LCR 5′HS3 Displays Specificity for ε-Globin Gene Activation during Primitive Erythropoiesis and γ-Globin Gene Activation during Fetal Definitive Erythropoiesis.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 1213-1213
Author(s):  
Kenneth R. Peterson ◽  
Halyna Fedosyuk ◽  
Susanna Harju
Keyword(s):  
Gene Expression ◽  
Globin Gene ◽  
Gene Activation ◽  
Gene Promoter ◽  
Site Specificity ◽  
A Site ◽  
Primitive Erythropoiesis ◽  
Definitive Erythropoiesis ◽  
Globin Gene Expression ◽  
Specific Sequences

Abstract A 2.9 Kb deletion of 5′HS3 (Δ5′HS3) or a 234 bp deletion of the 5′HS3 core (Δ5′HS3c) in a 213 Kb human β-globin locus yeast artificial chromosome (β-YAC) abrogate ε-globin gene expression during primitive erythropoiesis in β-YAC transgenic mice, suggesting that HS sequences of the LCR are involved directly in ε-globin gene activation. The reduction of ε-globin gene transcription in Δ5′HS3 or Δ5′HS3c β-YAC transgenics can be explained by two hypotheses. The first is site-specificity. The interaction between the LCR and the ε-globin gene promoter involves specific sequences of 5′HS3 and specific sequences of the ε-globin gene promoter. When 5′HS3 or its core is deleted, these interactions do not take place and ε-globin gene transcription is diminished. The second hypothesis is change in conformation of the LCR. Normally, in the embryonic stage, the LCR achieves a three-dimensional conformation that favors interaction with the first gene in the complex, i.e., the ε-globin gene. When 5′HS3 is deleted, an alternate conformation is assumed that decreases the chance that there will be an interaction between the LCR and the ε-globin gene. However, the LCR interacts with the next gene in order, the γ-globin gene. In Δ5′HS3c β-YAC mice, γ-globin gene expression is normal during primitive erythropoiesis, but is extinguished in the fetal stage of definitive erythropoiesis. These data suggest that a conformational change occurs in the Δ5′HS3c LCR during the switch from embryonic to definitive erythropoiesis, from one that supports γ-globin gene expression to one that does not. Alternately, the embryonic trans-acting environment may allow the mutant LCR to interact with and activate the γ-globin genes, but the fetal trans-acting environment may not support this interaction in the absence of the 5′HS3 core. To distinguish between these possibilities, β-YAC lines were produced in which the ε-globin gene was replaced with a second marked β-globin gene (βm), coupled to either an intact LCR, a 2.9 Kb 5′HS3 deletion or a 234 bp 5′HS3 core deletion. Δ5′HS3c Δε::βm β-YAC mice expressed βm-globin throughout development beginning at day 10 in the yolk sac. γ-globin was expressed in the embryonic yolk sac, but not in the fetal liver. Some wild-type β-globin was expressed in addition to βm-globin in adult mice. The γ-globin phenotype is consistent with published data on Δ5′HS3c β-YAC mice. Although ε-globin was not expressed in Δ5′HS3c β-YAC mice, βm-globin was expressed in Δ5′HS3c Δε::βm β-YAC embryos, demonstrating that the 5′HS3 core was necessary for ε-globin expression during embryonic erythropoiesis, but not for βm-globin expression. These data support a site specificity model of LCR HS-globin gene interaction. In addition, nuclear ligation experiments provided evidence for a specific physical interaction between 5′HS3 and the γ-globin promoter during fetal definitive erythropoiesis, further supporting a site specificity model.

Human β-Globin Locus Control Region Hypersensitive Site Specificity for Globin Gene Activation during Erythropoiesis.

Blood ◽  
2005 ◽  
Vol 106 (11) ◽  
pp. 3630-3630
Author(s):  
Kenneth R. Peterson ◽  
Halyna Fedosyuk ◽  
Susanna Harju
Keyword(s):  
Gene Expression ◽  
Fetal Liver ◽  
Globin Gene ◽  
Gene Activation ◽  
Gene Promoter ◽  
Yolk Sac ◽  
Site Specificity ◽  
Globin Genes ◽  
Definitive Erythropoiesis ◽  
Globin Gene Expression

Abstract Although the human β-globin locus control region (LCR) functions as a holocomplex within an active chromatin hub, we provide evidence that within the aggregate hypersensitive site (HS) activation domain of the holocomplex, the individual HSs still mediate preferential activation of the globin genes during development. A 2.9 Kb deletion of 5′HS3 (Δ5′HS3) or a 234 bp deletion of the 5′HS3 core (Δ5′HS3c) in a 213 Kb human β-globin locus yeast artificial chromosome (β-YAC) abrogate ε-globin gene expression during primitive erythropoiesis in β-YAC transgenic mice, suggesting that 5′HS3 sequences of the LCR are involved directly in ε-globin gene activation. The reduction of ε-globin gene transcription in Δ5′HS3 or Δ5′HS3c β-YAC transgenics can be explained by two hypotheses. The first is site-specificity. The interaction between the LCR and the ε-globin gene promoter involves specific sequences of 5′HS3 and specific sequences of the ε-globin gene promoter. When 5′HS3 or its core is deleted, these interactions do not take place and ε-globin gene transcription is diminished. The second hypothesis is change in conformation of the LCR. Normally, in the embryonic stage, the LCR achieves a three-dimensional conformation that favors interaction with the first gene in the complex, the ε-globin gene. When 5′HS3 is deleted, an alternate conformation is assumed that decreases the chance that there will be an interaction between the LCR and the ε-globin gene. However, the LCR interacts with the next gene in order, the γ-globin gene. In Δ5′HS3c β-YAC mice, γ-globin gene expression is normal during primitive erythropoiesis, but is extinguished in the fetal stage of definitive erythropoiesis. These data suggest that a conformational change occurs in the Δ5′HS3c LCR during the switch from embryonic to definitive erythropoiesis, from one that supports γ-globin gene expression to one that does not. Alternately, the embryonic trans-acting environment may allow the mutant LCR to interact with and activate the γ-globin genes, but the fetal trans-acting environment may not support this interaction in the absence of the 5′HS3 core. To distinguish between these possibilities, β-YAC lines were produced in which the ε-globin gene was replaced with a second marked β-globin gene (βm), coupled to either an intact LCR, a 2.9 Kb 5′HS3 deletion or a 234 bp 5′HS3 core deletion. Δ5′HS3c Δε::βm β-YAC mice expressed βm-globin throughout development beginning at day 10 in the yolk sac. γ-globin was expressed in the embryonic yolk sac, but not in the fetal liver. Some wild-type β-globin was expressed in addition to βm-globin in adult mice. The γ-globin phenotype is consistent with published data on Δ5′HS3c β-YAC mice. Although ε-globin was not expressed in Δ5′HS3c β-YAC mice, βm-globin was expressed in Δ5′HS3c Δε::βm β-YAC embryos, demonstrating that the 5′HS3 core was necessary for ε-globin expression during embryonic erythropoiesis, but not for βm-globin expression. A similar phenotype was observed in Δ5′HS3 Δε::βm β-YAC mice, except βm-globin expression was higher in the day 10 yolk sac and γ-globin expression continued into the fetal liver stage of definitive erythropoiesis consistent with results published on Δ5′HS3 β-YAC mice. These data support a site specificity model of LCR HS-globin gene interaction.

Zebrafish KLF4 Is Essential for Primitive Haematopoiesis.

Blood ◽  
2005 ◽  
Vol 106 (11) ◽  
pp. 1746-1746
Author(s):  
Andrew C. Perkins ◽  
Melissa R. Gardiner
Keyword(s):  
Gene Expression ◽  
Gene Knockout ◽  
Globin Gene ◽  
Cell Mass ◽  
Intermediate Cell ◽  
Lateral Plate ◽  
Essentially Normal ◽  
Primitive Erythropoiesis ◽  
Definitive Erythropoiesis ◽  
Globin Gene Expression

Abstract Gene knockout studies of Krüppel-like factors (KLFs) in mice have demonstrated key roles in organogenesis. EKLF (Klf1) plays an essential role in definitive erythropoiesis and b-globin gene expression, but primitive (yolk sac) erythropoiesis and embryonic globin gene expression are essentially normal. Since expression of embryonic globin genes is dependent upon proximal CACC box elements, additional KLFs must function during the embryonic wave of erythropoiesis. A number of KLFs have been described in zebrafish. One of these, zKLF4, the homologue of neptune, a Xenopus Laevis KLF expressed in the ventral blood island, cement and hatching glands, is an early marker of lateral plate mesoderm (LPM). From 1 somite and prior to expression of scl and flk1, there is a continuous rim of expression of zKLF4 2–3 cells wide within the LPM extending from the postero-lateral boundary of the polster to the tail. Expression in the posterior lateral plate persists as it migrates medially in a zipper-like movement to generate the intermediate cell mass (ICM), the site of embryonic haematopoiesis. zKLF4 is also expressed in a patch of dorsal mesendodermal cells from 70% epiboly which are fated to become the polster. Morpholino knockdown of zKLF4 results in moderate anaemia which resolves as definitive erythropoiesis replaces primitive erythropoiesis at 48–72 hpf. zKLF4 morphants show a down-regulation in the expression of GATA-1 (>100 fold) and embryonic globin (>10 fold) by real time RT-PCR. Both are expressed during the primitive wave of haematopoiesis. In addition there is a dramatic up-regulation (>100 fold) in the level of cmyb expression in zKLF4 morphant compared to control embryos at 72 hpf, which is consistent with expansion of the secondary definitive wave of erythropoiesis, possibly in response to anemia. These results suggest mammalian KLF orthologs of zKLF4, either KLF4 or KLF2, may play roles in primitive erythropoiesis and embryonic globin gene expression in mice or man.

Alterations in Protein-DNA Interactions in the γ-Globin Gene Promoter in Response to Butyrate Therapy

Blood ◽  
1998 ◽  
Vol 92 (8) ◽  
pp. 2924-2933 ◽  
Author(s):  
Tohru Ikuta ◽  
Yuet Wai Kan ◽  
Paul S. Swerdlow ◽  
Douglas V. Faller ◽  
Susan P. Perrine
Keyword(s):  
Gene Expression ◽  
Globin Gene ◽  
Gene Promoter ◽  
Dna Interactions ◽  
Globin Mrna ◽  
Mobility Shift ◽  
Protein Dna Interactions ◽  
American Society ◽  
Globin Gene Expression

Abstract The mechanisms by which pharmacologic agents stimulate γ-globin gene expression in β-globin disorders has not been fully established at the molecular level. In studies described here, nucleated erythroblasts were isolated from patients with β-globin disorders before and with butyrate therapy, and globin biosynthesis, mRNA, and protein-DNA interactions were examined. Expression of γ-globin mRNA increased twofold to sixfold above baseline with butyrate therapy in 7 of 8 patients studied. A 15% to 50% increase in γ-globin protein synthetic levels above baseline γ globin ratios and a relative decrease in β-globin biosynthesis were observed in responsive patients. Extensive new in vivo footprints were detected in erythroblasts of responsive patients in four regions of the γ-globin gene promoter, designated butyrate-response elements gamma 1-4 (BRE-G1-4). Electrophoretic mobility shift assays using BRE-G1 sequences as a probe demonstrated that new binding of two erythroid-specific proteins and one ubiquitous protein, CP2, occurred with treatment in the responsive patients and did not occur in the nonresponder. The BRE-G1 sequence conferred butyrate inducibility in reporter gene assays. These in vivo protein-DNA interactions in human erythroblasts in which γ-globin gene expression is being altered strongly suggest that nuclear protein binding, including CP2, to the BRE-G1 region of the γ-globin gene promoter mediates butyrate activity on γ-globin gene expression. © 1998 by The American Society of Hematology.

scholarly journals BCL2L1 is associated with γ-globin gene expression

2019 ◽  
Vol 3 (20) ◽  
pp. 2995-3001
Author(s):  
Yan Dai ◽  
Elmutaz M. Shaikho ◽  
Jessica Perez ◽  
Carolyn A. Wilson ◽  
Lesley Y. Liu ◽  
...  
Keyword(s):  
Gene Expression ◽  
Globin Gene ◽  
Gene Activation ◽  
Key Points ◽  
Globin Gene Expression

Key Points BCL2L1 is associated with HbF gene activation.

Effect of LCR 5′HS4 and 5′HS1 Deletions on β-Like Globin Gene Expression in β-Yac Transgenic Mice.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 1209-1209
Author(s):  
Susanna Harju ◽  
Halyna Fedosyuk ◽  
Kenneth R. Peterson
Keyword(s):  
Gene Expression ◽  
Homologous Recombination ◽  
Globin Gene ◽  
Developmental Expression ◽  
Mrna Levels ◽  
Wild Type ◽  
Rnase Protection ◽  
Transgenic Lines ◽  
Definitive Erythropoiesis ◽  
Globin Gene Expression

Abstract A 213 Kb human β-globin locus yeast artificial chromosome (β-YAC) was modified by homologous recombination to delete 2.9 Kb of cross-species conserved sequence similarity encompassing the LCR 5′HS4 (Δ5′HS4 β-YAC). Three transgenic mouse lines were established; each contained two intact copies of the β-globin locus as determined by long range restriction enzyme mapping (LRRM) and Southern blot hybridization analyses. Human ε-, γ- and β-globin, and mouse α- and ζ-globin mRNAs were measured by RNAse protection in hematopoietic tissues derived from staged embryos, fetuses and adult mice. No difference in the temporal pattern of globin transgene expression was observed between Δ5′HS4 β-YAC mice and wild-type β-YAC mice. In addition, quantitative per-copy human β-like globin mRNA levels were similar between Δ5′HS4 and wild-type β-YAC transgenic lines, although γ-globin gene expression was slightly increased in the fetal liver, while β-globin gene expression was slightly decreased in Δ5′HS4 β-YAC mice. These data are in contrast to data obtained from β-YAC mice containing a deletion of the 280 bp 5′HS4 core. In these mice, γ- and β-globin gene expression was significantly decreased during fetal definitive erythropoiesis and β-globin gene expression was decreased during adult definitive erythropoiesis. However, these data are consistent with the observation that deletion of the 5′HS core elements is more deleterious than large deletions of the 5′HSs. Together, the compiled deletion data supports the hypothesis that the LCR exists as a holocomplex in which the 5′HS cores form an active site and the flanking 5′HS regions constrain the holocomplex conformation. In this model, 5′HS core mutations are dominant negative, whereas larger deletions allow the LCR to fold into alternate holocomplex structures that function normally, albeit less efficiently. To complete the study on the contribution of the individual 5′HSs to LCR function, a 0.8 Kb 5′HS1 fragment was deleted in the 213 Kb β-YAC by homologous recombination. Two ΔHS1 β-YAC transgenic lines have been established; four additional founders were recently identified. Of the two lines, one contains two intact copies of the globin locus; the other contains four deleted copies, one of which extends from the LCR through just 5′ to the β-globin gene. For both lines, ε-globin gene expression was markedly reduced, approximately 5–10 fold, during primitive erythropoiesis. Developmental expression profiles and levels of the γ- and β-globin genes (in the line that contains loci including the β-globin gene) were unaffected by deletion of 5′HS1. Breeding of the remaining four founders to obtain F1 and F2 progeny for similar structure/function studies is in progress. Decreased expression of the β-globin gene is the first phenotype ascribed to a 5′HS1 mutation, suggesting that this HS does indeed have a role in LCR function.

scholarly journals Investigations of a Human Embryonic Globin Gene Silencing Element Using YAC Transgenic Mice

2006 ◽  
Vol 231 (3) ◽  
pp. 328-334 ◽  
Author(s):  
Patrick A. Navas ◽  
Qiliang Li ◽  
Kenneth R. Peterson ◽  
George Stamatoyannopoulos
Keyword(s):  
Gene Expression ◽  
Transgenic Mice ◽  
Yeast Artificial Chromosome ◽  
Globin Gene ◽  
Gene Promoter ◽  
Developmental Expression ◽  
Mrna Levels ◽  
Globin Genes ◽  
Embryonic Cells ◽  
Globin Gene Expression

A silencing element has been previously located upstream of the human ε-globin gene promoter using transient assays and transgenic mice carrying plasmid constructs in which the element has been deleted or its transcriptional motifs have been mutated. To investigate whether this element functions in the context of the whole β-globin locus, we analyzed ε-globin gene expression in transgenic mice carrying a deletion of the silencing element in the context of a 213-kilobase human β-globin yeast artificial chromosome (β-YAC). ε-Globin gene expression was measured during embryonic and fetal development and in adult mice. ε-mRNA levels in embryonic cells in Day 12 blood were as high as those measured in wild-type β-YAC controls, indicating that the deletion does not affect ε gene promoter function. ε-Globin gene expression was confined to the embryonic cells, indicating that deletion of this silencing element did not affect ε-globin developmental expression in the context of the β-YAC. These results suggest that in the context of the whole β-globin locus, other proximal and upstream ε gene promoter elements as well as competition by the downstream globin genes contribute to the silencing of the ε-globin gene in the cells of definitive erythropoiesis.

EKLF Is Recruited to the γ-Globin Gene Promoter as a Co-Activator and Is Required for γ-Globin Gene Induction by Short-Chain Fatty Acids.

Blood ◽  
2007 ◽  
Vol 110 (11) ◽  
pp. 1771-1771
Author(s):  
Susan P. Perrine ◽  
Rishikesh Mankidy ◽  
Michael S. Boosalis ◽  
James J. Bieker ◽  
Douglas V. Faller
Keyword(s):  
Gene Expression ◽  
Globin Gene ◽  
Gene Promoter ◽  
Gene Induction ◽  
Therapeutic Interventions ◽  
Short Chain ◽  
Dependent Manner ◽  
Erythroid Progenitors ◽  
Globin Promoter ◽  
Globin Gene Expression

Abstract The erythroid Kruppel-like factor, EKLF, is an essential transcription factor for mammalian β-type globin gene switching, and specifically activates transcription of the adult β-globin gene through binding of its zinc finger domain to the β-globin promoter. We report now that EKLF is also required for activation of the γ-globin gene by short-chain fatty acid (SCFA) derivatives. We found that specific knockdown of EKLF levels by siRNA prevents SCFA induced-expression of an integrated γ-globin promoter in a stably-expressed mLCRβprRluc AγprFluc cassette, and prevents induction of the endogenous γ-globin gene in primary human erythroid progenitors. In chromatin immunoprecipitation (ChIP) assays, EKLF was found to be actively recruited to the endogenous γ-globin gene promoter with exposure of human erythroid progenitors, and hematopoietic cell lines, to SCFA derivatives. The human SWI/WNF complex is a ubiquitous multimeric complex that regulates gene expression by remodeling nucleosomal structure in an ATP-dependent manner. We found that the SWI/SNF complex chromatin-modifying core ATPase BRG1 is also required for γ-globin gene induction by SCFA derivatives. Furthermore, BRG1 is actively recruited to the endogenous γ-globin promoter of human erythroid progenitors with exposure to SCFA derivatives, and this recruitment is dependent upon the presence of EKLF. These findings all demonstrate that EKLF, and the co-activator BRG1, previously demonstrated to be required for definitive or adult erythropoietic patterns of globin gene expression, are co-opted by SCFA derivatives to activate the fetal globin genes. Recently. we also identified a γ-globin-specific repressor complex, consisting of NCoR and HDAC3, which is displaced from the proximal γ-globin promoter by exposure to SCFA derivatives prior to activation of transcription (Blood, 108:3179–86, 2006). Collectively, these studies identify critical activating and repressing cofactors regulating γ-globin gene expression, and provide new targets for therapeutic interventions.

The -566 Aγ-Globin HPFH Mutation Disrupts Temporal Repression of Fetal Hemoglobin Synthesis During Fetal Liver Definitive Erythropoiesis.

Blood ◽  
2009 ◽  
Vol 114 (22) ◽  
pp. 2019-2019
Author(s):  
Kenneth R Peterson ◽  
Halyna Fedosyuk ◽  
Flavia C Costa
Keyword(s):  
Gene Expression ◽  
Transgenic Mice ◽  
Fetal Liver ◽  
Globin Gene ◽  
Fetal Hemoglobin ◽  
Wild Type ◽  
Repressor Complex ◽  
Definitive Erythropoiesis ◽  
Gata Motif ◽  
Globin Gene Expression

Abstract Abstract 2019 Poster Board I-1041 Hereditary persistence of fetal hemoglobin (HPFH) is a condition associated with continued fetal hemoglobin (HbF) production in adults, where normally only very low levels of HbF are found. Sickle cell disease (SCD) patients are phenotypically normal if they carry a compensatory HPFH mutation due to the high levels of HbF. Understanding the molecular mechanisms leading to reactivation or derepression of γ-globin gene expression will lead to the development of new or better therapies to treat SCD patients. In our long-established and highly-characterized model system, transgenic mice carrying wild-type human β-globin locus yeast artificial chromosomes (β-YACs) express predominantly γ-globin and a lesser amount of γ-globin in the primitive erythroid cells of the yolk sac, mostly β-globin and some γ-globin in the definitive erythroid cells of the fetal liver and nearly exclusively β-globin in the adult definitive red blood cells, as measured both at the transcript and protein levels. We recently identified a novel Aγ-globin gene silencer motif located at -566 relative to the mRNA CAP site in a GATA motif. Repression is mediated by binding a GATA-1-FOG-1-Mi2 protein complex. Since our initial studies of this GATA-1 repressor complex were performed using β-YAC transgenic mice in which a second copy of the Aγ-globin gene was introduced between the locus control region (LCR) and the γ-globin gene, our first goal was to test if this mutation was functional at the normally-located Aγ-globin globin gene. β-YAC transgenic mice were produced with the T>G HPFH point mutation at the -566 GATA site of this gene. These mice display a mild HPFH phenotype during adult definitive erythropoiesis; γ-globin gene expression levels were increased approximately 3% compared to wild-type β-YAC mice. Expression of γ-globin is also elevated relative to wild-type β-YAC controls during primitive erythropoiesis in the embryonic yolk sac and definitive erythropoiesis in the fetal liver. Chromatin immunoprecipitation (ChIP) experiments using day E12 to E18 post-conception fetal liver samples from wild type β-YAC transgenic mice demonstrate that GATA-1 is recruited to this GATA silencer first at day E16, followed by recruitment of FOG-1 and Mi2 at day E17. In addition, ChIP experiments performed with day E18 samples from the -566 HPFH mice demonstrate that this point mutation disrupts the recruitment of GATA-1 to this site at a developmental stage when it normally binds as a repressor in wild-type β-YAC transgenic samples. GATA-2 does not bind at the -566 GATA motif when γ-globin is actively transcribed. Thus, GATA-2/GATA-1 competition does not play a role in the function of this silencer or the mechanism of HPFH at this site. In addition, BCL11A does not appear to be a component of this GATA-1 repressor complex. Taken together our data indicate that a temporal repression mechanism is operative in the silencing of γ-globin gene expression and that the presence of the -566 Aγ-globin HPFH mutation disrupts establishment of repression, resulting in continued γ-globin gene transcription during adult definitive erythropoiesis. Disclosures: No relevant conflicts of interest to declare.

Erythroid Kruppel-like factor (EKLF) coordinates erythroid cell proliferation and hemoglobinization in cell lines derived from EKLF null mice

Blood ◽  
2001 ◽  
Vol 97 (6) ◽  
pp. 1861-1868 ◽  
Author(s):  
Elise Coghill ◽  
Sarah Eccleston ◽  
Vanessa Fox ◽  
Loretta Cerruti ◽  
Clark Brown ◽  
...  
Keyword(s):  
Gene Expression ◽  
Cell Lines ◽  
Target Genes ◽  
Fetal Liver ◽  
Globin Gene ◽  
Single Copy ◽  
Erythroid Cell ◽  
Functional Analyses ◽  
Definitive Erythropoiesis ◽  
Globin Gene Expression

Erythroid Kruppel-like factor (EKLF) is a transcription factor of the C2H2 zinc-finger class that is essential for definitive erythropoiesis. We generated immortal erythroid cell lines from EKLF−/− fetal liver progenitor cells that harbor a single copy of the entire human β-globin locus and then reintroduced EKLF as a tamoxifen-inducible, EKLF–mutant estrogen receptor (EKLF-ER™) fusion protein. Addition of tamoxifen resulted in enhanced differentiation and hemoglobinization, coupled with reduced proliferation. Human β-globin gene expression increased significantly, whereas γ-globin transcripts remained elevated at levels close to endogenous mouse α-globin transcript levels. We conclude that EKLF plays a role in regulation of the cell cycle and hemoglobinization in addition to its role in β-globin gene expression. The cell lines we used will facilitate structural and functional analyses of EKLF in these processes and provide useful tools for the elucidation of nonglobin EKLF target genes.

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