Angiogenesis is an essential step in the repair process that occurs after injury. In this study, we investigated whether the angiogenic thymic peptide thymosin beta4 (Tbeta4) enhanced wound healing in a rat full thickness wound model. Addition of Tbeta4 topically or intraperitoneally increased reepithelialization by 42% over saline controls at 4 d and by as much as 61% at 7 d post-wounding. Treated wounds also contracted at least 11% more than controls by day 7. Increased collagen deposition and angiogenesis were observed in the treated wounds. We also found that Tbeta4 stimulated keratinocyte migration in the Boyden chamber assay. After 4-5 h, migration was stimulated 2-3-fold over migration with medium alone when as little as 10 pg of Tbeta4 was added to the assay. These results suggest that Tbeta4 is a potent wound healing factor with multiple activities that may be useful in the clinic.
Thymosin beta 4 (T beta 4) is a 4.9 kDa polypeptide that interacts with G-actin and is thought to be an important mediator in cell proliferation, migration, and differentiation. T beta 4 has been identified as a factor involved in the differentiation of human umbilical vein endothelial cells (HUVECs) cultured on Matrigel. Here we have used various in vitro and in vivo migration assays to demonstrate the role of T beta 4 in endothelial cell migration. Our results demonstrate that T beta 4 acts as a chemoattractant for endothelial cells, stimulating the migration of HUVECs in Boyden chambers four- to sixfold over that observed with media alone. Of the primary cell types tested, only human coronary artery cells responded to T beta 4 treatment, suggesting that the migration activity of T beta 4 was endothelial cell-specific. T beta 4 significantly accelerated the rate of migration into the scratch wounded area of a HUVEC monolayer. T beta 4 treatment also increased the production of matrix metalloproteinases that may degrade the basement membrane during angiogenesis. Additional experiments using subcutaneously implanted Matrigel showed that T beta 4 stimulated cell migration in vivo. These results provide the first direct evidence that T beta 4 has chemoattractive activity and promotes angiogenesis by stimulating the migration of endothelial cells.
Laminin-1 is a basement membrane glycoprotein that promotes several biological activities including cell attachment, tumor metastasis, and angiogenesis. Angiogenesis plays an important role in tissue formation, reproduction, wound healing, and several pathological conditions. In this study, we screened 405 synthetic peptides from the alpha1 and beta1 chains to identify potential sites on laminin-1 active with endothelial cells. Peptides were initially screened by testing both endothelial cell adhesion to peptide-coated wells and tube formation on Matrigel in the presence of soluble peptide. Twenty active peptides were identified in these screens. A secondary screen using the rat aortic ring sprouting assay identified 13 of the 20 peptides that stimulated endothelial sprouting. Several of these active peptides were also found to stimulate human umbilical vein endothelial cell migration in Boyden chamber assays. Differences in the amount of peptide needed for the response and in the resultant morphologies/responses were observed between the peptides in all of the assays. Our results suggest that several active domains on laminin-1 may play important roles in stimulating different steps in angiogenesis.
The laminins belong to a family of trimeric basement membrane glycoproteins with multiple domains, structures, and functions. Endothelial cells bind laminin-1 and form capillary-like structures when plated on a laminin-1-rich basement membrane matrix, Matrigel. Laminin-1 is composed of 3 chains, alpha1, beta1, and gamma1. Because laminin-1 is known to contain multiple biologically active sites, we have screened 156 synthetic overlapping peptides spanning the entire laminin gamma1 chain for potential angiogenic sequences. Only 7 of these peptides, designated as C16, C25, C30, C38, C64, C75, and C102, disrupted the formation of capillary-like structures by human umbilical vein endothelial cells on Matrigel. Dose-response experiments in the presence of 50 to 200 microg/mL showed that tube formation was prevented by most peptides at 150 and 200 microg/mL, except for C16, which showed strong activity at all concentrations. Active peptides promoted vessel sprouting from aorta rings and angiogenesis in the chick chorioallantoic membrane assay. In addition, the active peptides also promoted endothelial cell adhesion to dishes coated with 0.1 microg of peptide and inhibited attachment to laminin-1 but not to plastic or fibronectin. Four of the active peptides, C25, C38, C75, and C102, may have cell-type specificity with endothelial cells, since they did not promote PC12 neurite outgrowth or adhesion of B16-F10 melanoma and human submandibular gland cells. These results suggest that specific laminin gamma1-chain peptides have angiogenic activity with potential therapeutic applications.
The laminins are a family of extracellular matrix glycoproteins localized in the basement membrane that separates epithelial cells from the underlying stroma. They are also found in basement membrane surrounding fat, muscle and peripheral nerve cells. The laminins are large trimeric glycoproteins comprising three disulphide-bonded chains. They are the first extracellular matrix molecules to be observed in the developing embryo and have potent biological activities. In addition, there have been new developments in the number and localization of the homologues of the laminin chains and the role of laminin in neuromuscular disease. Their primary role is in cell-matrix attachment, but many additional biological activities, including promoting cell growth and migration, tumour growth and metastases, neurite outgrowth, nerve regeneration, wound repair and graft survival, have been demonstrated. Many of these biological activities are duplicated by proteolytic fragments of laminin and by small laminin-derived synthetic peptides. These laminin-derived peptides may be useful clinical reagents for accelerating wound healing with minimal scarring or for blocking tumour metastases.
The search for rapid and reproducible in vivo angiogenesis and antiangiogenesis assays is an area of intense interest. These types of assays are extremely useful in testing putative drugs and biological agents and for the comparison and enhancement of in vitro tests. The Matrigel plug assay is one such assay and has proved to be a relatively quick and easy method to evaluate both angiogenic and antiangiogenic compounds in vivo. Initial indications of the levels of activity of strong angiogenic or antiangiogenic compounds can be visually assessed even as the plugs come out of the mouse because there are color differences in the plugs compared to the controls. Further quantitation is then needed to determine levels of angiogenic/antiangiogenic activity, and this can be performed using a variety of methods. This chapter presents an overview of the basic methods used to set up both angiogenic and antiangiogenic assays, discusses factors influencing variability, and discusses the methods for quantitating the plugs obtained. The Matrigel plug assay provides another useful tool in angiogenesis research.
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