Panel Of Lymphoblastoid Cell Lines Research Articles

AFNT-211: An FAS-41BB–enhanced TCR-T cell therapy with stem-like properties targeting KRAS G12V-expressing solid tumors.

2543 Background: KRAS is the most common oncogenic driver mutation in solid tumors, promoting the initiation and progression of many uncurable cancers, including colorectal, pancreatic and lung cancer. While small molecule inhibitors to KRASG12C mutations have been approved, there are no targeted therapies available for patients with highly prevalent KRASG12V mutations. TCR-T cell therapies have demonstrated remarkable responses in clinical trials, but their durability has been limited by the immunosuppressive tumor microenvironment (TME). AFNT-211 is an autologous T cell therapy engineered to express an HLA-A*11:01 KRASG12V-specific TCR, further enhanced with CD8α/β coreceptor and a FAS-41BB switch receptor to drive T cell persistence and durable clinical responses. CD8α/β coreceptor enables a coordinated CD4+/CD8+ T cell response and FAS-41BB converts the FAS ligand (FASL) TME death signal into a costimulatory signal through 41BB activation. Methods: AFNT-211 was assessed for efficacy in vitro against a panel of KRASG12V-expressing tumor cell lines and in vivo using human xenograft mouse models. In vitro safety studies were performed to assess potential cross-reactivity, alloreactivity, and cytokine-independent growth. The clinical manufacturing process consists of autologous CD4+/CD8+ T cells transduced with lentivirus and expanded using culture conditions that drive robust expansion while preserving stem-like properties. Phenotypic and functional analyses of AFNT-211 were performed using flow cytometry and cell-based assays. Results: Coculture of AFNT-211 with a panel of KRASG12V-expressing tumor cell lines led to significant effector cytokine secretion, T cell proliferation, and tumor cell killing. The CD8α/β coreceptor enabled CD4+ T cell recognition of KRASG12V and greater overall cytotoxicity. The FAS-41BB switch receptor dramatically augmented the magnitude and durability of the anti-tumor response against FASL-expressing tumor cells. XScan mutagenesis and potential off-target peptide testing revealed no significant cross-reactivities. No alloreactivity was observed against a panel of lymphoblastoid cell lines presenting the most frequent HLA types in the US population. Potent anti-tumor response was observed in vivo in a mouse xenograft model. Affini-T’s Thrive manufacturing platform used for the production of AFNT-211 consistently delivers >30-40e9 TCR-engineered T cells with a high frequency of naïve and central memory T cells expressing negligible markers of exhaustion. Conclusions: The AFNT-211 manufacturing process generates a large number of TCR-T cells with desirable stem-like properties optimized for clinical dosing. Preclinical data demonstrated a potent and safe profile for AFNT-211 that supports clinical development in HLA-A*11:01 patients with advanced/metastatic solid tumors harboring a KRAS G12V mutation.

Abstract PR08: TCR1020 specific for KRAS G12V restricted to HLA-A*11:01 exhibits potent and precise antigen specificity for clinical development

Abstract Background: KRAS mutations drive tumorigenesis in adenocarcinomas of the lung (30-40%), colon (40-50%) and pancreas (>90%). Recent clinical evidence demonstrates potent and durable anti-tumor activity of adoptively transferred KRAS-specific T cells in select patients with KRAS-mutated advanced solid tumors. We have defined mutant KRAS (mKRAS) epitopes restricted to high prevalence HLA class I alleles and validated this oncoprotein as an immunological target amenable to T cell receptor (TCR)-based therapeutic approaches. Here, we describe the pre-clinical development of TCR1020, a human TCRab specific for KRAS G12V restricted to HLA-A*11:01. Methods: In vitro stimulation assays were used to generate CD8+ T cell responses specific for a decamer epitope of KRAS G12V (VVVGAVGVGK) using blood specimens collected from A*11:01+ healthy donors. TCR1020 was identified by TCRab RNA sequencing of flow cytometrically sorted peptide/HLA multimer+ CD8 T cells. Transgenic expression of TCR1020 was attained via lentiviral transduction of reporter cell lines and gene-edited (TCRabnull) primary T cells. TCR1020 antigen specificity, affinity and cross-reactivity was assessed using in vitro coculture, limiting peptide dilution, and combinatorial peptide scanning assays. TCR1020 reactivity to G12V/A*11:01+ cell lines was assessed using in vitro cytokine release and cytotoxicity assays, as well as mouse xenograft tumor models. Results: TCR1020 exhibits specificity to the cognate KRAS G12V epitope with cross-reactivity to G12C but not wild-type KRAS. TCR1020 has a measured functional avidity (EC50) of 262 pM. TCR1020-redirected primary CD8+ T cells promote cytolysis of A*11:01+ tumor cell lines of lung, colonic or pancreatic origin harboring endogenous KRAS G12V mutations. The adoptive transfer of TCR1020-engineered primary CD8+ T cells exhibits potent in vivo antitumor activity in mouse xenograft tumor models of metastatic cancer. TCR1020 demonstrates CD8 co-receptor independence, and CD4+ T cells expressing TCR1020 express cytokines and lyse G12V/A*11:01+ tumor cell lines. In-depth characterization of the TCR1020 peptide recognition motif using alanine/glycine scanning libraries reveals a unique antigen binding motif with 5 critical amino acid residues excluding peptide/HLA anchor residues. Combinatorial peptide library scanning identifies five A*11:01-restricted peptide candidates within the human proteome with potential cross-reactivity to TCR1020, none of which activate TCR1020-engineered T cells over a wide range of concentrations. TCR1020 exhibits no evidence of reactivity against cell lines derived from healthy human tissues nor alloreactivity against a panel of lymphoblastoid cell lines encompassing a wide array of HLA class I alleles. Conclusion: TCR1020 exhibits high potency and exquisite antigen cognate specificity, and it is under clinical development for the treatment of A*11:01+ patients with KRAS G12V+ advanced solid tumors. Citation Format: Adham S. Bear, Rebecca B. Nadler, John Scholler, Robert H. Vonderheide, Gerald P. Linette, Beatriz M. Carreno. TCR1020 specific for KRAS G12V restricted to HLA-A*11:01 exhibits potent and precise antigen specificity for clinical development [abstract]. In: Proceedings of the AACR Special Conference: Targeting RAS; 2023 Mar 5-8; Philadelphia, PA. Philadelphia (PA): AACR; Mol Cancer Res 2023;21(5_Suppl):Abstract nr PR08.

Transcriptome innovations in primates revealed by single-molecule long-read sequencing.

Transcriptomic diversity greatly contributes to the fundamentals of disease, lineage-specific biology, and environmental adaptation. However, much of the actual isoform repertoire contributing to shaping primate evolution remains unknown. Here, we combined deep long- and short-read sequencing complemented with mass spectrometry proteomics in a panel of lymphoblastoid cell lines (LCLs) from human, three other great apes, and rhesus macaque, producing the largest full-length isoform catalog in primates to date. Around half of the captured isoforms are not annotated in their reference genomes, significantly expanding the gene models in primates. Furthermore, our comparative analyses unveil hundreds of transcriptomic innovations and isoform usage changes related to immune function and immunological disorders. The confluence of these evolutionary innovations with signals of positive selection and their limited impact in the proteome points to changes in alternative splicing in genes involved in immune response as an important target of recent regulatory divergence in primates.

Single Nucleotide Polymorphisms at a Distance from Aryl Hydrocarbon Receptor (AHR) Binding Sites Influence AHR Ligand-Dependent Gene Expression.

Greater than 90% of significant genome-wide association study (GWAS) single-nucleotide polymorphisms (SNPs) are in noncoding regions of the genome, but only 25.6% are known expression quantitative trait loci (eQTLs). Therefore, the function of many significant GWAS SNPs remains unclear. We have identified a novel type of eQTL for which SNPs distant from ligand-activated transcription factor (TF) binding sites can alter target gene expression in a SNP genotype-by-ligand–dependent fashion that we refer to as pharmacogenomic eQTLs (PGx-eQTLs)—loci that may have important pharmacotherapeutic implications. In the present study, we integrated chromatin immunoprecipitation-seq with RNA-seq and SNP genotype data for a panel of lymphoblastoid cell lines to identify 10 novel cis PGx-eQTLs dependent on the ligand-activated TF aryl hydrocarbon receptor (AHR)—a critical environmental sensor for xenobiotic (drug) and immune response. Those 10 cis PGx-eQTLs were eQTLs only after AHR ligand treatment, even though the SNPs did not create/destroy an AHR response element—the DNA sequence motif recognized and bound by AHR. Additional functional studies in multiple cell lines demonstrated that some cis PGx-eQTLs are functional in multiple cell types, whereas others displayed SNP-by-ligand–dependent effects in just one cell type. Furthermore, four of those cis PGx-eQTLs had previously been associated with clinical phenotypes, indicating that those loci might have the potential to inform clinical decisions. Therefore, SNPs across the genome that are distant from TF binding sites for ligand-activated TFs might function as PGx-eQTLs and, as a result, might have important clinical implications for interindividual variation in drug response.SIGNIFICANCE STATEMENTMore than 90% of single-nucleotide polymorphisms (SNPs) that are associated with clinical phenotypes are located in noncoding regions of the genome. However, the mechanisms of action of many of those SNPs have not been elucidated, and drugs may unmask functional expression quantitative trail loci (eQTLs). In the current study, we used drugs that bind to the ligand-activated transcription factor aryl hydrocarbon receptor (AHR) and identified SNPs that were associated with interindividual variation in gene expression following drug exposure—termed pharmacogenomic (PGx)-eQTLs. Possibly of greater significance, those PGx-eQTL SNPs were outside of AHR binding sites, indicating that they do not interrupt AHR DNA recognition. PGx-eQTLs such as those described in this work may have crucial implications for interindividual variation in drug.

Calcium mobilization is responsible for Thapsigargin induced Epstein Barr virus lytic reactivation in in vitro immortalized lymphoblastoid cell lines

The latent state is a critical component of all herpesvirus infections, and its regulation remains one of the most active areas of Epstein-Barr Virus (EBV) research. In particular, identifying environmental factors that trigger EBV reactivation into a virus-productive state has become a central goal in EBV latency research. Recently, a category of chemicals known as inducers of the endoplasmic reticulum unfolded protein response (UPR) have been shown to trigger EBV lytic reactivation in various established EBV-associated lymphoma cell lines. This has led to the recent belief that UPR is a universal cellular signaling pathway that directly triggers EBV lytic reactivation irrespective of cell type. We tested the potency of several widely used UPR inducers for EBV lytic reactivation on virus-immortalized primary lymphoblastoid cell lines (LCLs) in vitro. We found that, with the exception of Thapsigargin (Tg), UPR inducers did not trigger significant increases in BZLF1 transcripts or changes in the numbers of EBV genomic copies/cell in our panel of primary LCLs. Further investigation revealed that induction of lytic reactivation by Tg appeared to be due to its ability to trigger intracellular Ca2+ mobilization rather than its ability to induce UPR, based on our observations in which UPR induction alone was not sufficient to trigger the EBV lytic cycle in our LCLs. EBV immortalized LCLs have rarely been included in the majority of the lytic reactivation studies yet the characteristics of latent infection in LCLs should resemble those of proliferating B cells in clinically encountered lymphoproliferative diseases. Based on these observations, we propose an alternative mechanism of action for Tg in triggering EBV lytic reactivation in LCLs, and suggest that the proposed use of any chemical inducers of UPR for a purpose of oncolytic/lytic induction therapy needs to be fully evaluated pre-clinically in a panel of LCLs.

Principled multi-omic analysis reveals gene regulatory mechanisms of phenotype variation.

Recent studies have analyzed large-scale data sets of gene expression to identify genes associated with interindividual variation in phenotypes ranging from cancer subtypes to drug sensitivity, promising new avenues of research in personalized medicine. However, gene expression data alone is limited in its ability to reveal cis-regulatory mechanisms underlying phenotypic differences. In this study, we develop a new probabilistic model, called pGENMi, that integrates multi-omic data to investigate the transcriptional regulatory mechanisms underlying interindividual variation of a specific phenotype—that of cell line response to cytotoxic treatment. In particular, pGENMi simultaneously analyzes genotype, DNA methylation, gene expression, and transcription factor (TF)-DNA binding data, along with phenotypic measurements, to identify TFs regulating the phenotype. It does so by combining statistical information about expression quantitative trait loci (eQTLs) and expression-correlated methylation marks (eQTMs) located within TF binding sites, as well as observed correlations between gene expression and phenotype variation. Application of pGENMi to data from a panel of lymphoblastoid cell lines treated with 24 drugs, in conjunction with ENCODE TF ChIP data, yielded a number of known as well as novel (TF, Drug) associations. Experimental validations by TF knockdown confirmed 41% of the predicted and tested associations, compared to a 12% confirmation rate of tested nonassociations (controls). An extensive literature survey also corroborated 62% of the predicted associations above a stringent threshold. Moreover, associations predicted only when combining eQTL and eQTM data showed higher precision compared to an eQTL-only or eQTM-only analysis using pGENMi, further demonstrating the value of multi-omic integrative analysis.

Hypertension Susceptibility Loci are Associated with Anthracycline-related Cardiotoxicity in Long-term Childhood Cancer Survivors

Anthracycline-based chemotherapy is associated with dose-dependent, irreversible damage to the heart. Childhood cancer survivors with hypertension after anthracycline exposure are at increased risk of cardiotoxicity, leading to the hypothesis that genetic susceptibility loci for hypertension may serve as predictors for development of late cardiotoxicity. Therefore, we determined the association between 12 GWAS-identified hypertension-susceptibility loci and cardiotoxicity in a cohort of long-term childhood cancer survivors (N = 108) who received anthracyclines and were screened for cardiac function via echocardiograms. Hypertension-susceptibility alleles of PLCE1:rs9327264 and ATP2B1:rs17249754 were significantly associated with cardiotoxicity risk conferring a protective effect with a 64% (95% CI: 0.18–0.76, P = 0.0068) and 74% (95% CI: 0.07–0.96, P = 0.040) reduction in risk, respectively. In RNAseq experiments of human induced pluripotent stem cell (iPSC) derived cardiomyocytes treated with doxorubicin, both PLCE1 and ATP2B1 displayed anthracycline-dependent gene expression profiles. In silico functional assessment further supported this relationship - rs9327264 in PLCE1 (P = 0.0080) and ATP2B1 expression (P = 0.0079) were both significantly associated with daunorubicin IC50 values in a panel of lymphoblastoid cell lines. Our findings demonstrate that the hypertension-susceptibility variants in PLCE1 and ATP2B1 confer a protective effect on risk of developing anthracycline-related cardiotoxicity, and functional analyses suggest that these genes are influenced by exposure to anthracyclines.

Clinical validation of genetic variants associated with in vitro chemotherapy-related lymphoblastoid cell toxicity.

Hematotoxicity is one of the major side effects of chemotherapy. The aim of this study was to examine the association between single nucleotide polymorphisms (SNPs) and hematotoxicity in breast cancer patients in a subset of patients of the SUCCESS prospective phase III chemotherapy study. All patients (n = 1678) received three cycles of 5-fluorouracil, epirubicin, and cyclophosphamide (FEC) followed by three cycles of docetaxel or docetaxel/gemcitabine, depending on randomization. Germline DNA was genotyped for 246 SNPs selected from a previous genome-wide association study (GWAS) in a panel of lymphoblastoid cell lines, with gemcitabine toxicity as the phenotype. All SNPs were tested for their value in predicting grade 3 or 4 neutropenic or leukopenic events (NLEs). Their prognostic value in relation to overall survival and disease-free survival was also tested.None of the SNPs was found to be predictive for NLEs during treatment with docetaxel/gemcitabine. Two SNPs in and close to the PIGB gene significantly improved the prediction of NLEs after FEC, in addition to the factors of age and body surface area. The top SNP (rs12050587) had an odds ratio of 1.38 per minor allele (95% confidence interval, 1.17 to 1.62). No associations were identified for predicting disease-free or overall survival.Genetic variance in the PIGB gene may play a role in determining interindividual differences in relation to hematotoxicity after FEC chemotherapy.

A tiered, Bayesian approach to estimating of population variability for regulatory decision-making.

Characterizing human variability in susceptibility to chemical toxicity is a critical issue in regulatory decision-making, but is usually addressed by a default 10-fold safety/uncertainty factor. Feasibility of population-based in vitro experimental approaches to more accurately estimate human variability was demonstrated recently using a large (~1000) panel of lymphoblastoid cell lines. However, routine use of such a large population-based model poses cost and logistical challenges. We hypothesize that a Bayesian approach embedded in a tiered workflow provides efficient estimation of variability and enables a tailored and sensible approach to selection of appropriate sample size. We used the previously collected lymphoblastoid cell line in vitro toxicity data to develop a data-derived prior distribution for the uncertainty in the degree of population variability. The resulting prior for the toxicodynamic variability factor (the ratio between the median and 1% most sensitive individuals) has a median (90% CI) of 2.5 (1.4-9.6). We then performed computational experiments using a hierarchical Bayesian population model with lognormal population variability with samples sizes of n = 5 to 100 to determine the change in precision and accuracy with increasing sample size. We propose a tiered Bayesian strategy for fit-for-purpose population variability estimates: (1) a default using the data-derived prior distribution; (2) a pilot experiment using samples sizes of ~20 individuals that reduces prior uncertainty by > 50% with > 80% balanced accuracy for classification; and (3) a high confidence experiment using sample sizes of ~50-100. This approach efficiently uses in vitro data on population variability to inform decision-making.

Characterisation of the global transcriptional response to heat shock and the impact of individual genetic variation.

BackgroundThe heat shock transcriptional response is essential to effective cellular function under stress. This is a highly heritable trait but the nature and extent of inter-individual variation in heat shock response remains unresolved.MethodsWe determined global transcription profiles of the heat shock response for a panel of lymphoblastoid cell lines established from 60 founder individuals in the Yoruba HapMap population. We explore the observed differentially expressed gene sets following heat shock, establishing functional annotations, underlying networks and nodal genes involving heat shock factor 1 recruitment. We define a multivariate phenotype for the global transcriptional response to heat shock using partial least squares regression and map this quantitative trait to associated genetic variation in search of the major genomic modulators.ResultsA comprehensive dataset of differentially expressed genes following heat shock in humans is presented. We identify nodal genes downstream of heat shock factor 1 in this gene set, notably involving ubiquitin C and small ubiquitin-like modifiers together with transcription factors. We dissect a multivariate phenotype for the global heat shock response which reveals distinct clustering of individuals in terms of variance of the heat shock response and involves differential expression of genes involved in DNA replication and cell division in some individuals. We find evidence of genetic associations for this multivariate response phenotype that involves trans effects modulating expression of genes following heat shock, including HSF1 and UBQLN1.ConclusionThis study defines gene expression following heat shock for a cohort of individuals, establishing insights into the biology of the heat shock response and hypotheses for how variation in this may be modulated by underlying genetic diversity.Electronic supplementary materialThe online version of this article (doi:10.1186/s13073-016-0345-5) contains supplementary material, which is available to authorized users.

Estrogen, SNP-Dependent Chemokine Expression and Selective Estrogen Receptor Modulator Regulation.

We previously reported, on the basis of a genome-wide association study for aromatase inhibitor-induced musculoskeletal symptoms, that single-nucleotide polymorphisms (SNPs) near the T-cell leukemia/lymphoma 1A (TCL1A) gene were associated with aromatase inhibitor-induced musculoskeletal pain and with estradiol (E2)-induced TCL1A expression. Furthermore, variation in TCL1A expression influenced the downstream expression of proinflammatory cytokines and cytokine receptors. Specifically, the top hit genome-wide association study SNP, rs11849538, created a functional estrogen response element (ERE) that displayed estrogen receptor (ER) binding and increased E2 induction of TCL1A expression only for the variant SNP genotype. In the present study, we pursued mechanisms underlying the E2-SNP-dependent regulation of TCL1A expression and, in parallel, our subsequent observations that SNPs at a distance from EREs can regulate ERα binding and that ER antagonists can reverse phenotypes associated with those SNPs. Specifically, we performed a series of functional genomic studies using a large panel of lymphoblastoid cell lines with dense genomic data that demonstrated that TCL1A SNPs at a distance from EREs can modulate ERα binding and expression of TCL1A as well as the expression of downstream immune mediators. Furthermore, 4-hydroxytamoxifen or fulvestrant could reverse these SNP-genotype effects. Similar results were found for SNPs in the IL17A cytokine and CCR6 chemokine receptor genes. These observations greatly expand our previous results and support the existence of a novel molecular mechanism that contributes to the complex interplay between estrogens and immune systems. They also raise the possibility of the pharmacological manipulation of the expression of proinflammatory cytokines and chemokines in a SNP genotype-dependent fashion.

Heterozygous PALB2 c.1592delT mutation channels DNA double-strand break repair into error-prone pathways in breast cancer patients.

Hereditary heterozygous mutations in a variety of DNA double-strand break (DSB) repair genes have been associated with increased breast cancer risk. In the Finnish population, PALB2 (partner and localizer of BRCA2) represents a major susceptibility gene for female breast cancer, and so far, only one mutation has been described, c.1592delT, which leads to a sixfold increased disease risk. PALB2 is thought to participate in homologous recombination (HR). However, the effect of the Finnish founder mutation on DSB repair has not been investigated. In the current study, we used a panel of lymphoblastoid cell lines (LCLs) derived from seven heterozygous female PALB2 c.1592delT mutation carriers with variable health status and six wild-type matched controls. The results of our DSB repair analysis showed that the PALB2 mutation causes specific changes in pathway usage, namely increases in error-prone single-strand annealing (SSA) and microhomology-mediated end-joining (MMEJ) compared with wild-type LCLs. These data indicated haploinsufficiency regarding the suppression of error-prone DSB repair in PALB2 mutation carriers. To the contrary, neither reduced HR activities, nor impaired RAD51 filament assembly, nor sensitization to PARP inhibition were consistently observed. Expression of truncated mutant versus wild-type PALB2 verified a causal role of PALB2 c.1592delT in the shift to error-prone repair. Discrimination between healthy and malignancy-presenting PALB2 mutation carriers revealed a pathway shift particularly in the breast cancer patients, suggesting interaction of PALB2 c.1592delT with additional genomic lesions. Interestingly, the studied PALB2 mutation was associated with 53BP1 accumulation in the healthy mutation carriers but not the patients, and 53BP1 was limiting for error-prone MMEJ in patients but not in healthy carriers. Our study identified a rise in error-prone DSB repair as a potential threat to genomic integrity in heterozygous PALB2 mutation carriers. The used phenotypic marker system has the capacity to capture dysfunction caused by polygenic mechanisms and therefore offers new strategies of cancer risk prediction.

Transmembrane protein 55B is a novel regulator of cellular cholesterol metabolism.

Interindividual variation in pathways affecting cellular cholesterol metabolism can influence levels of plasma cholesterol, a well-established risk factor for cardiovascular disease. Inherent variation among immortalized lymphoblastoid cell lines from different donors can be leveraged to discover novel genes that modulate cellular cholesterol metabolism. The objective of this study was to identify novel genes that regulate cholesterol metabolism by testing for evidence of correlated gene expression with cellular levels of 3-hydroxy-3-methylglutaryl-CoA reductase (HMGCR) mRNA, a marker for cellular cholesterol homeostasis, in a large panel of lymphoblastoid cell lines. Expression array profiling was performed on 480 lymphoblastoid cell lines established from participants of the Cholesterol and Pharmacogenetics (CAP) statin clinical trial, and transcripts were tested for evidence of correlated expression with HMGCR as a marker of intracellular cholesterol homeostasis. Of these, transmembrane protein 55b (TMEM55B) showed the strongest correlation (r=0.29; P=4.0E-08) of all genes not previously implicated in cholesterol metabolism and was found to be sterol regulated. TMEM55B knockdown in human hepatoma cell lines promoted the decay rate of the low-density lipoprotein receptor, reduced cell surface low-density lipoprotein receptor protein, impaired low-density lipoprotein uptake, and reduced intracellular cholesterol. Here, we report identification of TMEM55B as a novel regulator of cellular cholesterol metabolism through the combination of gene expression profiling and functional studies. The findings highlight the value of an integrated genomic approach for identifying genes that influence cholesterol homeostasis.

Radiation-induced alterations of histone post-translational modification levels in lymphoblastoid cell lines

BackgroundRadiation-induced alterations in posttranslational histone modifications (PTMs) may affect the cellular response to radiation damage in the DNA. If not reverted appropriately, altered PTM patterns may cause long-term alterations in gene expression regulation and thus lead to cancer. It is therefore important to characterize radiation-induced alterations in PTM patterns and the factors affecting them.MethodsA lymphoblastoid cell line established from a normal donor was used to screen for alterations in methylation levels at H3K4, H3K9, H3K27, and H4K20, as well as acetylation at H3K9, H3K56, H4K5, and H4K16, by quantitative Western Blot analysis at 15 min, 1 h and 24 h after irradiation with 2 Gy and 10 Gy. The variability of alterations in acetylation marks was in addition investigated in a panel of lymphoblastoid cell lines with differing radiosensitivity established from lung cancer patients.ResultsThe screening procedure demonstrated consistent hypomethylation at H3K4me3 and hypoacetylation at all acetylation marks tested. In the panel of lymphoblastoid cell lines, however, a high degree of inter-individual variability became apparent. Radiosensitive cell lines showed more pronounced and longer lasting H4K16 hypoacetylation than radioresistant lines, which correlates with higher levels of residual γ-H2AX foci after 24 h.ConclusionSo far, the factors affecting extent and duration of radiation-induced histone alterations are poorly defined. The present work hints at a high degree of inter-individual variability and a potential correlation of DNA damage repair capacity and alterations in PTM levels.

TSPYL5 SNPs: Association with Plasma Estradiol Concentrations and Aromatase Expression

We performed a discovery genome-wide association study to identify genetic factors associated with variation in plasma estradiol (E2) concentrations using DNA from 772 postmenopausal women with estrogen receptor (ER)-positive breast cancer prior to the initiation of aromatase inhibitor therapy. Association analyses showed that the single nucleotide polymorphisms (SNP) (rs1864729) with the lowest P value (P = 3.49E-08), mapped to chromosome 8 near TSPYL5. We also identified 17 imputed SNPs in or near TSPYL5 with P values < 5E-08, one of which, rs2583506, created a functional estrogen response element. We then used a panel of lymphoblastoid cell lines (LCLs) stably transfected with ERα with known genome-wide SNP genotypes to demonstrate that TSPYL5 expression increased after E2 exposure of cells heterozygous for variant TSPYL5 SNP genotypes, but not in those homozygous for wild-type alleles. TSPYL5 knockdown decreased, and overexpression increased aromatase (CYP19A1) expression in MCF-7 cells, LCLs, and adipocytes through the skin/adipose (I.4) promoter. Chromatin immunoprecipitation assay showed that TSPYL5 bound to the CYP19A1 I.4 promoter. A putative TSPYL5 binding motif was identified in 43 genes, and TSPYL5 appeared to function as a transcription factor for most of those genes. In summary, genome-wide significant SNPs in TSPYL5 were associated with elevated plasma E2 in postmenopausal breast cancer patients. SNP rs2583506 created a functional estrogen response element, and LCLs with variant SNP genotypes displayed increased E2-dependent TSPYL5 expression. TSPYL5 induced CYP19A1 expression and that of many other genes. These studies have revealed a novel mechanism for regulating aromatase expression and plasma E2 concentrations in postmenopausal women with ER(+) breast cancer.

Production and characterization of two murine monoclonal antibodies directed against epitopes exclusive to soluble fragments of Fc epsilon RII/CD23.

Two murine monoclonal antibodies (mAb) designated as SU1 and SU3 directed against soluble Fc epsilon RII/CD23 have been generated by fusing X.63.AG.8653 (a mouse myeloma cell line) with spleen cells from mice immunized with an Epstein Barr virus (EBV)-transformed B cell line (RPMI-8866). The antibodies have been shown to be capable of detecting affinity purified soluble Fc epsilon RII/CD23 in an enzyme-linked immunosorbent assay. Indirect immunofluorescence has shown that the SU1 and SU3 mAb do not stain RPMI-8866, a Fc epsilon RII/CD23+ B cell line. By studying the migration profiles of affinity purified SU1- and SU3-reactive molecules on sodium dodecylsulfate-polyacrylamide gel electrophoresis it has been shown that SU1 mAb immunoprecipitates 33- and 12-kDa components, while the SU3 mAb recognized 25- and 45-kDa proteins from culture supernatants of RPMI-8866 cells. Moreover, affinity purified SU1- and SU3-reactive proteins have been shown to be recognized by human IgE but not by the human IgG molecule. These results provide evidence that SU1 and SU3 mAb may recognize some putative post-cleavage epitopes on the N-terminal end of the low affinity receptor which appear, perhaps, following the process of fragmentation. In addition, the effect of these antibodies on continuous growth of a panel of lymphoblastoid cell lines indicates that SU1 mAb was found incapable of influencing the spontaneous proliferation of EBV-immortalized B cell lines; whereas SU3 mAb completely blocked the spontaneous growth and proliferation of all B cell lines tested. The results are discussed in relation to the appearance of a functional post-cleavage epitope on soluble Fc epsilon RII/CD23.

Expression and immunogenicity of HLA‐B27 in high‐transfection recipient P815: a new method to induce monoclonal antibodies directed against HLA‐B27

The immunization of a (BALB/c x C57BL/6) FI mouse with murine transfectants expressing the HLA-B27 antigen resulted in a panel of polymorphic monoclonal antibodies with specificity for HLA-B27 and some additional HLA-antigens. Specificity of the antibodies was defined by cytofluorometric analysis on a panel of lymphoblastoid cell lines (LCL) derived from HLA typed individuals. Three of these antibodies are cytotoxic, and one of them inhibits B27-specific T cell cytotoxicity. Our results indicate that HLA-class I transfectants could be used to generate polymorphic antibodies, and that these antibodies may be helpful for HLA typing and for definition of epitopes recognized by T cells.

Generation of long-term human cytolytic cell lines with persistent natural killer activity.

Human cell lines maintained by in vitro stimulation with the HLA-A, B-negative, DR-positive, Epstein Barr virus-transformed, lymphoblastoid cell line Daudi in the presence of conditioned medium demonstrated significant NK activity for over 6 wk in continuous culture. These cells lyse K562 and a broad panel of lymphoblastoid cell lines but do not lyse normal peripheral blood lymphocytes or pokeweed mitogen blasts. They possess the sheep red blood cell receptor but lack other T cell markers (Lyt-3+, OKT3-). Natural killer activity correlated with the presence of a Mac 1-positive subpopulation of cells present in these long-term lines.