Loss-of-function mutations of Dynamin 2 promote T-ALL by enhancing IL-7 signalling.

Mutations in the DYNAMIN2 (DNM2) gene are frequently detected in human acute T-cell lymphoblastic leukemia (T-ALL), although the mechanisms linking these mutations to disease pathogenesis remain unknown. Using an ENU-based forward genetic screen for mice with erythroid phenotypes, we identified a heterozygous mouse line carrying a mutation in the GTPase domain of Dnm2 (Dnm2V265G) that induced a microcytic anemia. In vitro assays using the V265G mutant demonstrated loss of GTPase activity and impaired endocytosis that was comparable to other DNM2 mutants identified in human T-ALL. To determine the effects of DNM2 mutations in T-ALL, we bred the Dnm2V265G mice with the Lmo2 transgenic mouse model of T-ALL. Heterozygous Dnm2 mutants lacking the Lmo2 transgene displayed normal T-cell development, and did not develop T-ALL. In contrast, compound heterozygotes displayed an accelerated onset of T-ALL compared with mice carrying the Lmo2 oncogene alone. The leukemias from these mice exhibited a more immature immunophenotype and an expansion in leukemic stem cell numbers. Mechanistically, the Dnm2 mutation impaired clathrin-mediated endocytosis of the interleukin (IL)-7 receptor resulting in increased receptor density on the surface of leukemic stem cells. These findings suggest that DNM2 mutations cooperate with T-cell oncogenes by enhancing IL-7 signalling.

The Notch ligand DLL4 specifically marks human hematoendothelial progenitors and regulates their hematopoietic fate.

Notch signaling is essential for definitive hematopoiesis, but its role in human embryonic hematopoiesis is largely unknown. We show that in hESCs the expression of the Notch ligand DLL4 is induced during hematopoietic differentiation. We found that DLL4 is only expressed in a sub-population of bipotent hematoendothelial progenitors (HEPs) and segregates their hematopoietic versus endothelial potential. We demonstrate at the clonal level and through transcriptome analyses that DLL4(high) HEPs are enriched in endothelial potential, whereas DLL4(low/-) HEPs are committed to the hematopoietic lineage, albeit both populations still contain bipotent cells. Moreover, DLL4 stimulation enhances hematopoietic differentiation of HEPs and increases the amount of clonogenic hematopoietic progenitors. Confocal microscopy analysis of whole differentiating embryoid bodies revealed that DLL4(high) HEPs are located close to DLL4(low/-) HEPs, and at the base of clusters of CD45+ cells, resembling intra-aortic hematopoietic clusters found in mouse embryos. We propose a model for human embryonic hematopoiesis in which DLL4(low/-) cells within hemogenic endothelium receive Notch-activating signals from DLL4(high) cells, resulting in an endothelial-to-hematopoietic transition and their differentiation into CD45+ hematopoietic cells.

The differentiation stage of p53-Rb-deficient bone marrow mesenchymal stem cells imposes the phenotype of in vivo sarcoma development.

Increasing evidence suggests that mesenchymal stem/stromal cells (MSCs) carrying specific mutations are at the origin of some sarcomas. We have reported that the deficiency of p53 alone or in combination with Rb (Rb(-/-) p53(-/-)) in adipose-derived MSCs (ASCs) promotes leiomyosarcoma-like tumors in vivo. Here, we hypothesized that the source of MSCs and/or the cell differentiation stage could determine the phenotype of sarcoma development. To investigate whether there is a link between the source of MSCs and sarcoma phenotype, we generated p53(-/-) and Rb(-/-)p53(-/-) MSCs from bone marrow (BM-MSCs). Both genotypes of BM-MSCs initiated leiomyosarcoma formation similar to p53(-/-) and Rb(-/-)p53(-/-) ASCs. In addition, gene expression profiling revealed transcriptome similarities between p53- or Rb-p53-deficient BM-MSCs/ASCs and muscle-associated sarcomagenesis. These data suggest that the tissue source of MSC does not seem to determine the development of a particular sarcoma phenotype. To analyze whether the differentiation stage defines the sarcoma phenotype, BM-MSCs and ASCs were induced to differentiate toward the osteogenic lineage, and both p53 and Rb were excised using Cre-expressing adenovectors at different stages along osteogenic differentiation. Regardless the level of osteogenic commitment, the inactivation of Rb and p53 in BM-MSC-derived, but not in ASC-derived, osteogenic progenitors gave rise to osteosarcoma-like tumors, which could be serially transplanted. This indicates that the osteogenic differentiation stage of BM-MSCs imposes the phenotype of in vivo sarcoma development, and that BM-MSC-derived osteogenic progenitors rather than undifferentiated BM-MSCs, undifferentiated ASCs or ASC-derived osteogenic progenitors, represent the cell of origin for osteosarcoma development.

Rapid and sensitive method for determining free amino acids in honey by gas chromatography with flame ionization or mass spectrometric detection.

This paper describes a rapid, sensitive and specific method for determination of free amino acids in honey involving a new reaction of derivatization and gas chromatography (GC) with flame ionization (FID) and mass spectrometric (MS) detection. The method allows the determination of 22 free amino acids in honey samples in a short time: 8 and 5 min for GC-FID and GC-MS, respectively. Quantitation was performed using Norvaline as internal standard, with detection limits ranging between 0.112 and 1.795 mg/L by GC-FID and between 0.001 and 0.291 mg/L by GC-MS in the selected-ion monitoring mode. The method was validated and applied to a set of 74 honey samples belonging to four different botanical origins: eucaliptus, rosemary, orange and heather. The statistical treatment of data shows a correct classification of different origins over 90%.

Measles virus infection induces terminal differentiation of human thymic epithelial cells.

Measles virus infection induces a profound immunosuppression that may lead to serious secondary infections and mortality. In this report, we show that the human cortical thymic epithelial cell line is highly susceptible to measles virus infection in vitro, resulting in infectious viral particle production and syncytium formation. Measles virus inhibits thymic epithelial cell growth and induces an arrest in the G0/G1 phases of the cell cycle. Moreover, we show that measles virus induces a progressive thymic epithelial cell differentiation process: attached measles virus-infected epithelial cells correspond to an intermediate state of differentiation while floating cells, recovered from cell culture supernatants, are fully differentiated. Measles virus-induced thymic epithelial cell differentiation is characterized by morphological and phenotypic changes. Measles virus-infected attached cells present fusiform and stellate shapes followed by a loss of cell-cell contacts and a shift from low- to high-molecular-weight keratin expression. Measles virus infection induces thymic epithelial cell apoptosis in terminally differentiated cells, revealed by the condensation and degradation of DNA in measles virus-infected floating thymic epithelial cells. Because thymic epithelial cells are required for the generation of immunocompetent T lymphocytes, our results suggest that measles virus-induced terminal differentiation of thymic epithelial cells may contribute to immunosuppression, particularly in children, in whom the thymic microenvironment is of critical importance for the development and maturation of a functional immune system.

Identification of a late stage of small noncycling pTalpha- pre-T cells as immediate precursors of T cell receptor alpha/beta+ thymocytes.

During thymocyte development, progression from T cell receptor (TCR)beta to TCRalpha rearrangement is mediated by a CD3-associated pre-TCR composed of the TCRbeta chain paired with pre-TCRalpha (pTalpha). A major issue is how surface expression of the pre-TCR is regulated during normal thymocyte development to control transition through this checkpoint. Here, we show that developmental expression of pTalpha is time- and stage-specific, and is confined in vivo to a limited subset of large cycling human pre-T cells that coexpress low density CD3. This restricted expression pattern allowed the identification of a novel subset of small CD3(-) thymocytes lacking surface pTalpha, but expressing cytoplasmic TCRbeta, that represent late noncycling pre-T cells in which recombination activating gene reexpression and downregulation of T early alpha transcription are coincident events associated with cell cycle arrest, and immediately preceding TCRalpha gene expression. Importantly, thymocytes at this late pre-T cell stage are shown to be functional intermediates between large pTalpha+ pre-T cells and TCRalpha/beta+ thymocytes. The results support a developmental model in which pre-TCR-expressing pre-T cells are brought into cycle, rapidly downregulate surface pre-TCR, and finally become small resting pre-T cells, before the onset of TCRalpha gene expression.

Enhanced green fluorescent protein as an efficient reporter gene for retroviral transduction of human multipotent lymphoid precursors.

Owing to its autofluorescence properties, green fluorescent protein (GFP) has aroused increasing interest as a marker system for many research applications. In this study we investigated the suitability of the "enhanced" GFP (EGFP), a mutant version of GFP optimized for flow cytometry and microscopy detection, as a reporter gene for retroviral transduction protocols. EGFP was shown to display a bright and stably maintained emission pattern in transfected GP+envAm12 packaging cells. Stable fluorescent emission was observed as well after transduction in NIH 3T3 fibroblasts and in the human Jurkat T cell line, in which EGFP was shown to confer no deleterious effect or growth disadvantage on the expressing cells. Moreover, EGFP expression could be detected after short-term retroviral exposure, thus allowing a rapid and quantitative retroviral titering assay, alternative to the standard colony-formation procedure. Most importantly, we showed the feasibility of EGFP as a marker gene in retroviral-mediated transduction of primary lymphoid precursors. In particular, transduction of CD34+CD1- human thymocytes by short-term cocultivation yielded up to 30% of EGFP-expressing cells, while maintaining CD34 expression levels. Finally, when cultured under multicytokine-supported conditions, such transduced intrathymic progenitors were shown to efficiently generate lymphoid-related dendritic cells, which displayed a distinct EGFP expression. Therefore, because of its rapid and easy detectability and its nontoxic characteristics, EGFP proves itself to be a valuable reporter gene by allowing the transduction of multipotential progenitors and by being compatible with the developmental programs of lymphoid lineage generation.

Identification of a common developmental pathway for thymic natural killer cells and dendritic cells.

Current data support the notion that the thymus is seeded by a yet uncommitted progenitor cell able to generate T cells, B cells, natural killer (NK) cells, and dendritic cells (DCs). We assess in this report the developmental relationship of DCs and NK cells derived from a small subset of CD34(+) human postnatal thymocytes that, like the earliest precursors in the fetal thymus, display low CD33 surface expression. Culture of these isolated CD34(+) CD33(lo) thymic progenitors with a mixture of cytokines, including interleukin-7 (IL-7), IL-1alpha, IL-6, granulocyte-macrophage colony-stimulating factor, and stem cell factor, results in predominant generation of DCs. However, the addition of IL-2 to the cytokine mixture leads to the simultaneous development of DCs and NK cells. Both developmental pathways progress through a transient population of CD34(+)CD44(bright) CD5(lo/-)CD33(+) large-sized cells, distinct from small-sized T-lineage precursors, that contain bipotential NK/DC progenitors. These data provide evidence of linked pathways of NK cell and DC development from intrathymic precursors and suggest that NK cells and DCs branch off the T lineage through a common intermediate progenitor.

CD10 is expressed on human thymic epithelial cell lines and modulates thymopentin-induced cell proliferation.

Thymic hormones such as thymopoietin (TP) have been shown to regulate thymocyte differentiation and lymphocyte activation. However, it is not known whether thymopoietin affects thymic epithelial cell (TEC) functions. In this study we have examined the effect of a five amino acid active peptide (TP5), corresponding to amino acids 32-36 of TP, on the proliferation of nontransformed clones of human TEC. Our results indicate that TP5 induced reinitiation of DNA synthesis and potentiated fetal calf serum (FCS)-induced cell growth in postnatal and fetal-derived human TEC. We also found that TEC lines express high levels of endopeptidase 24.11, a cell-surface metallopeptidase also known as the CD10 antigen. We show that TP5 is cleaved by CD10 at the surface of TEC lines, indicating that this endopeptidase may regulate TP5-induced TEC proliferation. Phosphoramidon, a specific endopeptidase 24.11 inhibitor, consistently acts in synergy with TP5 to enhance FCS-induced TEC growth. Hence, we conclude that 1) TP5 alone or in combination with FCS supports the growth of TEC lines, and 2) TEC lines express high levels of CD10, which regulates TP5-induced TEC proliferation by acting as a thymic peptide degrading enzyme.

Herpesvirus saimiri immortalization of alpha beta and gamma delta human T-lineage cells derived from CD34+ intrathymic precursors in vitro.

Herpesvirus saimiri (HVS), an agent that can infect many human cell types, has been shown to immortalize selectively TCR alpha beta + CD3+ T lymphocytes. Human T cell precursors defined as CD34+CD3-CD4-CD8- were isolated from thymic samples and exposed to HVS in the presence of either IL-2 or IL-7. Cultures lacking the virus were non-viable by day 15. Test cultures, in contrast, showed a sustained proliferative activity lasting > 5 months, allowing the phenotypical and molecular analysis of the cellular progeny. In the presence of IL-7, TCR alpha beta + cells with three different phenotypes (mainly CD4+CD8-, but also CD4+CD8+ and CD4-CD8+) were immortalized, whereas no TCR gamma delta + cells were recovered. Kinetic studies showed that the expansion of immortalized TCR alpha beta + cells was preceded by a gradual loss of CD34+ cells followed by a transient accumulation of two distinct cell subsets: first CD1+CD4+CD3- cells and then CD4+CD8+ thymocytes. This resembles early phenotypic changes occurring during normal intrathymic T cell development. In the presence of IL-2, in contrast, only TCR gamma delta + cells were immortalized (mainly CD4-CD8+, but also CD4-CD8-). The results show that HVS can be used to read the CD3+ cellular outcome of T cell differentiation assays, including gamma delta + CD4-CD8+, gamma delta + CD4-CD8-, alpha beta + CD4+CD8-, alpha beta + CD4-CD8+ and alpha beta + CD4+CD8+ T cells. A clear role for different cytokines (IL-2 for gamma delta + cells, IL-7 for alpha beta + cells) in early T cell commitment was also apparent.

The development of T and non-T cell lineages from CD34+ human thymic precursors can be traced by the differential expression of CD44.

In addition to T-lineage cells, a small proportion of hematopoietic non-T cells are present in the human postnatal thymus. However, the origin of this minor non-T cell thymic compartment is presently unknown. In this study we have analyzed the developmental potential of the earliest human intrathymic precursors, characterized as CD34+ cells expressing intermediate levels of CD44. We show that these CD34+CD44int thymocytes cultured with interleukin 7 were able to develop simultaneously into both T- and non-T (monocytes and dendritic cells) -lineage cells. Both developmental pathways progress through a CD1+CD4+ intermediate stage, currently believed to be the immediate precursor of double positive thymocytes. However, separate progenitors for either T or non-T cells could be characterized within CD1+CD4+ thymocytes by their opposite expression of CD44. Downregulated levels of CD44 identified CD1+CD4+ T-lineage precursors, whereas CD44 upregulation occurred on CD1+CD4+ intermediates that later differentiated into non-T cells. Therefore, commitment of human early intrathymic precursors to either T or non-T cell lineages can be traced by the differential expression of the CD44 receptor.

Establishment and characterization of cloned human thymic epithelial cell lines. Analysis of adhesion molecule expression and cytokine production.

The thymic stromal microenvironment is required for the generation of immunocompetent T lymphocytes. However, the different thymic stromal cell types have not been fully characterized and their roles regarding T-cell development are not completely understood. To address the phenotypic characteristics of the epithelial component of the human thymic microenvironment as well as its functional involvement in T-cell development, we have established cloned thymic epithelial cell (TEC) lines from fetal and postnatal human thymuses by an explant technique, repeated subculture, and limiting dilution cloning. These cloned TEC lines were shown to be derived from cortical epithelium and to express a number of cell-surface molecules including CD40, major histocompatibility complex (MHC) HLA-ABC and HLA-DR antigens, homing-associated cell-adhesion molecule (H-CAM), intercellular adhesion molecule-1 (ICAM-1), leukocyte function-associated antigen 3 (LFA-3), and beta 1 subfamily integrins. Finally, both postnatal and fetal TEC clones were shown to produce interleukin-1 alpha (IL-1 alpha), IL-6, and IL-7. These well-defined cloned TEC lines may provide useful tools for the study of TEC biology and for the understanding of the precise role played by TEC in human T-cell development.

Putative prethymic T cell precursors within the early human embryonic liver: a molecular and functional analysis.

Hematopoietic cells present in the liver in early human fetal life were characterized by phenotypic analysis using a broad panel of monoclonal antibodies. Expression of very late antigen 4 and leukocyte function-associated antigen 3 cell adhesion receptors and 4F2 cell activation molecules was found in all fetal liver hematopoietic cells before acquisition of T cell-, B cell-, or myeloid-specific surface markers, and before the time of intrathymic colonization. Molecular studies showed that expression of the interleukin 2 receptor beta (IL-2R beta) also occurred in the embryonic liver at this early ontogenic stage. In contrast, no expression of IL-2R alpha or IL-2 transcripts was found in fetal liver cells, whereas transcription of the IL-4 gene was detected in a small fetal liver cell subset. Putative T cell precursors were identified among the hematopoietic fetal liver cells by the expression of genes encoding the gamma, delta, epsilon, and zeta invariant chains of the CD3-T cell receptor (TCR) complex. However, no transcription of the polymorphic alpha and beta TCR genes was detected. Functional in vitro assays further demonstrated that fetal liver hematopoietic cells from those early embryos were capable of proliferating in response to T cell growth factors, including IL-4 and IL-2. However, whereas IL-4-induced proliferation paralleled the appearance in vitro of CD45+CD7-CD4dull cells expressing the CD14 myeloid antigen, as well as of CD34+ primitive hematopoietic progenitors, differentiation into CD45+CD7+CD8+CD3- immature T cells was observed when using IL-2. Moreover, coculture with thymic epithelial cell monolayers provided additional evidence that early fetal liver hematopoietic cells may include very primitive T cell precursors, which were able to differentiate in vitro into TCR alpha/beta+ mature T cells. Therefore, our results indicate that, after triggering of the T cell-specific maturation program in primitive fetal liver hematopoietic progenitors, specific signals provided intrathymically by epithelial cells may fulfill the requirements to drive terminal differentiation of prethymically committed T cell precursors.

Involvement of the interleukin 4 pathway in the generation of functional gamma delta T cells from human pro-T cells.

We have used the technique of in situ hybridization to investigate the transcription of genes encoding the CD3 complex and the lymphokine interleukin 4 (IL-4) by human pro-T cells--i.e., cells that phenotypically resemble those T-cell precursors that colonize the thymus during early intrathymic development. CD1-2-3-4-7+8-45+ pro-T cells isolated from postnatal thymi via immunoselection with a panel of specific monoclonal antibodies are already committed to the T-cell lineage because most of them transcribe the genes encoding the delta and epsilon chains of the CD3 complex. About half of such pro-T cells synthesize IL-4 mRNA in the absence of any exogenous stimulation. Upon culture with IL-4, pro-T cells extensively proliferate and differentiate into functionally competent, mature gamma delta T cells expressing a T-cell receptor repertoire similar to that of gamma delta T cells that can be found in postnatal thymus. The IL-4 response of pro-T cells is not mediated by induction of the interleukin 2 (IL-2)-IL-2 receptor pathway and, unlike IL-2-driven T-cell differentiation, does not require the presence of stromal cells. Taken altogether, these findings suggest that an autocrine IL-4-mediated pathway might be implicated in early thymocyte differentiation--namely, in the generation of T cells bearing the gamma delta T-cell receptor.

Translocation of alkaline phosphatase during the activation of B cells.

The association of alkaline phosphatase (ALPase) with the cytoskeleton in lymphoid cells was investigated. Extracting cells with non-ionic detergents such as Triton, we determined that ALPase is present in the cytoskeletal fraction in fully differentiated B lymphocytes, X63 myeloma cells and Sp2/O hybridoma cells. During the course of B-lymphocyte activation, the ALPase shifted from a soluble to a Triton-insoluble form. Changes in the phosphorylation of Triton-insoluble proteins with molecular weights of 120, 100, 90, 75, 34 and 31 kDa were detected, coinciding with the appearance of the ALPase in this fraction. The possible role of ALPase in the differentiation of B cells is discussed.

The thousand and one ways of being a T cell.

Developing T cells diverge to several different effector classes, identified by their ability to express different set of genes. Aside from the genes encoding components of the TCR/CD3, there are many others that are activated and/or inactivated during T-cell development, but the functions of most of them are not yet defined. Despite the significant progress made, several fundamental aspects of the major steps of T-cell differentiation remains unclear. Thus, while long ago it was realized that the thymus is a central organ for the development of functionally competent T lymphocytes, it appears clear today that ectopic T-cell differentiation can also take place. In this article we review some of the molecules implicated in T-cell development and discuss some of the pathways that lead to mature T cells from precursors, both intra- and extra-thymically, as well as their implications in the acquisition of self tolerance.

Interleukin-2-dependent autocrine proliferation in T-cell development.

Activated T lymphocytes proliferate in response to interleukin-2 (IL-2), which binds to a specific high-affinity receptor (IL-2R). This consists of at least two noncovalently linked polypeptides, p55/IL-2R alpha (Tac) and p75/IL-2R beta. Both molecules bind IL-2 independently, with low and intermediate affinity respectively, but only IL-2R beta is thought to mediate IL-2 signal transduction. Although IL-2R beta seems to be constitutively expressed on resting T lymphocytes, the growth of these T cells is specifically induced by antigenic triggering by the T-cell receptor (TCR), which then results in the transcription of both IL-2 and IL-2R alpha genes. By contrast, activation of the IL-2/IL-2R pathway in the thymus seems to precede the appearance of the TCR, as IL-2R alpha is expressed on T-cell precursors lacking TCR. The basis for IL-2R expression by immature thymocytes, however, remains largely unknown. We show here that IL-2R alpha-negative T-cell precursors constitutively express IL-2R beta and produce their own IL-2. The IL-2/IL-2R beta interaction on these cells induces the expression of IL-2R alpha, leading to high-affinity IL-2R display and cellular proliferation. We suggest that this IL-2-dependent autocrine pathway of growth stimulation plays a key role in the intrathymic development of mature T cells.