ALBERT

Description: Thrombomodulin (TM) is a widely expressed glycoprotein receptor that plays a physiologically important role in maintaining normal hemostatic balance postnatally. Inactivation of the TM gene in mice results in embryonic lethality without thrombosis, suggesting that structures of TM not recognized to be involved in coagulation might be critical for normal fetal development. Therefore, the in vivo role of the cytoplasmic domain of TM was studied by using homologous recombination in ES cells to create mice that lack this region of TM (TMcyt/cyt). Cross-breeding of F1 TMwt/cyt mice (1 wild-type and 1 mutant allele) resulted in more than 300 healthy offspring with a normal Mendelian inheritance pattern of 25.7% TMwt/wt, 46.6% TMwt/cyt, and 27.7% TMcyt/cyt mice, indicating that the tail of TM is not necessary for normal fetal development. Phenotypic analyses showed that the TMcyt/cyt mice responded identically to their wild-type littermates after procoagulant, proinflammatory, and skin wound challenges. Plasma levels of plasminogen, plasminogen activator inhibitor 1 (PAI-1), and 2-antiplasmin were unaltered, but plasmin:2-antiplasmin (PAP) levels were significantly lower in TMcyt/cyt mice than in TMwt/wt mice (0.46 ± 0.2 and 1.99 ± 0.1 ng/mL, respectively; P 〈 .001). Tissue levels of TM antigen were also unaffected. However, functional levels of plasma TM in the TMcyt/cyt mice, as measured by thrombin-dependent activation of protein C, were significantly increased (P 〈 .001). This supported the hypothesis that suppression in PAP levels may be due to augmented activation of thrombin-activatable fibrinolysis inhibitor (TAFI), with resultant inhibition of plasmin generation. In conclusion, these studies exclude the cytoplasmic domain of TM from playing a role in the early embryonic lethality of TM-null mice and support its function in regulating plasmin generation in plasma.

Description: Current treatments for preventing thrombotic disease are still inconvenient and associated with a high risk of bleeding. Improved anticoagulant agents are therefore required. TB-402 is a monoclonal antibody (fully human IgG4-antibody) that targets factor VIII (FVIII) and represents a novel type of anticoagulant agent. In vitro, TB-402 only partially inhibits human FVIII even when TB-402 is in excess over FVIII. Preclinical studies confirmed this plateau inhibition and also established the antithrombotic efficacy of TB-402 (Jacquemin M, et al. J Thromb Haemost.2006; 4:1047). Plateau inhibition even in setting of excess TB-402 may allow for improved safety with decreased risk of overdose and decreased need for monitoring. The long half-life of the antibody creates the possibility for a once a month administration. TB-402 may therefore represent a safer and more convenient agent than other available anticoagulants. A Phase I study has completed enrolment of 56 healthy male volunteers. This randomised, double-blind, placebo-controlled, single dose, dose escalation study evaluated the safety and the pharmacokinetic/pharmacodynamic profile of TB-402. Volunteers were treated with a single intravenous administration of placebo or TB-402 at doses of 0.015, 0.1, 0.5, 2.5, 12.5, 37.5, 188, 620 or 1,860 μg/kg. All doses were evaluated in 18–45 year old volunteers, with the highest dose also evaluated in an older age, 55–75 years, cohort. Study drug has been well tolerated in both the young and the older age cohorts, with no safety issues observed. A plateau effect in terms of FVIII level inhibition has been observed. At plateau, FVIII levels were generally decreased by 1/3 to 2/3 from baseline. aPTT prolongation (generally 1.1–1.2 times baseline) was also observed whereas the Prothrombin time (PT) was not modified. aPTT prolongations at doses of ≥ 620 μg/kg were generally maintained for at least 4 weeks. Long half-life of drug and associated anticoagulant effect are supported by the finding of consistent and prolonged effect on aPTT. In conclusion, this study demonstrates that in healthy young and older volunteers a single administration of TB-402 results in a prolonged anticoagulation effect without the risk of overdosing or spontaneous hemorrhage. TB-402 will next be evaluated in patients at risk for venous thromboembolism.

Description: High-capacity adenoviral (HC-Ad) vectors expressing B-domain–deleted human or canine factor VIII from different liver-specific promoters were evaluated for gene therapy of hemophilia A. Intravenous administration of these vectors into hemophilic FVIII-deficient immunodeficient SCID mice (FVIIIKO-SCID) at a dose of 5 × 109 infectious units (IU) resulted in efficient hepatic gene delivery and long-term expression of supraphysiologic FVIII levels (exceeding 15 000 mU/mL), correcting the bleeding diathesis. Injection of only 5 × 107 IU still resulted in therapeutic FVIII levels. In immunocompetent hemophilic FVIII-deficient mice (FVIIIKO), FVIII expression levels peaked at 75 000 mU/mL but declined thereafter because of neutralizing anti-FVIII antibodies and a cellular immune response. Vector administration did not result in thrombocytopenia, anemia, or elevation of the proinflammatory cytokine interleukin-6 (IL-6) and caused no or only transient elevations in serum transaminases. Following transient in vivo depletion of macrophages before gene transfer, significantly higher and stable FVIII expression levels were observed. Injection of only 5 × 106 HC-Ad vectors after macrophage depletion resulted in long-term therapeutic FVIII levels in the FVIIIKO and FVIIIKO-SCID mice. Intravenous injection of an HC-Ad vector into a hemophilia A dog at a dose of 4.3 × 109 IU/kg led to transient therapeutic canine FVIII levels that partially corrected whole-blood clotting time. Inhibitory antibodies to canine FVIII could not be detected, and there were no signs of hepatotoxicity or of hematologic abnormalities. These results contribute to a better understanding of the safety and efficacy of HC-Ad vectors and suggest that the therapeutic window of HC-Ad vectors could be improved by minimizing the interaction between HC-Ad vectors and the innate immune system.

Description: Many patients with anemia fail, for unknown reasons, to respond to erythropoietin (Epo) - the key mediator of the erythropoietic response. Here, we report that loss of the growth arrest-specific gene 6 (Gas6), a polypeptide binding the receptor tyrosine kinases Tyro 3, Axl and Mer, caused a significant depletion of the reserve of erythroid progenitors in mice. As a result, the compensatory erythropoietic response to anemia induced by hemolysis or blood loss was defective in mice lacking Gas6 (Gas6−/ −). The impaired erythropoietic response was attributable to the hyporesponsiveness of Gas6−/ − erythroblasts to the survival activity of Epo. Only when recombinant Gas6 (rGas6) was administered together with Epo, did these factors synergistically rescue the mutant mice from anemia. Administration of rGas6 alone to Gas6−/ − mice also provided protection from phenylhydrazine (PHZ)-induced anemia, presumably due to the ability of Gas6 to enhance the pro-survival effects of Epo on erythroblasts. This was supported by in vivo and in vitro findings: (i) In the absence of Gas6, more erythroblasts died in the spleen of PHZ-treated mice, despite markedly elevated levels of Epo. (ii) Compared to WT, Gas6−/ − erythroblasts responded less to the pro-survival effects of Epo in vitro, suggesting that Gas6 signaling influences Epo receptor (EpoR) signaling. Absence of Gas6 did not alter tyrosine phosphorylation of the EpoR, but reduced Akt phosphorylation in erythroblasts when treated with Epo. Akt phosphorylation in Gas6−/ − erythroblasts was, however, restored to WT levels, when co-treated with Epo and rGas6. These findings indicate that Epo/EpoR-mediated erythroblast survival and proliferation is stimulated by Gas6 via the PI3K/Akt pathway. (iii) WT erythroblasts secrete Gas6 when treated with Epo. Together, erythroblasts, via a “Gas6 feedback system”, regulate, in an autocrine manner, their own responsiveness to Epo by reinforcing signaling downstream of EpoR. This mechanism is delicately balanced, since treatment of WT anemic mice with rGas6 alone reversed the acute anemia induced by hemolysis without causing polycythemia. A similar beneficial response in hematocrit restoration was observed when a transgenic mouse model with chronic anemia was treated with rGas6. In these mice, co-administration of rGas6 and Epo resulted in sustained rise in the hematocrit, to higher levels than achieved with Epo or rGas6 alone. Gas6 is therefore effective in chronic anemia, augments the effects of Epo, and may have Epo dose-sparing effects, and thus may provides novel and safe therapeutic approach to treat patients with Epo-resistant anemia.

Description: Von Willebrand disease (VWD) is an inherited bleeding disorder, caused by quantitative (type 1 and 3) or qualitative (type 2) defects in von Willebrand factor (VWF). Gene therapy is an appealing strategy for treatment of VWD because it is caused by a single gene defect and because VWF is secreted into the circulation, obviating the need for targeting specific organs or tissues. However, development of gene therapy for VWD has been hampered by the considerable length of the VWF cDNA (8.4 kb [kilobase]) and the inherent complexity of the VWF protein that requires extensive posttranslational processing. In this study, a gene-based approach for VWD was developed using lentiviral transduction of blood-outgrowth endothelial cells (BOECs) to express functional VWF. A lentiviral vector encoding complete human VWF was used to transduce BOECs isolated from type 3 VWD dogs resulting in high-transduction efficiencies (95.6% ± 2.2%). Transduced VWD BOECs efficiently expressed functional vector-encoded VWF (4.6 ± 0.4 U/24 hour per 106 cells), with normal binding to GPIbα and collagen and synthesis of a broad range of multimers resulting in phenotypic correction of these cells. These results indicate for the first time that gene therapy of type 3 VWD is feasible and that BOECs are attractive target cells for this purpose.

Description: Hematopoietic stem/progenitor cells (HSC/HPCs) are retained in the bone marrow (BM) niche via receptor-ligand interactions and mobilized from the BM after proteolytic degradation of these retention complexes. Yet, the proteinases and retention signals involved remain incompletely identified. Here, we studied the role of the plasminogen proteinase system with its plasminogen activators PA) tPA and uPA, and active plasmin (Pli) in chemo- and G-CSF-induced mobilization of HPCs and HSCs. Therefore, 5-fluorouracil (5-FU) or G-CSF were administered to mice lacking plasminogen (Plg−/−), tPA (tPA−/−), uPA (uPA−/−), both activators (tPA−/−uPA−/−), uPAR (uPAR−/−), PAI-1 (PAI-1−/−), or α2-antiplasmin (α2-AP−/−). 5-FU treatment in WT mice elevated Pli activity in BM plasma 5-fold, killed 10% of WT mice, and increased number/proliferation of HSC/HPCs in the surviving mice, with full hematopoietic recovery after 3 weeks. In contrast, up to 75% of 5-FU-treated Plg−/−and tPA−/−uPA−/− demised in the early phase of recovery, with reduced number/proliferation of HSC/HPCs and delayed hematopoietic recovery. Following G-CSF, deficiency of Plg or inhibition of Pli by tranexamic acid reduced HPC expansion and HSC translocation in the BM, resulting in impaired HPC/HSC mobilization, by up to 55% and 75%, respectively. Further analysis using uPA−/− and tPA−/− mice revealed that uPA was critical for 5-FU-induced mobilization, whereas tPA was crucial for G-CSF-induced mobilization. In addition, analysis of mice lacking MMP-2, -3, -9, and -12 revealed that 5-FU- and G-CSF-induced mobilization required predominantly MMP-9 and -3, respectively. MMP-3 and MMP-9 activities upon mobilization were reduced in Plg−/− mice, suggesting that Pli activates these MMPs. In the absence of Plg, degradation of fibronectin in the BM and production of soluble Kit ligand (but not SDF1 α) were impaired, indicating additional downstream targets of Pli. uPAR is a membrane-anchored receptor for uPA, which is cleaved into a soluble form (suPAR) by Pli and other proteinases. Interestingly, uPAR was expressed on BM-derived HPC/HSCs, and uPAR deficiency reduced their retention within the BM niche in vitro and in vivo. Furthermore, uPAR−/− mice showed poor HSC/HPC mobilization in response to 5-FU and G-CSF, while suPAR administration in WT mice amplified G-CSF-induced mobilization. Moreover, suPAR levels in the BM were increased in WT but not in Plg−/− mice during mobilization, indicating, all together, that uPAR might be a novel retention signal for HSC/HPCs in the BM niche. Finally, increased Pli activity in PAI-1−/− and α2-AP−/− mice, and WT mice treated with tenecteplase (i.e. recombinant tPA variant used for clinical thrombolysis) enhanced G-CSF-induced mobilization. Importantly, initial results suggest that thrombolytic treatment of individuals after acute myocardial infarction also seemed to stimulate HPC mobilization, extrapolating our findings to man. In conclusion, these genetic and pharmacological data reveal, for the first time, a novel role for uPAR as a retention signal for HSC/HPCs in the BM and suggest that strategies to increase PA or Pli activity might offer novel therapeutic opportunities for HSC/HPC mobilization.

Description: Impaired fibrinolysis, resulting from increased plasminogen activator inhibitor-1 (PAI-1) or reduced tissue-type plasminogen activator (t-PA) plasma levels, may predispose the individual to subacute thrombosis in sepsis and inflammation. The objective of these studies was to show that adenovirus-mediated gene transfer could increase systemic plasma t-PA levels and thrombolytic capacity in animal model systems. Recombinant adenovirus vectors were constructed that express either human wild type or PAI-1–resistant t-PA from the cytomegalovirus (CMV) promoter. Both t-PA-deficient (t-PA−/−) and PAI-1–overexpressing transgenic mice were infected by intravenous injection of these viruses. Intravenous injection of recombinant adenovirus resulted in liver gene transfer, t-PA synthesis, and secretion into the plasma. Virus dose, human t-PA antigen, and activity concentrations in plasma and extent of lysis of a 125I-fibrin–labeled pulmonary embolism were all closely correlated. Plasma t-PA antigen and activity were increased approximately 1,000-fold above normal levels. Clot lysis was significantly increased in mice injected with a t-PA–expressing virus, but not in mice injected with saline or an irrelevant adenovirus. Comparable levels of enzyme activity and clot lysis were obtained with wild type and inhibitor-resistant t-PA viruses. Adenovirus-mediated t-PA gene transfer was found to augment clot lysis as early as 4 hours after infection, but expression levels subsided within 7 days. Adenovirus-mediated transfer of a t-PA gene can effectively increase plasma fibrinolytic activity and either restore (in t-PA–deficient mice) or augment (in PAI-1–overexpressing mice) the thrombolytic capacity in simple animal models of defective fibrinolysis.

Description: Thrombomodulin (TM) is a multidomain protein that serves as a cofactor in a major natural anticoagulant system. To further characterize the structure-function of TM, we have transfected COS cells with different truncated forms of TM. In the first form, COS cells expressing TM that lacks the putative signal peptide (17 residues); the lectin-like, hydrophobic N-terminal domain (226 residues); and 12 residues of the first epidermal growth factor (EGF )-like repeat (COSdel.238 cells) were found to function normally with respect to TM transport to the cell surface and thrombin-dependent protein C activation. However, in contrast to wild-type TM, as visually studied by immunofluorescence and immunogold electron microscopy, the COSdel.238 cells did not constitutively internalize anti-TM–TM or thrombin-TM complexes. To identify the region responsible for mediating the endocytic process, deletant forms of TM lacking either the lectin-like region (residues 2-155) or the hydrophobic region of the N-terminal domain (residues 161-202) were expressed in COS cells (COSdel.2-155 and COSdel.161-202, respectively). Protein C cofactor activity was maintained in both cells. Although the COSdel.161-202 cells behaved similarly to wild-type TM-transfected cells, visual studies showed a lack of constitutive internalization of thrombin-TM or anti-TM–TM complexes in the COSdel.2-155 cells. We conclude that the lectin-like domain of human TM serves to regulate cell surface expression of TM via the endocytic route and therefore may also play a major physiologic role in controlling intracellular and extracellular accumulation of thrombin in a variety of biologic systems.

Description: Recombinant staphylokinase (SakSTAR) variants obtained by site-directed substitution with cysteine, in the core (lysine 96 [Lys96], Lys102, Lys109, and/or Lys135) or the NH2-terminal region that is released during activation of SakSTAR (serine 2 [Ser2] and/or Ser3), were derivatized with thiol-specific (ortho-pyridyl-disulfide or maleimide) polyethylene glycol (PEG) molecules with molecular weights of 5000 (P5), 10 000 (P10), or 20 000 (P20). The specific activities and thrombolytic potencies in human plasma were unaltered for most variants derivatized with PEG (PEGylates), but maleimide PEG derivatives had a better temperature stability profile. In hamsters, SakSTAR was cleared at 2.2 mL/min; variants with 1 P5 molecule were cleared 2-to 5-fold; variants with 2 P5 or 1 P10 molecules were cleared 10-to 30-fold; and variants with 1 P20 molecule were cleared 35-fold slower. A bolus injection induced dose-related lysis of a plasma clot, fibrin labeled with 125 iodine (125I-fibrin plasma clot), and injected into the jugular vein. A 50% clot lysis at 90 minutes required 110 μg/kg SakSTAR; 50 to 110 μg/kg of core-substitution derivatives with 1 P5; 25 μg/kg for NH2-terminal derivatives with 1 P5; 5 to 25 μg/kg with derivatives with 2 P5 or 1 P10; and 7 μg/kg with P20 derivatives. Core substitution with 1 or 2 P5 molecules did not significantly reduce the immunogenicity of SakSTAR in rabbits. Derivatization of staphylokinase with a single PEG molecule allows controllable reduction of the clearance while maintaining thrombolytic potency at a reduced dose. This indicates that mono-PEGylated staphylokinase variants may be used for single intravenous bolus injection.

Description: Circulating complexes of leukocytes and activated platelets are markers for atherosclerosis, but their interaction with the arterial endothelial lining has not been studied. Therefore, the effect of activated platelets on rolling and adhesion of labeled human THP-1 monocytoid cells to human umbilical vein endothelial cell (HUVEC) monolayers was studied by epifluorescence microscopy in a parallel plate flow chamber. In the absence of activated platelets, THP-1 rolling on resting HUVEC was negligible at shear rates greater than 300 s−1. Activation of HUVEC with 100 nmol/L phorbol myristate acetate (PMA) increased THP-1 cell adhesion at shear rates less than 400 s−1. Therefore, a shear rate of 400 s−1 was identified as a threshold for THP-1 adhesion. THP-1 rolling on activated HUVEC was reduced by 64% after L-selectin inhibition but was not affected by P-selectin inhibition. The addition of 1 to 50 thrombin receptor-activating peptide (TRAP)-activated platelets per THP-1 cell enhanced interactions between THP-1 cells and HUVEC, resulting in a steep bell-shaped dose-response curve, with a peak of 10 ± 3 rolling cells/50 seconds at 3 platelets per THP-1 cell (P 〈 .01v control) with a concomitant 2- to 3-fold increase of firmly adhering cells (P 〈 .01 v control). In reconstituted blood, low numbers of activated platelets had the same effect on THP-1 rolling and adhesion. P-selectin inhibition reduced platelet/THP-1 cell interaction in suspension and deposition of the complexes on the endothelial monolayer. Inhibition of both P- and L-selectin reduced THP-1/HUVEC interactions to 14% (P 〈 .01, n = 4). Sialidase digestion and removal of terminal sialic acid residues from HUVEC or THP-1 cells but not from platelets abolished the platelet mediated augmentation of THP-1 cell adhesion. Thus, THP-1 rolling on HUVEC is shear-dependent and largely mediated by L-selectin. P-selectin expressed on activated platelets increases monocytoid cell adhesion to endothelial cells at shear rates found in coronary arteries through interactions with both endothelial and monocytoid cells and may facilitate macrophage accumulation in the vessel wall.