Perinuclear Mlp proteins downregulate gene expression in response to a defect in mRNA export
2005; Springer Nature; Volume: 24; Issue: 4 Linguagem: Inglês
10.1038/sj.emboj.7600527
ISSN1460-2075
AutoresPatrizia Vinciguerra, Nahid Iglesias, Jurgi Camblong, Daniel Zenklusen, Françoise Stutz,
Tópico(s)Nuclear Structure and Function
ResumoArticle3 February 2005free access Perinuclear Mlp proteins downregulate gene expression in response to a defect in mRNA export Patrizia Vinciguerra Patrizia Vinciguerra Department of Cell Biology, Sciences III, University of Geneva, Geneva, Switzerland Search for more papers by this author Nahid Iglesias Nahid Iglesias Search for more papers by this author Jurgi Camblong Jurgi Camblong Search for more papers by this author Daniel Zenklusen Daniel Zenklusen Search for more papers by this author Françoise Stutz Corresponding Author Françoise Stutz Search for more papers by this author Patrizia Vinciguerra Patrizia Vinciguerra Department of Cell Biology, Sciences III, University of Geneva, Geneva, Switzerland Search for more papers by this author Nahid Iglesias Nahid Iglesias Search for more papers by this author Jurgi Camblong Jurgi Camblong Search for more papers by this author Daniel Zenklusen Daniel Zenklusen Search for more papers by this author Françoise Stutz Corresponding Author Françoise Stutz Search for more papers by this author Author Information Patrizia Vinciguerra1, Nahid Iglesias, Jurgi Camblong, Daniel Zenklusen and Françoise Stutz 1Department of Cell Biology, Sciences III, University of Geneva, Geneva, Switzerland *Corresponding author. Department of Cell Biology, Sciences III, University of Geneva, 30 Quai E Ansermet, 1211 Geneva 4, Switzerland. Tel.: +41 22 379 67 29; Fax: +41 22 379 64 42; E-mail: [email protected] The EMBO Journal (2005)24:813-823https://doi.org/10.1038/sj.emboj.7600527 PDFDownload PDF of article text and main figures. ToolsAdd to favoritesDownload CitationsTrack CitationsPermissions ShareFacebookTwitterLinked InMendeleyWechatReddit Figures & Info The mRNA export adaptor Yra1p/REF contributes to nascent mRNP assembly and recruitment of the export receptor Mex67p. yra1 mutants exhibit mRNA export defects and a decrease in LacZ reporter and certain endogenous transcripts. The loss of Mlp1p/Mlp2p, two TPR-like proteins attached to nuclear pores, rescues LacZ mRNA levels and increases their appearance in the cytoplasm, without restoring bulk poly(A)+ RNA export. Chromatin immunoprecipitation, FISH and pulse-chase experiments indicate that Mlps downregulate LacZ mRNA synthesis in a yra1 mutant strain. Microarray analyses reveal that Mlp2p also reduces a subset of cellular transcripts in the yra1 mutant. Finally, we show that Yra1p genetically interacts with the shuttling mRNA-binding protein Nab2p and that loss of Mlps rescues the growth defect of yra1 and nab2 but not other mRNA export mutants. We propose that Nab2p and Yra1p are required for proper mRNP docking to the Mlp platform. Defects in Yra1p prevent mRNPs from crossing the Mlp gate and this block negatively feeds back on the transcription of a subset of genes, suggesting that Mlps link mRNA transcription and export. Introduction Nascent mRNAs rapidly assemble into RNA protein complexes and undergo a series of processing steps, which result in export-competent messenger RNA ribonucleoprotein complexes (mRNPs). Two essential mRNA export factors Yra1p/REF and Sub2p, a DEHX box ATPase/RNA helicase, are recruited during transcription. The binding of Sub2p to mRNA is facilitated by Hpr1p, a component of the THO complex implicated in transcription elongation (Chavez et al, 2000; Lei et al, 2001; Strasser et al, 2002; Zenklusen et al, 2002). Yra1p and Sub2p copurify with THO in a complex called TREX, establishing a functional link between transcription and mRNA export (Strasser et al, 2002). Yra1p and other adaptor proteins such as Npl3p (Gilbert and Guthrie, 2004) facilitate the recruitment of the export receptor Mex67p to the mRNP. Mex67p then promotes mRNP export through the nuclear pore complex (NPC) via direct interactions with FG-nucleoporins (reviewed in Stutz and Izaurralde, 2003). Recent data indicate that Rrp6p, an exonuclease specific for the nuclear exosome, participates in the degradation of nuclear pre-mRNAs, unadenylated and 3′-unprocessed mRNAs, as well as mRNPs produced in yeast TREX mutants (Bousquet-Antonelli et al, 2000; Burkard and Butler, 2000; Hilleren et al, 2001; Libri et al, 2002; Torchet et al, 2002; Zenklusen et al, 2002). The enhanced susceptibility to the nuclear exosome observed in TREX mutants has been attributed to defects in early mRNP assembly and recruitment of maturation or export factors. Mutations in THO components, Sub2p or Yra1p result in reduced mRNA levels and sequestration of newly synthesized transcripts within nuclear foci at or close to the site of transcription (Jensen et al, 2001; Zenklusen et al, 2002; Thomsen et al, 2003). The deletion of Rrp6p in these strains releases transcripts from the dots and restores mRNA levels, suggesting that the exosome retains aberrant mRNPs and favours their destruction (Hilleren et al, 2001; Libri et al, 2002; Zenklusen et al, 2002). Although defects in early mRNP assembly and export appear to affect mRNA stability, independent studies suggested that the low LacZ mRNA levels detected in THO, sub2 or yra1 mutants resulted from transcriptional defects (Jimeno et al, 2002; Huertas and Aguilera, 2003). These two proposals are not mutually exclusive and inefficient mRNP assembly may trigger both a slow-down of mRNA transcription and increased susceptibility to degradation (Vinciguerra and Stutz, 2004). The yeast myosin-like proteins Mlp1p and Mlp2p are large nonessential proteins proposed to form intranuclear filamentous structures anchored at the NPC nuclear basket. Various studies have indicated that these two related proteins have distinct but clearly overlapping functions (Strambio-de-Castillia et al, 1999; Galy et al, 2000; Kosova et al, 2000; Feuerbach et al, 2002; Hediger et al, 2002). Mlp1p and Mlp2p are homologous to hTPR, and related proteins have been identified in Xenopus, Drosophila and Schizosaccharomyces pombe (Cordes et al, 1997; Zimowska et al, 1997; Strambio-de-Castillia et al, 1999). Yeast Mlp proteins and hTPR contain a long N-terminal domain predicted to form coiled-coils, which mediates homodimerization and includes the NPC-binding site (Bangs et al, 1998; Cordes et al, 1998; Strambio-de-Castillia et al, 1999). Several interactions have been described between yeast Mlp proteins and mRNP components. The globular C-terminal region of Mlp1p directly interacts with Nab2p and Npl3p, two shuttling hnRNP proteins required for mRNA export (Green et al, 2003). Mlp1p also copurified with Sub2p, and Mlp2p was found in association with Mex67p (Kosova et al, 2000; Strasser et al, 2002). Despite these interactions, no poly(A)+ RNA export defect was detected in strains lacking Mlp1p, Mlp2p or both (Strambio-de-Castillia et al, 1999; Kosova et al, 2000), indicating that these proteins fulfil no essential role in mRNA export. Interestingly, Mlp1p was recently proposed to contribute to a new step of mRNP surveillance by mediating nuclear retention of unprocessed pre-mRNAs (Galy et al, 2004). This study provides evidence that both Mlp1p and Mlp2p also retain intronless mRNP complexes produced in a yra1 mutant background, that is, mRNPs with early assembly defects. More specifically, the loss of Mlp1p or Mlp2p increases the levels of transcripts reduced in yra1 and substantially rescues the growth defect of both yra1 and nab2 mutants, consistent with a role of Yra1p and Nab2p in proper mRNP docking to Mlp proteins. The data also show that mRNP complexes loaded with mutant Yra1p are sequestered on the Mlp platform and unable to proceed along the export pathway. This block negatively impacts on the expression of a subset of genes, potentially located at the nuclear periphery. The data suggest that Mlp proteins may establish a link between mRNA synthesis and export through the nuclear pores. Results Loss of Mlp proteins rescues the temperature-sensitive phenotype of GFP-yra1-8 The yra1-8 mutant protein, containing two amino-acid substitutions (D10K and E11K), confers a weak growth defect on its own, but acquires a strong and tight temperature-sensitive (ts) phenotype when fused to GFP. At the nonpermissive temperature, the GFP-yra1-8 mutant exhibits nuclear retention of poly(A)+ RNA and accumulation of newly made heat-shock transcripts within nuclear foci. In addition, some transcripts are poorly expressed in this background and sensitive to degradation by the nuclear exosome (Zenklusen et al, 2002). Cells expressing wild-type (wt) GFP-Yra1p have no growth phenotype (data not shown). To extend the functional analysis of Yra1p, we searched for high-copy suppressors of GFP-yra1-8 and identified a genomic clone expressing the first 1000 amino acids of Mlp2p (data not shown). Further characterization of the relationship between Yra1p and Mlp proteins revealed that the deletion of MLP2 or MLP1 also substantially rescued the ts phenotype of GFP-yra1-8, whereas the combined deletion of MLP1 and MLP2 had no beneficial effect (Figure 1A; see Discussion). Overexpression of the N-terminus may interfere with the formation of functional Mlp2p homodimers (Kosova et al, 2000) and thus phenocopy an MLP2 deletion. Because the GFP-yra1-8 growth defect was more efficiently rescued by loss of Mlp1p or Mlp2p than by overexpression of the N-terminal domain of Mlp2p (data not shown), all the following experiments were carried out in the context of MLP gene disruptions. Further genetic analyses showed that the deletion of MLP2 not only suppressed the GFP-yra1-8 phenotype, but was even able to bypass the unviable phenotype of a Δyra1 knockout strain (Figure 1B). These observations taken together indicate that loss of Mlp2p, and to a lesser extent of Mlp1p, alleviates the requirement for intact Yra1p, suggesting a functional interaction between Yra1p and Mlp proteins. Figure 1.(A) Deletion of MLP2 or MLP1 rescues the ts phenotype of GFP-yra1-8. In all, 10-fold dilutions of wt YRA1 or GFP-yra1-8 strains as such, or in combination with Δmlp1, Δmlp2 or Δmlp1Δmlp2, were spotted on YEPD plates and incubated at 25 (two last dilutions only), 34 or 37°C for 3 days. (B) Deletion of MLP2 bypasses the requirement for Yra1p. The YRA1 shuffle strain (yra1::HIS3, pURA3-YRA1) as such, or combined with Δmlp1, Δmlp2 or Δmlp1/2, was spotted on a control plate (YEPD; two last dilutions only) or on medium containing 5-FOA to select against pURA3-YRA1. The YRA1 shuffle strain transformed with a wt YRA1 plasmid (pFS1877) served as positive control. (C) Mlp proteins physically interact with Yra1p and Mex67p in an RNA-dependent manner. Extracts prepared from a nontagged strain (FSY1026) or from strains expressing Mlp1-ProtA (FSY1567) or Mlp2-ProtA (FSY1351) fusions were treated (+) or not treated (−) with RNase A and purified on Pan Mouse IgG Dynabeads. Total extracts (input, left) or affinity-purified (IgG, right) extracts were analysed by Western blotting with antibodies against ProtA or the indicated proteins. Two different exposures are shown for the immunoprecipitation of Yra1p, expressed from the YRA1 cDNA. (D) The GFP-yra1-8 mutation affects mRNP composition and interaction with Mlp2p. Extracts prepared from nontagged or Mlp2-ProtA-tagged strains expressing wt GFP-Yra1p or GFP-yra1-8 and shifted to 37°C for 2.5 h were purified on Pan Mouse IgG Dynabeads. Total or affinity-purified extracts were analysed by Western blotting as above. GFP-yra1-8 migrates slightly more slowly than GFP-Yra1p. Download figure Download PowerPoint Mlp proteins physically interact with mRNP components To define whether Yra1p and additional mRNP components interact with Mlps, proteins copurifying with ProteinA-tagged Mlp1p or Mlp2p were examined by Western blotting (Figure 1C). As these interactions may be mediated by RNA, they were examined in untreated extracts or extracts subjected to a preliminary RNase A treatment. No association was detected between Mlp proteins and the export receptor Crm1p. In contrast, Yra1p, Nab2p and Mex67p, as well as Npl3p, Sub2p and Cbp80p (data not shown), were selected on IgG beads in the presence of Mlp1-ProtA and Mlp2-ProtA, but not with untagged extracts. These observations indicate that Mlp proteins specifically interact with these mRNP components. Yra1p interacts more strongly with Mlp2p than Mlp1p, suggesting an overlapping but distinct functional relationship of Yra1p with either protein, potentially related to the ability of Δmlp2, but not Δmlp1, to bypass Δyra1. The selection of Yra1p and Mex67p on IgG beads was sensitive to RNase A, indicating that interaction of these export factors with Mlp proteins is indirect and mediated by the mRNP. In contrast, interaction of Nab2p with Mlp1p or Mlp2p was only partially sensitive to RNase A, consistent with the proposition that Nab2p can directly interact with Mlp1p (Green et al, 2003) or Mlp2p (A Corbett, personal communication). The GFP-yra1-8 mutation alters interaction with Mlp2p and affects mRNP composition To determine whether the GFP-yra1-8 mutant protein is still capable of interacting with Mlp2p and whether the binding of Mex67p or Nab2p with Mlp2p is altered in the GFP-yra1-8 background, proteins copurifying with Mlp2-ProtA were compared in strains expressing wt GFP-Yra1p or mutant GFP-yra1-8 (Figure 1D). Significantly higher amounts of GFP-yra1-8 copurified with Mlp2-ProtA compared to wt GFP-Yra1p. The levels of Nab2p bound to Mlp2-ProtA were modestly increased in GFP-yra1-8, but also slightly more abundant in total extracts (see input samples and Figure 6D). Importantly, the GFP-yra1-8 mutation strongly inhibited the association of Mex67p with Mlp2-ProtA. These observations suggest that mRNPs loaded with GFP-yra1-8 are retained on Mlp2p and unable to recruit Mex67p. Figure 2.(A) Loss of Mlp1p and Mlp2p restores LacZ mRNA levels in GFP-yra1-8. Strains expressing wt Yra1p (FSY1485) or mutant GFP-yra1-8 (FSY1486) or yra1-8 (FSY1786) proteins as such, or in combination with the indicated Δmlp1, Δmlp2 or Δrrp6 simple, double or triple disruptions, were transformed with the reporter plasmid pLGSD5 (Legrain and Rosbash, 1989) encoding LacZ from a galactose-inducible promoter. Transformants were pregrown in selective medium containing 2% glycerol/2% lactate/0.05% glucose, and LacZ expression was induced by the addition of 3% galactose/1% raffinose for 2.5 h at 37°C. LacZ mRNA levels (light grey bars), defined by primer extension analysis of total RNA, were quantified and normalized to the U1 snRNA internal control. The same strains were analysed for β-galactosidase (β-gal) activity (dark grey bars). LacZ mRNA levels and β-galactosidase enzymatic activities were expressed as a percentage of wt and compared on the same histogram. Error bars have been derived from three independent experiments. (B) In situ localization of LacZ transcripts. The indicated strains transformed with pLGSD5 were induced with galactose as above and processed for in situ hybridization with Cy3-conjugated oligonucleotide probes specific for LacZ mRNA (panels a–e). DAPI staining indicates the position of the nucleus (panels f–j). RNA distribution was examined in fixed cells using a Zeiss axioplan fluorescent microscope with × 100 objective. Exposure time was of 4 s in panels a–d and only 1 s in panel e. (C) LacZ transcripts are located at the nuclear periphery. wt cells transformed with pLGSD5 were induced and prepared as above. Fixed cells were hybridized with Cy3-conjugated LacZ probes and subsequently immunostained with anti-Nsp1p monoclonal and FITC-labelled secondary antibodies. Samples were analysed and images taken with a Zeiss LSM510 confocal microscope. Download figure Download PowerPoint Deletion of MLP1 and MLP2 in GFP-yra1-8 partially rescues LacZ mRNA levels and β-galactosidase activity The rescue of the GFP-yra1-8 ts phenotype in the absence of Mlp2p or Mlp1p suggested that the loss of these proteins may reduce the poly(A)+ RNA export block observed in this mutant strain. However, the analysis of poly(A)+ RNA distribution in GFP-yra1-8 combined with Δmlp1, Δmlp2 or Δmlp1Δmlp2 showed no significant decrease in nuclear poly(A)+ RNA signal relative to GFP-yra1-8 alone (Supplementary Figure 1), suggesting that the better growth of GFP-yra1-8 in the absence of Mlp2p or Mlp1p is not due to a detectable increase in bulk poly(A)+ RNA export. To examine the effect of these mutations on a specific transcript, wt or GFP-yra1-8 mutant strains as such or in combination with Δmlp1, Δmlp2 or Δmlp1Δmlp2 were transformed with pLGSD5, a high-copy plasmid carrying a galactose-inducible and intronless LacZ gene (Legrain and Rosbash, 1989). The levels of LacZ transcripts and β-galactosidase activity were measured after inducing the cells for 2.5 h at 37°C (Figure 2A). LacZ transcripts were barely detectable in GFP-yra1-8 (0.6% of wt, lanes 1 and 5, light grey bars). These very low levels of LacZ transcripts probably result from the combination of a defect in Yra1p and the absence of a bona fide transcription terminator on the pLGSD5 reporter (Long et al, 1995, and see below). Deletion of Mlp1p or Mlp2p had marginal effects in the wt strain, but restored pLGSD5-encoded LacZ mRNA levels up to 50–60% of wt in GFP-yra1-8 (Figure 2A, lanes 1–3 and 5–7). Thus, Mlp proteins significantly affect LacZ mRNA synthesis and/or stability in the mutant, but not in the wt background. Mlp1p and Mlp2p are probably involved in the same process, as the double deletion did not lead to higher LacZ mRNA levels than the single ones (lanes 6–8). Figure 3.LacZ mRNA decay rates differ in GFP-yra1-8 and GFP-yra1-8Δmlp2. Exponential cultures of wt YRA1, YRA1Δmlp2, GFP-yra1-8 and GFP-yra1-8Δmlp2 strains transformed with the pGAL1-LacZ reporter construct were induced in medium containing 3% galactose/1% raffinose for 2.5 h at 37°C, transferred to preheated medium containing 2% glucose and collected after various times in glucose at 37°C. LacZ transcripts were quantified by primer extension and their levels expressed as a percentage of wt at time 0. LacZ mRNA half-lives were calculated as described (Materials and methods). Download figure Download PowerPoint LacZ mRNAs are a substrate for the nuclear exosome when Yra1p is defective (Zenklusen et al, 2002). To investigate whether Mlps participate in the exosome-dependent degradation, we examined LacZ mRNA levels in strains lacking both Rrp6p and Mlps. Δrrp6 is lethal in combination with GFP-yra1-8, but viable when Mlp1p and/or Mlp2p are already missing from the mutant strain (Supplementary Figure 2). The loss of Rrp6p in addition to Mlp1p and Mlp2p in GFP-yra1-8 had a clear additive effect on LacZ mRNA levels, which reached up to 270% of wt (lane 11). To corroborate these observations, we used the milder yra1-8 mutant, which is viable in the absence of Rrp6p and allows to analyse the effect of Δrrp6 alone (Zenklusen et al, 2002). Loss of Rrp6p in yra1-8 restored LacZ transcripts to wt levels (compare lanes 1, 12 and 13), and loss of Mlp1p and Mlp2p in addition to Rrp6p yielded even higher LacZ mRNA amounts (up to 176% of wt; compare lanes 13 and 14). These cumulative effects suggest that Mlp proteins do not contribute to Rrp6p activity, but rather that Rrp6p and Mlp proteins affect LacZ mRNA levels via distinct mechanisms. β-Galactosidase enzymatic activities were measured in all these strains to evaluate what fraction of LacZ transcripts was exported. Like LacZ mRNA levels, β-galactosidase activity was not significantly altered by loss of Mlp1p and/or Mlp2p in wt cells, confirming that Mlp proteins have no major effect on mRNA amounts and export under normal conditions (compare lanes 1–4; dark grey bars). β-Galactosidase activity was undetectable or extremely low in the GFP-yra1-8 or yra1-8 mutants respectively (lanes 5 and 12), consistent with the low mRNA levels. Importantly, loss of Mlp1p, Mlp2p or Rrp6p, which greatly increased the LacZ mRNA levels in these strains, led to marginal increases in enzymatic activity (lanes 6–8 and 13). Thus, only a small fraction of these transcripts was able to reach the cytoplasm, in agreement with the persistence of the poly(A)+ RNA export block in these cells (Supplementary Figure 1). The higher β-galactosidase activity in GFP-yra1-8 Δmlp1Δmlp2Δrrp6 (140% of wt, lane 11) may result from the extremely high LacZ mRNA levels present in this strain (270% of wt). One possibility is that loss of Mlp proteins increases LacZ mRNA access to the cytoplasm. Localization of LacZ transcripts by in situ hybridization To assess the cellular localization of the LacZ transcripts more directly, pLGSD5-transformed strains were induced with galactose at 37°C and examined by in situ hybridization with LacZ-specific probes (Figure 2B). In a wt strain, a weak and diffuse signal was detected in the cytoplasm but LacZ transcripts also accumulated as small nuclear foci, probably corresponding to nascent transcripts encoded by the multicopy plasmid (panel a). This distribution was specific for LacZ mRNA, as no signal was detected in noninduced cells (data not shown). Simultaneous detection of LacZ transcripts and the NPC protein Nsp1p indicated that LacZ nuclear foci were predominantly located at the nuclear periphery (Figure 2C). Consistent with the primer extension analyses, no LacZ transcripts were detected in GFP-yra1-8 (Figure 2B, panel b), but the signal was restored in the absence of Mlp1p or Mlp2p (panels c and d). In these strains, LacZ transcripts were detected primarily in the nucleus where they accumulated within a few foci. The cytoplasmic signal appeared weaker in these cells compared to wt, but slightly stronger than in GFP-yra1-8, in agreement with the appearance of a small fraction of LacZ transcripts in the cytoplasm. Finally, the LacZ signal was extremely strong and mainly nuclear in GFP-yra1-8Δmlp1Δmlp2Δrrp6, in agreement with the high mRNA levels detected in this strain (Figure 2A and B, panel e). The cytoplasmic signal appears weak in these cells, as exposure time was four times less in panel e to avoid overexposure of the nuclear signal. The same strains were examined for the distribution of endogenous SSA4 transcripts induced at 42°C (Supplementary Figure 3). In GFP-yra1-8, SSA4 mRNAs accumulated within a single nuclear focus, which persisted and became even slightly more intense in the absence of Mlp1p, Mlp2p or both (Supplementary Figure 3A). In contrast, the nuclear dot disappeared when RRP6 was deleted in these strains (Supplementary Figure 3B), indicating that the retention of heat-shock transcripts within foci depends on Rrp6p and not on Mlp proteins. These observations provide additional evidence for independent roles of Rrp6p and Mlp proteins in mRNP biogenesis. LacZ transcripts are not more stable in GFP-yra1-8 Δmlp2 than in GFP-yra1-8 To investigate how the absence of Mlp2p or Mlp1p may increase LacZ mRNA levels, mRNA turnover rates were compared in wt or GFP-yra1-8 strains in the presence or absence of Mlp2p. pLGSD5-encoded LacZ transcripts were not suitable for mRNA decay studies, since they were quasi-undetectable in GFP-yra1-8 (Figure 2A, lane 5). Thus, wt YRA1, YRA1Δmlp2, GFP-yra1-8 and GFP-yra1-8Δmlp2 strains were transformed with pGAL1-LacZ, a centromeric reporter construct containing a bona fide terminator (Chavez et al, 2000) and producing higher levels of LacZ transcripts in GFP-yra1-8 than pLGSD5 (Figure 3). After 2.5 h of galactose induction at 37°C, LacZ transcription was shut-off by shifting the cells to medium containing glucose, and mRNA decay was followed over time. In wt YRA1 and YRA1Δmlp2, LacZ transcripts accumulated to similar levels and decayed with a comparable half-life of 4.5 min (lanes 1–8). This half-life likely reflects cytoplasmic mRNA turnover, as LacZ mRNAs are efficiently assembled and exported in these two strains. In GFP-yra1-8, LacZ mRNAs accumulated to only 28% of wt and decayed more slowly, with a half-life of 13 min (lanes 9–12). Importantly, LacZ mRNA levels in GFP-yra1-8Δmlp2 accumulated to 68% of wt but decayed with a half-life of 6 min (lanes 13–16), an intermediate value between that obtained in wt and GFP-yra1-8. Notably, LacZ transcripts accumulate to higher steady-state levels in GFP-yra1-8Δmlp2 despite a shorter half-life, suggesting that loss of Mlp2p in GFP-yra1-8 does not stabilize LacZ transcripts, but results in increased mRNA synthesis. The data therefore support the view that Mlp2p downregulates mRNA synthesis in the GFP-yra1-8 mutant background. The drop in LacZ mRNA half-life, from 13 min in GFP-yra1-8 to 6 min in GFP-yra1-8Δmlp2, may reflect an increase in cytoplasmic LacZ mRNA levels, or changes in mRNP quality (Jensen et al, 2004). Figure 4.ChIP analysis of TBP binding to pGAL1-LacZ promoter. The indicated strains transformed with the pGAL1-LacZ reporter were induced with galactose for 2.5 h at 37°C prior to crosslinking with formaldehyde. Crosslinked and sonicated extracts were immunoprecipitated with antibodies against TBP, and copurifying DNA was amplified by real-time PCR with primers specific for the GAL1 promoter. The relative abundance of the GAL1 promoter segment in each immunoprecipitate was expressed as a fold increase with respect to a nontranscribed intergenic region value set to 1. TBP binding in the different strains was then expressed as a percentage of binding in wt YRA1. In wt YRA1, a 20-fold (±5) increase of TBP was measured at the GAL1 promoter in the presence of galactose. Values were derived from four independent experiments. Download figure Download PowerPoint The LacZ mRNA decay analyses as well as the two next experiments were performed in GFP-yra1-8Δmlp2 but not in GFP-yra1-8Δmlp1. Based on the similar phenotypes induced by the absence of Mlp1p or Mlp2p in GFP-yra1-8 (Figures 1 and 2), we speculate that loss of Mlp1p may have effects overlapping those induced by loss of Mlp2p in these other assays as well. Mlp2p downregulates LacZ mRNA synthesis in GFP-yra1-8 To evaluate the effect of Mlp2p on GAL1-LacZ mRNA transcription more directly, we used chromatin immunoprecipitation (ChIP) experiments to compare the association of the TATA-box-binding protein (TBP) with the GAL1 promoter in the wt YRA1, YRA1Δmlp2, GFP-yra1-8 and GFP-yra1-8Δmlp2 strains transformed with pGAL1-LacZ. Real-time PCR quantification of pGAL1-LacZ plasmid confirmed identical copy numbers of this centromeric reporter construct in the four strains (data not shown). Four independent ChIP experiments showed that the amount of TBP bound to the GAL1 promoter was more than two-fold lower in GFP-yra1-8 compared to wt (Figure 4). Importantly, loss of Mlp2p in GFP-yra1-8 increased TBP binding by at least two-fold, restoring nearly wt levels of TBP association. In contrast, loss of Mlp2p in wt YRA1 slightly reduced TBP binding (80% of wt). Additional ChIP analyses revealed comparable relative changes in the association of RNA polymerase II (Pol II) over the LacZ coding region in these four strains (data not shown). The two- to three-fold increase in TBP or RNA Pol II binding over the GAL1-LacZ transcription unit parallels the two- to three-fold increase in LacZ mRNA levels in GFP-yra1-8Δmlp2 relative to GFP-yra1-8 (Figure 3). Western blot analyses confirmed that the total levels of TBP were identical in all four strains (data not shown). These observations taken together show that Mlp2p downregulates LacZ gene transcription initiation and elongation in GFP-yra1-8 but not in the wt background. Figure 5.Mlp2p downregulates a subset of cellular transcripts in GFP-yra1-8 but not in wt YRA1. (A) The DNA microarray intensity values of the 194 transcripts decreased in GFP-yra1-8 (open triangles), and their values in GFP-yra1-8Δmlp2 (closed squares) were plotted as a function of the intensity of these 194 transcripts in GFP-yra1-8. (B) The intensity values of the same 194 selected transcripts in wt YRA1 (open diamonds) and YRA1Δmlp2 (closed circles) were plotted as a function of transcript intensity in wt YRA1. (C) Mlp2p downregulates MIG2 and ALD4 transcripts in GFP-yra1-8 but not in wt YRA1. Exponentially growing cultures of the indicated strains were shifted for 2.5 h to 37°C. Total RNA was extracted and examined by Northern blot analysis with MIG2- and ALD4-specific probes. The same blots were rehybridized with a probe specific for 18S RNA to correct for unequal loading. Download figure Download PowerPoint Mlp2p affects the levels of cellular transcripts To assess the effect of Mlp2p on gene expression in GFP-yra1-8 at a global level, DNA microarrays (Affymetrix) were used to compare mRNA levels in wt YRA1 to those in YRA1Δmlp2, GFP-yra1-8 and GFP-yra1-8Δmlp2 after a 2.5 h shift at 37°C. An initial comparison identified a set of 194 transcripts, which decreased by two-fold or more (median log ratio equal to or less than −1) in GFP-yra1-8 compared to wt YRA1 (Supplementary data and Supplementary Table I; Miamexpress accession number E-MEXP-130). Comparison of the mean intensity values revealed that most (85%) of these 194 transcripts increased in GFP-yra1-8Δmlp2 versus GFP-yra1-8, of which 58 augmented by 1.5-fold or more (dark green genes in Supplementary Table I). Thus, Mlp2p significantly downregulates at least 30% of the cellular transcripts most strongly affected in GFP-yra1-8 (Figure 5A). In contrast, the intensity values of the same set of 194 transcripts remained unchanged or became slightly lower in YRA1Δmlp2 versus wt YRA1 (Figure 5B). The 58 Mlp2p-sensitive genes in GFP-yra1-8 include low and highly expressed genes, located all over the genome and encoding proteins with various functions (Supplementary Table I and data not shown). Only three of these genes are essential and encode RNase P RNA (RPR1), or proteins involved in fatty
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