Results of unrelated umbilical cord blood hematopoietic stem cell transplantation

The number of umbilical cord blood transplants is increasing worldwide. The purpose of Eurocord is to evaluate the results and to compare the outcome of umbilical cord blood transplants with allogeneic bone marrow transplants. Data have been reported to Eurocord by multiple transplant centers. Close links have been established with the cord blood banks through Netcord. Bone marrow transplant data have been provided by transplant centers and also through the European Group for Blood and Marrow Transplantation (EBMT) and International Bone Marrow Transplant Registries (IBMTR). Eurocord has analyzed the outcome of unrelated umbilical cord blood transplants from 121 transplant centers and 29 countries. The results showed that survival with unrelated mismatched umbilical cord blood transplants was comparable to that with unrelated bone marrow transplants. Engraftment with cord blood was delayed, resulting in an increased incidence of early transplant complications. The incidence of acute and chronic graft-vs.-host disease was reduced with cord blood grafts even in human leukocyte antigen (HLA)-mismatched transplants and in adults. In patients with leukemia, the rate of relapse was similar to the rate of relapse after bone marrow transplant. The overall event-free survival with umbilical cord blood transplantation was not statistically different when compared to bone marrow transplants. This large registry study confirms the potential benefit of using umbilical cord blood hematopoietic stem cells for allogeneic transplants.     

Familiäre Leukämien

Leukemias and other hematological neoplasias are frequently observed in association with different genetic disorders, such as DNA repair deficiency syndromes, tumor predisposition syndromes, immunodeficiency syndromes, familial cancer syndromes and bone marrow failure syndromes, as well as in connection with several constitutional chromosomal anomalies. Recently, in families with increased leukemia incidence, constitutional mutations have been identified in genes that are also affected by somatic mutations in sporadic leukemias. In addition to these high penetrance mutations, gene alterations with low penetrance and polymorphisms seem to predispose to leukemia and/or modify the clinical course of the disease. Predisposing and modifying polymorphisms can be found in genes involved in cell proliferation, apoptosis, DNA repair, detoxification, etc. The novel findings on constitutional genetic alterations predisposing to leukemia start to close the gap between inborn and acquired genetic diseases.     

肿瘤干细胞的光动力治疗研究进展

肿瘤干细胞(cancerstem cells,CSCs)是在肿瘤组织中具有干细胞特性的细胞亚群,它具有正常干细胞的多向分化潜能,能够无限增值和自主分化为各种具有异质性的肿瘤细胞。CSCs在肿瘤的发生、生长、转移中起着重要作用。同时,CSCs对目前大多数治疗如化疗、放疗不敏感,甚至具有耐药性,这也就导致了恶性肿瘤在治疗后容易复发。鉴于此,针对肿瘤干细胞的治疗日益受到关注,光动力疗法(photodynamictherapy,PDT)由于其微创性,不良反应少,靶向性强等特点在肿瘤的治疗研究中不断得到发展。本文将从CSCs的特性入手,结合PDT治疗的最新进展,探讨PDT治疗在肿瘤干细胞治疗中的应用。     

Adoptive transfer of neoantigen-specific T-cell therapy is feasible in older patients with higher-risk myelodysplastic syndrome

BackgroundMyelodysplastic syndromes (MDS) represent the most common type of acquired bone marrow failure in adults and is characterized by ineffective maturation of myeloid precursor cells and peripheral cytopenias associated with higher rates of infection, bleeding and transfusion dependence. In higher-risk patients with MDS who relapse or do not respond after standard hypomethylating agent (HMA) therapy, the 2-year survival rate is 15%.MethodsHere the authors report the feasibility and safety of a novel experimental T-cell therapy called personalized adoptive cell therapy, which selects, immunizes and expands T cells against MDS-specific mutations and is targeted to patient-specific tumor cell neoantigens. Somatic mutations serve as the pathogenic drivers of cancer, including MDS, as these transformative genetic mutations may generate novel immunogenic proteins (i.e., neopeptides and possible neoantigens) that may be targeted therapeutically.ResultsThe authors demonstrate that the adaptive immune system can be trained ex vivo to recognize neopeptides as neoantigens and that the infusion of culture-expanded, neoantigen-immunized autologous T cells has been feasible and safe in the three patients treated to date.DiscussionThe authors report on early results from their first-in-human phase 1 clinical trial that aims to assess the safety and tolerability of this novel form of adoptive T-cell immunotherapy for HMA-refractory patients with higher-risk MDS.     

Recent advances in gene therapy and future prospects

Gene therapy, which is treatment of diseases by introducing normal genes into the body, is becoming feasible as the result of advances in genetic engineering. The hematopoietic stem cells have been considered as the appropriate target for gene transfer in many genetic diseases for which allogeneic bone marrow transplantation has been employed successfully. However, there are still many problems to be solved. In particular, expression from retrovirally transduced genes in bone marrow cells has been transient and unstable. On the other hand, an alternative approach to somatic cell gene therapy using nonhematopoietic cells, including skin fibroblasts, endothelial cells, keratinocytes, and lymphocytes, has been shown to possess several advantages. This kind of approach is usually applied to supplementation therapy in not only hereditary disorders but also various acquired diseases, such as cancer or infectious diseases. Recently, clinical application of gene transfer into lymphocytes to treat cancer and immunodeficiency have been approved at NIH (USA). The trial could represent the start of a new era in molecular medicine.     

Poor prognosis of acute lymphoblastic leukemia with translocation (1;19) in childhood: potential interest of allogeneic bone marrow transplantation

We report a new case of childhood acute lymphoblastic leukemia with translocation (1;19). At the time of diagnosis, the only adverse prognosis factor was the existence of this translocation. Under conventional chemotherapy, the girl experienced early marrow relapse (duration of first remission was 2 months). She received allogeneic bone marrow transplantation during the second remission and is alive in continuous complete remission 20 months after transplant. Several earlier reports have suggested that children with the (1;19) have a poor prognosis; If this poor response to conventional therapy is confirmed, an allogeneic bone marrow transplantation should be considered during the first remission.     

Evidence that specific T lymphocytes may participate in the elimination of chronic myelogenous leukemia

Although the immune system has long been implicated in the control of cancer, evidence for specific and efficacious immune responses in human cancer has been lacking. In the case of chronic myelogenous leukemia (CML), either allogeneic bone marrow transplant (BMT) or interferon-alpha2b (IFN-alpha2b) therapy can result in complete remission, but the mechanism for prolonged disease control is unknown and may involve immune anti-leukemic responses. We previously demonstrated that PR1, a peptide derived from proteinase 3, is a potential target for CML-specific T cells. Here we studied 38 CML patients treated with allogeneic BMT, IFN- alpha2b or chemotherapy to look for PR1-specific T cells using PR1/HLA-A*0201 tetrameric complexes. There was a strong correlation between the presence of PR1-specific T cells and clinical responses after IFN-alpha and allogeneic BMT. This provides for the first time direct evidence of a role for T-cell immunity in clearing malignant cells.     

Bone marrow transplantation results in donor-derived hepatocytes in an animal model of inherited cholestatic liver disease

Cell transplantation is a potential therapy for acquired or inherited liver diseases. Donor-derived hepatocytes (DDH) have been found in humans and mice after bone marrow transplantation (BMT) but with highly variable frequencies in different disease models. To test the effect of liver repopulation after BMT in inherited cholestatic liver diseases, spgp (sister of P-glycoprotein, or bile salt export pump, abcb11) knockout mice, a model for human progressive intrahepatic cholestasis type 2 with defects in excreting bile salts across the hepatocyte canalicular membrane, were transplanted with bone marrow cells from enhanced green fluorescent protein (EGFP) transgenic donor mice after lethal irradiation. One to 6 months later, scattered EGFP-positive DDHs with positive spgp staining were observed in the liver. These hepatocytes had been incorporated into hepatic plates and stained positively with hepatocyte-specific marker albumin. RT-PCR for the spgp gene revealed positive expression in the liver of sgsp knockout mice that had received the transplant. Bile acid analysis of bile samples showed that these mice also had higher levels of total biliary bile acid and taurocholic acid concentration than knockout mice without transplantation, indicating that BMT partially improved biliary bile acid secretion. Our results indicate that bone marrow cells could serve as a potential source for restoration of hepatic functions in chronic metabolic liver disease.     

Clinical use of rHuEPO in bone marrow transplantation

Recipients of bone marrow (BMT) or peripheral blood progenitor stem cells (PBSCT) transplant have in the period following transplantation a frequent need for red blood cell transfusions and therefore an increased risk of blood-transmitted infections. The anaemia is caused mainly by myelosuppression after high-dose chemotherapy, but an impaired erythropoietin (EPO) production and an inappropriate EPO response may also contribute. Since recombinant human erythropoietin (rHuEPO) has been established as a treatment for renal anaemia it has been of interest whether treatment may be of benefit in the transplant setting. This paper gives an overview of the studies conducted to date with rHuEPO treatment in patients receiving bone marrow transplants. Current data donot support any transfusional benefits when rHuEPO is used in patients receiving autologous transplants. However, in patients receiving allogeneic transplants several studies clearly indicate a therapeutic role for rHuEPO with patients showing accelerated erythroid engraftment, increased haemoglobin levels, a reduced requirement for red blood cell transfusions, and a shortened time to transfusion independence. Especially patients with immune haemolysis after transplantation seems to benefit from the treatment. In addition, rHuEPO treatment has been used for lateonset anaemia after BMT and to prevent the need for homologous red blood cell transfusions to the BMT donor. To reduce costs, it is important in future studies to identify not only the optimal dose and route of administration of rHuEPO but also the most effective combination with other haematopoietic growth factors and cytokines that are used before and after transplantation.     

Post-bone marrow transplant patient management

Increasingly, bone marrow transplant (BMT) is the treatment of choice for certain hematologic diseases. BMT is, however, a risky procedure with many potentially serious complications. Some complications are the result of the conditioning regimen, a stage of transplantation that includes large doses of chemotherapy and/or radiation therapy. Conditioning-induced neutropenia and thrombocytopenia often result in infection, bleeding, and mucositis. Veno-occlusive disease (VOD), a chemotherapy-induced hepatotoxicity, can cause a mild to severe form of liver disease. Other complications are directly attributable to the engrafted new marrow. Graft-versus-host disease, a rejection process initiated by immunocompetent donor T lymphocytes, is a complication frequently observed in allogeneic BMT. Approximately 14-28 days after the day of transplant, signs of engraftment begin to appear. When specific discharge criteria are met, the BMT patient is discharged from the hospital. Specific follow-up medical care is ongoing for about one year after BMT.     

Gene therapy using anticancer drug-resistance genes

Myelosuppression is a major dose-limiting factor in cancer chemotherapy. Introduction of drug-resistance genes into bone marrow cells of cancer patients has been proposed to overcome this limitation. In theory, any gene whose expression protects cells against the toxic effects of chemotherapy should be useful in vivo for this purpose. Among such genes, human multidrug-resistance gene (MDR1) has been studied most extensively for this purpose, and clinical trials of drug-resistance gene therapy have been started in the US for cancer patients who undergo high-dose chemotherapy with autologous hematopoietic stem cell transplantation. In Japan, our clinical protocol of MDR1 gene therapy "A clinical study of drug-resistance gene therapy to improve the efficacy and safety of chemotherapy against breast cancer" has been submitted to the government. To improve the efficacy and safety of this drug-resistance gene therapy, we have constructed a series of MDR1-bicistronic retrovirus vectors using a retrovirus backbone of Harvey murine sarcoma virus and internal ribosome entry site (IRES) from picornavirus to co-express a second gene with the MDR1 gene. MDR1-MGMT bicistronic vectors can be used to protect bone marrow cells of cancer patients from combination chemotherapy with MDR1-related anticancer agents and nitrosoureas. In addition, MDR1-bicistronic retrovirus vectors can be designed to use the MDR1 gene as an in vivo selectable marker to enrich the transduced cells which express therapeutic genes, if disease is curable by the expression of a single-peptide gene in any types of bone marrow cells or peripheral blood cells.     

人源化抗体制备及其应用研究进展

伴随着一系列重大生物技术(如PCR技术、抗体库技术、转基因动物技术等)的发展,抗体技术从最初的嵌合抗体、改型抗体逐渐发展为今天的人源化抗体。人源化抗体在治疗肿瘤、自身免疫性疾病和器官移植等方面已经显示出独特的优势和良好的应用前景。介绍了人源化抗体的构建及其表达系统,并对其临床应用进行了展望。     

Development of tolerogenic strategies in the clinic

The study of tolerance in the clinic can be divided into three areas: (i) focused evaluation of existing tolerant transplant recipients as to their mechanism of tolerance; (ii) prospective tolerance trials, such as combined bone marrow and kidney transplantation as well as T cell depletion followed by subsequent weaning of immunosuppression; and (iii) immunologic assays to assess the likelihood of rejection or tolerance. Frankly, a very small number of patients have been transplanted with the intention of removing all immunosuppressive therapy, but several clinical trials with this aim are currently in progress, largely sponsored by the Immune Tolerance Network, a joint venture between the National Institutes of Health and the Juvenile Diabetes Research Foundation. Similarly, a reliable assay to assess tolerance has not yet been developed but a variety of approaches towards assessing rejection, and in some cases tolerance, are being developed. It would be accurate to state that many of the experimental and preclinical approaches to the induction of tolerance have resulted in better immunosuppression for human transplantation, but reliable tolerance strategies in humans have not yet been achieved. Combined bone marrow and kidney transplantation may be considered as one exception to this, but such a strategy is not generally applicable to the vast majority of solid organ transplant recipients. This review will summarize efforts to date, particularly focusing on kidney transplantation.     

The human polyomavirus BK: Potential role in cancer

In human cancer, a role has been suggested for the human polyomavirus BK, primarily associated with tubulointerstitial nephritis and ureteric stenosis in renal transplant recipients, and with hemorrhagic cystitis in bone marrow transplant (BMT) recipients. After the initial infection, primarily unapparent and without clinical signs, the virus disseminates and establishes a persistent infection in the urinary tract and lymphocytes. There is correlative evidence regarding potential role of polyomavirus BK in cancer. In fact, the BK virus (BKV) DNA (complete genome and/or subgenomic fragments containing the early region) is able to transform embryonic fibroblasts and cells cultured from kidney and brain of hamster, mouse, rat, rabbit, and monkey. Nevertheless, transformation of human cells by BKV is inefficient and often abortive. Evidence supporting a possible role for BKV in human cancer has accumulated slowly in recent years, after the advent of polymerase chain reaction (PCR). BKV is known to commonly establish persistent infections in people and to be excreted in the urine by individuals who are asymptomatic, complicating the evaluation of its potential role in development of human cancer. Therefore, there is no certain proof that human polyomavirus BK directly causes the cancer in humans or acts as a cofactor in the pathogenesis of some types of human cancer.     

Multiple Chromosome Abnormalities Following Bone Marrow Transplant for Chronic Myelogenous Leukemia

A 44-year-old female was diagnosed in the chronic phase of chronic myelogenous leukemia (CML) and was confirmed to be Philadelphia chromosome positive by a bone marrow cytogenetic study. No additional cytogenetic abnormalities were found. The patient's cell counts were initially well controlled with hydrox-yurea. She then received an unrelated 6 of 6 HLA matched allo-geneic bone marrow transplant (BMT) from a male donor. The patient underwent myeloablative therapy with thiotepa and five fractions of total body radiation prior to the transplant. About four weeks after transplantation, the patient developed biopsy-proven graft-versus-host disease of the skin and GI tract. A blood sample was drawn at that time for cytogenetic analysis. Among 34 analyzed cells, 22 were normal male donor cells. The remaining 12 cells did not have the t(9;22), but had numerous structural abnormalities. While many cells were missing an X chromosome, other abnormalities, including deletions, rearrangements, dicentrics, acentric fragments, rings and marker chromosomes were non-clonal. No clinical evidence of progression from CML chronic phase was found, suggesting that the non-clonal abnor-malities were therapy related.     

Magnetic resonance (MR) evaluation of bone marrow in vertebral bodies.

Magnetic Resonance (MR) imaging was used to examine the hematopoietic bone marrow in the vertebral bodies of eight healthy subjects, and of 35 cancer patients who had been previously treated with radiation therapy. MR was instrumental in distinguishing viable hematopoietic tissue (red marrow) from adipose tissue (yellow marrow), whose presence reflected the extent of radiation-induced bone marrow injury. Different water content in proliferating hematopoietic tissue and adipose tissue enabled clear distinction of the two components even inside the same vertebral body. Three patterns of bone marrow viability were observed in irradiated patients: 1. Patients undergoing therapy at the time of MR study, and patients who had received low-intermediate dose several years before MR examination showed no alteration as compared with healthy controls (i.e. homogeneous presence of red marrow). 2. Patients who had received low-intermediate dose few years before MR, showed either partial re-colonization of yellow marrow or almost complete ablation of active red marrow with rare areas of re-colonization. 3. Patients who had received high dose, showed complete depletion of red marrow (fatty substitution) independently of the length of time elapsed since radiation therapy. Therefore, bone marrow recovery after radiation therapy was associate with two variables: received dose and length of time allowed for re-colonization by surviving hematopoietic tissue. In conclusion, our results provide evidence that MR can be purposively used to study composition and distribution of normal bone marrow, and to asses the extent of radiation-induced bone marrow injury; to monitor bone marrow recovery (or the lack of it); and in the general follow-up of treated cancer patients.     

Targeting gene-virotherapy for cancer

Gene therapy and viral therapy for cancer have therapeutic effects, but there has been no significant breakthrough in these two forms of therapy. Therefore, a new strategy called “targeting gene-virotherapy”, which combines the advantages of gene therapy and viral therapy, has been formulated. This new therapy has stronger antitumor effects than either gene therapy or viral therapy. A tumor-specific replicative adenovirus vector ZD55 （E1B55KD deleted Adv.） was constructed and various single therapeutic genes were inserted into ZD55 to form ZD55-gene. These are the targeting gene-virotherapy genes. But experiments showed that a single gene was not effective in eliminating the tumor mass, and therefore two genes were separately inserted into ZD55. This strategy is called “targeting dual gene-virotherapy” （with PCT patent）. Better results were obtained with this strategy, and all the xenograft tumor masses were completely eliminated in all mice when two suitable genes producing a synergetic or compensative effect were chosen. Twenty-six papers on these strategies have been published by researchers in our laboratory. Furthermore, an adenoviral vector with two targeting promoters harboring two antitumor genes has been constructed for cancer therapy. Promising results have been obtained with this adenoviral vector and another patent has been applied for. This antitumor strategy can be used to kill tumor cells completely with minimum damage to normal cells.     

Pathophysiology and therapy for haemoglobinopathies. Part II: thalassaemias

Thalassaemias result from mutations of the globin genes that cause reduced or absent haemoglobin production and thus interfere with the critical function of oxygen delivery. They represent the most common single-gene disorders, with 4.83% of the world population carrying globin gene variants. Reduced or absent alpha-globin (alpha-thalassaemia) or beta-globin (beta-thalassaemia) leads to anaemia and multifaceted clinical syndromes. In this second of two reviews on the pathophysiology of haemoglobinopathies, we describe the clinical features, pathophysiology and molecular basis of alpha- and beta-thalassaemias. We then discuss current targeted therapies, including the new oral iron chelators, which, along with chronic transfusions, constitute the mainstay of symptomatic therapy for the majority of patients. Finally, we describe potentially curative therapies, such as bone marrow transplant, and discuss some of the outstanding research studies and questions, including the upcoming field of gene therapy for beta-thalassaemia. An accompanying article on haemoglobinopathies (Part I) focuses on sickle cell disease.     

CRISPR/Cas9-mediated gene editing. A promising strategy in hematological disorders

The clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9 system has revolutionized the gene editing field, making it possible to interrupt, insert or replace a sequence of interest with high precision in the human genome. Its easy design and wide applicability open up a variety of therapeutic alternatives for the treatment of genetic diseases. Indeed, very promising approaches for the correction of hematological disorders have been developed in the recent years, based on the self-renewal and multipotent differentiation properties of hematopoietic stem and progenitor cells, which make this cell subset the ideal target for gene therapy purposes. This technology has been applied in different congenital blood disorders, such as primary immunodeficiencies, X-linked severe combined immunodeficiency, X-linked chronic granulomatous disease or Wiskott–Aldrich syndrome, and inherited bone marrow failure syndromes, such as Fanconi anemia, congenital amegakaryocytic thrombocytopenia or severe congenital neutropenia. Furthermore, CRISPR/Cas9-based gene editing has been implemented successfully as a novel therapy for cancer immunotherapy, by the development of promising strategies such as the use of oncolytic viruses or adoptive cellular therapy to the chimeric antigen receptor–T-cell therapy. Therefore, considering the variety of genes and mutations affected, we can take advantage of the different DNA repair mechanisms by CRISPR/Cas9 in different manners, from homology-directed repair to non-homologous-end-joining to the latest emerging technologies such as base and prime editing. Although the delivery systems into hematopoietic stem and progenitor cells are still the bottleneck of this technology, some of the advances in genome editing shown in this review have already reached a clinical stage and show very promising preliminary results.     

Transfer and expression of the human multiple drug resistance gene as potential human gene therapy

The human multiple drug resistance (MDR) gene has been used as a model for human gene transfer which could lead to human gene therapy. MDR is a transmembrane protein which pumps a number of toxic substances out of cells including several drugs used in cancer chemotherapy. Normal bone marrow cells express low levels of MDR and are particularly sensitive to the toxic effects of these drugs. There are two general applications of MDR gene therapy: (1) to provide drug-resistance to the marrow of cancer patients receiving chemotherapy, and (2) as a selectable marker which when co-transferred with a non-selectable gene such as the human beta globin gene can be used to enrich the marrow for cells containing both genes. We demonstrate efficient transfer and expression of the human MDR gene in a retroviral vector into live mice and human marrow cells including CD34⁺ cells isolated from marrow and containing the bulk of human hematopoietic progenitors. MDR gene transduction corrects the sensitivity of CD34⁺ cells to taxol, an MDR drug substrate, and enriches the marrow for MDR-transduced cells. The MDR gene-containing retroviral supernatant used has been shown to be safe and free of replication-competent retrovirus. Because of the safety of the MDR retroviral supernatant, and efficient gene transfer into mouse and human marrow cells, a phase 1 clinical protocol for MDR gene transfer into cancer patients has been approved to evaluate MDR gene transfer and expression in human marrow.