Human B-lymphoblastoid Cell Line Research Articles

Hotspot DNA Methyltransferase 3A (DNMT3A) and Isocitrate Dehydrogenase 1 and 2 (IDH1/2) Mutations in Acute Myeloid Leukemia and Their Relevance as Targets for Immunotherapy.

DNA methyltransferase 3A (DNMT3A) and isocitrate dehydrogenase 1 and 2 (IDH1/2) are genes involved in epigenetic regulation, each mutated in 7-23% of patients with acute myeloid leukemia. Here, we investigated whether hotspot mutations in these genes encode neoantigens that can be targeted by immunotherapy. Five human B-lymphoblastoid cell lines expressing common HLA class I alleles were transduced with a minigene construct containing mutations that often occur in DNMT3A or IDH1/2. From these minigene-transduced cell lines, peptides were eluted from HLA class I alleles and analyzed using tandem mass spectrometry. The resulting data are available via ProteomeXchange under the identifier PXD050560. Mass spectrometry revealed an HLA-A*01:01-binding DNMT3AR882H peptide and an HLA-B*07:02-binding IDH2R140Q peptide as potential neoantigens. For these neopeptides, peptide-HLA tetramers were produced to search for specific T-cells in healthy individuals. Various T-cell clones were isolated showing specific reactivity against cell lines transduced with full-length DNMT3AR882H or IDH2R140Q genes, while cell lines transduced with wildtype genes were not recognized. One T-cell clone for DNMT3AR882H also reacted against patient-derived acute myeloid leukemia cells with the mutation, while patient samples without the mutation were not recognized, thereby validating the surface presentation of a DNMT3AR882H neoantigen that can potentially be targeted in acute myeloid leukemia via immunotherapy.

Occupational health effect of TCE exposure: Experiment evidence of gene-environment interaction in hypersensitivity reaction

BackgroundRecently, Trichloroethylene (TCE) induced TCE hypersensitivity syndrome (THS) has attracted the attention of many researchers in the field of environmental and occupational health. Studies have revealed that Human leukocyte antigen (HLA) polymorphisms were the important genetic determinants of the diseases, but the potential molecular mechanism remains unclear. ObjectiveThis study aimed to investigate the association between THS and HLA at the molecular level. MethodWe chose the human B-lymphoblastoid cell line Hmy2.C1R transfected with cDNA of HLA-B*13:01 and HLA-B*13:02 to analyze the characteristics of HLA-B-binding peptides and investigate the effect of TCE on the binding affinity of peptides to the HLA-B molecules. Further, the mathematical model was used to identify the possible interaction between TCE and HLA-B*13:01 or HLA-B*13:02 molecule. Results54 HLA-B*13:01-binding peptides and 85 HLA-B*13:02-binding peptides were identified. Comparing the protein sequences of HLA-B*13:01 and HLA-B*13:02, amino acids were different at positions 94, 95 and 97. The results of the binding affinity of self-peptides to HLA molecules in the presence of TCE showed that TCE significantly decreased the binding affinity of peptides to HLA-B*13:01 only, but did not affect that of HLA-B*13:02. Molecular docking model showed that there was a unique high-affinity binding mode between TCE and HLA-B*13:01 (but not HLA-B*13:02), and the binding site located in the region of F pocket, suggesting that the unique structure of the F pocket of HLA-B*13:01 might provide the possibility of binding TCE. The pathogenesis of interaction between HLA-B*13:01 and TCE might belong to the model of the alteration of the HLA-presented self-peptide repertoire. DiscussionThis study explored the molecular mechanism of the association between THS and HLA-B*13:01, and had important implications for understanding the role of gene-environment interaction in the development of complex environment-related diseases.

Glucocorticoids mediate transcriptome-wide alternative polyadenylation: Potential mechanistic and clinical implications.

Alternative polyadenylation (APA) is a common genetic regulatory mechanism that generates distinct 3' ends for RNA transcripts. Changes in APA have been associated with multiple biological processes and disease phenotypes. However, the role of hormones and their drug analogs in APA remains largely unknown. In this study, we investigated transcriptome-wide the impact of glucocorticoids on APA in 30 human B-lymphoblastoid cell lines. We found that glucocorticoids could regulate APA for a subset of genes, possibly by changing the expression of 142 RNA-binding proteins, some with known APA-regulating properties. Interestingly, genes with glucocorticoid-mediated APA were enriched in viral translation-related pathways, while genes with glucocorticoid-mediated expression were enriched in interferon and interleukin pathways, suggesting that glucocorticoid-mediated APA might result in functional consequences distinct from gene expression. For example, glucocorticoids, a pharmacotherapy for severe COVID-19, were found to change the APA but not the expression of LY6E, an important antiviral inhibitor in coronavirus diseases. Glucocorticoid-mediated APA was also cell-type-specific, suggesting an action of glucocorticoids that may be unique to immune regulation. We also observed evidence for genotype-dependent glucocorticoid-mediated APA (referred to as pharmacogenomic-alterative polyadenylation quantitative trait loci), providing potential functional mechanisms for a series of common genetic variants that had previously been associated with immune disorders, but without a clear mechanism. In summary, this study reports a series of observations regarding the impact of glucocorticoids on APA, raising the possibility that this mechanism might have implications for both disease pathophysiology and drug therapy.

The expression of Phase II drug-metabolizing enzymes in human B-lymphoblastoid TK6 cells

In vitro genotoxicity testing plays an important role in chemical risk assessment. The human B-lymphoblastoid cell line TK6 is widely used as a standard cell line for regulatory safety evaluations. Like many other mammalian cell lines, TK6 cells have limited metabolic capacity; therefore, usually require a source of exogenous metabolic activation for use in genotoxicity testing. Previously, we developed a set of TK6-derived cell lines that individually express one of fourteen cytochrome P450s (CYPs). In the present study, we surveyed a panel of major Phase II drug-metabolizing enzymes to characterize their baseline expression in TK6 cells. These results may serve as a reference enzymatic profile of this commonly used cell line.

Functional Similarity of Proposed Biosimilar ABP 798 with Rituximab

▪BackgroundRegulatory guidelines governing the development of biosimilars require that proposed biosimilars undergo comprehensive structural and functional characterization prior to the initiation of clinical investigation. ABP 798 is being developed as a biosimilar to rituximab. The reference product is approved in the US for treatment of non-Hodgkin's lymphoma, chronic lymphocytic leukemia, severe rheumatoid arthritis, granulomatosis with polyangiitis, and microscopic polyangiitis. Development of biosimilars is challenging as even small variations in structure have the potential to alter the function of the molecule and thus may impact efficacy, safety, and/or bioavailability. Here we compare ABP 798 and rituximab reference product with respect to binding properties (CD20, C1q, FcRn, and Fcγ receptors), antibody-dependent cell-mediated cytotoxicity (ADCC), complement-dependent cytotoxicity (CDC) and induction of apoptosis. The reference product was sourced from the US (rituximab US) and the EU (rituximab EU).MethodsBinding of ABP 798 and rituximab to the CD20 antigen was characterized using a cell-based CD20 binding assay utilizing the CD20 expressing WIL2-S human B-lymphoblastoid cell line. A direct binding ELISA was used to assess the binding of the Fc domain of ABP 798 to C1q. Binding of the Fc moiety of ABP 798 and rituximab to FcγRIa, FcγRIIa, FcγRIIb, and FcγRIIIa (158V and 158F) were evaluated in AlphaLISAÒ competitive binding assays. Binding to FcRn was evaluated by an AlphaScreenÒ competitive binding assay. ADCC activity was evaluated in a functional cell-based assay, with WIL2-S cells used as target cells and NK92-MI cells, stably transfected with human CD16 (FcγRIIIa [158V]), used as effector cells. CDC activity was evaluated in a functional cell-based assay using the WIL2-S cell line and baby rabbit complement. Induction of apoptosis was assessed by measuring activation of caspase 3/7 in SU-DHL-4 cells, a CD20 expressing human B cell lymphoma cell line.ResultsRelative binding (%) as compared to an ABP 798 reference standard was similar between ABP 798 and rituximab (Table 1).The dose response profiles and relative activity for ADCC and CDC were also similar (ADCC relative cytotoxicity: ABP 798, 88%; rituximab US, 85%; rituximab EU, 86%; CDC relative cytotoxicity: ABP 798, 103%; rituximab US, 102%; rituximab EU, 104%). The dose-response profile for induction of caspase 3/7 was similar between ABP 798 and rituximab as well.ConclusionsThe results presented here demonstrate that ABP 798 is similar to rituximab sourced from both US and EU in terms of biological activity across the range of tested binding and functional assays. The functional assays tested the major and minor mechanisms of action related to clinical efficacy across approved rituximab indications and these results provide a foundation for further clinical development of ABP 798. [Display omitted] DisclosuresMcBride:amgen: Employment; amgen: Other: stockholder. Maher:amgen: Employment; amgen: Other: stockholder. Sweet:amgen: Employment; amgen: Other: stockholder. Foltz:amgen: Employment; amgen: Other: stockholder. Kuhns:amgen: Other: stockholder; amgen: Employment.

Diagnosing Cornelia de Lange syndrome and related neurodevelopmental disorders using RNA sequencing

PurposeNeurodevelopmental disorders represent a frequent indication for clinical exome sequencing. Fifty percent of cases, however, remain undiagnosed even upon exome reanalysis. Here we show RNA sequencing (RNA-seq) on human B-lymphoblastoid cell lines (LCL) is highly suitable for neurodevelopmental Mendelian gene testing and demonstrate the utility of this approach in suspected cases of Cornelia de Lange syndrome (CdLS). MethodsGenotype–Tissue Expression project transcriptome data for LCL, blood, and brain were assessed for neurodevelopmental Mendelian gene expression. Detection of abnormal splicing and pathogenic variants in these genes was performed with a novel RNA-seq diagnostic pipeline and using a validation CdLS-LCL cohort (n = 10) and test cohort of patients who carry a clinical diagnosis of CdLS but negative genetic testing (n = 5). ResultsLCLs share isoform diversity of brain tissue for a large subset of neurodevelopmental genes and express 1.8-fold more of these genes compared with blood (LCL, n = 1706; whole blood, n = 917). This enables testing of more than 1000 genetic syndromes. The RNA-seq pipeline had 90% sensitivity for detecting pathogenic events and revealed novel diagnoses such as abnormal splice products in NIPBL and pathogenic coding variants in BRD4 and ANKRD11. ConclusionThe LCL transcriptome enables robust frontline and/or reflexive diagnostic testing for neurodevelopmental disorders.

Anti-D monoclonal antibodies from 23 human and rodent cell lines display diverse IgG Fc-glycosylation profiles that determine their clinical efficacy

Anti-D immunoglobulin (Anti-D Ig) prophylaxis prevents haemolytic disease of the fetus and newborn. Monoclonal IgG anti-Ds (mAb-Ds) would enable unlimited supplies but have differed in efficacy in FcγRIIIa-mediated ADCC assays and clinical trials. Structural variations of the oligosaccharide chains of mAb-Ds are hypothesised to be responsible. Quantitative data on 12 Fc-glycosylation features of 23 mAb-Ds (12 clones, 5 produced from multiple cell lines) and one blood donor-derived anti-D Ig were obtained by HPLC and mass spectrometry using 3 methods. Glycosylation of mAb-Ds from human B-lymphoblastoid cell lines (B) was similar to anti-D Ig although fucosylation varied, affecting ADCC activity. In vivo, two B mAb-Ds with 77–81% fucosylation cleared red cells and prevented D-immunisation but less effectively than anti-D Ig. High fucosylation (>89%) of mouse-human heterohybridoma (HH) and Chinese hamster ovary (CHO) mAb-Ds blocked ADCC and clearance. Rat YB2/0 mAb-Ds with <50% fucosylation mediated more efficient ADCC and clearance than anti-D Ig. Galactosylation of B mAb-Ds was 57–83% but 15–58% for rodent mAb-Ds. HH mAb-Ds had non-human sugars. These data reveal high galactosylation like anti-D Ig (>60%) together with lower fucosylation (<60%) as safe features of mAb-Ds for mediating rapid red cell clearance at low doses, to enable effective, inexpensive prophylaxis.

Heteroplasmy concordance between mitochondrial DNA and RNA

Mitochondrial DNA (mtDNA) heteroplasmies are associated with various diseases but the transmission of heteroplasmy from mtDNA to mitochondrial RNA (mtRNA) remains unclear. We compared heteroplasmies in mtRNA from 446 human B-lymphoblastoid cell lines to their corresponding mtDNA using deep sequencing data from two independent studies. We observed 2786 heteroplasmies presenting in both DNA and RNA at 1% frequency cutoff. Among them, the frequencies of 2427 (87.1%) heteroplasmies were highly consistent (less than 5% frequency difference) between DNA and RNA. To validate these frequency consistencies, we isolated DNA and RNA simultaneously from GM12282 cell line used in those two sequencing studies, and resequenced its heteroplasmy sites. Interestingly, we also observed the rapid changes of heteroplasmy frequencies during 4 weeks of the cell culture: the frequencies at Day 14 increased by >25% than those at Day 0. However, the heteroplasmy frequencies from the same time point were highly consistent. In summary, our analysis on public data together with in vitro study indicates that the heteroplasmies in DNA can be transcribed into RNA with high fidelity. Meanwhile, the observed rapid-changing heteroplasmy frequency can potentially disturb cell functions, which could be an overlooked confounding factor in cell line related studies.

Extensive epigenetic and transcriptomic variability between genetically identical human B-lymphoblastoid cells with implications in pharmacogenomics research

Genotyped human B-lymphoblastoid cell lines (LCLs) are widely used models in mapping quantitative trait loci for chromatin features, gene expression, and drug response. The extent of genotype-independent functional genomic variability of the LCL model, although largely overlooked, may inform association study design. In this study, we use flow cytometry, chromatin immunoprecipitation sequencing and mRNA sequencing to study surface marker patterns, quantify genome-wide chromatin changes (H3K27ac) and transcriptome variability, respectively, among five isogenic LCLs derived from the same individual. Most of the studied LCLs were non-monoclonal and had mature B cell phenotypes. Strikingly, nearly one-fourth of active gene regulatory regions showed significantly variable H3K27ac levels, especially enhancers, among which several were classified as clustered enhancers. Large, contiguous genomic regions showed signs of coordinated activity change. Regulatory differences were mirrored by mRNA expression changes, preferentially affecting hundreds of genes involved in specialized cellular processes including immune and drug response pathways. Differential expression of DPYD, an enzyme involved in 5-fluorouracil (5-FU) catabolism, was associated with variable LCL growth inhibition mediated by 5-FU. The extent of genotype-independent functional genomic variability might highlight the need to revisit study design strategies for LCLs in pharmacogenomics.

Enhancing the antitumor functions of invariant natural killer T cells using a soluble CD1d-CD19 fusion protein

AbstractInvariant natural killer T (iNKT) cells comprise a unique lineage of CD1d-restricted lipid-reactive T lymphocytes that potently kill tumor cells and exhibit robust immunostimulatory functions. Optimal tumor-directed iNKT cell responses often require expression of the antigen-presenting molecule CD1d on tumors; however, many tumor cells downregulate CD1d and thus evade iNKT cell recognition. We generated a soluble bispecific fusion protein designed to direct iNKT cells to the site of B-cell cancers in a tumor antigen-specific but CD1d-independent manner. This fusion protein is composed of a human CD1d molecule joined to a single chain antibody FV fragment specific for CD19, an antigen widely expressed on B-cell cancers. The CD1d-CD19 fusion protein binds specifically to CD19-expressing, but not CD19-negative cells. Once loaded with the iNKT cell lipid agonist α-galactosyl ceramide (αGC), the CD1d-CD19 fusion induces robust in vitro activation of and cytokine production by human iNKT cells. iNKT cells stimulated by the αGC-loaded CD1d-CD19 fusion also strongly transactivate T-, B-, and NK-cell responses and promote dendritic cell maturation. Importantly, the αGC-loaded fusion induces robust lysis of CD19+CD1d− Epstein-Barr virus immortalized human B-lymphoblastoid cell lines that are otherwise resistant to iNKT cell killing. Consistent with these findings; administration of the αGC-loaded fusion protein controlled the growth of CD19+CD1d− tumors in vivo, suggesting that it can “link” iNKT cells and CD19+CD1d− targets in a therapeutically beneficial manner. Taken together, these preclinical studies demonstrate that this B cell–directed fusion protein can be used to effectively induce iNKT cell antitumor responses in vitro and in vivo.

Modeling Human Paroxysmal Nocturnal Hemoglobinuria Via CRISPR/Cas9 HSPC Gene Editing in Non-Human Primate

Recent advances in CRISPR/Cas9 technology allowing precise genome editing at a site of interest have enabled relevant human disease modeling and the development of corrective gene therapies for various genetic disorders. Paroxysmal nocturnal hemoglobinuria (PNH) is a hematological disorder linked to acquired somatic loss-of-function mutations disrupting the X-linked PIG-A gene in hematopoietic stem and progenitor cells (HSPC), characterized by the clinical triad of intravascular hemolysis, thrombosis and bone marrow failure, as well as clonal expansion of HSPC defective in glycosylphophatidylinositol(GPI)-linked proteins, due to loss of PIG-A enzymatic activity. There have been many attempts to model PNH utilizing conditional knockout strategies in mice, but these do not recapitulate the hemolytic phenotype or clonal dominance. Whether clonal expansion is intrinsic to PIG-A deficient HSPC or extrinsic, resulting from relative protection of PIG-A deficient HSPC and progeny cells from immune attack, is unclear. To explore the pathophysiologic mechanisms of PNH HSPC clonal expansion, we generated a relevant non-human primate model for PNH, utilizing autologous transplantation of HSPC edited with CRISPR/Cas9 at the PIG-A locus.The most efficient guide RNAs (gRNAs) targeting several sites within PIG-A exon 2 locus on the X chromosome, where most of mutations occur in patients with PNH, were selected based on efficiency of editing as screened in FRhK-4 cell lines and mobilized macaque CD34+ HSPC. Compared to editing of the control AAVS1 locus and other genes of interest, editing of all PIG-A locus sites was relatively inefficient. Autologous HSPC were transduced with ribonucleotide protein (RNP) complexes of Cas9 protein and selected gRNAs targeting either PIG-A or the AAVS1 “safe harbor” site, as an internal control, followed by transplantation into one female (ZI35) and one male (ZL19) macaque, respectively. Both animals engrafted promptly and clones acquiring the PNH loss-of-function phenotype, defined by loss of binding of FLAER, a fluorescent compound that binds to all GPI anchors, and loss of expression of lineage-specific GPI-linked proteins (CD24 for granulocytes and CD14 for monocytes) were stably maintained at levels of 0.2-0.4% for up to 19 months post-transplantation, with no evidence for intrinsic clonal expansion of PIG-A edited cells (Fig. 1A). Upon targeted deep sequencing, 0.4-1% insertions and deletions (INDELs) induced by CRISPR/Cas9 were detected, and the predominant INDEL type was identified as a single base deletion at the +1 or -1 positions of the target site consistently in granulocytes and other mature hematopoietic lineage cells from peripheral blood (PB), suggesting that initial mutations occurred in long-lasting HSPCs rather than short-term progenitor cells. Furthermore, as the PIG-A gene is located on X chromosome, we sought to investigate the difference in genome editing efficiency depending on the number of X alleles or activation state. Note that the expected INDEL frequency in completely PIG-A deficient sorted FLAERneg cells would be 100%, however, large deletions or rearrangements are not detected by standard deep sequencing methodologies. Interestingly, the mutation frequencies in total granulocytes and more importantly in sorted FLAER negative PNH cells were always much higher in male (ZL19) macaque cells than in female (ZI35) macaque cells (Fig. 1B and C). Consistently, gene editing PIG-A allele efficiency with CRISPR/Cas9 was also higher in human male B-lymphoblastoid cell lines (LCL) compared to female cells, 23.2% versus 16.6% (n=5), respectively. The finding that edited allele frequency was consistently lower in sorted FLAERneg female than male cells suggests that editing of the active X allele may be favored, potentially due to poor accessibility of inactive loci to editing machinery.In conclusion, we have successfully established a rhesus macaque model for PNH utilizing autologous transplantation of CRISPR/Cas9 edited HSPC. To date, we found no evidence for intrinsic expansion of PIG-A deficiency HSPC and hematopoietic progeny. This modeling approach could be utilized for further investigation of extrinsic or intrinsic factor responsible for clonal expansion. Furthermore, our findings provide a better insight into the relationship between CRISPR/Cas9 editing efficiency and active versus inactive X-linked genes. [Display omitted] DisclosuresDunbar:National Institute of Health: Research Funding.

A supporting role of Chinese National Immortalized Cell Bank in life science research.

A biorepository of human samples is essential to support the research of life science. Lymphoblastoid B cell line (LCL), which is easy to be prepared and can reproduce indefinitely, is a convenient form of sample preservation. LCLs are established from human B cells transformed by Epstein-Barr virus (EBV). Chinese National Immortalized Cell Bank has preserved human LCLs from different ethnic groups in China. As there are many studies on the nature of LCLs and public available resources with genome-wide data for LCLs, they have been widely applied in genetics, immunology, pharmacogenetics/genomics, regenerative medicine, cancer pathogenesis and immunotherapy, screening and generation of fully human neutralizing monoclonal antibodies and study on EBV pathogenesis. Here, we review the characteristics of LCLs and their contributions to scientific research, and introduce preserved samples in Chinese National Immortalized Cell Bank to the scientific community. We hope this bank can support more areas in the scientific research.

Peptide-guided targeting of GPR55 for anti-cancer therapy.

Expression of the lysophosphatidylinositol receptor GPR55 correlates with invasive potential of metastatic cells and bone metastasis formation of different types of tumors. These findings suggest a role for GPR55 signaling in cancer progression, including in lymphoproliferative diseases. Here, we screened a M13-phage-displayed random library using the bait of HEK293 cells that heterologously expressed full-length HA-GPR55. We selected a set of phagotopes that carried 7-mer insert peptides flanked by a pair of cysteine residues, which resulted in cyclized peptides. Sequencing of selected phagotopes dictated the primary structure for the synthetic FITC-labeled peptide P1, which was analyzed for binding specificity to immunoprecipitated HA-GPR55, and to endogenously expressed GPR55, using cells interfered or not for GPR55, as well as for co-localization imaging with HA-GPR55 at the membrane level. The peptide P1 stimulated GPR55 endocytosis and inhibited GPR55-dependent proliferation of EHEB and DeFew cells, two human B-lymphoblastoid cell lines. Our data support the potential therapeutic application of peptide ligands of GPR55 for targeting and inhibiting growth of neoplastic cells, which overexpress GPR55 and are dependent on GPR55 signaling for their proliferation.

The in vitro PIG-A gene mutation assay: glycosylphosphatidylinositol (GPI)-related genotype-to-phenotype relationship in TK6 cells.

In our previous work, we established an in vitro variant of the currently developed in vivo PIG-A assay as promising mutagenicity test system. We applied the human B-lymphoblastoid cell line TK6 for the in vitro assay development, which is based on the cellular glycosylphosphatidylinositol (GPI) status. At least 22 genes are involved in GPI biosynthesis, leading to the complex situation that, in principle, multiple genes could induce a GPI-deficient phenotype by acquiring inactivating mutations. However, only the PIG-A gene is located on the X-chromosome, rendering PIG-A more sensitive compared to autosomal linked, GPI-relevant genes. In this work, we investigated the GPI-related genotype-to-phenotype relationship in TK6 cells. By a next-generation sequencing approach, we identified a heterozygous chromosomal deletion on chromosome 17, where the PIG-L gene is located. In the analyzed TK6 cell clones, the GPI-deficient phenotype was induced either by mutations in PIG-A, by the complete absence of PIG-A mRNA, or by deletions in the remaining functional PIG-L gene, causing loss of heterozygosity. The identified PIG-L heterozygosity could also be responsible for the increased sensitivity toward mutagenic ethyl methanesulfonate or UV-C treatments of p53-proficient TK6 compared to the TK6-related, but p53-deficient WI-L2-NS cell line. Moreover, the WI-L2-NS cell line was found to exhibit a much lower number of GPI-deficient mutant cells in the purchased cell batch, and WI-L2-NS exerted a lower spontaneous rate of GPI deficiency compared to TK6 cells.

Whole genome and normalized mRNA sequencing reveal genetic status of TK6, WTK1, and NH32 human B-lymphoblastoid cell lines

Closely related TK6, WTK1, and NH32 human B-lymphoblastoid cell lines differ in their p53 functional status. These lines are used frequently in genotoxicity studies and in studies aimed at understanding the role of p53 in DNA repair. Despite their routine use, little is known about the genetic status of these cells. To provide insight into their genetic composition, we sequenced and analyzed the entire genome of TK6 cells, as well as the normalized transcriptomes of TK6, WTK1, and NH32 cells. Whole genome sequencing (WGS) identified 21,561 genes and 5.17×106 small variants. Within the small variants, 50.54% were naturally occurring single nucleotide polymorphisms (SNPs) and 49.46% were mutations. The mutations were comprised of 92.97% single base-pair substitutions and 7.03% insertions or deletions (indels). The number of predicted genes, SNPs, and small mutations are similar to frequencies observed in the human population in general. Normalized mRNA-seq analysis identified the expression of transcripts bearing SNPs or mutations for TK6, WTK1, and NH32 as 2.88%, 2.04%, and 1.71%, respectively, and several of the variant transcripts identified appear to have important implications in genetic toxicology. These include a single base deletion mutation in the ferritin heavy chain gene (FTH1) resulting in a frame shift and protein truncation in TK6 that impairs iron metabolism. SNPs in the thiopurine S-methyltransferase (TPMT) gene (TPMT*3A SNP), and in the xenobiotic metabolizing enzyme, NADPH quinine oxidoreductase 1 (NQO1) gene (NQO1*2 SNP), are both associated with decreased enzyme activity. The clinically relevant TPMT*3A and NQO1*2 SNPs can make these cell lines useful in pharmacogenetic studies aimed at improving or tailoring drug treatment regimens that minimize toxicity and enhance efficacy.

Partial Molecular Cloning of the JHK Retrovirus Using Gammaretrovirus Consensus PCR Primers

The JHK virus (JHKV) was previously described as a type C retrovirus that has some distinctive ultrastructural features and replicates constitutively in a human B-lymphoblastoid cell line, JHK-3. In order to facilitate the cloning of sequences from JHKV, a series of partially degenerate consensus retroviral PCR primers were created by a data-driven design approach based on an alignment of 14 diverse gammaretroviral genomes. These primers were used in the PCR amplification of purified JHK virion cDNA, and ana lysis of the resulting amplified sequence indicates that the JHKV is in the murine leukemia virus (MLV) family. The JHK sequence is nearly identical to the corresponding region of the Bxv-1 endogenous mouse retrovirus (GenBank accession AC115959) and distinct from XMRV. JHKV gag-specific amplification was demonstrated with nucleic acids from uncultivated, frozen, peripheral blood mononuclear cells (PBMCs) of the index patient, but not in PBMCs from nine healthy blood donors. Unlike earlier reports, in which MLV-like sequences were identified in human source material, which may have been due to murine contamination, budding retrovirions were demonstrated repeatedly by electron microscopy in uncultivated lymphocytes of the index patient that were morphologically identical in their development to the virions in the JHK-3 cells, and immunological evidence was obtained that the index patient produced IgG antibodies that bound to the budding viral particles in patient PBMCs and in the JHK-3 cells. These data indicate that the patient had been infected by JHKV, lending significance to the demonstration of JHKV amplicons in nucleic acids of the patient's PBMCs. In future studies, the PCR primer sets described herein may expand the detection of an amplifiable subset of viruses related to MLV.

Biological activity of Pd(II) complexes with mono- and disubstituted pyridines—Experimental and theoretical studies

Due to the similarity between Pd and Pt, the complexes of palladium(II) can be considered as potential anticancer agents. Activity of six PdCl2(X2Py)2 complexes (Py=pyridine, and X=CH3 or Cl) was measured by MTT test using MCF7, CCRF-SB, PC3 and human B-lymphoblastoid cell lines. We found that the effect of PdCl2(XnPy)2 was cell-specific and time-dependent. Obtained results were discussed and compared with the activation parameters calculated for the hydrolysis of PdCl2(XnPy)2, indicating a correlation between viability of MCF7 and CCRF-SB cells and rates of hydrolysis of the Pd(II) complexes.

In vitro evaluation of human hybrid cell lines generated by fusion of B-lymphoblastoid cells and ex vivo tumour cells as candidate vaccines for haematological malignancies

Fusions of dendritic cells (DCs) and tumour cells have been shown to induce protective immunity to tumour challenge in animal models, and to represent a promising approach to cancer immunotherapy. The broader clinical application of this approach, however, is potentially constrained by the lack of replicative capacity and limited standardisation of fusion cell preparations. We show here that fusion of ex vivo tumour cells isolated from patients with a range of haematological malignancies with the human B-lymphoblastoid cell line (LCL), HMy2, followed by chemical selection of the hybridomas, generated stable, self-replicating human hybrid cell lines that grew continuously in tissue culture, and survived freeze/thawing cycles. The hybrid cell lines expressed HLA class I and class II molecules, and the major T-cell costimulatory molecules, CD80 and CD86. All but two of 14 hybrid cell lines generated expressed tumour-associated antigens that were not expressed by HMy2 cells, and were therefore derived from the parent tumour cells. The hybrid cell lines stimulated allogeneic T-cell proliferative responses and interferon-gamma release in vitro to a considerably greater degree than their respective parent tumour cells. The enhanced T-cell stimulation was inhibited by CTLA4-Ig fusion protein, and by blocking antibodies to MHC class I and class II molecules. Finally, all of five LCL/tumour hybrid cell lines tested induced tumour antigen-specific cytotoxic T-cell responses in vitro in PBL from healthy, HLA-A2+ individuals, as detected by HLA-A2-peptide pentamer staining and cellular cytotoxicity. These data show that stable hybrid cell lines, with enhanced immunostimulatory properties and potential for therapeutic vaccination, can be generated by in vitro fusion and chemical selection of B-LCL and ex vivo haematological tumour cells.

Leukemic Blasts with the Paroxysmal Nocturnal Hemoglobinuria Phenotype in Children with Acute Lymphoblastic Leukemia

It has been proposed that genomic instability is essential to account for the multiplicity of mutations often seen in malignancies. Using the X-linked PIG-A gene as a sentinel gene for spontaneous inactivating somatic mutations, we previously showed that healthy individuals harbor granulocytes with the PIG-A mutant (paroxysmal nocturnal hemoglobinuria) phenotype at a median frequency (f) of ∼12 × 10(-6). Herein, we used a similar approach to determine f in blast cells derived from 19 individuals with acute lymphoblastic leukemia (ALL) and in immortalized Epstein-Barr virus-transformed B-cell cultures (human B-lymphoblastoid cell lines) from 19 healthy donors. The B-lymphoblastoid cell lines exhibited a unimodal distribution, with a median f value of 11 × 10(-6). In contrast, analysis of the f values for the ALL samples revealed at least two distinct populations: one population, representing approximately half of the samples (n = 10), had a median f value of 13 × 10(-6), and the remaining samples (n = 9) had a median f value of 566 × 10(-6). We conclude that in ALL, there are two distinct phenotypes with respect to hypermutability, which we hypothesize will correlate with the number of pathogenic mutations required to produce the leukemia.

Human lymphoblastoid B-cell lines reprogrammed to EBV-free induced pluripotent stem cells

AbstractGeneration 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 hematopoietic, cardiac, neural, and hepatocyte-like lineages. Significantly, although the parental LCLs express viral EBNA-1 and other Epstein-Barr virus latency-related elements for their survival, their presence was not detectable in LCL-iPSCs. Thus, reprogramming LCLs could offer an unlimited source for patient-specific iPSCs.