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© The Rockefeller University Press, 0021-9525/1998//587 $5.00
The Journal of Cell Biology, Volume 142, Number 2, , 1998 587-594

Integrin 1β1 Mediates a Unique Collagen-dependent Proliferation Pathway In Vivo

Ambra Pozzi^*, Kishore K. Wary, Filippo G. Giancotti, and Humphrey A. Gardner^*

^* Department of Cell Biology, The Scripps Research Institute, 10550 North Torrey Pines Road, La Jolla, CA, 92037; and Cellular Biochemistry and Biophysics Program, Memorial Sloan-Kettering Cancer Center, 1275 York Avenue, New York, 10021

Activation of integrins upon binding to extracellular matrix proteins is believed to be a crucial step for the regulation of cell survival and proliferation. We have used integrin 1-null mice to investigate the role of this collagen receptor in the regulation of cell growth and survival in vivo. 1-deficient animals, which are viable and fertile, have a hypocellular dermis and a deficiency in dermal fibroblast proliferation as embryos. In vitro analysis of 1-null embryonic fibroblasts has revealed that their proliferation rate is markedly reduced when plated on collagenous substrata, despite normal attachment and spreading. Moreover, on the same collagenous matrices, 1-null fibroblasts fail to recruit and activate the adaptor protein Shc. The failure to activate Shc is accompanied by a downstream deficiency in recruitment of Grb2 and subsequent mitogen-activated protein kinase activation. Taken together with the growth deficiency observed on collagens, this finding indicates that the 1β1 is the sole collagen receptor which can activate the Shc mediated growth pathway. Thus, integrin 1 has a unique role among the collagen receptors in regulating both in vivo and in vitro cell proliferation in collagenous matrices.

Key Words: 1β1 integrin • collagen • proliferation • signal transduction • dermis

Abbreviations used in this paper: BrdU, 5'-bromo-2'-deoxy-uridine; ECM, extracellular matrix; EF, embryonic fibroblasts; MAPK, mitogen-activated protein kinase; PCNA, proliferating cell nuclear antigen.

INTEGRINS are transmembrane heterodimeric receptors for extracellular matrix (ECM)¹ molecules (Hynes, 1992). They are composed of and β subunits that heterodimerize to produce >20 different receptors. One family of integrins, which all have the β1 subunit in common, include high affinity receptors for many ECM proteins including fibronectin, laminin, and the collagens. Three members of this family are known to be the major receptors for collagens, namely 1β1, 2β1, and 3β1 (Yamamoto and Yamamoto, 1994; Gardner et al., 1996). All three of these receptors are expressed by fibroblasts, and they seem to regulate different functions. Integrin 1β1, for example, appears to regulate collagen synthesis, whereas 2β1 mediates collagen gel contraction (Schiro et al., 1991; Langholz et al., 1995; Broberg and Heino, 1996).

Integrin 1β1 is widely expressed in the adult animal, being found in visceral and some vascular smooth muscle, liver, microvascular endothelium, activated lymphocytes, and dermis (see references cited in Gardner et al., 1996). During embryonic development, 1 is first expressed in trophoblast immediately after implantation (Sutherland et al., 1993), suggesting an essential role of this molecule during early stages of development. To analyze the role of 1 integrin during mouse formation, we have generated mice deficient in integrin 1 by gene targeting (Gardner et al., 1996). This disruption prevents the formation of the 1β1 receptor without altering other β1 integrin heterodimers. Animals homozygous for the disruption develop normally and are fertile, indicating that despite its prominent expression during development, 1 integrin is not essential for formation of the adult mouse. Using embryonic fibrobasts derived from mutant animals, we have shown that 1 uniquely confers on fibroblasts the ability to adhere and migrate on collagen IV, while being only one of three integrin collagen type I receptors present on fibroblasts, together with 2β1 and 3β1. Recent studies have also implicated DDR1 and 2, "orphan" tyrosine kinase receptors, as receptors for collagens (Shrivastava et al., 1997; Vogel et al., 1997).

The interaction between integrins and their ligands, besides mediating cell adhesion, plays a role in a number of cellular processes, including cell differentiation (Adams and Watt, 1993), cell cycle progression (Giancotti, 1997), and cell survival (Frisch and Ruoslahti, 1997). The regulation of these different events requires the activation of specific cellular targets, including protein kinase C (Clark and Brugge, 1995), PI3-OH kinase (Khwaja et al., 1997), and the small GTPase Rho (Schwartz et al., 1996). Moreover, there is evidence that integrins activate shared as well as subgroup-specific signaling pathways that contribute to organization of the cytoskeleton and activation of the mitogen-activated protein kinase (MAPK) cascades, thereby influencing immediate early gene expression (Clark and Hynes, 1997; Giancotti, 1997). Recent studies have indicated that a class of integrins that includes the 1β1, 5β1, 6β4, and vβ3 receptors, is coupled to the Ras–MAPK signaling pathway by the adaptor protein Shc (Maniero et al., 1995; Wary et al., 1996; Maniero et al., 1997). Adhesion mediated by Shc-linked integrins promotes cell survival and progression through the G1 phase of the cell cycle in response to mitogenic growth factors, whereas adhesion mediated by other integrins results in exit from the cell cycle and, in certain cases, cell death (Wary et al., 1996; Maniero et al., 1997). These in vitro studies suggest that integrin 1β1 may regulate cell survival and growth in response to ECM components. We have used integrin 1–null mice to investigate the role of this collagen receptor in the regulation of cell survival and proliferation in vivo. The observation that 1-null dermis is hypocellular, prompted us to analyze fibroblasts from control and integrin 1–deficient mice, and to compare their growth and survival in response to ECM. 1-null fibroblasts proliferate less than their normal counterparts both in vivo and in vitro, suggesting that survival and proliferation on collagenous substrata are events mediated specifically and uniquely by activation of integrin 1β1. These results suggest that 1β1 has, among many integrin and non-integrin collagen receptors, a unique signaling function in vivo.

	Materials and Methods

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Cell Culture and Matrix Components
Mouse embryonic fibroblasts (EFs) were isolated from wild-type and 1-null E 14.5 embryos by trypsinization (Li et al., 1992). All cells were used for in vitro studies at matched passage numbers 3 or 4. Cells were cultured in DME supplemented with 2% or 10% FCS (GIBCO BRL, Gaithersburg, MD). Matrix components used in the study were bovine skin collagen I (Vitrogen 100; Collagen Corp., Palo Alto, CA), human placental collagen IV (Sigma Chemical Co., St. Louis, MO), human fibrinogen (gift of Z. Ruggeri, The Scripps Research Institute, La Jolla, CA), and bovine plasma fibronectin (GIBCO BRL).

Evaluation of Fibroblast Density in the Dermis
129Sv/ter wild-type and integrin 1-null mice (6-, 12-, and 24-wk old) were killed by cervical dislocation. The dorsal skin was shaved, removed, fixed in formalin, and then embedded in paraffin. Sections were stained with hematoxylin and eosin, and the number of dermal nuclei was determined by random evaluation of six high power field views of normal, as well as 1-null dermis.

Measurement of In Vivo Proliferative Index by PCNA Labeling
Integrin 1–null and –positive control mouse embryos at day 16.5 of gestation, were obtained from timed matings. Embryos were fixed in formalin and paraffin embedded. For proliferating cell nuclear antigen (PCNA) staining, transverse midsections of three wild-type, as well as three 1- deficient embryos, were stained by using the mouse monoclonal IgG2a antibody PC10 (Zymed Laboratories, Inc., South San Francisco, CA) at a dilution of 1:200. Biotinylated secondary anti–mouse antibody and avidin/ biotin-HRP–conjugated complex were used to detect bound antibody. Sections were then counterstained with hematoxylin and the dermal proliferative index (PCNA-positive cells/total number of counted cells x 100) was determined by random evaluation of 12 40x field views of dermis of each embryo. At least 900 cells around the entire circumference of the dermis of each embryo were thus counted.

For wound healing experiments, 1-cm dorsal full thickness, cutaneous incisions were made and immediately closed with interrupted 6/0 prolene sutures in four wild-type and four age-matched 1-null animals. 12 d after the incision, animals were killed and the dorsal skin was shaved, removed, fixed in formalin, and then paraffin embedded. Sections were then subjected to PCNA staining as described above. Fibroblasts in three 40x fields encompassing the wound were counted, and the proliferation index expressed as number of PCNA-positive nuclei/total fibroblast number. At least 300 cells in each wound were counted.

Cell Proliferation Assay
Control and integrin 1-null EFs were obtained from E13.5 embryos, according to the method of Li et al. (1992). Cells were detached from culture dishes by trypsin, washed, resuspended in DME containing 2% or 10% FCS, and then plated at the density of 10 x 10⁴ cells on 24-well plates uncoated, or coated with fibrinogen (10 µg/ml), collagen I (100 µg/ml), or a mixture of collagen I (100 µg/ml) and IV (30 µg/ml). Fibrinogen solution was prepared in PBS, while the solutions containing collagen I were prepared in 0.1 M acetic acid, as described by Koyama et al. (1996). Cells were trypsinized and counted every 24 h, for a total of 72 h.

Measurement of In Vitro Proliferative Index by BrdU Labeling and FACS^®
To evaluate the proliferative index, control and integrin 1–deficient EFs were plated in presence of 2% FCS, at a density of 5 x 10⁴ cells on 16-well tissue culture chamber slides (Nunc, Inc., Naperville, IL) that were uncoated or coated with fibrinogen (10 µg/ml), collagen I (100 µg/ml), or a mixture of collagens I (100 µg/ml) and IV (30 µg/ml). After 24 h, cells were labeled with 10 µM 5'-bromo-2'-deoxy-uridine (BrdU; Sigma Chemical Co.), and incubated for a further 24 h. Cells were then washed, fixed, and stained with anti-BrdU mAbs (Sigma Chemical Co.), followed by biotinylated secondary anti–mouse antibody and avidin/biotin-HRP–conjugated complex (Vector Laboratories, Burlingame, CA). The BrdU labeling index (positive cells/total number of counted cells x 100) was determined by random evaluation of 10 40x fields, counting a minimum of 200 cells. For FACS^® analysis, 3 x 10⁵ serum-starved cells were plated on 6-well plates coated with fibronectin (10 µg/ml), fibrinogen (10 µg/ml) or collagen I (100 µg/ml) in 2% FCS. After 12 h, they were trypsinized and fixed in 70% ethanol. Cells were stained with PBS/0.1% Triton X-100/0.2 mg/ml RNase A/20 µg/ml propidium iodide, and analyzed on a Becton Dickinson FACScan^® machine. S phase measurements were obtained using the Mod Fit LT v.2 program (Verity Software, Topsham, ME).

Measurement of In Vitro Apoptotic Index by DAPI Labeling
To evaluate the effect of ECM proteins on cell survival, control and integrin 1–deficient EFs were either kept in suspension, or plated in absence of serum, at the density of 7 x 10⁴ cells on coverslips coated with fibrinogen (10 µg/ml), collagen I (20 µg/ml), or a mixture of collagen I (20 µg/ml) and IV (10 µg/ml). After 16 h, coverslips were washed with PBS to remove unattached cells, and then fixed and stained with 0.5 µg/ml DAPI (Sigma Chemical Co.)/PBS/0.1% Triton X-100. Chromatin condensation was used as morphological index for apoptotic cells. The apoptotic labeling index (cells with condensed chromatin/total number of counted cells x 100) was determined by random evaluation of 5–10 40x fields, counting a minimum of 300 cells.

In Vitro Immunoprecipitation Assay
Cell lysates were prepared according to the procedure described by Wary et al., 1996. Briefly, control and integrin 1–null EFs were growth factor starved for 8 h, and subsequently trypsinized. Cells were then resuspended in DME containing 0.1% BSA and kept at room temperature for 30 min. They were then either left in suspension or plated on dishes coated with fibronectin (10 µg/ml), collagen I (20 µg/ml), or a mixture of collagen I (20 µg/ml) and IV (10 µg/ml) all diluted in PBS. After 1 h at 37°C, the cells were washed with PBS, scraped with a rubber spatula in 50 mM Hepes, pH 7.5, 150 mM NaCl, 1% Triton X-100, and then centrifuged at 14,000 rpm at 4°C for 10 min. Protein concentration was determinded using the micro BCA assay (Pierce Chemical Co., Rockford, IL) with BSA as the standard. Immunoprecipitation and immunoblotting were performed as described by Maniero et al. (1995). Briefly, lysates containing equal amount of proteins were immunoprecipitated with affinity-purified anti-Shc polyclonal antibody (Maniero et al., 1995), and subjected to immunoblotting with anti-phosphotyrosine mAb RC-20H (Transduction Laboratories, Lexington, KY), anti-Grb2 polyclonal antibody (C-23; Santa Cruz Biotechnology, Santa Cruz, CA), and anti-Shc polyclonal antibody. Nitrocellulose-bound antibodies were detected by chemiluminescence with enhanced chemiluminescence (ECL; Amersham, Life Sciences, Little Chalfont, UK). To examine Erk activity, cell lysates containing equal amount of proteins were immunoprecipitated with anti-Erk2 polyclonal antibody C-14 (Santa Cruz Biotechnology) and subjected to in vitro kinase assay in 50 mM Tris, pH 7.5, 10 mM MgCl₂ containing 5 µCi of [³²P]ATP (4,500 Ci/mmol; ICN Biomedicals, Inc., Costa Mesa, CA) and 2.5 µg of myelin basic protein (Sigma Chemical Co.).

	Results

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1-deficient Dermis Is Hypocellular
Histological analysis of skin sections from wild-type and 1-deficient mice did not reveal any substantial differences in dermal morphology and thickness (Fig. 1 A). However, we observed that the number of dermal nuclei was reduced in the 1-null skin when compared with the wild-type group (Fig. 1 A). To quantify this difference, pairs of wild-type and knockout skins obtained from 6-, 12-, and 24-wk-old 129Sv/ter mice were stained with hematoxylin and eosin, and the number of dermal nuclei was determined by random evaluation of six high power field views of dermis. The number of dermal nuclei in 1-null dermis was reduced at all stages examined as compared with the wild-type dermis (Fig. 1 B). To assess whether the difference in cell number was due to dermal fibroblasts, rather than dermal lymphocytes, the dermis of both control and 1-deficient animals were stained with CD5, a specific T-lymphocyte marker. No CD5 dermal staining was observed in the dermis of wild-type or 1-null animals (data not shown), suggesting that dermal fibroblasts rather than lymphocytes account for the difference in cell number observed in the two groups.

View larger version (82K): [in this window] [in a new window] [Download PPT slide]   Figure 1 Fibroblast density in dermis of wild-type and 1-deficient animals. (A) Representative sections of wild-type (WT) and 1-deficient (KO) 6-wk-old skin stained with hematoxylin and eosin. The 1-deficient skin has apparently normal architecture but reduced numbers of nuclei in the dermis. (B) Counts of dermal nuclei in pairs of wild-type and knockout skin obtained from 6-, 12-, and 24-wk-old 129 Sv/ter mice. Each pair of bars represents one pair of apposed sections of back skin sectioned at 5 µm. Note the lower number of dermal nuclei in 1-null dermis compared with that observed in wild-type samples. Bars and errors show mean and standard deviation of counts of dermal nuclei in six high power field views of dermis. Differences between wild-type and 1-null groups were significant with P < 0.05 by Student's t test in each case. Bar, 100 µm.

1-null Embryonic Fibroblasts Show Marked Reduction in Proliferation Compared with Their Wild-Type Counterparts
To test the hypothesis that 1β1 integrin delivers a growth signal, the proliferative index of wild-type and 1-deficient dermal fibroblasts was assessed by staining both embryonic and adult skin with antibodies to PCNA. PCNA is a DNA polymerase – and –associated protein, which is bound tightly to DNA only during S phase (Toschi and Bravo, 1988); in formalin-fixed, paraffin-embedded tissues PCNA is preferentially retained in S phase cells. Whereas results from PCNA staining are not numerically comparable to other methods of estimating S phase fraction, they do provide robust comparisons between similarly processed samples (Holt et al., 1997). As expected, there was no appreciable proliferation in sections of adult dermis of either genotype (data not shown). Analysis of 16.5-d-old embryos, however, (Fig. 2 A) revealed a marked reduction in the proliferative index of 1-null dermis as compared with the wild-type (Fig. 2 B).

View larger version (92K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Proliferative index of wild-type and 1-null embryonic dermal fibroblasts. (A) Mid cross-section of 16.5 embryos were stained with anti-PCNA antibodies, and subsequently counterstained with hematoxylin. Note the higher number of dermal PCNA-positive cells in the wild-type (WT) dermis, as compared with their 1-null (KO) counterparts. (B) The dermal proliferative index (number of PCNA positive cells/total number of cells x 100) of three wild-type and three 1-null 16.5 embryos was determined by random evaluation of 12 different 40x microscopic fields for each sample, counting a minimum of 900 cells around the entire circumference of embryonal dermis. Bars and errors indicate the mean and standard deviation. Differences between wild-type and 1-null groups were significant with P < 0.05 by Student's t test. Bar, 30 µm.

View larger version (161K): [in this window] [in a new window] [Download PPT slide]   Figure 3 Proliferative index of wild-type and 1-null adult fibroblasts in wounded dermis. (A) Sections of wild-type (WT) and 1-deficient (KO) wounded skin, 12 d after incision and primary closure, stained with anti-PCNA antibodies, and subsequently counterstained with hematoxylin. The proportion of PCNA-positive cells in the dermal wound (seen as dark nuclei in the micrograph) was similar in wild-type and 1-null animals. (B) The dermal proliferative index (number of PCNA positive cells/total number of cells x 100) was determined by random evaluation of 3 different 40x microscopic fields for each sample, counting a minimum of 300 cells. Bars and errors indicate the mean and standard deviation. Bar, 100 µm.

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Growth of wild-type and 1-deficient embryonic fibroblasts on different substrata. 10 x 104 log phase wild-type () and 1-null (•) EFs were plated in presence of 2% FCS (A) or 10% FCS (B) on 24-well plates uncoated, or coated with fibrinogen (10 µg/ml), collagen I (100 µg/ml), or a mixture of collagen I (100 µg/ml) and IV (30 µg/ml). Two wells per group for each treatment were counted at the time point indicated. This experiment is representative of three repeated experiments. Note the reduced growth of 1-null EFs, on collagen-coated dishes, as compared with the wild-type cells. Bars and errors indicate the mean and the higher number from two dishes per each group.

View larger version (93K): [in this window] [in a new window] [Download PPT slide]   Figure 5 Profilerative index of wild-type and 1-null embryonic fibroblasts in vitro. (A) EFs were plated in presence of 2% FCS onto dishes uncoated or coated with fibrinogen (10 µg/ml), collagen I (100 µg/ml), or a mixture of collagen I (100 µg/ml) and collagen IV (30 µg/ml). 24 h after plating, cells were labeled with 10 µM BrdU (Sigma Chemical Co.), and incubated for a further 24 h. After staining with anti-BrdU mAbs, the Brdu labeling index (positive cells/total number of counted cells x 100) was determined by random evaluation of five different 40x microscopic fields for each duplicate sample, counting a minimum of 200 cells. Bars and errors indicate the mean and standard deviation. The differences seen between wild-type and 1-null groups on collagens are significant with P < 0.05 using a Student's t-test on the 10 microscopic fields counted for each sample. (B) S phase entry of wild-type and 1-null embryonic fibroblasts after serum starvation. Passage 4 EFs were starved for 24 h, before plating on various substrata in the presence of 2% FCS. After 12 h cells were recovered by trypsinization, and subjected to FACS® analysis as described in Materials and Methods. Bars indicate the mean and error bars the distance to the higher value for each pair of samples analyzed. TC, tissue culture; FN, fibronectin; FIB, fibrinogen; CI, collagen I; CI + IV, collagen I + IV; ST, serum starved.

View larger version (65K): [in this window] [in a new window] [Download PPT slide]   Figure 6 Apoptotic index of wild-type and 1-null EFs in vitro. (A) EFs were plated in absence of serum on coverslips coated with collagen I (20 µg/ml) or fibrinogen (10 µg/ ml). 16 h after plating, coverslips were washed to remove unattached cells, fixed, and then stained with 0.5 µg/ml DAPI. Chromatin condensation was used to score positive apoptotic cells. Note the higher number of apoptotic-positive cells in 1-null EFs as compared with wild-type cells when plated on collagen matrix. (B) The apoptotic index (cells with condensed chromatin/total number of counted cells x 100) of EFs, kept in suspension or plated in dishes coated as indicated, was determined by random evaluation of five different 40x microscopic fields for each duplicate sample, counting a minimum of 300 cells. Bars and errors indicate the mean and standard deviation. Significant differences were seen between wild-type and 1-null groups on collagens with P < 0.05 using a Student's t-test on the 10 microscopic fields counted for each sample. SUSP, suspension; FIB, fibrinogen; CI, collagen I; C I + IV, collagen I + IV. Bar, 40 µm.

1-null Embryonic Fibroblasts Fail to Activate the Adaptor Protein Shc When Plated on Collagens
The differences in proliferation between 1-null and wild-type EFs on collagen substrata suggests that the interaction between integrin 1β1 and collagens is required for the activation of a specific survival/proliferation pathway. It has been shown (Wary et al., 1996) that activation of 1β1 causes recruitment and tyrosine phosphorylation of the adaptor protein Shc. This protein, via recruitment of Grb2 and activation of the the Ras-MAP kinase pathway, cooperates with mitogens to mediate cell survival and proliferation. Based on this observation, we investigated the activation of Shc by wild-type and 1-deficient EFs upon adhesion on different substrata. We have previously shown that 1-deficient fibroblasts fail to adhere to collagen IV (Gardner et al., 1996). Thus, to analyze the contribution of this molecule in the activation of Shc via 1 integrin, 1-deficient cells were plated on a mixture of collagen I and IV, or on collagen I alone, and the level of Shc activation compared with that observed in their normal counterparts. With these substrata, the extent of adhesion of wild-type and 1-null cells is indistinguishable. Cells kept in suspension, or plated on fibronectin were used, respectively, as negative and positive controls for activation of the Shc pathway. Cell lysates were immunoprecipitated with anti-Shc antibody and subjected to immunoblotting with anti-phosphotyrosine antibody to determine Shc activation, with anti-Grb2 antibody to examine recruitment of Grb2, and with anti-Shc antibody to check for equal loading. Cell lysates were also immunoprecipitated with anti-Erk2 antibody and subjected to in vitro kinase assay to determine MAPK activation. As expected, EFs of both genotype failed to cause Shc phosphorylation when kept in suspension (Fig. 7 B), despite containing normal levels of protein (Fig. 7 A). Consequently, no recruitment of Grb 2 (Fig. 7 C), or activation of MAP kinase (Fig. 7 D) was observed. In contrast, both cell types activated Shc protein and its related downstream cascade, when plated on fibronectin (Fig. 7, A–D). Striking differences in the activation of Shc, and its related downstream events, however, were observed between wild-type and 1-null EFs after adhesion on collagen I or a mixture of collagen I and IV. 1-null EFs entirely failed to activate Shc when plated for 1 h on substrata of collagen I or a mixture of collagen I and IV in contrast to wild-type cells (Fig. 7 B). The failure to activate Shc by 1-deficient cells was accompanied by a downstream deficiency in recruitment of Grb 2 (Fig. 7 C) and subsequent MAPK activation (Fig. 7 D). Taken together with the growth deficiency we have observed in 1-null EFs on collagen substrata (Fig. 4), this finding demonstrates that 1 collagen receptor has a unique and pivotal role in regulating cell survival and proliferation on collagenous matrices.

View larger version (50K): [in this window] [in a new window] [Download PPT slide]   Figure 7 1-null EFs fail to recruit and activate Shc and subsequent downstream events when plated on collagens. EFs were serum starved for 8 h and then trypsinized. Cells were then resuspended in DME/0.1% BSA and kept at room temperature for 30 min. They were then either left in suspension or plated on dishes coated with fibronectin (10 µg/ml), collagen I (20 µg/ml), or a mixture of collagen I (20 µg/ml) and IV (10 µg/ml). After 1 h at 37°C, cells were lysed and an equal amount of proteins were immunoprecipitated with anti-Shc polyclonal antibody (A–C), and subjected to immunoblotting with anti-Shc polyclonal antibody (A), anti–P-Tyr mAb (B), or anti–Grb-2 mAb (C). In D, equal amount of proteins were immunoprecipitated with anti-ERK2 polyclonal antibody and subjected to in vitro kinase assay with myelin basic protein as substrate. Note that when plated on collagens, 1-null EFs fail to phosphorylate Shc (B) or to activate events downstream of Shc (C and D), despite containing normal level of Shc protein (A). SUSP, suspension; FN, fibronectin; CI, collagen I; C I + IV, collagen I + IV.

	Discussion

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In fibroblasts integrin 1β1 regulates different functions upon binding to collagen matrices. One of these is the regulation of collagen synthesis. We have found that the 1-null animals lack negative feedback regulation of collagen synthesis and synthesize excess dermal collagen in vivo. This is not apparent morphologically, as the animals also show increased synthesis of collagenases, and thus compensate excess synthesis with increased breakdown (Gardner, H., A. Broberg, A. Pozzi, J. Heino, submitted manuscript). This dysregulation appears to cause a small reduction in tensile strength of intact skin (Davidson, J., unpublished results).

Another function of integrin 1β1, analyzed in the present paper, is the control of cell growth and proliferation. We have shown that fibroblast growth, proliferation, and survival are events mediated by integrin 1 activation of the Ras-MAPK pathway, as previously suggested by the in vitro studies of Wary et al. (1996). We have demonstrated that when plated on collagen matrices, 1-deficient fibroblasts fail to activate the adaptor protein Shc, showing a reduced cell proliferation compared with their wild-type counterparts. This observation is complemented by our observation of dermal fibroblasts in vivo. Analysis of embryonic skin indicates that wild-type dermal fibroblasts proliferate more than their 1-null counterparts, supporting the hypothesis that 1 integrin plays a role in controlling cell growth. This difference in cell growth was not evident in adult skin, probably because the overall rate of proliferation in the adult dermis is negligible. Thus, our observation that adult 1-null dermis is hypocellular as compared with wild-type can be interpreted as the result of a defective proliferation of 1-deficient fibroblasts during embryogenesis, although a very slowly accumulated deficiency in proliferation in the adult 1-null dermis cannot be ruled out by our studies.

To induce fibroblast proliferation in adult dermis, we have performed dermal wound healing experiments on wild-type and 1-deficient animals. 12 d after the incision, no differences in the proliferative index of dermal fibroblasts of either genotype were evident in the wounded area. This may be explained by the fact that, during the first stages of wound healing fibrinogen, rather than collagen, is the major ECM component to be deposited in the wound, accompanied by local synthesis of fibronectin. These molecules could regulate, via vβ3 and 5β1 integrins, respectively, cell growth of both wild-type and 1-null fibroblasts, reducing or eliminating the differences in cell proliferation visible on collagen substrata. In this context, we have observed that when plated on fibronectin both wild-type and 1-deficient embryonic fibroblasts activate the Shc pathway, and show a similar growth profile. Fibroblasts express 5β1 (Dalton et al., 1992) and it has been shown that activation of 5β1 leads to recruitment of Shc (Wary et al., 1996). Similarly, our results on the proliferative index of wild-type and 1-deficient hepatocytes suggest the possibility that different ECM–integrin interactions could take place in these cells, and be dominant over the lack of 1 integrin in the control of cell survival and proliferation. In fact, given the variety of possible ligand integrin interactions, which do promote proliferation, it is striking that embryonic dermal fibroblasts have a perceptible dependence on the 1–collagen interaction for proliferation in vivo.

Our in vitro observation that activation of Shc on collagenous matrices occurs only in wild-type cells indicates that, although fibroblasts express three collagen receptors 1β1, 2β1, and 3β1 (Zutter and Santoro, 1990; Gardner et al., 1996), 1β1 integrin is the only one of these able to deliver a specific collagen-induced signal to the Ras-MAPK pathway, via Shc activation. Recently, it has been observed that the Shc phosphotyrosine binding domain can also bind to the DDR tyrosine kinase receptor after collagen stimulation and receptor autophosphorylation (Vogel et al., 1997), suggesting the possibility that DDR and integrin receptors may cooperate in the regulation of cell survival and proliferation. However, the observation that the MAPK pathway is not activated upon binding of DDR to collagen (Vogel et al., 1997), strongly supports the hypothesis that collagen- dependent proliferation is mainly mediated via activation of integrin 1β1.

Integrin 1β1 is only one of a larger family of integrins able to activate Shc. This subset of receptors includes integrin 5β1, the receptor involved in the control of cell cycle progression and proliferation in human umbilical vein endothelial cells (HUVECs) upon binding to fibronectin (Wary et al., 1996) and 6β4, which plays a role in regulating keratinocyte proliferation, via activation of the same Ras-MAPK pathway (Maniero et al., 1997). Thus, the same adaptor molecule, activated by different integrin–ligand interaction (1β1–collagen, 5β1–fibronectin, 6β4–laminin, and vβ3–fibrinogen) is able to regulate cell growth of different cell types. It is interesting to note in this context that integrin 5–null embryos, which die in mid-gestation, show a failure of proliferation of neural crest derivatives (Goh et al., 1997), suggesting that these may depend upon the 5β1–fibronectin interaction for proliferation in a manner analagous to the 1β1–collagen interaction in the dermis.

Whereas activation of Shc leads to cell growth and proliferation, adhesion mediated by integrins not linked to Shc appears unable to prevent apoptotic death (Wary et al., 1996). We have observed that 1-null cells, although able to adhere on collagen I or a mixture of collagen I and IV indistinguishably from their wild-type counterparts, are more susceptible to apoptosis, indicating that 1 integrin effects both fibroblast proliferation and survival. Shc signaling may contribute to protection from apoptosis by activating Ras and thereby PI-3 kinase, as activated forms of Ras and PI-3 kinase protect from suspension induced apoptosis (Khwaja et al., 1997). FAK activation by various integrins has also been implicated in cell survival (Frisch and Ruoslahti, 1997; Hungerford et al., 1996), and may too act via PI-3 kinase (Chen and Guan, 1994).

It is striking that the adhesive function of integrin 1β1 is apparently dispensable, permitting normal morphogenesis in the null, it is its role in regulating cell proliferation which, in its absence, gives rise to a perceptible phenotype in vivo. The observation that only one of the three dermal fibroblast collagen receptors specifically controls proliferation suggests that different integrin receptors for a single ligand accomplish different and unique functions within a single cell. Such functions may be quite distinct from, and in some instances more important than, their adhesive functions.

A recent study provides further evidence that integrin-mediated Shc signaling regulates cell proliferation in vivo (Murgia, C., P. Blaikie, N. Kim, M. Dans, H.T. Petrie, and F.G. Giancotti. 1998. EMBO (Eur. Mol. Biol. Organ.) J. In press).

	Acknowledgments

 
This work was supported by National Institutes of Health (NIH) grant R29-AR4415 and the Dr. Mark Flapan Memorial Grant Award from the Scleroderma Federation/United Scleroderma Foundation to H. Gardner, and by NIH grant CA78901 to F.G. Giancotti.

Submitted: 21 April 1998

Revised: 9 June 1998

H. Gardner thanks J. Trotter for training in flow cytometry, and J. Leopard for histotechnology.

Address all correspondence to Humphrey A. Gardner, Department of Cell Biology, The Scripps Research Institute, 10550 North Torrey Pines Road, La Jolla, CA 92037. Tel.: (619) 784-9821. Fax: (619) 784-9927. E-mail: humphrey{at}scripps.edu

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