Potent blockade of hepatocyte growth factor-stimulated cell motility, matrix invasion and branching morphogenesis by antagonists of Grb2 Src homology 2 domain interactions.

Hepatocyte growth factor (HGF) stimulates mitogenesis, motogenesis, and morphogenesis in a wide range of cellular targets during development, homeostasis and tissue regeneration. Inappropriate HGF signaling occurs in several human cancers, and the ability of HGF to initiate a program of protease production, cell dissociation, and motility has been shown to promote cellular invasion and is strongly linked to tumor metastasis. Upon HGF binding, several tyrosines within the intracellular domain of its receptor, c-Met, become phosphorylated and mediate the binding of effector proteins, such as Grb2. Grb2 binding through its SH2 domain is thought to link c-Met with downstream mediators of cell proliferation, shape change, and motility. We analyzed the effects of Grb2 SH2 domain antagonists on HGF signaling and observed potent blockade of cell motility, matrix invasion, and branching morphogenesis, with ED(50) values of 30 nm or less, but only modest inhibition of mitogenesis. These compounds are 1000-10,000-fold more potent anti-motility agents than any previously characterized Grb2 SH2 domain antagonists. Our results suggest that SH2 domain-mediated c-Met-Grb2 interaction contributes primarily to the motogenic and morphogenic responses to HGF, and that these compounds may have therapeutic application as anti-metastatic agents for tumors where the HGF signaling pathway is active.

Identification of BARD1 as mediator between proapoptotic stress and p53-dependent apoptosis.

The BRCA1-associated protein BARD1 is a putative tumor suppressor. We suggest that BARD1 is a mediator of apoptosis since (1) cell death in vivo (ischemic stroke) and in vitro is accompanied by increased levels of BARD1 protein and mRNA; (2) overexpression of BARD1 induces cell death with all features of apoptosis; and (3) BARD1-repressed cells are defective for the apoptotic response to genotoxic stress. The proapoptotic activity of BARD1 involves binding to and elevations of p53. BRCA1 is not required for but partially counteracts apoptosis induction by BARD1. A tumor-associated mutation Q564H of BARD1 is defective in apoptosis induction, thus suggesting a role of BARD1 in tumor suppression by mediating the signaling from proapoptotic stress toward induction of apoptosis.

Repression of the putative tumor suppressor gene Bard1 or expression of Notch4(int-3) oncogene subvert the morphogenetic properties of mammary epithelial cells.

We have investigated whether repression of the putative tumor suppressor gene BARD1 or expression of the Notch4(int-3) oncogene in non-tumorigenic mammary epithelial cells affects their in vitro morphogenetic properties. Bard1 (Brca1-associated ring domain) is a protein interacting with Brca1 and thought to be involved in Brca1-mediated tumor suppression. To investigate the potential role of Bard1 in mammary gland development, we repressed its expression in TAC-2 cells, a murine mammary epithelial cell line which, when grown in three-dimensional collagen gels, forms branching ducts in response to hepatocyte growth factor (HGF) and alveolar-like cysts in response to hydrocortisone. Whereas Bard1 repression did not markedly modify the tubulogenic response of TAC-2 cells to HGF, it dramatically altered cyst development, resulting in the formation of compact cell aggregates devoid of central lumen. In addition, when grown to post-confluence in two-dimensional cultures, Bard1-suppressed TAC-2 cells overcame contact-inhibition of cell proliferation and formed multiple cell layers. The Notch4(int-3) oncogene, which codes for a constitutively activated form of the Notch4 receptor, has been reported to induce undifferentiated carcinomas when expressed in the mammary gland. The potential effect of activated Notch4 on mammary gland morphogenesis was investigated by retroviral expression of the oncogene in TAC-2 cells. Notch4(int-3) expression was found to significantly reduce HGF-induced tubulogenesis and to markedly inhibit hydrocortisone-induced cyst formation. In addition, Notch4(int-3) expressing TAC-2 cells formed multilayers in post-confluent cultures and exhibited an invasive behavior when grown on the surface of collagen gels. Taken together, these results indicate that both repression of Bard1 and expression of Notch4(int-3) disrupt cyst morphogenesis and induce an invasive phenotype in TAC-2 mammary epithelial cells.

Regulation of VEGF and VEGF receptor expression in the rodent mammary gland during pregnancy, lactation, and involution.

Vascular endothelial growth factors (VEGFs) are endothelial cell-specific mitogens with potent angiogenic and vascular permeability-inducing properties. VEGF, VEGF-C, and VEGFRs -1, -2, and -3 were found to be expressed in post-pubertal (virgin) rodent mammary glands. VEGF was increased during pregnancy (5-fold) and lactation (15-19-fold). VEGF-C was moderately increased during pregnancy and lactation (2- and 3-fold respectively). VEGF levels were reduced by approximately 75% in cleared mouse mammary glands devoid of epithelial components, demonstrating that although the epithelial component is the major source of VEGF, approximately 25% is derived from stroma. This was confirmed by the findings (a) that VEGF transcripts were expressed predominantly in ductal and alveolar epithelial cells, and (b) that VEGF protein was localized to ductal epithelial cells as well as to the stromal compartment including vascular structures. VEGF was detected in human milk. Finally, transcripts for VEGFRs -2 and -3 were increased 2-3-fold during pregnancy, VEGFRs -1, -2 and -3 were increased 2-4-fold during lactation, and VEGFRs -2 and -3 were decreased by 20-50% during involution. These results point to a causal role for the VEGF ligand-receptor pairs in pregnancy-associated angiogenesis in the mammary gland, and suggest that they may also regulate vascular permeability during lactation.

Expression of an activated Notch4(int-3) oncoprotein disrupts morphogenesis and induces an invasive phenotype in mammary epithelial cells in vitro.

The protein encoded by the Notch4 gene is a member of the Notch/lin-12 family of transmembrane receptor proteins, which have been shown to control cell fate determination and cell differentiation in a wide variety of organisms. Expression of Notch4(int-3), a truncated form of Notch4 having most of its extracellular domain deleted, as a transgene in mice induces the formation of poorly differentiated mammary carcinomas. To establish whether Notch4(int-3) has the capacity of subverting normal epithelial architecture, we assessed the effect of Notch4(int-3) expression on the in vitro morphogenetic properties of TAC-2 mammary epithelial cells. When grown in three-dimensional collagen gels in the presence of hydrocortisone, both wild-type and LacZ-transfected TAC-2 cells formed alveolar-like structures composed of polarized epithelial cells surrounding a central lumen. In contrast, TAC-2 cells programmed to express Notch4(int-3) formed compact cell aggregates devoid of tissue-specific organization. In addition, when grown on the surface of a collagen gel, Notch4(int-3)-expressing TAC-2 cells invaded the underlying matrix, whereas TAC-2 LacZ cells remained strictly confined to the gel surface. Expression of Notch4(int-3) in TAC-2 cells also disrupted contact-inhibition of cell proliferation, resulting in cell multilayering. Our results suggest that the ability of Notch4(int-3) to subvert normal epithelial morphogenesis and to promote invasion of the extracellular matrix contributes significantly to its tumorigenic potential.

Laminin and beta1 integrins are crucial for normal mammary gland development in the mouse.

We have examined the role of integrin-extracellular matrix interactions in the morphogenesis of ductal structures in vivo using the developing mouse mammary gland as a model. At puberty, ductal growth from terminal end buds results in an arborescent network that eventually fills the gland, whereupon the buds shrink in size and become mitotically inactive. End buds are surrounded by a basement membrane, which we show contains laminin-1 and collagen IV. To address the role of cell-matrix interactions in gland development, pellets containing function-perturbing anti-beta1 integrin, anti-alpha6 integrin, and anti-laminin antibodies respectively were implanted into mammary glands at puberty. Blocking beta1 integrins dramatically reduced both the number of end buds per gland and the extent of the mammary ductal network, compared with controls. These effects were specific to the end buds since the rest of the gland architecture remained intact. Reduced development was still apparent after 6 days, but end buds subsequently reappeared, indicating that the inhibition of beta1 integrins was reversible. Similar results were obtained with anti-laminin antibodies. In contrast, no effect on morphogenesis in vivo was seen with anti-alpha6 integrin antibody, suggesting that alpha6 is not the important partner for beta1 in this system. The studies with beta1 integrin were confirmed in a culture model of ductal morphogenesis, where we show that hepatocyte growth factor (HGF)-induced tubulogenesis is dependent on functional beta1 integrins. Thus integrins and HGF cooperate to regulate ductal morphogenesis. We propose that both laminin and beta1 integrins are required to permit cellular traction through the stromal matrix and are therefore essential for maintaining end bud structure and function in normal pubertal mammary gland development.

Constitutively active mitogen-activated protein kinase kinase MEK1 disrupts morphogenesis and induces an invasive phenotype in Madin-Darby canine kidney epithelial cells.

During certain developmental processes, as well as during tumor progression, polarized epithelial cells integrated within multicellular structures convert into scattered, freely migrating fibroblast-like cells. Despite the biological and clinical importance of this phenomenon, the intracellular biochemical cascades that control the switch between the epithelial and mesenchymal phenotypes have not been elucidated. Using Madin-Darby canine kidney (MDCK) cells (clone C7) as a model system, we have assessed the potential role of the mitogen-activated protein kinase (MAPK)/ extracellular signal-regulated kinase (ERK) cascade in the modulation of epithelial plasticity. When grown in three-dimensional collagen gels, MDCK-C7 cells form spherical cysts composed of polarized epithelial cells circumscribing a central lumen. This morphogenetic behavior is profoundly subverted in MDCK-C7 cells expressing a constitutively active MAPK/ERK kinase 1 (caMEK1) mutant (C7-caMEK1 cells). When suspended in collagen gels, C7-caMEK1 cells assume an elongated fibroblastoid shape and are unable to generate multicellular cysts. In addition, when seeded onto the surface of a collagen gel, C7-caMEK1 cells penetrate extensively into the underlying matrix, unlike wild-type and mock-transfected MDCK-C7 cells, which remain confined to the surface of the gel. Similar changes in morphogenetic and invasive properties are observed in MDCK-C7F cells, a nontransfected, stably dedifferentiated derivative of MDCK-C7 cells that expresses substantially increased ERK2 activity. Both C7-caMEK1 and MDCK-C7F cells but not wild-type or mock-transfected MDCK-C7 cells express activated M(r) 72,000 gelatinase A [matrix metalloproteinase (MMP)-2] as well as elevated levels of membrane type-1 MMP. Synthetic MMP inhibitors as well as recombinant tissue inhibitor of metalloproteinases 2 and 3 suppress the invasion of collagen gels and restore the capacity of C7-caMEK1 cells to form cysts, thereby implicating the membrane type-1 MMP/MMP-2 proteolytic system in epithelial cell invasiveness and loss of multicellular organization. Taken together, our data demonstrate that increased activity of the MEK1-ERK2 signaling module in MDCK-C7 cells is associated with failure of morphogenesis and expression of a highly invasive phenotype. Sustained activation of the MAPK cascade therefore results in the destabilization of the three-dimensional architecture and the conversion of polarized epithelial cells into migrating mesenchymal-like cells.

Chromogranin A alters ductal morphogenesis and increases deposition of basement membrane components by mammary epithelial cells in vitro.

The extracellular function of chromogranin A (CgA), a glycoprotein widely distributed in secretory vesicles of neurons and neuroendocrine cells, has not been clearly established. To examine whether CgA might modulate the biological properties of epithelial cells, we used an in vitro model of ductal morphogenesis in which mammary epithelial (TAC-2) cells are grown in three-dimensional collagen gels. Whereas under control conditions TAC-2 cells formed thin, branched cords with pointed ends, in the presence of CgA they formed thicker cords with bulbous extremities, reminiscent of growing mammary ducts in vivo. Immunofluorescence analysis demonstrated that CgA increases the deposition of three major basement membrane components, i.e., collagen type IV, laminin, and perlecan, around the surface of the duct-like structures. Similar effects were observed with CgA partially digested with endoproteinase Lys-C, suggesting that one or more fragments of CgA are endowed with the same activity. These findings reveal a hitherto unsuspected activity for CgA, i.e., the ability to alter ductal morphogenesis and to promote basement membrane deposition in mammary epithelial cells.

In vitro repression of Brca1-associated RING domain gene, Bard1, induces phenotypic changes in mammary epithelial cells.

BRCA1-associated RING domain (BARD1) was identified as a protein interacting with the breast cancer gene product BRCA1. The identification of tumorigenic missense mutations within BRCA1 that impair the formation of BARD1-BRCA1 complexes, and of BARD1 mutations in breast carcinomas, sustain the view that BARD1 is involved in BRCA1-mediated tumor suppression. We have cloned the murine Bard1 gene and determined that its expression in different tissues correlates with the expression profile of Brca1. To investigate the function of Bard1, we have reduced Bard1 gene expression in TAC-2 cells, a murine mammary epithelial cell line that retains morphogenetic properties characteristic of normal breast epithelium. Partial repression of Bard1, achieved by the transfection of TAC-2 cells with plasmids constitutively expressing ribozymes or antisense RNAs, resulted in marked phenotypic changes, consisting of altered cell shape, increased cell size, high frequency of multinucleated cells, and aberrant cell cycle progression. Furthermore, Bard1-repressed cell clones overcame contact inhibition of cell proliferation when grown in monolayer cultures and lost the capacity to form luminal structures in three-dimensional collagen gels. These results demonstrate that Bard1 repression induces complex changes in mammary epithelial cell properties which are suggestive of a premalignant phenotype.

Induction of tissue inhibitor of metalloproteinases-3 is a delayed early cellular response to hepatocyte growth factor.

Hepatocyte growth factor (HGF) stimulates mitogenic, motogenic, and morphogenic responses in various cell types. We analysed HGF-responsive cells by differential display PCR to identify HGF-induced genes that mediate these biological events. One of the genes identified encoded a member of the tissue inhibitor of metalloproteinases (TIMP) family, TIMP-3. HGF transiently induced TIMP-3 mRNA in keratinocytes as well as kidney and mammary epithelial cells maximally between 4 and 6 h post-stimulation. Increased TIMP-3 protein secretion returned to basal levels within 18 h, while the expression of gelatinases A and B remained unchanged, suggesting that temporary suppression of matrix degradation is a delayed early response to HGF. Ectopic overexpression of TIMP-3 in cultured leiomyosarcoma cells conferred an epithelial morphology, reduced cell growth rate, anchorage-independent growth, and matrix invasion in vitro. Antisense suppression of TIMP-3 was associated with a scattered, fibroblastic cell morphology, as well as enhanced proliferation, anchorage-independent growth, and matrix invasion. A survey of tumor cell lines revealed an inverse relationship between metastatic potential and TIMP-3 expression level. These data suggest that early, transient TIMP-3 expression mediates specific HGF-induced phenotypic changes, and that loss of TIMP-3 expression may enhance the invasion potential of certain tumors.

Isolation of EpH4 mammary epithelial cell subpopulations which differ in their morphogenetic properties.

EpH4 is a nontumorigenic cell line derived from spontaneously immortalized mouse mammary gland epithelial cells (Fialka et al., 1996). When grown in collagen gels, EpH4 cells give rise to different types of structures, e.g., solid cords or branching tubes. By removing and subsequently dissociating single three-dimensional colonies of defined morphology, we have isolated six clonal subpopulations of EpH4 cells which display distinct morphogenetic properties in collagen gel cultures. Thus, cells from the H1B clone form branching cords devoid of a central lumen, K3A3 cells form cords enclosing small multifocal lumina, and J3B1 cells form large cavitary structures containing a wide lumen. I3G2 cells form either cords or tubes, depending on the type of serum added to the culture medium. Finally, when grown in serum-free medium, Bela cells form spherical cysts, whereas Be4a cells form long, extensively branched tubes. In additional assays of morphogenesis, i.e., cell sandwiching between two collagen gels or culture on a thick layer of Matrigel (a laminin-rich extracellular matrix), all clones form epithelial-cell lined cavitary structures, except H1B cells which are unable to generate lumina under these conditions. The EpH4 sublines we have isolated provide an in vitro system for studying the mechanisms responsible for lumen formation and branching morphogenesis, as well as for identifying the factors which subvert these developmental processes during mammary carcinogenesis.

Differential effects of hepatocyte growth factor isoforms on epithelial and endothelial tubulogenesis.

Hepatocyte growth factor (HGF)/scatter factor (SF) is a pleiotropic cytokine that acts as a mitogen, motogen, and morphogen for a variety of cell types. HGF/NK1 and HGF/NK2 are two naturally occurring truncated variants of HGF/SF, which extend from the NH2 terminus through the first and second kringle domain, respectively. Although these variants have been reported to have agonistic or antagonistic activity relative to HGF/SF in assays of cell proliferation and motility, their potential morphogenic activity has not been investigated. To address this issue, we assessed the ability of HGF/NK1 and HGF/NK2 to induce tube formation by (a) MCF-10A mammary epithelial cells grown within collagen gels and (b) human umbilical vein endothelial (HUVE) cells grown on Matrigel. We found that HGF/NK1 stimulated tubulogenesis by both MCF-10A and HUVE cells, whereas HGF/NK2 did not stimulate tubulogenesis, but efficiently antagonized the morphogenic effect of full-length HGF/SF. HGF/NK1 and HGF/NK2 also had agonistic and antagonistic effects, respectively, on MCF-10A cell proliferation and HUVE cell migration. These results demonstrate that HGF/NK1, which only consists of the NH2-terminal hairpin and first kringle domain, is sufficient to activate the intracellular signaling pathways required to induce morphogenic responses in epithelial and endothelial cells. In contrast, HGF/NK2, which differs from HGF/ NK1 by the presence of the second kringle domain, is devoid of intrinsic activity but opposes the effects of HGF/SF. The differential properties of the two HGF/SF isoforms provide a basis for the design of more potent HGF/SF agonists and antagonists.

Notch4 and Wnt-1 proteins function to regulate branching morphogenesis of mammary epithelial cells in an opposing fashion.

Elongation and branching of epithelial ducts is a crucial event during the development of the mammary gland. Branching morphogenesis of the mouse mammary epithelial TAC-2 cell line was used as an assay to examine the role of Wnt, HGF, TGF-beta, and the Notch receptors in branching morphogenesis. Wnt-1 was found to induce the elongation and branching of epithelial tubules, like HGF and TGF-beta 2, and to strongly cooperate with either HGF or TGF-beta 2 in this activity. Wnt-1 displayed morphogenetic activity in TAC-2 cells as it induced branching even under conditions that normally promote cyst formation. The Notch4(int-3) mammary oncoprotein, an activated form of the Notch4 receptor, inhibited the branching morphogenesis normally induced by HGF and TGF-beta 2. The minimal domain within the Notch4(int-3) protein required to inhibit morphogenesis consists of the CBF-1 interaction domain and the cdc10 repeat domain. Coexpression of Wnt-1 and Notch4(int-3) demonstrates that Wnt-1 can overcome the Notch-mediated inhibition of branching morphogenesis. These data suggest that Wnt and Notch signaling may play opposite roles in mammary gland development, a finding consistent with the convergence of the wingless and Notch signaling pathways found in Drosophila.

Roles of hepatocyte growth factor/scatter factor and transforming growth factor-beta1 in mammary gland ductal morphogenesis.

Epithelial-mesenchymal interactions are responsible for the unique pattern of ductal branching morphogenesis characteristic of the mammary gland. To investigate the factors which control the elongation and branching of lactiferous ducts, we developed an in vitro model of ductal morphogenesis in which clonal mouse mammary epithelial cells (TAC-2 cells) are grown in collagen gels. In this experimental system, fibroblast conditioned medium (CM)3 stimulates the formation of extensively arborized tubules. The molecule responsible for this tubulogenic effect was identified as hepatocyte growth factor/scatter factor (HGF/SF). To determine whether HGF/SF plays a role in mammary gland morphogenesis in vivo, the expression of HGF/SF and its receptor, c-Met, were analyzed in the rat mammary gland during pregnancy, lactation, and involution. Levels of HGF/SF and c-Met transcripts were progressively reduced during pregnancy, were virtually undetectable during lactation, and increased again during involution. Collectively, these in vitro and in vivo findings suggest that HGF/SF is a paracrine mediator of mammary gland ductal morphogenesis. We subsequently investigated the effect of another multifunctional cytokine, namely TGF-beta1, on branching morphogenesis of TAC-2 cells. TGF-beta1 had a striking biphasic effect: whereas relatively high concentrations of this cytokine inhibited colony formation, lower concentrations stimulated extensive elongation and branching of epithelial cords. Taken together, these studies indicate that HGF/SF is a stromal-derived paracrine mediator of mammary ductal morphogenesis, and that when present at low concentrations, TGF-beta1 can contribute to this process.

Modulation of clusterin gene expression in the rat mammary gland during pregnancy, lactation, and involution.

The mammary gland provides an excellent system for investigating factors involved in the regulation of epithelial growth, differentiation, morphogenesis, and involution. We have recently demonstrated that clusterin gene expression is associated with epithelial differentiation and morphogenesis during murine embryogenesis. In the present study, we have analyzed expression of clusterin in the rat mammary gland with particular emphasis on the periods of pregnancy and lactation. By Northern blot analysis we show that clusterin mRNA is present in virgin rat mammary glands, that it is increased during pregnancy and strongly down-regulated during lactation, and that mRNA levels return progressively to those found in virgin rats during the course of involution. Total protein levels, as assessed by Western blot analysis, were also seen to decrease during lactation. In situ hybridization showed that strong expression of clusterin was localized to epithelial cells of developing lactiferous ducts and alveoli during pregnancy, and confirmed that epithelial clusterin expression is down-regulated during lactation. This down-regulation was reproducibly observed in mothers to which pups were returned after 2 days of weaning, suggesting that maternal mammary clusterin production is under hormonal control. These results show that clusterin gene expression is highest in alveolar and tubular epithelial cells during pregnancy and lowest during lactation, when the protein synthetic machinery of differentiated alveolar epithelial cells is devoted to milk production. This suggests that clusterin may be involved not only in mammary gland involution but also in the regulation of tubuloalveolar morphogenesis and alveolar epithelial cell differentiation in the adult rat mammary gland.

TGF-beta1 induces morphogenesis of branching cords by cloned mammary epithelial cells at subpicomolar concentrations.

The factors which control the formation of lactiferous ducts during mammary gland development are not yet fully understood. To address this issue, we assessed the effect of the multifunctional cytokine transforming growth factor-beta-1 (TGF-beta1) on the morphogenetic properties of TAC-2.1 mammary epithelial cells grown in collagen gels. Here we demonstrate that TGF-beta1, has a biphasic effect on these cells: whereas relatively high concentrations (0.5-5 ng/ml) inhibit colony formation, lower concentrations (5-100 pg/ml = 200fM-4pM) stimulate colony elongation and branching, resulting in the formation of an extensive network of epithelial cords. We suggest that, in concert with other regulatory factors, low concentrations of TGF-beta1 promote mammary gland ductal morphogenesis.

Modulation of hepatocyte growth factor and c-met in the rat mammary gland during pregnancy, lactation, and involution.

Epithelial tubulogenesis is responsible for the exquisitely intricate organization of functional units of parenchymal organs. We have previously demonstrated that hepatocyte growth factor (HGF--also known as scatter factor) is a stroma-derived epithelial morphogen, which induces tubulogenesis by kidney-derived epithelial cells in vitro. The mammary gland provides a particularly attractive model for the study of epithelial morphogenesis, since its development in postnatal life involves elongation and branching of epithelial tubules. The aim of the present studies was to assess the expression and modulation of HGF and its receptor c-Met in the rat mammary gland during pregnancy, lactation, and involution. By ribonuclease protection assay, we demonstrate that levels of both HGF and c-met transcripts are progressively reduced during pregnancy, are virtually undetectable during lactation, and increase during the phase of involution to prepregnancy levels. The reduction in HGF and c-met expression corresponds to periods in which functions other than tubulogenesis predominate in the mammary gland, namely alveologenesis (mid to late pregnancy) and milk protein synthesis (lactation). Using a murine mammary gland-derived epithelial cell line, we demonstrate that levels of c-met mRNA are significantly reduced by exogenously added prolactin, providing a possible explanation for the reduction in c-met in the rat mammary gland during lactation. The potential significance of down-regulation of HGF/c-met during lactation is discussed.

Hepatocyte growth factor stimulates extensive development of branching duct-like structures by cloned mammary gland epithelial cells.

Although epithelial-mesenchymal (stromal) interactions are thought to play an important role in embryonic and postnatal development of the mammary gland, the underlying mechanisms are still poorly understood. To address this issue, we assessed the effect of fibroblast-derived diffusible factors on the growth and morphogenetic properties of a clonally derived subpopulation (clone TAC-2) of normal murine mammary gland (NMuMG) epithelial cells embedded in collagen gels. Under control conditions, TAC-2 mammary gland epithelial cells suspended within collagen gels formed either irregularly shaped cell aggregates or short branching cord-like structures. Addition of conditioned medium from Swiss 3T3 or MRC-5 fibroblasts dramatically stimulated cord formation by TAC-2 cells, resulting in the development of an extensive, highly arborized system of duct-like structures, which in appropriate sections were seen to contain a central lumen. The effect of fibroblast conditioned medium was completely abrogated by antibodies against hepatocyte growth factor (also known as scatter factor), a fibroblast-derived polypeptide that we have previously shown induces tubulogenesis by Madin-Darby canine kidney epithelial cells. Addition of exogenous recombinant human hepatocyte growth factor to collagen gel cultures of TAC-2 cells mimicked the tubulogenic activity of fibroblast conditioned medium by stimulating formation of branching duct-like structures in a dose-dependent manner, with a maximal 77-fold increase in cord length at 20 ng/ml. The effect of either fibroblast conditioned medium or hepatocyte growth factor was markedly potentiated by the simultaneous addition of hydrocortisone (1 microgram/ml), which also enhanced lumen formation. These results demonstrate that hepatocyte growth factor promotes the formation of branching duct-like structures by mammary gland epithelial cells in vitro, and suggest that it may act as a mediator of the inducing effect of mesenchyme (or stroma) on mammary gland development.

Heterogeneity and contact-dependent regulation of amylase release by individual acinar cells.

We have used a reverse hemolytic plaque assay to investigate the amylase release of single and aggregated pancreatic acinar cells. We have found that a minority of single acinar cells released detectable amounts of amylase under basal conditions and were modestly stimulated, in a dose-dependent manner, during a 30-min exposure to concentrations of carbamylcholine (CCh) ranging from 10(-8) to 10(-5) M. This stimulation was largely accounted for by the recruitment of additional secreting cells, rather than by a significant increase in their individual secretory output. We have also observed that aggregates comprising two to five acinar cells secreted more frequently and released more amylase than single acinar cells in the presence of each of the CCh concentrations tested. Under both basal conditions and following CCh stimulation, the proportion of secreting aggregates and their amylase output increased linearly with the aggregate size. Under basal conditions as well as in the presence of secretagogue concentrations in the 10(-8) - 10(-7) M range, individual cells contributed similarly to amylase secretion whether they were single or part of aggregates. By contrast, following stimulation by 10(-6) - 10(-5) M CCh, aggregated cells showed a much higher average secretion than single cells. Investigating the mechanism of this contact-dependent effect, we found that 10(-3) M heptanol did not significantly modify the secretion of single cells and markedly promoted the basal amylase release of acinar cell pairs. This effect was associated with a marked reduction in gap junctional communication between acinar cells, as evaluated by microinjection of Lucifer yellow, and was not observed during exposure to high concentrations of CCh, which also reduced junctional communication. These data show that pancreatic acinar cells are intrinsically heterogeneous in their ability to release amylase and that their basal as well as stimulated secretion are promoted by the establishment of direct intercellular contacts. Our experiments also suggest that junctional coupling contributes to the contact-dependent mechanism which enhances the recruitment of secreting cells and their individual output. These observations strengthen the view that direct interactions between acinar cells are essential in the control of pancreatic secretion.