Expression of chicken integrin beta 1 subunit in rat PC12 cells

We transfected rat pheochromocytoma (PC12) cells with a cDNA encoding chicken integrin beta 1 subunit. The chicken integrin beta 1 subunit produced in stable transfectants associated with two major alpha subunits of rat integrins to form interspecific chimeric receptors. These receptors mediated cell spreading and initial neurite outgrowth on laminin as did corresponding endogenous integrins, although they were slightly less effective in inducing cell adhesion to laminin. These results indicate that chicken integrin beta 1 may functionally substitute for beta 1 subunit of rat integrins in PC12 cells. Apparently, the structure of the integrin beta 1 subunit is highly conserved in the evolution of these species.     

Expression and functional analysis of a cytoplasmic domain variant of the beta 1 integrin subunit

We have previously described a variant form of the integrin beta 1 subunit (beta 1B)1 characterized by an altered sequence at the cytoplasmic domain. Using polyclonal antibodies to a synthetic peptide corresponding to the unique sequence of the beta 1B, we analyzed the expression of this molecule in human tissues and cultured cells. Western blot analysis showed that the beta 1B is expressed in skin and liver and, in lower amounts, in skeletal and cardiac muscles. The protein was not detectable in brain, kidney, and smooth muscle. In vitro cultured keratinocytes and hepatoma cells are positive, but fibroblasts, endothelial cells, and smooth muscle cells are negative. An astrocytoma cell line derived from immortalized fetal astrocytes was found to express beta 1B. In these cells beta 1B represent integral of 30% of the beta 1 and form heterodimers with alpha 1 and alpha 5 subunits. To investigate the functional properties of beta 1B, the full- length cDNA coding for this molecule was transfected into CHO cells. Stable transfectants were selected and the beta 1B was identified by a mAb that discriminate between the transfected human protein and the endogenous hamster beta 1A. Immunoprecipitation experiments indicated that the beta 1B was exported at the cell surface in association with the endogenous hamster alpha subunits. The alpha 5/beta 1B complex bound to a fibronectin-affinity matrix and was specifically released by RGD-containing peptides. Thus beta 1B and beta 1A are similar as far as the alpha/beta association and fibronectin binding are concerned. The two proteins differ, however, in their subcellular localization. Immunofluorescence studies indicated, in fact, that beta 1B, in contrast to beta 1A, does not localize in focal adhesions. The restricted tissue distribution and the distinct subcellular localization, suggest that beta 1B has unique functional properties.     

Expression of integrin subunit beta1B in integrin beta1-deficient GD25 cells does not interfere with alphaVbeta3 functions

We have expressed the beta1B integrin subunit in beta1-deficient GD25 cells to examine beta1B functions without the interference of endogenous beta1A expression. As previously reported [Retta et al., 1998, Mol. Biol. Cell 9, 715-731], the beta1B integrins did not mediate cell adhesion under normal culture conditions, while the presence of 0.3 mM Mn(2+) allowed beta1B integrins to support adhesion. Mn(2+), as well as the small soluble peptide GRGDS, induced a beta1B conformation, which was recognized by the mAb 9EG7, a marker for active or ligand-bound integrins. beta1B integrins were found to localize to a subset of focal contacts in a ligand-independent manner on fibronectin, but not on vitronectin. However, clustering of beta1B did not induce tyrosine phosphorylation of FAK, p130(Cas), or paxillin, as studied by beta1B-mediated adhesion, to fibronectin in the presence of Mn(2+) or to anti-beta1 antibody in DMEM. Induction of ligand-occupied conformation by the GRGDS peptide during the adhesion to anti-beta1 antibody also failed to trigger FAK phosphorylation. Stimulation of tyrosine phosphorylation on FAK, p130(Cas), and paxillin by adhesion via integrin alphaVbeta3 to fibronectin or vitronectin was not disturbed in GD25-beta1B cells compared to the untransfected GD25 cells, nor were any negative effects of beta1B observed on alphaVbeta3-mediated cell attachment, spreading, and actin organization, or on the cell proliferation rate. These results show that the reported negative effects of beta1B on adhesive events do not apply to alphaVbeta3-dependent interactions and suggest that they may specifically act on beta1 integrins.     

An alternative form of the integrin beta 1 subunit with a variant cytoplasmic domain.

We have identified an alternatively spliced form of the human beta 1 integrin subunit, beta 1S. The beta 1S mRNA is expressed in human platelets, HEL and K562 erythroleukemia cell lines, and THP1 monocytic and HL60 promyelocytic cell lines. It is undetectable in peripheral blood lymphocytes and cultured umbilical vein endothelial cells at early passages. The beta 1S cDNA encodes a new cytoplasmic domain distinct from the previously reported alternative cytoplasmic domain of the beta 1 subunit. The sequence reveals the presence of an insert of 116 nucleotides which produces a frame shift in the previously reported 3' end of the beta 1 integrin subunit and codes for a unique 48-amino acid COOH-terminal sequence. An antiserum prepared against a synthetic peptide generated from the deduced sequence of the beta 1S cytoplasmic domain immunoprecipitated an HEL cell surface molecule that comigrated with the usual beta 1 subunit in sodium dodecyl sulfate electrophoresis. The immunoprecipitation indicated that beta 1S constitutes a minor portion of total beta 1 subunit in these cells. This variant beta 1 cytoplasmic tail may modulate integrin affinity and may provide additional modes for the transduction of extracellular signals and modulation of cytoskeletal organization by beta 1 integrins.     

Regulation of alpha 6 beta 1 integrin laminin receptor function by the cytoplasmic domain of the alpha 6 subunit

The alpha 6 beta 1 integrin is expressed on the macrophage surface in an inactive state and requires cellular activation with PMA or cytokines to function as a laminin receptor (Shaw, L. M., J. M. Messier, and A. M. Mercurio. 1990. J. Cell Biol. 110:2167-2174). In the present study, the role of the alpha 6 subunit cytoplasmic domain in alpha 6 beta 1 integrin activation was examined. The use of P388D1 cells, an alpha 6-integrin deficient macrophage cell line, facilitated this analysis because expression of either the alpha 6A or alpha 6B subunit cDNAs restores their activation responsive laminin adhesion (Shaw, L. S., M. Lotz, and A. M. Mercurio. 1993. J. Biol. Chem. 268:11401-11408). A truncated alpha 6 cDNA, alpha 6-delta CYT, was constructed in which the human cytoplasmic domain sequence was deleted after the GFFKR pentapeptide. Expression of this cDNA in P388D1 cells resulted in the surface expression of a chimeric alpha 6-delta CYT beta 1 integrin that was unable to mediate laminin adhesion or increase this adhesion in response to PMA under normal conditions, i.e., in medium that contained physiological concentrations of Ca++ and Mg++. The alpha 6A-delta CYT transfectants adhered to laminin, however, when Ca++/Mg++ was replaced with 150 microM Mn++. We also assessed the role of serine phosphorylation in the regulation of alpha 6A beta 1 integrin function by site-directed mutagenesis of the two serine residues present in the alpha 6A cytoplasmic domain because this domain is phosphorylated on serine residues in response to stimuli that activate the laminin receptor function of alpha 6 A beta 1. Point mutations were introduced in the alpha 6A cDNA that changed either serine residue #1064 (M1) or serine residue #1071 (M2) to alanine residues. In addition, a double mutant (M3) was constructed in which both serine residues were changed to alanine residues. P388D1 transfectants which expressed these serine mutations adhered to laminin in response to PMA to the same extent as cells transfected with wild-type alpha 6A cDNA. These findings provide evidence for a novel mode of integrin regulation that is distinct from that reported for other regulated integrins (O'Toole, T. E., D. Mandelman, J. Forsyth, S. J. Shattil, E. F. Plow, and M. H. Ginsberg. 1991. Science (Wash. DC). 254:845-847. Hibbs, M. L., H. Xu, S. A. Stacker, and T. A. Springer. 1991. Science (Wash. DC). 251:1611-1613), and they demonstrate that serine phosphorylation of the alpha 6A cytoplasmic domain is not involved in this regulation.     

The Talin head domain binds to integrin beta subunit cytoplasmic tails and regulates integrin activation.

The beta subunit cytoplasmic domains of integrin adhesion receptors are necessary for the connection of these receptors to the actin cytoskeleton. The cytoplasmic protein, talin, binds to beta integrin cytoplasmic tails and actin filaments, hence forming an integrin-cytoskeletal linkage. We used recombinant structural mimics of beta(1)A, beta(1)D and beta(3) integrin cytoplasmic tails to characterize integrin-binding sites within talin. Here we report that an integrin-binding site is localized within the N-terminal talin head domain. The binding of the talin head domain to integrin beta tails is specific in that it is abrogated by a single point mutation that disrupts integrin localization to talin-rich focal adhesions. Integrin-cytoskeletal interactions regulate integrin affinity for ligands (activation). Overexpression of a fragment of talin containing the head domain led to activation of integrin alpha(IIb)beta(3); activation was dependent on the presence of both the talin head domain and the integrin beta(3) cytoplasmic tail. The head domain of talin thus binds to integrins to form a link to the actin cytoskeleton and can thus regulate integrin function.     

The integrin beta1 subunit cytoplasmic tail forms oligomers: a potential role in beta1 integrin clustering

Integrins are alpha/beta heterodimeric cell surface receptors devoid of enzymatic activity. Signal transduction therefore requires the association of cytosolic and cytoskeletal proteins with the integrin subunit intracellular regions. This association is initiated upon ligand binding to the integrin receptor and includes clustering of the integrins and recruitment of focal adhesion-associated proteins. Whether integrin clustering is solely dependent on ligand binding to the integrin extracellular parts or involves also interactions between the intracellular tails of integrins is so far unknown. To investigate intracellular events in integrin clustering, we have used peptides corresponding to the integrin beta1 cytoplasmic region. Loading of cells with the peptides results in a decreased cell adhesion and in an inhibition of cell spreading in agreement with the previously reported dominant negative effect of the beta1 integrin cytoplasmic tail on integrin clustering. Direct protein-protein interaction studies by surface plasmon resonance demonstrate that integrin beta1 cytoplasmic peptides self-associate in contrast to integrin beta3 cytoplasmic tails. Size exclusion chromatography and SDS-PAGE analysis of the peptides further show that the integrin beta1 cytoplasmic parts form oligomers and that they assume alpha helical conformation to the extent of about 13% and that this fraction is increased upon aggregation. Thus self-association of the integrin beta1 subunit cytoplasmic regions may be central to beta1 integrin clustering.     

Phosphorylation of the beta1 integrin cytoplasmic domain: toward an understanding of function and mechanism

As F9 stem cells differentiate into parietal endoderm they form focal adhesion sites. There is a concomitant decrease in the level of phosphorylation of S785 in the cytoplasmic domain of the beta1 integrin subunit. Previous transfection studies demonstrate that site-specific mutations at this residue, mimicking different phosphorylation states, can alter the subcellular localization of the subunit in differentiating F9 cells. We now extend these observations in an attempt to substantiate the function of beta1 phosphorylation and determine how the phosphorylation levels are regulated. We show that treatment of parietal endoderm with okadaic acid induces an increase in beta1 phosphorylation and selective loss of beta1 from focal adhesion sites. Using a PCR approach, we identify two phosphatases expressed in parietal endoderm, including PP2A. Using a crosslinking approach, where antibodies are added to live cells, we show that the catalytic subunit of PP2A co-immunoprecipitates with beta1. Immunocytochemistry shows PP2A colocalizing to focal adhesion sites with beta1. In addition integrin-linked kinase (ILK) co-immunoprecipitates with beta1 in parietal endoderm and localizes to focal adhesion sites. Okadaic acid treatment significantly decreases the level of ILK associated with beta1. A possible role for regulated beta1 phosphorylation in cell migration is discussed.     

Calpain cleavage promotes talin binding to the beta 3 integrin cytoplasmic domain

Talin links integrin beta cytoplasmic domains to the actin cytoskeleton and is involved in the clustering and activation of these receptors. To understand how talin recognizes integrin beta cytoplasmic domains, we configured surface plasmon resonance methodology to measure the interaction of talin with the beta3 integrin cytoplasmic domain. Here we report that the N-terminal approximately 47-kDa talin head domain (talin-H) has a 6-fold higher binding affinity than intact talin for the beta3 tail. The affinity difference is mainly due to a difference in k(on). Calpain cleavage of intact talin released talin-H and resulted in a 16-fold increase in apparent K(a) and a 100-fold increase in apparent k(on). The increase in talin binding after cleavage was greater than predicted for stoichiometric liberation of free talin-H. This additional increase in binding was due to cooperative binding of talin-H and talin rod domain to the beta3 tail. Talin resembles ERM (ezrin, radixin, moesin) proteins in possessing an N-terminal FERM (band four-point-one, ezrin, radixin, moesin) domain. These data show that the talin FERM domain, like that in the ERM proteins, is masked in the intact molecule. Furthermore, they suggest that talin cleavage by calpain may contribute to the effects of the protease on the clustering and activation of integrins.     

The top of the inserted-like domain of the integrin lymphocyte function-associated antigen-1 beta subunit contacts the alpha subunit beta -propeller domain near beta-sheet 3

We find that monoclonal antibody YTA-1 recognizes an epitope formed by a combination of the integrin alpha(L) and beta(2) subunits of LFA-1. Using human/mouse chimeras of the alpha(L) and beta(2) subunits, we determined that YTA-1 binds to the predicted inserted (I)-like domain of the beta(2) subunit and the predicted beta-propeller domain of the alpha(L) subunit. Substitution into mouse LFA-1 of human residues Ser(302) and Arg(303) of the beta(2) subunit and Pro(78), Thr(79), Asp(80), Ile(365), and Asn(367) of the alpha(L) subunit is sufficient to completely reconstitute YTA-1 reactivity. Antibodies that bind to epitopes that are nearby in models of the I-like and beta-propeller domains compete with YTA-1 monoclonal antibody for binding. The predicted beta-propeller domain of integrin alpha subunits contains seven beta-sheets arranged like blades of a propeller around a pseudosymmetry axis. The antigenic residues cluster on the bottom of this domain in the 1-2 loop of blade 2, and on the side of the domain in beta-strand 4 of blade 3. The I domain is inserted between these blades on the top of the beta-propeller domain. The antigenic residues in the beta subunit localize to the top of the I-like domain near the putative Mg(2+) ion binding site. Thus, the I-like domain contacts the bottom or side of the beta-propeller domain near beta-sheets 2 and 3. YTA-1 preferentially reacts with activated LFA-1 and is a function-blocking antibody, suggesting that conformational movements occur near the interface it defines between the LFA-1 alpha and beta subunits.     

The integrin beta1 subunit transmembrane domain regulates phosphatidylinositol 3-kinase-dependent tyrosine phosphorylation of Crk-associated substrate

Our previous studies on the transmembrane domain of human integrin subunits have shown that a conserved basic amino acid in both subunits of integrin heterodimers is positioned in the plasma membrane in the absence of interacting proteins. To investigate the possible functional role of the lipid-embedded lysine in the mouse integrin beta1 subunit, this amino acid was replaced with leucine, and the mutated beta1 subunit (beta1A(K756L)) was stably expressed in beta1-deficient GD25 cells. The extracellular domain of beta1A(K756L) integrins possesses a competent conformation for ligand binding as determined by the ability to mediate cell adhesion, and by the presence of the monoclonal antibody 9EG7 epitope. However, the spreading of GD25-beta1A(K756L) cells on fibronectin and laminin-1 was impaired, and the rate of migration of GD25-beta1A(K756L) cells on fibronectin was reduced compared with GD25-beta1A cells. Phosphorylation of tyrosines in focal adhesion kinase (FAK) and the Y416 in c-Src in response to beta1A(K756L)-mediated adhesion was similar to that induced by wild-type beta1. The tyrosine phosphorylation level of paxillin, a downstream target of FAK/Src, was unaffected by the beta1 mutation, whereas tyrosine phosphorylation of CAS was strongly reduced. The results demonstrate that CAS is a target for phosphorylation both by FAK-dependent and -independent pathways after integrin ligation. The latter pathway was inhibited by wortmannin and LY294002, implicating that it required an active phosphatidylinositol 3-kinase. Furthermore, the K756L mutation in the beta1 subunit was found to interfere with beta1-induced activation of Akt. The results from this study identify phosphatidylinositol 3-kinase as an early component of a FAK-independent integrin signaling pathway triggered by the membrane proximal part of the beta1 subunit.     

Urokinase receptors promote beta1 integrin function through interactions with integrin alpha3beta1

The urokinase receptor (uPAR) is linked to cellular migration through its capacity to promote pericellular proteolysis, regulate integrin function, and mediate cell signaling in response to urokinase (uPA) binding. The mechanisms for these activities remain incompletely defined, although uPAR was recently identified as a cis-acting ligand for the beta2 integrin CD11b/CD18 (Mac-1). Here we show that a major beta1 integrin partner for uPAR/uPA signaling is alpha3. In uPAR-transfected 293 cells uPAR complexed (>90%) with alpha3beta1 and antibodies to alpha3 blocked uPAR-dependent vitronectin (Vn) adhesion. Soluble uPAR bound to recombinant alpha3beta1 in a uPA-dependent manner (K(d) < 20 nM) and binding was blocked by a 17-mer alpha3beta1 integrin peptide (alpha325) homologous to the CD11b uPAR-binding site. uPAR colocalized with alpha3beta1 in MDA-MB-231 cells and uPA (1 nM) enhanced spreading and focal adhesion kinase phosphorylation on fibronectin (Fn) or collagen type I (Col) in a pertussis toxin- and alpha325-sensitive manner. A critical role of alpha3beta1 in uPA signaling was verified by studies of epithelial cells from alpha3-deficient mice. Thus, uPAR preferentially complexes with alpha3beta1, promoting direct (Vn) and indirect (Fn, Col) pathways of cell adhesion, the latter a heterotrimeric G protein-dependent mechanism of signaling between alpha3beta1 and other beta1 integrins.     

The cytoplasmic tyrosines of integrin subunit beta1 are involved in focal adhesion kinase activation

We have previously shown that mutation of the two tyrosines in the cytoplasmic domain of integrin subunit beta1 (Y783 and Y795) to phenylalanines markedly reduces the capability of beta1A integrins to mediate directed cell migration. In this study, beta1-dependent cell spreading was found to be delayed in GD25 cells expressing beta1A(Y783/795F) compared to that in wild-type GD25-beta1A. Focal adhesion kinase (FAK) tyrosine phosphorylation and activation were severely impaired in response to beta1-dependent adhesion in GD25-beta1A(Y783/795F) cells compared to that in wild-type GD25-beta1A or mutants in which only a single tyrosine was altered (beta1A(Y783F) or beta1A(Y795F)). Phosphorylation site-specific antibodies selective for FAK phosphotyrosine 397 indicated that the defect in FAK phosphorylation via beta1A(Y783/795F) lies at the level of the initial autophosphorylation step. Indeed, beta1A-dependent tyrosine phosphorylation of tensin and paxillin was lost in the beta1A(Y783/795F) cells, consistent with the impairment in FAK activation. In contrast, p130(CAS) overall tyrosine phosphorylation was unaffected by the beta1 mutations. Despite the defect in beta1-mediated FAK activation, FAK was still localized to focal adhesions. Taken together, the phenotype of the GD25-beta1A(Y783/795F) cells resembles, but is distinct from, the phenotype observed in FAK-null cells. These observations argue that tyrosines 783 and 795 within the cytoplasmic tail of integrin subunit beta1A are critical mediators of FAK activation and cell spreading in GD25 cells.     

Threonine 788 in integrin subunit beta1 regulates integrin activation

In the present study, the functional role of suggested phosphorylation of the conserved threonines in the cytoplasmic domain of integrin subunit beta1 was investigated. Mutants mimicking phosphorylated and unphosphorylated forms of beta1 were expressed in beta1 deficient GD25 cells. T788 in beta1 was identified as a site with major influence on integrin function. The mutation to A788 strongly reduced beta1-dependent cell attachment and exposure of the extracellular 9EG7 epitope, whereas replacement of T789 with alanine did not interfere with the ligand-binding ability. Talin has been shown to mediate integrin activation, but the talin head domain bound equally well to the wild-type beta1 and the mutants indicating that the T788A mutation caused defect integrin activation by another mechanism. The phosphorylation-mimicking mutation T788D was fully active in promoting cell adhesion. GD25 cells expressing beta1T788D accumulated increased number of focal contacts and migrated slowly compared to GD25 beta1 wild-type. An analogous phenotype is seen when focal adhesion kinase activation is abrogated. However, neither the beta1T788D nor the beta1T788A mutation failed to induce tyrosine phosphorylation of focal adhesion kinase. The results suggest that phosphorylation of T788 in integrin beta1 promotes inside-out receptor activation, as well as focal contact accumulation.     

Antibodies to the conserved cytoplasmic domain of the integrin beta 1 subunit react with proteins in vertebrates, invertebrates, and fungi

The integrin family of cell surface receptors can be divided into three groups on the basis of their homologous beta subunits: beta 1, beta 2, and beta 3. We have raised an antibody against a synthetic peptide corresponding to the COOH-terminal domain of the chicken integrin beta 1 subunit that reacts with beta subunits from a variety of vertebrates, invertebrates, and fungi, demonstrating strong evolutionary conservation of sequences in this domain. In Drosophila cells, the antibody recognizes integrin alpha beta complexes that appear to be identical with position-specific antigens. Cross-reactive proteins are also detected in Caenorhabditis elegans and Candida albicans. The antiserum is specific for beta 1 subunits and does not recognize other integrin beta subunits in humans. In immunofluorescence analyses of cultured cells, the antibody reacts only with permeabilized cells confirming that this highly conserved COOH-terminal segment is a cytoplasmic domain.     

CD98hc (SLC3A2) interaction with the integrin beta subunit cytoplasmic domain mediates adhesive signaling

In mammals, beta1 integrin adhesion receptors generate signals that mediate cell spreading, migration, proliferation, and survival. CD98, a heterodimeric transmembrane protein, physically associates with certain integrin beta subunit cytoplasmic domains (tails) via its heavy chain, CD98hc (SLC3A2), and loss of CD98hc impairs integrin signaling. Here we have used the lack of CD98hc interaction with the Drosophila integrin betaPS tail for a homology scanning analysis that implicated the C-terminal 8 residues of beta3 (Thr(755)-Thr(802)) in CD98hc binding. We then identified point mutations in the beta3 C terminus (T755K and T758M) that abolish CD98hc association and a double mutation in the corresponding residues in the betaPS tail (K839T,M842T), which resulted in gain of CD98hc interaction. Furthermore, the loss of function beta3(T755K) mutation or the gain of function beta3/betaPS(K839T,M842T) led to a loss or gain of integrin-mediated cell spreading, respectively. Thus, we have identified critical integrin residues required for CD98hc interaction and in doing so have shown that CD98c interaction with the integrin beta tail is required for its ability to mediate integrin signaling. These studies also provide new insights into how CD98hc may cooperate with other cytoplasmic domain binding proteins to modulate integrin functions and into the evolution of integrin signaling.     

The beta1 integrin subunit is not a specific component of the costamere domain in human myocardial cells

Studies on altered integrin receptor expression during cardiac hypertrophy and heart failure requires accurate knowledge of the distributional pattern of integrins in myocardial cells. At present the general consensus is that in cardiac muscle the ₁ integrin receptor is mainly localized to the same sarcolemmal domain as vinculin at Z-band levels (costamere). Since most previous studies have been focusing on myocardial integrin distribution in lower mammals, the myocardial localization of the ₁ integrin subunit was investigated in biopsies collected from the auricle of patients undergoing a coronary bypass operation. Non-invasive serial optical sectioning was carried out by immuno-laser scanning confocal microscopy. Double-labelling for vinculin/-actinin, and the cytoplasmic domain for the ₁ integrin subunit, showed that ₁ integrin is deposited throughout both the vinculin/-actinin domains and the non-vinculin/-actinin domains. These results were supported by a semi-quantitative analysis in extended focus images of the latter preparations. Higher magnification views at the electron microscopical levels of the large, extracellular domain of the ₁ integrin subunit disclosed a pronounced labelling in the form of a dense, irregular punctuate pattern that was distributed at Z-disc domains as well as along the entire sarcolemmal area between Z-discs. Our findings show that in human, myocardial cells, the ₁ integrin receptor does not only localize to the surface membrane at the Z-disc level (costamere in cardiac muscle), but has a widespread distribution along the sarcolemma.     

In vivo analyses of integrin beta 1 subunit function in fibronectin matrix assembly

Early development of the urodele amphibian Pleurodeles waltl is accompanied by a process of progressive fibronectin (FN) fibrillogenesis. FN begins to assemble into fibrils on the inner surface of the blastocoele roof at the early blastula stage and progressively forms a complex extracellular matrix. We have analyzed the mechanisms of FN-fibril formation under normal and experimental conditions in vivo with the following probes: iodinated FN, fluorescein-labeled FN, synthetic peptides containing the Arg-Gly-Asp (RGD) cell surface recognition sequence of FN, and polyclonal antibodies against both beta 1 subunit of the amphibian FN receptor and the cytoplasmic domain of beta 1 subunit. We report that in living embryos, exogenous labeled mammalian FN injected into the amphibian blastocoele undergoes FN-fibril formation in spatiotemporal patterns similar to those of endogenous FN. This indicates regulation of fibrillogenesis by the cell surface rather than by changes in the type of FN. Fibrillogenesis is inhibited in a dose-dependent manner both by the GRGDS peptide and monospecific antibodies to amphibian integrin beta 1 subunit. Furthermore, when injected intracellularly into uncleaved embryos or into selected blastomeres, antibodies to the cytoplasmic domain of integrin beta 1 subunit produce a reversible inhibition of FN-fibril formation that follows early cell lineages and cause delays in development. Together, these data indicate that in vivo, the integrin beta 1 subunit and the RGD recognition signal are essential for the proper assembly of FN fibrils in early amphibian development.     

The beta 4 subunit cytoplasmic domain mediates the interaction of alpha 6 beta 4 integrin with the cytoskeleton of hemidesmosomes.

The alpha 6 beta 4 integrin is structurally distinct from all the other known integrins because the cytoplasmic domain of beta 4 is unusually large and contains four type III fibronectin-like modules toward its C-terminus. To examine the function of the beta 4 cytoplasmic tail, we have expressed full-length and truncated human beta 4 cDNAs in rat bladder epithelial 804G cells, which form hemidesmosome-like adhesions in vitro. The cDNA encoded wild-type beta 4 subunit associated with endogenous alpha 6 and was recruited at the cell surface within hemidesmosome-like adhesions. A recombinant form of beta 4, lacking almost the entire cytoplasmic domain associated with alpha 6, reached the cell surface but remained diffusely distributed. A beta 4 molecule lacking almost the entire extracellular portion did not associate with alpha 6 but was correctly targeted to the hemidesmosome-like adhesions. Thus, the cytoplasmic portion of beta 4 contains sequences that are required and may be sufficient for the assembly of the alpha 6 beta 4 integrin into hemidesmosomes. To localize these sequences we examined the properties of additional mutant forms of beta 4. A truncated beta 4 subunit, lacking the most C-terminal pair of type III fibronectin homology domains, was incorporated into hemidesmosome-like adhesions, but another recombinant beta 4 molecule, lacking both pairs of type III fibronectin repeats, was not. Finally a recombinant beta 4 molecule, which was created by adjoining the region of the cytoplasmic domain including all type III repeats to the transmembrane segment, was efficiently recruited in hemidesmosome-like adhesions. Taken together these results suggest that the assembly of the alpha 6 beta 4 integrin into hemidesmosomes is mediated by a 303-amino acid region of beta 4 tail that comprises the first pair of type III fibronectin repeats and the segment between the second and third repeats. These data imply a function of a specific segment of the beta 4 cytoplasmic domain in interaction with cytoskeletal components of hemidesmosomes.