BackgroundA new class of non-coding RNAs, known as long non-coding RNAs (lncRNAs), has been recently described. These lncRNAs are implicated to play pivotal roles in various molecular processes, including development and oncogenesis. Gene expression profiling of human B-ALL samples showed differential lncRNA expression in samples with particular cytogenetic abnormalities. One of the most promising lncRNAs identified, designated B-ALL associated long RNA-6 (BALR-6), had the highest expression in patient samples carrying the MLL rearrangement, and is the focus of this study.ResultsHere, we performed a series of experiments to define the function of BALR-6, including several novel splice forms that we identified. Functionally, siRNA-mediated knockdown of BALR-6 in human B-ALL cell lines caused reduced cell proliferation and increased cell death. Conversely, overexpression of BALR-6 isoforms in both human and mouse cell lines caused increased proliferation and decreased apoptosis. Overexpression of BALR-6 in murine bone marrow transplantation experiments caused a significant increase in early hematopoietic progenitor populations, suggesting that its dysregulation may cause developmental changes. Notably, the knockdown of BALR-6 resulted in global dysregulation of gene expression. The gene set was enriched for leukemia-associated genes, as well as for the transcriptome regulated by Specificity Protein 1 (SP1). We confirmed changes in the expression of SP1, as well as its known interactor and downstream target CREB1. Luciferase reporter assays demonstrated an enhancement of SP1-mediated transcription in the presence of BALR-6. These data provide a putative mechanism for regulation by BALR-6 in B-ALL.ConclusionsOur findings support a role for the novel lncRNA BALR-6 in promoting cell survival in B-ALL. Furthermore, this lncRNA influences gene expression in B-ALL in a manner consistent with a function in transcriptional regulation. Specifically, our findings suggest that BALR-6 expression regulates the transcriptome downstream of SP1, and that this may underlie the function of BALR-6 in B-ALL.Electronic supplementary materialThe online version of this article (doi:10.1186/s12943-015-0485-z) contains supplementary material, which is available to authorized users.
Background Antibody-secreting cells are terminally differentiated B cells that play a critical role in humoral immunity through immunoglobulin secretion along with possessing the potential to be long-lived. It is now appreciated that antibody-secreting cells regulate multiple aspects of biology through the secretion of various cytokines. In this regard, intracellular flow cytometry is a key tool used to assess the presence of intracellular proteins such as cytokines and transcription factors. Methods Paraformaldehyde plus saponin or the eBioscience Foxp3/Transcription Factor Staining Buffer Set were used to evaluate the non-specific intracellular retention of phycoerythrin-containing antibody conjugates by antibody-secreting cells. Results We showed that the use of phycoerythrin-containing antibody conjugates led to a false interpretation of antibody-secreting cell intracellular protein expression compared to other cell types. This was mainly due to the inappropriate retention of these antibodies specifically within antibody-secreting cells. Furthermore, we demonstrated how to reduce this retention which allowed for a more accurate comparison of intracellular protein expression between antibody-secreting cells and other cell types such as B lymphocytes. Using this methodology, our data revealed that spleen antibody-secreting cells expressed Toll-like receptor 7 as well as the pro-form of the inflammatory cytokine interleukin-1β. Conclusion Increasing the number of centrifugation steps performed on antibody-secreting cells post-fixation leads to inappropriate retention of phycoerythrin-containing antibody conjugates during intracellular flow cytometry.
Antibody-secreting cells are essential contributors to the humoral response. This is due to multiple factors which include: 1) the ability to secrete thousands of antibodies per second, 2) the ability to regulate the immune response and 3) the potential to be long-lived. Not surprisingly, these cells can be found in numerous sites within the body which include organs that directly interface with potential pathogens (e.g., gut) and others that provide long-term survival niches (e.g., bone marrow). Even though antibody-secreting cells were first identified in the thymus of both humans and rodents in the 1960s, if not earlier, only recently has this population begun to be extensively investigated. In this article, we provide an update regarding the current breath of knowledge pertaining to thymus antibody-secreting cells and discuss the potential roles of these cells and their impact on health.
Antibody-secreting cells are terminally differentiated B cells that play a critical role in humoral immunity through immunoglobulin secretion along with possessing the potential to be long-lived. It is now appreciated that antibody-secreting cells regulate multiple aspects of biology through the secretion of various cytokines. In this regard, intracellular flow cytometry is a key tool used to assess the presence of intracellular proteins such as cytokines and transcription factors. Here, we showed that the use of phycoerythrin-containing antibody conjugates led to a false interpretation of antibody-secreting cell intracellular protein expression compared to other cell types. This was mainly due to the inappropriate retention of these antibodies specifically within antibody-secreting cells. Furthermore, we demonstrated how to reduce this retention which allowed for a more accurate comparison of intracellular protein expression between antibody-secreting cells and other cell types such as B lymphocytes. Using this methodology, our data revealed that spleen antibody-secreting cells expressed Toll-like receptor 7 as well as the pro-form of the inflammatory cytokine interleukin-1β.
In humans and mice, sex dichotomies exist in regards to physiological immune responses as well as pathological autoimmune responses. However, very little information exists in regards to how sex patterns the production and function of antibody-secreting plasmablast (PB) and plasma cell (PC) populations. Using the Prdm1-enhanced yellow fluorescent (eYFP) reporter mouse strain, we compared the percentages and numbers of PBs and PCs in the bone marrow (BM), spleen (SPL) and thymus (THY) of young (3 months old) female and male mice. While PB/PC generation was equivalent in the BM and SPL of both sexes, the female THY had significantly increased percentages and numbers of both PBs and PCs when compared to males. This correlated with the overall increase in thymopoiesis present in females. Characterization of THY PBs/PCs demonstrated increased expression of canonical B cell activation markers such as CD69 and MHC II when compared to their BM and SPL counterparts. In some aspects, these differences were sex-based in origin. αCD45 intravenous antibody labeling suggested that THY PBs/PCs were locally generated and not a consequence of immigration from the periphery. As such, female THY demonstrated increased numbers of a germinal center B (GCB) cell-like population expressing both GL7 and CD95(Fas). THY B cells have been previously shown to participate in the regulation of T cell selection and we hypothesized that THY PBs/PCs would be generated in a T cell dependent manner. Indeed, administration of αCD40L blocking antibodies ablated THY GCB, PB and to some extent PC production. In summary, female mice are skewed towards increased THY PB/PC generation. The production of these cells happens locally and is dependent on CD40L-based T cell interactions.
Antibody-secreting cells (ASCs) are key contributors to humoral immunity through immunoglobulin production and the potential to be long-lived. ASCs have been recently identified in the thymus (THY) which is of interest as autoreactive THY B cells regulate T cell tolerance. Here, we showed that the young female THY was skewed towards higher production of ASCs relative to males. However, these differences disappeared with age. Intravenous labeling combined with blockade of CD154(CD40L) suggested that THY ASCs were generated in situ in a T cell dependent fashion. Single cell RNA-sequencing revealed that THY ASCs possessed a transcriptional signature indicative of interferon signaling and activation. Flow cytometry confirmed that THY ASCs had increased levels of Toll-like receptor 7 as well as the activation markers CD69 and major histocompatibility class II. Overall, THY ASCs are a unique population that require further investigation to fully appreciate their biological significance.
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