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

Molecular mimicry between microbial and self-components is postulated as the mechanism that accounts for the antigen and tissue specificity of immune responses in postinfectious autoimmune diseases. Little direct evidence exists,and research in this area has focused principally on T cell-mediated,antipeptide responses,rather than on humoral responses to carbohydrate structures. Guillain-Barré syndrome,the most frequent cause of acute neuromuscular paralysis,occurs 1-2 wk after various infections,in particular,Campylobacter jejuni enteritis. Carbohydrate mimicry [Galbeta1-3GalNAcbeta1-4(NeuAcalpha2-3)Galbeta1-] between the bacterial lipooligosaccharide and human GM1 ganglioside is seen as having relevance to the pathogenesis of Guillain-Barré syndrome,and conclusive evidence is reported here. On sensitization with C. jejuni lipooligosaccharide,rabbits developed anti-GM1 IgG antibody and flaccid limb weakness. Paralyzed rabbits had pathological changes in their peripheral nerves identical with those present in Guillain-Barré syndrome. Immunization of mice with the lipooligosaccharide generated a mAb that reacted with GM1 and bound to human peripheral nerves. The mAb and anti-GM1 IgG from patients with Guillain-Barré syndrome did not induce paralysis but blocked muscle action potentials in a muscle-spinal cord coculture,indicating that anti-GM1 antibody can cause muscle weakness. These findings show that carbohydrate mimicry is an important cause of autoimmune neuropathy. View Publication

Imatinib mesylate has shown remarkable efficacy in the treatment of patients in the chronic phase of chronic myeloid leukemia. However,despite an overall significant hematological and cytogenetic response,imatinib therapy may favor the emergence of drug-resistant clones,ultimately leading to relapse. Some imatinib resistance mechanisms had not been fully elucidated yet. In this study we used sensitive and resistant sublines from a Bcr-Abl positive cell line to investigate the putative involvement of telomerase in the promotion of imatinib resistance. We showed that sensitivity to imatinib can be partly restored in imatinib-resistant cells by targeting telomerase expression,either by the introduction of a dominant-negative form of the catalytic protein subunit of the telomerase (hTERT) or by the treatment with all-trans-retinoic acid,a clinically used drug. Furthermore,we showed that hTERT overexpression favors the development of imatinib resistance through both its antiapoptotic and telomere maintenance functions. Therefore,combining antitelomerase strategies to imatinib treatment at the beginning of the treatment should be promoted to reduce the risk of imatinib resistance development and increase the probability of eradicating the disease. View Publication

The EphA2 receptor tyrosine kinase is overexpressed in many different types of human cancers where it functions as a powerful oncoprotein. Dramatic changes in the subcellular localization and function of EphA2 have also been linked with cancer,and in particular,unstable cancer cell-cell contacts prevent EphA2 from stably binding its ligand on the surface of adjoining cells. This change is important in light of evidence that ligand binding causes EphA2 to transmit signals that negatively regulate tumor cell growth and invasiveness and also induce EphA2 degradation. On the basis of these properties,we have begun to target EphA2 on tumor cells using agonistic antibodies,which mimic the consequences of ligand binding. In our present study,we show that a subset of agonistic EphA2 antibodies selectively bind epitopes on malignant cells,which are not available on nontransformed epithelial cells. We also show that such epitopes arise from differential cell-cell adhesions and that the stable intercellular junctions of nontransformed epithelial cells occlude the binding site for ligand,as well as this subset of EphA2 antibodies. Finally,we demonstrate that antibody targeting of EphA2 decreases tumor cell growth as measured using xenograft tumor models and found that the mechanism of antibody action relates to EphA2 protein degradation in vivo. Taken together,these results suggest new opportunities for therapeutic targeting of the large number of different cancers that express EphA2 in a manner that could minimize potential toxicities to normal cells. View Publication

DNA repair capacity of eukaryotic cells has been studied extensively in recent years. Mammalian cells have been engineered to overexpress recombinant nuclear DNA repair proteins from ectopic genes to assess the impact of increased DNA repair capacity on genome stability. This approach has been used in this study to specifically target O(6)-methylguanine DNA methyltransferase (MGMT) to the mitochondria and examine its impact on cell survival after exposure to DNA alkylating agents. Survival of human hematopoietic cell lines and primary hematopoietic CD34(+) committed progenitor cells was monitored because the baseline repair capacity for alkylation-induced DNA damage is typically low due to insufficient expression of MGMT. Increased DNA repair capacity was observed when K562 cells were transfected with nuclear-targeted MGMT (nucl-MGMT) or mitochondrial-targeted MGMT (mito-MGMT). Furthermore,overexpression of mito-MGMT provided greater resistance to cell killing by 1,3-bis (2-chloroethyl)-1-nitrosourea (BCNU) than overexpression of nucl-MGMT. Simultaneous overexpression of mito-MGMT and nucl-MGMT did not enhance the resistance provided by mito-MGMT alone. Overexpression of either mito-MGMT or nucl-MGMT also conferred a similar level of resistance to methyl methanesulfonate (MMS) and temozolomide (TMZ) but simultaneous overexpression in both cellular compartments was neither additive nor synergistic. When human CD34(+) cells were infected with oncoretroviral vectors that targeted O(6)-benzylguanine (6BG)-resistant MGMT (MGMT(P140K)) to the nucleus or the mitochondria,committed progenitors derived from infected cells were resistant to 6BG/BCNU or 6BG/TMZ. These studies indicate that mitochondrial or nuclear targeting of MGMT protects hematopoietic cells against cell killing by BCNU,TMZ,and MMS,which is consistent with the possibility that mitochondrial DNA damage and nuclear DNA damage contribute equally to alkylating agent-induced cell killing during chemotherapy. View Publication

Imatinib is a novel tyrosine kinase inhibitor used for the treatment of Philadelphia chromosome-positive leukemias and other malignancies. Side effects are mostly moderate; however,a dose-dependent hematologic toxicity affecting all hematopoietic lineages is observed clinically. The aim of this study was to investigate the effect of imatinib on normal hematopoietic stem and progenitor cells in vitro. A dose-dependent decrease in proliferation potential was found when CD34+ cells were expanded in serum-free medium supplemented with 6 growth factors and imatinib. Functionally,a decrease in colony-forming capacity was observed under increasing doses of imatinib. However,no such effect on more primitive cobblestone area-forming cells was detectable. Both withdrawal of stem cell factor from our expansion cultures or functional inhibition of c-kit led to a similar degree of inhibition of expansion,whereas the effect of imatinib was substantially greater at all dose levels tested. These data suggest a significant inhibitory effect of imatinib on normal CD34+ progenitor (but not stem) cells that is largely independent of c-kit signaling. View Publication

Identification of agents that target human leukemia stem cells is an important consideration for the development of new therapies. The present study demonstrates that rocaglamide and silvestrol,closely related natural products from the flavagline class of compounds,are able to preferentially kill functionally defined leukemia stem cells,while sparing normal stem and progenitor cells. In addition to efficacy as single agents,flavaglines sensitize leukemia cells to several anticancer compounds,including front-line chemotherapeutic drugs used to treat leukemia patients. Mechanistic studies indicate that flavaglines strongly inhibit protein synthesis,leading to the reduction of short-lived antiapoptotic proteins. Notably though,treatment with flavaglines,alone or in combination with other drugs,yields a much stronger cytotoxic activity toward leukemia cells than the translational inhibitor temsirolimus. These results indicate that the underlying cell death mechanism of flavaglines is more complex than simply inhibiting general protein translation. Global gene expression profiling and cell biological assays identified Myc inhibition and the disruption of mitochondrial integrity to be features of flavaglines,which we propose contribute to their efficacy in targeting leukemia cells. Taken together,these findings indicate that rocaglamide and silvestrol are distinct from clinically available translational inhibitors and represent promising candidates for the treatment of leukemia. View Publication

BACKGROUND Although studies have shown that Oct4,Sox2,Klf4,and c-Myc (OKSM)-mediated induced pluripotent stem cell (iPSC) technology sensitizes cancer cells to drugs,the potential risk of inserting c-Myc and random insertions of exogenous sequences into the genome persists. Several authors,including us,have presented microRNA (miRNA)-mediated reprogramming as an alternative approach. Herein,we evaluated the efficacy of miRNA-mediated reprogramming on hepatocellular carcinoma (HCC) cells. METHODS Among three miRNAs (miR-200c,miR-302s,and miR-369s) that were previously presented for miRNA-mediated reprogramming,miR-302 was expressed at low levels in HCC cells. After transfecting three times with miR-302,the cells were incubated in ES medium for 3 weeks and then characterized. RESULTS iPSC-like spheres were obtained after the 3-week incubation. Spheres presented high NANOG and OCT4 expression,low proliferation,high apoptosis,low epithelial-mesenchymal transition marker expression (N-cadherin,TGFBR2),and sensitization to drugs. Several miRNAs were changed (e.g.,low oncomiR miR-21,high miR-29b). cMyc was decreased,and methylation was elevated on histone 3 at lysine 4 (H3K4). Differentiated cells expressed markers of each germ layer (GFAP,FABP4,and ALB). AOF2 (also known as LSD1 or KDM1),one of the targets for miR-302,was repressed in iPSC-like-spheres. Silencing of AOF2 resulted in similar features of iPSC-like-spheres,including cMyc down-regulation and H3K4 methylation. In drug-resistant cells,sensitization was achieved through miR-302-mediated reprogramming. CONCLUSIONS miR-302-mediated iPSC technology reprogrammed HCC cells and improved drug sensitivity through AOF2 down-regulation,which caused H3K4 methylation and c-Myc repression. View Publication