搜索结果: 'methocult media formulations for mouse hematopoietic cells serum containing'

Two critical concerns in clinical cord blood transplantation are the initial time to engraftment and the subsequent restoration of immune function. These studies measured the impact of progenitor cell dose on both the pace and strength of hematopoietic reconstitution by transplanting nonobese diabetic/severe combined immunodeficiency/interleukin-2 receptor-gamma-null (NSγ) mice with lineage-depleted aldehyde dehydrogenase-bright CD34(+) human cord blood progenitors. The progress of each transplant was monitored over an extended time course by repeatedly analyzing the peripheral blood for human hematopoietic cells. In vivo human hematopoietic development was complete. After long-term transplantation assays (≥ 19 weeks),human T-cell development was documented within multiple tissues in 16 of 32 NSγ mice. Human T-cell differentiation was active within NSγ thymuses,as documented by the presence of CD4(+) CD8(+) T-cell progenitors as well as T-cell receptor excision circles. It is important to note that although myeloid and B-cell engraftment was detected as early as 4 weeks after transplantation,human T-cell development was exclusively late onset. High progenitor cell doses were associated with a robust human hematopoietic chimerism that accelerated both initial time to engraftment and subsequent T-cell development. At lower progenitor cell doses,the chimerism was weak and the human hematopoietic lineage development was frequently incomplete. View Publication

The coding region determinant-binding protein/insulin-like growth factor II mRNA-binding protein (CRD-BP/IMP1) is an RNA-binding protein specifically recognizing c-myc,leader 3' IGF-II and tau mRNAs,and the H19 RNA. CRD-BP/IMP1 is predominantly expressed in embryonal tissues but is de novo activated and/or overexpressed in various human neoplasias. To address the question of whether CRD-BP/IMP1 expression characterizes certain cell types displaying distinct proliferation and/or differentiation properties (i.e. stem cells),we isolated cell subpopulations from human bone marrow,mobilized peripheral blood,and cord blood,all sources known to contain stem cells,and monitored for its expression. CRD-BP/IMP1 was detected only in cord blood-derived CD34(+) stem cells and not in any other cell type of either adult or cord blood origin. Adult BM CD34(+) cells cultured in the presence of 5'-azacytidine expressed de novo CRD-BP/IMP1,suggesting that epigenetic modifications may be responsible for its silencing in adult non-expressing cells. Furthermore,by applying the short interfering RNA methodology in MCF-7 cells,we observed,subsequent to knocking down CRD-BP/IMP1,decreased c-myc expression,increased IGF-II mRNA levels,and reduced cell proliferation rates. These data 1) suggest a normal role for CRD-BP/IMP1 in pluripotent stem cells with high renewal capacity,like the CB CD34(+) cells,2) indicate that altered methylation may directly or indirectly affect its expression in adult cells,3) imply that its de novo activation in cancer cells may affect the expression of c-Myc and insulin-like growth factor II,and 4) indicate that the inhibition of CRD-BP/IMP1 expression might affect cancer cell proliferation. View Publication

Human cord blood (CB)-derived CD133+ cells carry characteristics of primitive hematopoietic cells and proffer an alternative for CD34+ cells in hematopoietic stem cell (HSC) transplantation. To characterize the CD133+ cell population on a genetic level,a global expression analysis of CD133+ cells was performed using oligonucleotide microarrays. CD133+ cells were purified from four fresh CB units by immunomagnetic selection. All four CD133+ samples showed significant similarity in their gene expression pattern,whereas they differed clearly from the CD133- control samples. In all,690 transcripts were differentially expressed between CD133+ and CD133- cells. Of these,393 were increased and 297 were decreased in CD133+ cells. The highest overexpression was noted in genes associated with metabolism,cellular physiological processes,cell communication,and development. A set of 257 transcripts expressed solely in the CD133+ cell population was identified. Colony-forming unit (CFU) assay was used to detect the clonal progeny of precursors present in the studied cell populations. The results demonstrate that CD133+ cells express primitive markers and possess clonogenic progenitor capacity. This study provides a gene expression profile for human CD133+ cells. It presents a set of genes that may be used to unravel the properties of the CD133+ cell population,assumed to be highly enriched in HSCs. View Publication

Bone marrow-derived mesenchymal stem cells (MSC) have been defined as primitive,undifferentiated cells,capable of self-renewal and with the ability to give rise to different cell lineages,including adipocytes,osteocytes,fibroblasts,chondrocytes,and myoblasts. MSC are key components of the hematopoietic microenvironment. Several studies,including some from our own group,suggest that important quantitative and functional alterations are present in the stroma of patients with myelodysplasia (MDS). However,in most of such studies the stroma has been analyzed as a complex network of different cell types and molecules,thus it has been difficult to identify and characterize the cell(s) type(s) that is (are) altered in MDS. In the present study,we have focused on the biological characterization of MSC from MDS. As a first approach,we have quantified their numbers in bone marrow,and have worked on their phenotypic (morphology and immunophenotype) and cytogenetic properties. MSC were obtained by a negative selection procedure and cultured in a MSC liquid culture medium. In terms of morphology,as well as the expression of certain cell markers,no differences were observed between MSC from MDS patients and those derived from normal marrow. In both cases,MSC expressed CD29,CD90,CD105 and Prolyl-4-hydroxylase; in contrast,they did not express CD14,CD34,CD68,or alkaline phosphatase. Interestingly,in five out of nine MDS patients,MSC developed in culture showed cytogenetic abnormalities,usually involving the loss of chromosomal material. All those five cases also showed cytogenetic abnormalities in their hematopoietic cells. Interestingly,in some cases there was a complete lack of overlap between the karyotypes of hematopoietic cells and MSC. To the best of our knowledge,the present study is the first in which a pure population of MSC from MDS patients is analyzed in terms of their whole karyotype and demonstrates that in a significant proportion of patients,MSC are cytogenetically abnormal. Although the reason of this is still unclear,such alterations may have an impact on the physiology of these cells. Further studies are needed to assess the functional integrity of MDS-derived MSC. View Publication

Human umbilical cord blood (UCB) contains high numbers of endothelial progenitors cells (EPCs) characterized by coexpression of CD34 and CD133 markers. Prior studies have shown that CD34+/CD133+ EPCs from the cord or peripheral blood (PB) can give rise to endothelial cells and induce angiogenesis in ischemic tissues. In the present study,it is shown that freshly isolated human cord blood CD34+ cells injected into ischemic adductor muscles gave rise to endothelial and,unexpectedly,to skeletal muscle cells in mice. In fact,the treated limbs exhibited enhanced arteriole length density and regenerating muscle fiber density. Under similar experimental conditions,CD34- cells did not enhance the formation of new arterioles and regenerating muscle fibers. In nonischemic limbs CD34+ cells increased arteriole length density but did not promote formation of new muscle fibers. Endothelial and myogenic differentiation ability was maintained in CD34+ cells after ex vivo expansion. Myogenic conversion of human cord blood CD34+ cells was also observed in vitro by coculture onto mouse myoblasts. These results show that human cord blood CD34+ cells differentiate into endothelial and skeletal muscle cells,thus providing an indication of human EPCs plasticity. The full text of this article is available online at http://www.circresaha.org. View Publication

BACKGROUND: Excessive maturation of hematopoietic cells leads to a reduction of long-term proliferative capability during cord blood (CB) expansion. In this study,we report the effects of anit-CD52 (Alemtuzumab,Campath) on both short- and long-term ex vivo expansion of CB hematopoietic stem cells (HSC) by evaluating the potential role of Alemtuzumab in preserving the repopulating capability in CB HSC and nonlymphoid progenitors. METHODS: Ex vivo expansion experiments were carried out using freshly purified CB CD34(+)cells in StemSpantrade mark SFEM medium in the presence of stem cell factor,Flt3-Ligand and thrombopoietin at 50 ng/ml. Alemtuzumab (10 microg/ml) was used to deplete CD52(+) cells during the cultures. Flow cytometry was used to monitor CB HSC and their differentiation. Colony forming unit (CFU) assays and long term culture-initiating cell (LTC-IC) assays were performed on cells obtained from day 0 (before culture) and day 14 after cultures. Secondary cultures was performed using CD34(+) cells isolated at 35 days from primary cultures and further cultured in StemSpantrade mark SFEM medium for another 14 days to confirm the long term effect of alemtuzumab in liquid cultures. RESULTS: Compared to cytokines alone,addition of alemtuzumab resulted in a significant increase in total nucleated cells,absolute CD34(+) cells,myeloid and megakaryocytic progenitors,multi-lineage and myeloid CFU and LTC-IC. CONCLUSION: The results from current study suggested that the use of alemtuzumab for ex vivo expansion of CBHSC maybe advantageous. Our findings may improve current technologies for CBHSC expansion and increase the availability of CB units for transplantation. However,in vivo studies using animal models are likely needed in further studies to test the hematopoietic effects using such expanded CB products. View Publication

Umbilical cord blood (UCB) preparation needs to be optimized in order to develop more simplified procedures for volume reduction,as well as to reduce the amount of contaminating cells within the final stem cell transplant. We evaluated a novel filter device (StemQuick((TM))E) and compared it with our routine buffy coat (BC) preparation procedure for the enrichment of hematopoietic progenitor cells (HPCs). Two groups of single or pooled UCB units were filtered (each n = 6),or equally divided in two halves and processed by filtration and BC preparation in parallel (n = 10). The engraftment capacity of UCB samples processed by whole blood (WB) preparation was compared with paired samples processed by filtration in the nonobese diabetic/severe combined immunodeficient (NOD/SCID) mouse animal model. Filtration of UCB units in the two groups with a mean volume of 87.8 and 120.7 ml,respectively,and nucleated cell (NC) content of 9.7 and 23.8 x 10(8) resulted in a sufficient mean cell recovery for mononucleated cells ([MNCs] 74.2%-77.5%),CD34(+) cells (76.3%-79.0%),and colony-forming cells (64.1%-86.3%). Moreover,we detected a relevant depletion of the transplants for RBCs (89.2%-90.0%) and platelets ([PLTs] 77.5%-86.1%). In contrast,the mean depletion rate using BC processing proved to be significantly different for PLTs (10%,p = 0.03) and RBCs (39.6%,p textless 0.01). The NC composition showed a highly significant increase in MNCs and a decrease in granulocytes after filtration (p textless 0.01),compared with a less significant MNC increase in the BC group (p textless 0.05). For mice transplanted with WB-derived progenitors,we observed a mean of 15.3% +/- 15.5% of human CD45(+) cells within the BM compared with 19.9% +/- 16.8% for mice transplanted with filter samples (p = 0.03). The mean percentage of human CD34(+) cells was 4.2% +/- 3.1% for WB samples and 4.5% +/- 3.2% for filter samples (p = 0.68). As the data of NOD/SCID mice transplantation demonstrated a significant engraftment capacity of HPCs processed by filtration,no negative effect on the engraftment potential of filtered UCB cells versus non-volume-reduced cells from WB transplants was found. The StemQuick((TM))E filter devices proved to be a useful tool for Good Manufacturing Practices conform enrichment of HPCs and MNCs out of UCB. Filtration enables a quick and standardized preparation of a volume-reduced UCB transplant,including a partial depletion of granulocytes,RBCs,and PLTs without the need for centrifugation. Therefore,it seems very probable that filter-processed UCB transplants will also result in sufficient hematopoietic reconstitution in humans. View Publication