Exogenously added GPI-anchored tissue inhibitor of matrix metal loproteinase-1 (TIMP-1) displays enhanced and novel biological activities

The family of tissue inhibitors of metalloproteinases (TIMPs) exhibits diverse physiological/biological functions including the inhibition of active matrix metalloproteinases, regulation of proMMP activation, cell growth, and the modulation of angiogenesis. TIMP-1 is a secreted protein that can be detected on the cell surface through its interaction with surface proteins. The diverse biological functions of TIMP-1 are thought to lie, in part, in the kinetics of TIMP-1/MMP/surface protein interactions. Proteins anchored by glycoinositol phospholipids (GPIs), when purified and added to cells in vitro, are incorporated into their surface membranes. A GPI anchor was fused to TIMP-1 to generate a reagent that could be added directly to cell membranes and thus focus defined concentrations of TIMP-1 protein on any cell surface independent of protein-protein interaction. Unlike native TIMP-1, exogenously added GPI-anchored TIMP-1 protein effectively blocked release of MMP-2 and MMP-9 from osteosarcoma cells. TIMP-1-GP1 was a more effective modulator of migration and proliferation than TIMP-1. While control hTIMP-1 protein did not significantly affect migration of primary microvascular endothelial cells at the concentrations tested, the GPI-anchored TIMP-1 protein showed a pronounced suppression of endothelial cell migration in response to bFGF. In addition, TIMP-1-GPI was more effective at inducing microvascular endothelial proliferation. In contrast, fibroblast proliferation was suppressed by the agent. Reagents based on this method should assist in the dissection of the protease cascades and activities involved in TIMP biology. Membrane-fixed TIMP-1 may represent a more effective version of the protein for use in therapeutic expression

The Collagen Binding Domain of Gelatinase A Modulates Degradation of Collagen IV by Gelatinase B

Type IV collagen remodeling plays a critical role in inflammatory responses, angiogenesis and metastasis. Its remodeling is executed by a family of matrix metalloproteinases (MMPs), of which the constitutive gelatinase A (MMP2) and the inducible gelatinase B (MMP9) are key examples. Thus, in many pathological conditions, both gelatinases act together. Kinetic data are reported for the enzymatic processing at 37 degrees C of type IV collagen from human placenta by MMP9 and its modulation by the fibronectin-like collagen binding domain (CBD) of MMP2. The alpha l and alpha 2 chain components of type IV collagen were cleaved by gelatinases and identified by mass spectrometry as well as Edman sequencing. Surface plasmon resonance interaction assays showed that CBD bound type IV collagen at two topologically distinct sites. On the basis of linked-function analysis, we demonstrated that CBD of MMP2 tuned the cleavage of collagen IV by MMP9, presumably by inducing a ligand-linked structural change on the type IV collagen. At low, concentrations, the CBD bound the first site and thereby allosterically modulated the binding of MMP9 to collagen IV, thus enhancing the collagenolytic activity of MMP9. At high concentrations, CBD binding to the second site interfered with MMP9 binding to collagen IV, acting as a competitive inhibitor. Interestingly, modulation of collagen IV degradation by inactive forms of MMP2 also occurred in a cell-based system, revealing that this interrelationship affected neutrophil migration across a collagen IV membrane. The regulation of the proteolytic processing by a catalytically inactive domain (i.e., CBD) suggests that the two gelatinases might cooperate in degrading substrates even when either one is inactive. This observation reinforces the idea of exosite targets for MMP inhibitors, which should include all macromolecular substrate recognition site

Molecular mechanisms of NET formation and degradation revealed by intravital imaging in the liver vasculature

Neutrophil extracellular traps (NETs) composed of DNA decorated with histones and proteases trap and kill bacteria but also injure host tissue. Here we show that during a bloodstream infection with methicillin-resistant Staphylococcus aureus, the majority of bacteria are sequestered immediately by hepatic Kupffer cells, resulting in transient increases in liver enzymes, focal ischaemic areas and a robust neutrophil infiltration into the liver. The neutrophils release NETs into the liver vasculature, which remain anchored to the vascular wall via von Willebrand factor and reveal significant neutrophil elastase (NE) proteolytic activity. Importantly, DNase although very effective at DNA removal, and somewhat effective at inhibiting NE proteolytic activity, fails to remove the majority of histones from the vessel wall and only partly reduces injury. By contrast, inhibition of NET production as modelled by PAD4-deficiency, or prevention of NET formation and proteolytic activity as modelled in NE(−/−) mice prevent collateral host tissue damage

In Vitro-Selected drug-resistant Varicella-Zoster Virus mutants in the thymidine kinase and DNA polymerase genes yield novel Phenotype-Genotype associations and highlight differences between antiherpesvirus drugs

Varicella zoster virus (VZV) is usually associated with mild to moderate illness in immunocompetent patients. However, older age and immune deficiency are the most important risk factors linked with virus reactivation and severe complications. Treatment of VZV infections is based on nucleoside analogues, such as acyclovir (ACV) and its valyl prodrug valacyclovir, penciclovir (PCV) as its prodrug famciclovir, and bromovinyldeoxyuridine (BVDU; brivudin) in some areas. The use of the pyrophosphate analogue foscarnet (PFA) is restricted to ACV-resistant (ACVr) VZV infections. Since antiviral drug resistance is an emerging problem, we attempt to describe the contributions of specific mutations in the viral thymidine kinase (TK) gene identified following selection with ACV, BVDU and its derivative BVaraU (sorivudine), and the bicyclic pyrimidine nucleoside analogues (BCNAs), a new class of potent and specific anti-VZV agents. The string of 6 Cs at nucleotides 493 to 498 of the VZV TK gene appeared to function as a hot spot for nucleotide insertions or deletions. Novel amino acid substitutions (G24R and T86A) in VZV TK were also linked to drug resistance. Six mutations were identified in the “palm domain” of VZV DNA polymerase in viruses selected for resistance to PFA, PCV, and the 2-phophonylmethoxyethyl (PME) purine derivatives. The investigation of the contributions of specific mutations in VZV TK or DNA polymerase to antiviral drug resistance and their impacts on the structures of the viral proteins indicated specific patterns of cross-resistance and highlighted important differences, not only between distinct classes of antivirals, but also between ACV and PC