Laminin-Binding Integrins and Their Tetraspanin Partners As Potential Antimetastatic Targets

Laminin-Binding Integrins and Their Tetraspanin Partners As Potential Antimetastatic Targets

expert reviews http://www.expertreviews.org/ in molecular medicine Laminin-binding integrins and their tetraspanin partners as potential antimetastatic targets Christopher S. Stipp Within the integrin family of cell adhesion receptors, integrins a3b1, a6b1, a6b4 and a7b1 make up a laminin-binding subfamily. The literature is divided on the role of these laminin-binding integrins in metastasis, with different studies indicating either pro- or antimetastatic functions. The opposing roles of the laminin-binding integrins in different settings might derive in part from their unusually robust associations with tetraspanin proteins. Tetraspanins organise integrins into multiprotein complexes within discrete plasma membrane domains termed tetraspanin-enriched microdomains (TEMs). TEM association is crucial to the strikingly rapid cell migration mediated by some of the laminin-binding as potential antimetastatic targets integrins. However, emerging data suggest that laminin-binding integrins also promote the stability of E-cadherin-based cell–cell junctions, and that tetraspanins are essential for this function as well. Thus, TEM association endows the laminin-binding integrins with both pro-invasive functions (rapid migration) and anti-invasive functions (stable cell junctions), and the composition of TEMs in different cell types might help determine the balance between these opposing activities. Unravelling the tetraspanin control mechanisms that regulate laminin-binding integrins will help to define the settings where inhibiting the function of these integrins would be helpful rather than harmful, and may create opportunities to modulate integrin activity in more sophisticated ways than simple functional blockade. Laminin-binding integrins and their tetraspanin partners Integrins, the major cellular receptors for proteins example, the b1 (ITGB1) subunit pairs with the of the extracellular matrix (ECM), are a1–a11 (ITGA1–11) subunits, as well as av heterodimers consisting of one a and one b (ITGAV). The resulting b1 integrins can be subunit. In mammals, eight b subunits and 18 a grouped by ligand-binding specificity. Integrins subunits combine to create 24 different a3b1, a6b1 and a7b1 bind laminin isoforms; heterodimers. Both the a and b subunits integrins a5b1, a8b1 and avb1 bind the Arg- contribute to ligand-binding specificity (Refs 1, Gly-Asp (RGD) motif found in fibronectin 2). While some integrin subunits pair with only (FN1) and other matrix proteins; integrins a4b1 one partner, others are promiscuous. For and a9b1 bind the Leu-Asp-Val (LDV) motif Departments of Biology and Molecular Physiology & Biophysics, 210 Iowa Avenue, BBE 236, University of Iowa, Iowa City, IA 52242, USA. E-mail: [email protected] 1 Accession information: doi:10.1017/S1462399409001355; Vol. 12; e3; January 2010 & Cambridge University Press 2010. Re-use permitted under a Creative Commons Licence – by-nc-sa. Downloaded from https://www.cambridge.org/core. IP address: 170.106.202.58, on 02 Oct 2021 at 18:43:15, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms. https://doi.org/10.1017/S1462399409001355 expert reviews http://www.expertreviews.org/ in molecular medicine also present in fibronectin and other matrix root ganglion and olfactory epithelial neurons proteins; and integrins a1b1, a2b1, a10b1 and both displayed preferential migration on a11b1 bind collagens (Refs 1, 2). Several of the laminin isoforms compared with other ECM collagen-binding integrins can also recognise proteins, such as collagens and fibronectin binding sites in certain laminin isoforms, but (Refs 5, 6). Moreover, as observed by interference for the purpose of this review, laminin-binding reflectance microscopy, neuronal cells made integrins refers to the subfamily containing the fewer and smaller close contacts with laminin related a3, a6 and a7 subunits. substrates than they did with fibronectin The data summarised above paint a complex substrates (Refs 6, 7). The organisation of focal picture in which many integrins recognise more adhesions – the cytoskeletal and signalling than one ligand and many ligands contain complexes that form at sites of integrin adhesion binding sites for more than one integrin. In to ECM – also appeared different on laminin: addition, they point to a conundrum regarding neurons formed prominent focal adhesions on the molecular basis of functional diversity fibronectin, but on laminin they formed smaller within specific classes of integrins. Upon ligand and less numerous focal-adhesion-like structures binding, different integrins transduce signals (Ref. 8). that differently influence cell survival, More recently,results similar to those described proliferation, cytoskeletal organisation, cell for neuronal cells have been obtained for tumour adhesion, and migration. Although a few and epithelial cells. Lung adenocarcinoma cells, cytoplasmic effectors have been identified that squamous carcinoma cells, and nontransformed interact with integrin a subunits, the substantial keratinocytes all migrated up to fivefold faster majority associate directly or indirectly with the on laminin isoforms than on other ECM ligands cytoplasmic tails of integrin b subunits (Refs 3, 4). such as fibronectin or collagen I (COL1A1) Thus, a question that arises for b1 integrins (Refs 9, 10, 11, 12). On fibronectin or collagen I, as potential antimetastatic targets is how so many different heterodimers, each cells formed large actin stress fibres and with a common b1 signalling subunit, are able prominent focal adhesions, while on laminins to mediate diverse cellular responses to fewer stress fibres and smaller, more-peripheral different ECM proteins. focal-adhesion-like structures (sometimes termed Here I review how the cell behaviours and ‘focal contacts’) were observed (Refs 9, 10, 11). signalling pathways mediated by the a3/a6/a7 Thus, data from both neuronal and tumour cell laminin-binding integrin subfamily differ from systems converge on the view that laminin- those mediated by other integrins, and discuss binding integrins frequently mediate distinct how these functional and cell biological cell behaviours typified by rapid migration, differences may relate to the unusual ability of smaller focal complexes, and fewer actin stress the laminin-binding integrins to interact with fibres. members of the tetraspanin family of proteins. In principle, the functional differences between The a6 subunit is further distinguished by its laminin-binding integrins and other integrins ability to pair with the b4 (ITGB4) subunit. The could result from differences in ligand-binding unique properties of a6b4 integrin, which affinities. However, the dissociation constants Laminin-binding integrins and their tetraspanin partners associates with tetraspanins as well, are also (Kds) of activated laminin-binding integrins for discussed in the review. Tetraspanin association different laminin isoforms are in the range of has significant implications not only for the 1–20 nM (Ref. 13), which is similar to the Kd complex roles the laminin-binding integrins of activated a5b1 for fibronectin (10 nM) play in metastasis but also for how these (Ref. 14), and the Kds of activated a1b1 and integrins might ultimately be targeted in a2b1 for collagen ligands (1–10 nM) (Ref. 15). anticancer therapies. Instead, it appears that laminin-binding integrins may signal differently than other Distinct cell responses mediated integrins. In lung adenocarcinoma cells, by laminin-binding integrins adhesion on fibronectin triggered strong Early recognition that cellular responses activation of the RhoA (RHOA) small GTPase, mediated by laminin-binding integrins might with little activation of the Rac1 (RAC1) small be different from those mediated by other GTPase (Ref. 9). Conversely a3b1-integrin- integrins came from studies of neurons. Dorsal dependent adhesion on laminin-10/11 (termed 2 Accession information: doi:10.1017/S1462399409001355; Vol. 12; e3; January 2010 & Cambridge University Press 2010. Re-use permitted under a Creative Commons Licence – by-nc-sa. Downloaded from https://www.cambridge.org/core. IP address: 170.106.202.58, on 02 Oct 2021 at 18:43:15, subject to the Cambridge Core terms of use, available at https://www.cambridge.org/core/terms. https://doi.org/10.1017/S1462399409001355 expert reviews http://www.expertreviews.org/ in molecular medicine laminin-511/521 when named according to its Potential roles of a3b1 integrin composition of a, b and g chains) triggered Rac in metastasis activation with very little concomitant RhoA Although several studies have identified a activation. In addition, focal adhesion kinase positive correlation between tumour cell (FAK/PTK2) activation was significantly higher expression of a3b1 integrin and propensity for in cells on fibronectin than in cells on laminin- metastasis, a roughly equal number of studies 10/11 or laminin-5 (laminin-332), while have reported negative correlations (Table 1). formation of the trimolecular complex of Moreover, in some cases, such as breast p130CAS (BCAR1), CrkII (CRK) and DOCK180 carcinoma and oral squamous cell carcinomas, (DOCK1), which promotes Rac1 activation and both positive and negative correlations have cell migration, was much higher on laminin been reported. These conflicting data suggest isoforms than on fibronectin (Ref. 9). Similarly, that the role of a3b1 integrin in metastasis may a3b1-integrin-dependent adhesion of squamous be highly dependent on context, even within carcinoma cells on

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