ALBERT

Description: Highly-conserved LIN28 proteins regulate certain developmentally-timed events in multicellular organisms by decreasing the levels of let-7 miRNAs. It was recently reported that increased expression of LIN28 proteins or decreased expression of the target let-7 miRNAs in human erythroblasts cultured from healthy adult humans causes increased fetal hemoglobin expression. Here LIN28A expression in sickle cell donors’ cells was explored for its potential to regulate fetal and sickle hemoglobin, and to affect the morphological sickling of the mature erythrocytes. After obtaining consent and assent, CD34(+) cells from five pediatric research subjects with HbSS genotype (ages 9-16 years old) were harvested from discarded whole blood following partial manual exchange transfusions. Transgenic expression of LIN28A was accomplished using lentiviral transduction of human CD34(+) sickle cells cultivated ex vivo in serum-free medium for a total of 21 days. On culture day 14, LIN28A over-expression (LIN28A-OE) was confirmed by Q-RT-PCR (control: 8.6E+00 ± 8.1E+00 copies/ng, LIN28A-OE: 2.3E+05 ± 2.1E+05 copies/ng) and Western blot analyses. Erythroblast differentiation and terminal maturation were not affected by LIN28A-OE. Enucleation, as assessed by thiazole orange (TO) staining, was equivalent between the LIN28A-OE cells and control transductions (LIN28A-OE enucleation 40.8 ± 17.0% compared to control 49.9 ± 23.4%, p=0.19). LIN28A-OE strongly suppressed all members of the let-7 family of miRNAs, with average reductions from 66% to 96% for let-7a, let-7b, let-7c, let-7d, let-7e, let-7f-2, let-7g and let-7i. LIN28A-OE caused reduced expression of BCL11A, a known repressor of gamma-globin gene expression. Gamma-, beta (sickle)- and alpha-globin mRNA levels were also investigated by Q-RT-PCR. Gamma-globin mRNA expression levels were significantly increased in LIN28A-OE samples (control: 2.0E+06 ± 7.0E+05 copies/ng, LIN28A-OE: 2.0E+07 ± 6.0E+06 copies/ng, p=0.006), and beta (sickle)-globin mRNA significantly decreased in LIN28A-OE samples (control: 2.0E+07 ± 5.2E+06 copies/ng, LIN28A-OE: 1.6E+07 ± 6.3E+06 copies/ng, p=0.024). Differences in alpha-globin mRNA expression were not statistically significant. Hemoglobin chromatography (HPLC) demonstrated that LIN28A-OE significantly increased the proportion of fetal hemoglobin (HbF control: 10.8 ± 7.1%, LIN28A-OE: 40.1 ± 14.0%; p=0.003) that was balanced by a significant decrease in the proportion of sickle hemoglobin. HbA was not detected. For investigation of the sickling phenotype, enucleated [TO(-)] sickle erythrocytes from LIN28A-OE and control transductions of two subjects’ cells were sorted at the end of the culture period into duplicate tissue culture wells. The sorted erythrocytes were incubated in hypoxia (2% oxygen) for 16 hours, and imaged using inverted microscopy within three minutes after removal from the hypoxia incubator. Four random microscopic field images from each well were acquired. Blinded observers then scored the images from the control and LIN28A-OE transductions according to non-sickled versus sickled morphologies. Cultured erythrocytes from the control transductions demonstrated 86.3 ± 9.5% with sickled morphologies. By comparison, a significant reduction in sickling morphology was observed in the LIN28A-OE cells (56.2 ± 23.1% sickled morphologies; p=0.000009). These results demonstrate that transgenic expression of LIN28A during ex vivo erythropoiesis causes increased gamma-globin gene and protein expression balanced with decreased beta (sickle)-globin at levels that are sufficient to ameliorate hypoxia-related sickling of mature erythrocytes. Disclosures: No relevant conflicts of interest to declare.

Description: Abstract 2666 Acute erythroid stress causes elevated levels of fetal hemoglobin (HbF) in primates. However, relationships between the chronic erythroid stress in children with Sickle Cell Disease (HbSS) and HbF production are less well understood. For this study, peripheral blood from children with HbSS was analyzed within 72 hours of collection and storage at 4°C. The level of erythroid stress was determined by absolute reticulocyte counts (ARC) as well as reticulocyte flow cytometry phenotyping and sorting using CD71 (HiCD71, LoCD71 and NegCD71) and CD36. Immature reticulocytes were identified by HiCD71 expression and included the CD36+ population. Sorted populations from at least three subjects were utilized to assess fetal globin expression during reticulocyte maturation according to quantitative polymerase chain reaction (qPCR), and high pressure liquid chromatography (HPLC). While the number of gamma-globin mRNA copies/cell decreased with reticulocyte maturation, the ratio of gamma/gamma+beta mRNA remained stable. HbF protein levels in the HiCD71 and LoCD71 populations were equivalent for each patient with average values of 4.3±4.2% HiCD71 vs. 4.4±4.0% LoCD71, p=0.96. By comparison, HbF levels in the NegCD71 were increased in all subjects (14.2±9.5% NegCD71, p

Description: The design and evaluation of therapies for the sickle cell and β-thalassemia syndromes rely on our understanding of hemoglobin accumulation during human erythropoiesis. Here we report direct measurements of hemoglobin composition and messenger RNA (mRNA) levels in cultured CD34+ cells and correlate those measurements with studies of freshly obtained bone marrow samples. Hemoglobin levels in differentiating cells were also compared with morphologic, immunophenotypic, and cell cycle assessments. A population of large preproerythroblasts was first identified within 24 hours and became the dominant population by day 5. The transition from proerythroblast to basophilic normoblast occurred later, from days 7 to 9, and correlated with a peak of 74.1% ± 3.9% of the cells in the S phase of cell cycle. Orthochromatic normoblasts were the dominant and final cell type by day 13. High-performance liquid chromatography–based quantitation of fetal (HbF) and adult (HbA) hemoglobin and real-time polymerase chain reaction globin mRNA quantitation demonstrated a coordinate rise in the accumulation of both proteins and mRNA among these developmentally staged populations. Quantitative analyses on freshly sorted bone marrow populations demonstrated a similar rising pattern with β-globin and HbA as the dominant species at both early and late stages of differentiation. We found no evidence for HbF dominant populations or switching during differentiation in adult cells. Instead, rapid increases in both HbF (heterocellular) and HbA (pancellular) content were observed, which coincided with the apex in cell cycling and the proerythroblast-basophilic normoblast transition. Based on these measurements, we conclude that HbF and HbA content are regulated with the rate of proliferation during adult erythropoiesis.

Description: Growth differentiation factor 15 (GDF15) is a member of the TGF-beta superfamily of cytokines previously found to suppress hepcidin in primary human hepatocytes. GDF15 is secreted from human erythroblasts, and extremely high serum levels are present in β-thalassemia patients (Tanno et al., Nat. Med. 2007, 13, 1096–1101). To determine if elevated GDF15 levels are unique for thalassemia or more generally associated with iron-loading related to ineffective erythropoiesis, we determined the GDF15 levels, as well as, serum hepcidin (Swinkels DW et al, PLoS ONE PLoS ONE. 2008;3:e2706), ferritin, erythropoietin (EPO) and soluble transferrin receptor (sTfR) in patients with the congenital dyserythropoietic anemia type I (CDA I). Seventeen Israeli Bedouins with CDA I were studied, all homozygous for the founder R1040W mutation in the CDAN1 gene. All of the patients studied were young adults with a mean age of 29 years. Two patients previously underwent splenectomy, and one patient is currently transfusion-dependent. For comparison, ten healthy volunteers (HV) were studied. The mean level of GDF15 in CDA I patients was significantly elevated [10,239 ± 3,049 pg/ml (range 5,530–17,008) compared to 269 ± 238 pg/ml in healthy controls; p = 1.5×10−10]. Consistent with a previous study of dyserythropoietic anemia patients, significantly higher levels of soluble transferrin receptor were detected among the CDA I population (sTfR; CDA I, 86.4 ± 14.0 nmol/L; HV, 21.4 ± 6.2 nmol/L, p = 7.4×10−15). Serum EPO levels were also elevated (EPO; CDA I, 118 ± 59 IU/dL; HV, 2.0 ± 1.5 IU/dL, p = 2.3×10−7). For iron analyses, three patients with extensive transfusion histories were excluded. Among the remaining 14 patients, iron overload was demonstrated by elevated serum ferritin (CDA I, 916 ± 507 ng/ml; HV, 72 ± 60 ng/ml, p = 1.4×10−5). Despite the significant elevation in iron stores, significantly elevated levels of hepcidin 25 (Hep25) were not detected in the CDA I patients. Instead, a minor decrease in serum Hep25 levels were detected (Hep25; CDA I, 3.3 ± 2.8 nM; HV, 4.1 ± 3.0 nM, p = 0.27). Correlation analyses were performed between the iron parameters (Ferritin and Hep25) and GDF15, sTfR, or EPO levels. Only GDF15 demonstrated a significant positive correlation with ferritin and significant inverse correlations with Hep25 and the Hep25/Ferritin ratio. Weaker correlations with EPO were identified. Unexpectedly, the correlation trends for sTfR were opposite those of GDF15 in this group. These results demonstrate that GDF15 is immensely over-expressed in CDA I, and further suggest this cytokine contributes to hepcidin dysregulation and secondary hemochromatosis in humans with ineffective erythropoiesis.

Description: Abstract 683 Mitochondrial specialization in erythroblasts is important for efficient heme synthesis, with defects or reduced expression of several mitochondrial proteins causing anemia. Trafficking kinesin binding 2 (TRAK2) is known to participate in mitochondrial movement along microtubule by interacting with kinesin motor protein and making a complex with Miro that is localized on the mitochondrial outer membrane. Transcriptome data suggest that TRAK2 is highly and specifically expressed in early erythroid cells. Here the role of TRAK2 was studied among human CD34+ cells that were grown in ex vivo serum-free cultures supplemented with erythropoietin (EPO, total culture period 21 days). Quantitative PCR studies indicated that TRAK2 expression is highly regulated during erythropoiesis. Its expression pattern was nearly identical to aminolevulinate synthase 2, the erythroid specific enzyme for the committed step of the heme biosynthetic pathway, and mitoferrin 1, the erythroid specific mitochondrial iron transporter. Western analyses revealed that TRAK2 protein is detected as a doublet band with molecular weights of 130kD and 105kD. Mitochondrial co-localization of TRAK2 was verified by confocal microscopy in TRAK2-overexpressing K562 cells. To study a potential role of TRAK2 in erythropoiesis, TRAK2 expression was reduced in cultured human erythroid cells using lentiviral shRNA transduction. TRAK2 knockdown (TRAK2-KD) was confirmed by Western analysis in K562 cells. In primary erythroblasts, TRAK2-KD caused slight reduction of CD36+ immature erythroblasts at culture day 7 prior to the addition of EPO (CD36+ population 58% in control vs 40% in TRAK2-KD). After the addition of erythropoietin to the culture medium, TRAK2-KD severely restricted erythroblast proliferation (5.0 million cells/ml in control vs 0.25 million cells/ml in TRAK2-KD on culture day 18). Flow cytometric analyses showed that 90% in control cultures. Annexin-V staining indicated that more than 90% of cells had undergone apoptosis by day 14. These data suggest that TRAK2 expression is required for erythroid differentiation. As such, defects in TRAK2 expression should be considered in cases of unexplained anemia. The data also support the notion that mitochondrial location or mobility within erythroblasts may be important for iron trafficking or heme synthesis. Disclosures: No relevant conflicts of interest to declare.

Description: MicroRNAs are ~22nt-long small noncoding RNAs that negatively regulate expression of target proteins through mRNA degradation or translational repression. They are functionally important in diverse biological processes including development, oncogenesis, and hematopoiesis. To study a potential role of microRNA for regulating cellular changes during erythroid ontogeny, we examined microRNA abundance patterns in circulating erythroid cells during the fetal and adult stages of human development. Expression profiling of microRNA was performed using total RNA from 4 adult peripheral blood samples compared to 4 cord blood samples after depletion of plasma, platelets, and nucleated cells. Labeled RNA was hybridized to custom spotted array containing 474 human microRNAs species (miRBase release 9.1). Total RNA from Epstein-Barr virus (EBV)-transformed lymphoblastoid cell lines was used as a hybridization reference for all samples to generate microRNA abundance profile for each sample. Among the differentially expressed probe-pairs, 40 microRNAs were significantly up-regulated in adult erythroid cells and only 4 microRNAs were down-regulated (p 〈 0.01 and fold change 〉 2). Two microRNAs, miR-144 and miR-451, previously reported as being GATA-1 regulated in erythroid cells, were detected above the dynamic range of the array technology in all eight samples. Quantitative PCR was performed to further quantitate differences in the microRNA abundance profiles of the 10 most differentially expressed microRNAs as well as miR-144 and miR-451. Per published recommendations, miR-103 was used for signal normalization. Among the studied microRNAs, 8 of 12 demonstrated a more than 4 fold increase in abundance in adult erythroid cells compared to cord blood by qPCR. In particular, let-7d and let-7e demonstrated more than 10-fold increased expression in adult cells. Of note, let-7 microRNAs regulate metamorphic processes in model organisms and inhibit ras-associated growth of cancer cells. According to miRBase predictions, over 1200 genes may be targeted by the 8 microRNAs (p 〈 0.001). Examination of cord and adult reticulocyte mRNA expression profiles (Goh et al. Phy. Gen. 2007) revealed 24 developmentally downregulated genes as predicted targets. Among globin genes, only gamma globin is a predicted target. These findings demonstrate dramatic up-regulation of specific erythroid microRNAs during the fetal-to-adult transition of ontogeny, and support the notion that microRNAs function as developmental regulators of erythropoiesis and globin gene switching.

Description: Within the erythroid lineage, erythropoietin (EPO) responsiveness is manifested by cell division and growth as well as specific changes in heme and globin production that ultimately result in the production of erythrocytes. However, the nascent relationship between EPO-associated mitosis and globin gene regulation has not been fully defined. In this study, cultured adult human CD34+ cells from peripheral blood were used to investigate early cellular responses to erythropoietin in the context of mitosis. Matched cultures were performed in replicate using human cells from at least two healthy adults. To detect mitosis, one million cells were labeled with 2uM carboxyfluorescein diacetate succinamidyl ester (CFSE). The CFSE-labeled cells were then cultured in the presence [EPO(+)] or absence [EPO(−)] of 4U/mL EPO, and analyzed using flow cytometry. No cell divisions were detected in either condition during the first 24 hours in culture, and multiple cell divisions were noted on subsequent culture days only in the EPO(+) cultures. Remarkably, dual-staining with CFSE and CD71 revealed a small (90% of those cells. These novel results suggest that the frequency and levels of gamma-globin transcripts are quite low at the earliest stages of an EPO response among adult human CD34+ cells. However, it is clearly demonstrated that the cells can increase their capacity to import iron and transcribe beta-globin mRNA at very high levels prior to their first EPO-dependent cell division.

Description: Iron overload and bony abnormalities cause considerable morbidity among patients with thalassemia syndromes. One possible explanation for this phenomenon is that proteins normally secreted into the marrow microenvironment during erythropoiesis are over-expressed in thalassemia patients due to expanded and ineffective erythropoiesis. We previously discovered that GDF15 is produced at very high levels in thalassemia patients and inhibits hepcidin expression. Transcriptome screens of erythroblasts were utilized here to identify twisted gastrulation (TWSG1) as a second candidate protein for further study. Quantitative PCR using the β-thalassemia murine model (Hbbth3/+ β-thalassemia intermedia mouse model, n=13; Hbbth3/th3 β-thalassemia major mouse model, n=5) revealed that splenic expression levels of Tsg (murine TWSG1) were significantly higher in thalassemia mice (Hbbth3/+, 2.2E02 ± 2.7E01 copies/ng RNA, p

Description: Primary mediastinal large B-cell lymphoma (MLBCL) is a clinically distinct entity that typically presents as localized, sclerotic disease in young, female patients. We previously characterized the transcriptional profiles of MLBCLs and identified important shared features with a clinically related disorder, classical Hodgkin lymphoma (cHL) (Blood 102:3871, 2003). Given the documented role of the NFkB survival pathway in Hodgkin Reed-Sternberg cells, we previously assessed NFkB activation in MLBCL by determining the subcellular location of the c-REL subunit of the NFkB heterodimer with a 2-color immunofluoresence assay. In a small pilot MLBCL series, c-REL was localized to the nucleus in the majority of examined cases, consistent with NFkB activation. In the current study, we evaluated c-REL subcellular localization in an additional series of MLBCLs and DLBCLs using a broadly applicable immunoperoxidase method. 100% of MLBCLs exhibited nuclear c-REL staining whereas DLBCL c-REL subcellular localization was more variable. Thereafter, we analyzed the transcription profiles of the 34 MLBCLs and 176 DLBCLs for coordinate expression of NFkB target genes, using literature-curated NFkB target gene lists from three independent sources and gene set enrichment analysis (GSEA). MLBCL signatures exhibited significant enrichment of 2 of the 3 NFkB target gene sets. In addition, 32 NFkB target genes from the combined set were significantly more abundant in MLBCLs than DLBCLs (〉 30% more abundant and 〉 99th percentile in permutation analysis). Similar results were obtained in an independent series of MLBCLs and DLBCLs with available gene expression profiles (J. Exp. Med. 198:851, 2003). To assess the role of c-REL amplification in NFkB activation in our lymphoma series, we compared c-REL amplification, c-REL subcellular localization and coordinate expression of the identified NFkB target genes and classified the DLBCLs according to putative cell of origin. The majority of c-REL amplifications (67%) were found in DLBCLs of germinal center (GC) subtype, consistent with the observation that c-REL is part of the described GC signature. However, most (71%) of the examined GC DLBCLs had cytoplasmic c-REL expression and the GC DLBCLs did not have increased expression of NFkB target genes. Taken together with the MLBCL analyses, these studies indicate that: 1) NFkB is consistently activated in MLBCL; 2) c-REL amplification is not closely associated with NFkB activation in large cell lymphomas (LCLs); and 3) NFkB activation in LCL subtypes does not require amplification of the c-REL locus.

Description: The oncogene c-maf is frequently overexpressed in multiple myeloma cell lines and patient samples and contributes to increased cellular proliferation in part by inducing cyclin D2 expression. To identify regulators of c-maf, we developed a chemical screen in NIH3T3 cells stably overexpressing c-maf and the cyclin D2 promoter driving luciferase. From a screen of 2400 off-patent drugs and chemicals, we identified glucocorticoids as c-maf–dependent inhibitors of cyclin D2 transactivation. In multiple myeloma cell lines, glucocorticoids reduced levels of c-maf protein without influencing corresponding mRNA levels. Subsequent studies demonstrated that glucocorticoids increased ubiquitination-dependent degradation of c-maf and up-regulated ubiquitin C mRNA. Moreover, ectopic expression of ubiquitin C recapitulated the effects of glucocorticoids, demonstrating regulation of c-maf protein through the abundance of the ubiquitin substrate. Thus, using a chemical biology approach, we identified a novel mechanism of action of glucocorticoids and a novel mechanism by which levels of c-maf protein are regulated by the abundance of the ubiquitin substrate.