PDGF­stimulated dispersal of cell clusters and disruption of fibronectin matrix on three-dimensional collagen matrices requires matrix metalloproteinase-2.

Formation of cell clusters is a common morphogenic cell behavior observed during tissue and organ development and homeostasis, as well as during pathological disorders. Dynamic regulation of cell clustering depends on the balance between contraction of cells into clusters and migration of cells as dispersed individuals. Previously we reported that under procontractile culture conditions, fibronectin fibrillar matrix assembly by human fibroblasts functioned as a nucleation center for cell clustering on three-dimensional collagen matrices. Here we report that switching preformed cell clusters from procontractile to promigratory culture conditions results in cell dispersal out of clusters and disruption of FN matrix. Experiments using small interfering RNA silencing and pharmacological inhibition demonstrated that matrix metalloproteinase activity involving MMP-2 was necessary for fibronectin matrix disruption and dispersal of cell clusters.

The different roles of myosin IIA and myosin IIB in contraction of 3D collagen matrices by human fibroblasts.

Contraction of 3D collagen matrices by fibroblasts frequently is used as an in vitro model of wound closure. Different iterations of the model - all conventionally referred to as "contraction" - involve different morphological patterns. During floating matrix contraction, cells initially are round without stress fibers and subsequently undergo spreading. During stressed matrix contraction, cells initially are spread with stress fibers and subsequently undergo shortening. In the current studies, we used siRNA silencing of myosin IIA (MyoIIA) and myosin IIB (MyoIIB) to test the roles of myosin II isoforms in fibroblast interactions with 3D collagen matrices and collagen matrix contraction. We found that MyoIIA but not MyoIIB was required for cellular global inward contractile force, formation of actin stress fibers, and morphogenic cell clustering. Stressed matrix contraction required MyoIIA but not MyoIIB. Either MyoIIA or MyoIIB was sufficient for floating matrix contraction (FMC) stimulated by platelet-derived growth factor. Neither MyoIIA or MyoIIB was necessary for FMC stimulated by serum. Our findings suggest that myosin II-dependent motor mechanisms for collagen translocation during extracellular matrix remodeling differ depending on cell tension and growth factor stimulation.

Fibroblast cluster formation on 3D collagen matrices requires cell contraction dependent fibronectin matrix organization.

Fibroblasts incubated on 3D collagen matrices in serum or lysophosphatidic acid (LPA)-containing medium self-organize into clusters through a mechanism that requires cell contraction. However, in platelet-derived growth factor (PDGF)-containing medium, cells migrate as individuals and do not form clusters even though they constantly encounter each other. Here, we present evidence that a required function of cell contraction in clustering is formation of fibronectin (FN) fibrillar matrix. We found that in serum or LPA but not in PDGF or basal medium, cells organized FN (both serum and cellular) into a fibrillar, detergent-insoluble matrix. Cell clusters developed concomitant with FN matrix formation. FN fibrils accumulated beneath cells and along the borders of cell clusters in regions of cell-matrix tension. Blocking Rho kinase or myosin II activity prevented FN matrix assembly and cell clustering. Using siRNA silencing and function-blocking antibodies and peptides, we found that cell clustering and FN matrix assembly required α5ß1 integrins and fibronectin. Cells were still able to exert contractile force and compact the collagen matrix under the latter conditions, which showed that contraction was not sufficient for cell clustering to occur. Our findings provide new insights into how procontractile (serum/LPA) and promigratory (PDGF) growth factor environments can differentially regulate FN matrix assembly by fibroblasts interacting with collagen matrices and thereby influence mesenchymal cell morphogenetic behavior under physiologic circumstances such as wound repair, morphogenesis and malignancy.

The effect of growth factor environment on fibroblast morphological response to substrate stiffness.

According to conventional understanding regarding dependence of cell behavior on substrate stiffness, tissue cells typically remain round on soft substrates but spread on stiff substrates. The current studies were carried out to learn if the growth factor environment influenced the foregoing relationship. Using standard methods, we prepared planar (2D) polyacrylamide (PA) gels ranging from 0.5 to 40 kPa and covalently cross-linked with fibronectin and collagen at concentrations ranging from 2.5 to 50 µg/ml. We carried out experiments with fibroblasts varying in their ability to form actin stress fibers and focal adhesions. In fetal bovine serum (FBS) containing medium--the growth factor environment in which most studies on cell spreading and substrate stiffness have been carried out--cell spreading increased with increasing substrate stiffness and adhesion ligand density. However, in platelet-derived growth factor (PDGF) containing medium, cell spreading was relatively independent of substrate stiffness and adhesion ligand density except little cell attachment occurred in the complete absence of cross-linked adhesion ligands. If cell contraction was blocked with blebbistatin, then cell spreading in FBS-containing medium became independent of substrate stiffness. The findings suggest that under growth factor conditions that stimulate global cell contraction (FBS), cell spreading cannot occur unless adhesion ligand density and substrate stiffness result in cell-substrate interactions strong enough to resist and overcome the inward tractional force. Under growth factor conditions that stimulate global cell protrusion (PDGF), such resistance is not required.

Modifications of the defense and remodeling functionalities of bovine neutrophils inside the mammary gland of milk stasis cows received a commercial dry-cow treatment.

An appropriate length of milk stasis between two consecutive lactations of dairy cows is crucial for sustainable milk production. This dry period of cows allows extensive remodeling and sufficient cell renewal in mammary gland. Nevertheless, early dry period is one of the most risky stages in cow lactation cycle to intramammary infection. Dry-cow treatment through teats is, therefore, widely practiced at the commencement of milk stasis. Neutrophils are the most abundant cellular components in cow mammary secretion during early dry period, which in turn attribute to the meanwhile elevation of somatic cell counts and matrix metalloproteinase-9 (MMP-9) level. This study used bovine peripheral neutrophils as a cell model to examine the mode of modifications in their defense and remodeling functionalities after infiltration into mammary gland during early dry period. Results indicate a dose-dependent suppression of phorbol 12-myristate 13-acetate-stimulated free radical production and induction of MMP 9 degranulation in bovine peripheral neutrophils exposure to the d 7-dry secretion of cows received dry cow treatment at d 0 in milk stasis. Meanwhile, an enhancement of plasminogen activation and TNF-α shedding on bovine peripheral neutrophils were also observed. These two cellular events might be involved in the functional modifications on infiltrated neutrophils during early dry period. In conclusion, the opposite trend of modifications in the defense and matrix remodeling functionalities of neutrophils inside the mammary gland of cows at early dry period reflect the collaboration of infiltrated neutrophils for promoting extensive glandular remodeling at minimum compromise of local defense during the acute involution period without apparent disturbance by dry cow treatment.

Promigratory and procontractile growth factor environments differentially regulate cell morphogenesis.

Three-dimensional (3D) cell-matrix cultures provide a useful model to analyze and dissect the structural, functional, and mechanical aspects of cell-matrix interactions and motile behavior important for cell and tissue morphogenesis. In the current studies we tested the effects of serum and physiological growth factors on the morphogenetic behavior of human fibroblasts cultured on the surfaces of 3D collagen matrices. Fibroblasts in medium containing serum contracted into clusters, whereas cells in medium containing platelet-derived growth factor (PDGF) were observed to migrate as individuals. The clustering activity of serum appeared to depend on lysophosphatidic acid, required cell contraction based on inhibition by blocking Rho kinase or myosin II, and was reversed upon switching to PDGF. Oncogenic Ras transformed human fibroblasts did not exhibit serum-stimulated cell clustering. Our findings emphasize the importance of cell-specific promigratory and procontractile growth factor environments in the differential regulation of cell motile function and cell morphogenesis.

Oncogenic Ras-transformed human fibroblasts exhibit differential changes in contraction and migration in 3D collagen matrices.

Tractional force exerted by tissue cells in 3D collagen matrices can be utilized for matrix remodeling or cell migration. The interrelationship between these motile processes is not well understood. The current studies were carried out to test the consequences of oncogenic Ras (H-Ras(V12)) transformation on human fibroblast contraction and migration in 3D collagen matrices. Beginning with hTERT-immortalized cells, we prepared fibroblasts stably transformed with E6/E7 and with the combination HPV16 E6/E7 and H-Ras(V12). Oncogenic Ras-transformed cells lost contact inhibition of cell growth, formed colonies in soft agar and were unable to make adherens junctions. We observed no changes in the extent or growth factor dependence of collagen matrix contraction (floating or stress-relaxation) by oncogenic Ras-transformed cells. On the other hand, transformed cells in nested collagen matrices lost not only growth factor selectivity, but also cell-matrix density-dependent inhibition of migration. These findings demonstrate differential regulation of collagen matrix contraction and cell migration in 3D collagen matrices.

Distinguishing fibroblast promigratory and procontractile growth factor environments in 3-D collagen matrices.

Understanding growth factor function during wound repair is necessary for the development of therapeutic interventions to improve healing outcomes. In the current study, we compare the effects of serum and purified growth factors on human fibroblast function in three different collagen matrix models: cell migration in nested matrices, floating matrix contraction, and stressed-released matrix contraction. The results of these studies indicate that platelet-derived growth factor (PDGF) is unique in its capacity to promote cell migration. Serum, lysophosphatidic acid, sphingosine-1-phophate (S1P), and endothelin-1 promote stressed-released matrix contraction but not cell migration. In addition, we found that S1P inhibits fibroblast migration and treatment of serum to remove lipid growth factors or treatment of cells to interfere with S1P(2) receptor function increases serum promigratory activity. Our findings suggest that different sets of growth factors generate promigratory and procontractile tissue environments for fibroblasts and that the balance between PDGF and S1P is a key determinant of fibroblast promigratory activity.

Microtubule function in fibroblast spreading is modulated according to the tension state of cell-matrix interactions.

Mechanical and physical features of the extracellular environment dramatically impact cell shape. Fibroblasts interacting with 3D relaxed collagen matrices appear much different from cells on 2D collagen-coated surfaces and form dendritic cell extensions that contain microtubule cores and actin-rich tips. We found that interfering with cellular microtubules caused cells in relaxed matrices to remain round and unable to form dendritic extensions, whereas fibroblasts on coverslips formed lamellipodial extensions and were spread completely without microtubules but were unable to become polarized. Fibroblasts in relaxed collagen matrices lack stress fibers, focal adhesions, and focal adhesion signaling. Fibroblasts on collagen-coated coverslips that were unable to develop stress fibers and focal adhesions, because of either adding blebbistatin to the cells or use of soft coverslips, also formed microtubule-dependent dendritic extensions. Conversely, fibroblasts interacting with precontracted collagen matrices developed stress fibers and lamellipodial extensions and required microtubules for polarization but not spreading. Our findings demonstrate an unexpected relationship between the role of microtubules in cell spreading and the tension state of cell-matrix interactions. At a low tension state (absence of stress fibers and focal adhesions) typical of fibroblasts in relaxed collagen matrices, cells spread with dendritic extensions whose formation requires microtubules; at a high tension state (stress fibers and focal adhesions) typical of cells on coverslips, cells spread with lamellipodial extensions and microtubules are required for cell polarization but not for spreading.

Different molecular motors mediate platelet-derived growth factor and lysophosphatidic acid-stimulated floating collagen matrix contraction.

Fibroblast-collagen matrix contraction has been used as a model system to study how cells organize connective tissue. Previous work showed that lysophosphatidic acid (LPA)-stimulated floating collagen matrix contraction is independent of Rho kinase, whereas platelet-derived growth factor (PDGF)-stimulated contraction is Rho kinase-dependent. The current studies were carried out to learn more about the molecular motors responsible for LPA- and PDGF-stimulated contraction. We found that neither PDGF nor LPA-dependent contractile mechanisms require myosin II regulatory light chain kinase or increased phosphorylation of myosin II regulatory light chain (measured as diphosphorylation). Low concentrations of the specific myosin II inhibitor blebbistatin blocked PDGF-stimulated matrix contraction and LPA-stimulated retraction of fibroblast dendritic extensions but not LPA-stimulated matrix contraction. These data suggest that PDGF- and LPA-stimulated floating matrix contraction utilize myosin II-dependent and -independent mechanisms, respectively. LPA-dependent, Rho kinase-independent force generation also was detected during fibroblast spreading on collagen-coated coverslips.

LPA-stimulated fibroblast contraction of floating collagen matrices does not require Rho kinase activity or retraction of fibroblast extensions.

Fibroblasts synthesize, organize, and maintain connective tissues during development and in response to injury and fibrotic disease. These morphogenetic processes depend on cell-matrix remodeling, which has been investigated using cells cultured in three-dimensional collagen matrices. The current studies were carried out to test the role of Rho kinase activity and retraction of fibroblast extensions on the matrix remodeling process. We found that remodeling (contraction) of floating collagen matrices stimulated by lysophosphatidic acid (LPA) did not require Rho kinase activity or retraction of fibroblast extensions. On the other hand, LPA-stimulated contraction of restrained matrices became Rho kinase dependent after the matrices were allowed to develop mechanical loading for 2-4 h, suggesting that the remodeling process itself was able to feed back to modulate cell behavior in an iterative process. Modulation was specific for LPA since fibroblast-collagen matrix contraction stimulated by platelet-derived growth factor was Rho kinase dependent before or after mechanical loading developed.

Dendritic fibroblasts in three-dimensional collagen matrices.

Cell motility determines form and function of multicellular organisms. Most studies on fibroblast motility have been carried out using cells on the surfaces of culture dishes. In situ, however, the environment for fibroblasts is the three-dimensional extracellular matrix. In the current research, we studied the morphology and motility of human fibroblasts embedded in floating collagen matrices at a cell density below that required for global matrix remodeling (i.e., contraction). Under these conditions, cells were observed to project and retract a dendritic network of extensions. These extensions contained microtubule cores with actin concentrated at the tips resembling growth cones. Platelet-derived growth factor promoted formation of the network; lysophosphatidic acid stimulated its retraction in a Rho and Rho kinase-dependent manner. The dendritic network also supported metabolic coupling between cells. We suggest that the dendritic network provides a mechanism by which fibroblasts explore and become interconnected to each other in three-dimensional space.

Transforming growth factor beta stimulates fibroblast-collagen matrix contraction by different mechanisms in mechanically loaded and unloaded matrices.

Studies were carried out to test the idea that transforming growth factor beta (TGFbeta) stimulated fibroblast contraction of collagen matrices by different mechanisms depending on mechanical loading on the cells and matrix. Under mechanically unloaded conditions (floating matrices), TGFbeta stimulated contraction directly as an agonist and indirectly by preactivating cells to express the myofibroblast phenotype. Increased contraction of floating matrices by preactivated cells appeared to result in part from an autocrine mechanism. Under mechanically loaded conditions (stressed matrices), TGFbeta had no direct agonist effect on contraction. Fibroblasts preactivated to become myofibroblasts showed increased ability to transfer tension to stressed matrices, and tension persisted even after the cells' actin cytoskeleton was disrupted. Our findings are consistent with the idea that fibroblasts activated to become myofibroblasts in vitro have increased contractile activity and indicate that multiple mechanisms that differ depending on mechanical loading on the cells and matrix are involved.