PAD4 has been strongly implicated in the pathogenesis of autoimmune, cardiovascular and oncological diseases, through clinical genetics and gene disruption in mice. Novel, selective PAD4 inhibitors binding to a calcium-deficient form of the PAD4 enzyme have, for the first time, validated the critical enzymatic role of human and mouse PAD4 in both histone citrullination and neutrophil extracellular trap formation. The therapeutic potential of PAD4 inhibitors can now be explored.
Adult chondrocytes are less chondrogenic than immature cells, yet it is likely that autologous cells from adult patients will be used clinically for cartilage engineering. The aim of this study was to compare the postexpansion chondrogenic potential of adult nasal and articular chondrocytes. Bovine or human chondrocytes were expanded in monolayer culture, seeded onto polyglycolic acid (PGA) scaffolds, and cultured for 40 days. Engineered cartilage constructs were processed for histological and quantitative analysis of the extracellular matrix and mRNA. Some engineered constructs were implanted in athymic mice for up to six additional weeks before analysis. Using adult bovine tissues as a cell source, nasal chondrocytes generated a matrix with significantly higher fractions of collagen type II and glycosaminoglycans as compared with articular chondrocytes. Human adult nasal chondrocytes proliferated approximately four times faster than human articular chondrocytes in monolayer culture, and had a markedly higher chondrogenic capacity, as assessed by the mRNA and protein analysis of in vitro-engineered constructs. Cartilage engineered from human nasal cells survived and grew during 6 weeks of implantation in vivo whereas articular cartilage constructs failed to survive. In conclusion, for adult patients nasal septum chondrocytes are a better cell source than articular chondrocytes for the in vitro engineering of autologous cartilage grafts. It remains to be established whether cartilage engineered from nasal cells can function effectively when implanted at an articular site.
A transient COS-7 cell expression system was used to investigate the functional domain arrangement of tissue inhibitor of metalloproteinases-3 (TIMP-3), specifically to assess the contribution of the amino-and carboxylterminal domains of the molecule to its matrix metalloproteinase (MMP) inhibitory and extracellular matrix (ECM) binding properties. Wild type TIMP-3 was entirely localized to the ECM in both its glycosylated (27 kDa) and unglycosylated (24 kDa) forms. A COOH-terminally truncated TIMP-3 molecule was found to be a non-ECM bound MMP inhibitor, whereas a chimeric TIMP molecule, consisting of the NH 2 -terminal domain of TIMP-2 fused to the COOH-terminal domain of TIMP-3, displayed ECM binding, albeit with a lower affinity than the wild type TIMP-3 molecule. Thus the functional domain arrangement of TIMP-3 is analogous to that seen in TIMP-1 and -2, namely that the NH 2 -terminal domain is responsible for MMP inhibition whereas the COOH-terminal domain is most important in mediating the specific functions of the molecule. A mutant TIMP-3 in which serine 181 was changed to a cysteine, found in Sorsby's fundus dystrophy, a hereditary macular degenerative disease, was also expressed in COS-7 cells. This gave rise to an additional 48-kDa species (possibly a TIMP-3 dimer) that retained its ability to inhibit MMPs and localize to the ECM. These data favor the hypothesis that the TIMP-3 mutations seen in Sorsby's fundus dystrophy contribute to disease progression by accumulation of mutant protein rather than by the loss of functional TIMP-3.The matrix metalloproteinases (MMPs) 1 are a family of zincdependent endopeptidases that exist in both secreted and membrane bound forms. The enzymes are initially expressed as inactive pro-enzymes becoming activated by proteolytic cleavage of their amino termini. The activity of MMPs is tightly regulated by the tissue inhibitors of metalloproteinases (TIMPs), a family of secreted proteins currently comprising four members (TIMP-1-TIMP-4) (1-4). The balance between MMPs and TIMPs regulates the integrity of the proteinacious extracellular matrix (ECM) and thus plays a key role in a wide range of physiological processes that include embryonic development, connective tissue remodeling, wound healing, glandular morphogenesis, and angiogenesis. An imbalance in MMP/ TIMP expression has been implicated in various diseases such as erosive joint disease, cardiovascular disease, and cancer (reviewed in Refs. 5-7).The TIMPs form high affinity 1:1 complexes with the active forms of most MMPs (reviewed in Ref. 8) but show varying specificity for different pro-MMPs allowing TIMPs to control the activation of specific MMPs (9 -12). Activities have also been ascribed to the TIMPs that are independent of their ability to inhibit MMPs; for example, anti-angiogenic and erythroid-potentiating activities have been described for TIMP-1 that are independent of MMP inhibition (13,14). Likewise TIMP-2 shows MMP independent inhibition of endothelial tube formation (15). These differences in TIMP ...
Collagens are the major structural proteins of connective tissues such as skin, bone, cartilage and tendon. Interstitial collagen types I, II and III are the most abundant, and the native triple helical structure of these molecules makes them highly resistant to proteolysis. However, collagenases of the matrix metalloproteinase (MMP) family [1] cleave native collagen types I, II and III at a specific site in all three chains of the triple helix, approximately three-quarters of the length from the N-terminus. The action of these collagenase enzymes is therefore critical for the initiation of collagenolysis. Once initiated, the cleaved helix unwinds at physiological temperatures and becomes susceptible to degradation by other, less-specific proteinases. MMP collagenases are active at neutral pH and play a highly important role in collagen degradation in vivo. The mammalian MMP collagenases currently include the 'classical' collagenases, MMP-1, and also the gelatinolytic enzyme, , and MMP-14 (MT1-MMP) [8], a member of the membrane-type subclass of MMPs.MMP-9 (also known as gelatinase B, 92 kDa gelatinase or 92 kDa type IV collagenase, EC 3.4.24.35) shares a close structural similarity with MMP-2 [9,10]. It was originally identified as a gelatinolytic enzyme produced by polymorphonuclear leukocytes [11] and subsequent studies have demonstrated secretion in the latent form (proMMP-9) by a variety of cell types. It has also been implicated in the pathogenesis of several human diseases, including arthritis [12][13][14][15]. Unlike other MMPs, MMP-9 and MMP-2 both contain three fibronectin type II repeats inserted into the catalytic Interstitial collagen types I, II and III are highly resistant to proteolytic attack, due to their triple helical structure, but can be cleaved by matrix metalloproteinase (MMP) collagenases at a specific site, approximately three-quarters of the length from the N-terminus of each chain. MMP-2 and -9 are closely related at the structural level, but MMP-2, and not MMP-9, has been previously described as a collagenase. This report investigates the ability of purified recombinant human MMP-9 produced in insect cells to degrade native collagen types I and III. Purified MMP-9 was able to cleave the soluble, monomeric forms of native collagen types I and III at 37°C and 25°C, respectively. Activity against collagens I and III was abolished by metalloproteinase inhibitors and was not present in the concentrated crude medium of mock-transfected cells, demonstrating that it was MMP-9-derived. Mutated, collagenase-resistant type I collagen was not digested by MMP-9, indicating that the three-quarters ⁄ one-quarter locus was the site of initial attack. Digestion of type III collagen generated a three-quarter fragment, as shown by comparison with MMP-1-mediated cleavage. These data demonstrate that MMP-9, like MMP-2, is able to cleave collagens I and III in their native form and in a manner that is characteristic of the unique collagenolytic activity of MMP collagenases.Abbreviations APMA, p-aminopheny...
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