Transfer of PR1-specific T-cell clones from donor to recipient by stem cell transplantation and association with GvL activity.

BACKGROUND: The curative effects of GvL following transfer of donor-derived T cells during allogeneic stem cell transplantation (SCT) are well established. However, little is known about the nature, origin and kinetics of the anti-leukemic T-cell responses involved. METHODS: We used quantitative real-time PCR (qRT-PCR) for interferongamma mRNA production (IFN-gamma) and PR1/HLA-A*0201 tetramer staining to detect PR1-specific CD8+ T-cell activity in a donor and a patient with CML. Unbiased strand switch anchored RT-PCR was used to further characterize specific clones in PR1 sorted CD8+ T-cell populations. RESULTS: We identified PR1-specific CD8(+) T-cell clones from a donor pre-transplant, and demonstrated their transfer in the recipient's blood post-SCT using molecular tracking of Ag-specific T-cell receptors. PR1-specific CD8(+) T-cell populations were polyclonal, with a range of functional avidities for cognate Ag, and displayed predominantly effector memory phenotype early post-SCT, suggesting active stimulation in vivo. Expansion of these PR1-specific CD8(+) T-cell clones in the recipient was followed by complete remission of CML. DISCUSSION: This report represents the first direct demonstration that PR1-specific CD8(+) T-cell clones can be transferred during SCT, and supports the feasibility of pre-transplant vaccination strategies that aim to boost the number of anti-leukemic T cells in the graft.

Platelet von Willebrand factor in Hermansky-Pudlak syndrome.

The Hermansky-Pudlak Syndrome (HPS) is an autosomal recessive inherited disorder characterized by oculocutaneous albinism, tissue accumulation of ceroid pigment, and a mild to moderate bleeding diathesis attributed to storage-pool deficient (SPD) platlets. Patients have platelet aggregation and release abnormalities. In addition, low levels of plasma von Willebrand factor (vWF) antigen in some HPS patients have been associated with a greater bleeding tendency than would be predicted from either condition alone. Other HPS patients have severe bleeding despite normal levels of plasma vWF, suggesting that at least one additional factor is responsible for their bleeding diathesis. Because platelet vWF levels have been well correlated with clinical bleeding times in patients with von Willebrand's disease, we have measured the platelet vWF activity and antigen levels in 30 HPS patients and have attempted to correlate their clinical bleeding with these values. The platelet vWF activity levels in patients was significantly lower than that of normal subjects (P < 0.0001). The patients as a group also had slightly lower values of plasma vWF activity when compared with normals (P-0.03). In 11 of the HPS patients, the multimeric structure of plasma vWF showed a decrease in the high molecular weight multimers and an increase in the low molecular weight multimers. In correlating the platelet and plasma vWF values with the bleeding histories, we were not able to show a predictable relationship in the majority of the patients.

Glycoprotein Ib alpha peptides inhibit thrombin and SFLLRN-induced platelet aggregation.

The platelet glycoprotein Ib(alpha) (GPIb(alpha)) receptor contains a high-affinity binding site for thrombin that, when occupied, augments platelet activation and aggregation in part via the 7-transmembrane domain receptor (7-TMDR). We have constructed a series of peptides derived from GPIb(alpha) that encompass the amino acid sequence F216-T240. We have studied the effect(s) of these peptides on platelet aggregation induced by thrombin or by the 7-TMDR peptide SFLLRN. Twenty-four peptides were synthesized from the peptide sequence F216-T240. Several of the peptides derived from the sequence W219-V227 of GPIb(alpha) inhibited platelet aggregation, which was primarily dependent on the presence of the amino acid sequence A224-N226 (AEN). These data suggest that a region within the GPIb(alpha) chain modulates the platelet aggregation induced by alpha-thrombin. These GPIb(alpha) peptides did not interfere with platelet aggregation induced by other agonists--for example, collagen, ristocetin, calcium ionophore, or botrocetin--which indicates that these GPIb(alpha) peptide-platelet interaction(s) are specific. Our studies provide another potential mechanism for modulating platelet activation and aggregation via synthetic and natural peptides.

1-Desamino-8-arginine-vasopressin corrects the hemostatic defects in type 2B von Willebrand's disease.

DDAVP is effective treatment in most types of von Willebrand's disease; however, in type 2B von Willebrand's disease the use of DDAVP has been contraindicated due to DDAVP-induced thrombocytopenia. Several reports have confirmed the thrombocytopenic effects of DDAVP and the presence of circulating platelet aggregates in type 2B von Willebrand's disease. We have infused three type 2B patients with DDAVP. The three patients had different mutations of their vWf. All three patients had a missense mutation which resulted in a single amino acid substitution in the disulfide loop of the A1 domain. Administration of 20 micrograms of DDAVP resulted in significant elevations of factor VIII, vWf antigen, and ristocetin cofactor levels. In contrast to other studies, DDAVP did not induce or enhance thrombocytopenia in these three patients. When blood was obtained by fingerstick and diluted into sodium oxalate (Unopette) or EDTA (Microvette), the platelet counts did not change over 4 hr. In contrast, blood collected directly into evacuated tubes containing sodium citrate, lithium heparin, or EDTA consistently demonstrated varying degrees of thrombocytopenia and platelet clumping. We also observed a shortening of the pre-infusion bleeding time over the 4 hr period. All three patients have been studied twice and each has shown consistent results. DDAVP appears to be a useful form of treatment in type 2B vWd.

Purification and characterization of human platelet von Willebrand factor.

Platelet von Willebrand factor (vWf) was purified from human platelet concentrates. The multimeric structure of the purified platelet vWf was similar to that observed in the initial platelet lysate, and, like the platelet lysate, the purified platelet vWf contained higher molecular weight multimers than plasma vWf. The apparent molecular weight of the reduced platelet vWf subunit was similar to the plasma vWf subunit. The N-terminal amino acid of the purified platelet and plasma vWf was blocked. In concentration dependent binding to botrocetin- or ristocetin-stimulated platelets, 125I-plasma vWf bound with a higher affinity than platelet. The ristocetin cofactor activity per mg of purified plasma vWf was 5-fold greater than the platelet vWf activity. Platelet and plasma vWf bound to collagen with similar affinities; however, platelet vWf bound to thrombin-stimulated platelets and to heparin with a higher affinity than plasma vWf. The differences in the binding affinity(s) of plasma and platelet vWf to platelet GPIb and GPIIb/IIIa and extracellular matrix proteins may reflect different roles for plasma and platelet vWf in the initial stages of haemostasis and thrombosis.

High-affinity alpha-thrombin binding to platelet glycoprotein Ib alpha: identification of two binding domains.

alpha-Thrombin binding to and activation of platelets are of major importance in the initiation of physiologic thrombi and in the genesis of arterial thrombus formation. We have studied the site(s) and affinity of thrombin binding to human platelets. Our studies of the peptide inhibition of thrombin binding indicate that the glycoprotein Ib alpha binding site is of high affinity, Kd approximately 10(-10) M, while the seven-transmembrane-domain site is a moderate-affinity thrombin binding site, Kd approximately 10(-8) M. Further studies to modulate the high- or moderate-affinity thrombin binding can be directed to a specific class of sites. This would allow partial or total inhibition of specific thrombin-platelet interaction(s) in different clinical settings.

Platelet adhesion to collagen in individuals lacking glycoprotein IV.

The Naka isoantigen is expressed on glycoprotein (GP) IV (CD36), a platelet membrane GP that has been identified as having a role in platelet interactions with collagen and thrombospondin and in binding Plasmodium falciparum-infected erythrocytes to endothelial cells and melanoma cells. We have studied normal platelets and Naka- platelets from two Japanese donors that have 1% of GPIV by concentration-dependent antibody binding and flow cytometry. We studied the adherence of normal and Naka- platelets to types I, III, and IV collagen in static and to type I collagen in flowing systems at high shear force. We have also studied aggregation of normal and Naka- platelets to type I collagen. Naka- platelets showed normal or increased aggregation to type I collagen and normal adhesion to types I, III, and IV collagen in the presence of Mg++ or EDTA. Platelet aggregation and adhesion were inhibited by the anti-alpha 2 beta 1 antibody 176D7 to the same extent in Naka- as in normal platelets. We also studied endogenous thrombospondin surface expression and found that thrombin-stimulated Naka- platelets expressed the same amount of thrombospondin as did normal platelets. From our studies with Naka- platelets, we cannot identify a definitive role for GPIV in platelet aggregation, in adhesion to types I, III, and IV collagen, or in endogenous thrombospondin binding to platelets.

Endogenous platelet fibrinogen: its modulation after surface expression is related to size-selective access to and conformational changes in the bound fibrinogen.

Platelet stimulation results in the release of endogenous platelet fibrinogen which binds to the platelet surface. Previous studies have demonstrated that plasma fibrinogen bound to activated platelets becomes inaccessible to a variety of probes. We have studied endogenous platelet fibrinogen binding to activated platelets by employing an immunopurified polyclonal anti-fibrinogen antibody and F26, a monoclonal anti-fibrinogen antibody, which recognizes fibrinogen only when it is bound to a surface. Employing the Ig or F(ab')2 of the poly- or monoclonal antibody we found a marked decrease of fibrinogen accessibility 30-60 min after platelet activation. In contrast, platelet-bound fibrinogen remains accessible to the Fab fragment of F26 at a constant level for 30 min and increases at 60 min. The reduction of the polyclonal Fab fragment binding at 30 and 60 min is similar to the F26 Ig. These results indicate that the decreased accessibility of bound fibrinogen is related to two mechanisms; (1) that the access route to fibrinogen in size selective for the antibody probes and only small antibody probes, e.g. Fab fragments, can gain access to fibrinogen and (2) fibrinogen undergoes a conformational change(s) after binding which exposes at least one neo-epitope in the D domain of fibrinogen and which may decrease or mask the reactivity of other fibrinogen domains. Only the F26 Fab probe has full access to and identifies fibrinogen present on the platelet surface 60 min after stimulation.

Platelet activation and alpha granule secretion in type IIB von Willebrand's disease.

Type IIB von Willebrand disease is characterized by enhanced ristocetin-induced platelet aggregation, spontaneous platelet aggregation, thrombocytopenia and the absence of the largest plasma von Willebrand factor (vWf) multimers. The absence of the largest plasma vWf multimers is related to their enhanced binding to platelets. The abnormal affinity of the IIB von Willebrand factor to platelets results in thrombocytopenia, but the mechanism is not known. We have studied the platelets from three patients with type IIB von Willebrand disease and have found evidence of platelet activation and alpha granule secretion as defined by increased amounts of von Willebrand factor, fibrinogen and the alpha granule protein PADGEM/GMP-140 on the surface of these platelets. The degree of thrombocytopenia appears to be directly related to the number of platelets with fibrinogen bound to the surface. PADGEM/GMP-140, an alpha granule membrane protein, fuses with the platelet plasma membrane after activation and is a site on platelets which binds to neutrophils or monocytes. This alpha granule protein may play an additional role in platelet clearance and thrombocytopenia in type IIB von Willebrand disease. This may, in part, explain the absence of thromboembolic phenomena despite the presence of activated platelets in patients with type IIB von Willebrand disease.

Endogenous platelet fibrinogen surface expression on activated platelets.

Intracellular platelet fibrinogen surface expression was studied in arabinogalactan-purified, resting, and thrombin-stimulated platelets. Platelet fibrinogen is derived from endocytosis of plasma fibrinogen by megakaryocytes. Like a variety of other adhesive proteins, it is stored in the platelet alpha-granule. Platelet fibrinogen surface expression was studied by using the antigen-binding fragments of a murine monoclonal antibody to platelet fibrinogen, F26, and an immunopurified polyclonal antifibrinogen antibody. Studies correlating platelet fibrinogen surface expression with the presence of the glycoprotein IIb-IIIa (GPIIb-IIIa) complex showed that in the presence of ethylene glycol tetraacetic acid (EGTA) at 37 degrees C, neither the GPIIb-IIIa complex nor platelet fibrinogen was expressed on the surface of thrombin-activated platelets. Similar experiments performed in the presence of EGTA and calcium showed proportional expression of the GPIIb-IIIa complex and platelet fibrinogen. The addition of Arg-Gly-Asp-Ser-containing peptides, the pentadecapeptide of the fibrinogen gamma-chain carboxy terminus, or the monoclonal antibody 10E5, when directed against the GPIIb-IIIa complex before thrombin activation, inhibited 65% to 94% of the platelet fibrinogen expression, as determined with the polyclonal and monoclonal antigen-binding fragments. When these same inhibitory agents were added immediately after or 5 minutes after thrombin, the amount of inhibition decreased significantly. Similar studies with a washed platelet system revealed that when the inhibitors of platelet fibrinogen expression were added before thrombin stimulation, the degree of inhibition observed was only 24% to 38%. This suggests that the major portion of platelet fibrinogen expression involves the release of platelet fibrinogen and its subsequent binding to GPIIb-IIIa. This binding may occur within the open canalicular system or on the platelet surface; in either case, wherever the site of released platelet fibrinogen binding occurs, it can be markedly inhibited by the RGD-containing peptides and the gamma-chain fibrinogen peptides. Approximately 10% to 30% of platelet fibrinogen may be expressed prebound to a platelet receptor, or else it is released and binds to a platelet receptor other than the GPIIb-IIIa complex.

Platelet von Willebrand factor.

von Willebrand factor (vWF) circulates in the blood in two distinct compartments. One, plasma vWF, is synthesized and released from endothelial cells; the second, synthesized by megakaryocytes, circulates in platelets primarily stored in the alpha granules. Recent experimental and clinical studies of von Willebrand's disease (vWD) indicate that platelet vWF plays an important role in the bleeding time determination and the degree of clinical bleeding in vWD. Platelet vWF is released from the platelet alpha granules by various agonists and then rebinds to the glycoprotein IIb/IIIa complex. Fibrinogen or monoclonal antibodies against this complex inhibit 60 to 70% of the expression of platelet vWF. Aspirin inhibits 80% of the adenosine diphosphate-induced platelet vWF surface expression, and the platelet vWF surface expression that is not inhibited by aspirin can be almost totally inhibited by disruption of the platelet cytoskeleton. Platelet vWF may, in part, be expressed in the open canalicular system prebound to a receptor. Transfusion studies have shown that correction of the bleeding time in severe vWD requires both plasma and platelet vWF. On the basis of numerous studies, we hypothesize that platelet vWF plays an important role in platelet interaction with the subendothelial surfaces under conditions of high shear stress. After platelet contact, platelet vWF is released, binds to the glycoprotein IIb/IIIa complex, and forms a bridge between the subendothelial surface and the platelet, which initiates and supports platelet spreading. Platelet vWF also acts as an intercellular bridge between platelets and thereby promotes platelet aggregation. This process is important not only in the initial steps of hemostasis but also in the process of thrombosis.