Cell culture

About: Cell culture is a research topic. Over the lifetime, 133361 publications have been published within this topic receiving 5364150 citations. The topic is also known as: cell culture techniques.

Epstein-Barr virus-coded BHRF1 protein, a viral homologue of Bcl-2, protects human B cells from programmed cell death

Abstract: Epstein-Barr virus, a human herpesvirus that persists within the B-lymphoid system, can enhance the survival potential of latently infected B cells in vitro through up-regulation of the cellular survival protein Bcl-2. The possibility that an analogous effect is operative in lytically infected cells was suggested by the observation of distant sequence homology between an Epstein-Barr virus-coded early lytic cycle protein, BHRF1, and Bcl-2. Here we show by gene transfer that BHRF1 resembles Bcl-2 both in its subcellular localization and in its capacity to enhance B-cell survival. Thus confocal microscopic analysis of cells acutely cotransfected with BHRF1 and Bcl-2 expression vectors revealed substantial colocalization of the two proteins in the cytoplasm. In subsequent experiments, stable BHRF1 gene transfectants of Burkitt lymphoma cells paralleled Bcl-2 transfectants in their enhanced survival under conditions that induce cell death by apoptosis. Despite their limited sequence conservation, therefore, the two proteins appear to be functionally homologous. We suggest that BHRF1 provides an alternative, Bcl-2-independent, means of enhancing B-cell survival that may operate during the virus lytic cycle.

B7, a new member of the Ig superfamily with unique expression on activated and neoplastic B cells.

Abstract: The human B cell restricted activation antigen B7 identifies an in vivo primed subpopulation of B cells that demonstrate an accelerated response to triggers of B cell activation and proliferation. The cDNA encoding B7 was molecularly cloned by cDNA expression. The identity of the B7 cDNA was confirmed by indirect immunofluorescence and immunoprecipitation of a 44/54-kDa protein from B7 transfected COS cells. The sequence of the B7 polypeptide predicts a type I membrane protein of 262 amino acids with eight potential N-linked glycosylation sites in the extracellular region and a short, highly positively charged cytoplasmic tail. The extracellular region is homologous to the Ig gene superfamily and consists of two contiguous Ig-like domains. The first Ig domain has the characteristics of a variable domain and the second that of a constant region domain. B7 mRNA was detected only on anti-Ig activated B lymphocytes and not in other hematopoietic cells. After in vitro activation of B cells with anti-Ig, B7 mRNA was maximally expressed between 4 and 12 h with four RNA transcripts of 1.7, 2.9, 4.2, and 10 kb. The 2.9-kb mRNA predominated in in vitro-activated B cells whereas the 1.7-kb mRNA was most abundant in tumor cells of B cell origin. B7 expression was confined to several histologically defined subgroups of B cell malignancies. The majority of non-Hodgkin's lymphomas were B7+ whereas the B cell leukemias and circulating non-Hodgkin's lymphomas were generally negative. These results demonstrate that the B7 gene encodes a unique molecule belonging to the Ig superfamily and that B7 expression is limited to normal activated B cells and noncirculating B cell malignancies.

Characterization of the optimal culture conditions for clinical scale production of human mesenchymal stem cells.

Abstract: Mesenchymal stem cells (MSCs) are multipotent cells defined by multilineage potential, ease to gene modification, and immunosuppressive ability, thus holding promise for tissue engineering, gene therapy, and immunotherapy. They exhibit a unique in vitro expansion capacity, which, however, does not compensate for the very low percentage in their niches given the vast numbers of cells required for the relative studies. Taking into consideration the lack of a uniform approach for MSC isolation and expansion, we attempted in this study, by comparing various culture conditions, to identify the optimal protocol for the large-scale production of MSCs while maintaining their multilineage and immunosuppressive capacities. Our data indicate that, apart from the quality of fetal calf serum, other culture parameters, including basal medium, glucose concentration, stable glutamine, bone marrow mononuclear cell plating density, MSC passaging density, and plastic surface quality, affect the final outcome. Furthermore, the use of basic fibroblast growth factor (bFGF), the most common growth supplement in MSC culture media, greatly increases the proliferation rate but also upregulates HLA-class I and induces low HLA-DR expression. However, not only does this upregulation not elicit significant in vitro allogeneic T cell responses, but also bFGF-cultured MSCs exhibit enhanced in vivo immunosuppressive potential. Besides, addition of bFGF affects MSC multilineage differentiation capacity, favoring differentiation toward the osteogenic lineage and limiting neurogenic potential. In conclusion, in this report we define the optimal culture conditions for the successful isolation and expansion of human MSCs in high numbers for subsequent cellular therapeutic approaches.

Directed elimination of senescent cells by inhibition of BCL-W and BCL-XL.

Abstract: Senescent cells, formed in response to physiological and oncogenic stresses, facilitate protection from tumourigenesis and aid in tissue repair. However, accumulation of such cells in tissues contributes to age-related pathologies. Resistance of senescent cells to apoptotic stimuli may contribute to their accumulation, yet the molecular mechanisms allowing their prolonged viability are poorly characterized. Here we show that senescent cells upregulate the anti-apoptotic proteins BCL-W and BCL-XL. Joint inhibition of BCL-W and BCL-XL by siRNAs or the small-molecule ABT-737 specifically induces apoptosis in senescent cells. Notably, treatment of mice with ABT-737 efficiently eliminates senescent cells induced by DNA damage in the lungs as well as senescent cells formed in the epidermis by activation of p53 through transgenic p14(ARF). Elimination of senescent cells from the epidermis leads to an increase in hair-follicle stem cell proliferation. The finding that senescent cells can be eliminated pharmacologically paves the way to new strategies for the treatment of age-related pathologies.