Factor IX antigen by radioimmunoassay. Abnormal factor IX protein in patients on warfarin therapy and with hemophilia B.

Factor IX, isolated from normal human plasma, was homogenous by polyacrylamide gel electrophoresis in urea and sodium dodecyl sulfate. On the latter, it migrated as a single polypeptide chain with or without reducing agents and had an apparent mol wt of 62,000. After iodination by chloramine-T, a single peak of 125I was found on gels. Immunoelectrophoresis in agarose with rabbit antifactor IX sera gave a single arc against both isolated and partially purified factor IX preparations. The rabbit antibody was specific as it failed to inhibit the activities of prothrombin or factors VII or X in normal plasma. At an additional 20-fold dilution, factor IX activity was inhibited 50%. In a double-antibody radioimmunoassay, excess rabbit anti-human factor IX precipitated 90-95% of the 125I-human factor IX. Control without specific antibody gave 6-8%. Dilutions of a pool of normal human plasma paralleled dilutions of the isolated preparation and were used for the standard curve. Of 39 plasma samples from normal donors, the mean factor IX antigen level was 93% of that of a separate normal pool. The radioimmunoassay detected the abnormal factor IX produced in patients on warfarin therapy. After Al(OH)3 adsorption of warfarin treated patient's plasma, factor IX antigen, but not activity, was present in the supernate. Samples from 28 patients on warfarin gave a mean factor IX clotting activity of 27% with a mean antigen of 69%. The antigen level from the warfarin group was significantly lower than the antigen level of the normal group (P less than 0.001). The factor IX antigen level was then assessed in 36 patients from 29 pedigrees with hemophilia B. The median antigen level was 17% of normal. The distribution of the antigen level was wide with two patients around 100% of normal; only two had levels below the limits of resolution of the radioimmunoassay as currently performed (less than 2%). Within each of the five pedigrees in which more than one affected member was tested, activity and antigen levels were the same. The degree of neutralization of the antibody's inhibition of normal plasma by patient's plasma was highly correlated. Additional evidence for the detection of abnormal protein was provided by immunodiffusion of plasmas concentrated by lyophilization. Reactions of complete identity occurred between normal, a warfarin treated and a hemophilia B subject's plasmas.     

Persistent delivery of factor IX in mice: gene therapy for hemophilia using implantable microcapsules.

Severe hemophilia B is a life-threatening, life long condition caused by absence of or defective coagulation factor IX. Gene therapy could provide an alternative treatment to repeated injection of plasma-derived concentrate or recombinant factor IX. We have previously described the use of implantable microcapsules containing recombinant myoblasts to deliver human factor IX in mice. This study reports the generation of improved myoblast-specific expression vectors. Mouse myoblast clones transfected with the various vectors secreted factor IX in vitro, at rates between 70 and 1000 ng/10(6) cells/day. The recombinant myoblast clones were then encapsulated and implanted into mice. Immunocompetent mice implanted with encapsulated myoblasts had up to 65 ng of factor IX per milliliter in their plasma for up to 14 days, after which antibodies to human factor IX became detectable, and this coincided with decreased factor IX in mouse plasma. In immunodeficient mice, however, factor IX delivery was maintained at a constant level for at least 6 weeks (end of experiment). Interestingly, the highest-secreting myoblast clone in vitro did not deliver the highest level of hFIX in vivo. This discrepancy observed between performance in vitro and in vivo may have important implications for the development of gene therapy protocols based on recombinant cells.     

Purification and characterization of an abnormal factor IX (Christmas factor) molecule. Factor IX Chapel Hill.

Human Factor IX (Christmas factor) was isolated from the plasma of a patient with mild hemophilia B. The patient's plasma contained 5% Factor IX clotting activity but 100% Factor IX antigenic activity as determined by immunological assays, which included inhibitor neutralization and a radioimmunoassay for Factor IX. This abnormal Factor IX is called Factor IX Chapel Hill (Factor IXCH). Both normal Factor IX and Factor IXCH have tyrosine as the NH2-terminal amino acid. The two proteins have a similar molecular weight, a similar amino acid analysis, the same number of gamma-carboxyglutamic acid residues (10 gamma-carboxyglutamic acid residues), and a similar carbohydrate content. Both exist as a single-chain glycoprotein in plasma. The major difference between normal Factor IX and Factor IXCH is that the latter exhibits delayed activation to Factor IXa in the presence of Factor XIa and Ca2+. Thus, Factor IXCH differs from other previously described abnormal Factor IX molecules.     

Three point mutations in the factor IX genes of five hemophilia B patients. Identification strategy using localization by altered epitopes in their hemophilic proteins.

In five patients with hemophilia B and detectable Factor IX antigen, altered reactivity to a specific polyclonal antibody fraction or monoclonal anti-Factor IX antibodies was noted. Amplification of selected portions of their Factor IX genes by polymerase chain reaction allowed rapid identification of a single base transition in each of the five families tested. In a patient with severe hemophilia and an altered calcium binding domain, a G to A transition in exon II changed the codon for Glu-27 to Lys (Factor IXSeattle 3). Patients from two families with mild hemophilia with decreased reactivity to a MAb that binds to a site within the sequence coded for by exon IV had a G to A transition changing the codon for Gly-60 to Ser (Factor IXDurham). Two unrelated patients with moderately severe hemophilia lacked reactivity to another murine monoclonal anti-Factor IX which binds to an epitope in the amino-terminal half of the heavy chain of Factor IXa. In these patients, exon VIII contained a G to A transition changing Arg-248 to Gln (Factor IXSeattle 4).     

Role of Vector in Activation of T Cell Subsets in Immune Responses against the Secreted Transgene Product Factor IX

Defining immune responses against the secreted transgene product in a gene therapy setting is critical for treatment of genetic diseases such as hemophilia B (coagulation factor IX deficiency). We have previously shown that intramuscular administration of an adeno-associated viral (AAV) vector results in stable expression of therapeutic levels of factor IX (F.IX) and may be associated with humoral immune responses against F.IX. This study demonstrates that intramuscular injection of an AAV vector expressing F.IX fails to activate F.IX-specific cytotoxic T lymphocytes (CTLs) in hemostatically normal or in hemophilia B mice, so that there is an absence of cellular immune responses against F.IX. However, transgene-derived F.IX can cause B cell responses characterized by production of T helper cell-dependent antibodies (predominantly IgG1, but also IgG2 subclasses) resulting from activation of CD4⁺ T helper cells primarily of the Th2 subset. In contrast, administration of an adenoviral vector efficiently activated F.IX-specific CTLs and T helper cells of both Th1 and Th2 subsets, leading to inflammation and destruction of transduced muscle tissue and activation of B cells as well. Therefore, vector sequences fundamentally influence T cell responses against transgene-encoded F.IX. In conclusion, activation of the immune system in AAV-mediated gene transfer is restricted to pathways mediated by F.IX antigen presentation through MHC class II determinants resulting in T and B cell responses that are more comparable to responses in the setting of protein infusion rather than of viral infection/gene transfer.     

Specific detection of human coagulation factor IX in cynomolgus macaques

Summary.  After screening for species-specific antihuman factor (F)IX monoclonal antibodies, we found that antibody 3A6 did not bind to cynomolgus FIX. The 3A6 epitope was found to include Ala262 of human FIX. The 3A6 antibody was used as a catching antibody in an enzyme immunoassay (EIA) for specific detection of human FIX in cynomolgus macaque plasma. No significant increase of substrate hydrolysis was observed when EIA buffer containing cynomolgus macaque plasma was subjected to the 3A6-based EIA. Addition of up to 30% cynomolgus macaque plasma or canine plasma to the assay did not alter detection of human FIX. Three cynomolgus macaques were injected with human FIX (10 U kg⁻¹; i.v.) and the circulating human FIX was quantified in the macaque plasma. The FIX level in the circulation increased to 470 ± 37.6 ng mL⁻¹ at 1 h after the injection and gradually decreased to 1.79 ± 1.1 ng mL⁻¹ by day 5, which is approximately 0.06% of the normal human plasma FIX concentration. These data suggest that the cynomolgus macaque can be used as a primate model for studying hemophilia B gene therapy by transduction of macaque organs with vectors to express human FIX in vivo and detection of human FIX using the 3A6 monoclonal antibody.     

Technology evaluation: AAV factor IX gene therapy, Avigen Inc

Avigen has developed a recombinant adeno-associated viral vector expressing human blood-coagulation Factor IX (F.IX) for the potential treatment of hemophilia B. In a phase I clinical trial being conducted at The Children's Hospital of Philadelphia and Stanford University Medical Center, the vector, AAV-CMV-hF.IX (Coagulin-B), was injected at a low dose into three patients with severe hemophilia B. No evidence of toxicity, germline transmission of vector sequences, or formation of inhibitory antibodies against F.IX was observed, and in two of the three patients there was an indication of a modest clinical response.     

Partial factor IX protein in a pedigree with hemophilia B due to a partial gene deletion.

A partial gene product was identified in a pedigree with hemophilia B due to a partial deletion of the Factor IX gene (Chen, S.-H.,S. Yoshitake, P.F. Chance, G.L. Bray, A.R. Thompson, C.R. Scott, and K. Kurachi, 1985, J. Clin. Invest., 76:2161-2164). Levels of this mutant protein in plasma of affected family members studied ranged from 24 to 36 ng/ml (0.6-0.9 U/dl or percent of normal) by a solid-phase immunoassay which is sensitive and specific for the calcium-dependent conformation of human Factor IX. No Factor IX antigen could be detected in patients' plasmas by a non-calcium-requiring monoclonal anti-Factor IX antibody (less than 2 ng/ml). The unconcentrated urine from the five affected family members and four obligate heterozygotes the five affected family members and four obligate heterozygotes tested contained calcium-dependent Factor IX antigen levels ranging from 64 to 160 ng/ml (1.6-4.0 U/dl) and from 10 to 68 ng/ml (0.25-1.7 U/dl), respectively. Of nine normal volunteers screened, three had detectable calcium-dependent antigen in unconcentrated first morning-voided urines with 9.6-16.8 ng/ml (0.24-0.42 U/dl), while the remaining six had detectable urinary antigen only after a 10-fold concentration. Abnormal and normal urinary Factor IX antigen species were concentrated, immunoaffinity purified, electrophoresed, immunoblotted, and distinguished by autoradiography after incubation with 125I-polyclonal calcium-requiring anti-Factor IX. After reducing purified or concentrated samples, a single abnormal 36,000-mol-wt band was identified in the urines from the four affected family members and four obligate heterozygotes tested. Electrophoresis of the reduced urinary Factor IX antigen from the one normal subject tested showed a broad 15,000-20,000-mol-wt band. This normal band was smaller than the species in patients' urines, and was seen as a minor component in the samples from the heterozygotes. No abnormal antigen could be detected in urine from the two other female family members tested. Thus, abnormal urinary Factor IX antigen represents a marker for the presence of the hemophilic Factor IX gene in this family.     

Factor IX concentrate versus prothrombin complex concentrate for the treatment of hemophilia B during surgery

Hemophilia B patients are usually treated for the prevention and control of bleeding episodes with a plasma derivative containing the four vitamin K-dependent clotting factors (PPSB). Prothrombin complex concentrate and the French PPSB concentrate are known to be thrombogenic when used in long-term treatment of surgical patients. The present study reports two cases of thrombotic episodes following surgery in PPSB-treated hemophilia B patients. Since 1986, there has been available a factor IX (FIX) concentrate depleted of the other vitamin K-dependent clotting factors and virally inactivated by the solvent-detergent method. This preparation has been used as replacement therapy in six patients with severe hemophilia B who were to undergo orthopedic surgery. The management of the patients before and after operation was without any thrombotic complication or undesirable side effects. The present study suggests that there is a need for an FIX preparation devoid of the other vitamin K-dependent clotting factors for long-term therapy of hemophilia B patients.     

Pharmacological Modulation of Humoral Immunity in a Nonhuman Primate Model of AAV Gene Transfer for Hemophilia B

Liver gene transfer for hemophilia B has shown very promising results in recent clinical studies. A potential complication of gene-based treatments for hemophilia and other inherited disorders, however, is the development of neutralizing antibodies (NAb) against the therapeutic transgene. The risk of developing NAb to the coagulation factor IX (F.IX) transgene product following adeno-associated virus (AAV)-mediated hepatic gene transfer for hemophilia is small but not absent, as formation of inhibitory antibodies to F.IX is observed in experimental animals following liver gene transfer. Thus, strategies to modulate antitransgene NAb responses are needed. Here, we used the anti-B cell monoclonal antibody rituximab (rtx) in combination with cyclosporine A (CsA) to eradicate anti-human F.IX NAb in rhesus macaques previously injected intravenously with AAV8 vectors expressing human F.IX. A short course of immunosuppression (IS) resulted in eradication of anti-F.IX NAb with restoration of plasma F.IX transgene product detection. In one animal, following IS anti-AAV6 antibodies also dropped below detection, allowing for successful AAV vector readministration and resulting in high levels (60% or normal) of F.IX transgene product in plasma. Though the number of animals is small, this study supports for the safety and efficacy of B cell-targeting therapies to eradicate NAb developed following AAV-mediated gene transfer.     

Therapeutic levels of factor IX expression using a muscle-specific promoter and adeno-associated virus serotype 1 vector

Extensive studies in animal models of the X-linked bleeding disorder hemophilia B (deficiency in functional coagulation factor IX, F.IX) have shown that muscle-directed adeno-associated (AAV)-mediated F.IX gene transfer can be used to treat this disease. However, large vector doses of AAV-2 vector are required for therapeutic levels of expression, and the number of vector doses that can be injected per intramuscular site is limited. Several studies have shown that some of these limitations can be overcome by use of AAV serotype 1 vector. Here, we demonstrate levels of F.IX transgene expression from a synthetic muscle-specific promoter (C5-12) that were higher than from the cytomegalovirus (CMV) immediate-early enhancer-promoter in cultured muscle cells in vitro and approximately 50% of CMV-driven expression in vivo in murine skeletal muscle after AAV-1 gene transfer. These data show for the first time that a tissue-specific promoter can be used to achieve therapeutic levels of muscle-derived F.IX expression in the context of viral gene transfer. However, use of a muscle-specific promoter did not prevent antibody formation in response to a murine F.IX transgene product in mice with F.IX gene deletion, indicating that the risk of humoral immune responses remains in the context of an immunologically unfavorable mutation.     

Heterogeneity of the factor IX locus in nine hemophilia B inhibitor patients.

DNA from nine hemophilia B patients who produce anti-factor IX inhibitors (antibodies), including two brothers, was analyzed by the Southern blotting method and hybridization with factor IX cDNA, intragenomic, and 3'-flanking probes. Two inhibitor patients were shown to have total deletions of the factor IX gene. Two other inhibitor patients, the brothers, were shown to have a presumably identical complex rearrangement of the factor IX gene involving two separate deletions. The first deletion is of approximately 5.0 kb and removes exon e. The second deletion is between 9 and 29 kb and removes exons g and h but leaves exon f intact. An abnormal Taq I fragment at one end of the deletion junctions acted as a marker for the inheritance of hemophilia B in the patients' family. Five other inhibitor patients have a structurally intact factor IX gene as detected by this method. Our studies indicate that whereas large structural factor IX gene defects predispose hemophilia B patients to developing an anti-factor IX inhibitor, the development of an inhibitor can be associated with other defects of the factor IX gene.     

Therapy with factor IX concentrate resulting in DIC and thromboembolic phenomena

The development of subclinical DIC in a patient with factor IX hemophilia receiving concentrate replacement therapy during surgery is discussed with respect to pertinent laboratory features. Subsequent thromboembolic phenomena are presented in the context of current literature. Of significance is the failure of heparin given with the factor IX concentrate to prevent DIC. The value of adequate laboratory monitoring during therapy is stressed.     

Identification of T-cell epitopes in clotting factor IX and lack of tolerance in inbred mice

Summary.  Immune responses to the factor IX protein pose problems for hemophilia B patients who develop antibodies against factor IX and for potential future treatment with gene therapy. To better define the response to human factor IX, we analyzed T-cell responses to human factor IX in factor IX knockout mice on BALB/c and C57BL/6 (B6) backgrounds, both strains having CD4+ T cells that proliferate in response to human factor IX. Surprisingly, wild-type mice have similar factor IX-recognizing CD4+ T cells. We defined a dominant CD4+ epitope for each strain (CVETGVKITVVAGEH for BALB/c and LLELDEPLVLNSYVTPIC for B6) that was recognized by both factor IX knockout and wild-type mice. While human factor IX did not cross-react with the mouse homologs of these epitopes, immunization with peptides from murine factor IX stimulated proliferation in factor IX knockout mice and wild-type mice, demonstrating a failure to delete murine factor IX-specific T cells in normal mice.     

Inhibitor-neutralisation assay and electro-immuno assay of human factor IX (Christmas factor)

A rabbit antibody specifically precipitating human factor IX has been used in the assay of factor IX antigen. The results obtained with two different methods (inhibitor-neutralisation assay and electro-immunoassay) have been compared in a group of healthy individuals and in a group of hemophilia B patients and carriers. In general, identical results are obtained with both methods, except in some hemophilia B⁺ carriers and patients, where the electroimmuno assay gives 1.5–2.0 times higher levels. Results obtained by electroimmuno assay are more accurate and reproducible than those obtained by inhibitor-neutralisation assay, which is of importance for its potential use in carrier detection.     

成肌细胞介导的hFⅨ蛋白在小鼠体内的持续表达

目的：以小鼠C2C12成肌细胞为对象开展血友病乙基因治疗研究。方法：首先将构建好的带有MCK增强手和hCMV启动子的反转录病毒载体G1NaMCⅨ转染PA317细胞，并用其上情感染C2C12细胞，所得克隆细胞在离体分别进行了Southern、Northern、Western鉴定。进一步用带有hFⅨcDNA的C2C12细胞进行C3H小鼠活体表达研究。结果：hFⅨ活体表达量与细胞注射数量、细胞离体表达量呈正相关，使用免疫抑制剂可提高hFⅨ活体表达量并延长表达时间；较长时间间隔后进行重复注射亦可延长hFⅨ表达时间。结论：同种异体成肌细胞存在免疫排斥现象，较长时间间隔重复注射可提高移植细胞存活率，从而有助于实现成肌细胞介导的血友病乙基因治疗。     

Induction of immune tolerance to coagulation factor IX antigen by in vivo hepatic gene transfer

Gene replacement therapy is an attractive approach for treatment of genetic disease, but may be complicated by the risk of a neutralizing immune response to the therapeutic gene product. There are examples of humoral and cellular immune responses against the transgene product as well as absence of such responses, depending on vector design and the underlying mutation in the dysfunctional gene. It has been unclear, however, whether transgene expression can induce tolerance to the therapeutic antigen. Here, we demonstrate induction of immune tolerance to a secreted human coagulation factor IX (hF.IX) antigen by adeno-associated viral gene transfer to the liver. Tolerized mice showed absence of anti-hF.IX and substantially reduced in vitro T cell responses after immunization with hF.IX in adjuvant. Tolerance induction was antigen specific, affected a broad range of Th cell subsets, and was favored by higher levels of transgene expression as determined by promoter strength, vector dose, and mouse strain. Hepatocyte-derived hF.IX expression induced regulatory CD4(+) T cells that can suppress anti-hF.IX formation after adoptive transfer. With a strain-dependent rate of success, tolerance to murine F.IX was induced in mice with a large F.IX gene deletion, supporting the relevance of these data for treatment of hemophilia B and other genetic diseases.     

An intragenic deletion of the factor IX gene in a family with hemophilia B.

A family of seven patients severely afflicted with hemophilia B has been studied for their factor IX genes through the use of factor IX cDNA and genomic DNA probes. The patients had detectable (less than 10% of normal) factor IX antigen in urine and no detectable inhibitors in sera to factor IX protein. Based on the DNA hybridization analysis, these patients showed a partial intragenic deletion in their factor IX gene. The deletion included two exons (exons V and VI) coding for the amino acid sequence from number 85 to 195 of the factor IX protein. The deleted portion of the gene contained the entire factor IX activation peptide. The length of the deletion was estimated to be 10 +/- 0.3 kilobase pairs. This specific gene has been named FIXSeattle. In this family both the deletion and a Taq 1 restriction fragment length polymorphism can be used as a useful marker for accurate detection of female carriers of the deficient factor IX gene.     

Muscle as a target for supplementary factor IX gene transfer

Immune responses to the factor IX (F.IX) transgene product are a concern in gene therapy for the X-linked bleeding disorder hemophilia B. The risk for such responses is determined by several factors, including the vector, target tissue, and others. Previously, we have demonstrated that hepatic gene transfer with adeno-associated viral (AAV) vectors can induce F.IX-specific immune tolerance. Muscle-derived F.IX expression, however, is limited by a local immune response. Here, skeletal muscle was investigated as a target for supplemental gene transfer. Given the low invasiveness of intramuscular injections, this route would be ideal for secondary gene transfer, thereby boosting levels of transgene expression. However, this is feasible only if immune tolerance established by compartmentalization of expression to the liver extends to other sites. Immune tolerance to human F.IX established by prior hepatic AAV-2 gene transfer was maintained after subsequent injection of AAV-1 or adenoviral vector into skeletal muscle, and tolerized mice failed to form antibodies or an interferon (IFN)-gamma(+) T cell response to human F.IX. A sustained increase in systemic transgene expression was obtained for AAV-1, whereas an increase after adenoviral gene transfer was transient. A CD8(+) T cell response specifically against adenovirus-transduced fibers was observed, suggesting that cytotoxic T cell responses against viral antigens were sufficient to eliminate expression in muscle. In summary, the data demonstrate that supplemental F.IX gene transfer to skeletal muscle does not break tolerance achieved by liver-derived expression. The approach is efficacious, if the vector for muscle gene transfer does not express immunogenic viral proteins.     

Major role of local immune responses in antibody formation to factor IX in AAV gene transfer

The risk of an immune response to the coagulation factor IX (F.IX) transgene product is a concern in gene therapy for the X-linked bleeding disorder hemophilia B. In order to investigate the mechanism of F.IX-specific lymphocyte activation in the context of adeno-associated viral (AAV) gene transfer to skeletal muscle, we injected AAV-2 vector expressing human F.IX (hF.IX) into outbred immune-competent mice. Systemic hF.IX levels were transiently detected in the circulation, but diminished concomitant with activation of CD4+ T and B cells. ELISPOT assays documented robust responses to hF.IX in the draining lymph nodes of injected muscle by day 14. Formation of inhibitory antibodies to hF.IX was observed over a wide range of vector doses, with increased doses causing stronger immune responses. A prolonged inflammatory reaction in muscle started at 1.5-2 months, but ultimately failed to eliminate transgene expression. By 1.5 months, hF.IX antigen re-emerged in circulation in approximately 70% of animals injected with high vector dose. Hepatic gene transfer elicited only infrequent and weaker immune responses, with higher vector doses causing a reduction in T-cell responses to hF.IX. In summary, the data document substantial influence of target tissue, local antigen presentation, and antigen levels on lymphocyte responses to F.IX.