Here, we report the isolation of a human multipotent adipose-derived stem (hMADS) cell population from adipose tissue of young donors. hMADS cells display normal karyotype; have active telomerase; proliferate >200 population doublings; and differentiate into adipocytes, osteoblasts, and myoblasts. Flow cytometry analysis indicates that hMADS cells are CD44+, CD49b+, CD105+, CD90+, CD13+, Stro-1−, CD34−, CD15−, CD117−, Flk-1−, gly-A−, CD133−, HLA-DR−, and HLA-Ilow. Transplantation of hMADS cells into the mdx mouse, an animal model of Duchenne muscular dystrophy, results in substantial expression of human dystrophin in the injected tibialis anterior and the adjacent gastrocnemius muscle. Long-term engraftment of hMADS cells takes place in nonimmunocompromised animals. Based on the small amounts of an easily available tissue source, their strong capacity for expansion ex vivo, their multipotent differentiation, and their immune-privileged behavior, our results suggest that hMADS cells will be an important tool for muscle cell–mediated therapy.
Colitis involves immune cell–mediated tissue injuries, but the contribution of epithelial cells remains largely unclear. Vanin-1 is an epithelial ectoenzyme with a pantetheinase activity that provides cysteamine/cystamine to tissue. Using the 2,4,6-trinitrobenzene sulfonic acid (TNBS)-colitis model we show here that Vanin-1 deficiency protects from colitis. This protection is reversible by administration of cystamine or bisphenol A diglycidyl ether, a peroxisome proliferator-activated receptor (PPAR)γ antagonist. We further demonstrate that Vanin-1, by antagonizing PPARγ, licenses the production of inflammatory mediators by intestinal epithelial cells. We propose that Vanin-1 is an epithelial sensor of stress that exerts a dominant control over innate immune responses in tissue. Thus, the Vanin-1/pantetheinase activity might be a new target for therapeutic intervention in inflammatory bowel disease.
The differentiation of multipotent cells into undesirable lineages is a significant risk factor when performing cell therapy. In muscular diseases, myofiber loss can be associated with progressive fat accumulation that is one of the primary factors leading to decline of muscular strength. Therefore, to avoid any contribution of injected multipotent cells to fat deposition, we have searched for a highly myogenic but nonadipogenic muscle-derived cell population. We show that the myogenic marker CD56, which is the gold standard for myoblast-based therapy, was unable to separate muscle cells into myogenic and adipogenic fractions. Conversely, using the stem cell marker CD34, we were able to sort two distinct populations, CD34(+) and CD34(-), which have been thoroughly characterized in vitro and in vivo using an immunodeficient Rag2(-/-)gamma(c) (-/-) mouse model of muscle regeneration with or without adipose deposition. Our results demonstrate that both populations have equivalent capacities for in vitro amplification. The CD34(+) cells and CD34(-) cells exhibit equivalent myogenic potential, but only the CD34(-) population fails to differentiate into adipocytes in vitro and in vivo after transplantation into regenerative fat muscle. These data indicate that the muscle-derived cells constitute a heterogeneous population of cells with various differentiation potentials. The simple CD34 sorting allows isolation of myogenic cells with no adipogenic potential and therefore could be of high interest for cell therapy when fat is accumulated in diseased muscle.
Dendritic cells (DCs) loaded with killed allogeneic melanoma cells can cross-prime naive CD8+ T cells to differentiate into melanoma-specific CTLs in 3-wk cultures. In this study we show that DCs loaded with killed melanoma cells that were heated to 42°C before killing are more efficient in cross-priming of naive CD8+ T cells than DCs loaded with unheated killed melanoma cells. The enhanced cross-priming was demonstrated by several parameters: 1) induction of naive CD8+ T cell differentiation in 2-wk cultures, 2) enhanced killing of melanoma peptide-pulsed T2 cells, 3) enhanced killing of HLA-A*0201+ melanoma cells in a standard 4-h chromium release assay, and 4) enhanced capacity to prevent tumor growth in vitro in a tumor regression assay. Two mechanisms might explain the hyperthermia-induced enhanced cross-priming. First, heat-treated melanoma cells expressed increased levels of 70-kDa heat shock protein (HSP70), and enhanced cross-priming could be reproduced by overexpression of HSP70 in melanoma cells transduced with HSP70 encoding lentiviral vector. Second, hyperthermia resulted in the increased transcription of several tumor Ag-associated Ags, including MAGE-B3, -B4, -A8, and -A10. Thus, heat treatment of tumor cells permits enhanced cross-priming, possibly via up-regulation of both HSPs and tumor Ag expression.
Cumulative evidence indicates that MYC, one of the major downstream effectors of NOTCH1, is a critical component of T-cell acute lymphoblastic leukemia (T-ALL) oncogenesis and a potential candidate for targeted therapy. However, MYC is a complex oncogene, involving both fine protein dosage and cell-context dependency, and detailed understanding of MYC-mediated oncogenesis in T-ALL is still lacking. To better understand how MYC is interspersed in the complex T-ALL oncogenic networks, we performed a thorough molecular and biochemical analysis of MYC activation in a comprehensive collection of primary adult and pediatric patient samples. We find that MYC expression is highly variable, and that high MYC expression levels can be generated in a large number of cases in absence of NOTCH1/FBXW7 mutations, suggesting the occurrence of multiple activation pathways in addition to NOTCH1. IntroductionT-cell acute lymphoblastic leukemias (T-ALL) are malignant proliferations of T-cell precursors that represent 10% of pediatric and 25% of adult ALL. 1 Although treatment outcome has significantly improved in the last decade, ϳ 30% of patients relapse and remain of dismal prognosis, stressing the critical importance of gaining further insights on the molecular pathways controlling malignant transformation and drug resistance. However, a major obstacle in deciphering such pathways and implementing targeted therapy strategies resides in the fact that T-ALLs constitute a particularly heterogeneous and complex group of disease, resulting from numerous combinations of multigenic aberrations and oncogenic cooperation. 2 To date, the deregulation of Ͼ 30 distinct oncogenes and tumor suppressors (TS) has been reported, occurring through a large diversity of genomic aberrations and epigenetic deregulations. All such mechanisms are not functionally equivalent, 3 and distinct modes of oncogenic activation may drive different oncogenic processes, and generate distinct subtypes of prognostic significance. Some oncogenes (eg, TLX1, TAL1) appear to be mutually exclusive (type A) and delineate distinct subgroups of prognostic significance, correlating with specific stages of thymocyte developmental arrest (immature/DN, intermediate/ pre-␣, and mature/T-cell receptor␣ ϩ , respectively). [4][5] By contrast, other deregulations, such as loss of CDKN2A/p14ARF, or constitutive NOTCH1 activation, are found in a large proportion of cases and irrespective of subgroups (type B), 2 indicating a more universal role for these alterations in T-ALL pathogenesis, and pointing to attractive therapeutic targets. One such target is NOTCH1 and downstream pathways. Indeed, the key finding that Ͼ 50% of T-ALL cases display gain-of-function NOTCH1 mutations (NOTCH1 m ) initially held great promise for targeted therapy through the use of ␥-secretase inhibitors (GSI). 6 However, the frequent occurrence of GSI-resistance (GSI R ) has revealed an unsuspected complexity of the oncogenic network signaling downstream of NOTCH1. 6-8 Among the numerous target genes and pa...
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