Heterogeneous T-cell response to MAGE-A10(254-262): high avidity-specific cytolytic T lymphocytes show superior antitumor activity.

MAGE-encoded antigens, which are expressed by tumors of many histological types but not in normal tissues, are suitable candidates for vaccine-based immunotherapy of cancers. Thus far, however, T-cell responses to MAGE antigens have been detected only occasionally in cancer patients. In contrast, by using HLA/peptide fluorescent tetramers, we have observed recently that CD8(+) T cells specific for peptide MAGE-A10(254-262) can be detected frequently in peptide-stimulated peripheral blood mononuclear cells from HLA-A2-expressing melanoma patients and healthy donors. On the basis of these results, antitumoral vaccination trials using peptide MAGE-A10(254-262) have been implemented recently. In the present study, we have characterized MAGE-A10(254-262)-specific CD8(+) T cells in polyclonal cultures and at the clonal level. The results indicate that the repertoire of MAGE-A10(254-262)-specific CD8(+) T cells is diverse both in terms of clonal composition, efficiency of peptide recognition, and tumor-specific lytic activity. Importantly, only CD8(+) T cells able to recognize the antigenic peptide with high efficiency are able to lyse MAGE-A10-expressing tumor cells. Under defined experimental conditions, the tetramer staining intensity exhibited by MAGE-A10(254-262)-specific CD8(+) T cells correlates with efficiency of peptide recognition so that "high" and "low" avidity cells can be separated by FACS. Altogether, the data reported here provide evidence for functional diversity of MAGE-A10(254-262)-specific T cells and will be instrumental for the monitoring of peptide MAGE-A10(254-262)-based clinical trials.

An improved panning technique for the selection of CD34+ human bone marrow hematopoietic cells with high recovery of early progenitors.

The human hematopoietic pluripotent repopulating "stem cell" is thought to be present within a minor subpopulation of CD34+ cells. This has not been definitively shown, although the more primitive CD34+ cell subset contains precursors for all lymphoid and nonlymphoid cell lineages. When purifying CD34+ cells, it is important to recover these early progenitors, which are more strongly immunoadsorbent to the separation devices. Using a commercialized panning system (AIS CELLector flasks), we observed that a high degree of purity requires a thorough washing procedure so that cells not binding or weakly binding to CD34 antibodies are removed. High recoveries can be obtained if the adherent cells are then efficiently detached by a 2-hour incubation in culture medium without added cytokines. In this way, we can routinely obtain 93.5 +/- 3.4% purity of CD34+ cells with a 74% yield of the multipotent colony-forming units (CFU-GEMM). Complete recovery of the putative "stem cell," or at least the early progenitor cell compartment (CD34+ CD38low/- CD34+ Thy-1+ cells), is also obtained. More than 30% of these cells can generate day-14 colonies in vitro. Comparable results were obtained when the separation was scaled up for clinical application using appropriate large-scale devices. The various incubation times of the procedure can be easily adjusted to the work schedule. This renders the procedure easy to handle, efficient, safe, and, because the cells can be observed under light microscopy, easy to control.

Increased stable retroviral gene transfer in early hematopoietic progenitors released from quiescence.

It has been previously demonstrated that prestimulation with cytokines could improve gene transfer in hematopoietic progenitors. However, we have shown that no combination of cytokines so far tested is able to release rapidly in vitro the stem cell compartment from quiescence unless an autocrine transforming growth factor-beta 1 (TGF-beta 1) is blocked by specific oligonucleotide antisense or antiserum (Hatzfeld et al., 1991, J. Exp. Med., 174, 925). We now report that a 10-hr cytokine prestimulation of SBA-CD34high human umbilical cord blood progenitors increases retrovirally mediated transfer of the nls-lacZ reporter gene from 1% to 23.8% and addition of anti-TGF-beta serum doubles this increase (47.3%). Interestingly, the effect of anti-TGF-beta preincubation on gene transfer is most effective on the most immature progenitors, which develop into high proliferative potential mixed colonies with 1-2 x 10(5) cells. Anti-TGF-beta serum pretreatment increases gene transfer in these early colony-forming units granulocyte-erythroid-megakaryocyte-macrophage (CFU-GEMM) from 54.1% to 93.3%. It augments significantly the stability of gene expression in all subpopulations of mixed colonies. Colonies obtained after pretreatment with anti-TGF-beta serum are larger and the expression of the stably integrated recombinant provirus does not reduce their size. This prestimulation method provides a substantial improvement for gene transfer efficiency within the quiescent stem cell compartment that is responsible for long-term engraftment.

Transfer of high copy number plasmid into mammalian cells by calcium phosphate transfection.

Using flow cytometry, single cell sorting, confocal microscopy and fluorescent plasmids, a thorough study of DNA uptake, DNA fate and DNA expression in mammalian cells transfected with the widely used calcium-phosphate precipitation method was executed. We show for the first time that up to 100,000 plasmid molecules can be delivered into individual cells, but also that DNA transfer into cells is a dynamic process that follows a defined kinetics of uptake and intracellular processing. Analyses by flow cytometry and confocal microscopy have also supported results suggesting endocytosis during Ca-Pi transfection. We also demonstrate that expression-enhancing treatment with glycerol during transfection did not result in increased DNA uptake. While cells with maximal DNA load appear to express the highest level of the transgene, these cells are negatively impacted in terms of growth and survival.

Specific dose-response effects of TGF-beta1 on developmentally distinct hematopoietic stem/progenitor cells from human umbilical cord blood.

INTRODUCTION: Transforming Growth Factor-beta1 is known to maintain primitive human hematopoietic stem/progenitor cells in a quiescent state. However, its specific role in the control of distinct progenitor cell types needs to be further elucidated. In this study, we have investigated the dose-response effect of TGF-beta1 on progenitors ranging from primitive high proliferative potential (HPP)-Mix, -GM or -BFU-E to later BFU-E, CFU-G or CFU-M. MATERIALS AND METHODS: A clonal semi-solid assay has been used to analyze the effects of a TGF-beta1 blocking antibody (anti-TGF-beta1) or that of active TGF-beta1 added to the medium at concentrations from 10-3000 pg/ml, on these different hematopoietic stem/progenitor cell types. RESULTS AND CONCLUSION: A preferential growth inhibitory effect on the earlier progenitors was observed when low concentrations of TGF-beta1 (10-300 pg/ml) were used. Concentrations of 10-30 pg/ml TGF-beta1 were sufficient to inhibit 90% of the primitive multipotent HPP-Mix, while 100-300 pg/ml TGF-beta1 were required to inhibit 70% of the bipotent HPP-GM and early HPP-BFU-E. TGF-beta1 did not significantly inhibit or activate the growth of later CFU-G and CFU-M, even when added at concentrations 10-100 fold higher. In contrast, a significant growth-inducing effect of very low TGF-beta1 concentrations (< or =30 pg/ml) on a subset of later BFU-E was observed and cannot be explained by a switch of early into later BFU-E. These results emphasize the polyfunctional role of TGF-beta1 in the regulation of hematopoiesis and the need for low, physiological concentrations of TGF-beta1, when studying both the stem cell compartment and more mature progenitor cell subpopulations.

Intranasal treatment with ovalbumin but not the major T cell epitope ovalbumin 323-339 generates interleukin-10 secreting T cells and results in the induction of allergen systemic tolerance.

BACKGROUND: Nasal administration of major peptide T cell epitopes gives contradictory data on the induction of peripheral tolerance. OBJECTIVE: To compare the prophylactic effect of intranasal treatment (INT) on the development of an allergic response, using either ovalbumin (OVA) or its major T cell epitope OVA 323-339 (OVAp). METHODS: BALB/c mice were treated intranasally with OVA or OVAp and subsequently immunized s.c. with OVA. Anti-OVA-specific antibody, T cell proliferation and cytokine responses were analysed. In an adoptive transfer model using OVAp specific TCR transgenic (Tg) T cells from D011.10 mice, in vivo tracking and characterization of transferred T cells in the cervical, inguinal and bronchial lymph nodes (BLN) and in the spleen were determined by FACS analysis. RESULTS: Prophylactic INT with OVA induced T cell tolerance towards subsequent OVA s.c. immunizations, inhibiting OVA specific T cell proliferation, IgE and IgG1 production, in contrast to INT with OVAp, which was unable to induce tolerance. In vivo analysis of transferred OVA-specific TCR Tg T cells showed that INT with OVA induced a preferential activation of T cells in BLN, as opposed to a broad, systemic activation with OVAp. In vivo, OVAp INT led to faster and more sustained cell division cycles than OVA INT. Ex vivo, tolerance to OVA was associated with the generation of IL-10 secreting CD4(+) T cells in BLN of OVA-treated mice only. CONCLUSION: INT with OVA but not with OVAp led to regional (as opposed to systemic) T cell activation and the induction of IL-10 secreting CD4(+) T cells in BLN, potentially critical steps in the induction of T cell-specific tolerance via the nasal route.

Co-stimulatory effects of steel factor, the c-kit ligand, on purified human hematopoietic progenitors in low cell density culture.

Steel factor (SF), the ligand for the c-kit, also called kit ligand, stem cell factor, or mast cell growth factor, was evaluated on colony formation alone or in combination with other cytokines, from purified human hematopoietic CD34+ cells in low density cell culture. SF alone had a slight effect on granulocyte (G) and macrophage (M) colony formation. It synergized with other cytokines on colony formation from colony-forming unit-granulocyte, erythroid, macrophage, megakaryocyte (CFU-GEMM), erythroid and granulocyte-macrophage (CFU-GM) progenitors. However, combination of SF with lineage-specific factors, such as erythropoietin (Epo) or/and granulocyte colony-stimulating factor (G-CSF) was not sufficient for the proliferation of multipotential progenitors (CFU-GEMM). These multipotential progenitors required the presence of multi-lineage factors, such as interleukin 3 (IL3) or granulocytic-macrophage CSF(GM-CSF) for their development.

IL-3, GM-CSF and CSF-1 modulate c-fms mRNA more rapidly in human early monocytic progenitors than in mature or transformed monocytic cells.

We have previously shown that a low concentration of CSF-1 (1 U/ml) can trigger human immature monocytic progenitor proliferation in the presence of low concentrations of IL3 (1.7 U/ml). No c-fms down-regulation was observed during this early cell activation. In contrast, 20 U/ml of CSF-1, active on late monocytic cell growth, down-regulated c-fms mRNA expression in immature progenitors and monocytes derived from bone marrow CD34+ cells in culture. We have now extended this study to include the effects of various concentrations of GM-CSF, IL3 and G-CSF on c-fms expression. We observed that high doses of GM-CSF or IL3 down-modulated c-fms mRNA, whereas low doses of GM-CSF or IL3, which were active on early monocytic growth, had no such effect. Similar results were observed at the protein level. In contrast, whatever the concentration, G-CSF had no effect on c-fms mRNA or protein levels. We further observed that the more immature the c-fms expressing progenitors, the faster the down-modulation of this receptor. This was observed within less than 1 hour for immature bone marrow cells, 6 hours for peripheral blood monocytes and even longer for transformed monocytic cells. These results suggest that oncogene expression can be regulated much more rapidly in immature progenitors than was previously observed in mature cells or transformed cell lines.

Release from quiescence of primitive human hematopoietic stem/progenitor cells by blocking their cell-surface TGF-beta type II receptor in a short-term in vitro assay.

Genetic alterations of the signaling cascade of transforming growth factor-beta (TGF-beta) are often associated with neoplastic transformation of primitive cells. This demonstrates the key role for this pleiotropic factor in the control of quiescence and cell proliferation in vivo. In the high proliferative potential-quiescent cell (HPP-Q) in vitro assay, the use of TGF-beta1 blocking antibodies (anti-TGF-beta1) allows the detection within two to three weeks of primitive hematopoietic cells called HPP-Q, which otherwise would not grow. However, the possibility of triggering cell proliferation by blocking the cell-surface TGF-beta receptors has not been investigated until now. We have tested here the efficiency of a blocking antibody against TGF-betaRII (anti-TGF-betaRII) on CD34(+)CD38(-) hematopoietic cells, a subpopulation enriched in primitive stem/progenitor cells, and compared its effect with that of anti-TGF-beta1. About twice as many HPP colony-forming cells were detected in the presence of anti-TGF-beta1 or anti-TGF-betaRII, compared to the control (p < 0.02). Moreover, anti-TGF-betaRII was as efficient as anti-TGF-beta1 for activating multipotent HPP-granulocyte erythroid macrophage megakaryocyte and HPP-Mix, bipotent HPP-granulocyte-macrophage (GM) and unipotent HPP-G, HPP-M and HPP-BFU-E. We therefore propose the use of anti-TGF-betaRII to release primitive cells from quiescence in the HPP-Q assay. This strategy could be extended to nonhematopoietic tissues, as TGF-beta1 may be a pleiotropic regulator of somatic stem cell quiescence.

High proliferative potential-quiescent cells: a working model to study primitive quiescent hematopoietic cells.

Human adult hematopoietic stem cells are mostly quiescent or slow cycling. We have previously demonstrated that blocking of transforming growth factor-beta1 (TGF-beta1) is able to activate, in the presence of cytokines, primitive quiescent hematopoietic multipotent progenitors which could not grow in a two week semi-solid culture assay (short term culture). We have also shown that anti-TGF-beta1 can up-modulate c-KIT, the receptor of the stem cell factor (steel factor). To elucidate whether TGF-beta1 plays a central role in controlling the quiescence of hematopoietic primitive cells, it was necessary to demonstrate, as detailed in this study, that: (1) whatever the cytokine combination tested, addition of anti-TGF-beta1 releases from quiescence multipotent progenitors with a significantly higher hematopoietic potential than those activated by cytokines alone. (2) Other important cytokine receptors controlling the most primitive hematopoietic cells such as FLT3 and the IL6 receptor (IL6-R) are down-modulated by TGF-beta1 but rapidly up-modulated by anti-TGF-beta1. (3) Anti-TGF-beta1-sensitive multipotent and high proliferative potential progenitors express these cytokine receptors at a low level (FLT3(low) and IL6-Rlow). According to these results, we propose the working model of 'High Proliferative Potential-Quiescent cells' to refer to these primitive hematopoietic multipotent progenitors that are highly sensitive to the growth inhibitory effect of TGF-beta1. This model could be valid not only to study the human hematopoietic quiescent progenitors but also for other somatic stem cell systems.

Release from quiescence of CD34+ CD38- human umbilical cord blood cells reveals their potentiality to engraft adults.

Using optimal culture conditions in which the transforming growth factor beta 1 (TGF-beta 1) inhibitory loop has been interrupted by antisense TGF-beta 1 oligonucleotides or anti-TGF-beta serum, we have compared the proliferative capacities and the abilities of the CD34+ CD38- cell populations from bone marrow and umbilical cord blood to generate early progenitors in long-term cultures. The CD34+ CD38- fraction of umbilical cord blood accounts for 4% of the CD34+ fraction compared to only 1% in bone marrow, indicating that umbilical cord blood may be relatively enriched in stem cells. We estimate that the CD34+ CD38- cells from a typical umbilical cord blood sample produce equivalent numbers of colony-forming units (CFU)-granulocyte/erythrocyte/macrophage/megakaryocyte, twice as many CFU-granulocyte/macrophage (GM) and 3 times as many burst-forming units-erythroid as the same population from an average bone marrow sample used in adult transplantation. In addition, the colonies resulting from the umbilical cord blood samples were significantly larger than those from bone marrow, indicating a greater growth potential. However, the content of later progenitors, which may be important for short-term reconstitution, was less in umbilical cord blood-derived than in bone marrow-derived cell preparations, as estimated by a 4-fold lower production of CFU-GM in long-term cultures of CD34+ CD38+ cells. This deficit is partially compensated by the higher growth capacity of the resulting CFU-GM. These studies suggest that umbilical cord blood is a suitable source of cells for adult transplantation.

Purification and release from quiescence of umbilical cord blood early progenitors reveal their potential to engraft adults.

Steel factor (SF) increases the frequency of colony formation by CD34+ CD38- cycling cells, but it does not reverse the effect of an autocrine production of transforming growth factor (TGF)-beta 1 by early progenitors of the stem cell compartment. We have used optimal culture conditions supplemented with SF and anti-TGF-beta serum to estimate the proliferative capacity and ability to generate early progenitors in long-term cultures of bone marrow and umbilical cord blood cells. We estimate that the CD34+ CD38- cells from a typical umbilical cord blood sample produce equivalent numbers of granulocyte erythrocyte macrophage megakaryocyte colony-forming units (CFU), twice as many granulocyte-macrophage (GM) CFU, and three times as many erythroid burst-forming units as the same population from an average bone marrow sample used in adult transplantation. These results suggest that umbilical cord blood is a suitable source of cells for adult transplantation.

[Positive and negative controls on hematopoietic progenitor development: models and facts]. / Contrôles positifs et négatifs du développement des progéniteurs hématopoïétiques: modèles et faits.

The stochastic model of stem cell differentiation is in accord with experimental findings but does not explain hematopoietic homeostasis. We discuss how positive and negative controls by cytokines and inhibitors could maintain homeostasis, even though progenitor commitment towards the various hematopoietic lineages may be stochastic.

Early CD34high cells can be separated into KIThigh cells in which transforming growth factor-beta (TGF-beta) downmodulates c-kit and KITlow cells in which anti-TGF-beta upmodulates c-kit.

We have previously shown that early human CD34high hematopoietic progenitors are maintained quiescent in part through autocrine transforming growth factor-beta 1 (TGF-beta 1). We also demonstrated that, in the presence of interleukin-3, interleukin-6, granulocyte colony-stimulating factor, and erythropoietin, TGF-beta 1 antisense oligonucleotides or anti-TGF-beta serum have an additive effect with KIT ligand (Steel factor [SF]), which suggests that they control different pathways of regulation in these conditions. This finding also suggests that autocrine TGF-beta 1 might suppress c-kit expression in primitive human hematopoietic progenitors. We have now distinguished two subpopulations of CD34high cells. One subpopulation expresses a c-kit mRNA that can be downmodulated by exogenous TGF-beta 1 within 6 hours. Another subpopulation of early CD34high cells expresses a low or undetectable level of c-kit mRNA, but its expression can be upmodulated within 6 hours by anti-TGF-beta. These effects disappear 48 hours after induction and cannot be maintained longer than 72 hours, even if TGF-beta 1 or anti-TGF-beta serum are added every day. Similar kinetics, although delayed, are observed with KIT protein expression. On the contrary, no specific effect of TGF-beta 1 was observed on c-fms, GAPDH, and transferrin receptor gene expression in these early progenitors. These results clarify the complex interaction between TGF-beta 1 and SF in normal early hematopoietic progenitors. SF does not switch off the TGF-beta 1 inhibitory pathway. Autocrine TGF-beta 1 appears to maintain these cells in a quiescent state, suppressing cell division by downmodulating the receptor of SF, a key cytokine costimulator of early progenitors.

Human umbilical cord blood CD34+ cell purification with high yield of early progenitors.

Human umbilical cord blood CD34+ cells were purified using a two-step procedure by elimination of the soybean agglutinin-binding cells and by a positive panning selection with a CD34 monoclonal antibody. The isolated fraction was 88-97% pure CD34+ cells. A yield of 48.5% was obtained when comparing the number of cells recovered in the CD34(+)-purified fraction and the number of CD34+ cells detected in the initial mononuclear cell fraction. By flow cytometry, we observed that the CD34+ cells that were not recovered were those that had the lower expression of CD34 antigen and were therefore the more mature cells. A high recovery of CFU-GEMM progenitors (73.9%) was also observed. These data suggest the possibility of purifying CD34+ umbilical cord blood cells for clinical applications, in particular for umbilical cord blood banking.

TGF-(beta)1 maintains hematopoietic immaturity by a reversible negative control of cell cycle and induces CD34 antigen up-modulation.

Somatic stem cells are largely quiescent in spite of their considerable proliferative potential. Transforming growth factor-(beta)1 (TGF-(beta)1) appears to be a good candidate for controlling this quiescence. Indeed, various mutations in the TGF-beta signalling pathway are responsible for neoplasic proliferation of primitive stem/progenitor cells in human tissues of various origins. In hemopoietic single cell culture assays, blocking autocrine and endogeneous TGF-(beta)1 triggers the cell cycling of high proliferative potential undifferenciated stem/progenitor cells. However, it has never been demonstrated whether TGF-(beta)1 has an apoptotic effect or a differentiating effect on these primitive cells, as already described for more mature cells. Using single cell experiments both in liquid or semi-solid culture assays and dye tracking experiments by flow cytometry, we demonstrate that low, physiological concentrations of TGF-(beta)1, which specifically maintain primitive human hemopoietic stem/progenitor cells in quiescence, have a reversible effect and do not induce apoptosis. We moreover demonstrate that these low concentrations prevent the rapid loss of the mucin-like protein CD34, a most common marker of immature hematopoietic stem/progenitor cells, which is progressively lost during differentiation. TGF-(beta)1 not only up-modulated the CD34 antigen before S phase entry but also maintained a high level of CD34 expression on cells which had escaped cell cycle inhibition, suggesting that proliferation inhibition and differentiation control by TGF-(beta)1 may be independent. These data provide additional evidence that TGF-(beta)1 acts as a key physiological factor ensuring the maintenance of a stem cell reserve.

The activatory receptor 2B4 is expressed in vivo by human CD8+ effector alpha beta T cells.

The membrane receptor 2B4 is a CD2 family member that is involved in lymphocyte activation. A fraction of human CD8+ alphabeta T cells up-regulate 2B4 in vivo, and here we demonstrate that this correlates with the acquisition of effector cell properties such as granzyme B and perforin expression, rapid IFN-gamma production, and down-regulation of the lymph node homing chemokine receptor CCR7. In PBLs from healthy donors, cytomegalovirus-specific effector T cells were 2B4 positive, whereas naive melanoma Ag (Melan-A/melanoma Ag recognized by T cells-1)-specific T cells were 2B4 negative. In melanoma patients, Melan-A-specific T cells up-regulated 2B4 in parallel with in vivo differentiation. This occurred in PBLs after vaccination with Melan-A peptides and in tumor-infiltrated lymph nodes, likely through disease-associated activation of Melan-A-specific T cells. Thus, 2B4 expression correlates with CD8+ T cell differentiation in vivo.

The Tie receptor tyrosine kinase is expressed by human hematopoietic progenitor cells and by a subset of megakaryocytic cells.

Growth factor receptors in human hematopoietic progenitor cells have become the focus of intense interest, because they may provide tools for the monitoring, enrichment, and expansion of stem cells. We have shown earlier that the Tie receptor tyrosine kinase is expressed in erythroid and megakaryoblastic human leukemia cell lines, in the blood islands of the yolk sac, and in endothelial cells starting from day 8.0 of mouse development. Here, the expression of Tie was studied in human hematopoietic cells of various sources. Peripheral blood mononuclear cells were Tie-. However, a large fraction of CD34+ cells from umbilical cord blood (UCB) and bone marrow (BM) expressed tie protein and mRNA. On average, 64% of the fluorescence-activated cell sorting-gated UCB CD34+ cells including CD38- cells and a fraction of cells expressing low levels of c-Kit were Tie+. Also, 30% to 60% of BM CD34+ cells were Tie+, including most of the BM CD34+CD38-, CD34+Thy-1+, and CD34+HLA-DR- cells. Under culture conditions allowing myeloid, erythroid, and/or megakaryocytic differentiation, purified UCB CD34+ cells lost Tie mRNA and protein expression concomitantly with that of CD34; however, a significant fraction of cells expressed Tie during megakaryocytic differentiation. These data suggest that, in humans, the Tie receptor and presumably its ligand may function at an early stage of hematopoietic cell differentiation.