Polycomb and trithorax group proteins regulate cellular pluripotency and differentiation by maintaining hereditable states of transcription. Many Polycomb and trithorax group proteins have been implicated in the covalent modification or remodeling of chromatin, but how they interact with each other and the general transcription machinery to regulate transcription is not well understood. The trithorax group protein Kismet-L (KIS-L) is a member of the CHD subfamily of chromatin-remodeling factors that plays a global role in transcription by RNA polymerase II (Pol II). Mutations in CHD7, the human counterpart of kis, are associated with CHARGE syndrome, a developmental disorder affecting multiple tissues and organs. To clarify how KIS-L activates gene expression and counteracts Polycomb group silencing, we characterized defects resulting from the loss of KIS-L function in Drosophila. These studies revealed that KIS-L acts downstream of P-TEFb recruitment to stimulate elongation by Pol II. The presence of two chromodomains in KIS-L suggested that its recruitment or function might be regulated by the methylation of histone H3 lysine 4 by the trithorax group proteins ASH1 and TRX. Although we observed significant overlap between the distributions of KIS-L, ASH1, and TRX on polytene chromosomes, KIS-L did not bind methylated histone tails in vitro, and loss of TRX or ASH1 function did not alter the association of KIS-L with chromatin. By contrast, loss of kis function led to a dramatic reduction in the levels of TRX and ASH1 associated with chromatin and was accompanied by increased histone H3 lysine 27 methylation—a modification required for Polycomb group repression. A similar increase in H3 lysine 27 methylation was observed in ash1 and trx mutant larvae. Our findings suggest that KIS-L promotes early elongation and counteracts Polycomb group repression by recruiting the ASH1 and TRX histone methyltransferases to chromatin.
The transcription of eukaryotic genes involves a highly ordered series of events, including the recruitment of RNA polymerase to promoters, the production of the RNA transcript, and termination. These events are coordinated with changes in chromatin structure that allow regulatory proteins and RNA polymerase to access the DNA template. The recruitment of RNA polymerase II to promoters is rate-limiting for the expression of most eukaryotic genes. However, RNA polymerase often pauses or stalls a short distance downstream of promoters, providing an additional step at which transcription can be regulated. In this study, we present evidence suggesting that a chromatin-remodeling factor, KIS-L, activates transcription by counteracting promoter-proximal pausing in Drosophila. KIS-L also counteracts histone H3 lysine 27 methylation—a covalent modification of chromatin involved in hereditable gene silencing. Our findings provide a plausible explanation for the developmental abnormalities associated with CHARGE syndrome, a serious disorder resulting from mutations in the human counterpart of KIS-L.
Citation: Srinivasan S, Dorighi KM, Tamkun JW (2008) Drosophila Kismet Regulates Histone H3 Lysine 27 Methylation and Early Elongation by RNA Polymerase II. PLoS Genet 4(10): e1000217. doi:10.1371/journal.pgen.1000217
Editor: Asifa Akhtar, European Molecular Biology Laboratory, Germany
Received: April 14, 2008; Accepted: September 8, 2008; Published: October 10, 2008
Copyright: © 2008 Srinivasan et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by a grant from the National Institutes of Health (NIH) (GM49883) to JWT. SS and KMD were supported by a training grant from the NIH (T32GM08646). KMD was also supported by a training grant from the California Institute for Regenerative Medicine (T3-00006).
Competing interests: The authors have declared that no competing interests exist.
Eukaryotic transcription involves a highly ordered series of events including the binding of transcription factors to cis-regulatory elements; the assembly of the pre-initiation complex and recruitment of Pol II to promoters; initiation; promoter clearance; elongation and termination . These events must be coordinated with changes in chromatin structure that allow transcription factors and Pol II to access the DNA template and the recruitment of factors that process nascent RNAs ,. The recruitment of Pol II to promoters is rate limiting for the transcription of many genes. In some cases, however, Pol II pauses or “stalls” a short distance downstream of promoters. Promoter-proximal stalling, first observed at Drosophila heat-shock genes, allows genes to be rapidly activated in response to cellular or environmental signals . Recent studies in both Drosophila and humans have shown that paused polymerases are present downstream of the promoters of many silent genes, suggesting that the regulation of early elongation is a relatively widespread phenomenon ,,,,. In addition to poising genes for rapid induction, pausing can be used to repress transcription and generate cell type-specific patterns of gene expression . These findings have stimulated great interest in the factors that regulate elongation by Pol II.
Numerous factors that regulate elongation or other aspects of transcription by Pol II have been identified in genetic studies of Drosophila homeotic (Hox) genes. Hox genes encode homeodomain transcription factors that specify cell fates in Drosophila and other metazoans . The transcription of Hox genes must be regulated precisely, since their inappropriate expression can lead to homeotic transformations and other developmental abnormalities. The initial patterns of Hox transcription are established in response to positional information in the early embryo. During subsequent development, these patterns are maintained by two ubiquitously expressed groups of regulatory proteins: the trithorax group of activators and the Polycomb group of repressors ,,. By maintaining heritable states of Hox transcription, trithorax and Polycomb group proteins play key roles in the control of cell fate.
Although the detailed mechanism of action of most Polycomb and trithorax group proteins is not well understood, many of these proteins regulate transcription by altering chromatin structure. Roughly a dozen Polycomb group genes have been identified in Drosophila; the majority of these genes encode subunits of two protein complexes: PRC1 and PRC2 . The Enhancer of zeste [E(z)] subunit of PRC2 methylates lysine 27 of histone H3 (H3K27) ; this covalent modification of chromatin is critical for Polycomb group repression and may recruit or stabilize the binding of PRC1 or other repressors to chromatin ,. The trithorax proteins Trithorax (TRX) and Absent, small or homeotic 1 (ASH1) also catalyze modifications of nucleosomal histones, including the methylation of lysine 4 of histone H3 (H3K4) ,,,,. H3K4 methylation is observed near the promoters of many active genes  and may directly or indirectly counteract Polycomb group repression ,. Other trithorax group proteins - including Brahma (BRM), Moira (MOR), Osa (OSA), and Kismet (KIS) - are involved in ATP-dependent chromatin remodeling . Thus, both the modification and remodeling of chromatin are critical for the maintenance of heritable states of Hox transcription.
A subset of trithorax group members, including kis, may regulate elongation by Pol II. Like many other trithorax group genes, kis was identified in a screen for extragenic suppressors of Polycomb (Pc) mutations, suggesting that it directly or indirectly counteracts Polycomb group repression . In support of this view, the loss of kis function causes homeotic transformations due to the failure to maintain transcription of Hox genes . kis encodes a large protein (KIS-L) which is highly related to human CHD7 and other members of the chromodomain-helicase-DNA binding (CHD) subfamily of ATP-dependent chromatin-remodeling factors ,. KIS-L is associated with the vast majority of transcriptionally active regions of salivary gland polytene chromosomes, suggesting that it plays a relatively global role in transcription by Pol II . KIS-L is not required for early stages of the transcription cycle, including the recruitment of Pol II to promoters and promoter clearance . By contrast, the loss of kis function leads to a dramatic reduction in the levels of elongating Pol II and the elongation factors SPT6 and CHD1 associated with polytene chromosomes . These findings suggest that KIS-L activates transcription by promoting an early stage of transcription elongation.
In addition to highly conserved ATPase domains, KIS-L and other CHD proteins contain chromodomains: a short domain implicated in the binding of methylated histone tails . The presence of two chromodomains in KIS-L suggests that its ability to remodel chromatin and stimulate transcription may be regulated by the site-specific methylation of nucleosomal histones. Perhaps the best candidate for a chromatin modification that regulates KIS-L function is H3K4 di- or tri-methylation. Numerous H3K4 methyltransferases have been identified, including yeast SET1, its relatives in Drosophila and mammals, and the trithorax group proteins ASH1 and TRX ,. H3K4 methylation is found near the promoters of many active genes and is thought to stimulate transcription by promoting the association of multiple regulatory proteins with chromatin . For example, CHD1 - a CHD protein related to KIS-L - directly binds methylated H3K4 (H3K4me) via its chromodomains ,,. Based on these findings, we suspected that the methylation of H3K4 by ASH1 and TRX might activate transcription by targeting KIS-L to promoters.
In this study, we sought to clarify the role of KIS-L in transcriptional regulation in vivo. By analyzing defects resulting from the loss of kis function, we found that KIS-L acts downstream of positive transcription elongation factor b (P-TEFb) recruitment to stimulate elongation by Pol II. KIS-L did not bind methylated histone tails in vitro or extensively co-localize with H3K4me on polytene chromosomes, as would be expected if this modification is necessary or sufficient for the recruitment of KIS-L to chromatin. Surprisingly, the loss of kis function led to a dramatic reduction in the levels of TRX and ASH1 associated with chromatin, accompanied by a significant increase in the level of H3K27 methylation. These findings suggest that KIS-L promotes transcription elongation and counteracts Polycomb group repression by recruiting the ASH1 and TRX histone methyltransferases to chromatin.
KIS-L Acts Downstream of P-TEFb to Facilitate Elongation by Pol II
Previous studies in our laboratory suggested that KIS-L promotes a step in transcription downstream of the recruitment of Pol II to promoters . The phosphorylation of the heptapeptide repeat Y1S2P3T4S5P6S7 of the C-terminal domain (CTD) of Pol II is highly regulated during the transcription cycle . When recruited to promoters, the CTD is hypophosphorylated (Pol IIa). Phosphorylation of serine 5 of the CTD by the Cdk7 subunit of TFIIH is associated with promoter clearance and Pol IIoser5 is enriched in promoter-proximal regions . The subsequent phosphorylation of serine 2 of the CTD by the Cdk9 subunit of P-TEFb relieves pausing and stimulates the transition to active elongation . Thus, Pol IIoser2 is associated with the body of actively transcribed genes. Using antibodies sensitive to the phosphorylation state of the CTD, we previously demonstrated that the loss of kis function leads to a dramatic reduction in the level of Pol IIoser2 - but not Pol IIa or Pol IIoser5 - associated with salivary gland polytene chromosomes . This observation suggested that KIS-L is required for a relatively early step in elongation by Pol II.
A key step in early elongation is the recruitment of P-TEFb to promoters . P-TEFb (a heterodimer of CycT and Cdk9) has multiple functions: it phosphorylates serine 2 of the CTD; promotes the maturation of elongation complexes; counteracts promoter-proximal pausing induced by the DRB sensitivity-inducing factor (DSIF) and negative elongation factor (NELF); and stimulates the processivity of elongating Pol II . The loss of P-TEFb function causes defects similar to those observed in kis mutants, including a reduction in the level of Pol IIoser2, but not Pol IIa or Pol IIoser5, associated with chromatin ,. We therefore suspected that KIS-L might be required for the recruitment of P-TEFb to promoters.
To determine whether KIS-L is required for P-TEFb recruitment, we stained polytene chromosomes of wild-type and kisk13416 larvae with an antibody against the CycT subunit of P-TEFb . As expected, the chromosomal distribution of P-TEFb and Pol IIoser2 overlap extensively in wild-type larvae (Figure 1A and C). Although the level of Pol IIoser2 associated with polytene chromosomes is dramatically reduced in kisk13416 larvae (Figure 1A and B), the loss of kis function has no obvious effect on either the level or distribution of CycT (Figure 1C and D). Thus, KIS-L affects a step in transcription downstream of the recruitment of P-TEFb to promoters.
Polytene chromosomes isolated from wild-type (A, C, E, and G) and kisk13416 (B, D, F, and H) larvae were stained with antibodies against Pol IIoser2 (A, B) and the CycT subunit of P-TEFb (C, D) or the CTD of RPB1 (that recognizes hypo- and hyper-phosphorylated forms of Pol II) (E, F) and BRM (G, H). The levels of total Pol II and Pol IIoser2 are reduced in kis mutants while the levels of BRM and CycT are not altered.
How does KIS-L influence transcription? The reduced levels of Pol IIoser2 on the salivary gland chromosomes of kis mutants could be due to either the decreased phosphorylation of serine 2 of the CTD or the stalling or loss of Pol II downstream of promoters. To distinguish between these possibilities, we stained polytene chromosomes of wild-type and kisk13416 larvae with an antibody (CTD4H8) that recognizes hypo- and hyper-phosphorylated forms of Pol II . The level of total Pol II associated with the salivary gland polytene chromosomes of kisk13416 larvae was significantly reduced relative to wild-type (Figure 1E and F); by contrast, the level of chromatin-remodeling factor BRM was not altered (Figure 1G and H). These findings suggest that KIS-L prevents the stalling or loss of Pol II a relatively short distance downstream of promoters.
KIS-L Co-localizes with the ASH1 and TRX Histone Methyltransferases on Polytene Chromosomes
We next investigated the functional relationship between KIS-L and the trithorax group proteins ASH1 and TRX. It has been reported that both ASH1 and TRX methylate H3K4 ,,; this covalent modification of chromatin is enriched near the promoters of many genes and is thought to recruit factors required for early events in the transcription cycle . Like other CHD proteins, KIS-L has two adjacent chromodomains (CD1 and CD2) suggesting that it might directly interact with methylated histone tails. We therefore suspected that ASH1 and TRX might activate transcription by recruiting KIS-L to promoters.
As a first step toward testing this hypothesis, we compared the distributions of KIS-L, ASH1 and TRX on polytene chromosomes. As reported previously , ASH1 binds to approximately one hundred sites on salivary gland polytene chromosomes (Figure 2A). Strong TRX staining is observed at about 20 sites on polytene chromosomes ,, but weaker signals are evident at many other sites (Figure 2H) . The chromosomal distributions of KIS-L and ASH1 are strikingly similar, with overlapping signals observed at more than 95% of the binding sites of both proteins (Figure 2A–G). The chromosomal distributions of KIS-L and TRX are also similar, but not identical, with overlapping signals present at approximately 85% of the bindings sites of both proteins (Figure 2H–N). The co-localization of KIS-L, ASH1 and TRX at the majority of active genes is consistent with a close functional relationship between the three proteins.
A–C) The distributions of ASH1 (A, red) and KIS-L (B, green) on wild-type polytene chromosomes are shown together with the merged image (C). D–G: Magnification of the chromosome arm bounded by the white rectangle in C is shown. Arrows in G mark examples of KIS-L bands that do not overlap with ASH1. H–J) The distributions of TRX (H, red), KIS-L (I, green) and the merged image (J) are shown. K–N: represent the magnification of the chromosome arm bound by the white rectangle in J. The arrows in N represent bands of KIS-L that do not overlap with TRX.
The Chromodomains of KIS-L Do Not Bind Methylated Histone Peptides in Vitro
CD2 of KIS-L is highly related to chromodomains that directly bind methylated histone tails (Figure 3A), including CD2 of yeast CHD1, which binds both di- and tri-methylated H3K4 . This similarity suggested that KIS-L might directly bind methylated H3K4. To investigate this possibility, we examined the ability of recombinant KIS-L proteins to bind immobilized synthetic peptides corresponding to N-terminal histone tails. A recombinant protein corresponding to KIS-L CD2 (residues 1937 to 1997) did not bind unmodified histone H3 tails or a variety of methylated H3 tails (including H3K4me2, H3K4me3, and H3K9me2), even at relatively low (150 mM) salt concentrations (Figure 3B). By contrast, we were able to detect the binding of the Drosophila HP1 chromodomain to H3K9me2 using this assay (Figure 3B), as previously observed by others ,. Recent studies of the human CHD1 protein have shown that both CD1 and CD2 are required for binding of methylated H3K4 in vitro ,. While we were able to reproduce this result (Figure 3B), a comparable recombinant protein spanning CD1 and CD2 of KIS-L – as well as full-length KIS-L proteins from embryo extracts – bound both unmodified and methylated H3 and H4 tails (data not shown), presumably due to non-specific ionic interactions with the positively charged tails. We were therefore unable to determine if regions outside of CD2 enable KIS-L to bind methylated histone tails. Thus, although KIS-L CD2 failed to interact with methylated histone tails in vitro, it remains possible that the full-length KIS-L protein recognizes one or more histone modifications in vivo.
A) CD2 of KIS-L is aligned with CD2 of other CHD proteins and the chromodomains of Drosophila HP1 and PC. Identical and conserved amino acids are highlighted in black and grey, respectively. Aromatic amino acids that are important for binding of methylated histone tails by the CD2 of yeast CHD1 are marked by stars. B) The in vitro binding of HIS-tagged CD2 of KIS-L, CD1 and 2 of human CHD1 and the Drosophila HP1 chromodomain to histone H3K4me2, H3K4me3, H3K9me2 and histone H3 peptides were examined. Input (I), unbound protein (S) and the bound proteins (P) were detected by western blotting using anti-HIS tag antibody. Note that the chromodomains of HP1 and human CHD1, but not KIS-L, specifically bound methylated H3K9 and H3K4 peptides, respectively. C–D) The distributions of H3K4me2 (C, red) and H3K4me3 (D, red) were compared to that of KIS-L (C and D, green) on a representative region of wild-type polytene chromosomes. The arrowheads represent H3K4me2 and H3K4me3 bands that do not overlap with KIS-L, respectively, while the arrows represent bands of KIS-L that do not overlap with H3K4me2 and H3K4me3 bands, respectively. E–F) The distributions of KIS-L and H3K4me3 over the fkh gene were determined by ChIP using chromatin isolated from the salivary glands of wild-type (red bars) or kisk13416 (green bars) larvae. A map of the fkh gene is shown below the X axis; black bars represent the primers used to amplify the following regions: C1: region upstream of fkh, E: fkh enhancer, P: fkh transcription start site, B: fkh body, C2: region downstream of fkh. For KIS-L, the percentages of DNA immunoprecipitated for regions E, P, B and C2 were normalized to the percentage of DNA immunoprecipitated for region C1 (E). The ratio of DNA immunoprecipitated with antibodies against H3K4me3 and histone H3 are shown for each region (F). Note that KIS-L is enriched over the transcription start site of fkh while H3K4me3 is enriched over both the transcription start site and the body of fkh gene. The bars represent the average of independent biological experiments (n = 4 for H3K4me3 and n = 5 for KIS-L) with the corresponding standard deviations.
H3K4 Methylation Is Not the Primary Determinant for the Recruitment of KIS-L to Chromatin
As an alternative approach for studying potential interactions between KIS-L and methylated histone tails, we compared the distributions of KIS-L and both di- and tri-methylated H3K4 on salivary gland polytene chromosomes. As expected for modifications associated with transcriptionally active regions, there is a high degree of overlap between KIS-L and both H3K4me2 and H3K4me3 (Figure 3C–D and Figure S1). However, there are many sites where KIS-L and these methyl marks do not overlap as well as considerable differences in the relative levels of KIS-L and H3K4 methylation at many sites (Figure 3C–D and Figure S1). These observations suggest that H3K4 methylation is not sufficient to recruit KIS-L to chromatin.
We next examined the relative distributions of H3K4 methylation and KIS-L at higher resolution using chromatin immunoprecipitation (ChIP) assays. We chose the forkhead (fkh) gene for these studies for several reasons. First, fkh is a relatively simple gene that is expressed in the salivary gland at high levels. A single enhancer located 9 kb upstream of the transcription start site activates fkh expression in this tissue . Furthermore, TRX has been implicated in fkh expression  and we have demonstrated that KIS-L is associated with fkh by immuno-FISH (data not shown).
We examined the binding of KIS-L to the fkh gene by ChIP using chromatin isolated from the salivary glands of wild-type third instar larvae. Consistent with a role in early elongation, KIS-L is associated with the transcriptional start site of the fkh gene (Figure 3E). The enrichment of KIS-L with the transcriptional start site is about 3-fold over a control region upstream of fkh (Figure 3E, primer P vs. primer C1). This binding is reduced to background levels in chromatin isolated from kis mutant larvae, suggesting that the association of KIS-L with fkh is specific (Figure 3E). This finding is consistent with a recent study showing that KIS-L is associated with the Ultrabithorax (Ubx) promoter . H3K4me3 is present at the transcription start site as well as the body of the fkh gene and does not precisely mirror the distribution of KIS-L (Figure 3F). These observations provide additional evidence that H3K4 methylation is not sufficient to recruit KIS-L to chromatin.
As an alternative approach for investigating the role of H3K4 methylation in KIS-L recruitment, we examined the effect of little imaginal discs (lid) mutations on the association of KIS-L with chromatin. lid encodes a H3K4me3 demethylase , , , ; larvae homozygous for the hypomorphic lid10424 allele survive until the third larval instar and display elevated levels of H3K4me3 on their polytene chromosomes . Increased trimethylation of H3K4 resulting from the loss of lid function has no obvious effect on the level of KIS-L associated with polytene chromosomes (Figure 4), suggesting that this covalent modification of chromatin does not mediate interactions between KIS-L and chromatin in vivo.
A–D) The levels of H3K4me3 (A, B, red) and KIS-L (C, D, green) on polytene chromosomes isolated from wild-type (A, C) and lid10424 (B, D) larvae were examined by indirect immunofluorescence microscopy. Loss of lid function led to a dramatic increase in H3K4me3 without affecting the level of KIS-L associated with chromatin.
Neither ASH1 nor TRX Is Required for the Association of KIS-L with Chromatin
The above results led us to question our hypothesis that ASH1 and TRX recruit KIS-L to chromatin by methylating H3K4 in the vicinity of promoters. To clarify this issue, we examined whether the loss of ASH1 or TRX function alters the association of KIS-L with salivary gland polytene chromosomes. Individuals trans-heterozygous for the hypomorphic ash122 and ash117 alleles survive until the third larval instar and display significantly reduced levels of ASH1 on polytene chromosomes (Figure 5A and C) . No obvious changes in the level or distribution of KIS-L were observed in these mutants relative to wild-type (Figure 5B and D), indicating that ASH1 is not required for the association of KIS-L with chromatin. Similar results were obtained using a conditional trx allele, trx1. At 29°C, trx1 homozygotes survive until the third larval instar and display significantly reduced levels of TRX on polytene chromosomes (Figure 5E and G) . We failed to detect obvious changes in the level or distribution of KIS-L on salivary gland chromosomes in trx1 mutants (Figure 5F and H). Thus, neither the ASH1 nor TRX histone methyltransferases are required for the association of KIS-L with chromatin in vivo.
A–D) The association of ASH1 (A, C, red) and KIS-L (B, D, green) on salivary gland polytene chromosomes of wild-type (A, B) and ash122/ash117 (C, D) larvae were detected by indirect immunofluorescence microscopy. E–H) The association of TRX (E, G, red) and KIS-L (F, H, green) on polytene chromosomes isolated from wild-type (E, F) and trx1 (G, H) larvae were detected by indirect immunofluorescence microscopy. Neither ASH1 nor TRX is required for the binding of KIS-L to polytene chromosomes.
KIS-L Is Required for the Association of ASH1 and TRX with Chromatin
In some cases, chromatin-remodeling factors stimulate transcription by recruiting histone-modifying enzymes to promoters ,. We therefore examined if KIS-L is required for the association of ASH1 and TRX with chromatin. The loss of kis function resulted in a significant reduction in the levels of both ASH1 and TRX associated with polytene chromosomes (Figure 6A–G). This is unlikely to result from the decreased expression of ASH1 or TRX, as western blotting indicated that both proteins, though slightly reduced, were still present in kis mutants (Figure S2). A few residual bands of relatively strong ASH1 and TRX staining were observed in the mutants (Figure 6C and G), suggesting that the recruitment of the two trithorax group proteins to a small number of chromosomal sites may be independent of KIS-L. These results demonstrate that KIS-L is required for the recruitment of ASH1 and TRX to the majority of their target genes in vivo.
The distribution of ASH1 (A, C, red) and TRX (E, G, red) on salivary gland polytene chromosomes isolated from wild-type and kisk13416 larvae were detected by indirect immunofluorescence microscopy. The chromosomes were also stained with an antibody against Pol IIa (B, D, F, H, green) as an internal control. The loss of KIS-L function dramatically reduces the levels of ASH1 and TRX, but not Pol IIa, associated with polytene chromosomes.
Although the substrate specificity of ASH1 is controversial, at least one previous study reported it to be responsible for the bulk of H3K4 methylation in the larval salivary gland . This observation, together with our finding that KIS-L recruits ASH1 and TRX to actively transcribed genes, led us to investigate whether KIS-L is a global regulator of H3K4 methylation. Surprisingly, we did not observe a significant decline in either H3K4 di- or trimethylation on the polytene chromosomes of kisk13416 mutant larvae, (Figure 7). Consistent with these data, the loss of KIS-L function had no effect on the level of H3K4 methylation over the promoter and body of the fkh gene, as assayed by ChIP (Figure 3F). We also examined the level of H3K4me2 and H3K4me3 on the salivary gland polytene chromosomes of ash1 and trx mutant larvae. As observed in kis mutants, there was no significant decrease in H3K4 di- or trimethylation in either ash122/ash117 or trx1 larvae relative to wild type (Figure S3 and S4). These data strongly suggest that ASH1, TRX and KIS-L are not required for the bulk of H3K4 methylation in Drosophila.
The distribution of H3K4me2 (A, C, red), KIS-L (B, D, F and H, green), and H3K4me3 (E, G, red) on salivary gland polytene chromosomes isolated from wild-type (A, B, E and F) and kisk13416 (C, D, G and H) larvae were detected by indirect immunofluorescence microscopy. The loss of KIS-L function does not cause obvious changes in the overall level or distribution of either H3K4me2 or H3K4me3.
KIS-L Does Not Stably Interact with Other Trithorax Group Proteins in Vivo
Using gel filtration chromatography, we previously showed that the 574 kDa KIS-L protein is a subunit of large (~1 MDa) complex, suggesting that it might also physically interact with other trithorax group proteins to regulate transcription by Pol II . Gel filtration chromatography is sensitive to protein conformation, however, and erroneously high estimates of the native molecular masses of CHD1 and several other chromatin-remodeling factors have been obtained using this technique ,,. We therefore re-examined whether KIS-L functions as a subunit of a large protein complex by sedimenting Drosophila embryo extracts through sucrose density gradients (Figure S5). In contrast to the results we obtained using gel filtration chromatography, we found that the native and predicted molecular masses of the KIS-L protein are virtually identical; the 574 kDa KIS-L protein co-sedimented with ISWI complexes, which have a native molecular mass of ~0.5 MDa (Figure S5). These data suggest that KIS-L acts as a monomer to regulate transcription by Pol II.
We also employed a genetic approach to investigate whether KIS-L acts as a monomer. Mutations in a conserved lysine residue in the ATP-binding site of chromatin-remodeling factors eliminate their catalytic activity without interfering with their ability to interact with other proteins. For chromatin-remodeling factors that function as subunits of protein complexes (e.g. BRM and ISWI), such catalytically inactive proteins exert strong, dominant-negative effects when expressed at high levels in vivo . Unlike catalytically inactive forms of BRM and ISWI (ISWIK159R and BRMK804R), the expression of high levels of an equivalent form of KIS-L (KIS-LK2060R) had no effect on the viability or development of a wide variety of tissues (data not shown). These findings provide additional, albeit indirect, evidence that KIS-L does not stably interact with other trithorax group proteins as a subunit of a chromatin-remodeling complex.
Loss of kis Function Does Not Alter the Level or Distribution of Polycomb Group Proteins on Polytene Chromosomes
Genetic studies have suggested that KIS-L and other trithorax group proteins counteract Polycomb group repression ,. Two complexes of Polycomb group proteins have been identified: PRC1 and PRC2 . The E(Z) subunit of PRC2 methylates lysine 27 of histone H3; this modification is thought to promote the association of PRC1 with chromatin, thereby leading to hereditable gene silencing ,. Does KIS-L prevent the binding of either PRC1 or PRC2 to chromatin? As reported previously, the level of the PC subunit of PRC1 associated with salivary gland polytene chromosomes is similar in wild-type and kisk13416 mutant larvae (Figure 8A and B) . Similar results were obtained when we compared the level of E(Z) on salivary gland chromosomes of wild-type and kisk13416 mutant larvae (Figure 8C and D). The loss of KIS-L function did not alter the number or distribution of PC binding sites (Figure 8G and H), and extensive co-localization of PC and E(Z) was observed in both wild-type and kis mutant larvae (Figure 8E and F). Thus KIS-L does not appear to influence the association of either PRC1 or PRC2 with chromatin.
A–F) The distribution of PC (A, B, green) and E(Z) (C, D, red) and the merged images of PC and E(Z) (E, F) on polytene chromosomes isolated from wild-type (A, C, E) and kisk13416 (B, D, F) larvae are shown. G–H) Comparison of the distribution of PC on the distal tip of the X chromosome of wild-type and kisk13416 larvae (G), together with the corresponding DAPI staining (H). Note that the loss of kis function does not lead to obvious changes in the level or distribution of PC or E(Z).
KIS-L Counteracts H3 Lysine 27 Trimethylation in Vivo
We previously noted that the majority (>80%) of PC binding sites in salivary gland polytene chromosomes are adjacent to sites of KIS-L binding . The majority of sites of H3K27 methylation are also flanked on one or both sides by KIS-L (Figure S6). These observations, together with the lack of obvious changes in the level or distribution of PRC1 and PRC2 in kis mutants, suggested that KIS-L might counteract Polycomb group repression by antagonizing H3K27 methylation. To investigate this possibility, we stained salivary gland polytene chromosomes of wild-type and kisk13416 mutant larvae with an antibody that specifically recognizes this histone modification. Loss of kis function results in a large (~7 fold) increase in the level of H3K27me3 on polytene chromosomes (Figure 9A and B) without altering the level or distribution of PC (Figure 9C and D). A similar increase in H3K27 trimethylation was observed over the entire fkh gene of kisk13416 mutant larvae by ChIP (Figure 9G).
A–D) The level and distribution of H3K27me3 (A, B, red) and PC (C, D, green) on salivary gland polytene chromosomes of wild-type (A, C) and kisk13416 (B, D) larvae was examined by double-label indirect immunofluorescence microscopy. Split images of the distributions of H3K27me3 (red) and PC (green) on wild-type (E) and kisk13416 (F) polytene chromosomes are shown. Loss of kis function results in an increase in the levels of H3K27me3 without altering the distribution of this modification on polytene chromosomes. For panels E and F, the levels of H3K27me3 were independently processed using Adobe Photoshop software to facilitate the comparison of the methyl mark and PC. G) The distribution of H3K27me3 over the fkh gene was determined by ChIP using chromatin isolated from the salivary glands of wild-type (red bars) or kisk13416 (green bars) larvae. A map of the fkh gene is shown below the X axis; black bars represent the primers used to amplify the following regions: C1: region upstream of fkh, E: fkh enhancer, P: fkh transcription start site, B: fkh body, C2: region downstream of fkh. The ratio of DNA immunoprecipitated with antibodies against H3K27me3 and histone H3 are shown for each region. The bars represent the average of three independent biological experiments with the corresponding standard deviations. The loss of KIS-L function leads to a significant increase in H3K27me3 over the entire fkh region.
E(Z) is responsible for the majority of H3K27 methylation in Drosophila , suggesting that the increased trimethylation of H3K27 in kis mutants is dependent on the action of Polycomb group proteins. Consistent with this view, the chromosomal distributions of PC and H3K27me3 are virtually identical (>90% overlap) in both wild type and kisk13416 mutant larvae (Figure 9E and F). Although the level of H3K27 methylation is elevated in kisk13416 mutants, the chromosomal distribution of both Polycomb group proteins and H3K27me3 appears to be relatively normal, suggesting that this increase is not due to the appearance of Polycomb group proteins or H3K27me at ectopic sites (Figure 9E and F). These findings suggest that that KIS-L antagonizes Polycomb group repression by counteracting H3K27 methylation catalyzed by the E(Z) subunit of PRC2.
A recent study showed that loss of ash1 function in the haltere discs of third instar larvae results in the spread of H3K27me3 into the coding region of the actively transcribed Ubx gene . Thus, KIS-L may indirectly counteract H3K27 methylation by promoting the association of ASH1 with chromatin. To investigate this possibility, we compared the level and distribution of H3K27me3 on the salivary gland polytene chromosomes of wild-type and ash1 mutant larvae. As observed in kis mutants, the level of H3K27me3 is dramatically elevated on the salivary gland polytene chromosomes of ash122/ash117 larvae relative to wild-type (Figure 10A and B). A similar effect was observed in trx1 homozygotes reared at 29° (Figure 10C and D). These findings suggest that KIS-L counteracts Polycomb group repression by promoting the association of ASH1 and TRX with chromatin.
The levels of H3K27me3 (A–D, red) on polytene chromosomes isolated from wild-type (A, C), ash122/ash117 (B) and trx1 (D) larvae were detected by double-label indirect immunofluorescence microscopy. H3K27me3 levels are higher on polytene chromosomes isolated from ash122/ash117 and trx1 mutants as compared to wild-type chromosomes. As an internal control, the chromosomes were simultaneously stained with antibodies against the RPB1 subunit of RNA Pol II (inset in lower right corner of A–D, green).
KIS-L Acts Downstream of P-TEFb to Promote Early Elongation by Pol II
The recent discovery that paused polymerases are present downstream of the promoters of many eukaryotic genes has stimulated great interest in the factors that regulate elongation by Pol II. Our findings suggest that KIS-L plays a critical role in this process. The initial stages of transcription, including the recruitment of Pol II to promoters and promoter clearance, are not affected by the loss of kis function. By contrast, the loss of kis function leads to a dramatic reduction in the level of elongating Pol II associated with chromatin. These findings suggest that KIS-L prevents the stalling or loss of Pol II a relatively short distance downstream of promoters.
How does KIS-L facilitate elongation? A key step in early elongation is the recruitment of P-TEFb to promoters. P-TEFb phosphorylates DSIF, NELF and the CTD of Pol II to counteract promoter-proximal pausing and stimulate elongation . Treatment with flavopiridol, an inhibitor of P-TEFb kinase activity, causes transcription defects similar to those observed in kis mutant larvae ,. We therefore suspected that KIS-L might promote elongation by recruiting P-TEFb to promoters. The loss of kis function had no effect on the level of the CycT subunit of P-TEFb associated with chromatin, however, suggesting that KIS-L acts downstream of P-TEFb recruitment to stimulate elongation.
Nucleosomes present a physical barrier to Pol II that must be overcome to permit elongation; the failure to remove this barrier in kis mutants could cause the stalling or loss of Pol II downstream of promoters. Although the biochemical activities of KIS-L have not been characterized, all CHD proteins studied to date have ATP-dependent chromatin-remodeling activity in vitro . It therefore seems likely that KIS-L facilitates elongation by altering the structure or spacing of nucleosomes in the vicinity of promoters. Precedent for this model is provided by work demonstrating that mammalian SWI/SNF stimulates elongation by remodeling nucleosomes downstream of the Hsp70 promoter .
Functional Interactions between KIS-L and Other Trithorax Group Proteins during the Transcription Cycle
A major goal of research on trithorax group proteins is to determine how they interact with each other and the general transcription machinery to activate gene expression and counteract Polycomb group repression. The majority of trithorax group proteins can be subdivided into three major classes based on their biochemical properties . The first class consists of proteins involved in ATP-dependent chromatin remodeling, including KIS-L and the SWI/SNF subunits BRM, MOR, OSA and SNR1. The second class consists of histone-modifying enzymes, including ASH1 and TRX. The third class consists of mediator subunits, including Kohtalo and Skuld. Although BRM and KIS-L were both identified in genetic screens for extragenic suppressors of Polycomb mutations  and overlap extensively on polytene chromosomes , the two proteins appear to facilitate distinct steps in the transcription cycle. The BRM complex (like other SWI/SNF complexes) promotes the association of transcriptional activators with chromatin and is required for the recruitment of Pol II to promoters ,, while KIS-L facilitates an early step in elongation by Pol II. Consistent with these observations, the loss of KIS-L function has no effect on the association of BRM with chromatin in vivo .
The presence of two chromodomains in KIS-L suggested that it might directly interact with nucleosomes in the vicinity of promoters that are methylated on H3K4 by ASH1 or TRX. However, several lines of evidence suggest that H3K4 methylation does not mediate interactions between KIS-L and chromatin. The chromodomains of KIS-L do not interact with H3K4 methylated peptides in vitro and we did not see a strong correlation between the distribution and level of KIS-L and methylated H3K4 on salivary gland polytene chromosomes of either wild-type or lid mutant larvae. Furthermore, neither ASH1 nor TRX are necessary for the association of KIS-L with chromatin in vivo. Although H3K4 methylation does not appear to play an important role in the recruitment of KIS-L to chromatin, it remains possible that this modification mediates transient interactions between KIS-L and its nucleosome substrate.
One of the more surprising outcomes of our work was the discovery that KIS-L is required for the association of ASH1 and TRX with many of their binding sites on polytene chromosomes. How does KIS-L promote the association of ASH1 and TRX with transcriptionally active genes? KIS-L might directly recruit the two proteins or indirectly promote their binding by influencing chromatin structure. Alternatively, KIS-L might promote the association of ASH1 and TRX with actively transcribed genes by promoting the transition from early to active elongation. A key step in this transition is the phosphorylation of serine 2 of the CTD repeat, which serves as a scaffold for the assembly of factors required for elongation and RNA processing . The reduced levels of Pol IIoser2 in kis mutants might therefore account for the decreased levels of ASH1 and TRX associated with chromatin.
Although we observed a dramatic decrease in the level of ASH1 and TRX associated with chromatin in kis mutants, we did not detect any obvious changes in the levels of BRM, Pol IIa, Pol IIoser5 or P-TEFb. These observations strongly suggest that TRX and ASH1, like KIS-L, promote a stage of transcription downstream of initiation and promoter clearance. Our findings reinforce recent studies implicating ASH1 and TRX in transcription elongation in vivo. For example, TRX facilitates transcriptional elongation of heat shock genes  and the TRX-containing TAC1 complex is recruited downstream of the Ubx and bxd non-coding RNA promoters . The levels of the 3′ end of Ubx mRNA and bxd non-coding RNA are reduced as compared to the 5′ end of these RNAs in trx mutants and the levels of SPT16, a member of the FACT elongation complex are also reduced in trx mutants . These observations indicate that TRX might promote the processivity of the elongating polymerase by recruiting the FACT complex. MLL, the mouse homolog of TRX, is associated with the coding region of its target genes and the distribution of the elongating polymerase is altered in Mll mutants . Although a role for ASH1 in elongation has not been firmly established, its binding downstream of the Ubx promoter in Drosophila and the human poly(A) binding protein, cytoplasmic 1 gene in HeLa cells is consistent with a role in promoting transcription elongation ,.
Does KIS-L promote elongation by recruiting ASH1 or TRX to promoters? Arguing against this possibility, we were unable to detect any significant alterations in the levels of Pol II on polytene chromosomes of ash1 and trx single mutants (Figure 10 and data not shown). The failure to observe transcription defects in ash1 and trx single mutants could be due to functional redundancy between the two trithorax group genes. Alternatively, KIS-L may promote elongation via ASH1 and TRX-independent mechanisms. Further work will be required to clarify the relative roles of KIS-L, ASH1 and TRX in transcription by Pol II.
KIS-L Is a Negative Regulator of H3K27 Methylation
Several lines of evidence suggest that ASH1 and TRX activate transcription by counteracting Polycomb group repression. For example, in the absence of Polycomb group function, neither ASH1 nor TRX are required for Ubx transcription . Furthermore, the loss of ash1 function in haltere discs leads to the spread of H3K27me3 into the body of the Ubx gene, which is normally transcribed in this tissue . Thus, ASH1 and TRX function may counteract Polycomb group silencing by interfering with H3K27 methylation.
Our discovery that KIS-L promotes the association of ASH1 and TRX with chromatin led us to investigate whether KIS-L might also counteract Polycomb group silencing. Polycomb group proteins are associated with relatively specific regions of chromatin (Polycomb-response elements, or PREs) as revealed by genome-wide ChIP assays ,. By contrast, H3K27me3 is found over broad chromatin domains adjacent to PREs, encompassing both the regulatory and coding regions of transcriptionally silent genes . The loss of kis function led to a significant increase in the levels of H3K27me3 on salivary gland polytene chromosomes, suggesting that KIS-L may prevent the spreading of H3K27 methylation in the vicinity of PREs. Our observations provide a molecular explanation for the functional antagonism between kis and Polycomb group genes.
How does KIS-L antagonize H3K27 methylation? The steady-state level of H3K27 methylation is determined by multiple factors, including the level and activity of the E(z) methyltransferase; the accessibility of its nucleosome substrate; the frequency of nucleosome eviction; the frequency of histone H3 exchange, and the level and activity of histone H3K27 demethylases. The loss of KIS-L does not alter the distribution or level of PRC1 or PRC2 on polytene chromosomes, suggesting that it acts downstream of the E(Z) methyltransferase to counteract H3K27 methylation. Several H3K27 demethylases have been identified, including JMJD3 and UTX . Drosophila UTX co-localizes with elongating Pol II, suggesting that H3K27 demethylation may be directly coupled to transcription elongation . In humans, both JMJD3 and UTX are associated with complexes containing MLL proteins, the human orthologues of Drosophila TRX ,. Thus, KIS-L may indirectly antagonize H3K27 methylation by promoting elongation or the association of TRX with chromatin.
It is also possible that KIS-L counteracts H3K27 methylation by promoting the replacement of histone H3 by the histone variant H3.3. H3.3 displays covalent modifications associated with actively transcribed genes, including elevated H3K4 methylation and low levels of H3K27 methylation . Elevated histone H3 replacement has also been observed at the binding sites of Polycomb and trithorax group proteins in the vicinity of Drosophila Hox genes . The disruption of histone H3 replacement in cis-regulatory regions could therefore contribute to the increased levels of H3K27 methylation observed in kis, ash1 and trx mutants. The exchange of histone H3 and H3.3 is also elevated in regions transcribed by Pol II . By blocking transcription elongation and the resulting exchange of histone H3, the loss of KIS-L function could lead to elevated levels of H3K27 methylation in the body of genes. This would provide a straightforward explanation for why many transcriptionally active genes are refractory to Polycomb group silencing during early development.
Implications for Human Disease
KIS-L is a member of a large family of CHD proteins that are conserved from flies to humans. Heterozygosity for loss of function mutations in CHD7, a human counterpart of KIS-L, leads to CHARGE syndrome, a serious developmental disorder affecting approximately one in 8,500 births . Our findings suggest that CHARGE syndrome results from defects in transcriptional elongation, possibly due to the diminished recruitment of MLL complexes and elevated H3K27 methylation. Our findings also suggest a possible role for CHD7 in cancer through the recruitment of MLL fusion proteins, which have been implicated in several forms of leukemia . Finally, numerous recent studies have revealed that the methylation of H3K27 by Polycomb proteins is critical for the maintenance of stem cell pluripotency in mammals . By counteracting H3K27 methylation, CHD7 may promote the differentiation of pluripotent stem cells into specialized cell types. Further work will be necessary to test these hypotheses and clarify the role of KIS-L and its human counterparts in transcription, differentiation and disease.
Materials and Methods
Flies were raised on cornmeal/molasses/yeast/agar medium containing Tegosept and propionic acid. Strains are described in FlyBase (http://www.flybase.org) unless otherwise indicated. kisk13416 is a recessive loss of function allele; homozygotes survive until late larval or early pupal stages, but express undetectable levels of KIS-L in salivary gland nuclei . Oregon R was used as the wild-type strain for all experiments.
Immunostaining of Polytene Chromosomes
Indirect immunofluorescence microscopy was used to examine the distribution of proteins on salivary gland polytene chromosomes ,. Primary antibodies used included goat antibodies against PC and KIS-L (Santa Cruz Biotech); rat antibodies against KIS-L ; rabbit antibodies against ASH1 , BRM , CycT , E(Z) , ISWI , KIS-L , TRX , Histone H3, H3K4me2, H3K4me3 and H3K27me3 (Upstate Signaling); and mouse antibodies against Pol IIa (8WG16), PoI IIoser2 (H5), RPB1 (CTD4H8) (Covance) and His epitope tag (Anaspec). Salivary gland polytene chromosomes from third instar larvae were fixed for 5 minutes in 45% acetic acid/1.85% formaldehyde and stained with antibodies against ASH1, TRX, RPB1, Pol IIa, Pol IIoser5 and KIS-L. To stain polytene chromosomes with antibodies against KIS-L, CycT, PoI IIoser2, E(Z), PC, H3K4me2, H3K4me3 and H3K27me3, glands were dissected in 0.7% NaCl and fixed in 6 mM MgCl2, 1% citric acid and 1% Triton X-100 for 2 minutes. Secondary antibodies were obtained from Jackson ImmunoResearch Laboratories (West Grove, PA). Samples were mounted in Vectashield containing DAPI (Vector Laboratories). Images were captured using a Zeiss Axioskop 2 plus microscope equipped with an Axioplan HRm camera and Axiovision 4 software (Carl Zeiss, Germany). Merged and split images were generated using Adobe Photoshop CS3 software as previously described .
The levels of proteins associated with wild-type and mutant polytene chromosomes were compared by processing, capturing and analyzing the samples at the same time under identical conditions as described in Srinivasan et al. (2005). To quantify the increase in H3K27me3 levels in kis mutants, polytene chromosomes from wild-type and mutant larvae stained with antibodies against H3K27me3 were photographed using exposure times that yielded images of comparable intensity. The fold increase in H3K27me3 was calculated as a ratio of the average exposure times for the wild-type and mutant samples.
Protein Expression and Binding Assays
Standard techniques were used to analyze proteins by SDS-PAGE and Western blotting . To produce recombinant chromodomains, DNA encoding KIS-L chromodomain 2 (amino acids 1937–1997) was amplified using the primers 5′-GGAATTCCATATGCAGGACTTTACTGAAGT-3′ and 5′-CGGGATCCGATTTTGTTAAAGCGCAGGTA-3′. DNA encoding the HP1 chromodomain (amino acids 22–75) was amplified using the primers 5′-GGAATTCCATATGGAGGAGTACGCCGTGGA-3′ and 5′-CGGGATCCCTTGCGGCTCGCCTCGTACTG-3′. The amplified sequences were cloned between the Nde I and BamH I sites of pET-16b (Novagen). A pET-16b construct encoding chromodomains 1 and 2 of human CHD1 (amino acids 268 to 443) was generously provided by Sepidah Khorasanizadeh . Chromodomains were expressed as His-tagged proteins in BL21pLysS (Stratagene) and purified by Ni2+ affinity chromatography under native conditions using the manufacturer's protocol (Qiagen). The binding of purified chromodomains to biotinylated peptides corresponding to N-terminal histone tails (Upstate) immobilized on strepavidin agarose (Upstate) was assayed as described in Pray-Grant et al. (2005).
Analysis of Protein Expression in Salivary Glands
Identical numbers of salivary glands were dissected from third instar wild-type or kisk13416 larvae, transferred to an eppendorf tube containing ice-cold 0.7% NaCl, and pelleted by brief centrifugation. After removing the supernatant, the glands were flash frozen in liquid nitrogen. Following the addition of boiling SDS-PAGE loading buffer, proteins were extracted from the glands by grinding with a pestle and analyzed by SDS-PAGE and western blotting using antibodies against ASH1 and TRX.
Fractionation of Protein Extracts on Sucrose Gradients
Proteins were extracted from 0–16 hour Drosophila embryos as described previously  and fractionated by centrifugation through a 10 ml 5–30% sucrose gradient (in 50 mM Hepes, pH 7.6, 500 mM NaCl, 0.55% Tween-20, 10% glycerol, 1 mM MgCl2, 1 mM EDTA) at 4°C for 20 hours at 35,000 rpm in an SW41 rotor (Beckman Instruments). 500 µl fractions were collected and analyzed by SDS-PAGE and western blotting using antibodies against BRM, KIS-L and ISWI.
Chromatin Immunoprecipitation (ChIP) and Quantitative-PCR
Distribution of KIS-L and H3K4 methylation on polytene chromosomes. The distributions of H3K4me2 (B, red) and H3K4me3 (E, red) are compared to that of KIS-L (A and D, green) on wild-type salivary gland polytene chromosomes by double-label indirect immunofluorescence microscopy. Merged images are shown in C and F. KIS-L is present at many, but not all, sites of H3K4 methylation.
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Loss of KIS-L function does not dramatically alter the level of TRX and ASH1 in larval salivary glands. Proteins extracted from equal numbers of salivary glands of wild-type and kisk13416 mutant larvae were analyzed by SDS-PAGE and western blotting using antibodies against TRX and ASH1. The loss of KIS-L function leads to only a modest reduction in the levels of TRX and ASH1, even though the salivary glands of kisk13416 larvae are significantly (greater than two fold) reduced in size relative to those of wild-type larvae.
(0.4 MB TIF)
Loss of ASH1 function does not dramatically alter H3K4 methylation in vivo. The distribution of H3K4me2 (A, C, red), KIS-L (B, D, F and H, green), and H3K4me3 (E, G, red) on salivary gland polytene chromosomes isolated from wild-type (A, B, E and F) and ash122/ash117 (C, D, G and H) larvae were detected by indirect immunofluorescence microscopy. The loss of ASH1 function does not cause obvious changes in the overall level or distribution of either H3K4me2 or H3K4me3.
(4.2 MB TIF)
Loss of TRX function does not dramatically alter H3K4 methylation in vivo. The distribution of H3K4me2 (A, C, red), KIS-L (B, D, F and H, green), and H3K4me3 (E, G, red) on salivary gland polytene chromosomes isolated from wild-type (A, B, E and F) and trx1 (C, D, G and H) larvae were detected by indirect immunofluorescence microscopy. The loss of TRX function does not cause obvious changes in the overall level or distribution of either H3K4me2 or H3K4me3.
(5.7 MB TIF)
KIS-L is not a subunit of a large protein complex. The native molecular mass of KIS-L was determined by fractionating whole embryo extracts by sedimentation through a sucrose density gradient. Fractions were analyzed by SDS-PAGE and western blotting using antibodies against KIS-L, BRM and ISWI. The denatured molecular masses of KIS-L, BRM and ISWI are shown in kDa. KIS-L has a native molecular weight of slightly more than 0.5 MDa based on its sedimentation relative to the 1 MDa BRM and 0.5 MDa ISWI complexes.
(5.0 MB TIF)
Colocalization of KIS-L and H3K27 methylation. A) The distributions of KIS-L (green) and H3K27me3 (red) on wild-type salivary gland polytene chromosomes were compared by double-label immunofluorescence microscopy (A). B–E) The distributions of H3K27me3 (B), KIS-L (C), merged (D) and split (E) images corresponding to chromosome arm bounded by the white rectangle are shown. Note that KIS-L flanks many sites of H3K27me3 staining on polytene chromosomes.
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(0.02 MB DOC)
We thank the Bloomington Stock Center for the Drosophila strains. We thank Grant Hartzog, Tiffani Quan, Susan Strome, Rohinton Kamakaka and the members of our laboratory for numerous helpful discussions during the course of this work. We also thank Sepidah Khorasanizadeh, Richard Jones, Alexander Mazo, David Price and Allen Shearn for generously providing us with antibodies, Drosophila strains and plasmid constructs. We are grateful to Renate Deuring for the generation and analysis of transgenic strains expressing mutant KIS-L proteins.
Conceived and designed the experiments: SS KMD JWT. Performed the experiments: SS KMD. Analyzed the data: SS KMD JWT. Contributed reagents/materials/analysis tools: SS KMD JWT. Wrote the paper: SS KMD JWT.
- 1. Svejstrup JQ (2004) The RNA polymerase II transcription cycle: cycling through chromatin. Biochim Biophys Acta 1677: 64–73.
- 2. Phatnani HP, Greenleaf AL (2006) Phosphorylation and functions of the RNA polymerase II CTD. Genes Dev 20: 2922–2936.
- 3. Li B, Carey M, Workman JL (2007) The role of chromatin during transcription. Cell 128: 707–719.
- 4. Saunders A, Core LJ, Lis JT (2006) Breaking barriers to transcription elongation. Nat Rev Mol Cell Biol 7: 557–567.
- 5. Barski A, Cuddapah S, Cui K, Roh TY, Schones DE, et al. (2007) High-resolution profiling of histone methylations in the human genome. Cell 129: 823–837.
- 6. Guenther MG, Levine SS, Boyer LA, Jaenisch R, Young RA (2007) A chromatin landmark and transcription initiation at most promoters in human cells. Cell 130: 77–88.
- 7. Kim TH, Barrera LO, Zheng M, Qu C, Singer MA, et al. (2005) A high-resolution map of active promoters in the human genome. Nature 436: 876–880.
- 8. Muse GW, Gilchrist DA, Nechaev S, Shah R, Parker JS, et al. (2007) RNA polymerase is poised for activation across the genome. Nat Genet 39: 1507–1511.
- 9. Zeitlinger J, Stark A, Kellis M, Hong JW, Nechaev S, et al. (2007) RNA polymerase stalling at developmental control genes in the Drosophila melanogaster embryo. Nat Genet 39: 1512–1516.
- 10. Gellon G, McGinnis W (1998) Shaping animal body plans in development and evolution by modulation of Hox expression patterns. Bioessays 20: 116–125.
- 11. Schwartz YB, Pirrotta V (2007) Polycomb silencing mechanisms and the management of genomic programmes. Nat Rev Genet 8: 9–22.
- 12. Schuettengruber B, Chourrout D, Vervoort M, Leblanc B, Cavalli G (2007) Genome regulation by Polycomb and trithorax proteins. Cell 128: 735–745.
- 13. Ringrose L, Paro R (2004) Epigenetic regulation of cellular memory by the Polycomb and trithorax group proteins. Annu Rev Genet 38: 413–443.
- 14. Levine SS, King IF, Kingston RE (2004) Division of labor in Polycomb group repression. Trends Biochem Sci 29: 478–485.
- 15. Cao R, Zhang Y (2004) The functions of E(Z)/EZH2-mediated methylation of lysine 27 in histone H3. Curr Opin Genet Dev 14: 155–164.
- 16. Muller J, Hart CM, Francis NJ, Vargas ML, Sengupta A, et al. (2002) Histone methyltransferase activity of a Drosophila Polycomb group repressor complex. Cell 111: 197–208.
- 17. Wang L, Brown JL, Cao R, Zhang Y, Kassis JA, et al. (2004) Hierarchical recruitment of polycomb group silencing complexes. Mol Cell 14: 637–646.
- 18. Beisel C, Imhof A, Greene J, Kremmer E, Sauer F (2002) Histone methylation by the Drosophila epigenetic transcriptional regulator Ash1. Nature 419: 857–862.
- 19. Smith ST, Petruk S, Sedkov Y, Cho E, Tillib S, et al. (2004) Modulation of heat shock gene expression by the TAC1 chromatin-modifying complex. Nat Cell Biol 6: 162–167.
- 20. Byrd KN, Shearn A (2003) ASH1, a Drosophila trithorax group protein, is required for methylation of lysine 4 residues on histone H3. Proc Natl Acad Sci U S A 100: 11535–11540.
- 21. Petruk S, Sedkov Y, Smith S, Tillib S, Kraevski V, et al. (2001) Trithorax and dCBP acting in a complex to maintain expression of a homeotic gene. Science 294: 1331–1334.
- 22. Tanaka Y, Katagiri Z, Kawahashi K, Kioussis D, Kitajima S (2007) Trithorax-group protein ASH1 methylates histone H3 lysine 36. Gene 397: 161–168.
- 23. Ruthenburg AJ, Allis CD, Wysocka J (2007) Methylation of lysine 4 on histone H3: intricacy of writing and reading a single epigenetic mark. Mol Cell 25: 15–30.
- 24. Klymenko T, Muller J (2004) The histone methyltransferases Trithorax and Ash1 prevent transcriptional silencing by Polycomb group proteins. EMBO Rep 5: 373–377.
- 25. Papp B, Muller J (2006) Histone trimethylation and the maintenance of transcriptional ON and OFF states by trxG and PcG proteins. Genes Dev 20: 2041–2054.
- 26. Kingston R, Tamkun JW (2007) Transcriptional Regulation by Trithorax Group Proteins. In: Allis CD, Jenuwein T, Reinberg D, Caparros M-L, editors. Epigenetics. Cold Spring Harbor, N.Y.: Cold Spring Harbor Laboratory Press. pp. 231–248.
- 27. Kennison JA, Tamkun JW (1988) Dosage-dependent modifiers of Polycomb and Antennapedia mutations in Drosophila. Proc Natl Acad Sci U S A 85: 8136–8140.
- 28. Daubresse G, Deuring R, Moore L, Papoulas O, Zakrajsek I, et al. (1999) The Drosophila kismet gene is related to chromatin-remodeling factors and is required for both segmentation and segment identity. Development 126: 1175–1187.
- 29. Therrien M, Morrison DK, Wong AM, Rubin GM (2000) A genetic screen for modifiers of a kinase suppressor of Ras-dependent rough eye phenotype in Drosophila. Genetics 156: 1231–1242.
- 30. Srinivasan S, Armstrong JA, Deuring R, Dahlsveen IK, McNeill H, et al. (2005) The Drosophila trithorax group protein Kismet facilitates an early step in transcriptional elongation by RNA Polymerase II. Development 132: 1623–1635.
- 31. Brehm A, Tufteland KR, Aasland R, Becker PB (2004) The many colours of chromodomains. Bioessays 26: 133–140.
- 32. Flanagan JF, Mi LZ, Chruszcz M, Cymborowski M, Clines KL, et al. (2005) Double chromodomains cooperate to recognize the methylated histone H3 tail. Nature 438: 1181–1185.
- 33. Pray-Grant MG, Daniel JA, Schieltz D, Yates JR 3rd, Grant PA (2005) Chd1 chromodomain links histone H3 methylation with SAGA- and SLIK-dependent acetylation. Nature 433: 434–438.
- 34. Sims RJ 3rd, Chen CF, Santos-Rosa H, Kouzarides T, Patel SS, et al. (2005) Human but not yeast CHD1 binds directly and selectively to histone H3 methylated at lysine 4 via its tandem chromodomains. J Biol Chem 280: 41789–41792.
- 35. Price DH (2000) P-TEFb, a cyclin-dependent kinase controlling elongation by RNA polymerase II. Mol Cell Biol 20: 2629–2634.
- 36. Peterlin BM, Price DH (2006) Controlling the elongation phase of transcription with P-TEFb. Mol Cell 23: 297–305.
- 37. Ni Z, Saunders A, Fuda NJ, Yao J, Suarez JR, et al. (2008) P-TEFb is critical for the maturation of RNA polymerase II into productive elongation in vivo. Mol Cell Biol 28: 1161–1170.
- 38. Ni Z, Schwartz BE, Werner J, Suarez JR, Lis JT (2004) Coordination of transcription, RNA processing, and surveillance by P-TEFb kinase on heat shock genes. Mol Cell 13: 55–65.
- 39. Peng J, Marshall NF, Price DH (1998) Identification of a cyclin subunit required for the function of Drosophila P-TEFb. J Biol Chem 273: 13855–13860.
- 40. Kristjuhan A, Walker J, Suka N, Grunstein M, Roberts D, et al. (2002) Transcriptional inhibition of genes with severe histone H3 hypoacetylation in the coding region. Mol Cell 10: 925–933.
- 41. Tripoulas N, LaJeunesse D, Gildea J, Shearn A (1996) The Drosophila ash1 gene product, which is localized at specific sites on polytene chromosomes, contains a SET domain and a PHD finger. Genetics 143: 913–928.
- 42. Chinwalla V, Jane EP, Harte PJ (1995) The Drosophila trithorax protein binds to specific chromosomal sites and is co-localized with Polycomb at many sites. EMBO J 14: 2056–2065.
- 43. Kuzin B, Tillib S, Sedkov Y, Mizrokhi L, Mazo A (1994) The Drosophila trithorax gene encodes a chromosomal protein and directly regulates the region-specific homeotic gene fork head. Genes Dev 8: 2478–2490.
- 44. Petruk S, Sedkov Y, Riley KM, Hodgson J, Schweisguth F, et al. (2006) Transcription of bxd noncoding RNAs promoted by trithorax represses Ubx in cis by transcriptional interference. Cell 127: 1209–1221.
- 45. Bannister AJ, Zegerman P, Partridge JF, Miska EA, Thomas JO, et al. (2001) Selective recognition of methylated lysine 9 on histone H3 by the HP1 chromo domain. Nature 410: 120–124.
- 46. Lachner M, O'Carroll D, Rea S, Mechtler K, Jenuwein T (2001) Methylation of histone H3 lysine 9 creates a binding site for HP1 proteins. Nature 410: 116–120.
- 47. Zhou B, Bagri A, Beckendorf SK (2001) Salivary gland determination in Drosophila: a salivary-specific, fork head enhancer integrates spatial pattern and allows fork head autoregulation. Dev Biol 237: 54–67.
- 48. Eissenberg JC, Lee MG, Schneider J, Ilvarsonn A, Shiekhattar R, et al. (2007) The trithorax-group gene in Drosophila little imaginal discs encodes a trimethylated histone H3 Lys4 demethylase. Nat Struct Mol Biol 14: 344–346.
- 49. Secombe J, Li L, Carlos L, Eisenman RN (2007) The Trithorax group protein Lid is a trimethyl histone H3K4 demethylase required for dMyc-induced cell growth. Genes Dev 21: 537–551.
- 50. Lloret-Llinares M, Carre C, Vaquero A, de Olano N, Azorin F (2008) Characterization of Drosophila melanogaster JmjC+N histone demethylases. Nucleic Acids Res 36: 2852–2863.
- 51. Lee N, Zhang J, Klose RJ, Erdjument-Bromage H, Tempst P, et al. (2007) The trithorax-group protein Lid is a histone H3 trimethyl-Lys4 demethylase. Nat Struct Mol Biol 14: 341–343.
- 52. Cosma MP, Tanaka T, Nasmyth K (1999) Ordered recruitment of transcription and chromatin remodeling factors to a cell cycle- and developmentally regulated promoter. Cell 97: 299–311.
- 53. Krebs JE, Kuo MH, Allis CD, Peterson CL (1999) Cell cycle-regulated histone acetylation required for expression of the yeast HO gene. Genes Dev 13: 1412–1421.
- 54. Lusser A, Urwin DL, Kadonaga JT (2005) Distinct activities of CHD1 and ACF in ATP-dependent chromatin assembly. Nat Struct Mol Biol 12: 160–166.
- 55. Smith CL, Horowitz-Scherer R, Flanagan JF, Woodcock CL, Peterson CL (2003) Structural analysis of the yeast SWI/SNF chromatin remodeling complex. Nat Struct Biol 10: 141–145.
- 56. Corona DF, Armstrong JA, Tamkun JW (2004) Genetic and cytological analysis of Drosophila chromatin-remodeling factors. Methods Enzymol 377: 70–85.
- 57. Hall JA, Georgel PT (2007) CHD proteins: a diverse family with strong ties. Biochem Cell Biol 85: 463–476.
- 58. Corey LL, Weirich CS, Benjamin IJ, Kingston RE (2003) Localized recruitment of a chromatin-remodeling activity by an activator in vivo drives transcriptional elongation. Genes Dev 17: 1392–1401.
- 59. Kal AJ, Mahmoudi T, Zak NB, Verrijzer CP (2000) The Drosophila brahma complex is an essential coactivator for the trithorax group protein zeste. Genes Dev 14: 1058–1071.
- 60. Armstrong JA, Papoulas O, Daubresse G, Sperling AS, Lis JT, et al. (2002) The Drosophila BRM complex facilitates global transcription by RNA polymerase II. EMBO J 21: 5245–5254.
- 61. Milne TA, Dou Y, Martin ME, Brock HW, Roeder RG, et al. (2005) MLL associates specifically with a subset of transcriptionally active target genes. Proc Natl Acad Sci U S A 102: 14765–14770.
- 62. Gregory GD, Vakoc CR, Rozovskaia T, Zheng X, Patel S, et al. (2007) Mammalian ASH1L is a histone methyltransferase that occupies the transcribed region of active genes. Mol Cell Biol 27: 8466–8479.
- 63. Schwartz YB, Kahn TG, Nix DA, Li XY, Bourgon R, et al. (2006) Genome-wide analysis of Polycomb targets in Drosophila melanogaster. Nat Genet 38: 700–705.
- 64. Tolhuis B, de Wit E, Muijrers I, Teunissen H, Talhout W, et al. (2006) Genome-wide profiling of PRC1 and PRC2 Polycomb chromatin binding in Drosophila melanogaster. Nat Genet 38: 694–699.
- 65. Swigut T, Wysocka J (2007) H3K27 demethylases, at long last. Cell 131: 29–32.
- 66. Smith ER, Lee MG, Winter B, Droz NM, Eissenberg JC, et al. (2008) Drosophila UTX is a histone H3 Lys27 demethylase that colocalizes with the elongating form of RNA polymerase II. Mol Cell Biol 28: 1041–1046.
- 67. De Santa F, Totaro MG, Prosperini E, Notarbartolo S, Testa G, et al. (2007) The histone H3 lysine-27 demethylase Jmjd3 links inflammation to inhibition of Polycomb-mediated gene silencing. Cell 130: 1083–1094.
- 68. Lee MG, Villa R, Trojer P, Norman J, Yan KP, et al. (2007) Demethylation of H3K27 regulates Polycomb recruitment and H2A ubiquitination. Science 318: 447–450.
- 69. McKittrick E, Gafken PR, Ahmad K, Henikoff S (2004) Histone H3.3 is enriched in covalent modifications associated with active chromatin. Proc Natl Acad Sci U S A 101: 1525–1530.
- 70. Mito Y, Henikoff JG, Henikoff S (2007) Histone replacement marks the boundaries of cis-regulatory domains. Science 315: 1408–1411.
- 71. Henikoff S, Ahmad K (2005) Assembly of variant histones into chromatin. Annu Rev Cell Dev Biol 21: 133–153.
- 72. Blake KD, Prasad C (2006) CHARGE syndrome. Orphanet J Rare Dis 1: 34.
- 73. Krivtsov AV, Armstrong SA (2007) MLL translocations, histone modifications and leukaemia stem-cell development. Nat Rev Cancer 7: 823–833.
- 74. Buszczak M, Spradling AC (2006) Searching chromatin for stem cell identity. Cell 125: 233–236.
- 75. Elfring LK, Daniel C, Papoulas O, Deuring R, Sarte M, et al. (1998) Genetic analysis of brahma: the Drosophila homolog of the yeast chromatin remodeling factor SWI2/SNF2. Genetics 148: 251–265.
- 76. Carrington EA, Jones RS (1996) The Drosophila Enhancer of zeste gene encodes a chromosomal protein: examination of wild-type and mutant protein distribution. Development 122: 4073–4083.
- 77. Tsukiyama T, Daniel C, Tamkun J, Wu C (1995) ISWI, a member of the SWI2/SNF2 ATPase family, encodes the 140 kDa subunit of the nucleosome remodeling factor. Cell 83: 1021–1026.
- 78. Harlow E, Lane D (1988) Antibodies: a Laboratory Manual. Cold Spring Harbor: Cold Spring Harbor Publications.
- 79. Danzer JR, Wallrath LL (2004) Mechanisms of HP1-mediated gene silencing in Drosophila. Development 131: 3571–3580.
- 80. Kuras L, Struhl K (1999) Binding of TBP to promoters in vivo is stimulated by activators and requires Pol II holoenzyme. Nature 399: 609–613.