Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P39060 (endostatin)
 2,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

It has been repeatedly postulated that the high heat resistance of bacterial spores is due to stabilization of biopolymers in the spore interior by a solid deposit of protective cement consisting of coordination complexes of ligands with divalent metal ions. This report presents data on metal-binding characteristics of some of the ligands related to spores as determined by means of potentiometric equilibrium measurements under conditions of temperature and ionic strength (t = 25.0 degrees C; mu = 1.0 KNO(3)) identical with those reported earlier by the authors in order to facilitate correlation by using comparable data. The spore ligands investigated in this study included 2,6-pyridinedicarboxylic acid (DPA), alpha,epsilon-diaminopimelic acid, D-glutamic acid, and D-alanine in a ratio of 1:1 with metal ions which are known to play a role in heat resistance of spores. Stability constants of the chelates of these spore ligands with metal ions such as Ca(II), Mg(II), Cu(II), Ni(II), Zn(II), Co(II), and Mn(II) have been determined. In general the metal chelates of DPA exhibited the greatest stability. On the basis of a consideration of the stability data together with the known configurations of the ligand and the coordination requirements of the metal ions, possible structures indicating the coordinate binding of the spore ligands with the metal ions are presented. All the metal chelates except those of Ca(II) were found to undergo hydrolysis and separation of solid phase in the pH range 7-8.5. The relatively greater hydrolytic stability of Ca(II) chelates and the high affinity of DPA for metal ions appear to be of biological significance insofar as these two spore components are more widely associated with the heat resistance of bacterial spores.
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PMID:Coordinative binding of divalent cations with ligands related to bacterial spores. Equilibrium studies. 556 93

Fetal mouse metatarsals are well-known models to study cartilage differentiation and osteoclastic resorption. We show here the outgrowth of PECAM-1 positive tubelike structures from the bone rudiments. This feature can be used to study angiogenesis in vitro. The area of outgrowth significantly increased with culture time, as shown by computerized image analysis of PECAM-1 positive tubelike structures. Treatment with recombinant human vascular endothelial growth factor (rhVEGF-A) stimulated the formation of tubelike structures. Treatment of explants with the angiogenesis inhibitor endostatin, the chemokine IP-10, and the thalidomide derivative phatolyl glutamic acid (PG-acid) resulted in an inhibition of the formation of PECAM-1 positive tubelike structures of 48.8% (+/- 4%), 50.2% (+/- 12%), and 80.8% (+/- 3%), respectively. Outgrowth of tubelike structures was partly dependent on endogenous VEGF-A because treatment with anti-mVEGF-A and truncated VEGF receptor 1 (soluble fms-like tyrosine kinase 1, sFIt1) strongly inhibited the formation of tubelike structures 74% (+/- 4%) and 38% (+/- 5%), respectively. Neither onset of tube formation nor total area of tubelike structures were changed when metatarsals were cultured on a fibrin gel or collagen type I gel. Tube formation required activation of matrix metalloproteinases because treatment of the bones with an inhibitor of matrix metalloproteinases completely inhibited migration and tube formation, whereas treatment with an inhibitor of plasmin had no effect. In conclusion, we describe a new in vitro model to study angiogenesis that can be used to test the angiogenic or antiangiogenic potential of novel test compounds that also combines the multicellularity of in vivo assays with the accessibility and flexibility of in vitro assays.
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PMID:Effect of angiogenic and antiangiogenic compounds on the outgrowth of capillary structures from fetal mouse bone explants. 1120 73

In the recent years, several pieces of evidence have pointed out that disease progression in multiple myeloma (MM) is characterized by an increased bone marrow neovascularization. Targeting the mechanisms that control angiogenesis could thus represent an innovative therapeutic approach to MM. Thalidomide, a glutamic acid derivative with sedative properties, is able to inhibit angiogenesis in murine models; this compound has recently demonstrated to be effective in relapsed/refractory MM, leading to a 30-40% response, coupled with mild systemic toxicity. Inhibition of angiogenesis is probably just one of the mechanisms by which thalidomide exerts its action in MM, as immunomodulation and inhibition of cytokine production by bone marrow stroma could also be involved. At present, several studies are ongoing, aiming at testing thalidomide-based drug combinations, mainly with dexamethasone, but also with conventional chemotherapy; the results that have been obtained so far show a synergistic effect of the drug combinations, with a response rate ranging from 50 to 70% in pretreated patients. There is now growing interest in novel compounds with potential antiangiogenic effects, among them a promising activity both in vitro and in animal models has been displayed by thalidomide analogs, inhibitors of vascular endothelial growth factor receptor-2 and endostatin.
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PMID:Antiangiogenic therapy in multiple myeloma. 1181 18