play an important role in the tumor growth and invasion [3, 78].

 

ROLE OF MITOGEN-ACTIVATED PROTEIN KINASES (MAPKS) IN THE PROCESSES OF CELL MIGRATION AND INVASION

Many extracellular signals converge on the pathway of proteins belonging to the serine/threonine kinase family and known as MAPKs. MAPKs play an important role in cell proliferation, oncogenesis, differentiation, inflammation and response to stress [91], but several evidence suggest that these kinases is also essential for cell migration [92].

All MAPKs contain tyrosine-X-threonine motifs (where X is any amino acid) in the activation domain and are activated through a kinase cascade in which MAPKKKs (MAPKs kinase kinase) activates MAPKK (MAPKs kinase) which, in turn, activates MAPK by the phosphorylation of threonine and tyrosine residues located in the activation domain (Figure 5). Based on differences in the activation domain, MAPK family can be subdivided into three groups: kinases regulated by extracellular signals (ERK1/2), which display a threonine-glutamine-tyrosine motif, p38 MAPK isoforms which have a threonine-alanine-tyrosine motif, and JNK1/2/3 which present threonine-proline-tyrosin.

Numerous experimental observations have shown that ERK1/2 is directly involved in cell motility [9395]. Some growth factors and ECM components activate ERK through signalling pathways involving Ras, Raf and MEK1/2. Once activated, ERK phosphorylates different substrates including MLCK, calpain, paxillin and FAK [96-99].

The MLcK phosphorylation determines the focal contact turnover and the formation of cell membrane protrusions at the migrating front [60, 100]. Activated calpain, instead, interacts with the cytoskeleton proteins by promoting focal contact disassembly [95]. Finally, the phosphorylation of FAK and paxillin by ERK may regulate the focal contact dynamics likely by affecting the interaction between FAK and paxillin [97].

Recent studies have shown that p38 MAPK involved in inflammation, apoptosis, cardiomyocyte hypertrophy and cell differentiation, plays a key role in the migration of different cell types, [101-104]. p38 MAPK activity is stimulated by many growth factors, cytokines and chemotactic substances that activate MEK3/6: this protein, in turn, phosphorylates and activates p38 MAPK [105]. p38 MAPK substrates are mainly MAPKAPK2/3 (a protein activated by either MAPK or MK), paxillin and cald-esmon which, directly or through the phosphorylation of other proteins, lead to the reorganization of actin and the formation of the "stress fibers" and adhesion structures, thus stimulating the directional migration of cells [106]. Studies on Drosophila embryos have shown that JNK is involved in the control of actin cytoskeleton in the formation of filopodia and lamellopodia, and in the movement of cells during neural tube closure [107, 108]. It was also demonstrated that JNK determines the formation of "stress fibers" and their accumulation in the leading front of fibroblasts [109].

 

RELATIONSHIP BETWEEN DRUG RESISTANCE AND INVASION

In the past studies on drug resistance and invasion generally proceeded along different research paths. Later the interest was focused on the possible relationship between the two phenomena. currently, many experimental evidence suggest a possible correlation between drug resistance instaurance and acquisition of a highly aggressive phenotype. This relationship has been demonstrated by two observations: (i) drug resistant tumor cells are more invasive and metastatic, when compared with sensitive tumor cells, (ii) in some cases, most metastatic tumors show a greater resistance to chemotherapy [110]. The resistance of tumors to chemotherapy is a multifactorial and complex phenomenon that often involves different cellular mechanisms [111]. Two types of resistance are known: an "intrinsic resistance" that occurs in cells never exposed to chemotherapy and an "acquired resistance" induced in response to chemotherapeutic treatment [112, 113].

The main cellular mechanisms so far identified, and that play a significant role in the phenomenon of drug resistance can be classified into five groups:

1. drug-target interaction (target resistance);

2. alterations of drug activation, or inactivation, by endogenous biochemical systems present in tumor cell (metabolic resistance);

3. alteration of DNA repair;

4. alteration in the ability of cancer cell to respond to death (resistance to apoptosis);

5. increased drug transport through cell membrane (transport molecule-mediated resistance). After selection for resistance to a single drug, cancer cells may also show cross-resistance to other drugs, structurally and functionally not related [114]. This phenomenon is known as "multidrug resistance" (MDR) and could explain why combined treatments that involve the use of cytotoxic agents with different targets can be not efficacious. MDR acquisition, induced by the treatment with a cytotoxic agent, is generally associated with an increase of transport proteins that results in a reduced intracellular concentration of cytotoxic drug.

The currently known active transporters that play an important role in MDR phenomenon are: members of the P-glycoprotein/TAP (ABcB-P-gp) subfamily (Figure 6), members of the of MDR-associ-ated protein subfamily (ABcc1-MRP1), members of the MXR/BCRP (ABCG) subfamily and the lung resistance related protein (LRP). Except for LRP, all belong to the superfamily of ABC transporters.

 

 

If P-gp, MRP and LRP are three important markers of drug resistance, immunohistochemical analyses showed that they are also markers of invasion and metastasis [110, 115]. Moreover, a study on human prostate carcinoma cell lines and its resistant variants with different metastatic capacity [116] gave the following results: cultured, highly metastatic cells express higher levels of bFGF m-RNA, IL-8, MMP-2, MMP-9 and P-gp than poorly metastatic parental cells line. These data suggest a possible correlation between metastasis and drug resistance mediated by P-gp [117]. An in vivo study conducted by Bradley et al. [118] showed that different stages of tumor progression displayed different levels of P-gp m-RNA expression. Surprisingly, 460 lung metastases were examined and each metastasis was positive for P-gp. Moreover, in an in vitro study it was demonstrated that human hepatoma cells rich in P-gp showed increased invasive properties, when compared to cells expressing low levels of P-gp [119]. Bates and colleagues [120] found that a CD44 isoform, normally involved in migration and invasion, coferred chemoresistance to colon carcinoma cells. Also a study of lung carcinoma cells showed that the standard form of CD44 is able to increase the expression of the MRP2 transporter (belonging to the family of "ATP-binding cassette"), resulting in the acquisition of a drug resistance phenotype by NSCLC cell line [121].

The human breast cancer drug resistant cell line MCF-7 ADR which overexpress P-gp shows a different invasive and metastatic potential when compared to the parental line [122, 123] shown that the loss of E-cadherin and the increase of N-cadherin during the acquisition of the resistant drug phenotype correlated with the increase in metastasizing capacity of MCF-7 ADR cells. The variation in expression of cadherin could be due to the control by twist transcription factor. In fact, twist overexpression results in the epithelial-mesenchymal transition (EMT) with the increase in cell motility and invasion. Many studies have shown that the transcriptional activation of the MDR1 transporter is regulated by the MAPK pathway [124, 125], while others have shown that also Snail, a transcription factor that mediates EMT, is regulated by the MAPK pathway as well [126]. Further studies on the involvement of P-gp in the mechanisms of cell migration and invasion have shown that treating MCF-7 ADR cells with the transport substrates of the molecule an increase in the production of CD147, and MMP-2 and MMP-9 is achieved [127]. So the expression and activity of drug resistance genes could simultaneously cross-activate genes that induce tumor metastasis.

Finally, malignant melanoma shows high levels of intrinsic drug resistance associated with a highly invasive phenotype. CD44, it is the major cell surface receptor to hyaluronan, implicated in cell adhesion, metastasis and tumor progression [128, 129]. When overexpressed in melanoma cells CD44 enhances the experimental metastatic potential and tumorigenicity [128], but its clinical significance in cutaneous melanoma is still unclear.

CD44 proteins assemble intracellular complexes that are important in signal transduction: key players in this regulation are ezrin, radixin and moesin (ERM) proteins. ERM proteins are involved in many physiological functions including regulation of actin cytoskeleton, control of cell shape, adhesion, motility and modulation of signal transduction pathways. In the phosphorylated form ERM proteins anchor CD44 to actin and support cell proliferation [130].

Advances on ezrin involvement in the metastatic phenomenon has been recently reviewed [131]. Novel molecular processes driven by ezrin activation include: phagocytosis, acquisition of resistance to chemotherapeutics and triggering of programmed cell death signals. Federici et al., [132] highlight that ezrin activity is mandatory for both the maintenance of migratory and invasive capacity of tumors and conservation of the ability to feed through other cells. This occurs through the specific molecular association between ezrin and molecules involved in many activities of metastatic cells, such as CD44 and Lamp-1. Particularly, the molecular interaction between ezrin and Lamp-1 was never been described together with its importance in allowing Lamp-1 membrane localization in metastatic cells.

The association of Pgp with actin mediated by ERM family proteins was demonstrated in drug resistant human tumor cells. Such an association appeared to be essential for the maintaining of the MDR phenotype [133]. Successively, a relationship between CD44 and the MDR1 transporter Pgp does exist in carcinoma cell lines [134]. In this study it was stated that the expression of Pgp alone does not increase the migration potential and that it is the interaction of Pgp with CD44 that affects cell migration.

In an our recent study [135], we investigated the role of the drug transporter P-glycoprotein (Pgp) in the invasion potential of drug-sensitive (M14 WT, Pgp-negative) and drug-resistant (M14 ADR, Pgp-positive) human melanoma cells. In particular, co-immunoprecipitation experiments assessed the association of Pgp with the adhesion molecule CD44 in multidrug resistant (MDR) melanoma cells, compared with parental ones. In MDR cells, the two proteins colocalized in the plasma membrane as visualized by confocal microscopy and immunoelectron microscopy on ultrathin cryosections. MDR melanoma cells displayed a more invasive phenotype compared with parental cells, as demonstrated by quantitative transwell chamber invasion assay. The Pgp molecule, after stimulation with specific antibodies, appeared to cooperate with CD44, through the activation of ERK1/2 and p38 MAPK proteins. This activation led to an increase of metalloproteinase (MMP-2, MMP-3, and MMP-9) mRNAs, and proteolytic activities, which are associated with an increased invasive behavior. RNA interference experiments further demonstrated Pgp involvement in migration and invasion of resistant melanoma cells. A link was identified between MDR transporter Pgp, and MAPK signaling and invasion. Finally, differently from drug-sensitive (Pgp-negative) melanoma cells, which showed an "individual mesenchimal" behaviour (Figure 7), Pgp-overexpressing melanoma cells adopted a 'chain collective' migration strategy reflecting potential high metastatic capacity (Figure 8).

 

 

 

 

Finally, new perspectives raise from a growing body of literature data which suggest a key role of tumor acidic microenvironment in cancer development, progression, and metastasis [136]. As reviewed in Fais et al [136], V-ATPases play a crucial function in determining the acidification of tumor microenvironment and are overexpressed in many types of metastatic cancers and positively correlated to their invasion and metastasis. The promoting effect of V-ATPases on cancer invasion and metastasis mainly relies on their ability to maintain an acidic pH of extracellular microenvironment and very acidic luminal pH. This pathway is in turn related to the activation, secretion, and cellular distribution of many proteases involved in the digestion of ECM. Molecular inhibition of V-ATPases by small interfering RNA in vivo as well as a pharmacologic inhibition through proton pump inhibitors (PPIs) led to tumor cytotoxicity and marked inhibition of human tumor growth in xenograft models.

Noteworthy, tumor acidity is also related to tumor cannibalism, a characteristic of malignancy and metastatic behaviour. Through this function metastatic tumors feed off other cells, either dead or alive, including the T lymphocytes that should kill them. Experimental data have shown that cannibalism is increased in acidic culture conditions [137]. A new marker of malignancy with a specific role in tumor cannibalism and in the establishment of metastatic phenotype has been recently proposed [138]. Tumor cannibalism has some similarities to the phagocytic activity of Dictyostelium discoideum. Recently, ph-g1A has been described as a protein that is primarily involved in the phagocytic process of this microorganism. The closest human homologue to phg1A is transmembrane 9 superfamily protein member 4 (TM9SF4). TM9SF4 is highly expressed in human malignant melanoma cells deriving from metastatic lesions, whereas it is undetectable in healthy human tissues and cells. TM9SF4 is predominantly expressed in acidic vesicles of melanoma cells, in which it co-localizes with the early endosome antigens Rab5 and early endosome antigen 1. TM9SF4 silencing induced marked inhibition of cannibal activity, which is consistent with a derangement of intracellular pH gradients, with alkalinization of acidic vesicles and acidification of the cell cytosol.

 

REFERENCES

1. von der Mark K, Schöber S, Goodman SL. Integrins in cell migration. Methods Mol Biol 1999;129:219-30.         

2. Cho SY, Klemke RL. Extracellular-regulated kinase activation and CAS/Crk coupling regulate cell migration and suppress apoptosis during invasion of the extracellular matrix. J Cell Biol 2000;149:223-36.         

3. Pantel K, Brakenhoff RH. Dissecting the metastatic cascade. Nature Rev Canc 2004;4:448-56.         

4. Liotta LA, Kleinerman J, Catanzaro P, Rynbrandt D. Degradation of basement membrane by murine tumor cells. J Natl Cancer Inst 1977;58:1427-31.         

5. Friedl P, Bröcker EB. The biology of cell locomotion with three-dimensional extracellular matrix. Cell Mol Life Sci 2000;57:41-64.         

6. Abercrombie M, Dunn GA, Heath JP. The shape and movement of fibroblasts in culture. Soc Gen Physiol Ser 1977;32:57-70.         

7. Lauffenburger DA, Horwitz AF. Cell migration: a physically integrated molecular process. Cell 1996;84:359-69.         

8. Pollard TD, Borisy GG. Cellular motility driven by assembly and disassembly of actin filaments. Cell 2003;112:453-65.         

9. Rohatgi R, Ma L, Miki H, Lopez M, Kirchhausen T, Takenawa T, Kirschner MW. The interaction between N-WASP and the Arp2/3 complex links Cdc42-dependent signals to actin assembly. Cell 1999;97:221-31.         

10. Kaibuchi K, Kuroda S, Amano M. Regulation of the cytoskeleton and cell adhesion by the Rho family GTPases in mammalian cells. Annu Rev Biochem 1999;68:459-86.         

11. Adams JC. Cell-matrix contact structures. Cell Mol Life Sci 2001;58:371-92.         

12. Cramer LP. Organization and polarity of actin filament networks in cells: implications for the mechanism of myosinbased cell motility. Biochem Socy Symp 1999;65:173-205.         

13. Pontieri GM. Patologia Generale (2 Ed.). Padova: Piccin; 1996. p. 888-94.         

14. Gumbiner BM. Regulation of cadherin-mediated adhesion in morphogenesis. Nat Rev Mol Cell Biol 2005;6:622-34.         

15. van Roy F, Berx G. The cell-cell adhesion molecule E-cadherin. Cell Mol Life Sci 2008;65:3756-88.         

16. Strumane K, Berx G, Van Roy F. Cadherins in cancer. In: Behrens J, Nelson J. (Eds.). Cell Adhesion vol. 165, Heidelberg: Springer-Verlag; 2004. p.69-103.         

17. Frixen UH, Behrens J, Sachs M, Eberle G, Voss B, Warda A, Lochner D, Birchmeier W. E-cadherin-mediated cell-cell adhesion prevents invasiveness of human carcinoma cells. J Cell Biol 1991;113:173-85.         

18. Vleminckx K, Vakaet L Jr, Mareel M, Fiers W, van Roy F. Genetic manipulation of E-cadherin expression by epithelial tumor cells reveals an invasion suppressor role. Cell 1991;66:107-19.         

19. Perl AK, Wilgenbus P, Dahl U, Semb H, Christofori G. A causal role for E-cadherin in the transition from adenoma to carcinoma. Nature 1998;392:190-3.         

20. Hemler ME. VLA proteins in the integrin family: structures, functions, and their role on leukocytes. Annu Rev Immunol 1990;8:365-400.         

21. Leitinger B, Hohenester E. Mammalian collagen receptors. Matrix Biol 2007;26:146-55.         

22. Caswell P, Norman J. Endocytic transport of integrins during cell migration and invasion. Trends Cell Biol 2008;18:257-63.         

23. Gilcrease MZ, Truong L, Brown RW. Correlation of very late activation integrin and CD44 expression with extrarenal invasion and metastasis of renal cell carcinomas. Hum Pathol 1996;27:1355-60.         

24. Hynes RO. Integrin: bidirectional, allosteric signaling machines. Cell 2002;110:673-87.         

25. Chammas R, Brentani R. Integrins and metastases: an overview. Tumour Biol 1991;12:309-20.         

26. Burridge K, Fath K, Kelly T, Nuckolls G, Turner C. Focal adhesions: transmembrane junctions between the extracellular matrix and the cytoskeleton. Annu Rev Cell Biol 1988; 4:487-525.         

27. Albeda SM. Role of integrins and other cell adhesion molecules in tumor progression and metastasis. Lab Invest 1993; 68:4-17.         

28. Hogg N, Landis RC. Adhesion molecules in cell interactions. Curr Opin Immunol 1993;5:383-90.         

29. Ruoslahti E, Giancotti FG. Integrins and tumor cell dissemination. Cancer Cells 1989;1:119-26.         

30. Shimizu Y, Shaw S. Lymphocyte interactions with extracellular matrix. Faseb J 1991;5:2292-9.         

31. Ferguson TA, Mizutani H, Kupper TS. Two integrin-binding peptides abrogate T-cell-mediated immune responses in vivo. Proc Natl Acad Sci USA 1991;88:8072-6.         

32. Screaton GR, Bell MV, Jackson DG, Cornelis FB, Gerth U, Bell JI. Genomic structure of DNA encoding the lynphocyte homing receptor CD44 reveals at least 12 alternatively spliced exons. Proc Natl Acad Sci USA 1992;89:12160-4.         

33. Gunthert U, Hofmann M, Rudy W, Reber S, Zoller M, Haussmann I, Matzku S, Wenzel A, Ponta H, Herrlich P. A new variant of glycoprotein CD44 confers metastatic potential to rat carcinoma cells. Cell 1991;65:13-24.         

34. Naor D, Sionov RV, Ish-Shalom D. CD44: structure, function, and association with the malignant process. Adv Cancer Res 1997;71:241-319.         

35. Nagano O, Saya H. Mechanism and biological significance of CD44 cleavage. Cancer Sci 2004;95:930-5.         

36. Santini MT, Rainaldi G, Ferrante A, Indovina P, Donelli G, Indovina PL. A 50 Hz sinusoidal magnetic field does not damage MG-63 three-dimensional tumor spheroids but induces changes in their invasive properties. Bioelectromagnetics 2006; 27:132-41.         

37. Legg JW, Isacke CM. Identification and functional analysis in the ezrin-binding site in the hyaluronan receptor, CD44. Curr Biol 1998;8:705-8.         

38. Yonemura S, Hirao M, Doi Y, Takahashi N, Kondo T, Tsukita S, Tsukita S. Ezrin/radixin/moesin (ERM) proteins bind to a positively charged amino acid cluster in the juxta-membrane cytoplasmic domain of CD44, CD43, and ICAM-2. J Cell Biol 1998;140:885-95.         

39. Bourguignon LY, Zhu H, Shao L, Zhu D, Chen YW. Rhokinase (ROK) promotes CD44v (3,8-10)-ankyrin interaction and tumor cell migration in metastatic breast cancer cells. Cell Motil Cytoskeleton 1999;43:269-87.         

40. Bretscher A, Edwards K, Fehon RG. ERM proteins and merlin: integrators at the cell cortex. Nat Rev Mol Cell Biol 2002;3:586-99.         

41. Gautreau A, Louvard D, Arpin M. ERM proteins and NF2 tumor suppressor: the Yin and Yang of cortical actin organization and cell growth signaling. Curr Opin Cell Biol 2002;14:104-9.         

42. Zamir E, Katz M, Posen Y, Erez N, Yamada KM, Katz BZ, Lin S, Lin DC, Bershadsky A, Kam Z, Geiger B. Dynamics and segregation of cell-matrix adhesions in cultured fibroblasts. Nat Cell Biol 2000;2:191-6.         

43. Zamir E, Geiger B. Components of cell-matrix adhesions. J Cell Sci 2001;114:3577-9.         

44. Degani S, Balzac F, Brancaccio M, Guazzone S, Retta SF, Silengo L, Eva A, Tarone G. The integrin cytoplasmic domain-associated protein ICAP-1 binds and regulates Rho family GTPases during cell spreading. J Cell Biol 2002; 156:377-88.         

45. Schwartz MA, Shattil SJ. Signaling networks linking integrins and rho family GTPases. Trends Biochem Sci 2000; 25:388-91.         

46. Aberle H, Bauer A, Stappert J, Kispert A, Kemler R. Betacatenin is a target for the ubiquitin-proteasome pathway. EMBO J 1997;16:3797-804.         

47. Bhatt A, Kaverina I, Otey C, Huttenlocher A. Regulation of focal complex composition and disassembly by the calcium-dependent protease calpain. J Cell Sci 2002;115:3415-25.         

48. Franco SJ, Huttenlocher A. Regulating cell migration: calpains make the cut. J Cell Sci 2005;118:3829-38.         

49. Friedl P, Wolf K. Tumor-cell invasion and migration: diversity and escape mechanisms. Nat Rev Caner 2003;3:362-74.         

50. Polte TR, Eichler GS, Wang N, Ingber DE. Extracellular matrix controls myosin light chain phosphorylation and cell contractility through modulation of cell shape and cytoskeletal prestress. Am J Physiol Cell Physiol 2004;286:C518-28.         

51. Palecek SP, Loftus JC, Ginsberg MH, Lauffenburger DA, Horwitz AF. Integrin-ligand binding properties govern cell migration speed through cell-substratum adhesiveness. Nature 1997;385:537-40.         

52. Ballestrem C, Hinz B, Imhof BA. Wehrle-Haller B. Marching at the front and dragging behind: differential alphaVbeta3-integrin turnover regulates focal adhesion behavior. J Cell Biol 2001;155:1319-32.         

53. Hall A. Ras-related GTPases and the cytoskeleton. Mol Biol Cell 1992;3:475-9.         

54. Fukata Y, Kaibuchi K, Amano M, Kaibichi K. Rho-Rhokinase pathway in smooth muscle contraction and cytoskeletal reorganization of non-muscle cells. Trends Pharmacol Sci 2001;22:32-9.         

55. Riento K, Ridley AJ. Rocks: multifunctional kinases in cell behaviour. Nat Rev Mol Cell Biol 2003;4:446-56.         

56. Vasiliev JM. Cytoskeletal mechanism responsible for invasive migration of neoplastic cells. Int J Dev Biol 2004;48:425-39.         

57. Geiger B, Bershadsky A. Exploring the neighborhood: adhesion-coupled cell mechanosensors. Cell 2002;110:139-42.         

58. Katoh K, Kano Y, Amano M, Onishi H, Kaibuchi K, Fujiwara K. Rho-kinase-mediated contraction of isolated stress fibers. J Cell Biol 2001;153:560-84.         

59. Chew TL, Wolf WA, Gallagher PJ, Matsumura F, Chisholm RL. A fluorescent resonant energy transfer-based biosensor reveals transient and regional myosin light chain kinase activation in lamella and cleavage furrows J Cell Biol 2002;156:543-53.         

60. Totsukawa G, Wu Y, Sasaki Y, Hartshorne DJ, Yamakita Y, Yamashiro S, Matsumura F. Distinct roles of MLCK and ROCK in the regulation of membrane protrusions and focal adhesion dynamics during cell migration of fibroblasts. J Cell Biol 2004;164:427-39.         

61. Somlyo AV, Phelps C, Dipierro C, Eto M, Read P, Barrett M, Gibson JJ, Burnitz MC, Myers C, Somlyo AP. Rho kinase and matrix metalloproteinase inhibitors cooperate to inhibit angiogenesis and growth of human prostate cancer xenotransplants. Faseb J 2003;17:223-34.         

62. Geho DH, Bandle RW, Clair T, Liotta AL. Physiological mechanism of tumor-cell invasion and migration. Physiology 2005;20:194-200.         

63. Stylli SS, Kaye AH, Lock P. Invadopodia: at the cutting edge of tumor invasion. J Clin Neurosci 2008;15:725-37.         

64. Chen WT. Proteolytic activity of specialized surface protrusions formed at rosette contact sites of transformed cells. J Exp Zool 1989;251:167-85.         

65. Kelly T, Yan Y, Osborne RL, Athota AB, Rozypal TL, Colclasure JC, Chu WS. Proteolysis of extracellular matrix by invadopodia facilitates human breast cancer cell invasion and is mediated by matrix metalloproteinases. Clin Exp Metastasis 1998;16:501-12.         

66. Tarone G, Cirillo D, Giancotti FG, Comoglio PM, Marchisio PC. Rous sarcoma virus-transformed fibroblasts adhere primarily at discrete protrusions of the ventral membrane called podosomes. Exp Cell Res 1985;159:141-57.         

67. Chen WT, Lee CC, Goldstein L, Bernier S, Liu CH, Lin CY, Yeh Y, Monsky WL, Kelly T, Dai M. Zhou J-Y, Mueller SC. Membrane proteases as potential diagnostic and therapeutic targets for breast malignancy. Breast Cancer Res Treat 1994;31:217-26.         

68. Buccione R, Orth JD, McNiven MA. Foot and mouth: podosomes, invadopodia and circular dorsal ruffles. Nat Rev Mol Cell Biol 2004;5:647-57.         

69. Linder S. The matrix corroded: podosomes and invadopodia in extracellular matrix degradation. Trends Cell Biol 2007;17:107-17.         

70. Artym VV, Zhang Y, Seillier-Moiseiwitsch, F, Yamada KM, Mueller SC. Dynamic interactions of cortactin and membrane type 1 matrix metalloproteinase at invadopodia: defining the stages of invadopodia formation and function. Cancer Res 2006;66:3034-43.         

71. Lorenz M, Yamaguchi H, Wang Y, Singer RH, Condeelis J. Imaging sites of N-wasp activity in lamellipodia and invadopodia of carcinoma cells. Curr Biol 2004;14:697:703.         

72. Clark ES, Whigham AS, Yarbrough WG, Weaver AM. Cortactin is an essential regulator of matrix metalloproteinase secretion and extracellular matrix degradation in invadopodia. Cancer Res 2007;67: 4227-35.         

73. Mizutani K, Miki H, He H, Maruta H, Takenawa T. Essential role of neural Wiskott-Aldrich syndrome protein in podosome formation and degradation of extracellular matrix in src-transformed fibroblasts. Cancer Res 2002;62:669-74.         

74. Bowden ET, Barth M, Thomas D, Glazer RI, Mueller SC. An invasion-related complex of cortactin, paxillin and PKCmu associates with invadopodia at sites of extracellular matrix degradation. Oncogene 1999;5:4440-9.         

75. Yamaguchi H, Lorenz M, Kempiak S, Sarmiento C, Coniglio S, Symons M, Segall J, Eddy R, Miki H, Takenawa T, Condeelis J. Molecular mechanisms of invadopodium formation: the role of the N-WASP-Arp2/3 complex pathway and cofilin. J Cell Biol 2005;168:441-52.         

76. Onodera Y, Hashimoto S, Hashimoto A, Morishige M, Mazaki Y, Yamada A, Ogawa E, Adachi M, Sakurai T, Manabe T, Wada H, Matsuura N, Sabe H. Expression of AMAP1, an ArfGAP, provides novel targets to inhibit breast cancer invasive activities. EMBO J 2005;24:963-73.         

77. Seals DF, Azucena EF Jr, Pass I, Tesfay L, Gordon R, Woodrow M, Resau JH, Courtneidge SA. The adaptor protein Tks5/Fish is required for podosome formation and function, and for the protease-driven invasion of cancer cells. Cancer Cell 2005;7:155-65.         

78. Stetler-Stevenson WG, Aznavoorian S, Liotta LA. Tumor cell interactions with the exstracellular matrix during invasion and metastasis. Annu Rev Cell Biol, 1993; 9:541-73.         

79. Nagase H, Woessner JFJr. Matrix metalloproteinase. J Biol Chem 1999;274:21491-4.         

80. Ravanti L, Kahari VM. Matrix metalloproteinases in wound repair. Int J Mol Med 2000;6:391-407.         

81. Curran S, Murray GI. Matrix metalloproteinases: molecular aspects of their roles in tumour invasion and metastasis. Eur J Cancer 2000;36:1621-30.         

82. Sato H, Takino T, Okada Y, Cao J, Shinagawa A, Yamamoto E, Seiki M. A matrix metalloproteinase expressed on the surface of invasive tumour cells. Nature 1994;370:61-5.         

83. Kojima S, Itoh Y, Matsumoto S, Masuho Y, Seiki M. Membrane-type 6 matrix metalloproteinase (MT6-MMP, MMP-25) is the second glycosyl-phosphatidyl inositol (GPI)-anchored MMP. FEBS Lett 2000;480:142-6.         

84. Birkedal-Hansen H, Moore WG, Bodden MK, Windsor LJ, Birkedal-Hansen B, DeCarlo A, Engler JA. Matrix metalloproteinases: a review. Crit Rev Oral Biol Med 1993;4:197-250.         

85. Westermarck J, Kahari, VM. Regulation of matrix metalloproteinase expression in tumour invasion. FASEB J 1999; 13:781-92.         

86. Nagase H. Activation mechanisms of matrix metalloproteinases. Biol Chem 1997;378:151-160.         

87. Sato H, Kinoshita T, Takino T, Nakayama K, Seiki M. Activation of a recombinant membrane type 1-matrix metalloproteinase (MT1-MMP) by furin and its interaction with tissue inhibitor of metalloproteinases (TIMP)-2. FEBS Lett 1996;393:101-4.         

88. Gomez DE, Alonso DF, Yoshiji H, Thorgeirsson UP. Tissue inhibitors of metalloproteinases: structure, regulation and biological functions. Eur J Cell Biol 1997;74:111-22.         

89. Strongin AY, Collier I, Bannikov G, Marmer BL, Grant GA, Goldberg GI. Mechanism of cell surface activation of 72-kDa type IV collagenase. Isolation of the activated form of the membrane metalloprotease. J Biol Chem 1995;270:5331-8.         

90. Coussens LM, Werb Z. Matrix metalloproteinases and the development of cancer. Chem Biol 1996;3:895-904.         

91. Johnson GL, Lapadat R. Mitogen-activated protein kinase pathways mediated by ERK, JNK, and p38 protein kinases. Science 2002;298:1911-2.         

92. Fu P, Jiang X, Arcasoy MO. Constitutively active erythropoietin receptor expression in breast cancer cells promotes cellular proliferation and migration through a MAP-kinase dependent pathway. Biochem Biophys Res Commun 2009; 379:696-701.         

93. Webb DJ, Nguyen DH, Gonias SL. Extracellular signal-regulated kinase functions in the urokinase receptor-dependent pathway by which neutralization of low density lipoprotein receptor-related protein promotes fibrosarcoma cell migration and matrigel invasion. J Cell Sci 2000;113:123-34.         

94. Lai CF, Chaudhary L, Fausto A, Halstead LR, Ory DS, Avioli LV, Cheng SL. ERK is essential for growth, differentiation, integrin expression, and cell function in human osteoblastic cells. J Biol Chem 2001;276:14443-50.         

95. Cuevas BD, Abell AN, Witowsky JA, Yujiri T, Johnson NL, Kesavan K, Ware M, Jones PL, Weed SA, DeBiasi RL, Oka Y, Tyler KL, Johnson GL. MEKK1 regulates calpain-dependent proteolysis of focal adhesion proteins for rear-end detachment of migrating fibroblasts. EMBO J 2003;22:3346-55.         

96. Klemke RL, Cai S, Giannini AL, Gallagher PJ, de Lanerolle P, Cheresh DA. Regulation of cell motility by mitogen-activated protein kinase. J Cell Biol 1997;137:481-92.         

97. Liu ZX, Yu CF, Nickel C, Thomas S, Cantley LG. Hepatocyte growth factor induces ERK-dependent paxillin phosphorylation and regulates paxillin-focal adhesion kinase association. J Biol Chem 2002;277:10452-8.         

98. Hunger-Glaser I, Salazar EP, Sinnett-Smith J, Rozengurt E. Bombesin, lysophosphatidic acid, and epidermal growth factor rapidly stimulate focal adhesion kinase phosphorylation at Ser-910: requirement for ERK activation. J Biol Chem 2003;278:22631-43.         

99. Glading A, Bodnar RJ, Reynolds IJ, Shiraha H, Satish L, Potter DA, Blair HC, Wells A. Epidermal growth factor activates m-calpain (calpain II), at least in part, by extracellular signal-regulated kinase-mediated phosphorylation. Mol Cell Biol 2004;24:2499-512.         

100. Webb DJ, Donais K, Whitmore LA, Thomas SM, Turner CE, Parsons JT, Horwitz AF. FAK-Src signalling through paxillin, ERK and MLCK regulates adhesion disassembly. Nat Cell Biol 2004;6:154-61.         

101. Allen MP, Linseman DA, Udo H, Xu M, Schaack JB, Varnum B, Kandel ER, Heidenreich KA, Wierman ME. Novel mechanism for gonadotropin-releasing hormone neuronal migration involving Gas6/Ark signaling to p38 mitogen-activated protein kinase. Mol Cell Biol 2002;22:599-613.         

102. Bakin AV, Rinehart C, Tomlinson AK, Arteaga CL. p38 mitogen-activated protein kinase is required for TGF beta-mediated fibroblastic transdifferentiation and cell migration. J Cell Sci 2002:115:3193-206.         

103. Kotlyarov A, Yannoni Y, Fritz S, LaaB K, Telliez JB, Pitman D, Lin LL, Gaestel M. Distinct cellular functions of MK2. Mol Cell Biol 2002;22:4827-35.         

104. Sharma GD, He J, Bazan HE. p38 and ERK1/2 coordinate cellular migration and proliferation in epithelial wound healing: evidence of cross-talk activation between MAP-kinase cascades. J Biol Chem 2003;278:21989-97.         

105. Ono K, Han J. The p38 signal transduction pathway: activation and function. Cell Signal 2000;12:1-13.         

106. Hannigan MO, Zhan L, Ai Y, Kotlyarov A, Gaestel M, Huang CK. Abnormal migration phenotype of mitogen-activated protein kinase-activated protein kinase 2(-/-) neutrophils in Zigmond chambers containing formyl-methionyl-leucyl-phenylalanine gradients. J Immunol 2001;167:3953-61.         

107. Martin-Blanco E, Pastor-Pareja JC, Garcia-Bellido A. JNK and decapentaplegic signaling control adhesiveness and cytoskeleton dynamics during thorax closure in Drosophila. Proc Natl Acad Sci USA 2000;97:7888-93.         

108. Kaltschmidt JA, Lawrence N, Morel V, Balayo T, Garcia Fernandez B, Pelissier A, Jacinto A, Martinez Arias A. Planar polarity and actin dynamics in the epidermis of Drosophila. Nat Cell Biol 2002;4:937-44.         

109. Zhang L, Wang W, Hayashi Y, Jester JV, Birk DE, Gao M, Liu C-Y, Kao W.W-Y, Karin M, Xia Y. A role for MEK kinase 1 in TGF-B,/activin-induced epithelium movement and embryonic eyelid closure. EMBO J 2003;22:4443-54.         

110. Liang Y, McDonnell S, Clynes M. Examining the relationship between cancer invasion/metastasis and drug resistance. Curr Cancer Drug Targets 2002;2:257-77.         

111. Mattern J. Drug resistance in cancer: a multifactorial problem. Anticancer Res 2003;23:1769-72.         

112. Schadendordf D, Worm M, Algermissen B, Kohlmus CM, Czarnetzki BM. Chemosensitivity testing of human malignant melanoma. A retrospective analysis of clinical response and in vitro drug sensitivity. Cancer 1994;73:103-8.         

113. Kern MA, Helmbach H, Artuc M, Karmann D, Jurgovsky K, Schadendorf D. Human melanoma cell lines selected in vitro displaying various levels of drug resistance against cisplatin, fotemustine, vindesine or etoposide: modulation of proto-oncogene expression. Anticancer Res 1997;17:4359-70.         

114. Gottesman MM, Fojo T, Bates SE. Multridrug resistance in cancer: role of ATP-dependent transporters. Nat Rev Cancer 2002;2:48-58.         

115. Weinstein RS, Jakate SM, Dominguez JM, Lebovitz MD, Koukoulis GK, Kuszak JR, Klusens LF, Grogan TM, Saclarides TJ, Roninson IB, Coon JS. Relationship of the expression of the multidrug resistance gene product (P-glycoprotein) in human colon carcinoma to local tumor aggressiveness and lymph node metastasis. Cancer Res 1991; 51:2720-6.         

116. Scaddan PB, Dufresne MJ. Characterization of cysteine proteases and their endogenous inhibitors in MCF-7 and adriamycin-resistant MCF-7 human breast cancer cells. Invasion Metastasis 1993;13:301-13.         

117. Greene GF, Kitadai Y, Pettaway CA, von Eschenbach AC, Bucana CD, Fidler IJ. Correlation of metastasis-related gene expression with metastatic potential in human prostate carcinoma cells implanted in nude mice using an in situ messenger RNA hybridization technique. Am J Pathol 1997;150:1571-82.         

118. Bradley AL, Chapman WC, Wright JK, Marsh JW, Geevarghese S, Blair KT, Pinson CW. Surgical experience with hepatic colorectal metastasis. Am Surg 1999;65:560-6.         

119. Bj0rnland K, Lehne G, Johansen HT, Fodstad O, Rugstad HE, Aasen AO, Ree AH. Human hepatoma cells rich in P-glycoprotein display enhanced in vitro invasive properties compared to P-glycoprotein-poor hepatoma cells. Oncol Res 1998;10:255-62.         

120. Bates RC, Edwards NS, Burns GF, Fisher DE. A CD44 survival pathway triggers chemoresistance via lyn kinase and phosphoinositide 3-kinase/Akt in colon carcinoma cells. Cancer Res 2001;61:5275-3.         

121. Ohashi R, Takahashi F, Cui R, Yoshioka M, Gu T, Sasaki S, Tominaga S, Nishio K, Tominaga Tabane KK, Takahashi K. Interaction between CD44 and hyaluronate induces chemoresistance in non-small cell lung cancer cell. Cancer Lett 2007;252:225-34.         

122. Yang J-M, Xu Z, Wu H, Zhu H, Wu X, Hait WN. Overexpres-sion of extracellular matrix metalloproteinase inducer in multigrug resistant cancer cells. Mol Cancer Res 2003;1:420-7.         

123. Zhang F, Shi Y, Zhang L, Zhang B, Wei X, Yang Y, Wang R, Niu R. Epithelial-mesenchymal transition and the expression of Twist in MCF-7/ADR, human multidrug-resistant breast cancer cells. Chinese J Clin Oncol 2007;4:21-5.         

124. Ding S, Chamberlain M, McLaren A, Goh L, Duncan I, Wolf CR. Cross-talk between signalling pathways and the multidrug resistant protein MDR-1. Br J Cancer 2001;85:1175-4.         

125. Yang J-M, Vassil AD, Hait WN. Activation of phospholi-pase C induces the expression of the multidrug resistance (MDR1) through the Raf-MAPK pathway. Mol Pharmacol 2001;60:674-80.         

126. Grotegut S, Von Schweinitz D, Christofori G, Lehembre F. Hepatocyte growth factor induces cell scattering through MAPK/Egr-1-mediated upregulation of Snail. EMBO J 2006;25:3534-45.         

127. Li QQ, Wang WJ, Xu JD, Cao XX, Chen Q, Yang JM, Xu ZD. Up-regulation of CD147 and matrix metalloproteinase-2, -9 induced by P-glicoprotein substrates in multigrug resistant breast cancer cells. Cancer Sci 2007;98:1767-74.         

128. Birch M, Mitchell S, Hart IR. Isolation and characterization of human melanoma cell variants expressing high and low levels of CD44. Cancer Res 1991;51:6660-7.         

129. Bartolazzi A, Peach R, Aruffo A, Stamenkovic I. Interaction between CD44 and hyaluronate is directly implicated in the regulation of tumor development. J Exp Med 1994;180:53-66.         

130. Ponta H, Scherman L, Herrlich PA. CD44: from adesion molecules to signaling regulators. Nat Rev Mol Cell Biol 2003;4:33-45.         

131. Brambilla D, Fais S. The Janus-faced role of ezrin in ''linking'' cells to either normal or metastatic phenotype. Int J Cancer 2009;25:2239-45.         

132. Federici C, Brambilla D, Lozupone F, Matarrese P, de Milito A, Lugini L, Iessi E, Cecchetti S, Marino M, Perdicchio M, Logozzi M, Spada M, Malorni W, Fais S. Pleiotropic function of ezrin in human metastatic melanomas. Int J Cancer 2009;124:2804-12.         

133. Luciani F, Molinari A, Lozupone F, Calcabrini A, Lugini L, Stringaro A, Puddu P, Arancia G, Cianfriglia M, Fais S. P-glycoprotein-actin association through ERM family proteins: a role in P-glycoprotein function in human cells of lymphoid origin. Blood 2002;99:641-8.         

134. Miletti-Gonzàlez KE, Chen S, Muthukumaran N, Saglimbeni GN, Wu X, Yang J, Apolito K, Shih WJ, Hait WN, Rodriguez-Rodriguez L. The CD44 receptor interacts with P-glycoprotein to promote cell migration and invasion in cancer. Cancer Res 2005;65:6660-7.         

135. Colone M, Calcabrini A, Toccacieli L, Bozzuto G, Stringaro A, Gentile M, Cianfriglia M, Ciervo A, Caraglia M, Budillon A, Meo G , Arancia G and Molinari A. The multidrug transporter P-glycoprotein: a mediator of melanoma invasion? J Invest Dermatol 2008;128:957-71.         

136. Fais S, De Milito A, You H, Qin W. Targeting vacuolar H+-ATPases as a new strategy against cancer. Cancer Res 2007;67:10627-30.         

137. Lugini L, Matarrese P, Tinari A, Lozupone F, Federici C, Iessi E, Gentile M, Luciani F, Parmiani G, Rivoltini L, Malorni W, Fais S. Cannibalism of live lymphocytes by human metastatic but not primary melanoma cells. Cancer Res 2006;66:3629-38.         

138. Lozupone F, Perdicchio M, Brambilla D, Borghi M, Meschini S, Barca S, Marino ML, Logozzi M, Federici C, Iessi E, de Milito A, Fais S. The human homologue of Dictyostelium discoideum phg1A is expressed by human metastatic melanoma cells. EMBO Rep 2009;10:1348-54.         

 

 

Address for correspondence:
Agnese Molinari
Dipartimento di Tecnologie e Salute
Istituto Superiore di Sanità
Viale Regina Elena 299
00161 Rome, Italy
E-mail: agnese.molinari@iss.it

Received on 16 October 2009
Accepted on 14 January 2010

Istituto Superiore di Sanità Roma - Rome - Italy
E-mail: annali@iss.it