Extracellular Matrix Modulates Expression of Cell-Surface Proteoglycan Genes in Fibroblasts

Cell-surface proteoglycans are involved in many functions, including interactions with components of the extracellular microenvironment. They also act as coreceptors that bind and modify the actions of various growth factors, cytokines, and the extracellular matrix (ECM). This study investigated the regulation by the ECM of the expression of cell-surface proteoglycans (CD44, syndecan-1–4, betaglycan, glypican-1). We examined the changes in the expression levels of cell-surface proteoglycan genes in intact tendon, monolayer culture, and under various culture conditions. There was a significant increase in the expression of CD44 and syndecan-4 mRNAs during cell isolation from the tendon. With the switch to a 3D culture environment, there was a significant increase in the expression of CD44 at each passage point relative to its expression in 2D at those passage points. Syndecan-4 mRNA also increased steadily at each passage point in 3D culture environment. This influence on cell surface proteoglycans gene expression may indicate that collagen gel culture mimics in vivo tendon environment. This study provides further insight into the regulation of cell-surface proteoglycans in ligament and tendon fibroblasts by the ECM and 3D culture conditions.     

Cultures of Ligament Fibroblasts in Fibrin Matrix Gel

The cellular properties of anterior cruciate ligament (ACL) and medial collateral ligament (MCL) fibroblasts have been analyzed in a three-dimensional fibrin matrix gel (FMG) system. The MCL fibroblasts proliferated significantly faster than ACL fibroblasts in 10% fetal bovine serum (FBS). FMG contraction resembles soft-tissue wound contraction. Transforming growth factor- &#103 1 (TGF- &#103 1) (5 ng/ml) caused a significantly faster rate of FMG contraction than control (0.5% FBS) in both ACL and MCL fibroblasts. Unlike the cells in 10% FBS, this faster rate of FMG contraction was achieved without increasing the initial cell number. In the FMG, the MCL fibroblasts demonstrated significantly higher collagen synthesis per cell than ACL fibroblasts between the days 2 and 6 of culture. These differences in properties of the ACL and MCL fibroblasts that were observed in vitro may explain the differences in the healing potential of these ligaments in vivo.     

Extracellular Matrix of Mechanically Stretched Cardiac Fibroblasts Improves Viability and Metabolic Activity of Ventricular Cells

Background: In heart, the extracellular matrix (ECM), produced by cardiac fibroblasts, is a potent regulator of heart^,s function and growth, and provides a supportive scaffold for heart cells in vitro and in vivo. Cardiac fibroblasts are subjected to mechanical loading all the time in vivo. Therefore, the influences of mechanical loading on formation and bioactivity of cardiac fibroblasts^, ECM should be investigated.Methods: Rat cardiac fibroblasts were cultured on silicone elastic membranes and stimulated with mechanical cyclic stretch. After removing the cells, the ECMs coated on the membranes were prepared, some ECMs were treated with heparinase II (GAG-lyase), then the collagen, glycosaminoglycan (GAG) and ECM proteins were assayed. Isolated neonatal rat ventricular cells were seeded on ECM-coated membranes, the viability and lactate dehydrogenase (LDH) activity of the cells after 1-7 days of culture was assayed. In addition, the ATPase activity and related protein level, glucose consumption ratio and lactic acid production ratio of the ventricular cells were analyzed by spectrophotometric methods and Western blot.Results: The cyclic stretch increased collagen and GAG levels of the ECMs, and elevated protein levels of collagen I and fibronectin. Compared with the ECMs produced by unstretched cardiac fibroblasts, the ECMs of mechanically stretched fibroblasts improved viability and LDH activity, elevated the Na⁺/K⁺-ATPase activity, sarco(endo)plasmic reticulum Ca²⁺-ATPase (SERCA) activity and SERCA 2a protein level, glucose consumption ratio and lactic acid production ratio of ventricular cells seeded on them. The treatment with heparinase II reduced GAG levels of these ECMs, and lowered these metabolism-related indices of ventricular cells cultured on the ECMs.Conclusions: Mechanical stretch promotes ECM formation of cardiac fibroblasts in vitro, the ECM of mechanically stretched cardiac fibroblasts improves metabolic activity of ventricular cells cultured in vitro, and the GAG of the ECMs is involved in regulating metabolic activity of ventricular cells.     

Effect of Cell Migration on the Maintenance of Tension on a Collagen Matrix

Although it is known that cells promote structural reorganization of the collagen architecture, how individual cells exert mechanical tension on the matrix is not clearly understood. In the present study we have investigated the mechanical interaction of individual corneal fibroblasts with a collagen matrix using an improved version of our previously described in vitro force-measurement system (Roy, P. et al. Exp. Cell Res. 232:106–117, 1997). The elastic distortion of the collagen matrix exerted by cells was temporally recorded and analyzed using a two-dimensional finite-element model to quantify the forces exerted on the matrix. Time-lapse videomicroscopy of serum-cultured cells on the matrix for up to 6 h revealed that individual fibroblasts generated measurable tension on the matrix during pseudopodial extension and slow retraction. Fast retraction, an event observed during active cell migration, was associated with dramatic release of tension on the matrix. An apparent inverse correlation was observed between cell translocation and maintenance of matrix tension. Additional experiments with cells under serum-free conditions revealed that these cells fail to generate any detectable tension on the matrix despite undergoing filopodial extension and retraction. Since serum-free cells do not form focal adhesions or stress fibers, these experimental data suggest that contractility of nonmotile cells, coupled with strong cell–matrix adhesion, is the most favorable mechanism of generating and maintaining tension on the extracellular matrix. © 1999 Biomedical Engineering Society. PAC99: 8718Ed, 8715La, 8714Ee, 4266Ct, 0270DhJoint program in Biomedical Engineering between the University of Texas Southwestern Medical Center     

Extracellular matrix modifications in the interdigital spaces of the chick embryo leg bud during the formation of ectopic digits

In previous studies we have observed that the interdigital mesenchyme of the chick leg bud, in the stages preceding the onset of cell death, retains a significant regulatory potential, forming ectopic extra digits under a variety of surgical manipulations. Most evidence suggests that interdigital extra digits are caused by the abolition of local antichondrogenic effects operating in the interdigital spaces under normal conditions rather than by modifications of the signalling mechanisms accounting for the normal patterning of the digits in early stages of development. The interdigital spaces exhibit a complex scaffold of extracellular matrix with well-defined domains of spatial distribution of type I and type VI collagens, tenascin, fibronectin, laminin and elastic matrix components that have been proposed to play a role in the establishment of the non-chondrogenic fate of the interdigital tissue in situ. In an attempt to analyze this possible role of the interdigital extracellular matrix (ECM), in the present work we have studied changes in the pattern of ECM distribution associated with the formation of extra digits. Extra digits were induced by making a T-cut in the third interdigital space of the leg but of stage 29 HH chick embryos. Subsequent modifications of the ECM were detected immunohistochemically in whole-mount specimens using laser confocal microscopy. Our results reveal that in the first hours after the operation, changes in the ECM apparently related to the healing of the wound cause a significant reorganization of the normal ECM scaffold of the interdigit. In addition, chondrogenesis of the interdigital tissue is preceded by disappearance of elastin fibers in the interdigital mesenchyme subjacent to the wound and by an intense deposition of tenascin. Tenascin deposition and loss of the elastin fibrillar scaffold were also observed preceding chondrogenesis in fragments of interdigital tissue explanted to culture conditions. The significance of these observations in relation to the establishment of the skeletal elements of the autopodium is discussed.     

Changes in Gene Expression of Matrix Constituents with Respect to Passage of Ligament and Tendon Fibroblasts

Trauma to the knee joint often results in injury to one or more supporting soft tissue structures, such as the medial collateral (MCL) and anterior cruciate (ACL) ligaments. Also, a portion of the patellar tendon (PT) is frequently used as a replacement graft for the ACL, resulting in a PT defect. The healing responses of these tissues are dramatically different and range from spontaneous healing to little or no healing. Studies have suggested that native cell behavior could be responsible for differences in healing potential. However, it is difficult to make comparisons as the reported results are based on different cellular passages which could have a dramatic effect on their potential to form healing tissues. Therefore, the objective of this study was to quantify the gene expression of collagen and other matrix constituents of fibroblasts from the MCL, ACL, and PT to document how they change with cell passage. We hypothesized that MCL fibroblasts would possess higher potential for matrix production through passages than ACL and PT cells because the MCL mounts a robust healing response unlike the ACL and PT. These differences in matrix expression would be dependent on passage because at earlier passages all cells would mostly be proliferating while at later passages they would tend to become senescent. Cells were isolated from the MCL, ACL, and PT of three rats and passaged a total of five times (Passage 1 to Passage 5). Using real time RT-PCR, expression of all genes of interest (Collagen Type I (ligament/tendon’s main matrix constituent), Collagen Type III, Fibronectin, Metalloprotease-13 [MMP-13], and Tissue Inhibitor of Metallopreotease-1 [TIMP-1]) were quantitatively assessed. It was found that cell number for all three fibroblast types remained high from Passage 1 to Passage 5. There was a statistically significant increase in Collagen Type I of rat MCL fibroblasts throughout passage (p < 0.05). This was evident in the higher relative abundance (to GAPDH) at Passages 3 and 4 (14.5 ± 2.2 fold and 15.3 ± 6.9 fold, respectively) than at Passage 1 (3.3 ± 2.6 fold) (p < 0.05). On the other hand, Collagen Type I expression for ACL and PT fibroblasts were lower than that of MCL fibroblasts and remained at 2.5 ± 2.0 fold and 1.7 ± 0.8 fold, respectively. Interestingly, the gene expressions of Collagen Type III, Fibronectin, MMP-13, and TIMP-1 for MCL, ACL, and PT fibroblasts were all relatively constant throughout passage and were not significantly different from one another. The findings of this study indicate that passage does affect the Collagen Type I gene expression of rat MCL fibroblasts and further show that for in vitro ligament tissue engineering efforts, MCL fibroblasts have a more robust potential for ligament remodeling and repair due to the increase in collagen gene expression.     

Growth Characteristics of Retinal Capillary Endothelial Cells Compared with Pulmonary Vein Endothelial Cells in Culture

Bovine retinal capillary endothelial cells (RCECs) and pulmonary vein endothelial cells (PVECs) were isolated and investigated in plate culture, three-dimensional culture and in co-culture with pericytes. In plate culture, RCECs required growth factor in the medium for growth whereas PVECs did not. Phenotypic modulation (a tendency to become similar morphologically to smooth muscle cells, and to accumulate into thread-like structures) was observed in PVECs but not in RCECs. In three-dimensional culture, RCECs contracted, aggregated and were unable to proliferate. Proliferation was elicited when the gel matrix was adsorbed by fibronectin or upon co-culture with pericytes. In contrast, PVECs not only proliferated but also formed tubular structures. In co-culture with pericytes, PVECs in close contact with, or in near apposition to pericytes formed tubular structures earlier than those without contact in the same dish. These results provide new findings about differences in the growth characteristics of endothelial cells between microvessels and large vessels. In addition, it is considered that pericytes may promote tube formation by endothelial cells in three-dimensional culture. Acta Pathol Jpn 41: 133-142, 1991.     

Changes in Extracellular Matrix Materials in the Uterine Myometrium of Rats during Pregnancy and Postparturition

Morphological changes in extracellular matrix materials in the uterine myometrium of rats during pregnancy and postparturition were studied by light and electron microscopy together with immunofluorescence microscopy for type III and IV collagens, fibronectin and laminin. The main components present in late pregnancy were 1) various-sized collagen fibrils, 2) thick elastic fibers adjacent to smooth muscle cells, and 3) continuous and thick basement membranes of hypertrophic smooth muscle cells. These findings are considered to indicate degradation of collagen fibrils and development of elastic fibers and basement membranes of smooth muscle cells. This change in extracellular matrix materials in the late stage of pregnancy may be important in the process of uterine enlargement associated with elasticity and preparation for labor. In the postpartum stage, myofibroblastic interstitial cells were seen to phagocytize collagen fibrils, and elastic fibers accumulated mainly around the bundles of smooth muscle cells. These changes in the postpartum stage are thought to be important for the process in which the uterus returns to the nonpregnant condition. It is suggested that smooth muscle cells participate in regulating the development of their basement membranes and elastic fibers, and that myofibroblastic interstitial cells function by clearing degraded collagen fibrils from the uterine myometrium. Acta Pathol Jpn 41: 122-132, 1991.     

Modulation of Growth Factor Action by the Extracellular Matrix

Growth factors were historically defined as molecules produced by the body to regulate cell growth and proliferation. After the identification of their receptors and the intracellular signaling machinery they activate, it is now clear that they are involved in the regulation of multiple processes essential for development and normal tissue function. The present review gives a brief overview of growth factor action. Receptor activation and signaling are discussed, highlighting the role of extracellular matrix interactions.     

Characterization of Superparamagnetic Nanoparticle Interactions with Extracellular Matrix in an in Vitro System

Controlled dispersion of therapeutic agents within liquid- and gel-filled cavities represents a barrier to treatment of some cancers and other pathological states. Interstitial delivery is compromised by the poor mobility of macromolecules and larger nanoscale structures. We developed an in vitro system to quantify the suitability of superparamagnetic nanoparticles (SPM NPs) as a site-specific therapeutic vehicle for delivery through fluid- and gel-based systems. SPM NP motion was induced by an external magnetic field. NP migration was modulated by NP concentration and surface coating. 135 nanometer radius PEGylated NPs moved through the extracellular matrix with an average velocity of 1.5 mm h⁻¹, suitable for some clinical applications. Increasing the SPM NP radius to 400 nm while maintaining the same per NP magnetic susceptibility resulted in a greater than 1000-fold reduction in magnetic mobility, to less than 0.01 mm h⁻¹. The critical influence of NP size on gel permeation was also observed in silica-coated 135 nm SPM NPs that aggregated under the experimental conditions. Aggregation played a critical role in determining the behavior of the nanoparticles. SPM NPs allow significant free-solution mobility to specific sites within a cavity and generate sufficient force to penetrate common in vivo gels.     

Collagen Protein Abnormalities Produced by Site-Directed Mutagenesis of the Proal(I) Gene

Site-directed mutagenesis of collagen genes offers a powerful new approach for studying structure-function relationships. The construction of engineered mutant collagen genes coding for glycine substitutions and their expression giving rise to the osteogenesis imperfecta type II phenotype in cells and transgenic mice has recently been achieved^I. This paper further defines the molecular abnormalities of collagen and bone pathology resulting from the expression of the mutant genes.     

The Role of IL-4 and IL-12 in the Regulation of Collagen Synthesis by Fibroblasts

Chronic sclerodermifomic graft versus host disease is a rare but important complication of allogeneic hematopoietic stem cell transplantation that especially occurs in patients who are treated with donor lymphocyte infusions for relapse of a malignant disease. Today most knowledge about the pathogenesis of chronic Graft-versus-Host Disease is based on mice models. In this report we describe the development of an allogeneic in vitro model that allows studying the pathogenesis of chronic sclerodermifomic Graft-versus-Host Disease in the human setting. We report that priming of mononuclear cells in the presence of allogeneic fibroblasts and Interleukin (IL)-4 induces fibroblast collagen synthesis, whereas priming in the presence of IL-12 suppresses collagen synthesis during subsequent coculture of primed mononuclear cells with allogeneic fibroblasts. Since IL-12 is also known to mediate anti-tumor effects by stimulation of Natural Killer cell and Lymphokine Activated Killer cell activity, these findings indicate that treatment of patients with IL-12 or pretreatment of donor lymphocytes with IL-12 might strengthen a graft versus leukemia effect and at the same time decrease the risk of chronic sclerodermifomic Graft-versus-Host Disease development.     

Temporal Effects of Cyclic Stretching on Distribution and Gene Expression of Integrin and Cytoskeleton by Ligament Fibroblasts In Vitro

Cyclic stretching is pivotal to maintenance of the ligaments. However, it is still not clear when ligament fibroblasts switch on expression of genes related to the mechanotransduction pathway in response to cyclic stretching. This in vitro study investigated, using ligament fibroblasts, the time-dependent changes in distribution and gene expression of β1 integrin, the cytoskeleton, and collagens after the application of 6% cyclic stretching at a frequency of 0.1 Hz for 3 hr on silicon membranes. We carried out confocal laser scanning microscopy to demonstrate changes in distribution of these components as well as quantitative real-time RT-PCR to quantify levels of these gene expression both during application of cyclic stretching and at 0, 2, 6, 12, and 18 hr after the termination of stretching. Control (unstretched) cells were used at each time point. Within 1 hr of the application of stretching, the fibroblasts and their actin stress fibers became aligned in a direction perpendicular to the major axis of stretch, whereas control (unstretched) cells were randomly distributed. In response to cyclic stretching, upregulation of actin at the mRNA level was first observed within 1 hr after the onset of stretching, while upregulation of β1 integrin and type I and type III collagens was observed between 2 and 12 hr after the termination of stretching. These results indicate that the fibroblasts quickly modify their morphology in response to cyclic stretching, and subsequently they upregulate the expression of genes related to the mechanotransduction pathway mainly during the resting period after the termination of stretching.     

NaOH消蚀法制备骨细胞外基质材料的实验研究

目的 :　研制一各新型的天然骨移植替代材料 ,为其临床应用提供实验依据。方法 :　采用NaOH消蚀法制作家兔骨细胞外基质支架 ,扫描电镜观察 ;对支架行生物相容性实验 ,将支架埋植于兔背部肌肉内 ,分别于术后 1周、2周、4周、6周取出行组织学观察 ,X射线能谱分析埋植前、后化学元素组成的改变。结果 :　 (1)SEM观察 ,以NaOH消蚀处理后 ,骨组织中的细胞成分被彻底清除掉 ,细胞外基质成分 -胶原纤维及骨盐则维持原有形态及三维立体网状结构。 (2 )光镜下观察 ,支架周围有成纤维细胞及毛细血管增生 ,轻度淋巴浸润 ;支架结构随埋植时间渐稀疏、紊乱。 (3)X射线能谱分析结果 ,埋植后钙原子含量低于埋植前水平 (p <0 .0 0 1)。结论 :　NaOH消蚀骨支架作为骨移植替代材料 ,其三维立体网状结构为成骨细胞发挥功能提供了有利空间 ,有可能作为骨组织工程中种子细胞的载体 ;骨盐的存在使其具有一定的力学强度 ,适宜修复较大节段的骨缺损 ;组织相容性好 ,在体内可降解吸收。     

Zonal Uniformity in Mechanical Properties of the Chondrocyte Pericellular Matrix: Micropipette Aspiration of Canine Chondrons Isolated by Cartilage Homogenization

The pericellular matrix (PCM) is a region of tissue that surrounds chondrocytes in articular cartilage and together with the enclosed cells is termed the chondron. Previous studies suggest that the mechanical properties of the PCM, relative to those of the chondrocyte and the extracellular matrix (ECM), may significantly influence the stress–strain, physicochemical, and fluid-flow environments of the cell. The aim of this study was to measure the biomechanical properties of the PCM of mechanically isolated chondrons and to test the hypothesis that the Young's modulus of the PCM varies with zone of origin in articular cartilage (surface vs. middle/deep). Chondrons were extracted from articular cartilage of the canine knee using mechanical homogenization, and the elastic properties of the PCM were determined using micropipette aspiration in combination with theoretical models of the chondron as an elastic incompressible half-space, an elastic compressible bilayer, or an elastic compressible shell. The Young's modulus of the PCM was significantly higher than that reported for isolated chondrocytes but over an order of magnitude lower than that of the cartilage ECM. No significant differences were observed in the Young's modulus of the PCM between surface zone (24.0 ± 8.9 kPa) and middle/deep zone cartilage (23.2 ± 7.1 kPa). In combination with previous theoretical biomechanical models of the chondron, these findings suggest that the PCM significantly influences the mechanical environment of the chondrocyte in articular cartilage and therefore may play a role in modulating cellular responses to micromechanical factors.     

Extracellular Matrix Composition of Full-Thickness Defect Repair Tissue is Little Influenced by Exercise in Rat Articular Cartilage

Full-thickness articular cartilage defects in the femoral condyles of adult rats were examined four and eight weeks after injury. Quantitative polarized light microscopic analysis showed that birefringence of the tissue in the central repair area increased more in rats exercised on a treadmill. Glycosaminoglycan content in the repair tissue was also higher than in the intermit-tent active motion group at four weeks after injury, but by eight weeks the levels were similar in both groups. No normal-looking articular cartilage was formed in the lesions, and only in one animal type II collagen was observed in the superficial zone of repair tissue. No 3B3(-) antigenicity of the proteoglycans was seen during repair. In conclusion, exercise minimally modified the repair of full-thickness articular cartilage defects in adult rats. The repair in the exercised group may occur slightly faster in the early stages but no difference was seen at the eight week time interval between the exercised and the intermittently active group.     

Three-Dimensional Culture Environment Increases the Efficacy of Platelet Rich Plasma Releasate in Prompting Skin Fibroblast Differentiation and Extracellular Matrix Formation

Platelet rich plasma clot- releasate (PRCR) shows significant influence on tissue regeneration in clinical trials. Although, the mechanism of PRCR effect on fibroblast differentiation has been studied on 2D culture system, a detailed investigation is needed to establish the role of PRCR in cell seeded in 3D scaffolds. Therefore, a study was conducted to evaluate the influence of PRCR in fibroblasts (DFB) differentiation and extracellular matrix formation on both 3D and 2D culture systems. Cell viability was measured using MTT assay and DFB differentiation was evaluated by determining the expression levels of nucleostamin and alpha smooth muscle actin (α-SMA), using indirect immunostaining and Western blotting. The expression levels of extracellular matrix genes (collagen-I, collagen-III, fibronectin and laminin) and focal adhesion formation gene (integrin beta-1) were measured using Real-time PCR. The PRCR at 10% showed significant effect on cells viability compared with 5% and 20% in both culture environments. The decrease in the expression levels of nucleostamin and the increase in α-SMA signify the DFB differentiation to myofibroblast-like cells that was prominently greater in 3D compared to 2D culture. In 3D culture systems, the total collage production, expression levels of the extracellular matrix gene and the focal adhesion gene were increased significantly compared to 2D culture. In conclusion, 3D culture environments enhances the proliferative and differentiation effects of PRCR on DFB, thereby potentially increases the efficacy of DFB for future tissue engineering clinical application.