Andreas R. Klatt

Complexes of Matrilin-1 and Biglycan or Decorin Connect Collagen VI Microfibrils to Both Collagen II and Aggrecan

Native supramolecular assemblies containing collagen VI microfibrils and associated extracellular matrix proteins were isolated from Swarm rat chondrosarcoma tissue. Their composition and spatial organization were characterized by electron microscopy and immunological detection of molecular constituents. The small leucine-rich repeat (LRR) proteoglycans biglycan and decorin were bound to the N-terminal region of collagen VI. Chondroadherin, another member of the LRR family, was identified both at the N and C termini of collagen VI. Matrilin-1, -3, and -4 were found in complexes with biglycan or decorin at the N terminus. The interactions between collagen VI, biglycan, decorin, and matrilin-1 were studied in detail and revealed a biglycan/matrilin-1 or decorin/matrilin-1 complex acting as a linkage between collagen VI microfibrils and aggrecan or alternatively collagen II. The complexes between matrilin-1 and biglycan or decorin were also reconstituted in vitro. Colocalization of collagen VI and the different ligands in the pericellular matrix of cultured chondrosarcoma cells supported the physiological relevance of the observed interactions in matrix assembly.

Molecular Structure and Tissue Distribution of Matrilin-3, a Filament-forming Extracellular Matrix Protein Expressed during Skeletal Development

Matrilin-3 is a recently identified member of the superfamily of proteins containing von Willebrand factor A-like domains and is able to form hetero-oligomers with matrilin-1 (cartilage matrix protein) via a C-terminal coiled-coil domain. Full-length matrilin-3 and a fragment lacking the assembly domain were expressed in 293-EBNA cells, purified, and subjected to biochemical characterization. Recombinantly expressed full-length matrilin-3 occurs as monomers, dimers, trimers, and tetramers, as detected by electron microscopy and SDS-polyacrylamide gel electrophoresis, whereas matrilin-3, purified from fetal calf cartilage, forms homotetramers as well as hetero-oligomers of variable stoichiometry with matrilin-1. In the matrix formed by cultured chondrosarcoma cells, matrilin-3 is found in a filamentous, collagen-dependent network connecting cells and in a collagen-independent pericellular network. Affinity-purified antibodies detect matrilin-3 expression in a variety of mouse cartilaginous tissues, such as sternum, articular, and epiphyseal cartilage, and in the cartilage anlage of developing bones. It is found both inside the lacunae and in the interterritorial matrix of the resting, proliferating, hypertrophic, and calcified cartilage zones, whereas the expression is lower in the superficial articular cartilage. In trachea and in costal cartilage of adult mice, an expression was seen in the perichondrium. Furthermore, matrilin-3 is found in bone, and its expression is, therefore, not restricted to chondroblasts and chondrocytes.

The matrilins: modulators of extracellular matrix assembly.

The matrilins form a family of oligomeric extracellular adaptor proteins that are most strongly expressed in cartilage but also present in many other extracellular matrices. Matrilins bind to different types of collagen fibrils, to other noncollagenous proteins and to aggrecan. They thereby support matrix assembly by connecting fibrillar components and mediating interactions between these and the aggrecan gel. The binding avidity of a matrilin can be varied by alternative splicing, proteolytic processing and formation of homo- and heterooligomers. Such changes in matrilin structure may lead to a modulation of extracellular matrix assembly. Some matrilins bind weakly to α1β1 integrin and cell surface proteoglycans, but even though matrilins play a role in mechanotransduction and matrilin-3 activates the expression of osteoarthritis-associated genes the physiological relevance of matrilin-cell interactions is unclear. Matrilin knockout mice do not display pronounced phenotypes, which points to a redundancy within the protein family or with functionally related proteins. In man, dominant mutations in the von Willebrand factor A like domain of matrilin-3 lead to a protein retention in the endoplasmic reticulum that causes multiple epiphyseal dysplasia by initiating a cell stress response. In contrast, a mutation in an EGF domain of matrilin-3 that is associated with hand osteoarthritis and disc degeneration does not interfere with secretion but instead with extracellular assembly of matrix structures. In this review we summarize such information on matrilin structure and function that we believe is important for the understanding of extracellular matrix assembly and for deciphering pathophysiological mechanisms in diseases causing skeletal malformations or cartilage degeneration.

A critical role for collagen II in cartilage matrix degradation: collagen II induces pro-inflammatory cytokines and MMPs in primary human chondrocytes.

We report a process that results in the acceleration of matrix degradation in human articular cartilage, a phenomenon commonly observed in osteoarthritis (OA). The study was conducted by (1) examining the potential of collagen II in modulating the gene expression profile of primary human chondrocytes (PHCs), and (2) investigating the involvement of pro‐inflammatory signaling cascades. We first tested the collagen II‐dependent induction of pro‐inflammatory cytokines and matrix metalloproteinases (MMPs) in PHCs. PHCs were incubated with or without monomeric (i.e., nonfibrillar) collagen II. Cells were then analyzed by RT‐PCR for the expression of MMP1, MMP3, MMP13, MMP14, and IL‐1β. ELISA was used to quantify IL‐6 and IL‐8 release. To examine the influence of collagen II signaling, specifically the role of MAPK p38, a p38‐inhibitor was added prior to collagen treatment. Changes in IκB concentration were monitored by immunoblot analysis to detect NFκB signaling. Results indicated that incubation of PHCs with collagen II did produce a dose‐dependent induction of MMP1, MMP3, MMP13, MMP14, as well as cytokines IL‐1β, IL‐6, and IL‐8. At the same time, inhibition of p38 and IκB degradation revealed that collagen II‐dependent gene induction also involves MAPK p38 and NFκB signaling. Thus, we provide evidence for a collagen II‐dependent feed‐forward mechanism whereby collagen II induces first MMPs and pro‐inflammatory cytokines and then release of collagen II fragments from mature collagen II fibers. This, in turn, induces more pro‐inflammatory cytokines and MMPs, and the process is repeated, which results in the acceleration and perpetuation of cartilage matrix degradation.

Expression of matrilins during maturation of mouse skeletal tissues

The matrilins are a recently discovered family of non-collagenous extracellular matrix proteins. During embryogenesis, all matrilins are expressed in skeletal tissues. Additionally, matrilin-2 and -4 are expressed in the dermis and in connective tissues of internal organs, e.g. of the lung and kidney. After birth, the expression of matrilin-1 and -3 remains specific for cartilage and bone whereas matrilin-2 and -4 display a broader tissue distribution and could be detected in epithelial, muscle, and nervous tissue as well as in loose and dense connective tissue. In epiphyseal cartilage of growing long bones, matrilin-1 and -3 are present in all cartilage regions, in contrast to matrilin-2, which is expressed in the proliferative and the upper hypertrophic zones. Similarly matrilin-4 was detected all over the epiphyseal cartilage, with the weakest expression in the hypertrophic zone. Although it was shown that matrilin-1 and -3 can form hetero-oligomers and are often co-localized in tissue, clear differences in their spatial distribution could be demonstrated by double-immunolabelling. During joint development matrilin-2 and matrilin-4 are present at the developing joint surface, while in articular cartilage of 6-week-old mice all matrilins are only weakly expressed.

Expression of matrilin-1, -2 and -3 in developing mouse limbs and heart.

The expression of matrilin-1, -2 and -3 was studied in the heart and limb during mouse development. Matrilin-1 is transiently expressed in the heart between days 9.5 and 14.5 p.c. Matrilin-2 expression was detected in the heart from day 10.5 p.c. onwards. In the developing limb bud, both matrilin-1 and -3 were observed first at day 12.5 p.c. Throughout development matrilin-3 expression was strictly limited to cartilage, while matrilin-1 was also found in some other forms of connective tissue. Matrilin-2, albeit present around hypertrophic chondrocytes in the growth plate, was mainly expressed in non-skeletal structures. The complementary, but in part overlapping, expression of matrilins indicates the possibility for both redundant and unique functions among the members of this novel family of extracellular matrix proteins.

Discoidin domain receptor 2 mediates the collagen II-dependent release of interleukin-6 in primary human chondrocytes.

We deciphered constituent parts of a signal transduction cascade that is initiated by collagen II and results in the release of various pro‐inflammatory cytokines, including interleukin‐6 (IL‐6), in primary human chondrocytes. This cascade represents a feed‐forward mechanism whereby cartilage matrix degradation is exacerbated by the mutually inducing effect of released collagen II fragments and pro‐inflammatory cytokines. We previously proposed discoidin domain receptor 2 as a central mediator in this event. Since this cascade plays a prominent role in the pathogenesis of osteoarthritis, our study further investigates the hypothesis that discoidin domain receptor 2 is a candidate receptor for collagen II, and that transcription factor NFκB, lipid kinase PI3K, and the MAP kinases are constituent parts of this very signal transduction cascade. To accomplish this, we selectively knocked down the molecules of interest in primary human chondrocytes, induced the specified cascade by incubating primary human chondrocytes with collagen II, and observed the outcome, specifically the changes in interleukin‐6 release. Knockdown was performed by siRNA‐mediated gene silencing in the case of discoidin domain receptor 2 (DDR2) or by using specific inhibitors for the remainder of the molecules. Results indicated that discoidin domain receptor 2 mediates the collagen II‐dependent release of interleukin‐6 in primary human chondrocytes and that MAP kinases p38, JNK and ERK, as well as transcription factor NFκB, are integral components of intracellular collagen II signalling. Given the detrimental role of these molecules in osteoarthritis, our findings provide new targets for more specific therapeutics, which may have fewer side effects than those currently applied. Copyright

Matrilin‐3 activates the expression of osteoarthritis‐associated genes in primary human chondrocytes

Here, we tested the matrilin‐3‐dependent induction of osteoarthritis‐associated genes in primary human chondrocytes. Matrilin stimulation leads to the induction of MMP1, MMP3, MMP13, COX‐2, iNOS, IL‐1β, TNFα, IL‐6 and IL‐8. Furthermore, we show the participation of ADAMTS4 and ADAMTS5 in the in vitro degradation of matrilin‐3. We provide evidence for a matrilin‐3‐dependent feed‐forward mechanism of matrix degradation, whereby proteolytically‐released matrilin‐3 induces pro‐inflammatory cytokines as well as ADAMTS4 and ‐5 indirectly via IL‐1β. ADAMTS4 and ADAMTS5, in turn, cleave matrilin‐3 and may release more matrilin‐3 from the matrix, which could lead to further release of pro‐inflammatory cytokines and proteases in cartilage.

Proteolytic processing causes extensive heterogeneity of tissue matrilin forms

The matrilins are a family of multidomain extracellular matrix proteins with adapter functions. The oligomeric proteins have a bouquet-like structure and bind to a variety of different ligands whereby the avidity of their interactions is dependent on the number of subunits and domains present. Here we show the contribution of post-translational proteolytic processing to the heterogeneity of matrilins seen in tissue extracts and cell culture supernatants. A cleavage site after two glutamate residues in the hinge region close to the C-terminal coiled-coil oligomerization domain is conserved among the matrilins. Cleavage at this site yields molecules that lack almost complete subunits. The processing is least pronounced in matrilin-1 and particularly complex in matrilin-2, which contains additional cleavage sites. Replacement of the hinge region in matrilin-4 by the matrilin-1 hinge region had no marked effect on the processing. A detailed study revealed that matrilin-4 is processed already in the secretory pathway and that the activation of the responsible enzymes is dependent on proprotein convertase activity. Matrilin-3 and -4, but not matrilin-1 subunits present in matrilin-1/-3 hetero-oligomers, were identified as substrates for ADAMTS4 and ADAMTS5, whereas ADAMTS1 did not cleave any matrilin. A neo-epitope antibody raised against the N terminus of the C-terminal cleavage product of matrilin-4 detected processed matrilin-4 in cultures of primary chondrocytes as well as on cartilage sections showing that the conserved cleavage site is used in vivo.

Metformin causes a futile intestinal–hepatic cycle which increases energy expenditure and slows down development of a type 2 diabetes-like state

Objective Metformin, the first line drug for treatment of type 2 diabetes, suppresses hepatic gluconeogenesis and reduces body weight in patients, the latter by an unknown mechanism. Methods Mice on a high fat diet were continuously fed metformin in a therapeutically relevant dose, mimicking a retarded formulation. Results Feeding metformin in pharmacologically relevant doses to mice on a high fat diet normalized HbA1c levels and ameliorated glucose tolerance, as expected, but also considerably slowed down weight gain. This was due to increased energy expenditure, since food intake was unchanged and locomotor activity was even decreased. Metformin caused lactate accumulation in the intestinal wall and in portal venous blood but not in peripheral blood or the liver. Increased conversion of glucose-1-13C to glucose-1,6-13C under metformin strongly supports a futile cycle of lactic acid production in the intestinal wall, and usage of the produced lactate for gluconeogenesis in liver. Conclusions The reported glucose–lactate–glucose cycle is a highly energy consuming process, explaining the beneficial effects of metformin given continuously on the development of a type 2 diabetic-like state in our mice.