Jay M. Edelberg

Lipoprotein(a) inhibition of plasminogen activation by tissue-type plasminogen activator

Here experimental evidence is presented demonstrating that Lp(a) inhibits the activation of Pg by the physiologic activator tissue-type plasminogen activator (t-PA) bound to fibrinogen fragments. The competitive inhibition constant, Kie, of the Lp(a) inhibition is 22 nM, or 8.6 mg/dL which corresponds to normal plasma levels

Neonatal plasminogen displays altered cell surface binding and activation kinetics. Correlation with increased glycosylation of the protein.

Plasminogen isolated from 60 full-term newborns differs from adult plasminogen in carbohydrate composition, kinetic activation constants, and cell binding. Amino acid composition and amino-terminal sequence analysis data indicate that the plasminogens of neonates and adults have the same amino acid sequence. Like the adult, the neonate has two glycoforms, but both have significantly more mannose and sialic acid than the adult forms. The difference in the neonatal glycosylation is probably responsible for the altered migration observed by isoelectric focusing. Moreover, the difference in carbohydrate composition appears to be the basis of the decreased functional activity of the neonatal plasminogen. The kcat/Km ratios indicate that the overall activation rates of the two neonatal plasminogen glycoforms are lower compared with the adult glycoforms. In addition, neonatal plasminogen does not bind as well to cellular receptors compared with adult plasminogen. These studies suggest a basis for the decreased fibrinolytic activity observed in neonates.

Lipoprotein(a) inhibits plasminogen activation in a template-dependent manner.

Lipoprotein(a) [Lp(a)] is a low density lipoprotein whose plasma levels strongly correlate with the occurrence of atherosclerotic disease. Structural studies have demonstrated that Lp(a) contains two disulphide bonded subunits, one of which has structural similarity to plasminogen. This subunit, designed apo-lipoprotein(a), contains multiple repeat copies of a kringle homologous to kringle-4 of plasminogen, one copy of a kringle-5-like structure and a domain homologous to the catalytic light chain of plasmin. This subunit, however, lacks the site where plasminogen activators cleave plasminogen to generate the active proteinase. Recent studies demonstrate that Lp(a) competes with plasminogen for binding to endothelial cells and macrophages and thus prevents assembly of the fibrinolytic system on cell surfaces. Lp(a) also inhibits activation of plasminogen by streptokinase, urokinase-type plasminogen activator or tissue-type plasminogen activator (t-PA). Inhibition of plasminogen activation by t-PA requires the presence of a template on which activation occurs. This template can be either fibrin or heparin. This review considers the role of Lp(a) as an inhibitor of template-dependent activation of the fibrinolytic system.

Lipoprotein (a) regulates plasmin generation and inihibition

The relationship between lipoprotein (a) (Lp(a)) and atherosclerosis has been appreciated for a number of years. Only in recent years, however, has the structural relationship of Lp(a) to plasminogen resulted in studies of the effect of this lipoprotein on fibrinolysis. Lp(a) inhibits activation of plasminogen by tissue-type (t-PA) and urinary-type (u-PA) plasminogen activators. These inhibitory reactions are surface-dependent. When Lp(a) binds to fibrin, fibrinogen, heparin or cells it blocks activation of plasminogen by t-PA. u-PA-mediated activation of plasminogen is blocked on surfaces including heparin and chondroitin sulfate. Lp(a) also favors inhibition of plasmin by alpha 2-antiplasmin (alpha 2-AP). The ability of Lp(a) to compete with plasmin for fibrin binding displaces plasmin into solution where alpha 2-AP rapidly inhibits this proteinase. These effects are all antifibrinolytic. Lp(a) also exhibits one profibrinolytic effect, since it blocks inhibition of t-PA by plasminogen activator type 1 in the presence of fibrinogen or heparin. Thus, Lp(a) modulates most of the reactions involved in plasmin generation and inhibition. Its overall effect will depend primarily on the concentrations of Lp(a), PAI-1 and t-PA in vivo.

Ionic modulation of the effects of heparin on plasminogen activation by tissue plasminogen activator: The effects of ionic strength, divalent cations, and chloride☆

Ionic strength, divalent cations, and Cl- modulate the ability of the glycosaminoglycan heparin to stimulate the activation of human plasminogen (Pg) by tissue-type Pg activator. Kinetic analysis of Pg activation indicates that heparin is inhibitory, stimulatory, or nonstimulatory as a function of ionic strength. While increasing ionic strength inhibits Pg activation in the absence of heparin, in it presence an activation phase followed by an inhibitory phase is observed. Divalent cations, inhibitors of activation in the absence of heparin, increase the rate of activation in its presence. Kinetic analysis demonstrates that divalent cations augment the heparin stimulatory effect a maximum of 60-fold due to increases in kcat without changes in Km of the reaction. This effect is heparin-specific, since activation is not affected by Ca2+ in the presence of heparan sulfate or de-N-sulfated heparin. Also, Cl- inhibits Pg activation in the presence of heparin by acting as a competitive inhibitor (Kic of 100 mM). Furthermore, inhibition by Cl- reduces the overall magnitude of heparin stimulation of Pg activation. These results suggest that physiologic ions in combination with heparin may be significant effectors of Pg activation in the vascular microenvironment.

Lipoprotein (a) : purification and kinetic analysis

Publisher Summary This chapter discusses the purification and kinetic analysis of lipoprotein. Lipoprotein (a) levels in excess of 30 mg/dl are associated with a two-to fivefold increased risk of atherosclerosis. Elevated Lp(a) levels also are linked to stenosis of carotid and cerebral arteries and rethrombosis of venous grafts. Lp(a) downregulates fibrinolysis by competing with Pg for various vascular binding sites, including cellular binding sites, fibrinogen fragments, and heparin. Pg cellular binding sites on endothelial cells, macrophages, and other cells locally concentrate Pg, which is then activated by adjacently bound Pg activators. Lp(a) binds to these sites with an affinity comparable to Pg as a result of the apo(a) kringle-4 domains. Lp(a) displacement of Pg from these cellular binding sites may prevent Pg from interacting with Pg activators, such as tissue-type Pg activator (t-PA) and urinary-type Pg activator (u-PA) and may, thereby depress fibrinolysis. Thus in vitro Lp(a) competes with Pg for various cellular binding sites, inhibits plasmin generation by Pg activators, and promotes plasmin inhibition, but protects Pg activators from inhibition.