Insights into the biology of cord blood stem/progenitor cells

OBJECTIVES: To review information on cord blood banking and transplantation with respect to the author's studies, and in context of this field of investigation. RESULTS: Cord blood transplantation has been successfully used to treat a number of malignant and non-malignant disorders. However, this technique is still associated with limited numbers of cells for transplantation, and with delayed engraftment of neutrophils and platelets. The field of cord blood transplantation will benefit from enhanced and mechanistically based information on haematopoietic stem cell function and potential means to enhance its effectiveness are reviewed. This includes notions concerning possibility of retrieving more cells from the placenta and cord blood, to expand haematopoietic stem cells ex vivo and to increase efficiency of homing and engraftment of these cells. Also discussed are cryopreservation and long-term storage of cord blood haematopoietic and progenitor cells, and new laboratory findings and animal studies for non-haematopoietic uses of cord blood.     

脐血干细胞向不同体细胞分化的研究进展

脐血干细胞是一种具有多分化潜能的原始细胞,具备自我更新和增殖的能力,并能在特定因素的影响或诱导下,向多种细胞或组织分化。脐血来源的间充质干细胞不但可以分化为骨、脂肪和软骨,还可以转变成带有神经、肝脏及骨骼肌特异标记的细胞,并且具有应用到组织损伤修复、基因治疗载体和造血干细胞共移植等方面的潜力。旨在对于脐血干细胞在一定条件下分化为多种细胞研究进展进行综述。     

Molecular and cellular mechanisms underlying the role of blood vessels in spinal cord injury and repair

Spinal cord injury causes immediate damage of nervous tissue accompanied by the loss of motor and sensory function. The limited self-repair ability of damaged nervous tissue underlies the need for reparative interventions to restore function after spinal cord injury. Blood vessels play a crucial role in spinal cord injury and repair. Injury-induced loss of local blood vessels and a compromised blood-brain barrier contribute to inflammation and ischemia and thus to the overall damage to the nervous tissue of the spinal cord. Lack of vasculature and leaking blood vessels impede endogenous tissue repair and limit prospective repair approaches. A reduction of blood vessel loss and the restoration of blood vessels so that they no longer leak might support recovery from spinal cord injury. The promotion of new blood vessel formation (i.e., angio- and vasculogenesis) might aid repair but also incorporates the danger of exacerbating tissue loss and thus functional impairment. The delicate interplay between cells and molecules that govern blood vessel repair and formation determines the extent of damage and the success of reparative interventions. This review deals with the cellular and molecular mechanisms underlying the role of blood vessels in spinal cord injury and repair.     

Transplantation and its biology: from fantasy to routine.

The replacement of diseased organs and tissues by the healthy ones of others has been a unique milestone in modern medicine. For centuries, transplantation remained a theme of fantasy in literature and the arts. Within the past five decades, however, it has developed from a few isolated attempts to salvage occasional individuals with end-stage organ failure to a routine treatment for many patients. In parallel with the progressive improvements in clinical results has come an explosion in immunology, transplantation biology, immunogenetics, cell and molecular biology, pharmacology, and other relevant biosciences, with knowledge burgeoning at a rate not dreamed of by the original pioneers. Indeed, there have been few other instances in modern medicine in which so many scientific disciplines have contributed in concert toward understanding and treating such a complex clinical problem as the failure of vital organs. The field has been a dramatic example of evolution from an imagined process to an accepted form of therapy.     

小鼠脐血移植模型研究进展

脐血中含有丰富的原始造血干细胞,由于免疫细胞发育不成熟,抗原表达和功能活性低下,移植物抗宿主疾病发生率低。脐血来源丰富、不易受病毒及残留肿瘤细胞的污染,越来越多地作为造血干细胞的优质来源在临床上广泛应用。通过建立小鼠脐血移植模型,对临床多种疾病尤其是对恶性血液病的造血干细胞移植研究提供有效途径,可以对脐血的生物学功能、植入过程、移植疗效做进一步研究,不断优化的小鼠移植模型对我们解读人类疾病的发病机理、疾病进程起到推动作用,本文将从小鼠种属的选择、移植模型的构建及脐血移植模型新进展等方面对进行综述。     

What is the future for cord blood stem cells?

Stem and progenitor cells are present in cord blood at a high frequency making these cells a major target population for experimental and clinical studies. Over the past decade there has been considerable developments in cord blood research and transplantation but despite the rapid progress many problems remain. The initial hope that cord blood would be an alternative source of haemopoietic cells for transplantation has been tempered by the fact that there are insufficient cells in most cord blood collections to engraft an adult of average weight. In attempts to increase the cell number, a plethora of techniques for ex-vivo expansion have been developed.These techniques have also proved useful for gene therapy. As cord blood cells possess unique properties this allows them to be utilised as suitable vehicles for gene therapy and long-term engraftment of transduced cells has been achieved. Current work examining the nature of the stem cells present in this haematological source indicates that cord blood contains not only haemopoietic stem cells but also primitive non-haemopoietic cells with high proliferative and developmental potential. As attention focuses on stem cell biology and the controversies surrounding the potential use of embryonic stem cells in treatment of disease, the properties of stem cells from other sources including cord blood are being re-appraised. The purpose of this article is to review some of the current areas of work and highlight biological problems associated with the use of cord blood cells. This revised version was published online in July 2006 with corrections to the Cover Date.     

Hematopoietic stem cell transplantation for thalassemia

Hematopoietic stem cell transplantation (HSCT) represents the only cure for patients with thalassemia. At present HSCT in younger patients from an HLA- matched sibling donor offers 80% to 87% probability of cure according to risk classes. However, results HSCT in adult patients continue to be inferior due to advanced of disease. High-resolution tissue typing techniques have enabled transplant centres to offer allogeneic HSCT from unrelated donors to patients with thalassemia who could not benefit from matched sibling donor transplantation with results comparable to those obtained using sibling donors. Advances in transplantation biology have made it possible to perform haploidentical HSCT in patients with thalassemia who lack a related or unrelated matched donor. Although limited number of patients, results of unrelated cord blood transplantation for thalassemia are encouraging. Patients with graft failure could now benefit from second transplantation using the same donor with a high disease-free survival rate. Most ex-thalassemics continue to have disease and treatment-related complications acquired before transplantation which require adequate treatment following BMT.     

Advances in umbilical cord blood transplantation

The first successful cord blood transplant was reported in 1989. In the last sixteen years, there has been a substantial increase in the use of cord blood as an alternative stem cell source for patients without matched related or unrelated bone marrow donors. Approximately 5000 cord blood transplants have been performed worldwide. Recently, the results in adult cord blood transplantation appear promising. In this review, the preclinical background, cord blood banking, and ethical issues will be briefly addressed. Outcome data for both pediatric and adult transplantation will be reviewed, with an emphasis on new strategies for adult cord blood transplantation. New indications for cord blood use outside of hematology/oncology will also be explored.     

脐血干细胞与创面修复

脐血干细胞是一类具有多向分化潜能的原始祖细胞,具备自我更新和增殖的能力,在特定条件诱导下可以分化为不同细胞,逐渐作为临床组织工程的来源细胞。近年来随着对脐血干细胞的不断研究,发现其在创面修复中具有明显的优势,成为创面临床治疗的一条新途径。本文从脐血干细胞的生物学特性、采集与冻存、体外扩增等方面对创面修复的研究进行综述。     

脐血干细胞与创面修复

脐血干细胞是一类具有多向分化潜能的原始祖细胞,具备自我更新和增殖的能力,在特定条件诱导下可以分化为不同细胞,逐渐作为临床组织工程的来源细胞。近年来随着对脐血干细胞的不断研究,发现其在创面修复中具有明显的优势,成为创面临床治疗的一条新途径。本文从脐血干细胞的生物学特性、采集与冻存、体外扩增等方面对创面修复的研究进行综述。     

IMGT-Kaleidoscope, the formal IMGT-ONTOLOGY paradigm

IMGT, the international ImMunoGeneTics information system (http://imgt.cines.fr), is the reference in immunogenetics and immunoinformatics. IMGT standardizes and manages the complex immunogenetic data which include the immunoglobulins (IG) or antibodies, the T cell receptors (TR), the major histocompatibility complex (MHC) and the related proteins of the immune system (RPI) which belong to the immunoglobulin superfamily (IgSF) and the MHC superfamily (MhcSF). The accuracy and consistency of IMGT data and the coherence between the different IMGT components (databases, tools and Web resources) are based on IMGT-ONTOLOGY, the first ontology for immunogenetics and immunoinformatics. IMGT-ONTOLOGY manages the immunogenetics knowledge through diverse facets relying on seven axioms, "IDENTIFICATION", "DESCRIPTION", "CLASSIFICATION", "NUMEROTATION", "LOCALIZATION", "ORIENTATION" and "OBTENTION", that postulate that objects, processes and relations have to be identified, described, classified, numerotated, localized, orientated, and that the way they are obtained has to be determined. These axioms constitute the Formal IMGT-ONTOLOGY, also designated as IMGT-Kaleidoscope. Through the example of the IG molecular synthesis, the concepts generated from the "IDENTIFICATION", "DESCRIPTION", "CLASSIFICATION" and "NUMEROTATION" axioms are detailed with their main instances and semantic relations. The axioms have been essential for the conceptualization of the molecular immunogenetics knowledge and can be used to generate concepts for multi scale approaches at the molecule, cell, tissue, organ, organism or population level, emphasizing the generalization of the application domain. In that way the Formal IMGT-ONTOLOGY represents a paradigm for the elaboration of ontologies in system biology.     

The lymphatic vasculature in disease

Blood vessels form a closed circulatory system, whereas lymphatic vessels form a one-way conduit for tissue fluid and leukocytes. In most vertebrates, the main function of lymphatic vessels is to collect excess protein-rich fluid that has extravasated from blood vessels and transport it back into the blood circulation. Lymphatic vessels have an important immune surveillance function, as they import various antigens and activated antigen-presenting cells into the lymph nodes and export immune effector cells and humoral response factors into the blood circulation. Defects in lymphatic function can lead to lymph accumulation in tissues, dampened immune responses, connective tissue and fat accumulation, and tissue swelling known as lymphedema. This review highlights the most recent developments in lymphatic biology and how the lymphatic system contributes to the pathogenesis of various diseases involving immune and inflammatory responses and its role in disseminating tumor cells.     

Downregulation of beta2-microglobulin in human cord blood somatic stem cells after transplantation into livers of SCID-mice: an escape mechanism of stem cells?

Adherently growing, non-hematopoietic somatic stem cells isolated from human cord blood were stained with the fluorescent dye PKH26 and transplanted into livers of SCID-mice to examine a possible cell fate transition. Already 7 days after transplantation stem cells were well integrated into the liver tissue. Human albumin that was not expressed by the stem cells before transplantation was detectable in the host's livers after injection of cord blood stem cells. Human alpha1-antitrypsin was detectable in stem cells already before transplantation and remained positive in the mouse liver. The most interesting observation in this study was the downregulation of human beta2-microglobulin (beta2M) in the stem cells after transplantation: beta2M is expressed constitutively in our cord blood stem cells. However, beta2M was no longer detectable by RT-PCR in all tissues where human albumin and alpha1-antitrypsin were expressed after stem cell transplantation. beta2M is known to participate as an integral part of the major histocompatibility complex. Absence of beta2M makes the residual heavy chain inactive as an antigen. Thus, downregulation of beta2M may represent an escape mechanism from killer-T cells and may be a molecular mechanism explaining the recently described "immunological blindness" [37] of stem cells. In contrast to the results obtained after direct injection of stem cells as a suspension, no consistent downregulation of beta2M was observed after transplantation of stem cells encapsulated in alginate beads to generate a compartment where stem cells are protected from the host's natural killer cells. No expression of human genes was observed after transplantation of human cord blood derived mononuclear cells (MNC) that were used as a negative control. In conclusion, we have shown that human cord blood somatic stem cells survive and are reprogrammed after transplantation into mouse livers, although a complete transdifferentiation to hepatocytes did not occur within 7 days, since some marker genes (GATA4 and alpha-fetoprotein) were still negative. Switching off expression of beta2M may be part of an intriguing and novel mechanism explaining why stem cells escape the host's immune system.     

Neural stem cells in aging and disease

Aging in the central nervous system is associated with progressive loss of function which is exacerbated by neurodegenerative disorders such as Alzheimer's and Parkinson's diseases. The two primary cell replacement strategies involve transplantation of exogenous tissue, and activation of proliferation of endogenous cells. Transplanted tissue is used to either directly replace lost tissue, or to implant genetically engineered cells that secrete factors which promote survival and/or proliferation. However, successful application of any cell replacement therapy requires knowledge of the complex relationships between neural stem cells and the more restricted neural and glial progenitor cells. This review focuses on recent advances in the field of stem cell biology of the central nervous system, with an emphasis on cellular and molecular approaches to replacing cells lost in neurodegenerative disorders.     

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.     

HLA techniques: typing and antibody detection in the laboratory of immunogenetics

The HLA loci are a part of the genetic region known as the major histocompatibility complex (MHC). In the last twenty years there has been an exponential growth in the application of DNA technology to the field of histocompatibility and immunogenetics. Histocompatibility between the patient and donor is a prerequisite for the success of haematopoietic stem cell transplantation. In haematopoietic stem cell transplantation allele-level typing needs to evaluate compatibility for the HLA-A,B,C Class I and DRB1 and DQB1 Class II loci in the average transplant program because it is well established that mismatches at certain HLA loci between donor-recipients are closely linked to the risk of graft versus host disease. Resolution at an antigen level in solid organ transplantation is currently sufficient for HLA-A,B and DR antigens and it could be achieved by serological or molecular biology techniques. In solid organ transplantation the definition of antibodies in the recipient to HLA antigens is more important and it was performed primarily by serological technique and more recently by solid phase immunoassays that are more sensitive and specific.     

Neural stem cells for spinal cord repair

Spinal cord injury (SCI) causes the irreversible loss of spinal cord parenchyma including astroglia, oligodendroglia and neurons. In particular, severe injuries can lead to an almost complete neural cell loss at the lesion site and structural and functional recovery might only be accomplished by appropriate cell and tissue replacement. Stem cells have the capacity to differentiate into all relevant neural cell types necessary to replace degenerated spinal cord tissue and can now be obtained from virtually any stage of development. Within the last two decades, many in vivo studies in small animal models of SCI have demonstrated that stem cell transplantation can promote morphological and, in some cases, functional recovery via various mechanisms including remyelination, axon growth and regeneration, or neuronal replacement. However, only two well-documented neural-stem-cell-based transplantation strategies have moved to phase I clinical trials to date. This review aims to provide an overview about the current status of preclinical and clinical neural stem cell transplantation and discusses future perspectives in the field.     

Mesenchymal stem cells: biology and clinical potential in type 1 diabetes therapy

Mesenchymal stem cells (MSCs) can be derived from adult bone marrow, fat and several foetal tissues. In vitro , MSCs have the capacity to differentiate into multiple mesodermal and non-mesodermal cell lineages. Besides, MSCs possess immunosuppressive effects by modulating the immune function of the major cell populations involved in alloantigen recognition and elimination. The intriguing biology of MSCs makes them strong candidates for cell-based therapy against various human diseases. Type 1 diabetes is caused by a cell-mediated autoimmune destruction of pancreatic β-cells. While insulin replacement remains the cornerstone treatment for type 1 diabetes, the transplantation of pancreatic islets of Langerhans provides a cure for this disorder. And yet, islet transplantation is limited by the lack of donor pancreas. Generation of insulin-producing cells (IPCs) from MSCs represents an attractive alternative. On the one hand, MSCs from pancreas, bone marrow, adipose tissue, umbilical cord blood and cord tissue have the potential to differentiate into IPCs by genetic modification and/or defined culture conditions In vitro . On the other hand, MSCs are able to serve as a cellular vehicle for the expression of human insulin gene. Moreover, protein transduction technology could offer a novel approach for generating IPCs from stem cells including MSCs. In this review, we first summarize the current knowledge on the biological characterization of MSCs. Next, we consider MSCs as surrogate β-cell source for islet transplantation, and present some basic requirements for these replacement cells. Finally, MSCs-mediated therapeutic neovascularization in type 1 diabetes is discussed.     

Delivering cellular therapies: lessons learned from ex vivo culture and clinical applications of hematopoietic cells

Advances in stem cell biology and cellular therapy have led to promising treatments in a range of incurable diseases. However, it is unclear whether primitive stem cells can be delivered to damage tissue for regeneration of functional mature cells or stem cells must be stimulated to differentiate into mature cells in vitro and these cells delivered to patients. A range of other questions remains to be determined including how to formulate cellular products for in vivo delivery and how to undertake pharmacological testing of cellular products. Insights into these questions can be obtained from hematopoietic stem cells (HSC) which have been used for the past 50 years in bone marrow transplantation for regeneration of blood cells in patients undergoing high dose chemotherapy to treat cancer. The differentiation of HSC into mature blood cells is controlled by proteins called hematopoietic growth factors and these factors have been used to generate cellular products in vitro for clinical applications. This chapter will review some of the results of cellular therapies performed with HSC and the lessons that can be learned from these studies.     

Transplantation of adult spinal cord grafts into spinal cord transected rats improves their locomotor function

Grafted embryonic central neural tissue pieces can recover function of hemisected spinal cord in neonatal rats and promote axonal growth in adults. However, spinal cord segments from adults have not been used as donor segments for allogeneic transplantation. Here, we utilized adult spinal cord tissue grafts(aSCGs) as donor constructs for repairing complete spinal cord injury(SCI). Moreover, to provide a favourable microenvironment for SCI treatment, a growth factor cocktail containing three growth factors(brain-derived neurotrophic factor, neurotrophin-3 and vascular endothelial growth factor), was applied to the aSCG transplants. We found that the locomotor function was significantly improved 12 weeks after transplantation of aSCGs into the spinal cord lesion site in adult rats. Transplantation of aSCGs combined with these growth factors enhanced neuron and oligodendrocyte survival and functional restoration. These encouraging results indicate that treatment of complete SCI by transplanting aSCGs, especially in the presence of growth factors, has a positive effect on motor functional recovery, and therefore could be considered as a possible therapeutic strategy for SCI.