Epstein-Barr virus (EBV) infects cells in latent or lytic forms, but the role of lytic infection in EBV- DLBCL). Animals infected with the control virus developed tumors more frequently than Z-KO virus-infected animals. Specific immune responses against EBV-infected B cellswere generated in mice infected with either the control virus or the Z-KO virus. In both cases, forms of viral latency (type I and type IIB) were observed that are less immunogenic than the highly transforming form (type III) commonly found in tumors of immunocompromised hosts, suggesting that immune pressure contributed to the outcome of the infection. These results point to an important role for lytic EBV infection in the development of B cell lymphomas in the context of an active host immune response.
Induced pluripotent stem cells (iPSCs) hold enormous potential for the development of personalized in vitro disease models, genomic health analyses, and autologous cell therapy. Here we describe the generation of T lymphocyte-derived iPSCs from small, clinically advantageous volumes of non-mobilized peripheral blood. These T-cell derived iPSCs (“TiPS”) retain a normal karyotype and genetic identity to the donor. They share common characteristics with human embryonic stem cells (hESCs) with respect to morphology, pluripotency-associated marker expression and capacity to generate neurons, cardiomyocytes, and hematopoietic progenitor cells. Additionally, they retain their characteristic T-cell receptor (TCR) gene rearrangements, a property which could be exploited for iPSC clone tracking and T-cell development studies. Reprogramming T-cells procured in a minimally invasive manner can be used to characterize and expand donor specific iPSCs, and control their differentiation into specific lineages.
The methodology to create induced pluripotent stem cells (iPSCs) affords the opportunity to generate cells specific to the individual providing the host tissue. However, existing methods of reprogramming as well as the types of source tissue have significant limitations that preclude the ability to generate iPSCs in a scalable manner from a readily available tissue source. We present the first study whereby iPSCs are derived in parallel from multiple donors using episomal, non-integrating, oriP/EBNA1-based plasmids from freshly drawn blood. Specifically, successful reprogramming was demonstrated from a single vial of blood or less using cells expressing the early lineage marker CD34 as well as from unpurified peripheral blood mononuclear cells. From these experiments, we also show that proliferation and cell identity play a role in the number of iPSCs per input cell number. Resulting iPSCs were further characterized and deemed free of transfected DNA, integrated transgene DNA, and lack detectable gene rearrangements such as those within the immunoglobulin heavy chain and T cell receptor loci of more differentiated cell types. Furthermore, additional improvements were made to incorporate completely defined media and matrices in an effort to facilitate a scalable transition for the production of clinic-grade iPSCs.
The failure of engraftment in human cases of in utero hematopoietic cell transplantation (IUHCT) in which no immunodeficiency exists suggests the presence of an unrecognized fetal immune barrier. A similar barrier in murine IUHCT appears to be dependent on the chimerism level and is poorly explained by a lack of T-cell tolerance induction. Therefore, we studied the effect of the chimerism level on engraftment and host natural killer (NK)-cell education in a murine model of IUHCT. The dose of transplanted cells was found to exhibit a strong correlation with both the engraftment rate and chimerism level. More specifically, a threshold level of initial chimerism (> 1.8%) was identified that predicted durable engraftment for allogeneic IUHCT, whereas low initial chimerism (< 1.8%) predicted a loss of engraftment. NK cells taken from chimeras above the "chimerism threshold" dis-
Generation of patient-specific induced pluripotent cells (iPSCs) holds great promise for regenerative medicine. Epstein-Barr virus immortalized lymphoblastoid B-cell lines (LCLs) can be generated from a minimal amount of blood and are banked worldwide as cellular reference material for immunologic or genetic analysis of pedigreed study populations.We report the generation of iPSCs from 2 LCLs (LCL-iPSCs) via a feeder-free episomal method using a cocktail of transcription factors and small molecules. LCL-derived iPSCs exhibited normal karyotype, expressed pluripotency markers, lost oriP/EBNA-1 episomal vectors, generated teratomas, retained donor identity, and differentiated in vitro into hema- IntroductionPatient-specific induced pluripotent stem cells (iPSCs) can serve as useful models for understanding the etiology of disease and facilitating the development of novel therapeutic interventions. 1 B cells represent a larger fraction of the peripheral blood mononuclear cell population (ϳ 20%) and can be transformed in vitro by Epstein-Barr virus (EBV) to generate lymphoblastoid cell lines (LCLs) using as little as 0.5 mL blood, 2 creating an unlimited proliferative source of cells for reprogramming trials. LCLs are a precious resource for immunologic, epidemiologic, and rare disease studies. A number of facilities manage collections of LCLs available internationally to researchers. 2 Thus, generating iPSCs from LCLs offers the advantage of working with minimal amounts of blood from living donors as well as frozen LCL collections banked worldwide.The capability to reprogram terminally differentiated cells depends on the inherent physiologic plasticity of the cell type. B lymphocytes can transdifferentiate to macrophages 3,4 or hematopoietic precursor cells (HPCs) after down-regulation of Pax5 expression. 4 Murine B cells have been reprogrammed to iPSCs via viral transduction of reprogramming factors with 5 and without Pax5 inhibition. 6 Generating iPSCs via nonviral, nonintegrating methods is appealing to generate clinically useful iPSCs. Recently, iPSCs have been generated by delivering the reprogramming factors via oriP/EBNA-1-based plasmids in fibroblasts and peripheral blood CD34 ϩ cells. 7,8 The inherent plasticity of B cells, their receptivity to oriP/EBNA-1 plasmids, ease of generating LCLs, and availability of banked LCL collections inspired our efforts to reprogram LCLs using oriP/EBNA-1-based vectors.LCL-derived iPSCs (LCL-iPSCs) demonstrated the characteristics of pluripotent stem cells, a normal karyotype, the genetic identity, and IgGH signature of the parental LCLs and lost expression of the episomal reprogramming genes as well as viral genes, leading to self-sustained LCL-iPSCs essentially free of exogenous reprogramming and viral elements. MethodsDetailed methods are included in supplemental Methods (available on the Blood Web site; see the Supplemental Materials link at the top of the online article). All animal experiments were conducted according to relevant national and international guideline...
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