112 resultados para engraftment
Resumo:
Prospective studies have shown rapid engraftment using granulocyte-colony-stimulating factor-mobilized peripheral blood stem cells (G-PBSCs) for allogeneic transplantation, though the risks for graft-versus-host disease (GVHD) may be increased. It was hypothesized that the use of G-CSF to prime bone marrow (GBM) would allow rapid engraftment without increased risk for GVHD compared with G-PBSC. Patients were randomized to receive G-BM or G-PBSCs for allogeneic stem cell transplantation. The study was designed (beta < .8) to detect a difference in the incidence of chronic GVHD of 33% ( < .05). The plan was to recruit 100 patients and to conduct an interim analysis when the 6-month follow-up point was reached for the first 50 patients. Fifty-seven consecutive patients were recruited (G-BM, n = 28; G-PBSC, n = 29). Patients in the G-PBSC group received 3-fold more CD34(+) and 9-fold more CD3(+) cells. Median times to neutrophil (G-BM, 16 days; G-PBSC, 14 days; P < .1) and platelet engraftment (G-BM, 14 days; G-PBSC, 12 days; P < .1) were similar. The use of G-PBSC was associated with steroid refractory acute GVHD (G-BM, 0%; G-PBSC, 32%; P < .001), chronic GVHD (G-BM, 22%; G-PBSC, 80%; P < .02), and prolonged requirement for immunosuppressive therapy (G-BM, 173 days; G-PBSC, 680 days; P < .009). Survival was similar for the 2 groups. Compared with G-PBSC the use of G-BM resulted in comparable engraftment, reduced severity of acute GVHD, and less subsequent chronic GVHD. (Blood. 2001;98:3186-3191) (C) 2001 by The American Society of Hematology.
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Cellular metabolism is emerging as a potential fate determinant in cancer and stem cell biology, constituting a crucial regulator of the hematopoietic stem cell (HSC) pool [1-4]. The extremely low oxygen tension in the HSC microenvironment of the adult bone marrow forces HSCs into a low metabolic profile that is thought to enable their maintenance by protecting them from reactive oxygen species (ROS). Although HSC quiescence has for long been associated with low mitochondrial activity, as testified by the low rhodamine stain that marks primitive HSCs, we hypothesized that mitochondrial activation could be an HSC fate determinant in its own right. We thus set to investigate the implications of pharmacologically modulating mitochondrial activity during bone marrow transplantation, and have found that forcing mitochondrial activation in the post-transplant period dramatically increases survival. Specifically, we examined the mitochondrial content and activation profile of each murine hematopoietic stem and progenitor compartment. Long-term-HSCs (LT-HSC, Lin-cKit+Sca1+ (LKS) CD150+CD34-), short-term-HSCs (ST-HSC, LKS+150+34+), multipotent progenitors (MPPs, LKS+150-) and committed progenitors (PROG, Lin-cKit+Sca1-) display distinct mitochondrial profiles, with both mitochondrial content and activity increasing with differentiation. Indeed, we found that overall function of the hematopoietic progenitor and stem cell compartment can be resolved by mitochondrial activity alone, as illustrated by the fact that low mitochondrial activity LKS cells (TMRM low) can provide efficient long-term engraftment, while high mitochondrial activity LKS cells (TMRM high) cannot engraft in lethally irradiated mice. Moreover, low mitochondrial activity can equally predict efficiency of engraftment within the LT-HSC and ST-HSC compartments, opening the field to a novel method of discriminating a population of transitioning ST-HSCs that retain long-term engraftment capacity. Based on previous experience that a high-fat bone marrow microenvironment depletes short-term hematopoietic progenitors while conserving their long-term counterparts [5], we set to measure HSC mitochondrial activation in high-fat diet fed mice, known to decrease metabolic rate on a per cell basis through excess insulin/IGF-1 production. Congruently, we found lower mitochondrial activation as assessed by flow cytometry and RT-PCR analysis as well as a depletion of the short-term progenitor compartment in high fat versus control chow diet fed mice. We then tested the effects of a mitochondrial activator known to counteract the negative effects of high fat diet. We first analyzed the in vitro effect on HSC cell cycle kinetics, where no significant change in proliferation or division time was found. However, HSCs responded to the mitochondrial activator by increasing asynchrony, a behavior that is thought to directly correlate with asymmetric division [6]. As opposed to high-fat diet fed mice, mice fed with the mitochondrial activator showed an increase in ST-HSCs, while all the other hematopoietic compartments were comparable to mice fed on control diet. Given the dependency on short-term progenitors to rapidly reconstitute hematopoiesis following bone marrow transplantation, we tested the effect of pharmacological mitochondrial activation on the recovery of mice transplanted with a limiting HSC dose. Survival 3 weeks post-transplant was 80% in the treated group compared to 0% in the control group, as predicted by faster recovery of platelet and neutrophil counts. In conclusion, we have found that mitochondrial activation regulates the long-term to short-term HSC transition, unraveling mitochondrial modulation as a valuable drug target for post-transplant therapy. Identification of molecular pathways accountable for the metabolically mediated fate switch is currently ongoing.
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Objective: Cultured autologous epidermal stem cells are used to treat extensively burned patients. However, engraftment is variable and it is fundamental to know 1- how many stem cells survive the stress of transplantation and 2- how many stem cells are needed for long-term self-renewal of the regenerated epidermis. Therefore, we have recapitulated the transplantation of autologous cultured epidermal stem cells in the minipig to investigate the cellular and molecular mechanisms involved in engraftment. Methods: Pig keratinocytes were cultivated according to the protocol used in human epidermal cell therapy. Human surgical procedures were adapted to the pig. Engraftment was evaluated clinically and by histology. The presence of epidermal stem cells was evaluated by clonal analysis. The presence of dividing or apoptotic cells was revealed by Ki67 and cleaved-caspase3 immunostaining respectively. Results: The skin of the pig closely resembles human skin and contains clonogenic keratinocytes that can be serially cultivated, cloned or transduced with a gene encoding GFP (Green Fluorescent Protein) by means of recombinant retroviral vectors. Cultured epidermal autografts can be successfully transplanted and their behavior recapitulate our observations in the human. Our experiments confirm that the number of epidermal stem cells rapidly decreases following transplantation. Most importantly, the regenerated epithelium contains dividing cells but little apoptotic cells, thus indicating that transplanted stem cells are pushed toward differentiation in response to the transplantation procedure. Conclusions: The minipig model is extremely useful to investigate stem cell fate during transplantation in human. Understanding engraftment is crucial to improve cell therapy and to design a more efficient generation of epidermal stem cell based products.
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Early revascularization of pancreatic islet cells after transplantation is crucial for engraftment, and it has been suggested that vascular endothelial growth factor-A (VEGF-A) plays a significant role in this process. Although VEGF gene therapy can improve angiogenesis, uncontrolled VEGF secretion can lead to vascular tumor formation. Here we have explored the role of temporal VEGF expression, controlled by a tetracycline (TC)-regulated promoter, on revascularization and engraftment of genetically modified beta cells following transplantation. To this end, we modified the CDM3D beta cell line using a lentiviral vector to promote secretion of VEGF-A either in a TC-regulated (TET cells) or a constitutive (PGK cells) manner. VEGF secretion, angiogenesis, cell proliferation, and stimulated insulin secretion were assessed in vitro. VEGF secretion was increased in TET and PGK cells, and VEGF delivery resulted in angiogenesis, whereas addition of TC inhibited these processes. Insulin secretion by the three cell types was similar. We used a syngeneic mouse model of transplantation to assess the effects of this controlled VEGF expression in vivo. Time to normoglycemia, intraperitoneal glucose tolerance test, graft vascular density, and cellular mass were evaluated. Increased expression of VEGF resulted in significantly better revascularization and engraftment after transplantation when compared to control cells. In vivo, there was a significant increase in vascular density in grafted TET and PGK cells versus control cells. Moreover, the time for diabetic mice to return to normoglycemia and the stimulated plasma glucose clearance were also significantly accelerated in mice transplanted with TET and PGK cells when compared to control cells. VEGF was only needed during the first 2-3 weeks after transplantation; when removed, normoglycemia and graft vascularization were maintained. TC-treated mice grafted with TC-treated cells failed to restore normoglycemia. This approach allowed us to switch off VEGF secretion when the desired effects had been achieved. TC-regulated temporal expression of VEGF using a gene therapy approach presents a novel way to improve early revascularization and engraftment after islet cell transplantation.
Resumo:
This trial was aimed to explore the efficacy of pegfilgrastim to accelerate neutrophil engraftment after stem cell autotransplant. Twenty patients with multiple myeloma and 20 with lymphoma received pegfilgrastim 6 mg on day +1. Forty cases treated with daily filgrastim starting at median day +7 (5-7), matched by age, sex, diagnosis, high-dose chemotherapy schedule, CD34 + cell-dose, and prior therapy lines, were used for comparison. Median time to neutrophil engraftment was 9.5 vs. 11 days for pegfilgrastim and filgrastim, respectively (p < 0.0001). Likewise, duration of neutropenia, intravenous antibiotic use, and hospitalization favored pegfilgrastim, while platelet engraftment, transfusion requirement, and fever duration were equivalent in both groups. No grade ≥ 3 toxicities were observed. Patients with lymphoma performed similarly to the entire cohort, while patients with myeloma showed faster neutrophil engraftment and shorter neutropenia but not shorter hospitalization and antibiotic use. The possibility of different outcomes for lymphoma and myeloma suggests that stratification by diagnosis may be useful in future phase III studies.
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PURPOSE: To evaluate the implant of human adipose derived stem cells (ADSC) delivered in hyaluronic acid gel (HA), injected in the subcutaneous of athymic mice. METHODS: Control implants -HA plus culture media was injected in the subcutaneous of the left sub scapular area of 12 athymic mice. ADSC implants: HA plus ADSC suspended in culture media was injected in the subcutaneous, at the contra lateral area, of the same animals. With eight weeks, animals were sacrificed and the recovered implants were processed for extraction of genomic DNA, and histological study by hematoxilin-eosin staining and immunufluorescence using anti human vimentin and anti von Willebrand factor antibodies. RESULTS: Controls: Not visualized at the injection site. An amorphous substance was observed in hematoxilin-eosin stained sections. Human vimentin and anti von Willebrand factor were not detected. No human DNA was detected. ADSC implants - A plug was visible at the site of injection. Fusiform cells were observed in sections stained by hematoxilin- eosin and both human vimentin and anti von Willebrand factor were detected by immunofluorescence. The presence of human DNA was confirmed. CONCLUSION: The delivery of human adipose derived stem cells in preparations of hyaluronic acid assured cells engraftment at the site of injection.
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Die akute myeloische Leukämie (AML) stellt ein äußerst heterogenes hämatologisches Krankheitsbild dar, welches durch die unkontrollierte Proliferation unausdifferenzierter und gleichzeitig nicht-funktioneller hämatopoetischer Zellen gekennzeichnet ist. Sowohl die unterschiedliche Zellherkunft, als auch zytogenetische Aberrationen und molekulargenetische Mutationen sorgen für eine große Diversität der Erkrankung. In der Therapie kommen Chemotherapeutika zum Einsatz, welche die Leukämie in eine komplette Remission bringen sollen. Der einzige kurative Ansatz besteht aus der allogenen hämatopoetischen Stammzelltransplantation. Abgesehen von den gewünschten kurativen Effekten, induzieren die im Transplantat befindlichen Spender-T-Lymphozyten ebenfalls die Transplantat-gegen-Wirt Erkrankung – eine Hauptursache von Mortalität und Morbidität nach erfolgter allogener hämatopoetischer Stammzelltransplantation. Da bei vielen Patienten aufgrund ihres Alters und ihrer Begleiterkrankungen eine Transplantation nicht tolerieren und da viele akuten myeloischen Leukämien trotz Chemotherapie progredient sind, schlägt die Therapie fehl und es gibt keine Chance auf Heilung. rnZur Erforschung der pathologischen Prozesse der akuten myeloischen Leukämie sowie für die Entwicklung neuer Therapiekonzepte bedarf es stabiler Tiermodelle, die die maligne Erkrankung des Menschen darstellen können. Ziel der vorliegenden Arbeit war die Untersuchung des Engraftments humaner primärer akuter myeloischer Leukämien in immuninkompetenten NSG-Mäusen. Die Untersuchungen zeigten, dass lediglich 61,5% der getesteten Leukämien in den Versuchstieren nach der Xenotransplantation nachgewiesen werden konnten. Die Gründe hierfür sind noch nicht ausreichend geklärt, beinhalten jedoch vermutlich Elemente des Homings, des Überlebens der Zelle in der fremden murinen Knochenmarknische, der Abwesenheit spezifischer humaner Wachstumsfaktoren, sowie intrinsische Unterschiede unter den verschiedenen Leukämieproben. Leukämien, die mit einer schlechten Prognose beim Patienten verbunden sind, wachsen in den Tieren stärker an. In den Versuchen konnte gezeigt werden, dass Leukämien mit einer Längenmutation des FLT3-Rezeptors eher häufiger in den NSG-Mäusen anwachsen, als wenn diese Mutation fehlt. Die Analyse der erstellten Wachstumskinetiken zweier Leukämien ergab, dass die Höhe des Engraftments in den einzelnen Organen sowohl von der transplantierten Zellmenge, als auch von der Höhe der angesetzten Versuchszeit abhängt. Zudem wurde ein Wachstum humaner T-Lymphozyten in den xenotransplantierten Mäusen beobachtet, welches sowohl mit einem höheren Engraftment der Leukämie in der Maus verbunden war, als auch mit einer höheren Tiersterblichkeit vergesellschaftet war.rnZum Verhindern dieses Wachstums wurden zwei unterschiedliche Methoden angewendet und miteinander verglichen. Dabei erzielten sowohl die medikamentöse Behandlung der Tiere mit dem Calcineurininhibitor Cyclosporin A, als auch die CD3-Depletion der Leukämie vor der Transplantation ein T-Zell-freies Wachstum in den Mäusen, letzteres erwies sich jedoch als das schonendere Verfahren. In den T-Zell-freien Tieren konnte bei dem Großteil der Tiere kein Engraftment im Knochenmark festgestellt werden, was auf einen positiven Einfluss der humanen T-Lymphozyten beim Vorgang des Engraftments schließen lässt.rn
Resumo:
Current research indicates that exogenous stem cells may accelerate reparative processes in joint disease but, no previous studies have evaluated whether bone marrow cells (BMCs) target the injured cranial cruciate ligament (CCL) in dogs. The objective of this study was to investigate engraftment of BMCs following intra-articular injection in dogs with spontaneous CCL injury. Autologous PKH26-labelled BMCs were injected into the stifle joint of eight client-owned dogs with CCL rupture. The effects of PKH26 staining on cell viability and PKH26 fluorescence intensity were analysed in vitro using a MTT assay and flow cytometry. Labelled BMCs in injured CCL tissue were identified using fluorescence microscopy of biopsies harvested 3 and 13 days after intra-articular BMC injection. The intensity of PKH26 fluorescence declines with cell division but was still detectable after 16 days. Labelling with PKH26 had no detectable effect on cell viability or proliferation. Only rare PKH26-positive cells were present in biopsies of the injured CCL in 3/7 dogs and in synovial fluid in 1/7 dogs. No differences in transforming growth factor-beta1, and interleukin-6 before and after BMC treatment were found and no clinical complications were noted during a 1 year follow-up period. In conclusion, BMCs were shown to engraft to the injured CCL in dogs when injected into the articular cavity. Intra-articular application of PKH26-labelled cultured mesenchymal stem cells is likely to result in higher numbers of engrafted cells that can be tracked using this method in a clinical setting.
Resumo:
Interactions between neoplastic cells and the host stroma play a role in both tumor cell migration and proliferation. Stromal cells provide structural support for malignant cells, modulate the tumor microenvironment, and influence phenotypic behavior as well as the aggressiveness of the malignancy. In response, the tumor provides growth factors, cytokines, and cellular signals that continually initiate new stromal reactions and recruit new cells into the microenvironment to further support tumor growth. Since growing tumors recruit local cells, as well as supplemental cells from the circulation, such as fibroblasts and endothelial precursors, the question arises if it would be possible to access circulating stromal cells to modify the tumor microenvironment for therapeutic benefits. One such cell type, mesenchymal stem cells (MSC), could theoretically be engrafted into stroma. MSC are pluripotent cells that have been shown to form stromal elements such as myofibroblasts, perivascular tissues and connective tissues. Several reports have demonstrated that MSC can incorporate into sites of wound healing and tissue repair, due to active tissue remodeling and local paracrine factors, and given the similarity between wound healing and the carcinoma induced stromal response one can hypothesize that MSC have the potential to be recruited to sites of tumor development. In addition, gene-modified MSC could be used as cellular vehicles to deliver gene products into tumors. My results indicate that MSC home to and participate in tumor stroma formation in ovarian tumor xenografts in mice. Additionally, once homed to tumor beds, MSC proliferate rapidly and integrate. My studies aim at understanding the fate of MSC in the tumor microenvironment, as well as utilizing them for cellular delivery of therapeutic genes into the stroma of ovarian carcinomas. ^
Resumo:
Epidermis is renewed by a population of stem cells that have been defined in vivo by slow turnover, label retention, position in the epidermis, and enrichment in β1 integrin, and in vitro by clonogenic growth, prolonged serial passage, and rapid adherence to extracellular matrix. The goal of this study is to determine whether clonogenic cells with long-term growth potential in vitro persist in vivo and give rise to a fully differentiated epidermis. Human keratinocytes were genetically labeled in culture by transduction with a retrovirus encoding the lacZ gene and grafted to athymic mice. Analysis of the cultures before grafting showed that 21.1–27.8% of clonogenic cells with the capacity for >30 generations were successfully transduced. In vivo, β-galactosidase (β-gal) positive cells participated in the formation of a fully differentiated epithelium and were detected throughout the 40-week postgraft period, initially as loosely scattered clusters and later as distinct vertical columns. Viable cells recovered from excised grafts were seeded at clonal densities and 23.3–33.3% of the colonies thus formed were β-gal positive. In addition, no evidence of transgene inactivation was obtained: all keratinocyte colonies recovered from grafted tissue that were β-gal negative also lacked the lacZ transgene. These results show that cells with long-term growth properties in vitro do indeed persist in vivo and form a fully differentiated epidermis, thereby exhibiting the properties of stem cells.
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Gene transduction of pluripotent human hematopoietic stem cells (HSCs) is necessary for successful gene therapy of genetic disorders involving hematolymphoid cells. Evidence for transduction of pluripotent HSCs can be deduced from the demonstration of a retroviral vector integrated into the same cellular chromosomal DNA site in myeloid and lymphoid cells descended from a common HSC precursor. CD34+ progenitors from human bone marrow and mobilized peripheral blood were transduced by retroviral vectors and used for long-term engraftment in immune-deficient (beige/nude/XIS) mice. Human lymphoid and myeloid populations were recovered from the marrow of the mice after 7-11 months, and individual human granulocyte-macrophage and T-cell clones were isolated and expanded ex vivo. Inverse PCR from the retroviral long terminal repeat into the flanking genomic DNA was performed on each sorted cell population. The recovered cellular DNA segments that flanked proviral integrants were sequenced to confirm identity. Three mice were found (of 24 informative mice) to contain human lymphoid and myeloid populations with identical proviral integration sites, confirming that pluripotent human HSCs had been transduced.
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