C-terminal apolipoprotein E-derived peptide, Ep1.B, displays anti-atherogenic activity.

OBJECTIVE: Apolipoprotein E (ApoE) is a lipid transport protein with expanded functions in cellular responses to tissue injury, immune regulation and cell growth. ApoE directs vascular changes that contribute to arterial protection as evidenced by the fact that isoforms of ApoE and ApoE deficiency correlate closely with accelerated plaque growth. The N-terminus of the ApoE protein has well-characterized functions, displaying lipid-binding and anti-atherogenic activity, whereas the function of the C-terminus is only partially defined. We have assessed the effects of a 14 amino acid C-terminal ApoE peptide, termed Ep1.B (239-252), on intimal neoplasia in animal models. This peptide is a fragment of a naturally processed peptide (236-252) of murine ApoE. METHODS AND RESULTS: Ep1.B injection reduced neointimal hyperplasia after vascular surgery in rats and mice. When given during early plaque progression in ApoE-deficient mice, Ep1.B injections also prevented plaque growth. Treatment with Ep1.B did not, however, reduce established plaque growth in older mice. Peptides with alanine substitution of amino acid 249, Ep1.N, and with complete sequence reversal, Ep1.R, did not consistently inhibit plaque growth. CONCLUSION: A naturally processed C-terminal ApoE peptide, Ep1.B, has anti-atherogenic activity indicating a role for this naturally metabolized peptide in vascular wound healing and lipid homeostasis.

Serp-1, a viral anti-inflammatory serpin, regulates cellular serine proteinase and serpin responses to vascular injury.

Complex DNA viruses have tapped into cellular serpin responses that act as key regulatory steps in coagulation and inflammatory cascades. Serp-1 is one such viral serpin that effectively protects virus-infected tissues from host inflammatory responses. When given as purified protein, Serp-1 markedly inhibits vascular monocyte invasion and plaque growth in animal models. We have investigated mechanisms of viral serpin inhibition of vascular inflammatory responses. In vascular injury models, Serp-1 altered early cellular plasminogen activator (tissue plasminogen activator), inhibitor (PAI-1), and receptor (urokinase-type plasminogen activator) expression (p < 0.01). Serp-1, but not a reactive center loop mutant, up-regulated PAI-1 serpin expression in human endothelial cells. Treatment of endothelial cells with antibody to urokinase-type plasminogen activator and vitronectin blocked Serp-1-induced changes. Significantly, Serp-1 blocked intimal hyperplasia (p < 0.0001) after aortic allograft transplant (p < 0.0001) in PAI-1-deficient mice. Serp-1 also blocked plaque growth after aortic isograft transplant and after wire-induced injury (p < 0.05) in PAI-1-deficient mice indicating that increase in PAI-1 expression is not required for Serp-1 to block vasculopathy development. Serp-1 did not inhibit plaque growth in uPAR-deficient mice after aortic allograft transplant. We conclude that the poxviral serpin, Serp-1, attenuates vascular inflammatory responses to injury through a pathway mediated by native uPA receptors and vitronectin.