The Krüppel-like factor (KLF) family of transcription factors play critical roles in haematopoiesis. KLF1, the founding member of the family, has been implicated in the control of both erythropoiesis and megakaryopoiesis. Here we describe a novel system using an artificial dominant negative isoform of KLF1 to investigate the role of KLF1 in the erythroid/megakaryocytic switch in vivo. We developed murine cell lines stably overexpressing a GST-KLF1 DNA binding domain fusion protein (GST-KLF1 DBD), as well as lines expressing GST only as a control. Interestingly, overexpression of GST-KLF1 DBD led to an overall reduction in erythroid features and an increase in megakaryocytic features indicative of a reduced function of endogenous KLF1. We simultaneously compared in vivo DNA occupancy of both endogenous KLF1 and GST-KLF1 DBD by ChIP qPCR. Here we found that GST-KLF1 DBD physically displaces endogenous KLF1 at a number of loci, providing novel in vivo evidence of direct competition between DNA binding proteins. These results highlight the role of KLF1 in the erythroid/megakaryocyte switch and suggest that direct competition between transcription factors with similar consensus sequences is an important mechanism in transcriptional regulation.
Erythrocytes and megakaryocytes are specialised cells of the haematopoietic system that are both derived from the megakaryocyte/erythroid progenitor (MEP). They have highly distinct gene expression profiles, functions and morphologies. Various transcription factors are involved in determining whether an MEP differentiates towards the erythroid or megakaryocyte lineage. These cells do, however, share a number of key transcription factors, the balance of which helps to determine which lineage an MEP will ultimately differentiate towards.
The Krüppel-like factor (KLF) family, consisting of 18 members to date1,2,3, has been widely implicated in haematopoiesis3. The family is characterised by three highly conserved C-terminal C2H2 zinc finger motifs that function as the DNA-binding domain4. These bind to CACCC-boxes and other GC rich elements, which are found at promoter and enhancer regions of their target genes5,6,7. Members of this family have been shown to function as both transcriptional activators and/or repressors, and have been divided into groups based on their functional similarities or their overall homology2.
The function of KLF1, the founding member of the family, has been extensively studied and its expression is largely restricted to erythroid cells7. KLF1 has been demonstrated to be a potent transcriptional activator, capable of binding CACCC-box motifs prevalent in the regulatory regions of many erythroid-associated genes7,8,9,10,11. It mediates its activation effects in part through interactions with CREB binding protein and p300 (CBP/p300)12. The most notable CACCC-box lies within the adult β-globin promoter, and KLF1 is central in driving the expression of this gene8, 13. It has been shown by chromatin immunoprecipitation (ChIP) to bind directly to the β-globin promoter in vivo 14, 15, and Klf1 null mice die in utero at around E15 of severe β-globin deficiency and anaemia16, 17. Many other erythroid genes are also deregulated in the absence of Klf1 10, 14, 18, 19, including another member of the KLF family, the transcriptional repressor, Krüppel-like factor 3 (Klf3)20. Expression of Klf3 has since been demonstrated to be directly activated by KLF121.
KLF1 has not only been shown to be important in promoting erythropoiesis, but has been identified as playing a role in repressing megakaryopoiesis. While KLF1 is highly upregulated as MEPs differentiate towards erythroid cells, it is conversely downregulated during megakaryocyte differentiation22. It has been shown that overexpression of KLF1 inhibits megakaryopoiesis22, and that loss of KLF1 promotes the expansion of megakaryocytes22, 23. In the absence of KLF1, murine erythroleukaemia (MEL) cells have been shown to upregulate the expression of megakaryocyte and platelet specific genes, such as GpIIIa and GpIX. It is believed that KLF1 is able to modulate its effect on megakaryopoiesis through the repression of the important megakaryocytic transcriptional regulator, Fli1 22, 24, 25.
Here we report a novel system using a GST tag fused upstream of the DNA binding domain of KLF1 (GST-KLF1 DBD) to investigate the roles of KLF1 in the erythroid/megakaryocytic switch. For these experiments, we selected the mouse erythroleukemia cell line, MEL cells. We developed MEL cell lines overexpressing GST-KLF1 DBD, as well as lines expressing GST alone as a negative control. Interestingly, these cells displayed a strong phenotypic effect, where cells expressing GST-KLF1 DBD displayed an overall reduced erythroid and increased megakaryocyte phenotype. This is consistent with the previously reported role of KLF1 in these processes and suggests that GST-KLF1 DBD has a dominant negative effect on endogenous KLF1. In order examine this dominant negative mechanism in greater detail, we investigated the in vivo binding of endogenous KLF1, and the binding of the ectopically expressed GST-KLF1 DBD. We found that GST-KLF1 DBD is able to out-compete endogenous KLF1 at a subset of target sites. Our results provide interesting new evidence to support a role for KLF1 in the erythroid/megakaryocyte switch, as well as indicating that transcription factor competition is an important regulation mechanism in eukaryotes in vivo.
GST only and GST-KLF1 DBD constructs are detectably expressed in MEL cells, and GST-KLF1 DBD is capable of binding to DNA
We generated mouse erythroleukemia (MEL) cell lines stably expressing GST fused upstream of the first zinc finger, and thus encompassing the three zinc finger DNA binding domain, of KLF1 (261–376) (GST-KLF1 DBD). We also developed lines expressing GST only which served as negative controls (Fig. 1A). Four different clones from each line were selected as replicates, based on comparable levels of protein expression, as assessed by Western blot (Fig. 1B).
Electrophoretic mobility shift assays (EMSAs) were used to determine whether GST-KLF1 DBD is able to bind to the same sequence as KLF1 in vitro. We used the canonical KLF1 binding CACCC sequence, from the β-globin promoter20, and performed EMSAs in the MEL lines stably expressing GST alone and those expressing the GST-KLF1 DBD protein. This result demonstrates that the GST protein alone is unable to bind to DNA (Fig. 1C lanes 2–4), while the GST-KLF1 DBD protein is capable of binding the same consensus sequence as KLF1 in vitro (Fig. 1C, lanes 5–7).
We next sought to determine whether expression of GST-KLF1 DBD affected the endogenous levels of KLF1. Using an antibody that recognises both endogenous KLF1 and GST-KLF1 DBD in a Western blot with nuclear extracts from MEL cells, we show that GST-KLF1 DBD overexpression does not effect expression of endogenous KLF1 (Fig. 1D, quantitation in Fig. S1A). There was also no difference in the expression of Klf1 at the mRNA level as determined by real time quantitative RT-PCR (qPCR) using primers that recognise endogenous KLF1 but not GST-KLF1 DBD (Fig. S1B). The level of GST-KLF1 DBD was 2–3 times that of the endogenous level of KLF1 protein in MEL cells expressing GST or GST-KLF1 DBD (Fig. 1D, quantitation in Fig. S1A).
Endogenous KLF3, which also binds to the CACCC sequence from the β-globin promoter, can be visualised on the EMSA. The identity of the band marked as KLF3 was confirmed by supershift with an antibody to KLF3 (Fig. 1C, lane 3). It was noted that the expression of KLF3 appeared reduced in cells overexpressing GST-KLF1 DBD (Fig. 1C lanes 5–7). In order to further investigate this finding in all four clones, we performed Western blots, examining the levels of KLF3. We found that KLF3 is indeed downregulated in MEL cells overexpressing the GST-KLF1 DBD construct compared to GST only cells (Fig. 1E). Densitometry analyses on both the EMSAs and the Western blots was performed to confirm these observations (Fig. S2A,B). We also investigated the levels of Klf3 by qPCR and found it to be significantly reduced in MEL cells overexpressing GST-KLF1 DBD compared to GST only expressing cells (Fig. S2C). These data all confirm a reduction in the levels of KLF3 in cells expressing the GST-KLF1 DBD construct. To exclude the possibility that GST alone influences KLF3 levels, we remade new MEL cell clones stably overexpressing GST and GST-KLF1 DBD and, at the same time, generated control clonal MEL cells (grown in media without puromycin). The reduction in KLF3 protein and Klf3 mRNA in GST-KLF1 DBD expressing MEL cells was replicated in these independent clones and GST alone had no effect on KLF3 expression when compared to clonal populations of the parental MEL cell line (Fig. S3). As Klf3 expression is known to be activated by KLF1, the reduced Klf3 expression in the cells expressing GST-KLF1 DBD suggests that this construct has a dominant negative effect on KLF1 activity.
MEL cells expressing GST-KLF1 DBD show a reduced erythroid phenotype
We initially investigated the phenotype of the MEL lines by flow cytometry. Here, we found that the cells expressing GST-KLF1 DBD express markedly less TER119, the marker for mature erythroid cells, on their cell surface compared to cells expressing GST only (Fig. 2A–C). In contrast, the expression of the progenitor marker CD71 is not altered on the surface of these cells. We attempted to terminally induce these cells using DMSO as previously described26 to determine if this phenotype becomes more pronounced upon erythroid differentiation. Here we found that induction was blocked in the lines overexpressing GST-KLF1 DBD, as evidenced by their overall pale color compared to the hemoglobinized hue of the induced MEL cells expressing GST (Fig. 2D). Indeed, this reduction in globin expression in the GST-KLF1 DBD cells was also seen at the transcript level by qPCR, as the levels of the α-globin genes, Hba-x and Hba-a, and the β-globin genes, Hbb-y, Hbb-bh1 and Hbb-b, are markedly reduced in these cells (Fig. 2E).
MEL cells expressing GST-KLF1 DBD show an increased megakaryocyte phenotype
Considering KLF1’s role in establishing erythroid lineage commitment at the expense of megakaryopoiesis, we next sought to determine whether MEL cells expressing GST-KLF1 DBD display any increased megakaryocytic characteristics. To determine this, we investigated the megakaryocyte cell surface markers CD41 and CD42a by flow cytometry. We found that cells expressing GST-KLF1 DBD do indeed show increased levels of the megakayocytic marker CD41 on their surface compared to GST control cells (Fig. 3A–C). The marker CD42a, however, was unchanged across the two groups. We also examined the expression of megakaryocyte genes at the transcript level by qPCR, and found that the levels of Gata2 and Itga2b were significantly increased in these cells, an increase in Runx1 and GpIX appraoching significance (p = 0.07 and p = 0.06 respectively) was also obersved. Gata1 levels were significantly decreased and interestingly, levels of Fli1 were unchanged (Fig. 3D).
GST-KLF1 DBD has a dominant negative effect on endogenous KLF1 at selective target sites
The results reported above are consistent with a dominant negative role of GST-KLF1 DBD on endogenous KLF1 in these cells. We hypothesised that the mechanism underlying this dominant negative effect is direct competition of GST-KLF1 DBD and endogenous KLF1. In order to investigate the potential of competitive binding between GST-KLF DBD and endogenous KLF1, we performed chromatin immunoprecipitation (ChIP) in MEL cells expressing GST only, as well as those expressing GST-KLF1 DBD. Here we used an antibody against the N-terminus of KLF1 in order to detect endogenous KLF1 binding only in both cell types, as well as an antibody against GST, to detect the binding of GST-KLF1 DBD (Fig. 4A). The GST ChIP in GST only cells acted as a negative control, while IgG was used as an additional negative control in both cell types.
We were predominantly interested in investigating the effects of endogenous KLF1 binding upon the introduction of GST-KLF1 DBD, as well as the binding of GST-KLF1 DBD itself. Here we found that GST-KLF1 DBD is capable of binding to a number of KLF1 target sites, particularly the promoters of Klf3 and Klf8, and that this binding appears to reduce the binding of endogenous KLF1 (Fig. 4B). We also found that GST-KLF1 DBD is capable of binding to some regions and not affect KLF1 binding, for instance at the Lgals3 promoter, and that there are some regions where KLF1 is capable of binding, but GST-KLF1 DBD is not, for instance at the Klf1 promoter. Taken together these results provide evidence for competition between transcription factors, but a complex and context dependent mechanism appears to be in operation.
We developed cell lines expressing GST fused upstream of the DNA binding domain of KLF1 (GST-KLF1 DBD), in order to probe the function of KLF1 in the erythroid/megakaryocyte switch. We discovered a pronounced phenotypic effect in these cells, providing further evidence for involvement of KLF1 in this process. Endogenous KLF1 levels are not altered in cells expressing GST-KLF1 DBD compared to cells expressing GST alone, suggesting that this phenotype is due to competition of GST-KLF1 DBD with endogenous KLF1. In support of this we found that the GST-KLF1 DBD protein is capable of binding to DNA, both in vitro and in vivo, and is capable of outcompeting endogenous KLF1 at particular KLF1 target sites, providing in vivo evidence of direct competition between transcription factors.
We initially found a decrease in the expression of a key KLF1 target gene, Klf3, in MEL cells overexpressing the GST-KLF1 DBD compared to GST only cells, at both the transcript and protein level. We also demonstrated a reduced erythroid phenotype and an increase in the megakaryocytic phenotype in MEL cells overexpressing this protein. These data support of the dual role of KLF1 in the erythroid/megakaryocyte switch, where KLF1 promotes erythroid differentiation, and represses megakaryocyte differentiation, and are indicative of a dominant negative affect of GST-KLF1 DBD on endogenous KLF1 in these lines.
While the MEL cells overexpressing GST-KLF1 DBD showed a marked reduction in erythroid features, the concomitant increase in megakaryocyte features was more subtle. Significant increases were seen only for CD41 cell surface antigen levels and for and Gata2 and Itga2b expression at the mRNA level. Gata1 expression was lower in the cells expressing GST-KLF1 DBD than cells expressing GST only, but this could be accounted for by the decreased erythroid phenotype in these cells as GATA1 is a key transcription factor in erythroid cells as well as megakaryocytes. It has previously been shown that MEL cells without KLF1 upregulate the expression of megakaryocyte specific genes such as GpIX and KLF1 is thought to block megakaryopoiesis via repression of Fli1 22, 24, 25. Interestingly, Fli1 expression was not altered in our model. It is possible that the GST-KLF1 DBD does not have an effect at all KLF1 target genes for reasons discussed below. It is also plausible that the previously reported repression of Fli1 by KLF1, was in fact modulated by KLF3. Our lab has previously shown that a number of non-erythroid genes are activated by KLF1, and attenuated by KLF318, 27. It is conceivable that the level of downregulation of KLF3 in the cells expressing GST-KLF1 DBD is not enough to significantly affect Fli1 expression in these cells.
Finally, we explored the potential mechanism underlying the observed dominant negative effects of GST-KLF1 DBD on endogenous KLF1. Steric hindrance, a concept established in prokaryotes, particularly at the Escherichia coli lactose (lac) operon28, is less well described in eukaryotic cells. In this example, the lac repressor protein (LacI) inhibits DNA binding of RNA polymerase, and subsequent gene activation28. This model can conceivably apply in eukaryotic cells to transcription factors with similar DNA binding specificities, whereby one factor preferentially binds competitively with factors possessing similar specificity. This mechanism would rely on a number of factors, including abundance of the various transcription factors involved, as well as their co-factors, and their relative DNA binding affinities. Many transcription factors are capable of binding similar DNA motifs, but which factors are actually bound at a given point in time in vivo is still an open research question. However, while there is much in vitro evidence of competition of transcription factors with similar sequence specificities, there are fewer examples where this has been observed in vivo. Here we investigated whether the GST-KLF1 DBD protein is capable of directly competing for binding sites at a number of known KLF1 targets.
In order to achieve this, we utilised the GST tag to perform parallel ChIP qPCR studies to examine the binding of both endogenous KLF1, and GST-KLF1 DBD in cells expressing either GST only, and those expressing GST-KLF1 DBD. In this experiment we found that GST-KLF1 DBD is capable of binding in vivo to some known KLF1 target sites, and that binding of endogenous KLF1 was significantly reduced at some, but not all, of these sites. The presence of KLF1 binding is markedly reduced at the Klf3 and Klf8 promoters, where GST-KLF1 DBD is found to bind. The expression of Klf3 was found to be reduced in MEL cells expressing GST-KLF1 DBD compared to GST alone. This suggests that the binding of GST-KLF1 DBD is competitively inhibiting the binding of endogenous KLF1, and thereby acting as a dominant negative at some target sites. We have, however, found some sites, namely the Klf1 promoter, where endogenous KLF1 is not significantly reduced, and the GST-KLF1 DBD fusion protein is unable to bind.
The observation that the GST-zinc finger DNA-Binding Domain is able to bind and compete with endogenous KLF1 at some targets and not others is at first surprising, but in fact fits with our prior observations studying KLF3 binding. We have previously performed experiments with a series of KLF3 mutants and found that a construct retaining only the minimal DNA-Binding Domain of KLF3 was able to bind some sites, but not others, in vivo 29, 30. We found that the functional domain of KLF3, that is the non-zinc finger N-terminal domain, is critical for the ability of wildtype KLF3 to locate and bind many of its target sites in vivo. This is likely due to interactions with various co-factors and other DNA-binding proteins that enable the proper targeting of this transcription factor to its target sites. This results with the GST-KLF1 DBD fusion protein investigated here, where the lack of the KLF1 N-terminal functional domain also shows effects on target gene specificity. It is likely that this protein is unable to interact with its normal cofactors, such as CBP/p300 and other SRC family members, and therefore, is unable to reach all of the CACCC sequences that wildtype KLF1 is able to bind to and regulate.
We therefore propose the following model for how the GST-KLF1 DBD protein is exerting its striking phenotypic effects in MEL cells (Fig. 5). Under normal conditions, KLF1, with the help of its co-factors CBP/p300 and other SRC family proteins, is able to locate and bind to all of its target sites in vivo, and thereby either activate, or in some instances repress, gene expression (Fig. 5A). However, at some KLF1 target sites, the interactions with co-factors and other DNA-binding proteins are less important, and it is at these sites that GST-KLF1 DBD is able to outcompete endogenous KLF1 and bind, thereby resulting in reduced activation of these target genes, such as Klf3 and Klf8 (Fig. 5B). However, at the sites where co-factors and other protein-protein interactions are more important for KLF1 binding, endogenous KLF1 is still capable of binding, and GST-KLF1 DBD is unable to bind, and therefore no altered effect on target gene expression is seen (Fig. 5C).
This mechanism can be more broadly applied to the potential competition between other transcription factors. KLF1 and KLF3, for instance, have similar DNA-binding preferences, and the two factors have been shown to bind in vitro to many of the same erythroid promoter CACCC-boxes18, 20, including that of the adult β-globin gene. KLF1, KLF3 and another related family member, KLF8, have been shown to be involved in a regulatory loop that plays a role in fine-tuning the expression of erythroid genes, including genes at the β-globin locus. That is, KLF1 is capable of activating a multitude of erythroid and non-erythroid genes, including Klf3 and Klf8, and KLF3 plays a critical role in repressing a subset of these non-erythroid genes to maintain the correct expression program in erythroid cells31. It is not known, however, whether these factors are capable of binding competitively to the same target sites in vivo. Our results suggest that direct competition between these factors may be an important mechanism in gene regulation.
Future work will centre on investigating the properties of each of the KLF family members. This work will shed light on the importance of the functional domain in determining the DNA binding specificity of transcription factors as a whole.
Constructs and generation of stable lines
The vector pEF-IRES-puro5 (pEF1α) was provided by Dr Daniel Peet (University of Adelaide, Adelaide, Australia). GST was amplified from NpGEX2T, kindly provided by José Perdomo (School of Biochemistry, University of Sydney, Australia), using the following primers; 5′-GGTTTTCCATATGATTTTGGAGGATGGTCGCC-3′ and 5′-GGACTAGTTCATTTTGGAGGATGGTCGCC-3′, and cloned into pEF1α using the restriction enzymes NcoI and SpeI. The KLF1 DBD domain (261–376) was amplified from murine spleen cDNA using the following primers; 5′-CCGGAATTCGGGGCCACTGCGATCGCC-3′ and 5′-CGCGGATCCTCAGAGGTGACGCTTCATGTG-3′, and cloned into pEF1α using the restriction enzymes NcoI and SpeI.
Mouse erythroleukaemia (MEL) cells were maintained in RPMI1640 (Life Technologies) supplemented with 10% fetal calf serum (FCS; Life Technologies) and 1% penicillin, streptomycin and L-glutamine (PSG, Life Technologies). Stably expressing cells were created using the Neon Transfection System (Life Technologies). Cells (105) were resuspended in nucleofection buffer T (Neon Transfection Kit, Life Technologies) and given three pulses of 1,450 V for 20 milliseconds. Cells were then cultured for 48–72 h in RPMI1640 supplemented with 10% FCS before selection. After this time MEL cells were selected with 0.5 µg/mL puromycin for 5 days before single cell sorting using the FACS Aria II (BD Bioscience). Expression of desired constructs was analysed by Western blot.
For induction of MEL cells, cells were cultured for 72 hours in RPMI1640 supplemented with 10% FCS, 1% PSG, and 2% DMSO, as previously described26.
Cytoplasmic and nuclear extracts, and Western blots
20 µg of cytoplasmic or nuclear fractions were obtained, and Western blots were performed by standard methods. Briefly, extracts were separated using 10% Bis-Tris NuPAGE gels (Thermo Fisher Scientific) and were electrotransferred to nitrocellulose membrane, which was blocked with 4% skim milk in 50 mM Tris-HCl (pH 7.5), 150 mM NaCl, 0.05% Tween-20 (TBST). GST and KLF3 proteins were probed for 1 hour in TBST using 0.2 µg/mL anti-GST antibody (1:5,000 dilution - ab19256, Abcam) or 0.2 µg/mL anti-KLF3 (1:5,000 dilution - PA5–18030, Thermo Fisher Scientific), respectively. KLF1 proteins were probed overnight in 4% skim milk in TBST using a KLF1 antibody that recognises both endogenous mouse KLF1 and GST-KLF1 DBD (1:1,000 dilution, antibody generation reported previously)20. The Immobilon Western Chemiluminescent HRP Substrate System (Millipore Corporation) was used for detection. Membranes were subsequently stripped using 0.2 M NaOH for 10 minutes and were probed with anti-β-actin (1:30,000 dilution - A1978, Sigma) as a loading control.
Electrophoretic mobility shift assay (EMSA)
EMSAs were performed as previously described20. The radiolabelled probe containing the KLF1 consensus binding site comprises sense and antisense oligonucleotides for the sequence 5′-TAGAGCCACACCCTGGTAAG-3′, as described20. 2 µl of the same antibodies used for Western blot analysis were used in the supershift lanes.
Densitometry of relative band intensities was performed using ImageJ Gel Analysis tool32, 33. Briefly, ImageJ was used to select and determine the background-subtracted density of the bands for KLF3 in both the EMSAs and western blots. In the EMSAs, KLF3 was normalised to SP1 as a loading control, and in the Western blot analysis KLF3 and KLF1/GST-KLF1 DBD bands were normalised to the loading control Actin.
Flow cytometry was performed using the LSRFortessa Flow Cytometry (BD Bioscience), and the data analysed using FlowJo v7.6.5 (TreeStar) Software. The mouse antibodies TER119 (BD Bioscience), CD71 (clone RI7217, Biolegend), CD41 (clone MWReg30, BD Bioscience) and CD42a (clone Xia.B4, Emfret Analytics) were used at the concentrations recommended by the manufacturers.
cDNA synthesis and real time RT-PCR (qPCR)
Total RNA was extracted using the RNeasy Mini Kit (Qiagen) as per the manufacturer’s instructions. The DNA-free kit (Ambion) was used to eliminate genomic DNA contamination. 5 µg of RNA was converted to cDNA with the SuperScript VILO cDNA synthesis kit (Invitrogen) for use in real time qPCR.
Paired primers were designed using the PrimerExpress software (Version 2.0) (Applied Biosystems) to cross exon-exon boundaries, where possible, in order to prevent the amplification of potential contaminating genomic DNA. Primer specificity was checked using the Basic Local Alignment Search Tool (BLAST; http://www.ncbi.nlm.nih.gov/BLAST)34. The oligonucleotide sequences for murine primers are as follows: 18S, 5′-CACGGCCGGTACAGTGAAAC-3′ and 5′-TTGGTCGCTCGCTCCTCT-3′; Klf1, 5′-AGACTGTCTTACCCTCCATCAGTACA-3′ and 5′-CCGCCACCACTTGAGGAA-3′; Klf3, 5′-GAAATGTCACCCCCTTTAATGAAC-3′ and 5′-ACCATCCTTCCGTCATCGTG-3′; Hba-x, 5′-ATGCGGTTAAGAGCATCGAC-3′ and 5′-CAACTTCAAGCTCCTGTCCC-3′; Hba-a1, 5′-CTCTGGGGAAGACAAAAGCA-3′ and 5′-ACTTTGATGTAAGCCACGGC-3′; Hbb-y, 5′-GGCCTGTGGAGTAAGGTCAA-3′ and 5′-TTTGGGAACTTGTCCTCTGC-3′; Hbb-bh1, 5′-AATCACCAGCTTCTGCCAGGC-3′ and 5′-TGAGCAAAGGTCTCCTTGAG-3′; Hbb-b1, 5′-CACTGTGACAAGCTGCATGT-3′ and 5′-CTGGCTCACAAGTACCACTA-3′; Gata2, 5′-AGAACCGGCCGCTCATC-3′ and 5′-TCGTCTGACAATTTGCACAACAG-3′; Runx1, 5′-CCCGCCTTCAGGAGAGGTGC-3′ and 5′-GGAAGGCGGCGTGAAGCG-3′; Fli1, 5′-ACCAGCCAGTGAGAGTCAAT-3′ and 5′-CCGTTCTTCTCATCCATGTA-3′; GPiX, 5′-TACCAGCCCACAAAAGGTGT-3′ and 5′-GGGCAAGCCTGAGTATCTGT-3′; Itga2b, 5′-CCCTGTCGCGCCAACACCAT-3′ and 5′-CAGCCTGGGTCACCGCCAAG-3′.
qPCR runs were performed in triplicate with Power SYBR green PCR Master Mix and using the 7500 Fast Real time PCR system (Applied Biosystems) as previously described35. Approximately 10 ng of cDNA and a final concentration of 2 µM of primer were used per reaction.
Chromatin immunoprecipitation (ChIP)
ChIP was performed based on the protocol by Schmidt et al.36, with slight modifications. Briefly, 1.5 × 108 cells were crosslinked using formaldehyde for 20 minutes. Each pellet was used for three IPs, with the following antibodies each at 15 µg, Goat IgG (sc-2028, Santa Cruise), GST (ab-19256, Abcam) and KLF1 (PA5-18031, Thermo Fisher Scientific). Real-time PCR quantification of chromatin pull-down was performed as described above and amounts were normalised to the level of input material prior to immunoprecipitation. In order to equate for subtle differences across samples, each antibody for each cell type was normalised to the most negative region. The primer sequences are as follows; Klf3 Promoter, 5′-CTGGGTGTGGGCAGAATCTT-3′ and 5′-AGTTGGACTCGCCCTGGC-3′; Klf8 Intron, 5′-CCAGCTCGTGCACACTGAA-3′ and 5′-TTCCACTCCTGATGTTAAGGCTTC-3′; Klf1 Promoter, 5′-CACAACAGAGCAATTCAAAGCTAAA-3′ and 5′-CTCAAGGAGGAACAGAGCTATGG-3′; Lgals3 Promoter, 5′-TGGAAAAACACCCGTGCCTCTGA-3′ and 5′-GAGTCATCTGGGCGTAGGCACTG-3′; Klf8 +33 kb, 5′-AACCTGGGTGCCTCCTTGTA-3′ and 5′-AAAGCACTAAAGTCAAAGGCATGA-3′.
Pei, J. & Grishin, N. V. A new family of predicted Krüppel-like factor genes and pseudogenes in placental mammals. PLoS ONE 8, e81109 (2013).
Pearson, R., Fleetwood, J., Eaton, S., Crossley, M. & Bao, S. Krüppel-like transcription factors: a functional family. Int J Biochem Cell Biol 40, 1996–2001 (2008).
McConnell, B. B. & Yang, V. W. Mammalian Krüppel-like factors in health and diseases. Physiol Rev 90, 1337–1381 (2010).
Kaczynski, J., Cook, T. & Urrutia, R. Sp1- and Krüppel-like transcription factors. Genome Biol 4, 206 (2003).
Van Vliet, J., Turner, J. & Crossley, M. Human Krüppel-like factor 8: a CACCC-box binding protein that associates with CtBP and represses transcription. Nucleic Acids Res 28, 1955–1962 (2000).
Philipsen, S. & Suske, G. A tale of three fingers: the family of mammalian Sp/XKLF transcription factors. Nucleic Acids Res 27, 2991–3000 (1999).
Miller, I. J. & Bieker, J. J. A novel, erythroid cell-specific murine transcription factor that binds to the CACCC element and is related to the Krüppel family of nuclear proteins. Mol Cell Biol 13, 2776–2786 (1993).
Feng, W. C., Southwood, C. M. & Bieker, J. J. Analyses of beta-thalassemia mutant DNA interactions with erythroid Krüppel-like factor (EKLF), an erythroid cell-specific transcription factor. J Biol Chem 269, 1493–1500 (1994).
Raich, N. & Romeo, P. H. Erythroid regulatory elements. Stem Cells 11, 95–104 (1993).
Tallack, M. R. et al. A global role for KLF1 in erythropoiesis revealed by ChIP-seq in primary erythroid cells. Genome Res 20, 1052–1063 (2010).
Su, M. Y. et al. Identification of biologically relevant enhancers in human erythroid cells. J Biol Chem 288, 8433–8444 (2013).
Zhang, W., Kadam, S., Emerson, B. M. & Bieker, J. J. Site-specific acetylation by p300 or CREB binding protein regulates erythroid Krüppel-like factor transcriptional activity via its interaction with the SWI-SNF complex. Mol Cell Biol 21, 2413–2422 (2001).
Donze, D., Townes, T. M. & Bieker, J. J. Role of erythroid Kruppel-like factor in human gamma- to beta-globin gene switching. J Biol Chem 270, 1955–1959 (1995).
Hodge, D. et al. A global role for EKLF in definitive and primitive erythropoiesis. Blood 107, 3359–3370 (2006).
Shyu, Y. C. et al. Chromatin-binding in vivo of the erythroid kruppel-like factor, EKLF, in the murine globin loci. Cell Res 16, 347–355 (2006).
Nuez, B., Michalovich, D., Bygrave, A., Ploemacher, R. & Grosveld, F. Defective haematopoiesis in fetal liver resulting from inactivation of the EKLF gene. Nature 375, 316–318 (1995).
Perkins, A. C., Sharpe, A. H. & Orkin, S. H. Lethal beta-thalassaemia in mice lacking the erythroid CACCC-transcription factor EKLF. Nature 375, 318–322 (1995).
Funnell, A. P. et al. The CACCC-binding protein KLF3/BKLF represses a subset of KLF1/EKLF target genes and is required for proper erythroid maturation in vivo. Mol Cell Biol 32, 3281–3292 (2012).
Tallack, M. R. & Perkins, A. C. KLF1 directly coordinates almost all aspects of terminal erythroid differentiation. IUBMB Life 62, 886–890 (2010).
Crossley, M. et al. Isolation and characterization of the cDNA encoding BKLF/TEF-2, a major CACCC-box-binding protein in erythroid cells and selected other cells. Mol Cell Biol 16, 1695–1705 (1996).
Funnell, A. P. et al. Erythroid Krüppel-like factor directly activates the basic Krüppel-like factor gene in erythroid cells. Mol Cell Biol 27, 2777–2790 (2007).
Frontelo, P. et al. Novel role for EKLF in megakaryocyte lineage commitment. Blood 110, 3871–3880 (2007).
Tallack, M. R. & Perkins, A. C. Megakaryocyte-erythroid lineage promiscuity in EKLF null mouse blood. Haematologica 95, 144–147 (2010).
Starck, J. et al. Functional cross-antagonism between transcription factors FLI-1 and EKLF. Mol Cell Biol 23, 1390–1402 (2003).
Bouilloux, F. et al. EKLF restricts megakaryocytic differentiation at the benefit of erythrocytic differentiation. Blood 112, 576–584 (2008).
Antoniou, M. Induction of Erythroid-Specific Expression in Murine Erythroleukemia (MEL) Cell Lines. Methods Mol Biol 7, 421–434 (1991).
Mak, K. S. et al. Repression of chimeric transcripts emanating from endogenous retrotransposons by a sequence-specific transcription factor. Genome Biol 15, R58 (2014).
Lewis, M. The lac repressor. C R Biol 328, 521–548 (2005).
Burdach, J. et al. Regions outside the DNA-binding domain are critical for proper in vivo specificity of an archetypal zinc finger transcription factor. Nucleic Acids Res 42, 276–289 (2014).
Lim, W. F. et al. Directing an artificial zinc finger protein to new targets by fusion to a non-DNA-binding domain. Nucleic Acids Res 44, 3118–3130 (2016).
Funnell, A. P. et al. Generation of mice deficient in both KLF3/BKLF and KLF8 reveals a genetic interaction and a role for these factors in embryonic globin gene silencing. Mol Cell Biol 33, 2976–2987 (2013).
Schneider, C. A., Rasband, W. S. & Eliceiri, K. W. NIH Image to ImageJ: 25 years of image analysis. Nat Methods 9, 671–675 (2012).
Abramoff, M. D., Magalhaes, P. J. & Ram, S. J. Image processing with ImageJ. Biophoton Int 11, 36–42 (2004).
Altschul, S. F., Gish, W., Miller, W., Myers, E. W. & Lipman, D. J. Basic local alignment search tool. J Mol Biol 215, 403–410 (1990).
Hancock, D., Funnell, A., Jack, B. & Johnston, J. Introducing undergraduate students to real-time PCR. Biochem Mol Biol Educ 38, 309–316 (2010).
Schmidt, D. et al. ChIP-seq: using high-throughput sequencing to discover protein-DNA interactions. Methods 48, 240–248 (2009).
We would like to acknowledge the staff from within the Flow Cytometry Facility in the Biological Resources Imaging Laboratory of the Mark Wainwright Analytical Centre at the University of New South Wales for their flow cytometry services and guidance. This work was supported by funding from the National Health and Medical Research Council of Australia (APP1025873). LJN, SH and ESS were supported by Australian Postgraduate Awards.
The authors declare that they have no competing interests.
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Norton, L.J., Hallal, S., Stout, E.S. et al. Direct competition between DNA binding factors highlights the role of Krüppel-like Factor 1 in the erythroid/megakaryocyte switch. Sci Rep 7, 3137 (2017). https://doi.org/10.1038/s41598-017-03289-5