Extracellular matrix proteins involved in pseudoislets formation

Extracellular matrix proteins are known to mediate, through integrins, cell adhesion and are involved in a number of cellular processes, including insulin expression and secretion in pancreatic islets. We investigated whether expression of some extracellular matrix proteins were implied in islets-like structure formation, named pseudoislets. For this purpose, we cultured the β-cell line, RINm5F, during 1, 3, 5 and 7 days of culture on treated or untreated culture plate to form adherent cells or pseudoislets and analysed insulin, collagen IV, fibronectin, laminin 5 and β1-integrin expression. We observed that insulin expression and secretion were increased during pseudoislets formation. Moreover, we showed by immunohistochemistry an aggregation of insulin secreting cells in the centre of the pseudoislets. Peripheral β-cells of pseudoislets did not express insulin after 7 days of culture. RT-PCR and immunohistochemistry studies showed a transient expression of type IV collagen in pseudoislets for the first 3 days of culture. Study of fibronectin expression indicated that adherent cells expressed more fibronectin than pseudoislets. In contrast, laminin 5 was more expressed in pseudoislets than in adherent cells. Finally, expression of β1-integrin was increased in pseudoislets as compared to adherent cells. In conclusion, laminin 5 and collagen IV might be implicated in pseudoislets formation whereas fibronectin might be involved in cell adhesion. These data suggested that extracellular matrix proteins may enhance the function of pseudoislets.     

Extracellular matrix changes regulate calcium crystal formation in articular cartilage

PURPOSE OF REVIEW: The pathologic matrix mineralization seen in calcium pyrophosphate dihydrate and basic calcium phosphate deposition diseases identifies a subset of osteoarthritis patients with an unusual joint distribution and rapid progression of disease. Several factors contribute to pathologic matrix mineralization, including changes in the extracellular matrix of articular cartilage. The factors contributing to extracellular matrix changes that promote crystal formation are important and not well understood. Better characterization of these factors will enhance the understanding of the pathogenesis of pathologic matrix mineralization and may identify potential targets for novel therapeutic interventions. RECENT FINDINGS: Histologic studies of cartilage from patients affected by calcium crystal arthritis show changes in the pericellular matrix of articular chondrocytes. The amounts and types of collagens, proteoglycans, and calcium-binding proteins are altered. The mechanisms by which these changes occur remain poorly understood. Recent work, however, has implicated alterations in the chondrocyte phenotype and post-translational matrix-modulating enzymes such as the transglutaminases. SUMMARY: Changes in extracellular matrix are associated with the pathologic matrix mineralization seen in calcium pyrophosphate dihydrate and basic calcium phosphate crystal deposition diseases. The literature on growth plate cartilage provides observations and mechanisms through which extracellular matrix contributes to normal matrix mineralization, and has served as a model on which to base studies in articular cartilage. More studies are warranted to enhance the understanding of how changes in extracellular matrix contribute to crystal deposition diseases.     

Extracellular matrix formation in piecemeal necrosis: immunoelectron microscopic study

ABSTRACT— Immunolocalization of Type I, Type III and Type IV collagens, laminin and prolyl hydroxylase (PH), a key enzyme in collagen synthesis, was examined to clarify the fibrotic process in chronic, active liver disease. In piecemeal necrosis of chronic, active hepatitis (CAH) and active liver cirrhosis (LC), fat-storing cells (FSCs) and transitional cells (TSCs), containing abundant rough endoplasmic reticulum (RER), were increased in number and stained intensely for PH. Immunodeposits of extracellular matrix (ECM) components were found in the RER, Golgi apparatus (GA) and vesicles of these cells, especially in cases with marked inflammation. On the other hand, in the periportal areas of chronic, persistent hepatitis (CPH) or inactive LC, immunoreaction of ECM components was seldom found in the RER of FSCs and TSCs. In the portal tract, immunodeposits of ECM components were seldom found in the organelles of fibroblasts, although ECM was increased there. These findings indicate that FSCs and TSCs in piecemeal necrosis might play a role in the production of ECM components in the progression of fibrosis during the development of chronic active liver disease. In addition, ECM component production by FSCs and TSCs is associated with marked inflammation.     

Extracellular matrix formation in piecemeal necrosis: immunoelectron microscopic study.

Immunolocalization of Type I, Type III and Type IV collagens, laminin and prolyl hydroxylase (PH), a key enzyme in collagen synthesis, was examined to clarify the fibrotic process in chronic, active liver disease. In piecemeal necrosis of chronic, active hepatitis (CAH) and active liver cirrhosis (LC), fat-storing cells (FSCs) and transitional cells (TSCs), containing abundant rough endoplasmic reticulum (RER), were increased in number and stained intensely for PH. Immunodeposits of extracellular matrix (ECM) components were found in the RER, Golgi apparatus (GA) and vesicles of these cells, especially in cases with marked inflammation. On the other hand, in the periportal areas of chronic, persistent hepatitis (CPH) or inactive LC, immunoreaction of ECM components was seldom found in the RER of FSCs and TSCs. In the portal tract, immunodeposits of ECM components were seldom found in the organelles of fibroblasts, although ECM was increased there. These findings indicate that FSCs and TSCs in piecemeal necrosis might play a role in the production of ECM components in the progression of fibrosis during the development of chronic active liver disease. In addition, ECM component production by FSCs and TSCs is associated with marked inflammation.     

Regulation of cytoskeletal proteins involved in cell contact formation during differentiation of granulosa cells on extracellular matrix.

The organization and the expression of cytoskeletal proteins involved in determining cell contact and shape were analyzed in granulosa cells during their differentiation on extracellular matrix (ECM)-coated culture plates. Rat granulosa cells from preovulatory follicles displayed an epithelial shape on ECM and formed multilayered aggregates with numerous gap junctions between neighboring cells. These cells had few actin cables and often only a diffuse pattern of actin and a low amount of vinculin in very thin focal adhesion sites. In contrast, cells grown on plastic formed a monolayer of flat cells with a reduced number of gap junctions but with numerous stress fibers and abundant large vinculin-containing focal contacts. On ECM, the cells were stimulated to produce high levels of progesterone, while only trace amounts of the steroid accumulated in cells on plastic dishes. Two-dimensional gel electrophoretic analysis of [35S]methionine-labeled cells revealed a dramatic decrease in vinculin, alpha-actinin, and actin synthesis in cells grown on ECM, as compared to cells grown on plastic, while the synthesis of the tubulins and of the intermediate filament protein vimentin remained unchanged. RNA blot analysis showed a marked decrease in actin mRNA levels in cells from ECM plates, while the level of tubulin mRNA remained essentially unchanged. It is concluded that the differentiation of granulosa cells on ECM in vitro is associated with changes in cell shape and cell contacts and that such changes in cell morphology are accompanied by simultaneous alterations in the organization and expression of cytoskeletal proteins that are involved in determining these cellular structures.     

Extracellular matrix in ovarian follicles

A lot is known about the control of the development of ovarian follicles by growth factors and hormones, but less is known about the roles of extracellular matrix in the control of follicular growth and development. In this review we focus on the specialized extracellular matrix of the basal laminas that are present in ovarian follicles. These include the follicular basal lamina itself, the Call-Exner bodies of the membrana granulosa, the subendothelial and arteriole smooth muscle basal laminas in the theca, and the basal lamina-like material of the thecal matrix. We discuss the evidence that during follicle development the follicular basal lamina changes in composition, that many of its components are produced by the granulosa cells, and that the follicular basal laminas of different follicles have different ultrastructural appearances, linked to the shape of the aligning granulosa cells. All these studies suggest that the follicular basal lamina is extremely dynamic during follicular development.     

Extracellular matrix proteins protect pancreatic cancer cells from death via mitochondrial and nonmitochondrial pathways

BACKGROUND AND AIMS: Pancreatic cancer is a very aggressive malignancy. Normal cells die through apoptosis when detached from extracellular matrix (ECM), but the role of ECM in cancer cell survival is poorly understood. Here, we determined the effects of ECM proteins on death responses and underlying signaling pathways in human pancreatic cancer cells. METHODS: We measured apoptosis and necrosis, caspase activation, and mitochondrial dysfunction in MIA PaCa-2 and PANC-1 pancreatic carcinoma cells both detached and attached to ECM proteins. RESULTS: Detachment of pancreatic cancer cells from ECM did not induce classic apoptosis, as it does in normal cells, but induced necrosis and apoptosis associated with secondary necrosis. It caused a pronounced mitochondrial depolarization and release of cytochrome c and Smac/DIABLO. However, as different from normal cells, cytochrome c release did not result in downstream caspase activation. Executioner caspases were activated in detached pancreatic cancer cells independent of cytochrome c. Laminin and fibronectin, but not collagen I, markedly increased pancreatic cancer cell survival by inhibiting both mitochondrial dysfunction (leading to inhibition of necrosis) and caspase activity (leading to decreased apoptotic DNA fragmentation). CONCLUSIONS: ECM proteins greatly protect pancreatic cancer cells from death by mechanisms different from those operating in normal cells. The results suggest ECM proteins and their receptors as potential targets for treatment of pancreatic cancer.     

Extracellular matrix and cardiac remodelling

Cardiac remodelling associated with primitive and secondary cardiomyopathy is generally associated with changes in the expression in extracellular matrix (ECM) proteins as well as their transmembrane receptors, the integrins. It emerges now that the ECM provides a structural, chemical, and mechanical substrate that is essential in cardiac function and responses to pathophysiological signals. This review will describe the various elements of the ECM, its modifications that are associated with cardiac hypertrophy and heart failure, and the molecular basis bringing a better insight into the dynamics of the ECM.     

细胞外基质与肝脏疾病

编者按细胞外基质(extracellular matrix,ECM)是指位于机体细胞外的非细胞性的有形或无定形基质成分.以往人们多注意细胞内成分及其功能,认为细胞外基质只是为细胞或组织提供力学支持和物理强度的作用.近年来,随着对细胞代谢和功能的深入研究,发现细胞外基质对组织细胞的增生、分化、代谢、运动等多方面发挥重要作用,细胞外基质自身也不是一成不变的,也是处于不断的转换(tumover)中.由于细胞外基质的不断变化,尤其是在某些病理状态下的变化使细胞外基质发生了质和量的改变,造成了细胞周围微环境的改变,直接影响着细胞的功能和器官的形态.肝脏疾病的发展过程一般是由早期的各种因素造成组织细胞的损伤和炎症,随着损伤的持续和炎症的慢性化,细胞外基质在肝内不断沉积,形成肝脏的纤维化;如果损伤因素持续存在,纤维化不断发展,造成肝脏的正常结构消失,假小叶形成而发展为肝硬变.在肝硬变形成后,由于各种致病因子的作用及细胞微环境的改变,可致使个别细胞发生突变而形成肝细胞癌.肝细胞癌如果能够大量产生破坏细胞外基质的金属蛋白酶,则可破坏肿瘤周围由细胞外基质形成的包膜或基底膜,造成对周围组织的侵犯,如果侵入血管或淋巴管,则造成血路或淋巴路的转移.由此可见,细胞外基质在肝脏疾病的各个阶段都发挥着重要的作用,深入研究肝脏细胞外基质的功能和代谢,对阐明慢性肝病的发生和发展有重要价值.为此,我们邀请有关专家对细胞外基质与肝病的关系进行系统的介绍和讨论.     

Extracellular matrix fibrotic markers in heart failure

Given the importance of fibrous tissue in leading to myocardial dysfunction, non-invasive assessment of fibrosis could prove a clinically useful tool in heart failure (HF) patients. Biomarkers may be used for early detection of otherwise subclinical disease, diagnostic assessment of an acute or chronic clinical syndrome, risk stratification of patients with a suspected or confirmed diagnosis, selection of an appropriate therapeutic intervention and monitoring the response to therapy. Extracellular matrix (ECM) biomarkers in HF are promising biomarkers. They are able to detect early changes in heart and large vessel structure and function and transition to HF. High ECM biomarker levels have been associated with poor outcome. The ability of treatment to reduce myocardial fibrosis in HF patients may be monitored by the measurement of various serum peptides arising from the metabolism of collagen types. Biomarkers may be selectively influenced by pharmacological agents.     

Extracellular matrix alterations in hypertensive vascular remodeling

Vascular cells are very sensitive to their hemodynamic environment. Any change in blood pressure or blood flow can be sensed by endothelial and vascular smooth muscle cells and ultimately results in structural modifications within the vascular wall that accommodate the new conditions. In the case of hypertension, the increase in arterial stretch stimulates vessel thickening to normalize the tensile forces. This process requires modification of the extracellular matrix and of cell-matrix interactions, which mainly involves extracellular proteases. In hypertension, chronic exposure of the arterial wall to stretch leads to vascular remodeling, arterial stiffness and calcification, which finally affect target organ function. This review surveys how mechanical stretch regulates extracellular proteases, considering the signaling pathways involved and the consequences on the cardiovascular system.     

Extracellular matrix and pathogenic mechanisms in osteoarthritis

Osteoarthritis (OA) is a heterogeneous condition of joint degeneration characterized by structural changes in extracellular matrices such as subchondral bone and cartilage. Research has identified many diverse ways of initiating OA, varying from mechanical disruption to gene mutations in structural proteins. A frequent end point is cartilage loss, which can occur irrespective of the initiating mechanism. Of the mechanisms responsible for cartilage matrix damage, a disintegrin and metalloproteinase with thrombospondin motifs (ADAMTS)-5 was identified as of key importance in knockout mice, but work with human cartilage has suggested that ADAMTS-4 was also involved. A transgenic mouse expressing aggrecan lacking a key aggrecanase site clearly showed that loss of aggrecan from cartilage was an important step in both inflammatory and trauma-induced joint degeneration. In OA, cartilage chondrocytes show changes in gene expression, and it remains to be resolved if this reflects adaptive responses to changes in biological, physical, and mechanical signaling rather than any form of differentiation.     

Extracellular matrix structure after heart transplantation

Following heart transplantation remodeling of the donor heart causes changes in the extracellular myocardial matrix. We investigated 20 right ventricular endomyocardial biopsies taken 17+/-4 days (group I, n=9) and 63+/-13 days (group II, n=11) after heart transplantation from 16 patients transplanted for end-stage cardiomyopathy (15 dilated/1 ischemic). Immunohistochemical staining for collagen I, collagen III, collagen IV, and fibronectin was used. Evaluation was performed at a magnification of 400x using a computer-assisted image analyzing system measuring the relative area stained by the immunoperoxidase method, the number of cells in the given area, and the total area. Collagen I per cell was 13.9+/-5.9 microm2 in group I and increased significantly 66+/-13 days after heart transplantation in the perimysium around the myocardial cells as well as in the endocardium to 49.9+/-15.1 microm2 (P<0.05). No quantitative change in collagen III was noted (75.7+/-12.4 versus 75.5+/-16.0 microm2 n.s.). Collagen IV was found in the perimysial, in the capillary bed and in the vascular network. Significant quantitative change in the amount of collagen IV was not found (64.1+/-12.6 versus 61.0+/-8.9 microm2). Fibronectin was found in the entire perimysial extracellular matrix and in the endocardium in relationship with collagen I and III. An increased amount of fibronectin from 87.09+/-9.9 microm2 (group I) to 140.8+/-17.9 microm2 (group II, P<0.05) was found. The cell area and cell diameters were not significantly different (group I; cell area 772+/-227 microm2, diameter 31.3 microm; group II; cell area 776+/-224 microm2, diameter 31.4 microm). It is concluded that remodeling of the donor heart after transplantation is characterized by a specific increase in collagen I and fibronectin, whereas a change in other collagen subtypes was not observed.     

Extracellular matrix in normal and fibrotic human lungs

Polyclonal affinity-purified antibodies to human collagen types I, III, and IV, and laminin were used to compare the extracellular matrix (ECM) in 10 normal and 32 abnormal lungs by indirect immunofluorescence. In normal lungs, type IV collagen and laminin codistributed in a uniform linear pattern along the epithelial and endothelial basement membranes. Type III collagen was found within the alveolar septa and interstitium in an interrupted ribbonlike pattern and was aggregated at the entrance rings of the alveoli. Type I collagen was distributed irregularly within the alveolar wall and was less prominent than type III collagen. In patients with pulmonary disease not characterized by interstitial fibrosis (n = 15), the distribution of ECM components studied was essentially normal. In pulmonary disease in which interstitial fibrosis was the characteristic feature, such as idiopathic pulmonary fibrosis (IPF) and adult respiratory distress syndrome (ARDS) (n = 17), collagen types I and III accumulated in the expanded interstitium. Type III collagen was initially predominant in the thickened alveolar septa and interstitium, whereas type I collagen appeared to be the principal collagen at later stages in the disease course. The basement membrane was disrupted early in the disease course with invasion of the alveolar spaces by interstitial collagens similar in type to those present in the adjacent interstitium.