Showing papers in "Stem Cells in 1997"

Regulation and Significance of Apoptosis in the Stem Cells of the Gastrointestinal Epithelium

Abstract: In rapidly proliferating tissues the stringent control of cell proliferation and cell death by apoptosis is central to the maintenance of tissue homeostasis. In the gastrointestinal tract most work studying the control of tissue cell number has traditionally focused on the growth factor control of proliferation, and the changes that occur during carcinogenesis. However, in recent years it has become increasingly apparent that the control of apoptosis is also crucial. Apoptosis is an important mechanism for eliminating both excess normal cells and those cells which have sustained damage; therefore maintaining a tissue, i.e., stem cells with preserved DNA integrity. In this review the incidence of apoptosis in the stem cells of both the small and large intestine will be discussed in relation to the expression of a number of apoptosis regulating genes (e.g. p53, Bcl-2, bax) within these cells. The importance of apoptosis as a means of controlling stem cell number (and therefore cellular output) will be addressed, as will the mechanisms by which any alterations to this process may contribute to malignancy.

The Regulation of Neovascularization by Matrix Metalloproteinases and Their Inhibitors

Abstract: The process of new capillary formation from preexisting vessels, angiogenesis, is a complex physiological event which is strictly controlled, occurring only very rarely under normal conditions. In contrast, there are a number of serious diseases, among them solid tumor growth, rheumatoid arthritis and several eye diseases, which are characterized by unrestricted new capillary growth and which are described as "angiogenic diseases." One of the key events required for successful angiogenesis is extracellular proteolysis. Increased attention has been focused on matrix metalloproteinase (MMP) family of enzymes whose activity is a rate-limiting step in extracellular matrix remodeling. This review will present the accumulating body of evidence, from a number of laboratories, which documents the important role of MMP activity in the regulation of angiogenesis. Taken together, these data suggest that one strategy for controlling the deregulated angiogenesis characteristic of these serious angiogenic diseases may be one which is operative at the level of the control of MMP activity.

TGF‐β Latency: Biological Significance and Mechanisms of Activation

Abstract: Transforming growth factor (TGF-) beta is secreted as a latent complex in which the mature growth factor remains associated with its propeptide. In order to elicit a biological response, the cytokine must be released from the latent complex, a process termed latent TGF-beta activation or TGF-beta formation. Although latent TGF-beta activation is a critical step in the regulation of its activity, little is known about the molecular mechanisms that lead to the production of active TGF-beta. In this article, we present an overview of the data available on this topic, and we propose a tentative model for the mechanism of TGF-beta formation based upon the observations with different cell systems and on recent findings on the structure of the latent TGF-beta complex.

HER-2/neu signal transduction in human breast and ovarian cancer.

Abstract: The HER-2/neu proto-oncogene encodes a 185 kDa transmembrane receptor tyrosine kinase with significant sequence homology to other members of the class I receptor tyrosine kinase family. The HER-2/neu gene is amplified and/or overexpressed in 25%-30% of human breast and ovarian cancers, and overexpression of the receptor is associated with poor prognosis. Tyrosine phosphorylation and activation of the HER-2 receptor lead to activation of specific signal transduction pathways in breast and ovarian cancer cells, including the ras/MAP kinase cascade, phosphatidylinositol 3-kinase, and phospholipase C-gamma. HER-2/neu signal transduction pathways ultimately converge on the cell nucleus, where the expression of diverse genes is induced after activation of the receptor. A more complete understanding of HER-2/neu signal transduction pathways may allow the development of specific therapeutics for the treatment of those human breast and ovarian cancers containing this alteration.

Dendritic cell development: multiple pathways to nature's adjuvants.

Abstract: Dendritic cells are a system of bone marrow-derived antigen-presenting cells specialized for interaction with T lymphocytes and essential for initiating primary T cell immune responses. Recent investigation indicates that dendritic cells are of diverse origin, with at least two types of myeloid precursors and a lymphoid precursor implicated in their generation. Mature dendritic cell subtypes, while sharing the capacity to activate T cells, show additional functional specialization. Some dendritic cells are equipped with additional mechanisms to regulate the response of the T cells they activate, while others are able to interact with B cells and modify B cell responses.

Contrasting Effects of TGF‐β1 and TNF‐α on the Development of Dendritic Cells from Progenitors in Mouse Bone Marrow

Abstract: Dendritic cells (DC) are a distinct population of leukocytes and specialized antigen-presenting cells for T cell responses. Prior work has shown that GM-CSF can induce the development of large numbers of DC from proliferating progenitors in mouse bone marrow. We have monitored the effects of potentially enhancing and suppressive cytokines in these cultures. In this system, many immature DC develop from proliferating precursors during the first six days of culture, and between days 6-8 maturation of typical nonadherent and nonreplicating DC takes place. The maturation is accompanied by a large increase in the expression of major histocompatibilities complex class II (MHC II) and B7-2/CD86, and in mixed leukocyte reaction stimulating activity. Tumor necrosis factor-alpha (TNF-alpha), previously shown to be required for development of human DC, was found to enhance the maturation of mouse DC in the last two days of culture. Transforming growth factor-beta 1 (TGF-beta 1), on the other hand, almost totally blocked DC maturation, but it had to be given in the first six days of culture when the DC were actively proliferating. TGF-beta 1 did not block the production of immature, MHC II-positive but B7-2/CD86-negative DC. Maturation would take place between days 6-8 as long as the cultures were depleted of Fc-receptor-bearing cells, or if TNF-alpha were added. In both instances, maturation was not blocked even when TGF-beta 1 remained in the culture. We conclude that the development of DC, in response to GM-CSF, can be modified by other cytokines. TGF-beta 1 is suppressive but only indirectly via Fc-receptor-bearing suppressive cells, presumably suppressive macrophages, while TNF-alpha enhances the final maturation of DC.

Assay of human stem cells by repopulation of NOD/SCID mice.

Abstract: The only conclusive method to assay stem cells is to follow their ability to repopulate conditioned recipients, making it difficult to study human stem cells. The development of systems to transplant human hematopoietic cells into immune-deficient mice lays the foundation for such an experimental repopulation assay for primitive human cells. Cell purification and gene marking studies have shown that the repopulating cells, termed severe-combined immunodeficiency (SCID) mouse-repopulating cells (SRC), are primitive and distinct from most of the progenitors that are detected using short and long-term in vitro culture assays. The SRC are exclusively CD34+CD38- and poorly infected with retrovirus vectors. These gene marking data are reminiscent of the human clinical trials establishing that the SRC assay is a good surrogate to develop improved transduction methods. Limiting dilution analysis has been used to establish a quantitative assay for SRC that can be used to precisely determine the effect of various cytokine cocktails on the proliferation and differentiation of SRC during in vitro culture.

Structure, Function and Expression on Blood and Bone Marrow Cells of the Urokinase‐Type Plasminogen Activator Receptor, uPAR

Abstract: Several important functions have been assigned to the receptor for urokinase-type plasminogen activator, uPAR. As implied by the name, uPAR was first identified as a high affinity cellular receptor for urokinase plasminogen activator (uPA). It mediates the binding of the zymogen, pro-uPA, to the plasma membrane where trace amounts of plasmin will initiate a series of events referred to as “reciprocal zymogen activation” where plasmin converts pro-uPA to the active enzyme, uPA, which in turn converts plasma membrane-associated plasminogen to plasmin. This is an efficient machinery to generate broad-spectrum proteolytic activity which is spatially restricted to the plasma membrane, since plasmin that diffuses away from the plasma membrane is rapidly inactivated by circulating inhibitors (i.e., α2-antiplasmin). The system is controlled by a series of plasminogen activator inhibitors (PAIs), most importantly PAI-1 and PAI-2, providing means of temporally restricting the process of plasminogen activation. In addition to its role in plasminogen activation, compelling evidence has demonstrated a role for uPAR in cell-cell and cell-extracellular matrix adhesion, both directly and indirectly. uPAR is directly involved in binding to the extracellular matrix molecule, vitronectin, and the affinity of this binding is increased when uPAR is occupied by (pro-)uPA. A more indirect but presumably very important role of uPAR in cell adhesion seems to be mediated through interactions between uPAR and β1- or β2-integrins. It has been demonstrated that uPAR may bind physically to integrins in a reversible manner. The interaction seems to be of functional importance since the affinity of the integrin for its corresponding ligand is modulated by the association of integrin with uPAR. In some experimental setups uPAR has been shown to reduce the affinity of the associated integrin for certain ligands, while other experimental systems have demonstrated an increased affinity of the interaction between integrin and ligand after binding of uPAR to the integrin. Finally, uPAR has also been shown to participate in signal transduction events. Since uPAR is not a transmembrane molecule but belongs to the group of proteins that are tethered to the plasma membrane via a glycosyl-phosphatidylinositol anchor, association with a transmembrane adaptor is required for transmission of signals via uPAR. Integrins may serve as such signal transducers, and indeed uPAR has been shown to be associated in the plasma membrane with complexes of integrins and (phosphorylated) tyrosin kinases suggesting a role for these complexes in transmembrane transmission of signals via uPAR. In the hematopoietic system it has been shown that urokinase-type plasminogen activator (uPAR) is expressed as a differentiation antigen on cells of the myelomonocytic lineage and as an activation antigen on monocytes and T lymphocytes. Neutrophils contain intracellular reservoirs of uPAR that are translocated to the plasma membrane upon activation, and neutrophils from patients with the rare blood disease paroxysmal nocturnal hemoglobinuria (PNH) that fail to express glycosyl-phosphatidylinositol-anchored proteins including uPAR, show a very significantly reduced transmigration over an endothelial barrier. Cell-associated plasminogen activation by PNH-affected neutrophils is severely impaired, and it has been proposed that this may be causally related to the propensity for thrombosis in PNH. The pattern of expression of uPAR in hematological malignancies mirrors the expression by normal blood and bone marrow counterparts with some exceptions (differentiated myeloid leukemias are positive, undifferentiated myeloid may be negative and the majority of lymphoid leukemias and lymphomas are negative). The potential clinical relevance of uPAR expression in leukemias and lymphomas has not been determined.

1 – Stem cells and cellular pedigrees – a conceptual introduction

Abstract: This chapter focuses on some of the problems involved in current discussions on stem cells in adult mammalian tissues. The present concepts involve a number of pitfalls, logical, semantic, and classification problems. This indicates the necessity for new and well-defined concepts that are amenable to experimental analysis. One of the major difficulties in considering stem cells is that they are defined in terms of their functional capabilities which can only be assessed by testing the abilities of the cells, which itself may alter their characteristics during the assay procedure; a situation similar to the uncertainty principle in physics. Hence, a proper description requires the measurement, i.e., manipulation process itself to be taken into account. This chapter serves as a framework for the stem-cell models. Starting with some general definitions, this chapter sets up criteria that should be fulfilled for stem cells. The chapter points out the conceptual distinction between stem cells and transit cells before discussing the problem of obtaining measurements on stem cells. The basic elements of models used to describe cellular hierarchies and stem cells were also discussed.

Bone Marrow-Derived Dendritic Cells Serve as Potent Adjuvants for Peptide-Based Antitumor Vaccines

Abstract: Dendritic cells (DCs) are considered the most effective antigen-presenting cells (APCs) for primary immune responses. Since presentation of antigens to the immune system by appropriate professional APCs is critical to elicit a strong immune reaction and DCs seem to be quantitatively and functionally defective in the tumor host, DCs hold great promise to improve cancer vaccines. Even though they are found in lymphoid organs, skin and mucosa, the difficulty of generating large numbers of DCs has been a major limitation for their use in vaccine studies. A simple method for obtaining DCs from mouse bone marrow cells cultured in the presence of GM-CSF + interleukin 4 is now available. In four different tumor models, mice injected with DCs grown in GM-CSF plus interleukin 4 and prepulsed with a cytotoxic T lymphocyte-recognized tumor peptide epitope developed a specific cytotoxic T lymphocyte response and were protected against a subsequent tumor challenge with tumor cells expressing the relevant tumor antigen. Moreover, treatment of day 5-14 tumors with peptide-pulsed DCs resulted in sustained tumor regression in five different tumor models. These results suggest that presentation of tumor antigens to the immune system by professional APCs is a promising method to circumvent tumor-mediated immunosuppression and is the basis for ongoing clinical trials of cancer immunotherapy with tumor peptide-pulsed DCs.

Jaks and stats in cytokine signaling

Abstract: Hematopoiesis is regulated through the binding of cytokines to receptors of the cytokine receptor superfamily. Although lacking catalytic domains, members of the cytokine receptor superfamily mediate ligand-dependent activation of protein tyrosine phosphorylation through their association and activation of members of the Janus kinase (Jak) family of protein tyrosine kinases. The activated Jaks phosphorylate the receptors which creates docking sites for SH2-containing signaling proteins which are tyrosine phosphorylated following their association with the complex. Among the substrates of tyrosine phosphorylation are members of the signal transducers and activators of the transcription family of proteins (Stats). Various cytokines induce the tyrosine phosphorylation and activation of one or more of the seven family members. The pattern of Stat activation provides a level of cytokine individuality that is not observed in the activation of other signaling pathways. The role of various Stats in the biological responses to cytokines has been assessed through the analysis of receptor mutations which disrupt Stat activation and more recently by disruption of the genes in mice. Our results have demonstrated that the activation of Stat5a and Stat5b by erythropoietin is critical for the activation of a number of immediate early genes but is not required for a mitogenic response. Mice in which the genes for Stat4 and Stat6 are disrupted are viable but lack functions that are mediated by interleukin 12 (IL-12) or IL-4, respectively, suggesting that these Stats perform very specific functions in immune responses. Stem Cells 1997; 15(suppl 1): 105–112

Osteoblast precursor cells are found in CD34+ cells from human bone marrow.

Abstract: It is known that osteoblast precursor cells are found in the low-density mononuclear (LDMN) fraction of human bone marrow (BM) aspirates. The purpose of this study was to investigate whether CD34, a hematopoietic progenitor cell marker, is present on osteoblast progenitor cells. LDMN, CD34+, and CD34− cells were cultured under conditions that promote growth and differentiation of mineral-secreting osteoblasts in a limiting dilution manner. With LDMN cells, osteoblast progenitor cells were found at an average frequency of 1/36,000 cells. With CD34− cells, osteoblast progenitor frequency remained at an average of 1/33,000, similar to LDMN cells. With CD34+ selected cells, osteoblast progenitor frequency increased to an average of 1/5,000. This osteoblast progenitor frequency is maintained in sorted CD34+/CD38+ cells. The osteoblasts generated from CD34+ cells were morphologically normal, and expression of skeletal-specific alkaline phosphatase and osteonectin increased upon differentiation induced by dexamethasone (DEX) treatment. Ultrastructurally, these CD34+ cell-derived osteoblasts displayed osteoblast-specific features. Functionally, these CD34+ cell-derived osteoblasts differentiated with DEX treatment, increased the level of cyclic adenosine monophosphate in response to parathyroid hormone stimulation, increased the level of alkaline phosphatase activity, and increased mineral secretion. These results demonstrate that osteoblast progenitor cells are enriched in the CD34+ cell population from BM and that these progenitor cells can differentiate into functional osteoblasts in culture.

Microenvironmental regulation of hematopoietic stem cells.

Abstract: A major challenge in hematopoietic biology is the description and understanding of the molecular mechanisms responsible for the regulation of the primitive stem cell compartment. In one sense there exists a wealth of functional and physical properties which provide insight into the biology of the stem cell and its clonal progeny. However, much of this information is descriptive and available only as a function of complex in vivo assays. In order to move beyond these limitations, in vitro systems which accurately recapitulate the self-renewal, differentiation and proliferative behaviors of stem cells are required. We have approached this issue by focusing on the in vivo stem cell microenvironment. Dissection of this microenvironment into discrete cellular entities has yielded a cell line with in vitro stem cell supportive properties consistent with those which might be expected in a stem cell niche. Studies are summarized which suggest that a single stromal cell line provides a milieu which facilitates the in vitro maintenance of transplantable stem cells as well as the generation of large populations of committed progenitors. It is anticipated that this system will allow a direct analysis of stem cell regulatory pathways.

Mechanisms of the Graft-versus-Leukemia Reaction

Abstract: It is now clear that the graft-versus-leukemia (GVL) effect which accompanies allogeneic bone marrow transplantation for hematological malignancies is a powerful therapeutic weapon which, if harnessed, could improve our ability to treat refractory malignant disorders. Advances in the understanding of the alloimmune response now provide a clearer picture of the mechanisms involved in the GVL reaction: the CD4+ T cell plays a central role in the orchestration of leukemia cell killing. The immunogenicity of the leukemia is also a major factor determining the effectiveness of the GVL response. The characterization of antigens restricted to leukemia and hematopoietic tissues should make it eventually possible to produce specific and powerful antileukemic alloresponses in donor lymphocytes by adoptive immunotherapy or by vaccines.

8 – Liver stem cells*

Abstract: This chapter reviews evidence for the presence of epithelial stem cells or stem-like cells in the liver, and the roles that these cells may play in the development, growth, and repair of the liver. The population dynamics of the major types of liver epithelial cells—hepatocytes and bile duct epithelial cells—differ drastically from the population dynamics of the classic stem-cell-fed lineages. Both hepatocytes and bile duct epithelial cells are long-lived, with very little turnover in the absence of cell loss induced by the toxic damage or surgical resection. Even after induced loss of cells, replacement of hepatocytes and bile duct epithelial cells occurs by proliferation of residual differentiated cells under most circumstances, without involving the activation of stem cells. Most of the data reviewed in this chapter result from experimental studies in rodents, since spatial constraints prevent a comprehensive review of data from other species, including humans. This chapter briefly summarizes the parenchymal structure of the adult liver and the population dynamics and cell kinetics of the hepatocyte and bile duct epithelial cell populations during embryogenesis and postnatal growth of this organ. It also discusses about the founding of hepatocytes and bile duct epithelial cells from hepatoblasts, postnatal liver growth, and evidences for liver stem cells.

Transplantation of Hematopoietic Stem Cells in Utero

Abstract: Hematopoietic stem cell (HSC) transplantation in children and adults with congenital lymphohematopoietic disorders is limited by donor availability, graft failure, graft-versus-host disease (GVHD) and delayed immunological reconstitution. These problems may be circumvented by transplanting the patient before birth. Prenatal cellular therapy for the treatment of congenital diseases has tremendous theoretical appeal. Potential advantages of prenatal transplantation include: A) fetal immunologic immaturity and the potential for induction of donor-specific tolerance; B) available space in the developing bone marrow for engraftment of donor cells; C) the sterile, protective, fetal environment which provides isolation from environmental pathogens, and D) prevention of clinical manifestations of the disease. Normal hematopoietic and immunologic development during ontogeny creates a "window of opportunity" during which events favor the engraftment of transplanted allogeneic (and xenogeneic) HSC and their proliferation. This is a period in which the fetus is immunologically naive and thus incapable of rejecting the foreign HSC, and the expanding bone marrow spaces allow homing and engraftment of HSC without the need for myeloablation. Experiments in sheep have established the optimal age of the recipient, route of donor cell administration, sources of HSC, and other parameters necessary for the successful engraftment and long-term expression of donor HSC. In preclinical studies, transplantation of CD34-enriched or highly purified populations of human adult bone marrow cells in utero resulted in the long-term engraftment and expression of donor HSC without graft failure and GVHD. The strategies developed in allogeneic and xenogeneic fetal sheep models were used to successfully treat human fetuses with X-linked recessive severe combined immunodeficiency.

Signaling mechanisms in growth factor-stimulated cell motility.

Abstract: Most mammalian cells have the capacity to migrate. When placed into culture, cells will generally display a set rate of basal, unstimulated locomotion. The cells will begin to move in one direction and, after some time, change directions resulting in a random walk. External stimuli can influence cell motility in several ways to either enhance or retard the rate of migration (chemokinesis), to change the average amount of cell migration observed before the cell turns (persistence), or to increase the directionality of movement by limiting the number of turns made by the cells. Several factors have been identified that stimulate cell movement, but the signaling mechanisms that mediate this induced cell movement have only recently begun to be studied. In this review, we discuss the signals that support the directional movement of fibroblasts and epithelial cells in response to chemoattractant gradients. The work will emphasize studies carried out by our laboratory and others on the stimulation of cell motility by the PDGF. These results indicate that at least two sets of signaling molecules cooperate to regulate cell motility in vivo. These include phospholipase C-gamma, phosphoinositide-3' kinase and the Ras-GTPase activating protein Ras-GAP. The first set are those which bind to the intracellular domain of the receptor tyrosine kinase and bring about the phosphorylation and/or activation of intracellular effectors proximal to the receptor. The second is a set of down-stream effectors that regulate either the rate of cell movement or the directionality of that movement depending on the cell type. These include Ras and the Ras-related GTPase Rac along with free phosphoinositides and calcium ions that regulate the actin polymerization machinery. Signals that mediate nuclear changes leading to cell proliferation, such as elements of the MAP kinase pathway, do not appear to play a role in PDGF-stimulated cell migration. Current work thus suggests that a coordinated spatial regulation of signaling elements that interact with the cell membrane and cytoskeleton but not necessarily with nuclear elements is the controlling mediator of directional cell motility.

Serum Ferritin Iron, a New Test, Measures Human Body Iron Stores Unconfounded by Inflammation

Abstract: Serum ferritin protein is an acute phase reactant. We hypothesized that serum ferritin protein generated in response to an inflammatory process would have much less iron (Fe) in it than would “normal” ferritin protein, and therefore measuring serum ferritin iron would assess human body iron status unconfounded by inflammation. Basic Methods. We measured serum ferritin iron in 140 clinical samples obtained from the serum banks of Bronx VA Medical Center Hematology and Nutrition Laboratory (Bronx, NY), the CDC Nutritional Biochemistry serum sample bank (Atlanta, GA), and the sample bank from patients with thalassemia and iron overload treated at New York Hospital (New York, NY). Each was analyzed for three conventional criteria of iron status: serum iron, percentage of transferrin saturation and ferritin protein. In addition, tests for inflammation were also performed: C-reactive protein, WBC and transaminases. Seventy-seven patients' sera from 140 screened met each of three consistent criteria for stages of iron status. Serum ferritin was immobilized by immunoprecipitation with rabbit antihuman polyclonal antibody bound to agarose and separated from other iron-containing proteins, digested with 0.2 ml of 3N nitric acid and analyzed for iron content by atomic absorption spectroscopy. Results. Serum ferritin iron ranged in normal controls from 10 ng to 35 ng Fe/ml. The patients with iron deficiency (4/4) and those in negative iron balance (5/6) had values ≤10 ng. Positive iron balance (8/9) and iron overload (22/22) values were >35 ng/ml, in contrast to 11/19 with inflammation. Seventeen of twenty-two with overload had values >100 ng/ml while only 1/19 with inflammation had such a value. Ferritin iron in ferritin protein was >15% by weight in 14/22 with iron overload but in 0/19 with inflammation. Implications of the Work. Serum ferritin iron is a simple, direct measure of iron stores that we propose, in conjunction with measuring serum ferritin protein, as a minimally invasive screening procedure for accurately assessing the whole range of human body iron status, unconfounded by inflammation.

The Broad Spectrum of Cytokine Gene Expression by Myoid Cells from the Human Marrow Microenvironment

Abstract: Nontransformed stromal colony-derived cell lines (CDCLs) consist of a pure stromal cell population that differentiates following a vascular smooth muscle cell repertoire, and whose in vivo counterpart is that of myoid cells found in adult and fetal human bone marrow cords. We studied the cytokine expression by reverse-transcriptase polymerase chain reaction (RT-PCR) from pooled fast-growing clones from 10 different bone marrow samples. RT-PCR indicated that 30 cytokines (out of 42 studied) were expressed by CDCLs (20 after medium renewal and hydrocortisone renewal, three after addition of interleukin I beta (IL-1 beta) and seven in only part of the CDCL layers examined). The cytokines expressed comprised mediators known to be involved in the maintenance of early and late hematopoiesis (IL-1 alpha and IL-beta, IL-6, IL-7, IL-8, IL-11 and IL-13; colony-stimulating factors, thrombopoietin, erythropoietin, stem cell factor, fit 3-ligand, hepatocyte cell growth factor, tumor necrosis factor alpha, leukemia inhibitory factor, transforming growth factors beta 1 and beta 3; and macrophage inflammatory protein 1 alpha), angiogenic factors (fibroblast growth factors 1 and 2, vascular endothelial growth factor) and mediators whose usual target (and source) is the connective tissue-forming cells (platelet-derived growth factor A, epidermal growth factor, transforming growth factors alpha and beta 2, oncostatin M and insulin-like growth factor 1), or neuronal cells (nerve growth factor). The cytokines not expressed were lymphokines (IL-2, IL-3, IL-4, IL-5, IL-9, IL-10, and IL-12 and interferon gamma) or mediators synthesized by macrophages (inhibin, activin, platelet-derived growth factor B, and IL-1 receptor antagonist). This study complements the description of the phenotype of the myoid cells, confirming that these cells are the marrow connective tissue-forming cells; moreover, this work suggests that stromal control of hematopoiesis is multifactorial and that myoid cells are involved in the control of marrow angiogenesis and innervation.

Functional Differences between Subpopulations of Mobilized Peripheral Blood-Derived CD34+ Cells Expressing Different Levels of HLA-DR, CD33, CD38 and c-kit Antigens

Abstract: We have investigated the functional characteristics of peripheral blood-derived CD34+ cells mobilized by a combination of chemotherapy and G-CSF (mobilized peripheral blood-derived [MPB] CD34+ cells). In this study, subpopulations of MPB CD34+ cells have been directly compared in clonal cultures, long-term cultures with bone marrow (BM) stromal cells, and single-cell cultures. MPB CD34+ cells could be subdivided by expression levels of HLA-DR (DR), CD38, CD33 and c-kit antigens. The majority of MPB CD34+ cells expressed DR and CD38 antigens. In contrast, approximately 60% and 20% of the MPB CD34+ cells expressed CD33 and c-kit antigens, respectively. Interestingly, MPB CD34+ cells can be subdivided into three fractions which express high, low or negative levels of c-kit receptor. All types of committed progenitors were observed in populations of CD34+DR+, CD34+DR-, CD34+CD33-, CD34+CD38+ and CD34+ c-kit(low) cells. Colony forming unit-granulocyte/macrophage was highly enriched in the population of CD34+CD33+ cells, whereas BFU-E was highly enriched in the population of CD34+ c-kit(high) cells. In the population of CD34+CD38- cells, however, a few myeloid progenitors were detected. In addition, limiting dilution analyses clearly showed that the long-term culture-initiating cell (LTC-IC) is enriched in the populations of CD34+DR-, CD34+CD33- and CD34+c-kit-(or low) cells, but very few in CD34+ c-kit(high) cells, and that CD38 antigen is not a useful marker for the enrichment of LTC-IC derived from MPB CD34+ cells. Moreover, single cell clone sorting experiments clearly demonstrated the functional differences between CD34+CD38+ and CD34+CD38- cells as well as CD34+ cells expressing different levels of c-kit receptor. Our results suggest that an immunophenotype of LTC-IC is different between BM-, cord blood- and MPB-derived CD34+ cells and that primitive and committed progenitors existing in these sources may be functionally different.

The Use of Mobilized Peripheral Blood Stem Cells from Normal Donors for Allografting

Abstract: Peripheral blood stem cells (PBSCs) are gaining increasing acceptance as an alternative to bone-marrow (BM)-derived stem cells for allografting. Although scarce under steady-state conditions, CD34+ progenitor cells can be effectively mobilized into the peripheral blood (PB) in the vast majority of normal donors with a brief (3-4 days) course of recombinant human (rHu)G-CSF. Those cytokine-peripheralized progenitor cells and, among them, pluripotent stem cells, are collected by apheresis in sufficient amounts to achieve complete and permanent alloengraftment after myeloablative treatment in patients with primarily malignant hematologic disorders. The short-term tolerability profile of PBSC mobilization and apheresis in normal donors appears to be acceptable, although continued monitoring is necessary to ensure long-term safety. When compared with BM progenitor cells, mobilized PBSCs seem to exhibit a more primitive phenotype and a different clonogenic potential. The impact of factors affecting the efficiency of PBSC mobilization, such as rHuG-CSF dose, duration of cytokine treatment, and, to a lesser extent, donor age is now being recognized. Potential ways to optimize and possibly "engineer" PBSC collection, such as the use of cytokine/chemokine combinations (e.g., thrombopoietin, stem cell factor, etc.) and monoclonal antibodies directed against integrin receptors on CD34+ progenitor cells, are now being explored as well. In the clinical setting, engraftment after PBSC allografting is rapid and probably faster than after BM allografting. PBSC allografting seems to be associated with an incidence and severity of acute graft-versus-host disease (GVHD) comparable to the ones observed after BM allografting, although the incidence of chronic GVHD after allogeneic PBSC transplantation is still controversial. The infusion of a larger number of lymphoid cells appears to translate into a more rapid immunologic recovery and may lead to an enhanced graft-versus-leukemia effect. The collection of large numbers of mobilized PBSCs should provide ample opportunities for graft engineering and gene therapy. PBSCs may eventually replace, at least in part, BM as the preferred source of stem cells for both auto- and allotransplantation.

Long-Term Cytokine Production from Engineered Primary Human Stromal Cells Influences Human Hematopoiesis in an In Vivo Xenograft Model

Abstract: Human hematopoiesis can be supported in beige/nude/ XID (bnx) mice by coinjection of human bone marrow stromal cells engineered to secrete human interleukin 3 (HuIL-3). The major limitation is a total absence of human B cell development in the mice, which could be due to supraphysiological levels of HuIL-3 in the circulation. In an effort to obtain human B lymphoid, as well as T lymphoid and myeloid cell development in the mice, CD34+ cells were coinjected with human marrow stromal cells engineered to secrete human IL-2, IL-7, stem cell factor or FLT3 ligand, +/- IL-3. No single factor other than IL-3 supported sustained human hematopoiesis in the mice, although cytokines were expressed for four to six months post-transplantation. Production of both HuIL-3 and IL-7 in the mice supported extrathymic development of human T lymphocytes, but no B cells, myeloid cells, or clonogenic progenitors were detected. Human B cells were not produced from CD34+ cells in the bnx mice under any condition tested. Another limitation to the bnx/Hu system is a lack of maturation of human red blood cells, although BFU-E are maintained. Stromal cells secreting human erythropoietin and IL-3 were cotransplanted into mice with HuCD34+ cells and an increase in hematocrit from 40%-45% to 80%-85% resulted, with production of human and murine red blood cells. Unfortunately, all mice (n = 9) suffered strokes, displayed paralysis and died within three weeks. The bnx/Hu cotransplantation model provides an interesting system in which to study human hematopoietic cell differentiation under the influence of various cytokines.

Retroviral stem cell gene therapy.

Abstract: Long-term in vivo gene transfer studies in mice have shown that recombinant murine retroviruses are able to infect murine hemopoietic stem cells with high efficiency. Taken together the results indicated that the proviral structure was present at high frequency in circulating hemopoietic cells resulting in significant expression levels. Because of the success of these murine studies, it was believed that gene therapy would soon be applicable to treat a wide variety of congenital or acquired human diseases associated with the hemopoietic system. However, results from gene transfer studies in nonhuman primates and first human clinical trails have indicated that murine retrovirus infection of primate hemopoietic stem cells is inefficient. Although there are essential differences between the murine and primate gene therapy studies with respect to the recombinant viruses and transduction protocols used, these differences cannot solely account for the differences observed in infection efficiency. Therefore, in recent years effort has been spent on the identification of factors limiting retroviral transduction of primate hemopoietic stem cells. Increasing knowledge concerning hemopoiesis and retroviral infection has helped in identifying a number of limiting factors. Novel transduction strategies and tools have been generated which attempt to circumvent these limiting factors. These factors as well as the strategies that showed increased retroviral infection of primate hemopoietic stem cells will be discussed.

Importance of Parenchymal: Stromal Cell Ratio for the Ex Vivo Reconstitution of Human Hematopoiesis

Abstract: Many new developments in tissue engineering rely on the culture of primary tissues which is composed of parenchymal and mesenchymal (stromal) cell populations. Because stroma regulates parenchymal function, the parenchymal:stromal cell (P:S) ratio will likely influence culture behavior. To investigate parenchymal-stromal cell interactions, the P:S ratio was systematically varied in a human bone marrow (BM) culture system, measuring the output of mature cells, immature progenitors (colony forming units-granulocyte/macrophage [CFU-GM]), and primitive stem cells (long-term culture-initiating cells [LTC-IC]). When parenchymal CD34-enriched cells were grown without stroma, cell and CFU-GM output increased linearly as inoculum density was increased, resulting in constant cell and CFU-GM expansion ratios. On irradiated preformed stroma (IPFS), culture output was significantly higher and less dependent on CD34-enriched cell inoculum density, resulting in greater expansion ratios at lower inoculum densities. The number of IPFS cells required to support CD34-enriched cells was independent of the CD34-enriched cell number, suggesting that IPFS did not provide discrete niches, but instead acted through soluble signals. Experiments using conditioned medium (CM) from IPFS confirmed the presence of soluble signals, but CM did not completely substitute for direct contact between CD34-enriched cells and IPFS. Because of known differences between IPFS and stroma growing within BM mononuclear cell (MNC) cultures, experiments were next performed using mixtures of CD34-enriched and CD34-depleted fractions of MNC. When inoculated with a fixed CD34+lin- cell number, culture output was optimal near the P:S ratio of the unmanipulated MNC sample and declined as CD34- cell number was increased or decreased. In cultures inoculated with a fixed total cell number, CFU-GM output increased as CD34+lin- cell number was increased, whereas LTC-IC output reached a plateau. These data suggest that a limited number of LTC-IC supportive niches were present in MNC stroma, whereas IPFS lacks these niches and acts predominantly through a less potent soluble mechanism. These studies underscore the importance of parenchymal-stromal cell interactions in the ex vivo reconstitution of tissue function and offer insight into the nature of these interactions in the human BM culture system.

Hematopoietic Stem Cells: Inferences-from In Vivo Assays

Abstract: Mice and humans both contain a population in their marrow which can permanently regenerate all of the hematopoietic lineages. This developmental potential was first demonstrated in myeloablated mice transplanted with genetically marked marrow obtained from congenic donors. More recently, this approach has been used to devise an in vivo limiting dilution assay for "competitive (lymphomyeloid) repopulating units" (CRU) that allows murine hematopoietic stem cells to be quantitated. Measurements of murine CRU have shown that this population expands concomitantly with the total hematopoietic system during ontogeny and to some extent post-transplant. During these periods of expansion, defective c-kit function can be seen to preferentially compromise CRU self-renewal more than early CRU detection (which requires differentiation and amplification of the progeny of CRU, but may not require extensive CRU self-renewal). In humans, a similar cell type with transplantable lymphomyeloid differentiation potential can be identified in cord blood on the basis of its ability to engraft sublethally irradiated immunodeficient nonobese diabetic/severe combined immunodeficient mice. Quantitation of these human CRU by limiting dilution analysis of unseparated, highly purified (CD34+CD38-) and cultured (CD34+CD38-) human cord blood cells indicates that their numbers (like the long-term culture-initiating cell [LTC-IC] population) can be slightly expanded in cytokine-supplemented serum-free media, although not as extensively as anticipated from analogous studies of human marrow LTC-IC cultured under the same conditions. Taken together, the results of our studies suggest that the self-renewal of mitotically activated hematopoietic stem cells can be enhanced by their interactions with particular cytokine combinations whose effectiveness in this regard may change during ontogeny.

12 – Tumour stem cells

Abstract: This chapter provides an overview of the tumor stem cells. There is a characteristic difference between the concept of stem cells in tumors and stem cells in normal tissues. In tumors, stem cells may be defined as the biological units which have the potential of giving rise to a new tumor, either by metastasis or by tumor recurrence after therapy. This definition provides a much more rigorous test for identifying stem cells than is available in most normal tissues except for the bone marrow stem cells CFU-S. In normal tissue stem cells are defined on the basis of a compartimentalized system of constant cell renewal with cells progressing through a series of differentiation and maturation steps, and by their capacity to maintain the steady state of cell production, cell differentiation and cell loss although it is only by severe perturbation of the steady state that they can be tested. This chapter discusses the proliferative structure of malignant tumors. It explains concepts related to the identification and measurement of tumor stem cells. The chapter elaborates in detail about the implications of the hierarchical proliferative structure of tumors on the interpretation of experimental results in cancer research.

Assay systems for hematopoietic stem and progenitor cells

Abstract: Progress in our understanding of the hematopoietic system as well as novel cellular and molecular biology techniques are increasingly promoting the ex vivo manipulation and therapeutic use of hematopoietic stem and progenitor cells. For both, development of stem cell therapies and basic hematopoietic research, test systems for hematopoietic stem cells are required to monitor the intrinsic and ex vivo-induced properties of these cells. In vitro assays for primitive hematopoietic cells (colony-forming units-blast, cobblestone area-forming cells, long-term culture-initiating cells [LTC-IC]) have been established which demonstrate the proliferative and differentiation capacities of these populations. The potentials of these assays have been recently enhanced by the extended LTC and the switch LTC modifications. Although some hematopoietic cells characterized in vitro have the multipotential and proliferative properties of pluripotent hematopoietic stem cells (PHSC), their capacity to long-term repopulate hematopoiesis in vivo, a hallmark of PHSC, has not been established. Without this confirmation, populations defined in vitro should not be considered the equivalent of PHSC. In animals, the properties of primitive hematopoietic cells can be systematically analyzed by multiple in vivo assays. Therefore, various strategies have been pursued to develop an animal model for human hematopoiesis. In fetal sheep and immunodeficient mice, the functions of human PHSC are reproduced, and long-term multilineage repopulation capacity and extensive proliferative potential have been demonstrated for xenografted human cells. Thus, both models can be considered stem cell assays and may significantly enhance the study of early hematopoiesis and the development of therapeutic strategies.

Expression of Murine Interleukin 11 and its Receptor α‐Chain in Adult and Embryonic Tissues

Abstract: Interleukin 11 (IL-11) is a multifunctional cytokine that has diverse effects on blood cells and their precursors and on a number of cell types outside of the hematopoietic system. The cDNAs encoding murine IL-11 and its receptor α-chain (IL-11Rα) have recently been isolated. We have used the RNase protection assay to examine the expression of murine IL-11 and IL-11Rα in a range of adult mouse tissues, in embryos, and during development of embryonic stem (ES) cells into cystic embryoid bodies in vitro. The testis showed a high level of IL-11 gene expression while a much lower level of expression was detected in the lung, stomach, small intestine, and large intestine. Expression of IL-11 was not detected between day 10.5 and day 18.5 post coitum of embryonic development or in differentiating ES cells in vitro. In contrast, the IL-11Rα was found to be expressed in all adult tissues examined, during embryonic development, and in totipotent and differentiating ES cells.

Stem cell gene therapy, position effects and chromatin insulators.

Abstract: Low efficiency of gene transfer is the main obstacle for a clinically effective gene therapy at the level of the pluripotent hematopoietic stem cell. Another important aspect of stem cell gene therapy, the actual expression of the transduced genes, has only been investigated adequately in very few studies, mainly for globin genes. Transcriptional silencing and position effects due to negative effects of surrounding chromatin on the expression of randomly integrated vector sequences may seriously jeopardize the success of current gene therapy strategies, even if transduction efficiency can be significantly improved. We propose the incorporation of chromatin insulators in the design of gene therapy vectors to overcome the problem of position effects. Chromatin insulators are protein-binding DNA elements that lack intrinsic promoter/enhancer activity but shelter genes from transcriptional influence of surrounding chromatin. The best characterized insulators are from Drosophila. We hypothesize that the important cellular function of chromatin organization is evolutionarily conserved and that human homologs to Drosophila insulator binding proteins such as the suppressor of Hairy-wing exist and can be cloned. Using these putative proteins, it should be possible to identify corresponding minimal binding sites with insulator activity. The design and incorporation of effective chromatin insulator sequences in the next generation of gene therapy vectors should lead to improved and more predictable expression of therapeutic transgenes and constitute an important step toward clinically effective gene therapy.

Bone Marrow Cryopreservation: Improved Recovery Due to Bioantioxidant Additives in the Freezing Solution

Abstract: One hypothesis of cryoinjury is the damaging effect of oxygen-free radicals formed during freezing and thawing. Addition of physiologically acceptable antioxidants into the preservation solution improved the cryoprotection of bone marrow cells. Bone marrow nucleated cells were frozen using rate-controlled freezing devices. Antioxidants used in combination with 10% dimethylsulfoxide were alpha tocopheryl acetate, catalase, ascorbic acid, superoxide dismutase and reduced glutathione. The parameters used to assess the efficacy of cryopreservation were viability, nucleated cell recovery, and colony-forming unit assays: granulocyte-macrophage and granulocyte-erythroid-macrophage-megakaryocyte. Results obtained indicate that the first three antioxidants increase the post-thaw recovery of cells, particularly in terms of early and late progenitors. Superoxide dismutase and reduced glutathione, however, have no beneficial effect on the preservation. The response of cryopreserved cells to suboptimal concentrations of colony-stimulating factors in in vitro assays was also restored to some extent when the cells were frozen with antioxidants.