Activation of the beta-globin promoter by the locus control region correlates with binding of a novel factor to the CAAT box in murine erythroleukemia cells but not in K562 cells

ZmDof30 Negatively Regulates the Promoter Activity of the Pollen-Specific Gene Zm908

The maize (Zea mays) pollen-predominant gene Zm908, a novel small-peptide gene, was reported to play critical roles in pollen germination and pollen tube growth in our previous work. In this study, we aimed to explore the regulatory mechanism of Zm908. The putative promoter of Zm908 was cloned and analyzed. The activity analysis of a series of promoter truncations in different tissues of transgenic tobacco plants indicated that the Zm908 promoter is pollen-specific and that the -126 to -68 region is crucial for pollen expression. The 5' deletion analysis of the -126 to -68 region revealed that the -126 to -102 region functions as a transcriptional suppression element. ZmDof30, which is predominantly expressed in pollen and whole anthers, was cloned and characterized. ZmDof30-GFP localized to the nuclei of maize protoplasts and possessed no transcriptional activation activity in a yeast system. ZmDof30 could bind to the AAAG elements in p184 sequence containing the -126 to +58 region of the Zm908 promoter in vitro and in vivo, and negatively regulated p184 activity in tobacco leaves. Collectively, ZmDof30 may function as a Zm908 transcriptional repressor in pollen, and these results may provide a better understanding of the regulation of the Zm908 gene. Additionally, the pollen-specific Zm908 promoter may be valuable for genetically engineering male sterility.

The regulation of human globin promoters by CCAAT box elements and the recruitment of NF-Y

CCAAT boxes are motifs found within the proximal promoter of many genes, including the human globin genes. The highly conserved nature of CCAAT box motifs within the promoter region of both α-like and β-like globin genes emphasises the functional importance of the CCAAT sequence in globin gene regulation. Mutations within the β-globin CCAAT box result in β-thalassaemia, while mutations within the distal γ-globin CCAAT box cause the Hereditary Persistence of Foetal Haemoglobin, a benign condition which results in continued γ-globin expression during adult life. Understanding the transcriptional regulation of the globin genes is of particular interest, as reactivating the foetal γ-globin gene alleviates the symptoms of β-thalassaemia and sickle cell anaemia. NF-Y is considered to be the primary activating transcription factor which binds to globin CCAAT box motifs. Here we review recruitment of NF-Y to globin CCAAT boxes and the role NF-Y plays in regulating globin gene expression. This article is part of a Special Issue entitled: Nuclear Factor Y in Development and Disease, edited by Prof. Roberto Mantovani.

C/EBPδ and C/EBPγ bind the CCAAT-box in the human β-globin promoter and modulate the activity of the CACC-box binding protein, EKLF

Developmental- and tissue-specific expression of globin genes is mediated by a few key elements within the proximal promoter of each gene. DNA-binding assays previously identified NF-Y, GATA-1, C/EBPbeta and C/EBPgamma as candidate regulators of beta-globin transcription via the CCAAT-box, a promoter element situated between CACC- and TATA-boxes. We have identified C/EBPdelta as an additional beta-globin CCAAT-box binding protein. In reporter assays, we show that C/EBPdelta can co-operate with EKLF, a CACC-box binding protein, to activate the beta-globin promoter, whereas C/EBPgamma inhibits the transcriptional activity of EKLF in this assay.

The tkNeo gene, but not the pgkPuro gene, can influence the ability of the beta-globin LCR to enhance and confer position-independent expression onto the beta-globin gene

Whether drug-selectable genes can influence expression of the beta-globin gene linked to its LCR was assessed here. With the tkNeo gene placed in cis and used to select transfected cells, the beta-globin gene was expressed fourfold lower when it was positioned upstream of the LCR rather than downstream. This difference did not occur when the pgkPuro gene replaced tkNeo. Moreover, the beta-globin gene situated upstream of the LCR was transcribed without position effects when it was cotransfected with a pgkPuro-containing plasmid, whereas cotransfection with a tkNeo plasmid gave measurable position effects. Previous results from transfected cells selected via a linked tkNeo gene suggested that the 3' end of the beta-globin gene has no impact on LCR-enhanced expression. Here, removal of the 3' end of the beta-globin gene resulted in lower and much more variable expression in both transgenic mice and cells cotransfected with pgkPuro. Together, the results suggest that tkNeo, but not pgkPuro, can strongly influence expression of the beta-globin gene linked to its LCR. The findings could partly explain why data on beta-globin gene regulation obtained from transfected cells have often not agreed with those obtained using transgenic mice. Hence, one must be careful in choosing a drug-selectable gene for cell transfection studies.

Expression of a human beta-globin transgene in mice with the CACC motif and upstream sequences deleted from the promoter still depends on erythroid Krüppel-like factor

Mice in which the erythroid Krüppel-like Factor (EKLF) gene is inactivated die in fetal life due to down-regulation of the beta-globin gene. Results have suggested that EKLF functions through the proximal CACC motif of the beta-globin promoter. For example, natural mutations of this element that fail to bind EKLF give reduced gene expression and the ability of EKLF to activate reporter genes in co-transfection assays is dependent on an intact CACC. Here, removal of the CACC motif and upstream promoter sequences from the beta-globin gene resulted in reduced expression in transgenic mice. However, breeding onto an EKLF-/- background demonstrated that a CACC-less beta-globin transgene remains highly dependent on EKLF. Hence, although the beta-globin gene partly depends on the proximal CACC motif for expression, it is unlikely that the major mechanism of gene activation by EKLF is through this element. We also show that a lacZ reporter gene linked to the beta-globin promoter, with or without the CACC box present, is actually expressed higher in EKLF-/- fetuses than in wild type animals, suggesting that EKLF may be able to act as an inhibitor of transcription with certain transgene configurations.

The gamma-globin promoter has a major role in competitive inhibition of beta-globin gene expression in early erythroid development

The human gamma-globin gene competitively inhibits beta-globin gene expression in early erythroid development. To identify the gamma-globin gene sequences required for this effect, transgenic mice and stable transfection analyses with constructs containing 5'HS2 from the locus control region, modified gamma-globin genes, and the beta-globin gene were used. The -136 to +56 region of the gamma-globin promoter is necessary for competitive inhibition, as the beta-globin gene was inappropriately expressed in mouse embryos and in K562 and HEL cells containing constructs in which this region was deleted. Independently, the -140 to +56 region of gamma-globin gene was not sufficient to inhibit beta-globin transcription in mouse embryos or in cultured cells. Competitive inhibition of beta-globin gene expression was observed in K562 and HEL cells having a gamma-globin gene with a -161 promoter. The data suggest that the -161 gamma-globin promoter, which includes the CACCC box, two CCAAT boxes, the stage selector element (SSE), and TATA box, has a major role in suppressing beta-globin transcription early in development. Proteins binding to these or other gamma-globin promoter elements may interact with those binding to the locus control region, consequently precluding beta-globin transcription.

Oncogenic transformation-dependent expression of a transcription factor NF-Y subunit

As a result of differential splicing, one subunit of the nuclear factor Y (NF-Y) consists of two major isoforms designated short (NF-YaS) and long (NF-YaL). In proliferating normal human fibroblasts, NF-YaL is by far the more expressed isoform. Surprisingly, NF-YaS was found by immunoblotting to be as prominent as NF-YaL in simian virus 40 (SV40)-transformed cell derivatives. As a consequence, two NF-Y/DNA complexes, one containing the long and the other the short isoform, were formed with extracts from transformed cells and a target promoter element in electrophoretic mobility-shift assays. Only the complex containing NF-YaL was detected with extracts from normal fibroblasts. Furthermore, the NF-Y recognition motif contributed to promoter activation in SV40-transformed cells but not in normal, cells. Our finding links transcription stimulation in transformed cells to quantitative changes in the expression of an NF-Ya subunit.

NF-Y organizes the gamma-globin CCAAT boxes region

The CCAAT-binding activator NF-Y is formed by three evolutionary conserved subunits, two of which contain putative histone-like domains. We investigated NF-Y binding to all CCAAT boxes of globin promoters in direct binding, competition, and supershift electrophoretic mobility shift assay; we found that the alpha, zeta, and proximal gamma CCAAT boxes of human and the prosimian Galago bind avidly, and distal gamma CCAAT boxes have intermediate affinity, whereas the epsilon and beta sequences bind NF-Y very poorly. We developed an efficient in vitro transcription system from erythroid K562 cells and established that both the distal and the proximal CCAAT boxes are important for optimal gamma-globin promoter activity. Surprisingly, NF-Y binding to a mutated distal CCAAT box (a C to T at position -114) is remarkably increased upon occupancy of the high affinity proximal element, located 27 base pairs away. Shortening the distance between the two CCAAT boxes progressively prevents simultaneous CCAAT binding, indicating that NF-Y interacts in a mutually exclusive way with CCAAT boxes closer than 24 base pairs apart. A combination of circular permutation and phasing analysis proved that (i) NF-Y-induced angles of the two gamma-globin CCAAT boxes have similar amplitudes; (ii) occupancy of the two CCAAT boxes leads to compensatory distortions; (iii) the two NF-Y bends are spatially oriented with combined twisting angles of about 100 degrees. Interestingly, such distortions are reminiscent of core histone-DNA interactions. We conclude that NF-Y binding imposes a high level of functionally important coordinate organization to the gamma-globin promoter.

Erythroid Krüppel-Like Factor Is Essential for β-Globin Gene Expression Even in Absence of Gene Competition, But Is Not Sufficient to Induce the Switch From γ-Globin to β-Globin Gene Expression

Different genes in the β-like globin locus are expressed at specific times during development. This is controlled, in part, by competition between the genes for activation by the locus control region. In mice, gene inactivation of the erythroid Krüppel-like factor (EKLF) transcription factor results in a lethal anemia due to a specific and substantial decrease in expression of the fetal/adult-stage–specific β-globin gene. In transgenic mice carrying the complete human β-globin locus, EKLF ablation not only impairs human β-globin–gene expression but also results in increased expression of the human γ-globin genes during the fetal/adult stages. Hence, it may appear that EKLF is a determining factor for the developmental switch from γ-globin to β-globin transcription. However, we show here that the function of EKLF for β-globin–gene expression is necessary even in absence of gene competition. Moreover, EKLF is not developmental specific and is present and functional before the switch from γ-globin to β-globin–gene expression occurs. Thus, EKLF is not the primary factor that controls the switch. We suggest that autonomous repression of γ-globin transcription that occurs during late fetal development is likely to be the initiating event that induces the switch.

Erythroid Krüppel-Like Factor Is Essential for β-Globin Gene Expression Even in Absence of Gene Competition, But Is Not Sufficient to Induce the Switch From γ-Globin to β-Globin Gene Expression

Different genes in the β-like globin locus are expressed at specific times during development. This is controlled, in part, by competition between the genes for activation by the locus control region. In mice, gene inactivation of the erythroid Krüppel-like factor (EKLF) transcription factor results in a lethal anemia due to a specific and substantial decrease in expression of the fetal/adult-stage–specific β-globin gene. In transgenic mice carrying the complete human β-globin locus, EKLF ablation not only impairs human β-globin–gene expression but also results in increased expression of the human γ-globin genes during the fetal/adult stages. Hence, it may appear that EKLF is a determining factor for the developmental switch from γ-globin to β-globin transcription. However, we show here that the function of EKLF for β-globin–gene expression is necessary even in absence of gene competition. Moreover, EKLF is not developmental specific and is present and functional before the switch from γ-globin to β-globin–gene expression occurs. Thus, EKLF is not the primary factor that controls the switch. We suggest that autonomous repression of γ-globin transcription that occurs during late fetal development is likely to be the initiating event that induces the switch.

Gamma-Globin Gene Promoter Elements Required for Interaction With Globin Enhancers

Normal expression of the human β-globin domain genes is dependent on at least three types of regulatory elements located within the β-globin domain: the locus control region (LCR), globin enhancer elements (3′β and 3′Aγ), and the individual globin gene promoter and upstream regions. It has been postulated that regulation occurs through physical interactions between factors bound to these elements, which are located at considerable distances from each other. To identify the elements required for promoter-enhancer interactions from a distance, we have investigated the expression of the wild-type, truncated, and mutated γ-globin promoters linked to the 5′HS2 enhancer. We show that in K562 cells, 5′HS2 increases activity approximately 20-fold from both a wild-type and truncated (-135 → +25) γ promoter and that truncation or site-directed mutagenesis of the tandem CCAAT boxes eliminated the enhancement by 5′HS2. Mutation of the γ-globin gene promoter GATA-1 binding sites did not decrease either promoter strength or enhancement of activity by 5′HS2. To determine if enhanced expression of γ-globin gene promoters carrying mutations associated with hereditary persistence of fetal hemoglobin (HPFH) was due to greater interactions with enhancers, we linked these HPFH γ-globin gene promoters to 5′HS2 and demonstrated a twofold to threefold higher expression than the corresponding wild-type promoter plus enhancer in MEL cells. Addition of the Aγ-globin gene 3′ enhancer to a plasmid containing the γ-globin gene promoter and 5′HS2 did not further enhance promoter strength. Furthermore, we have demonstrated that the previously identified core 5′HS2 enhancer (46-bp tandem AP-1/NF-E2 sites) increased expression only when located 5′, but not 3′, to the γ-globin-luciferase reporter gene, suggesting that its enhancer effect is not by DNA looping. Our results suggest that CCAAT boxes, but not GATA or CACCC binding sites, are required for interaction between the γ-globin promoter and the LCR/5′HS2 and that regulatory elements in addition to the core enhancer may be required for the enhancer to act from a distance.

Gamma-Globin Gene Promoter Elements Required for Interaction With Globin Enhancers

Normal expression of the human β-globin domain genes is dependent on at least three types of regulatory elements located within the β-globin domain: the locus control region (LCR), globin enhancer elements (3′β and 3′Aγ), and the individual globin gene promoter and upstream regions. It has been postulated that regulation occurs through physical interactions between factors bound to these elements, which are located at considerable distances from each other. To identify the elements required for promoter-enhancer interactions from a distance, we have investigated the expression of the wild-type, truncated, and mutated γ-globin promoters linked to the 5′HS2 enhancer. We show that in K562 cells, 5′HS2 increases activity approximately 20-fold from both a wild-type and truncated (-135 → +25) γ promoter and that truncation or site-directed mutagenesis of the tandem CCAAT boxes eliminated the enhancement by 5′HS2. Mutation of the γ-globin gene promoter GATA-1 binding sites did not decrease either promoter strength or enhancement of activity by 5′HS2. To determine if enhanced expression of γ-globin gene promoters carrying mutations associated with hereditary persistence of fetal hemoglobin (HPFH) was due to greater interactions with enhancers, we linked these HPFH γ-globin gene promoters to 5′HS2 and demonstrated a twofold to threefold higher expression than the corresponding wild-type promoter plus enhancer in MEL cells. Addition of the Aγ-globin gene 3′ enhancer to a plasmid containing the γ-globin gene promoter and 5′HS2 did not further enhance promoter strength. Furthermore, we have demonstrated that the previously identified core 5′HS2 enhancer (46-bp tandem AP-1/NF-E2 sites) increased expression only when located 5′, but not 3′, to the γ-globin-luciferase reporter gene, suggesting that its enhancer effect is not by DNA looping. Our results suggest that CCAAT boxes, but not GATA or CACCC binding sites, are required for interaction between the γ-globin promoter and the LCR/5′HS2 and that regulatory elements in addition to the core enhancer may be required for the enhancer to act from a distance.

The beta-globin locus control region enhances transcription of but does not confer position-independent expression onto the lacZ gene in transgenic mice

The beta-globin locus control region (LCR) confers high levels of position-independent, copy number-dependent expression onto globin transgenes. Here > 40 independent transgenic mouse lines and founders that carried the LCR in cis with the beta-globin gene promoter driving a lacZ reporter gene were studied. Expression of the lacZ transgene was assayed by measuring beta-galactosidase enzyme activity in fetal liver extracts, the levels of which correlated with the quantity of lacZ mRNA determined using RNase protection assays. Unexpectedly, expression of the lacZ transgene was found to show strong position effects, varying as much as 700-fold per transgene copy. These position effects occurred even if the whole beta-globin gene was incorporated as part of the lacZ reporter gene. Moreover, DNase I-hypersensitive sites appeared in the transgene LCR in high expressing but not in low expressing lines, suggesting that the LCR itself was position dependent. In contrast, MEL cell clones, in which transcriptionally active integration sites were selected for, gave < 13-fold variation in expression per copy of an LCR-lacZ construct. These results show that the lacZ reporter affects the ability of the LCR to activate chromatin in mice and that culture cells are not an adequate model for position-independent gene expression studies.

CAAT/enhancer-binding proteins are involved in beta-globin gene expression and are differentially expressed in murine erythroleukemia and K562 cells

Acting in cis with the beta-globin locus control region, the CAAT box of the beta-globin gene promoter stimulates transcription 10-fold in murine erythroleukemia (MEL) cells but is without effect in K562 cells. Our previous studies suggested that of four proteins from MEL cells that bind to this CAAT box region (CP1, GATA-1, and two factors that were denoted DSFr and DSF1) DSFr is involved in the up-regulation of transcription. In the present report, the DSFr protein in MEL cells was identified as C/EBPgamma through expression cloning and antibody studies. C/EBPgamma DNA binding activity could not be detected in K562 cells. However, K562 cells, but not MEL cells, were found to express LIP, which is a truncated form of C/EBPbeta and is an inhibitor of transcription. Thus, the differential expression of C/EBP members could account for the ability of the beta-globin CAAT box to stimulate transcription in MEL cells, but not function in K562 cells. Juxtaposing a specific C/EBP binding sequence next to the beta-globin promoter, in constructs in which the CAAT box had been rendered inactive by mutation or deletion, restored full promoter activity in MEL cells only if CP1 still bound to the promoter. In conjunction with previous mutation analyses, these results suggest that C/EBPgamma may collaborate with CP1 to enhance transcription through the beta-globin CAAT box.

Erythroid Krüppel-like factor exhibits an early and sequentially localized pattern of expression during mammalian erythroid ontogeny

Erythroid Krüppel-like factor (EKLF) is an erythroid cell-specific transcription factor that mediates activation via binding to a 9 base pair sequence that encompasses the CACCC element, one of a trio of evolutionarily conserved sequence motifs that are functionally important for transcription of red cell-specific genes. Molecular analyses have delineated the specificity of its interaction and activation through the CAC site at the adult beta-globin promoter. However, its expression and distribution during murine ontogeny have not been established. To address these issues, we have focused on biological aspects of EKLF expression by examining the onset and localization of its mRNA during murine development by using reverse transcription/polymerase chain reaction (RT/PCR) analysis of differentiating embryonic stem cells and in situ analyses of normal developing embryos. In addition, we have monitored the presence of EKLF protein by blot analysis of whole-cell extracts derived from circulating cells and embryonic tissue. Our studies show that EKLF mRNA is first expressed at the neural plate stage (day 7.5) within primitive erythroid cells at the very beginning of blood island formation in the yolk sac. EKLF is then expressed by day 9 in the hepatic primordia and remains high in the liver, which becomes the sole source of EKLF mRNA in the 14.5 day fetus. Concomitantly with EKLF mRNA, EKLF protein is also expressed in primitive erythroid cells and in the fetal liver. Finally, EKLF expression in the adult spleen is strictly localized to the red pulp. These studies demonstrate that EKLF is a specific, early marker of erythroid differentiation consistent with its requirement for later globin (and possibly other red cell gene-specific) expression. In addition, EKLF exhibits alternate, sequentially active sites of expression within regions known to harbor hematopoietic precursors during murine ontogeny. Thus, EKLF expression exhibits biological properties that, in addition to previous molecular and more recent genetic studies, augment the evidence in favor of its important role in erythroid cell-specific expression.

Major histocompatibility complex class II-associated invariant chain gene expression is up-regulated by cooperative interactions of Sp1 and NF-Y

Expression of the major histocompatibility complex (MHC) class II-associated invariant chain (Ii) is required for efficient and complete presentation of antigens by MHC class II molecules and a normal immune response. The Ii gene is generally co-regulated with the MHC class II molecules at the level of transcription and a shared SXY promoter element has been described. This report defines the proximal promoter region of Ii which may regulate Ii transcription distinct from MHC class II. In vivo genomic footprinting identified an occupied, imperfect CCAAT box and an adjacent GC box in the proximal region. These sites are bound in Ii-ositive cell lines and upon interferon-gamma induction of Ii transcription. In contrast, both sites are unoccupied in Ii-egative cell lines and in inducible cell lines prior to interferon-gamma treatment. Together these two sites synergize to stimulate transcription. Independently, the transcription factor NF-Y binds poorly to the imperfect CCAAT box with a rapid off rate, while Sp1 binds to the GC box. Stabilization of NF-Y binding occurs upon Sp1 binding to DNA. In addition, the half-life of Sp1 binding also increased in the presence of NF-Y binding. These findings suggest a mechanism for the complete functional synergy of the GC and CCAAT elements observed in Ii transcription. Furthermore, this report defines a CCAAT box of imperfect sequence which binds NF-Y and activates transcription only when stabilized by an adjacent factor, Sp1.