Human semen contains very potent blood clotting activity; for example, seminal serum diluted up to 10,000-fold significantly decreased the recalcification clotting time of blood plasma. This seminal coagulant activity was dependent on factor X and calcium ions, suggesting the presence of a facto X activator. Immunoblotting analysis and immunoadsorption studies confirmed the presence of tissue factor antigen (45 kDa) in semen. Centrifugation studies suggested that tissue factor was membrane associated, and fractionation of seminal serum by gel filtration followed by immunoelectron microscopy revealed that tissue factor antigen was on the prostasome vesicle surface. Tissue factor originated from prostatic fluid and not from seminal vesicle secretions. Tissue factor antigen averaged 21 ng/ml in seminal serum. Hypothetical roles for very high levels of tissue factor in semen include several possibilities. In the event of abrasion and bleeding during intercourse, rapid blood clotting at lesion sites would prevent sperm and seminal components, including infectious agents such as human immunodeficiency virus, from entering the blood stream, generating antibodies, or promoting infectious disease. This could imply that development of infection from semen-borne agents or development of antisperm antibodies in some patients could result from impairment or absence of seminal tissue factor.
Regulation of the coagulation factor VIII (fVIII) level in circulation involves a hepatic receptor low-density lipoprotein receptor-related protein (LRP). One of two major LRP binding sites in fVIII is located within the A2 domain (A2), likely exposed within the fVIII complex with von Willebrand factor and contributing to regulation of fVIII via LRP. This work aimed to identify A2 residues forming its LRP-binding site, previously shown to involve residues 484-509. Isolated A2 was subjected to alanine-scanning mutagenesis followed by expression of a set of mutants in a baculovirus system. In competition and surface plasmon resonance assays, affinities of A2 mutants K466A, R471A, R484A, S488A, R489A, R490A, H497A, and K499A for LRP were found to be decreased by 2-4-fold. This correlated with 1.3-1.5-fold decreases in the degree of LRP-mediated internalization of the mutants in cell culture. Combining these mutations into pairs led to cumulative effects, i.e., 7-13-fold decrease in affinity for LRP and 1.6-2.2-fold decrease in the degree of LRP-mediated internalization in cell culture. We conclude that the residues mentioned above play a key role in formation of the A2 binding epitope for LRP. Experiments in mice revealed an approximately 4.5 times shorter half-life for A2 in the circulation in comparison with that of fVIII. The half-lives of A2 mutant R471A/R484A or A2 co-injected with receptor-associated protein, a classical ligand of LRP, were prolonged by approximately 1.9 and approximately 3.5 times, respectively, compared to that of A2. This further confirms the importance of the mutated residues for interaction of A2 with LRP and suggests the existence of an LRP-dependent mechanism for removing A2 as a product of dissociation of activated fVIII from the circulation.
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