lactoferrin and Thrombosis

Neutrophil extracellular traps (NETs) are extracellular DNA filaments formed during neutrophil activation. This process, called netosis, was originally associated with neutrophil antibacterial properties. However, several lines of evidence now suggest a major role for netosis in thrombosis, autoimmune diseases, and cancer. We demonstrate here that highly purified human blood monocytes are also capable of extracellular trap (ET) release in response to several stimuli. Monocyte ETs display a morphology analogous to NETs and are associated with myeloperoxidase (MPO), lactoferrin (LF), citrullinated histones, and elastase. Monocyte ET release depends on oxidative burst but not on MPO activity, in contrast to neutrophils. Moreover, we demonstrate procoagulant activity for monocyte ETs, a feature that could be relevant to monocyte thrombogenic properties. This new cellular mechanism is likely to have implications in the multiple pathologic contexts where monocytes are implicated, such as inflammatory disorders, infection, or thrombosis.

Topics: Extracellular Traps; Histones; Humans; Infections; Inflammation; Lactoferrin; Monocytes; Pancreatic Elastase; Peroxidase; Thrombosis

KRDS (Lys-Arg-Asp-Ser), a tetrapeptide from human lactotransferrin, was tested for its effects in vitro on dog platelet function and in vivo on femoral arterial thrombus formation in dogs. KRDS inhibited ADP (8 microM)-induced platelet aggregation (IC50: 350 microM) and arachidonic acid (2 mM)-induced thromboxane B2 generation (IC50: 175 microM). In addition, the thrombin (0.2 U/ml)-induced serotonin release was inhibited by KRDS (IC50: 525 microM) and the expression of alpha-granule membrane protein (GMP-140) was also inhibited (IC50: 350 microM). The results show that KRDS is an inhibitor for platelet aggregation and secretion to which the inhibition is more potent. Meanwhile, in the experiment of arterial thrombosis in dogs, KRDS (5 microM/kg) and 125I-SZ-51 (a monoclonal antibody against GMP-140) were injected before operation and immediately after the thrombus formation, respectively. In the KRDS group, the weight of removed thrombi was reduced to 50% of that in controls and the radioactivity per mg of labeled thrombi to 33.3% while in blood the radioactivity increased 2 times that in controls at the 4th hour after the injection of 125I-SZ-51. The radioactivity ratio between removed thrombi and blood was only 16% of that in controls. These results indicate that KRDS can inhibit thrombus formation in vivo and is a promising antithrombotic agent.

Topics: Amino Acid Sequence; Animals; Blood Platelets; Dogs; Fibrinolytic Agents; Lactoferrin; Molecular Sequence Data; P-Selectin; Peptide Fragments; Platelet Aggregation; Platelet Aggregation Inhibitors; Platelet Membrane Glycoproteins; Serotonin; Thrombosis; Thromboxane B2