2002

DOI: 10.1161/hq0102.101129

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Metalloproteinase Inhibition and the Response to Angioplasty and Stenting in Atherosclerotic Primates

Gregory S. Cherr

¹

,

Stephen J. Motew

²

,

Jeffrey A. Travis

³

et al.

Abstract: Abstract-Determinants of restenosis after angioplasty include constrictive remodeling and intimal hyperplasia. Both processes require extensive matrix turnover, so matrix metalloproteinases (MMPs) have become potential targets of antirestenosis therapies. We studied the effects of RO113-2908, a broad-spectrum MMP inhibitor (MMPI), on the response to iliac artery angioplasty and stenting in atherosclerotic cynomolgus monkeys. Lumen diameter (LD) was measured angiographically, and artery wall geometry was assess… Show more

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Cited by 43 publications

(26 citation statements)

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“…However, small molecule MMP inhibitors fail to prevent restenosis, even though they efficiently block early smooth muscle cell migration (Bendeck et al, 1996). Recently, the broad spectrum MP inhibitor RO113-2908 failed to prevent angioplasty-or stent-induced intermal hyperplasia over 4 weeks in atherosclerotic primates (Cherr et al, 2002), although MP inhibitors do reduce constrictive remodeling in a porcine angioplasty model (de Smet et al, 2000). Similarly, TIMP overexpression (Cheng et al, 1998;Dollery et al, 1999;Forough et al, 1996) prevented smooth muscle cell migration but long-term benefits were not fully established.…”

Section: Mmp Blockade and Cardiovascular Diseasementioning

confidence: 99%

Metalloproteinase inhibitors: biological actions and therapeutic opportunities

¹

,

²

,

³

2002

Journal of Cell Science

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IntroductionMetalloproteinases (MPs) play key roles in the responses of cells to their microenvironment. By effecting proteolytic degradation or activation of cell surface and extracellular matrix (ECM) proteins they can modulate both cell-cell and cell-ECM interactions, which influence cell differentiation, migration, proliferation and survival. Both secreted and membranebound forms of metalloproteinases have been implicated in pericellular proteolysis, including the matrix metalloproteinases (MMPs), the adamalysin-like proteinases with both metalloproteinase and disintegrin-like domains (ADAMs and their counterparts that have a thrombospondin-1-like domain, ADAM-TSs) and the astacins (Werb, 1997). Cells use various strategies to regulate extracellular proteinases: transcriptional regulation, trafficking of membrane-bound forms (secretion and endocytosis), activation of latent proenzyme forms, extracellular binding proteins and the action of endogenous inhibitors. Here we will discuss the role of metalloproteinase inhibitors, from the well-known tissue inhibitors of metalloproteinases (TIMPs) and α2-macroglobulin through to newer and less well-understood putative inhibitors (Fig. 1). We look at the available evidence that their other roles in cell biology do not all relate to their metalloproteinase inhibitory activity. Finally, we discuss the potential for use of such natural metalloproteinase inhibitors as therapeutic agents. Tissue inhibitors of metalloproteinases (TIMPs):basic structure and activity Four mammalian TIMPs have been cloned, purified and characterised. These secreted proteins are thought to regulate MMP activity during tisssue remodelling. One TIMP gene has been identified in Drosophila, and its ablation generates a phenotype similar to that of integrin mutants, which indicates that it has a role in ECM function (Godenschwege et al., 2000). All four mammalian TIMPs have many basic similarities, but they exhibit distinctive structural features, biochemical properties and expression patterns (Table 1). This suggests that each TIMP has specific roles in vivo. As in Drosophila, the mammalian TIMP genes are embedded intragenically in intron 5 of synapsin genes (Edwards, 2000).The TIMPs have molecular weights of ~21 kDa and are variably glycosylated (Table 1). They have six disulphide bonds and comprise a three-loop N-terminal domain and an interacting three-loop C-subdomain. Most of the biological functions of these proteins discovered thus far are attributable to sequences within the N-terminal domain, although the Csubdomains mediate interactions with the catalytic domains of some MMPs and with the hemopexin domains of MMP-2 and MMP-9 . The TIMPs are secreted proteins, but may be found at the cell surface in association with membrane-bound proteins; for example, TIMP-2, TIMP-3 and Many of these MMP inhibitors, including the TIMPs, possess other biological activities which may not be related to their inhibitory capacities. These need to be thoroughly characterized in order to allow informed develop...

“…However, small molecule MMP inhibitors fail to prevent restenosis, even though they efficiently block early smooth muscle cell migration (Bendeck et al, 1996). Recently, the broad spectrum MP inhibitor RO113-2908 failed to prevent angioplasty-or stent-induced intermal hyperplasia over 4 weeks in atherosclerotic primates (Cherr et al, 2002), although MP inhibitors do reduce constrictive remodeling in a porcine angioplasty model (de Smet et al, 2000). Similarly, TIMP overexpression (Cheng et al, 1998;Dollery et al, 1999;Forough et al, 1996) prevented smooth muscle cell migration but long-term benefits were not fully established.…”

Section: Mmp Blockade and Cardiovascular Diseasementioning

confidence: 99%

Metalloproteinase inhibitors: biological actions and therapeutic opportunities

¹

,

²

,

³

2002

Journal of Cell Science

View full text Add to dashboard Cite

IntroductionMetalloproteinases (MPs) play key roles in the responses of cells to their microenvironment. By effecting proteolytic degradation or activation of cell surface and extracellular matrix (ECM) proteins they can modulate both cell-cell and cell-ECM interactions, which influence cell differentiation, migration, proliferation and survival. Both secreted and membranebound forms of metalloproteinases have been implicated in pericellular proteolysis, including the matrix metalloproteinases (MMPs), the adamalysin-like proteinases with both metalloproteinase and disintegrin-like domains (ADAMs and their counterparts that have a thrombospondin-1-like domain, ADAM-TSs) and the astacins (Werb, 1997). Cells use various strategies to regulate extracellular proteinases: transcriptional regulation, trafficking of membrane-bound forms (secretion and endocytosis), activation of latent proenzyme forms, extracellular binding proteins and the action of endogenous inhibitors. Here we will discuss the role of metalloproteinase inhibitors, from the well-known tissue inhibitors of metalloproteinases (TIMPs) and α2-macroglobulin through to newer and less well-understood putative inhibitors (Fig. 1). We look at the available evidence that their other roles in cell biology do not all relate to their metalloproteinase inhibitory activity. Finally, we discuss the potential for use of such natural metalloproteinase inhibitors as therapeutic agents. Tissue inhibitors of metalloproteinases (TIMPs):basic structure and activity Four mammalian TIMPs have been cloned, purified and characterised. These secreted proteins are thought to regulate MMP activity during tisssue remodelling. One TIMP gene has been identified in Drosophila, and its ablation generates a phenotype similar to that of integrin mutants, which indicates that it has a role in ECM function (Godenschwege et al., 2000). All four mammalian TIMPs have many basic similarities, but they exhibit distinctive structural features, biochemical properties and expression patterns (Table 1). This suggests that each TIMP has specific roles in vivo. As in Drosophila, the mammalian TIMP genes are embedded intragenically in intron 5 of synapsin genes (Edwards, 2000).The TIMPs have molecular weights of ~21 kDa and are variably glycosylated (Table 1). They have six disulphide bonds and comprise a three-loop N-terminal domain and an interacting three-loop C-subdomain. Most of the biological functions of these proteins discovered thus far are attributable to sequences within the N-terminal domain, although the Csubdomains mediate interactions with the catalytic domains of some MMPs and with the hemopexin domains of MMP-2 and MMP-9 . The TIMPs are secreted proteins, but may be found at the cell surface in association with membrane-bound proteins; for example, TIMP-2, TIMP-3 and Many of these MMP inhibitors, including the TIMPs, possess other biological activities which may not be related to their inhibitory capacities. These need to be thoroughly characterized in order to allow informed develop...

“…7,8) We herein have shown that ONO-4817 could inhibit the atherosclerotic neointimal hyperplasia in experimental hyperlipidemic rabbits.…”

Section: Discussionmentioning

confidence: 73%

“…In previous studies 7,8) and a recent study by RS-130830, 9) it was reported that intimal hyperplasia could not be attained by these drugs. The inhibitory activity of RS-130830 and ONO-4817 is summarized in Table. 9,10) The balance of inhibitory activity, not the strength of inhibitory activity, may explain the inhibition of intimal hyperplasia.…”

Section: Discussionmentioning

confidence: 90%

“…7,8) Because ONO-4817 may be the first MMPi that is able to suppress the development of intimal hyperplasia induced by intimal injury in hypercholesterolemic hamsters, 16) we have presented data on atherosclerotic intimal hyperplasia in dietary hypercholesteloremic rabbits in this report.…”

Section: Discussionmentioning

confidence: 99%

“…[4][5][6] Several studies with synthetic matrix metalloproteinase inhibitors (MMPi) have been conducted to test this hypothesis, but no convincing morphologic data have yet been obtained. [7][8][9] ONO-4817, a newly synthesized MMPi, is active as an MMPi after oral administration, and has a partially selective inhibitory spectrum (MMP-2, MMP-8, MMP-9, MMP-12, and MMP-13 but not MMP-1 or MMP-7).…”

mentioning

confidence: 99%

See 2 more Smart Citations

A Matrix Metalloproteinase Inhibitor, ONO-4817, Suppresses the Development of Aortic Intimal Hyperplasia in Experimental Hyperlipidemic Rabbit

¹

,

²

,

³

et al. 2007

Int. Heart J.

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SUMMARYInhibition of matrix metalloproteinases (MMPs) would be expected to suppress atherosclerotic neointimal proliferation and thus limit atheromatous plaque progression, but this has not yet been demonstrated morphologically in atherosclerotic intimal hyperplasia induced by cholesterol loading in experimental animals. We therefore investigated whether a broad-spectrum MMP inhibitor (MMPi), ONO-4817, could inhibit the development of intimal hyperplasia in male hyperlipidemic rabbits (n = 6) fed laboratory chow supplemented with 1% cholesterol for 2 months followed by a 1% cholesterol diet plus 100 mg/kg ONO-4817 for another month (Chol + ONO group). Control animals (n = 6) received no ONO-4817. When the aortas were studied both histologically and immunohistochemically, intimal hyperplasia was inhibited in Chol + ONO rabbits. The distribution of macrophages and MMP-12 in the hyperplastic tissue of the Chol + ONO rabbits was limited to the luminal side of the lesions. No such limitation in the distribution of macrophages and MMP-12 was observed in the control group. The distribution of smooth muscle cells in the hyperplastic tissue was not different between the Chol + ONO and control groups. However, the distribution of MMP-2 and MMP-12 was limited to the luminal side of lesions in the Chol + ONO group. This is the first reported evidence that an MMPi can suppress the development of intimal hyperplasia in hyperlipidemic rabbits. (Int Heart J 2007; 48: 369-378)

Fabrication of micropored elastomeric film‐covered stents and acute‐phase performances

Ueda-Ishibashi³

et al. 2002

J Biomedical Materials Res

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To prevent thrombus formation in the acute phase and restenosis in the subacute to chronic phase after stenting of atherosclerotic arteries, we developed a covered stent with a micropored elastomeric film, the blood-contacting surface of which was coated with a photocured gelatin layer immobilized with heparin. Segmented polyurethane (SPU) film (30 microm in wall thickness) as a cover material was multiply micropored by excimer laser-directed microprocessing (pore diameter, 30 microm; interpore distance, 125 microm). An aqueous mixed solution of benzophenone-derivatized gelatin and heparin was coated on the micropored SPU film. Upon ultraviolet light irradiation, a thin layer of a gelatin gel immobilized with heparin was formed and simultaneously fixed on the SPU film. The fully covered stents were assembled by wrapping a balloon-expandable stent with gelatin/heparin gel-layered SPU film and subsequently suturing and then gluing. To assess the validity of this covered stent in vivo, "half-covered" stents, in which half at the distal side was covered with the gel-layered SPU film, was implanted in rabbit common carotid arteries (about 3 mm in diameter). After 3 months of implantation, all the half-covered stents (n = 7) were patent. Regardless of the covered or noncovered region of the stents, the entire luminal surface of the stents was fully endothelialized and a thin neointimal tissue was formed. The potential advantages of a covered stent as designed above are discussed.

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