α5ß1-Integrin promotes tension-dependent mammary epithelial cell invasion by engaging the fibronectin synergy site.

Tumors are fibrotic and characterized by abundant, remodeled, and cross-linked collagen that stiffens the extracellular matrix stroma. The stiffened collagenous stroma fosters malignant transformation of the tissue by increasing tumor cell tension to promote focal adhesion formation and potentiate growth factor receptor signaling through kinase. Importantly, collagen cross-linking requires fibronectin (FN). Fibrotic tumors contain abundant FN, and tumor cells frequently up-regulate the FN receptor α5ß1 integrin. Using transgenic and xenograft models and tunable two- and three-dimensional substrates, we show that FN-bound α5ß1 integrin promotes tension-dependent malignant transformation through engagement of the synergy site that enhances integrin adhesion force. We determined that ligation of the synergy site of FN permits tumor cells to engage a zyxin-stabilized, vinculin-linked scaffold that facilitates nucleation of phosphatidylinositol (3,4,5)-triphosphate at the plasma membrane to enhance phosphoinositide 3-kinase (PI3K)-dependent tumor cell invasion. The data explain why rigid collagen fibrils potentiate PI3K activation to promote malignancy and offer a perspective regarding the consistent up-regulation of α5ß1 integrin and FN in many tumors and their correlation with cancer aggression.

A self-assembling peptide matrix used to control stiffness and binding site density supports the formation of microvascular networks in three dimensions.

A three-dimensional (3-D) cell culture system that allows control of both substrate stiffness and integrin binding density was created and characterized. This system consisted of two self-assembling peptide (SAP) sequences that were mixed in different ratios to achieve the desired gel stiffness and adhesiveness. The specific peptides used were KFE ((acetyl)-FKFEFKFE-CONH2), which has previously been reported not to support cell adhesion or MVN formation, and KFE-RGD ((acetyl)-GRGDSP-GG-FKFEFKFE-CONH2), which is a similar sequence that incorporates the RGD integrin binding site. Storage modulus for these gels ranged from ∼60 to 6000Pa, depending on their composition and concentration. Atomic force microscopy revealed ECM-like fiber microarchitecture of gels consisting of both pure KFE and pure KFE-RGD as well as mixtures of the two peptides. This system was used to study the contributions of both matrix stiffness and adhesiveness on microvascular network (MVN) formation of endothelial cells and the morphology of human mesenchymal stem cells (hMSC). When endothelial cells were encapsulated within 3-D gel matrices without binding sites, little cell elongation and no network formation occurred, regardless of the stiffness. In contrast, matrices containing the RGD binding site facilitated robust MVN formation, and the extent of this MVN formation was inversely proportional to matrix stiffness. Compared with a matrix of the same stiffness with no binding sites, a matrix containing RGD-functionalized peptides resulted in a ∼2.5-fold increase in the average length of network structure, which was used as a quantitative measure of MVN formation. Matrices with hMSC facilitated an increased number and length of cellular projections at higher stiffness when RGD was present, but induced a round morphology at every stiffness when RGD was absent. Taken together, these results demonstrate the ability to control both substrate stiffness and binding site density within 3-D cell-populated gels and reveal an important role for both stiffness and adhesion on cellular behavior that is cell-type specific.

Improved microvascular network in vitro by human blood outgrowth endothelial cells relative to vessel-derived endothelial cells.

Evidence suggests that bone marrow-derived cells circulating in adult blood, sometimes called endothelial progenitor cells, contribute to neovascularization in vivo and give rise to cells expressing endothelial markers in culture. To explore the utility of blood-derived cells expressing an endothelial phenotype for creating tissue-engineered microvascular networks, we employed a three-dimensional in vitro angiogenesis model to compare microvascular network formation by human blood outgrowth endothelial cells (HBOECs) with three human vessel-derived endothelial cell (EC) types: human umbilical vein ECs (HUVECs), and adult and neonatal human microvascular ECs. Under every condition investigated, HBOECs within collagen gels elongated significantly more than any other cell type. Under all conditions investigated, gel contraction and cell elongation were correlated, with HBOECs demonstrating the largest generation of force. HBOECs did not exhibit a survival advantage, nor did they enhance elongation of HUVECs when the two cell types were cocultured. Network formation of both HBOECs and HUVECs was inhibited by blocking antibodies to alpha2beta1, but not alpha(v)beta3, integrins. Taken together, these data suggest that superior network exhibited by HBOECs relative to vessel-derived endothelial cells is not due to a survival advantage, use of different integrins, or secretion of an autocrine/paracrine factor, but may be related to increased force generation.

The relative magnitudes of endothelial force generation and matrix stiffness modulate capillary morphogenesis in vitro.

When suspended in collagen gels, endothelial cells elongate and form capillary-like networks containing lumens. Human blood outgrowth endothelial cells (HBOEC) suspended in relatively rigid 3 mg/ml floating collagen gels, formed in vivo-like, thin, branched multi-cellular structures with small, thick-walled lumens, while human umbilical vein endothelial cells (HUVEC) formed fewer multi-cellular structures, had a spread appearance, and had larger lumens. HBOEC exert more traction on collagen gels than HUVEC as evidenced by greater contraction of floating gels. When the stiffness of floating gels was decreased by decreasing the collagen concentration from 3 to 1.5 mg/ml, HUVEC contracted gels more and formed thin, multi-cellular structures with small lumens, similar in appearance to HBOEC in floating 3 mg/ml gels. In contrast to floating gels, traction forces exerted by cells in mechanically constrained gels encounter considerable resistance. In constrained collagen gels (3 mg/ml), both cell types appeared spread, formed structures with fewer cells, had larger, thinner-walled lumens than in floating gels, and showed prominent actin stress fibers, not seen in floating gels. These results suggest that the relative magnitudes of cellular force generation and apparent matrix stiffness modulate capillary morphogenesis in vitro and that this balance may play a role in regulating angiogenesis in vivo.

Bone morphogenetic protein 9: a potent modulator of cartilage development in vitro.

Few publications describe the activity of bone morphogenetic protein-9 (BMP-9), but the consensus of these largely in vivo studies is that while BMP-9 can induce ectopic bone formation at relatively large concentrations, it is primarily active in non-skeletal locations--including the liver, nervous system and marrow. To study the effects of BMP-9 on chondrogenesis in a well-defined environment, calf articular chondrocytes were seeded onto biodegradable PGA scaffolds. The resulting cell-polymer constructs were cultured in either control medium or medium supplemented with 1, 10, 50 or 100 ng/ml of BMP-9. After 4 weeks of in vitro culture, all concentrations of BMP-9 increased the total mass of the constructs, and the amounts of collagen, glycosaminoglycans (GAG) and cells per construct. On a mass percentage basis, BMP-9 tended to increase GAG, to decrease the relative amount of collagen and had little effect on the relative amount of cells. BMP-9 elicited qualitatively similar responses as BMP-2, -12 and -13. However, in contrast to BMP-12 and -13, BMP-9 (at concentrations > or = 10 ng/ml) induced hypertrophic chondrocyte formation and was the only BMP tested to induce mineralization. Taken together, these data suggest that BMP-9 is a potent modulator of cartilage development in vitro.

Noninvasive determination of perfused artery dimensions ex vivo using a pressure-diameter relationship.

Based on the decisive effects of the hemodynamic and mechanical environments on the development and remodeling of arteries in vivo, several groups have cultured tissue-engineered vessels and excised vessels in various mechanically active perfusion systems. To facilitate the interpretation and design of such studies, accurate estimates of the applied forces and resulting stresses are required, which in turn require an accurate estimate of vessel dimensions. The measured pressure drop along the length of the vessel could be used to calculate the average inner diameter, but practical considerations, including the modest accuracy of many pressure transducers, limit this approach. Using nine porcine arteries harvested from pigs weighing between 25 and 100 kg, we show that when real-time measurements of the pressure drop and the outer diameter during a vasoactive event are fit to a theoretical model, offset errors in the pressure measurement can be compensated for and estimates of vessel wall transverse area with an average error of 4.1% (not exceeding 8.3%) are achieved.

Mechanical environment, donor age, and presence of endothelium interact to modulate porcine artery viability ex vivo.

Though ex vivo culture of arteries is a widely used model of native arteries and is closely aligned with efforts to generate tissue-engineered arteries, the effects of culture conditions on artery viability are poorly characterized. To investigate factors regulating long-term viability of cultured arteries, carotid arteries from neonatal and adolescent pigs were perfused for up to 27 days with steady laminar flow ranging from approximately 2% to approximately 200% of physiological flow rates. Arteries from neonatal animals (2 weeks old, approximately 5 kg) were susceptible to spontaneous progressive endothelial denudation followed by deterioration of the vessel wall that spread from luminal to abluminal regions. Subphysiological levels of flow and pressure abrogated this deterioration. Arteries harvested from adolescent (6 months old, approximately 100 kg) animals maintained viability and retained structure for at least 9 days as assessed by normal histology, presence of intact endothelium, normal mitochondrial activity, and low levels of cell death and proliferation, unless the vessels were subjected to superphysiological levels of flow or the endothelium was intentionally denuded. Adolescent arteries perfused at subphysiological, but not physiological, flow rates maintained viability and normal structure for at least 27 days. These data indicate that under the appropriate conditions, arteries may be cultured long term but careful attention to the viability is merited.

Bone morphogenetic proteins-2, -12, and -13 modulate in vitro development of engineered cartilage.

Bovine calf articular chondrocytes were seeded onto biodegradable polyglycolic acid (PGA) scaffolds and cultured in either control medium or medium supplemented with 1, 10, or 100 ng/mL of bone morphogenetic proteins (BMPs) BMP-2, BMP-12, or BMP-13. Under all conditions investigated, cell-polymer constructs cultivated for 4 weeks in vitro macroscopically and histologically resembled native cartilage. Addition of 100 ng/mL of BMP-2, BMP-12, or BMP-13 increased the total mass of the constructs relative to the controls by 121%, 80%, and 62%, respectively, which was accompanied by increases in the absolute amounts of collagen, glycosaminoglycans (GAG), and cells. The addition of 100 ng/mL of BMP-2, BMP-12, or BMP-13 increased the weight percentage of GAG in the constructs by 27%, 18%, and 15%, and decreased the weight percent of total collagen to 63%, 89%, and 83% of controls, respectively. BMP-2, but not BMP-12 or BMP-13 promoted chondrocyte hypertrophy. Taken together, these data suggest that BMP-2, BMP-12, and BMP-13 increase growth rate and modulate the composition of engineered cartilage and that 100 ng/mL of BMP-2 has the greatest effect. In addition, in vitro engineered cartilage provides a system for studying the effects of BMPs on chondrogenesis in a well-defined environment.

Systemic delivery of human growth hormone using genetically modified tissue-engineered microvascular networks: prolonged delivery and endothelial survival with inclusion of nonendothelial cells.

Endothelial cells have the potential to provide efficient long-term delivery of therapeutic proteins to the circulation if a sufficient number of genetically modified endothelial cells can be incorporated into the host vasculature and if these cells persist for an adequate period of time. Here we describe the ability of nonendothelial cells to modulate the survival of implanted endothelial cells and their incorporation into host vasculature. Bovine aortic endothelial cells (BAECs) suspended in Matrigel and cultured in vitro remained spherical and decreased in number over time. Subcutaneous implantation of gels containing BAECs secreting human growth hormone (hGH) in mice initially resulted in detectable plasma hGH levels, which were undetectable after 2 weeks. When mixed with fibroblasts and suspended in Matrigel, hGH-secreting BAECs formed microvascular networks in vitro. Implantation of these gels resulted in plasma hGH levels that decreased slightly over 2 weeks and then remained stable for at least 6 weeks. BAECs incorporated into blood vessels within both the implant and fibrous capsule that surrounded and invaded implants. Within implants containing BAECs and fibroblasts, viable BAECs were present for at least 6 weeks at a higher density than in implants containing BAECs alone at 3 weeks. These results indicate that implanted BAECs can incorporate into host blood vessels and that inclusion of fibroblasts in this system prolongs BAEC survival and hGH delivery.

IGF-I and mechanical environment interact to modulate engineered cartilage development.

Bovine calf articular chondrocytes were seeded onto biodegradable polyglycolic acid scaffolds and cultured for four weeks using in vitro systems providing different mechanical environments (static and mixed Petri dishes, static and mixed flasks, and rotating vessels) and different biochemical environments (medium with and without supplemental insulin-like growth factor I, IGF-I). Under all conditions, the resulting engineered tissue histologically resembled cartilage and contained its major constituents: glycosaminoglycans, collagen, and cells. The mechanical environment and supplemental IGF-I (a) independently modulated tissue morphology, growth, biochemical composition, and mechanical properties (equilibrium modulus) of engineered cartilage as previously reported; (b) interacted additively or in some cases nonadditively producing results not suggested by the independent responses, and (c) in combination produced tissue superior to that obtained by modifying these factors individually.

Effects of mixing intensity on tissue-engineered cartilage.

Mechanical forces regulate the structure and function of many tissues in vivo; recent results indicate that the mechanical environment can decisively influence the development of engineered tissues cultured in vitro. To investigate the effects of the hydrodynamic environment on tissue-engineered cartilage, primary bovine calf chondrocytes were seeded on fibrous polyglycolic acid meshes and cultured in spinner flasks either statically or at one of nine different turbulent mixing intensities. In medium from unmixed flasks, CO(2) accumulated and O(2) was depleted, whereas in medium from mixed flasks the concentrations of both gases approached their equilibrium values. Relative to constructs exposed to nonmixed conditions, constructs exposed to mixing contained higher fractions of collagen, synthesized and released more GAG, but contained lower fractions of GAG. Across the wide range of mixing intensities investigated, the presence or absence of mixing, but not the intensity of the mixing, was the primary determinant of the GAG and collagen content in the constructs. The all-or-none nature of these responses may provide insight into the mechanism(s) by which engineered cartilage perceives changes in its hydrodynamic environment and responds by modifying extracellular matrix production and release. 2001 John Wiley & Sons, Inc.

Biomaterial-microvasculature interactions.

The utility of implanted sensors, drug-delivery systems, immunoisolation devices, engineered cells, and engineered tissues can be limited by inadequate transport to and from the circulation. As the primary function of the microvasculature is to facilitate transport between the circulation and the surrounding tissue, interactions between biomaterials and the microvasculature have been explored to understand the mechanisms controlling transport to implanted objects and ultimately improve it. This review surveys work on biomaterial-microvasculature interactions with a focus on the use of biomaterials to regulate the structure and function of the microvasculature. Several applications in which biomaterial-microvasculature interactions play a crucial role are briefly presented. These applications provide motivation and framework for a more in-depth discussion of general principles that appear to govern biomaterial-microvasculature interactions (i.e., the microarchitecture and physio-chemical properties of a biomaterial as well as the local biochemical environment).

Exogenous, basal, and flow-induced nitric oxide production and endothelial cell proliferation.

The role of nitric oxide (NO) from endogenous and exogenous sources in regulating large vessel and microvascular endothelial cell proliferation was investigated. Exogenous NO liberated from five different chemical donors inhibited bovine aortic, bovine retinal microvascular, and human umbilical vein endothelial cell proliferation in a dose-dependent manner as determined by 3H-thymidine incorporation. The potency of the donors varied as a function of the donors' half-lives. Donors with half-lives greater than 30 min were more effective than donors with significantly shorter half-lives. Coincubation of endothelial cells with 0.4 mM deoxyadenosine and 0.4 mM deoxyguanosine reduced the percentage of inhibition due to an NO donor. These data are consistent with a ribonucleotide reductase-dependent mechanism of inhibition. Inhibition of basal NO production with four different inhibitors of nitric oxide synthase (NOS) did not modify proliferation. Laminar flow with a wall shear stress of 22 dyn/cm2 inhibited the proliferation of subconfluent bovine aortic endothelial cells. The addition of a NOS inhibitor did not abrogate the flow-induced inhibition of proliferation, suggesting that flow-stimulated release of NO from endothelial cells did not account for flow-induced inhibition of proliferation. Taken together, these data suggest that relatively large concentrations of exogenous NO inhibit endothelial cell proliferation, while endogenous levels of NO are inadequate to inhibit proliferation.

The nucleation of receptor-mediated endocytosis.

A theory of the mechanical origins of receptor-mediated endocytosis shows that a spontaneous membrane complex formation can provide the stimulus for a local membrane motion toward the cytosol. This motion is identified with a nucleation stage of receptor-mediated endocytosis. When membrane complexes cluster, membrane deformation is predicted to be most rapid. The rate of growth of membrane depressions depends upon the relative rates of approach of aqueous cytosolic and extracellular fluids toward the cell membrane. With cytosolic and extracellular media characterized by apparent viscosities, the rate of growth of membrane depressions is predicted to increase as the extracellular viscosity nears the apparent viscosity of the cytosol and then to decrease when the extracellular viscosity exceeds that of the cytosol. To determine whether these trends would be apparent in the overall endocytosis rate constant, an experimental study of transferrin-mediated endocytosis in two different cell lines was conducted. The experimental results reveal the same dependence of internalization rate on extracellular viscosity as predicted by the theory. These and other comparisons with experimental data suggest that the nucleation stage of receptor-mediated endocytosis is important in the overall endocytosis process.

Flow- and bradykinin-induced nitric oxide production by endothelial cells is independent of membrane potential.

The objective of this study was to evaluate the role transmembrane potential plays in flow-induced nitric oxide (NO) production in endothelial cells (EC). NO production was monitored by measuring intracellular guanosine 3',5'-cyclic monophosphate (cGMP) and extracellular nitrite plus nitrate (NOx). Primary human umbilical vein endothelial cells (HUVEC) were exposed to laminar flow (22 dyn/cm2) of medium with 5.4 mM KCl (control medium) with or without 3 mM tetraethylammonium chloride (TEA) or 90 mM KCl (K(+)-rich medium). Bradykinin (BK) was added to time-matched stationary cultures to give a final concentration of 5 nM. With control medium, 30 s, 2 min, and 3 h of treatment with flow or 2 min of treatment with BK resulted in an approximately threefold increase in cGMP over stationary cultures. Depolarization with KCl or TEA did not influence cGMP production in flow-treated or stationary cultures. Flow of either control or potassium-rich medium resulted in an approximately 10-fold increase in average NOx production rate over 3 h compared with stationary cultures. Taken together these data indicate that neither membrane hyperpolarization nor normal membrane potential is necessary for flow- or BK-induced NO production by HUVEC.

Shear sensitivity in animal cell culture.

Over the past year, considerable progress has been made in understanding shear sensitivity in animal cell culture as a result of extensive theoretical and experimental work. Here we review this progress, paying special attention to the physical and biological mechanisms by which mechanical forces act upon cells, and the effects of such forces.