Hideto Matsui

Ex Vivo Gene Therapy for Hemophilia A That Enhances Safe Delivery and Sustained In Vivo Factor VIII Expression from Lentivirally Engineered Endothelial Progenitors

Novel therapeutic strategies for hemophilia must be at least as effective as current treatments and demonstrate long‐term safety. To date, several small clinical trials of hemophilia gene transfer have failed to show the promise of preclinical evaluations. Therefore, we wanted to develop and evaluate the feasibility of a novel ex vivo gene transfer strategy whereby cells derived from progenitor cells are engineered to express factor VIII (FVIII) and then implanted subcutaneously to act as a depot for FVIII expression. Circulating blood outgrowth endothelial cells (BOECs) were isolated from canine and murine blood and transduced with a lentiviral vector encoding the canine FVIII transgene. To enhance safety, these cells were implanted subcutaneously in a Matrigel scaffold, and the efficacy of this strategy was compared with i.v. delivery of engineered BOECs in nonhemophilic nonobese diabetic/severe combined immunodeficiency mice. Therapeutic levels of FVIII persisted for 15 weeks, and these levels of stable expression were extended to 20 weeks when the cytomegalovirus promoter was replaced with the thrombomodulin regulatory element. Subsequent studies in immunocompetent hemophilic mice, pretreated with tolerizing doses of FVIII or with transient immunosuppression, showed therapeutic FVIII expression for 27 weeks before the eventual return to baseline levels. This loss of transgene expression appears to be due to the disappearance of the implanted cells. The animals treated with either of the two tolerizing regimens did not develop anti‐FVIII antibodies. Biodistribution analysis demonstrated that BOECs were retained inside the subcutaneous implants. These results indicate, for the first time, that genetically modified endothelial progenitor cells implanted in a subcutaneous scaffold can provide sustained therapeutic levels of FVIII and are a promising and safe treatment modality for hemophilia A.

A MicroRNA-regulated and GP64-pseudotyped Lentiviral Vector Mediates Stable Expression of FVIII in a Murine Model of Hemophilia A

The objective to use gene therapy to provide sustained, therapeutic levels of factor VIII (FVIII) for hemophilia A is compromised by the emergence of inhibitory antibodies that prevent FVIII from performing its essential function as a cofactor for factor IX (FIX). FVIII appears to be more immunogenic than FIX and an immune response is associated more frequently with FVIII than FIX gene therapy strategies. We have evaluated a modified lentiviral delivery strategy that facilitates liver-restricted transgene expression and prevents off-target expression in hematopoietic cells by incorporating microRNA (miRNA) target sequences. In contrast to outcomes using this strategy to deliver FIX, this modified delivery strategy was in and of itself insufficient to prevent an anti-FVIII immune response in treated hemophilia A mice. However, pseudotyping the lentivirus with the GP64 envelope glycoprotein, in conjunction with a liver-restricted promoter and a miRNA-regulated FVIII transgene resulted in sustained, therapeutic levels of FVIII. These modifications to the lentiviral delivery system effectively restricted FVIII transgene expression to the liver. Plasma levels of FVIII could be increased to around 9% that of normal levels when macrophages were depleted prior to treating the hemophilia A mice with the modified lentiviral FVIII delivery system.

A murine model for induction of long-term immunologic tolerance to factor VIII does not require persistent detectable levels of plasma factor VIII and involves contributions from Foxp3+ T regulatory cells

Under certain instances, factor VIII (FVIII) stimulates an immune response, and the resulting neutralizing antibodies present a significant clinical challenge. Immunotherapies to re-establish or induce long-term tolerance would be beneficial, and an in-depth knowledge of mechanisms involved in tolerance induction is essential to develop immune-modulating strategies. We have developed a murine model system for studying mechanisms involved in induction of immunologic tolerance to FVIII in hemophilia A mice. We used lentiviral vectors to deliver the canine FVIII transgene to neonatal hemophilic mice and demonstrated that induction of long-term FVIII tolerance could be achieved. Hemophilia A mice are capable of mounting a robust immune response to FVIII after neonatal gene transfer, and tolerance induction is dependent on the route of delivery and type of promoter used. High-level expression of FVIII was not required for tolerance induction and, indeed, tolerance developed in some animals without evidence of detectable plasma FVIII. Tolerance to FVIII could be adoptively transferred to naive hemophilia recipient mice, and FVIII-stimulated splenocytes isolated from tolerized mice expressed increased levels of interleukin-10 and decreased levels of interleukin-6 and interferon-gamma. Finally, induction of FVIII tolerance mediated by this protocol is associated with a FVIII-expandable population of CD4(+)CD25(+)Foxp3(+) regulatory T cells.

Delivery of Full-Length Factor VIII Using a piggyBac Transposon Vector to Correct a Mouse Model of Hemophilia A

Viral vectors have been used for hemophilia A gene therapy. However, due to its large size, full-length Factor VIII (FVIII) cDNA has not been successfully delivered using conventional viral vectors. Moreover, viral vectors may pose safety risks, e.g., adverse immunological reactions or virus-mediated cytotoxicity. Here, we took advantages of the non-viral vector gene delivery system based on piggyBac DNA transposon to transfer the full-length FVIII cDNA, for the purpose of treating hemophilia A. We tested the efficiency of this new vector system in human 293T cells and iPS cells, and confirmed the expression of the full-length FVIII in culture media using activity-sensitive coagulation assays. Hydrodynamic injection of the piggyBac vectors into hemophilia A mice temporally treated with an immunosuppressant resulted in stable production of circulating FVIII for over 300 days without development of anti-FVIII antibodies. Furthermore, tail-clip assay revealed significant improvement of blood coagulation time in the treated mice.piggyBac transposon vectors can facilitate the long-term expression of therapeutic transgenes in vitro and in vivo. This novel gene transfer strategy should provide safe and efficient delivery of FVIII.

Ratio of von Willebrand factor propeptide to ADAMTS13 is associated with severity of sepsis.

ABSTRACT Von Willebrand factor (VWF)–cleaving protease (ADAMTS13) cleaves ultralarge VWF (ULVWF) secreted from endothelium and by which is regulating its physiologic function. An imbalance between ULVWF secretion and ADAMTS13 level occurs in sepsis and may cause multiple organ dysfunction. We evaluated the association between the VWF-propeptide (VWF-pp)/ADAMTS13 ratio and disease severity in patients with severe sepsis or septic shock. In 27 patients with severe sepsis or septic shock and platelet count less than 120 000/&mgr;L, we measured plasma VWF, VWF-pp, and ADAMTS13 levels on hospital days 1, 3, 5, and 7. The VWF-pp/ADAMTS13 ratio was increased greater than 12-fold in patients with severe sepsis or septic shock on day 1 and remained markedly high on days 3, 5, and 7 compared with normal control subjects. The VWF-pp/ADAMTS13 ratio significantly correlated with Acute Physiology and Chronic Health Evaluation II score on days 1 and 5; Sepsis-related Organ Failure Assessment score on days 1, 3, and 5; maximum Sepsis-related Organ Failure Assessment score and tumor necrosis factor &agr; level on days 1, 3, 5, and 7; and creatinine level on days 1, 5, and 7. Patients with greater than stage 1 acute kidney injury had significantly higher VWF-pp/ADAMTS13 ratio than patients without acute kidney injury. In summary, the VWF-pp/ADAMTS13 ratio was associated with disease severity in patients with severe sepsis or septic shock and may help identify patients at risk for multiple organ dysfunction by detecting severe imbalance between ULVWF secretion and ADAMTS13 level.

ADAMTS13 safeguards the myocardium in a mouse model of acute myocardial infarction

Masaaki Doi1,2; Hideto Matsui1; Yukiji Takeda3; Yoshihiko Saito3; Maiko Takeda4; Yasunori Matsunari1,5; Kenji Nishio6; Midori Shima2; Fumiaki Banno7; Masashi Akiyama7; Koichi Kokame7; Toshiyuki Miyata7; Mitsuhiko Sugimoto1 1Department of Regulatory Medicine for Thrombosis, Nara Medical University, Kashihara, Japan; 2Department of Pediatrics, Nara Medical University, Kashihara, Japan; 3Department of Internal Medicine, Nara Medical University, Kashihara, Japan; 4Department of Pathology, Nara Medical University, Kashihara, Japan; 5Department of Anesthesiology, Nara Medical University, Kashihara, Japan; 6Department of General Medicine, Nara Medical University, Kashihara, Japan; 7Department of Molecular Pathogenesis, National Cerebral and Cardiovascular Center, Osaka, Japan

Transient hypoplastic anemia caused by primary human parvovirus B19 infection in a previously untreated patient with hemophilia transfused with a plasma-derived, monoclonal antibody-purified factor VIII concentrate.

BACKGROUND Modern plasma-derived clotting factor concentrates are produced using various virus-inactivation protocols and are assumed to be safer than they were previously with regard to the risk for transmitting viral infections such as human immunodeficiency virus, hepatitis B, and hepatitis C. The risks from viruses that are relatively resistant to the current inactivation procedures remain uncertain. PATIENT A 7-year-old with mild hemophilia A who had not been previously infused with any blood products was treated with a plasma-derived, monoclonal antibody-purified factor VIII concentrate to cover orthopedic surgery after traumatic fracture of his left arm. RESULTS A typical primary human parvovirus (HPV)-B19 infection was observed associated with transient hypoplastic anemia. Retrospective studies including serologic examination and polymerase chain reaction analysis confirmed that the HPV-B19 infection was transmitted by the factor VIII concentrate. CONCLUSIONS Clotting factor concentrates for the treatment of hemophilia retain a risk for HPV-B19 contamination. HPV-B19 viral infection might induce hypoplastic anemia in these patients, particularly during enhanced hemopoiesis after acute blood loss.

A Novel Cell-Sheet Technology That Achieves Durable Factor VIII Delivery in a Mouse Model of Hemophilia A

Gene- or cell-based therapies aimed at creating delivery systems for coagulation factor VIII (FVIII) protein have emerged as promising options for hemophilia A treatment. However, several issues remain to be addressed regarding the efficacies and adverse events of these new classes of therapies. To improve an existing cell-based therapy involving the subcutaneous transplantation of FVIII-transduced blood outgrowth endothelial cells (BOECs), we employed a novel cell-sheet technology that allows individual dispersed cells to form a thin and contiguous monolayer without traditional bioabsorbable scaffold matrices. Compared to the traditional methodology, our cell-sheet approach resulted in longer-term and 3–5-fold higher expression of FVIII (up to 11% of normal) in recipient hemophilia A mice that lacked a FVIII humoral immune response due to transient immunosuppression with cyclophosphamide. Histological studies revealed that the transplanted BOEC sheets were structured as flat clusters, supporting the long-term expression of therapeutic FVIII in plasma from an ectopic subcutaneous space. Our novel tissue-engineering approach using genetically modified BOEC sheets could aid in development of cell-based therapy that will allow safe and effective in vivo delivery of functional FVIII protein in patients with hemophilia A.

Characterization of viability and proliferation of alginate-poly-L-lysine–alginate encapsulated myoblasts using flow cytometry

Genetically modified cells encapsulated in alginate-poly-L-lysine-alginate (APA) are being developed to deliver therapeutic products to treat a variety of diseases. The characterization of the encapsulated cells thus becomes paramount. This study reports a novel method to assess the viability, granularity and proliferation of encapsulated cells based on flow cytometry. The in vitro viability of encapsulated G8 murine myoblasts secreting canine FVIII (cFVIII) measured by flow cytometry was comparable to the traditional trypan blue exclusion method and both correlated with cFVIII secretion levels. In contrast, after implantation into mice, only viability measured by flow cytometry correlated with cFVIII secretion. Further, flow cytometry analysis of encapsulated cells maintained in vitro and in vivo revealed a greater fraction of granular cells compared to free cells, suggesting that encapsulation influences the morphology (cytoplasmic composition) of cells within APA microcapsules. Interestingly, the proliferation study showed that encapsulated cells proliferate faster, on average, and were more heterogeneous in vivo compared to in vitro culture conditions, suggesting that encapsulated cell proliferation is complex and environment-dependent. In conclusion, we show that flow cytometry analysis allows for a more consistent and comprehensive examination of encapsulated cells to aid in the development of cell therapy protocols.

Endothelial progenitor cell-based therapy for hemophilia A

As shown by the results of both pre-clinical and clinical studies reported in past decades, the goal of establishing an effective and successful gene therapy for hemophilia A remains feasible and realistic. However, at this time, no single approach has been shown to be clearly superior, and a number of recurring challenges remain to be overcome. Given the persistent problems presented by the host immune response to systemic in vivo gene delivery, and the additional obstacles of inadequate transgene delivery and expression, we propose a re-evaluation of an ex vivo gene transfer approach that utilizes a genetically modified stem cell population. In this strategy, autologous blood outgrowth endothelial progenitor cells are obtained from hemophilic animals, into which a normal copy of the factor VIII gene is introduced via an engineered virus. Cell numbers are expanded in culture prior to their re-implantation under the skin of the hemophilic animals in an artificially developed supporting environment. Follow-up assessment of the treatment involves the general evaluation of clotting activity, the specific measurement of factor VIII levels in the blood, and clinical observation.