Spatial mapping of integrin interactions and dynamics during cell migration by image correlation microscopy.

Image correlation microscopy methodology was extended and used to determine retrospectively the density, dynamics and interactions of alpha5-integrin in migrating cells. Alpha5-integrin is present in submicroscopic clusters containing 3-4 integrins before it is discernibly organized. The integrin in nascent adhesions, as identified by the presence of paxillin, is approximately 1.4 times more concentrated, approximately 4.5 times more clustered and much less mobile than in surrounding regions. Thus, while integrins are clustered throughout the cell, they differ in nascent adhesions and appear to initiate adhesion formation, despite their lack of visible organization. In more mature adhesions where the integrin is visibly organized there are approximately 900 integrins microm(-2) (about fivefold higher than surrounding regions). Interestingly, alpha5-integrin and alpha-actinin, but not paxillin, reside in a complex throughout the cell, where they diffuse and flow together, even in regions where they are not organized. During adhesion disassembly some integrins diffuse away slowly, alpha-actinin undergoes a directed movement at speeds similar to actin retrograde flow (0.29 microm min(-1)), while all of the paxillin diffuses away rapidly.

The LD4 motif of paxillin regulates cell spreading and motility through an interaction with paxillin kinase linker (PKL).

The small GTPases of the Rho family are intimately involved in integrin-mediated changes in the actin cytoskeleton that accompany cell spreading and motility. The exact means by which the Rho family members elicit these changes is unclear. Here, we demonstrate that the interaction of paxillin via its LD4 motif with the putative ARF-GAP paxillin kinase linker (PKL) (Turner et al., 1999), is critically involved in the regulation of Rac-dependent changes in the actin cytoskeleton that accompany cell spreading and motility. Overexpression of a paxillin LD4 deletion mutant (paxillinDeltaLD4) in CHO.K1 fibroblasts caused the generation of multiple broad lamellipodia. These morphological changes were accompanied by an increase in cell protrusiveness and random motility, which correlated with prolonged activation of Rac. In contrast, directional motility was inhibited. These alterations in morphology and motility were dependent on a paxillin-PKL interaction. In cells overexpressing paxillinDeltaLD4 mutants, PKL localization to focal contacts was disrupted, whereas that of focal adhesion kinase (FAK) and vinculin was not. In addition, FAK activity during spreading was not compromised by deletion of the paxillin LD4 motif. Furthermore, overexpression of PKL mutants lacking the paxillin-binding site (PKLDeltaPBS2) induced phenotypic changes reminiscent of paxillinDeltaLD4 mutant cells. These data suggest that the paxillin association with PKL is essential for normal integrin-mediated cell spreading, and locomotion and that this interaction is necessary for the regulation of Rac activity during these events.

Differential dynamics of alpha 5 integrin, paxillin, and alpha-actinin during formation and disassembly of adhesions in migrating cells.

To investigate the mechanisms by which adhesions form and disperse in migrating cells, we expressed alpha 5 integrin, alpha-actinin, and paxillin as green fluorescent protein (GFP) fusions. All localized with their endogenous counterparts and did not perturb migration when expressed at moderate levels. alpha 5-GFP also rescued the adhesive defects in CHO B2 cells, which are alpha 5 integrin deficient. In ruffling cells, alpha 5-GFP and alpha-actinin--GFP localized prominently at the leading edge in membrane protrusions. Of the three GFP fusion proteins that we examined, paxillin was the first component to appear visibly organized in protrusive regions of the cell. When a new protrusion formed, the paxillin appeared to remodel from older to newer adhesions at the leading edge. alpha-Actinin subsequently entered adhesions, which translocated toward the cell center, and inhibited paxillin turnover. The new adhesions formed from small foci of alpha-actinin--GFP and paxillin-GFP, which grew in size. Subsequently, alpha 5 integrin entered the adhesions to form visible complexes, which served to stabilize the adhesions. alpha 5-GFP also resided in endocytic vesicles that emanated from the leading edge of protrusions. Integrin vesicles at the cell rear moved toward the cell body. As cells migrated, alpha 5 vesicles also moved from a perinuclear region to the base of the lamellipodium. The alpha 5 vesicles colocalized with transferrin receptor and FM 4-64 dye. After adhesions broke down in the rear, alpha 5-GFP was found in fibrous structures behind the cell, whereas alpha-actinin--GFP and paxillin-GFP moved up the lateral edge of retracting cells as organized structures and then dissipated.

The role of transient ERK2 signals in fibronectin- and insulin-mediated DNA synthesis.

Both the extracellular matrix and growth factors jointly regulate cell cycle progression via a complex network of signaling pathways. Applying quantitative assays and analysis, we demonstrate here that concurrent stimulation of Chinese hamster ovary (CHO) cells with fibronectin (Fn) and insulin elicits a DNA synthesis response that reveals a synergy far more complex than a simple additive enhancement of response magnitude. CHO cell adhesion to higher Fn density shifts the sensitivity of the DNA synthesis response to insulin concentration from smoothly graded to sharply 'switch-like' and dramatically decreases the insulin concentration required for half-maximal response by about 1000-fold. Conversely, treatment with insulin has a milder and less complex effect on the response to varying Fn concentrations. Governing this DNA synthesis response is a common requirement for a transient, cell area-independent extracellular signal-regulated kinase 2 (ERK2) signal. Moreover, we show that the time-integrated value of this 'pulse' signal provides an appropriate metric for quantifying the dependence of DNA synthesis on the degree of ERK2 activation. Indeed, in the absence of insulin, the adhesion-mediated response is linearly proportional to ERK2 activation over a broad range of stimulatory Fn and MEK inhibitor amounts. However, in the presence of both Fn and insulin, total integrated ERK2 activity (the sum of Fn- and insulin-mediated signals) no longer serves as a predictor of DNA synthesis, demonstrating that the signaling crosstalk underlying response synergism does not converge at ERK2 activation. Instead, adhesion to higher Fn density enhances insulin stimulation of DNA synthesis, not by increasing insulin-mediated ERK2 activation, but via parallel elevation of at least one other insulin-mediated signal such as IRS-1 phosphorylation.

Quantitative relationship among integrin-ligand binding, adhesion, and signaling via focal adhesion kinase and extracellular signal-regulated kinase 2.

Because integrin-mediated signals are transferred through a physical architecture and synergistic biochemical network whose properties are not well defined, quantitative relationships between extracellular integrin-ligand binding events and key intracellular responses are poorly understood. We begin to address this by quantifying integrin-mediated FAK and ERK2 responses in CHO cells for varied alpha(5)beta(1) expression level and substratum fibronectin density. Plating cells on fibronectin-coated surfaces initiated a transient, biphasic ERK2 response, the magnitude and kinetics of which depended on integrin-ligand binding properties. Whereas ERK2 activity initially increased with a rate proportional to integrin-ligand bond number for low fibronectin density, the desensitization rate was independent of integrin and fibronectin amount but proportional to the ERK2 activity level with an exponential decay constant of 0.3 (+/- 0.08) min(-1). Unlike the ERK2 activation time course, FAK phosphorylation followed a superficially disparate time course. However, analysis of the early kinetics of the two signals revealed them to be correlated. The initial rates of FAK and ERK2 signal generation exhibited similar dependence on fibronectin surface density, with both rates monotonically increasing with fibronectin amount until saturating at high fibronectin density. Because of this similar initial rate dependence on integrin-ligand bond formation, the disparity in their time courses is attributed to differences in feedback regulation of these signals. Whereas FAK phosphorylation increased to a steady-state level as new integrin-ligand bond formation continued during cell spreading, ERK2 activity was decoupled from the integrin-ligand stimulus and decayed back to a basal level. Accordingly, we propose different functional metrics for representing these two disparate dynamic signals: the steady-state tyrosine phosphorylation level for FAK and the integral of the pulse response for ERK2. These measures of FAK and ERK2 activity were found to correlate with short term cell-substratum adhesivity, indicating that signaling via FAK and ERK2 is proportional to the number of integrin-fibronectin bonds.

A rapid and sensitive quantitative kinase activity assay using a convenient 96-well format.

Activation of protein kinases in response to growth factor and extracellular matrix stimulation has been implicated in regulating a number of cell functions including differentiation, gene expression, migration, and proliferation. An improved quantitative assay for measuring protein kinase activity is crucial to the detailed study of this important category of signaling proteins and their role in regulating cell behavior. We describe a modified in vitro kinase activity assay that is both sensitive and quantitative. It offers several advantages when compared to the traditional immunoprecipitation/kinase assay: (i) high sensitivity that reduces the required amount of cell lysate by an order of magnitude, (ii) an immunoseparation technique utilizing antibody immobilization onto the surface of microtiter wells that replaces the cumbersome immunoprecipitation method, (iii) a 96-well plate configuration that eases handling of multiple samples and increases throughput of the assay, and (iv) the use of 96-well filter plates that greatly reduces radioactive liquid waste generation. While we implement this technique in a case study for measuring the activity of extracellular signal-regulated kinase 2 (ERK2), this assay can be extended to studying other protein kinases by using an appropriate antibody and in vitro substrate for the kinase of interest.

Kinetic model for integrin-mediated adhesion release during cell migration.

Under many circumstances, cell migration speed is limited by the rate of cell-substratum detachment at the cell rear. We have constructed a mathematical model to integrate how the biophysical and biochemical interactions between integrins, the cytoskeleton, and the matrix affect rear retraction and linkage dissociation mechanisms. Our model also examines how applied forces and integrin clustering affect retraction kinetics. The model predicts two distinct detachment phenotypes. In the first, detachment is extremely rapid, dominated by integrin extracellular-matrix dissociation, and it occurs at high forces or low adhesiveness. In the second, detachment is much slower, dominated by integrin-cytoskeleton dissociation, and it occurs at low forces or high adhesiveness. The amount of integrin extracted from the rear of the cell is an assay for the detachment phenotype. During rapid detachment cells leave little integrin on the substratum whereas during slow detachment a large fraction of integrin rips from the membrane. This model delineates parameters which can be exploited to regulate cell speed in each detachment regime. The model also offers an explanation as to why some cell types, such as leukocytes or keratocytes, are able to detach easily and move very quickly while other cell types, such as fibroblasts, tend to migrate more slowly and release many more integrins during detachment.

Quantitative changes in integrin and focal adhesion signaling regulate myoblast cell cycle withdrawal.

We previously demonstrated contrasting roles for integrin alpha subunits and their cytoplasmic domains in controlling cell cycle withdrawal and the onset of terminal differentiation (Sastry, S., M. Lakonishok, D. Thomas, J. Muschler, and A.F. Horwitz. 1996. J. Cell Biol. 133:169-184). Ectopic expression of the integrin alpha5 or alpha6A subunit in primary quail myoblasts either decreases or enhances the probability of cell cycle withdrawal, respectively. In this study, we addressed the mechanisms by which changes in integrin alpha subunit ratios regulate this decision. Ectopic expression of truncated alpha5 or alpha6A indicate that the alpha5 cytoplasmic domain is permissive for the proliferative pathway whereas the COOH-terminal 11 amino acids of alpha6A cytoplasmic domain inhibit proliferation and promote differentiation. The alpha5 and alpha6A cytoplasmic domains do not appear to initiate these signals directly, but instead regulate beta1 signaling. Ectopically expressed IL2R-alpha5 or IL2R-alpha6A have no detectable effect on the myoblast phenotype. However, ectopic expression of the beta1A integrin subunit or IL2R-beta1A, autonomously inhibits differentiation and maintains a proliferative state. Perturbing alpha5 or alpha6A ratios also significantly affects activation of beta1 integrin signaling pathways. Ectopic alpha5 expression enhances expression and activation of paxillin as well as mitogen-activated protein (MAP) kinase with little effect on focal adhesion kinase (FAK). In contrast, ectopic alpha6A expression suppresses FAK and MAP kinase activation with a lesser effect on paxillin. Ectopic expression of wild-type and mutant forms of FAK, paxillin, and MAP/erk kinase (MEK) confirm these correlations. These data demonstrate that (a) proliferative signaling (i.e., inhibition of cell cycle withdrawal and the onset of terminal differentiation) occurs through the beta1A subunit and is modulated by the alpha subunit cytoplasmic domains; (b) perturbing alpha subunit ratios alters paxillin expression and phosphorylation and FAK and MAP kinase activation; (c) quantitative changes in the level of adhesive signaling through integrins and focal adhesion components regulate the decision of myoblasts to withdraw from the cell cycle, in part via MAP kinase.

Identification of a domain on the integrin alpha5 subunit implicated in cell spreading and signaling.

The alpha5 beta1 integrin is a cell surface receptor for fibronectin implicated in several cellular activities including cell proliferation, differentiation, and migration. The primary site at which the alpha5 beta1 integrin interacts with fibronectin is the RGD (Arg-Gly-Asp) amino acid sequence. In general, the sites on the integrin alpha subunits involved in ligand binding are not well characterized. Based on previous cross-linking studies, sequence alignment, predicted conformation, and intron-exon boundaries, we identified a 144-residue region (positions 223-367) on the alpha5 subunit as a putative binding region and divided it into four subdomains named domains I, II, III, and IV. Chimeric receptors were prepared in which sequences on the alpha5 subunit were exchanged with the corresponding sequences on the alpha6 subunit, which is specific for laminin and does not bind via an RGD sequence. The mutated human alpha5 integrin gene was transfected into CHO B2 cells, which are deficient in alpha5 expression. Only chimeras of domain III or IV express on the cell surface. Both of these chimeras decreased the adhesion, spreading, focal adhesion assembly, and migration on fibronectin. The adhesion of the chimeric receptors to fibronectin remained sensitive to the RGD peptide, and antibodies that inhibit interaction with the fibronectin synergy site and RGD loop remain inhibitory for the chimeras, indicating that our chimeras do not inhibit binding to either the RGD or synergy sites. Finally, the affinity of soluble fibronectin to cells via the alpha5 beta1 receptor decreased only about 3-fold. This decrease is substantially less than the observed effects on migration and spreading, which were not altered by changes in substrate concentration. Thus, the alteration in binding sites does not easily account for the changes in cell spreading and focal adhesion assembly. The tyrosine phosphorylation and focal adhesion assembly that are seen when cells expressing the wild type alpha5 receptor adhere to fibronectin were inhibited in cells expressing the chimeric receptors. Therefore, our results suggest that the chimeras of these domains likely interrupt alpha5-mediated conformational signaling.

Immunopurification of a sarcomeric junctional protein complex containing GAPDH.

We have isolated a monoclonal antibody, P4B2, which localizes to multiple anchorage junctions, namely, a subset of focal adhesions, the Z-disk of muscle, and neuromuscular junctions. Immunopurification of the antigen to this antibody from chicken brain tissue yielded a complex of three prominent proteins with mobilities of 36, 30, and 18 kDa. Amino acid sequencing of the purified proteins identified the 36-kDa protein as glyceraldehyde-3-phosphate dehydrogenase (GAPDH). The other two protein bands were heterogeneous, containing proteins found in the synaptic vesicle fusion core complex. Immunolocalization of P4B2 antigen in developing cultured muscle cells showed that the antigen is incorporated into Z-lines soon after the sarcomeric architecture was positive for alpha-actinin. Together, the data indicate the P4B2 antigen is part of a unique GAPDH-containing protein complex that may be involved in reinforcement of established cytoskeletal structures.

Physical and biochemical regulation of integrin release during rear detachment of migrating cells.

Cell migration can be considered as a repeated cycle of membrane protrusion and attachment, cytoskeletal contraction and rear detachment. At intermediate and high levels of cell-substratum adhesiveness, cell speed appears to be rate-limited by rear detachment, specifically by the disruption of cytoskeleton-adhesion receptor-extracellular matrix (ECM) linkages. Often, cytoskeletal linkages fracture to release integrin adhesion receptors from the cell. Cell-extracellular matrix bonds may also dissociate, allowing the integrins to remain with the cell. To investigate molecular mechanisms involved in fracturing these linkages and regulating cell speed, we have developed an experimental system to track integrins during the process of rear retraction in Chinese hamster ovary (CHO) cells. Integrin expression level was varied by transfecting CHO B2 cells, which express very little endogenous alpha5 integrin, with a plasmid containing human alpha5 integrin cDNA and sorting the cells into three populations with different alpha5 expression levels. Receptor/ligand affinity was varied using CHO cells transfected with either alphaIIbbeta3 or alphaIIbbeta3(beta1-2), a high affinity variant. alphaIIbbeta3(beta1-2) is activated to a higher affinity state with an anti-LIBS2 antibody. Fluorescent probes were conjugated to non-adhesion perturbing anti-integrin antibodies, which label integrins in CHO cells migrating on a matrix-coated glass coverslip. The rear retraction area was determined using phase contrast microscopy and integrins initially in this area were tracked by fluorescence microscopy and a cooled CCD camera. We find that rear retraction rate appears to limit cell speed at intermediate and high adhesiveness, but not at low adhesiveness. Upon rear retraction, the amount of integrin released from the cell increases as extracellular matrix concentration, receptor level and receptor-ligand affinity increase. In fact, integrin release is a constant function of cell-substratum adhesiveness and the number of cell-substratum bonds. In the adhesive regime where rear detachment limits the rate of cell migration, cell speed has an inverse relationship to the amount of integrin released at the rear of the cell. At high cell-substratum adhesiveness, calpain, a Ca2+-dependent protease, is also involved in release of cytoskeletal linkages during rear retraction. Inhibition of calpain results in decreased integrin release from the cell membrane, and consequently a decrease in cell speed, during migration. These observations suggest a model for rear retraction in which applied tension and calpain-mediated cytoskeletal linkage cleavage are required at high adhesiveness, but only applied tension is required at low adhesiveness.

Integrin and cadherin synergy regulates contact inhibition of migration and motile activity.

Integrin receptors play a central role in cell migration through their roles as adhesive receptors for both other cells and extracellular matrix components. In this study, we demonstrate that integrin and cadherin receptors coordinately regulate contact-mediated inhibition of cell migration. In addition to promoting proliferation (Sastry, S., M. Lakonishok, D. Thomas, J. Muschler, and A. Horwitz. 1996. J. Cell Biol. 133:169-184), ectopic expression of the alpha5 integrin in cultures of primary quail myoblasts promotes a striking contact-mediated inhibition of cell migration. Myoblasts ectopically expressing alpha5 integrin (alpha5 myoblasts) move normally when not in contact, but upon contact, they show inhibition of migration and motile activity (i.e., extension and retraction of membrane protrusions). As a consequence, these cells tend to grow in aggregates and do not migrate to close a wound. This phenotype is also seen with ectopic expression of beta1 integrin, paxillin, or activated FAK (CD2 FAK) and therefore appears to result from enhanced integrin-mediated signaling. The contact inhibition observed in the alpha5 myoblasts is mediated by N-cadherin, whose expression is upregulated more than fivefold. Perturbation studies using low calcium conditions, antibody inhibition, and ectopic expression of wild-type and mutant N-cadherins all implicate N-cadherin in the contact inhibition of migration. Ectopic expression of N-cadherin also produces cells that show inhibited migration upon contact; however, they do not show suppressed motile activity, suggesting that integrins and cadherins coordinately regulate motile activity. These observations have potential importance to normal and pathologic processes during embryonic development and tumor metastasis.

Integrin-ligand binding properties govern cell migration speed through cell-substratum adhesiveness.

Migration of cells in higher organisms is mediated by adhesion receptors, such as integrins, that link the cell to extracellular-matrix ligands, transmitting forces and signals necessary for locomotion. Whether cells will migrate or not on a given substratum, and also their speed, depends on several variables related to integrin-ligand interactions, including ligand levels, integrin levels, and integrin-ligand binding affinities. These and other factors affect the way molecular systems integrate to effect and regulate cell migration. Here we show that changes in cell migration speed resulting from three separate variables-substratum ligand level, cell integrin expression level, and integrin-ligand binding affinity-are all quantitatively predictable through the changes they cause in a single unifying parameter: short-term cell-substratum adhesion strength. This finding is consistent with predictions of a mathematical model for cell migration. The ligand concentration promoting maximum migration speed decreases reciprocally as integrin expression increases. Increases in integrin-ligand affinity similarly result in maximal migration at reciprocally lower ligand concentrations. The maximum speed attainable, however, remains unchanged as ligand concentration, integrin expression, or integrin-ligand affinity vary, suggesting that integrin coupling with intracellular motors remains unaltered.

Regulation of cell migration by the calcium-dependent protease calpain.

Integrin receptors play an important role during cell migration by mediating linkages and transmitting forces between the extracellular matrix and the actin cytoskeleton. The mechanisms by which these linkages are regulated and released during migration are not well understood. We show here that cell-permeable inhibitors of the calcium-dependent protease calpain inhibit both beta1 and beta3 integrin-mediated cell migration. Calpain inhibition specifically stabilizes peripheral focal adhesions, increases adhesiveness, and decreases the rate of cell detachment. Furthermore, these inhibitors alter the fate of integrin receptors at the rear of the cell during migration. A Chinese hamster ovary cell line expressing low levels of calpain I also shows reduced migration rates with similar morphological changes, further implicating calpain in this process. Taken together, the data suggest that calpain inhibition modulates cell migration by stabilizing cytoskeletal linkages and decreasing the rate of retraction of the cell's rear. Inhibiting calpain-mediated proteolysis may therefore be a potential therapeutic approach to control pathological cell migration such as tumor metastasis.

Modulation of cell migration by integrin-mediated cytoskeletal linkages and ligand-binding affinity.

Integrin cell surface adhesion receptors play a central role in mediating cell migration. We have developed a model system consisting of CHO cells ectopically expressing the alpha IIb beta 3 integrin to study integrin affinity and cytoskeletal interactions during cell migration. The alpha IIb beta 3 integrins are suited for study of integrin receptors during cell migration because they are well characterized with respect to ligand binding, cytoskeletal interactions, and signal transduction, and mutants with altered receptor function are available. The alpha IIb beta 3 receptor specifically mediates migration of alpha IIb beta 3-transfected CHO cells. The migration of transfected CHO cells was studied on a fibrinogen substrate both by time lapse videomicroscopy and by random and haptotactic transwell assays. Haptotactic and random transwell assays measured distinct aspects of migration, with the random transwell assay correlating most closely with time lapse videomicroscopy. Mutations in the cytoplasmic domains that increase ligand affinity or activation of the alpha IIb beta 3 receptor into a high affinity state by the LIBS6 antibody decreased the migration rate. Likewise, mutations that increase cytoskeletal organization without affecting affinity also decreased the migration rate. In contrast, truncation of the beta chain, which alters cytoskeletal associations as assayed by absence of focal adhesions, decreased haptotactic migration while increasing random migration. These effects on the migration rate were partially compensated for by altering substrate concentration, demonstrating optimum substrate concentrations that supported maximal migration. For example, cells expressing integrins locked in the high affinity state showed maximal migration at lower substrate concentrations than cells expressing low affinity receptor. Together, these results implicate the strength of adhesion between cell and substrate, as modulated by receptor affinity, organization of adhesive complexes, and substrate concentration, as important regulators of cell migration rate. Further, we demonstrate a dominant effect of high affinity integrin in inhibiting migration regardless of the organization of adhesive complexes. These observations have potential implications for tumor metastasis and its therapy.

Integrin dynamics on the tail region of migrating fibroblasts.

Cell migration is a complex process that can be considered as a repeated cycle of lamellipod extension and attachment, cytoskeletal contraction, and tail detachment. While lamellipodial and cytoskeletal phenomena are currently the focus of considerable research on cell migration, under many conditions locomotion appears to be rate-limited by events at the cell rear, especially release of cell/substratum adhesions. To study the mechanism of tail detachment, we have developed a novel experimental system that permits observation of integrin dynamics on the ventral surface of migrating fibroblasts. Photoactivatable caged fluorescein is coupled to a non-adhesion-perturbing anti-avian-beta 1 integrin subunit antibody, which labels integrins on chicken fibroblasts migrating on a laminin-coated glass coverslip. Ultraviolet light is focused through a pinhole to photoactivate the caged fluorophore in a 10-micron-diameter spot at the rear of a polarized cell. The fate of integrins initially present in this spot is monitored using a cooled CCD camera to follow the movement of fluorescent intensity as a function of time over a 2 to 3 hour period. We find that a substantial fraction of the integrins is left behind on the substratum as the cell detaches and locomotes, while another fraction collects into vesicles which are transported along the cell body as the cell migrates. As aggregates rip from the cell membrane, the integrin-cytoskeletal bonds are preferentially fractured resulting in 81 +/- 15% of the integrin remaining attached to the substratum. We additionally find that adhesions sometimes disperse into integrins which can form new adhesions at other locations in the cell. Adhesions along the cell edge can release from the substrate and translocate with the cell. They either disperse in the cell membrane, rip from the cell membrane and remain attached to the substratum, or form a new aggregate. These observations indicate that the behavior of integrins at the cell rear is much more dynamic than previously appreciated, suggesting that an important locus for regulation of motility may reside in this region.

Integrin alpha subunit ratios, cytoplasmic domains, and growth factor synergy regulate muscle proliferation and differentiation.

The role of integrins in muscle differentiation was addressed by ectopic expression of integrin alpha subunits in primary quail skeletal muscle, a culture system particularly amenable to efficient transfection and expression of exogenous genes. Ectopic expression of either the human alpha5 subunit or the chicken alpha6 subunit produced contrasting phenotypes. The alpha5-transfected myoblasts remain in the proliferative phase and are differentiation inhibited even in confluent cultures. In contrast, myoblasts that overexpress the alpha6 subunit exhibit inhibited proliferation and substantial differentiation. Antisense suppression of endogenous quail alpha6 expression inhibits myoblast differentiation resulting in sustained proliferation. These effects of ectopic alpha subunit expression are mediated, to a large extent, by the cytoplasmic domains. Ectopic expression of chimeric alpha subunits, alpha5ex/6cyto and alpha6ex/5cyto, produced phenotypes opposite to those observed with ectopic alpha5 or alpha6 expression. Myoblasts that express alpha5ex/6cyto show decreased proliferation while differentiation is partially restored. In contrast, the alpha6ex/5cyto transfectants remain in the proliferative phase unless allowed to become confluent for at least 24 h. Furthermore, expression of human alpha5 subunit cytoplasmic domain truncations, before and after the conserved GFFKR motif, shows that this sequence is important in alpha5 regulation of differentiation. Ectopic alpha5 and alpha6 expression also results in contrasting responses to the mitogenic effects of serum growth factors. Myoblasts expressing the human alpha5 subunit differentiate only in the absence of serum while differentiation of untransfected and alpha6-transfected myoblasts is insensitive to serum concentration. Addition of individual, exogenous growth factors to alpha5-transfected myoblasts results in unique responses that differ from their effects on untransfected cells. Both bFGF or TGFbeta inhibit the serum-free differentiation of alpha5-transfected myoblasts, but differ in that bFGF stimulates proliferation whereas TGF-beta inhibits it. Insulin or TGF-alpha promote proliferation and differentiation of alpha5-transfected myoblasts; however, insulin alters myotube morphology. TGF-alpha or PDGF-BB enhance muscle alpha-actinin organization into myofibrils, which is impaired in differentiated alpha5 cultures. With the exception of TGF-alpha, these growth factor effects are not apparent in untransfected myoblasts. Finally, myoblast survival under serum-free conditions is enhanced by ectopic alpha5 expression only in the presence of bFGF and insulin while TGF-alpha and TGF-beta promote survival of untransfected myoblasts. Our observations demonstrate (1) a specificity for integrin alpha subunits in regulating myoblast proliferation and differentiation; (2) that the ratio of integrin expression can affect the decision to proliferate or differentiate; (3) a role for the alpha subunit cytoplasmic domain in mediating proliferative and differentiative signals; and (4) the regulation of proliferation, differentiation, cytoskeletal assembly, and cell survival depend critically on the expression levels of different integrins and the growth factor environment in which the cells reside.