SIR2 and SIR4 interactions differ in core and extended telomeric heterochromatin in yeast

The Ku complex in silencing the cryptic mating-type loci of Saccharomyces cerevisiae

Sir1 establishes transcriptional silencing at the cryptic mating-type loci HMR and HML (HM loci) by recruiting the three other Sir proteins, Sir2, -3, and -4, that function directly in silenced chromatin. However, SIR1-independent mechanisms also contribute to recruiting the Sir2-4 proteins to the HM loci. A screen to elucidate SIR1-independent mechanisms that establish HMR silencing identified a mutation in YKU80. The role for Ku in silencing both HMR and HML was masked by SIR1. Ku's role in silencing the HM loci was distinct from its shared role with the nuclear architecture protein Esc1 in tethering the HM loci and telomeres to the nuclear periphery. The ability of high-copy SIR4 to rescue HMR silencing defects in sir1Delta cells required Ku, and chromatin immunoprecipitation (ChIP) experiments provided evidence that Ku contributed to Sir4's physical association with the HM loci in vivo. Additional ChIP experiments provided evidence that Ku functioned directly at the HM loci. Thus Ku and Sir1 had overlapping roles in silencing the HM loci.

SATB2 interacts with chromatin-remodeling molecules in differentiating cortical neurons

During our search for developmental regulators of neuronal differentiation, we identified special AT-rich sequence-binding protein (SATB)2 that is specifically expressed in the developing rat neocortex and binds to AT-rich DNA elements. Here we investigated whether the regulatory function of SATB2 involves chromatin remodeling at the AT-rich DNA site. In-vitro and in-vivo assays using a DNA affinity pre-incubation specificity test of recognition and chromatin immunoprecipitation showed that SATB2 specifically binds to histone deacetylase 1 and metastasis-associated protein 2, members of the nucleosome-remodeling and histone deacetylase complex. Double immunohistochemistry showed that, in the developing rat neocortex, SATB2 is coexpressed with both proteins. Using a cell culture model, we showed that trichostatin A treatment, which blocks the activities of histone deacetylases, reverses the AT-rich dsDNA-dependent repressor effect of SATB2. These findings suggested that the molecular regulatory function of SATB2 involves modification of the chromatin structure. Semi-quantitative chromatin immunoprecipitation analysis of cortices from SATB2 mutant and wild-type animals indicated that, in the knock-out brains, SATB2 is replaced in the chromatin-remodeling complex by AU-rich element RNA binding protein 1, another AT-rich DNA binding protein also expressed in differentiating cortical neurons. These results suggested that an altered chromatin structure, due to the presence of different AT-rich DNA binding proteins in the chromatin-remodeling complex, may contribute to the developmental abnormalities observed in the SATB2 mutant animals. These findings also raised the interesting possibility that SATB2, along with other AT-rich DNA binding proteins, is involved in mediating epigenetic influences during cortical development.

Cellular and molecular effects of nonreciprocal chromosome translocations in Saccharomyces cerevisiae

Saccharomyces cerevisiae strains harboring a nonreciprocal, bridge-induced translocation (BIT) between chromosomes VIII and XV exhibited an abnormal phenotype comprising elongated buds and multibudded, unevenly nucleated pseudohyphae. In these cells, we found evidence of molecular effects elicited by the translocation event and specific for its particular genomic location. Expression of genes flanking both translocation breakpoints increased up to five times, correlating with an increased RNA polymerase II binding to their promoters and with their histone acetylation pattern. Microarray data, CHEF, and quantitative PCR confirmed the data on the dosage of genes present on the chromosomal regions involved in the translocation, indicating that telomeric fragments were either duplicated or integrated mostly on chromosome XI. FACS analysis revealed that the majority of translocant cells were blocked in G(1) phase and a few of them in G(2). Some cells showed a posttranslational decrease of cyclin B1, in agreement with elongated buds diagnostic of a G(2)/M phase arrest. The actin1 protein was in some cases modified, possibly explaining the abnormal morphology of the cells. Together with the decrease in Rad53p and the lack of its phosphorylation, these results indicate that these cells have undergone adaptation after checkpoint-mediated G(2)/M arrest after chromosome translocation. These BIT translocants could serve as model systems to understand further the cellular and molecular effects of chromosome translocation and provide fundamental information on its etiology of neoplastic transformation in mammals.

Chromatin immunoprecipitation assays: molecular analysis of chromatin modification and gene regulation

Gene expression pattern in cancer cells differ significantly from their normal counter parts, owing to mutations in oncogenes and tumor suppressor genes, their downstream targets, or owing to increased proliferation, and altered apoptotic potential. Various microarray based techniques have been widely utilized to study the differential expression of genes in cancer in recent years. Along with this, attempts have been made to study the transcriptional regulatory mechanisms and chromatin modifications facilitating such differential gene expression. One of the widely used assays for this purpose is the chromatin immunoprecipitation (ChIP) assay, which enables the analysis of the association of regulatory molecules with specific promoters or changes in histone modifications in vivo, without overexpressing any component. This has been of immense value, because ChIP assays can provide a snapshot of the regulatory mechanisms involved in the expression of a single gene, or a variety of genes at the same time. This review article outlines the general strategies and protocols used to carry out ChIP assays to study the differential recruitment of transcription factors, based on the experience in studying E2F1 and histone modifications as well as other published protocols. In addition, the use of ChIP assays to carry out global analysis of transcription factor recruitment is also addressed.

Members of the NuRD chromatin remodeling complex interact with AUF1 in developing cortical neurons

Chromatin remodeling plays an important role in coordinating gene expression during cortical development, however the identity of molecular complexes present in differentiating cortical neurons that mediate the process remains poorly understood. The A + U-rich element-binding factor 1 (AUF1) is a known regulator of messenger RNA stability and also acts as a transcription factor upon binding to AT-rich DNA elements. Here we show that AUF1 is specifically expressed in subsets of proliferating neural precursors and differentiating postmitotic neurons of the developing cerebral cortex. Moreover, AUF1 is coexpressed with histone deacetylase 1 (HDAC1) and metastasis-associated protein 2 (MTA2), members of the nucleosome remodeling and histone deacetylase complex. AUF1 specifically and simultaneously binds to HDAC1, MTA2, and AT-rich DNA element, its gene regulatory function is modulated by the extent of histone acetylation and in animals lacking AUF1, the composition of the complex is modified. These results suggest that AUF1 is involved in integrating genetic and epigenetic signals during cortical development through recruiting HDAC1 and MTA2 to AT-rich DNA elements.

Artificial recruitment of mediator by the DNA-binding domain of Adr1 overcomes glucose repression of ADH2 expression

The transcription factor Adr1 activates numerous genes in nonfermentable carbon source metabolism. An unknown mechanism prevents Adr1 from stably binding to the promoters of these genes in glucose-grown cells. Glucose depletion leads to Snf1-dependent binding. Chromatin immunoprecipitation showed that the Adr1 DNA-binding domain could not be detected at the ADH2 promoter under conditions in which the binding of the full-length protein occurred. This suggested that an activation domain is required for stable binding, and coactivators may stabilize the interaction with the promoter. Artificial recruitment of Mediator tail subunits by fusion to the Adr1 DNA-binding domain overcame both the inhibition of promoter binding and glucose repression of ADH2 expression. In contrast, an Adr1 DNA-binding domain-Tbp fusion did not overcome glucose repression, although it was an efficient activator of ADH2 expression under derepressing conditions. When Mediator was artificially recruited, ADH2 expression was independent of SNF1, SAGA, and Swi/Snf, whereas ADH2 expression was dependent on these factors with wild-type Adr1. These results suggest that in the presence of glucose, the ADH2 promoter is accessible to Adr1 but that other interactions that occur when glucose is depleted do not take place. Artificial recruitment of Mediator appears to overcome this requirement and to allow stable binding and transcription under normally inhibitory conditions.

The silent information regulator 3 protein, SIR3p, binds to chromatin fibers and assembles a hypercondensed chromatin architecture in the presence of salt

The telomeres and mating-type loci of budding yeast adopt a condensed, heterochromatin-like state through recruitment of the silent information regulator (SIR) proteins SIR2p, SIR3p, and SIR4p. In this study we characterize the chromatin binding determinants of recombinant SIR3p and identify how SIR3p mediates chromatin fiber condensation in vitro. Purified full-length SIR3p was incubated with naked DNA, nucleosome core particles, or defined nucleosomal arrays, and the resulting complexes were analyzed by electrophoretic shift assays, sedimentation velocity, and electron microscopy. SIR3p bound avidly to all three types of templates. SIR3p loading onto its nucleosomal sites in chromatin produced thickened condensed fibers that retained a beaded morphology. At higher SIR3p concentrations, individual nucleosomal arrays formed oligomeric suprastructures bridged by SIR3p oligomers. When condensed SIR3p-bound chromatin fibers were incubated in Mg(2+), they folded and oligomerized even further to produce hypercondensed higher-order chromatin structures. Collectively, these results define how SIR3p may function as a chromatin architectural protein and provide new insight into the interplay between endogenous and protein-mediated chromatin fiber condensation pathways.

The role of Schizosaccharomyces pombe SUMO ligases in genome stability

SUMOylation is a post-translational modification that affects a large number of proteins, many of which are nuclear. While the role of SUMOylation is beginning to be elucidated, it is clear that understanding the mechanisms that regulate the process is likely to be important. Control of the levels of SUMOylation is brought about through a balance of conjugating and deconjugating activities, i.e. of SUMO (small ubiquitin-related modifier) conjugators and ligases versus SUMO proteases. Although conjugation of SUMO to proteins can occur in the absence of a SUMO ligase, it is apparent that SUMO ligases facilitate the SUMOylation of specific subsets of proteins. Two SUMO ligases in Schizosaccharomyces pombe, Pli1 and Nse2, have been identified, both of which have roles in genome stability. We report here on a comparison between the properties of the two proteins and discuss potential roles for the proteins.

Chromatin immunoprecipitation for determining the association of proteins with specific genomic sequences in vivo

Chromatin immunoprecipitation (ChIP) is a powerful and widely applied technique for detecting the association of individual proteins with specific genomic regions in vivo. Live cells are treated with formaldehyde to generate protein-protein and protein- DNA cross-links between molecules in close proximity on the chromatin template in vivo. DNA sequences that cross-link with a given protein are selectively enriched and reversal of the formaldehyde cross-link permits recovery and quantitative analysis of the immunoprecipitated DNA. As formaldehyde inactivates cellular enzymes essentially immediately upon addition to cells, ChIP provides snapshots of protein-protein and protein- DNA interactions at a particular time point, and hence is useful for kinetic analysis of events occurring on chromosomal sequences in vivo. In addition, ChIP can be combined with microarray technology to identify the location of specific proteins on a genome-wide basis. This unit describes the ChIP protocol for Saccharomyces cerevisiae; however, it is also applicable to other organisms.

Subtelomeric elements influence but do not determine silencing levels at Saccharomyces cerevisiae telomeres

In Saccharomyces cerevisiae, genes placed near telomeres are transcriptionally repressed (telomere position effect, TPE). Although telomeric DNA sequence is the same at all chromosome ends, the subtelomeric elements (STEs) and level of TPE vary from telomere to telomere. We tested whether STEs determine TPE levels. STEs contributed to TPE, as deleting the X element from the VI-R telomere modestly decreased silencing at this telomere. However, STEs were not the major determinant of TPE levels, as inserting the VI-R X element at the truncated VII-L telomere did not increase TPE. These data suggest that the TPE levels of individual telomeres are dependent on some aspect of chromosome context.

Chromatin immunoprecipitation for determining the association of proteins with specific genomic sequences in vivo

Chromatin immunoprecipitation (ChIP) is a powerful and widely applied technique for detecting the association of individual proteins with specific genomic regions in vivo. Live cells are treated with formaldehyde to generate protein-protein and protein-DNA cross-links between molecules that are in close proximity on the chromatin template in vivo. DNA sequences that cross-link with a given protein are selectively enriched, and reversal of the formaldehyde cross-linking permits recovery and quantitative analysis of the immunoprecipitated DNA. As formaldehyde inactivates cellular enzymes essentially immediately upon addition to cells, ChIP provides snapshots of protein-protein and protein-DNA interactions at a particular time point, and hence is useful for kinetic analysis of events occurring on chromosomal sequences in vivo. In addition, ChIP can be combined with microarray technology to identify the location of specific proteins on a genome-wide basis. in this unit describes the ChIP procedure for Saccharomyces cerevisiae; describes the corresponding steps for mammalian cells.

Human DDA3 is an oncoprotein down-regulated by p53 and DNA damage

Mouse DDA3 (mDDA3) is a microtubule-associated protein that promotes cell growth. mDDA3 contains an intronic p53 binding motif that is absent in human DDA3 (hDDA3), and is transcriptionally activated during DNA damage in a p53-dependent way. We now report that hDDA3 mRNA and protein levels were suppressed by p53, as well as in DNA damaged cells harboring wild type, but not mutant-p53 expression. We have located three consensus El-Deiry decamers at -1478/-1403 of the hDDA3 gene, and shown by chromatin immunoprecipitation that p53 bound to the region. Luciferase analysis showed that the hDDA3 promoter containing the putative p53 binding motif was responsible for p53-mediated repression. Expression of hDDA3 decreased the cell's requirement for serum, furthermore, overexpression of hDDA3 mRNA was detected in hepatoma tissues. Together our results show that hDDA3 is a p53- and DNA-damage down-regulated target that exhibits oncogenic characteristics.

Role of the conserved Sir3-BAH domain in nucleosome binding and silent chromatin assembly

Silent chromatin domains in Saccharomyces cerevisiae represent examples of epigenetically heritable chromatin. The formation of these domains involves the recruitment of the SIR complex, composed of Sir2, Sir3, and Sir4, followed by iterative cycles of NAD-dependent histone deacetylation and spreading of SIR complexes over adjacent chromatin domains. We show here that the conserved bromo-adjacent homology (BAH) domain of Sir3 is a nucleosome- and histone-tail-binding domain and that its binding to nucleosomes is regulated by residues in the N terminus of histone H4 and the globular domain of histone H3 on the exposed surface of the nucleosome. Furthermore, using a partially purified system containing nucleosomes, the three Sir proteins, and NAD, we observe the formation of SIR-nucleosome filaments with a diameter of less than 20 nm. Together, these observations suggest that the SIR complex associates with an extended chromatin fiber through interactions with two different regions in the nucleosome.

Long-range communication between the silencers of HMR

Gene regulation involves long-range communication between silencers, enhancers, and promoters. In Saccharomyces cerevisiae, silencers flank transcriptionally repressed genes to mediate regional silencing. Silencers recruit the Sir proteins, which then spread along chromatin to encompass the entire silenced domain. In this report we have employed a boundary trap assay, an enhancer activity assay, chromatin immunoprecipitations, and chromosome conformation capture analyses to demonstrate that the two HMR silencer elements are in close proximity and functionally communicate with one another in vivo. We further show that silencing is necessary for these long-range interactions, and we present models for Sir-mediated silencing based upon these results.

Domain organization and quaternary structure of the Saccharomyces cerevisiae silent information regulator 3 protein, Sir3p

The silent information regulator protein 3 (Sir3p) functions in the initiation, propagation, and maintenance of transcriptionally silenced chromatin in Saccharomyces cerevisiae. To better understand the physicochemical basis for its effects on chromatin architecture, recombinant full-length S. cerevisiae Sir3p has been purified to near homogeneity on the large-scale and characterized by circular dichroism, limited protease digestion, and analytical ultracentrifugation. Results indicate that the Sir3p monomer has a unique tripartite domain organization, including a nearly 300-amino-acid residue stretch of intrinsically disordered residues that lies internal to its structured N- and C-terminal regions. Sir3p self-associates extensively in moderate salt and at micromolar protein concentrations producing a broad range of oligomers that sediment from 8 to in excess of 85 S. These results provide new insight into Sir3p domain organization and quaternary structure and support a nucleosome bridging model for Sir3p-dependent regulation of chromatin architecture.

Spn1 regulates the recruitment of Spt6 and the Swi/Snf complex during transcriptional activation by RNA polymerase II

We investigated the timing of the recruitment of Spn1 and its partner, Spt6, to the CYC1 gene. Like TATA binding protein and RNA polymerase II (RNAPII), Spn1 is constitutively recruited to the CYC1 promoter, although levels of transcription from this gene, which is regulated postrecruitment of RNAPII, are low. In contrast, Spt6 appears only after growth in conditions in which the gene is highly transcribed. Spn1 recruitment is via interaction with RNAPII, since an spn1 mutant defective for interaction with RNAPII is not targeted to the promoter, and Spn1 is necessary for Spt6 recruitment. Through a targeted genetic screen, strong and specific antagonizing interactions between SPN1 and genes encoding Swi/Snf subunits were identified. Like Spt6, Swi/Snf appears at CYC1 only after activation of the gene. However, Spt6 significantly precedes Swi/Snf occupancy at the promoter. In the absence of Spn1 recruitment, Swi/Snf is constitutively found at the promoter. These observations support a model whereby Spn1 negatively regulates RNAPII transcriptional activity by inhibiting recruitment of Swi/Snf to the CYC1 promoter, and this inhibition is abrogated by the Spn1-Spt6 interaction. These findings link Spn1 functions to the transition from an inactive to an actively transcribing RNAPII complex at a postrecruitment-regulated promoter.

Conversion of a replication origin to a silencer through a pathway shared by a Forkhead transcription factor and an S phase cyclin

Silencing of the mating-type locus HMR in Saccharomyces cerevisiae requires DNA elements called silencers. To establish HMR silencing, the origin recognition complex binds the HMR-E silencer and recruits the silent information regulator (Sir)1 protein. Sir1 in turn helps establish silencing by stabilizing binding of the other Sir proteins, Sir2-4. However, silencing is semistable even in sir1Delta cells, indicating that SIR1-independent establishment mechanisms exist. Furthermore, the requirement for SIR1 in silencing a sensitized version of HMR can be bypassed by high-copy expression of FKH1 (FKH1(hc)), a conserved forkhead transcription factor, or by deletion of the S phase cyclin CLB5 (clb5Delta). FKH1(hc) caused only a modest increase in Fkh1 levels but effectively reestablished Sir2-4 chromatin at HMR as determined by Sir3-directed chromatin immunoprecipitation. In addition, FKH1(hc) prolonged the cell cycle in a manner distinct from deletion of its close paralogue FKH2, and it created a cell cycle phenotype more reminiscent to that caused by a clb5Delta. Unexpectedly, and in contrast to SIR1, both FKH1(hc) and clb5Delta established silencing at HMR using the replication origins, ARS1 or ARSH4, as complete substitutes for HMR-E (HMRDeltaE::ARS). HMRDeltaE::ARS1 was a robust origin in CLB5 cells. However, initiation by HMRDeltaE::ARS1 was reduced by clb5Delta or FKH1(hc), whereas ARS1 at its native locus was unaffected. The CLB5-sensitivity of HMRDeltaE::ARS1 did not result from formation of Sir2-4 chromatin because sir2Delta did not rescue origin firing in clb5Delta cells. These and other data supported a model in which FKH1 and CLB5 modulated Sir2-4 chromatin and late-origin firing through opposing regulation of a common pathway.

Sir2 deacetylates histone H3 lysine 56 to regulate telomeric heterochromatin structure in yeast

At telomeric heterochromatin in yeast, the Sir protein complex spreads from Rap1 sites to silence adjacent genes. This cascade is believed to occur when Sir2, an NAD(+)-dependent enzyme, deacetylates histone H3 and H4 N termini, in particular histone H4 K16, enabling more Sir protein binding. Lysine 56 of histone H3 is located at the entry-exit points of the DNA superhelix surrounding the nucleosome, where it may control DNA compaction. We have found that K56 substitutions disrupt silencing severely without decreasing Sir protein binding at the telomere. Our in vitro and in vivo data indicate that Sir2 deacetylates K56 directly in telomeric heterochromatin to compact chromatin and prevent access to RNA polymerase and ectopic bacterial dam methylase. Since the spread of Sir proteins is necessary but not sufficient for silencing, we propose that silencing occurs when Sir2 deacetylates H3 K56 to close the nucleosomal entry-exit gates, enabling compaction of heterochromatin.

Tel1p preferentially associates with short telomeres to stimulate their elongation

In many organisms, telomeric DNA consists of long tracts of short repeats. Shorter tracts are preferentially lengthened by telomerase, suggesting a conserved mechanism that recognizes and elongates short telomeres. Tel1p, an ATM family checkpoint kinase, plays an important role in telomere elongation, as cells lacking Tel1p have short telomeres and show reduced recruitment of telomerase components to telomeres. We show that Tel1p association increased as telomeres shortened in vivo in the presence or absence of telomerase and that Tel1p preferentially associated with the shortest telomeres. Tel1p association was independent of Tel1p kinase activity and enhanced by Mre11p. Tel1p overexpression simultaneously stimulated telomerase-mediated elongation and Tel1p association with all telomeres. Thus, Tel1p preferentially associates with the shortest telomeres and stimulates their elongation by telomerase.

A poised initiation complex is activated by SNF1

Snf1, the yeast AMP kinase homolog, is essential for derepression of glucose-repressed genes that are activated by Adr1. Although required for Adr1 DNA binding, the precise role of Snf1 is unknown. Deletion of histone deacetylase genes allowed constitutive promoter binding of Adr1 and Cat8, another activator of glucose-repressed genes. In repressed conditions, at the Adr1-and Cat8-dependent ADH2 promoter, partial chromatin remodeling had occurred, and the activators recruited a partial preinitiation complex that included RNA polymerase II. Transcription did not occur, however, unless Snf1 was activated, suggesting a Snf1-dependent event that occurs after RNA polymerase II recruitment. Glucose regulation persisted because shifting to low glucose increased expression. Glucose repression could be completely relieved by combining the three elements of 1) chromatin perturbation by mutation of histone deacetylases, 2) activation of Snf1, and 3) the addition of an Adr1 mutant that by itself confers only weak constitutive activity.

Genome-wide, as opposed to local, antisilencing is mediated redundantly by the euchromatic factors Set1 and H2A.Z

In Saccharomyces cerevisiae, several nonessential mechanisms including histone variant H2A.Z deposition and transcription-associated histone H3 methylation antagonize the local spread of Sir-dependent silent chromatin into adjacent euchromatic regions. However, it is unclear how and where these factors cooperate. To probe this question, we performed systematic genetic array screens for gene deletions that cause a synthetic growth defect in an htz1Delta mutant but not in an htz1Delta sir3Delta double mutant. Of the four genes identified, three, SET1, SWD1, and SWD3, encode components of the Set1 complex, which catalyzes the methylation of histone H3 on lysine 4 (H3-K4), a highly conserved modification that occurs in the coding sequences of transcribed genes. Using microarray-based transcriptional profiling, we find that H2A.Z and Set1 cooperate to prevent Sir-dependent repression of a large number of genes located across the genome, rather than the local effects reported previously for the individual mechanisms. This global, redundant function appears to be direct: using a DamID chromatin profiling method, we demonstrate ectopic association of Sir3 and Sir4 in htz1Delta set1Delta mutants at loci distant from silent chromatin domains. Antisilencing mechanisms may therefore cooperate to play a considerably broader role in regulating genome-wide transcription than previously thought.

MSN2 and MSN4 link calorie restriction and TOR to sirtuin-mediated lifespan extension in Saccharomyces cerevisiae

Calorie restriction (CR) robustly extends the lifespan of numerous species. In the yeast Saccharomyces cerevisiae, CR has been proposed to extend lifespan by boosting the activity of sirtuin deacetylases, thereby suppressing the formation of toxic repetitive ribosomal DNA (rDNA) circles. An alternative theory is that CR works by suppressing the TOR (target of rapamycin) signaling pathway, which extends lifespan via mechanisms that are unknown but thought to be independent of sirtuins. Here we show that TOR inhibition extends lifespan by the same mechanism as CR: by increasing Sir2p activity and stabilizing the rDNA locus. Further, we show that rDNA stabilization and lifespan extension by both CR and TOR signaling is due to the relocalization of the transcription factors Msn2p and Msn4p from the cytoplasm to the nucleus, where they increase expression of the nicotinamidase gene PNC1. These findings suggest that TOR and sirtuins may be part of the same longevity pathway in higher organisms, and that they may promote genomic stability during aging.

Budding yeast with human telomeres: a puzzling structure

Telomeres share some common features among eukaryotes, with few exceptions such as the fruit fly Drosophila that uses transposons as telomeres, they consist of G-rich repetitive DNA that is elongated by telomerase and/or alternative pathways depending on recombination. Telomere structure comprises both cis-acting satellite DNA (telomeric DNA) and proteins that interact directly and/or indirectly with the underlying DNA. Telomeric DNAs are surprisingly conserved among the vertebrates and very similar in most eukaryotes, but present some differences in yeast such as Saccharomyces cerevisiae. The telomeric proteins are more variable although the basic mechanisms which control telomere lengthening and capping are very similar, in fact orthologues of the yeast telomeric proteins, which have been studied first, have been identified in other organisms. Here we describe the structure of human telomeres in budding yeast as compared to canonical yeast and mammalian telomeres taking into consideration the more recent findings highlighting the mechanisms that are responsible for chromosome end protection and lengthening, and the role of chromatin organization in telomere function. This yeast represents a model for the study of mammalian telomeres that could be reconstituted step-by-step in all their components, moreover it could be useful for the assembly of mammalian artificial chromosome.

Functions of site-specific histone acetylation and deacetylation

Histone acetylation regulates many cellular processes, and specific acetylation marks, either singly or in combination, produce distinct outcomes. For example, the acetylation pattern on newly synthesized histones is important for their assembly into nucleosomes by histone chaperones. Additionally, the degree of chromatin compaction and folding may be regulated by acetylation of histone H4 at lysine 16. Histone acetylation also regulates the formation of heterochromatin; deacetylation of H4 lysine 16 is important for spreading of heterochromatin components, whereas acetylation of this site serves as a barrier to this spreading. Finally, histone acetylation is critical for gene transcription, but recent results suggest that deacetylation of certain sites also plays an important role. There are many histone acetyltransferases (HATs) and deacetylases, with differing preferences for the various histone proteins and for specific sites on individual histones. Determining how these enzymes create distinct acetylation patterns and regulate the functional outcome is an important challenge.

Exploring Novel Function of Yeast Ssa1/2p by Quantitative Profiling Proteomics Using NanoESI-LC−MS/MS

In the present study, we profiled proteins in ssa1/2 mutant and wild-type using one-dimensional gel electrophoresis coupled with liquid chromatography and mass spectrometry to reveal a total of 322 proteins. Sixty and 84 nonredundant proteins were detected in ssa1/2 and wild-type, respectively, whereas 178 were common. A quantitative profiling proteomic approach using a modified N-terminal isotope tagging method was undertaken to determine quantitative changes in proteins between mutant and wild-type. Out of 210 identified proteins selected for quantification, 103 propionylated proteins were obtained. Eight only D0-propionylated protein (wild-type) and 4 only D5-propionylated proteins (ssa1/2) were detected; 90 proteins were overlapped in the ssa1/2 mutant and wild-type. In the ssa1/2 mutant, 28 proteins were up-regulated and 26 were down-regulated. The expression levels of the rest of 49 proteins were not changed compared with the wild-type. Furthermore, non-correlation between mRNA and protein expressions was found. Among up-regulated proteins, 19 proteins involved in protein synthesis, chromatin condensation, and silencing showed unchanged mRNA expression levels. Among down-regulated proteins, 21 proteins consisting mainly of transcription factors showed unchanged mRNA expressions. Surprisingly, several proteins involved in protein synthesis were also found among the down-regulated proteins. These results suggested that the proteins showing changed protein expressions and unchanged mRNA expressions were affected by the deletion of SSA1 and SSA2 genes at translational efficiency, mRNA degradation, or protein degradation. Moreover, we found the proteins related to chromosomal control were up-regulated in ssa1/2 mutant, a novel finding of this study, suggesting that the Ssa1/2p might contribute to chromosomal control.

Telomeric position effect: from the yeast paradigm to human pathologies?

Alteration of the epigenome is associated with a wide range of human diseases. Therefore, deciphering the pathways that regulate the epigenetic modulation of gene expression is a major milestone for the understanding of diverse biological mechanisms and subsequently human pathologies. Although often evoked, little is known on the implication of telomeric position effect, a silencing mechanism combining telomere architecture and classical heterochromatin features, in human cells. Nevertheless, this particular silencing mechanism has been investigated in different organisms and several ingredients are likely conserved during evolution. Subtelomeres are highly dynamic regions near the end of the chromosomes that are prone to recombination and may buffer or facilitate the spreading of silencing that emanates from the telomere. Therefore, the composition and integrity of these regions also concur to the propensity of telomeres to regulate the expression, replication and recombination of adjacent regions. Here we describe the similarities and disparities that exist among the different species at chromosome ends with regard to telomeric silencing regulation with a special accent on its implication in numerous human pathologies.

Redundancy of chromatin remodeling pathways for the induction of the yeast PHO5 promoter in vivo

Induction of the yeast PHO5 and PHO8 genes leads to a prominent chromatin transition at their promoter regions as a prerequisite for transcription activation. Although induction of PHO8 is strictly dependent on Snf2 and Gcn5, there is no chromatin remodeler identified so far that would be essential for the opening of PHO5 promoter chromatin. Nonetheless, the nonessential but significant involvement of cofactors can be identified if the chromatin opening kinetics are delayed in the respective mutants. Using this approach, we have tested individually all 15 viable Snf2 type ATPase deletion mutants for their effect on PHO5 promoter induction and opening. Only the absence of Snf2 and Ino80 showed a strong delay in chromatin remodeling kinetics. The snf2 ino80 double mutation had a synthetic kinetic effect but eventually still allowed strong PHO5 induction. The same was true for the snf2 gcn5 and ino80 gcn5 double mutants. This strongly suggests a complex network of redundant and mutually independent parallel pathways that lead to the remodeling of the PHO5 promoter. Further, chromatin remodeling kinetics at a transcriptionally inactive TATA box-mutated PHO5 promoter were affected neither under wild type conditions nor in the absence of Snf2 or Gcn5. This demonstrates the complete independence of promoter chromatin opening from downstream PHO5 transcription processes. Finally, the histone variant Htz1 has no prominent role for the kinetics of PHO5 promoter chromatin remodeling.

Infrequently transcribed long genes depend on the Set2/Rpd3S pathway for accurate transcription

The presence of Set2-mediated methylation of H3K36 (K36me) correlates with transcription frequency throughout the yeast genome. K36me targets the Rpd3S complex to deacetylate transcribed regions and suppress cryptic transcription initiation at certain genes. Here, using a genome-wide approach, we report that the Set2-Rpd3S pathway is generally required for controlling acetylation at coding regions. When using acetylation as a functional readout for this pathway, we discovered that longer genes and, surprisingly, genes transcribed at lower frequency exhibit a stronger dependency. Moreover, a systematic screen using high-resolution tiling microarrays allowed us to identify a group of genes that rely on Set2-Rpd3S to suppress spurious transcripts. Interestingly, most of these genes are within the group that depend on the same pathway to maintain a hypoacetylated state at coding regions. These data highlight the importance of using the functional readout of histone codes to define the roles of specific pathways.

Dal81 enhances Stp1- and Stp2-dependent transcription necessitating negative modulation by inner nuclear membrane protein Asi1 in Saccharomyces cerevisiae

The yeast transcription factors Stp1 and Stp2 are synthesized as latent cytoplasmic precursors. In response to extracellular amino acids, the plasma membrane SPS sensor endoproteolytically excises the N-terminal domains that mediate cytoplasmic retention, enabling the processed forms to efficiently enter the nucleus and induce gene expression. Cytoplasmic retention is not absolute, low levels of full-length Stp1 and Stp2 "leak" into the nucleus, and the concerted action of inner nuclear membrane proteins Asi1, Asi2, and Asi3 restricts their promoter access. In cells lacking Asi function, the precursor forms bind promoters and constitutively induce gene expression. To understand the requirement of Asi-dependent repression, spontaneous mutations in Required for Latent Stp1/2-mediated transcription (RLS) genes that abolish the constitutive expression of SPS sensor-regulated genes in an asi1Delta strain were selected. A single gene, allelic with DAL81, was identified. We show that Dal81 indiscriminately amplifies the transactivation potential of both full-length and processed Stp1 and Stp2 by facilitating promoter binding. In dal81Delta mutants, the repressing activity of the Asi proteins is dispensable, demonstrating that without amplification, the levels of full-length Stp1 and Stp2 that escape cytoplasmic retention are insufficient to activate transcription. Conversely, the high levels of processed Stp1 and Stp2 that accumulate in the nucleus of induced cells activate transcription in the absence of Dal81.

Genome-wide analysis of chromatin status using tiling microarrays

The eukaryotic genome is packaged into chromatin, and chromatin modification and remodeling play an important role in transcriptional regulation, DNA replication, recombination and repair. Recent findings have shown that various post-translational histone modifications cooperate to recruit different effector proteins that bring about mobilization of the nucleosomes and cause distinct downstream consequences. The combination of chromatin immunoprecipitation (ChIP) using antibodies directed against the core histones or specific histone modifications, with high-resolution tiling microarray analysis allows the examination of nucleosome occupancy and histone modification status genome-wide. Comparing genome-wide chromatin status with global gene expression patterns can reveal causal connections between specific patterns of histone modifications and the resulting gene expression. Here, we describe current methods based on recent advances in microarray technology to conduct such studies.

Isolation and characterization of a GCN5-interacting protein from Arabidopsis thaliana

An Arabidopsis protein, AtEML, was isolated based on its interaction with the histone acetyltransferase AtGCN5 in a yeast two-hybrid screen. RNA blot and RT-PCR analysis showed that AtEML is expressed in flowers, leaves, stems and siliques. The promoter region of AtEML has several cis-acting elements associated with response to biotic and abiotic stress conditions, and the accumulation of the AtEML transcript was found to be regulated by cold and salt treatments. In vitro and in vivo protein-protein interaction assays indicated that AtEML interacts with AtGCN5 through the N-terminal region. Furthermore, AtEML was shown to activate expression of the lacZ reporter gene in yeast through recruitment of AtGCN5. Such recruitment was accompanied by an increase in histone H3 acetylation at the promoter driving lacZ expression, as determined by chromatin immunoprecipitation. A higher level of AtEML gene expression was detected in the Arabidopsis gcn5 knockout mutant as compared to wild type Arabidopsis, indicating that AtEML expression is regulated by AtGCN5. These results suggest that AtEML may be a transcription factor that co-ordinates the expression of target stress regulated genes through involvement in recruiting AtGCN5 to their promoters.

The epigenetic regulation of mammalian telomeres

Increasing evidence indicates that chromatin modifications are important regulators of mammalian telomeres. Telomeres provide well studied paradigms of heterochromatin formation in yeast and flies, and recent studies have shown that mammalian telomeres and subtelomeric regions are also enriched in epigenetic marks that are characteristic of heterochromatin. Furthermore, the abrogation of master epigenetic regulators, such as histone methyltransferases and DNA methyltransferases, correlates with loss of telomere-length control, and telomere shortening to a critical length affects the epigenetic status of telomeres and subtelomeres. These links between epigenetic status and telomere-length regulation provide important new avenues for understanding processes such as cancer development and ageing, which are characterized by telomere-length defects.

Spreading of silent chromatin: inaction at a distance

One of the oldest unsolved problems in genetics is the observation that gene silencing can 'spread' along a chromosome. Although spreading has been widely perceived as a process of long-range assembly of heterochromatin proteins, such 'oozing' might not apply in most cases. Rather, long-range silencing seems to be a dynamic process, involving local diffusion of histone-modifying enzymes from source binding sites to low-affinity sites nearby. Discontinuous silencing might reflect looping interactions, whereas the spreading of continuous silencing might be driven by the processive movement of RNA or DNA polymerases. We review the evidence for the spreading of silencing in many contexts and organisms and conclude that multiple mechanisms have evolved that silence genes at a distance.

Smc5/6 is required for repair at collapsed replication forks

In eukaryotes, three pairs of structural-maintenance-of-chromosome (SMC) proteins are found in conserved multisubunit protein complexes required for chromosomal organization. Cohesin, the Smc1/3 complex, mediates sister chromatid cohesion while two condensin complexes containing Smc2/4 facilitate chromosome condensation. Smc5/6 scaffolds an essential complex required for homologous recombination repair. We have examined the response of smc6 mutants to the inhibition of DNA replication. We define homologous recombination-dependent and -independent functions for Smc6 during replication inhibition and provide evidence for a Rad60-independent function within S phase, in addition to a Rad60-dependent function following S phase. Both genetic and physical data show that when forks collapse (i.e., are not stabilized by the Cds1Chk2 checkpoint), Smc6 is required for the effective repair of resulting lesions but not for the recruitment of recombination proteins. We further demonstrate that when the Rad60-dependent, post-S-phase Smc6 function is compromised, the resulting recombination-dependent DNA intermediates that accumulate following release from replication arrest are not recognized by the G2/M checkpoint.

The rad51-K191R ATPase-defective mutant is impaired for presynaptic filament formation

The nucleoprotein filament formed by Rad51 polymerization on single-stranded DNA is essential for homologous pairing and strand exchange. ATP binding is required for Rad51 nucleoprotein filament formation and strand exchange, but ATP hydrolysis is not required for these functions in vitro. Previous studies have shown that a yeast strain expressing the rad51-K191R allele is sensitive to ionizing radiation, suggesting an important role for ATP hydrolysis in vivo. The recruitment of Rad51-K191R to double-strand breaks is defective in vivo, and this phenotype can be suppressed by elimination of the Srs2 helicase, an antagonist of Rad51 filament formation. The phenotype of the rad51-K191R strain is also suppressed by overexpression of Rad54. In vitro, the Rad51-K191R protein exhibits a slight decrease in binding to DNA, consistent with the defect in presynaptic filament formation. However, the rad51-K191R mutation is dominant in heterozygous diploids, indicating that the defect is not due simply to reduced affinity for DNA. We suggest the Rad51-K191R protein either forms an altered filament or is defective in turnover, resulting in a reduced pool of free protein available for DNA binding.

The histone deubiquitinating enzyme Ubp10 is involved in rDNA locus control in Saccharomyces cerevisiae by affecting Sir2p association

Histone modifications influence chromatin structure and thus regulate the accessibility of DNA to replication, recombination, repair, and transcription. We show here that the histone deubiquitinating enzyme Ubp10 contributes to the formation/maintenance of silenced chromatin at the rDNA by affecting Sir2p association.

Modulation of Rad26- and Rpb9-mediated DNA repair by different promoter elements

Rad26, the yeast homologue of human Cockayne syndrome group B protein, and Rpb9, a nonessential subunit of RNA polymerase II, have been shown to mediate two subpathways of transcription-coupled DNA repair in yeast. Here we show that Rad26- and Rpb9-mediated repair in the yeast GAL1 gene is differently modulated by different promoter elements. The initiation site and efficiency of Rad26-mediated repair in the transcribed strand are determined by the upstream activating sequence (UAS) but not by the TATA or local sequences. The role of UAS in determining the Rad26-mediated repair is not through loading of RNA polymerase II or the transcriptional regulatory complex SAGA. However, both the UAS and the TATA sequences are essential for confining Rad26-mediated repair to the transcribed strand. Mutation of the TATA sequence, which greatly reduces transcription, or deletion of the TATA or mutation of the UAS, which completely abolishes transcription, causes Rad26-mediated repair to occur in both strands. Rpb9-mediated repair only occurs in the transcribed strand and is efficient only in the presence of both TATA and UAS sequences. Also, the efficiency of Rpb9-mediated repair is dependent on the SAGA complex. Our results suggest that Rad26-mediated repair can be either transcription-coupled, provided that a substantial level of transcription is present, or transcription-independent, if the transcription is too low or absent. In contrast, Rpb9-mediated repair is strictly transcription-coupled and is efficient only when the transcription level is high.

HPV-18 E7 conjugates to c-Myc and mediates its transcriptional activity

Several reports in the literature have indicated that the E6 not only elevates the level of c-Myc level but that the protein also associates with the Myc complex and activates Myc-responsive genes. There would seem to be a mechanism by which this oncogene can modulate cell proliferation and differentiation. Furthermore, an increase in c-Myc levels has also observed during ectopic expression of HPV E7 alone. Using the yeast two-hybrid system, we further found that the c-Myc interacts and forms a specific complex with HPV-16E7. In this study, we have demonstrated that E7 does indeed interact with c-Myc and a sequential deletion analysis of E7 maps the c-Myc interaction site to the carboxyl-terminal region. We determined two HPV-18 E7 binding sites on c-Myc involving the amino acids regions 1-100 and 367-439. The interaction of the high-risk type HPV E7 with c-Myc can augment c-Myc transactivation activity but this does not occur with low-risk type HPV E7. Deletion within the Cys-X-X-Cys repeat motif at the C-terminus of HPV-18 E7 leads to a lost of association with c-Myc and also abolishes the enhancement of c-Myc's transactivation activity. Furthermore, the interaction of HPV-18 E7 with c-Myc functionally promotes c-Myc's DNA-binding ability. Using the hTERT promoter as a model, enhanced c-Myc binding ability to the hTERT promoter as measured by immunoprecipitation assay was observed and occurred in an E7 dose-dependent manner. Taken together, these results provide significant new insights into the association of c-Myc with E7 and the possible involvement of high-risk E7 in oncogenesis.

SIR2 modifies histone H4-K16 acetylation and affects superhelicity in the ARS region of plasmid chromatin in Saccharomyces cerevisiae

The null mutation of the SIR2 gene in Saccharomyces cerevisiae has been associated with a series of different phenotypes including loss of transcriptional silencing, genome instability and replicative aging. Thus, the SIR2 gene product is an important constituent of the yeast cell. SIR2 orthologues and paralogues have been discovered in organisms ranging from bacteria to man, underscoring the pivotal role of this protein. Here we report that a plasmid introduced into sir2Delta cells accumulates more negative supercoils compared to the same plasmid introduced into wild-type (WT) cells. This effect appears to be directly related to SIR2 expression as shown by the reduction of negative supercoiling when SIR2 is overexpressed, and does not depend on the number or positioning of nucleosomes on plasmids. Our results indicate that this new phenotype is due to the lack of Sir2p histone deacetylase activity in the sir2Delta strain, because only the H4-K16 residue of the histone octamer undergoes an alteration of its acetylation state. A model proposing interference with the replication machinery is discussed.

The transcriptional activity of RNA polymerase I is a key determinant for the level of all ribosome components

Regulation of ribosome biogenesis is a key element of cell biology, not only because ribosomes are directly required for growth, but also because ribosome production monopolizes nearly 80% of the global transcriptional activity in rapidly growing yeast cells. These observations underscore the need for a tight regulation of ribosome synthesis in response to environmental conditions. In eukaryotic cells, ribosome synthesis involves the activities of the three nuclear RNA polymerases (Pol). Although postulated, there is no clear evidence indicating whether the maintenance of an equimolar supply of ribosomal components reflects communication between the nuclear transcriptional machineries. Here, by constructing a yeast strain expressing a Pol I that remains constitutively competent for the initiation of transcription under stress conditions, we demonstrate that derepression of Pol I transcription leads to a derepression of Pol II transcription that is restricted to the genes encoding ribosomal proteins. Furthermore, we show that the level of 5S rRNA, synthesized by Pol III, is deregulated concomitantly with Pol I transcription. Altogether, these results indicate that a partial derepression of Pol I activity drives an abnormal accumulation of all ribosomal components, highlighting the critical role of the regulation of Pol I activity within the control of ribosome biogenesis.

The spatial arrangement of ORC binding modules determines the functionality of replication origins in budding yeast

In the quest to define autonomously replicating sequences (ARSs) in eukaryotic cells, an ARS consensus sequence (ACS) has emerged for budding yeast. This ACS is recognized by the replication initiator, the origin recognition complex (ORC). However, not every match to the ACS constitutes a replication origin. Here, we investigated the requirements for ORC binding to origins that carry multiple, redundant ACSs, such as ARS603. Previous studies raised the possibility that these ACSs function as individual ORC binding sites. Detailed mutational analysis of the two ACSs in ARS603 revealed that they function in concert and give rise to an initiation pattern compatible with a single bipartite ORC binding site. Consistent with this notion, deletion of one base pair between the ACS matches abolished ORC binding at ARS603. Importantly, loss of ORC binding in vitro correlated with the loss of ARS activity in vivo. Our results argue that replication origins in yeast are in general comprised of bipartite ORC binding sites that cannot function in random alignment but must conform to a configuration that permits ORC binding. These requirements help to explain why only a limited number of ACS matches in the yeast genome qualify as ORC binding sites.

A non-universal transcription factor? The Leishmania tarentolae TATA box-binding protein LtTBP associates with a subset of promoters

In kinetoplastids a 39-nucleotide spliced leader RNA is trans-spliced to the 5' end of nuclear mRNAs before they can be translated, thus the spliced leader is central to gene expression in kinetoplastid biology. The spliced leader RNA genes in Leishmania tarentolae contain promoters with important sites at approximately -60 and -30. A complex forms specifically on the -60 element as shown by electrophoretic mobility shift. The -60 shift complex has an estimated mass of 159 kDa. An L. tarentolae homologue of TATA-binding protein, LtTBP, co-fractionates with the -60 shift complex. Inclusion of anti-LtTBP antiserum in the shift assay disrupts the shift, indicating that LtTBP is a component of the complex that interacts with the TATA-less -60 element of the spliced leader RNA gene promoter. Both LtTBP and LtSNAP50 are found near the spliced leader RNA gene promoter and the promoters important for tRNAAla and/or U2 snRNA gene transcription, as demonstrated by chromatin immunoprecipitation. The LtTBP appears to interact with a subset of promoters in kinetoplastids with an affinity for short transcription units.

The nuclear GTPase Gsp1p can affect proper telomeric function through the Sir4 protein inSaccharomyces cerevisiae

The small Ras-like GTPase Ran/Gsp1p is a highly conserved nuclear protein required for the nucleocytoplasmic trafficking of macromolecules. Recent findings suggest that the Ran/Gsp1p pathway may have additional roles in several aspects of nuclear structure and function, including spindle assembly, nuclear envelope formation, nuclear pore complex assembly and RNA processing. Here, we provide evidence that Gsp1p can regulate telomeric function in Saccharomyces cerevisiae. We show that overexpression of PRP20, encoding the Gsp1p GDP/GTP nuclear exchange factor, specifically weakens telomeric silencing without detectably affecting nucleocytoplasmic transport. In addition to this silencing defect, we show that Rap1p and Sir3p delocalize from their normal telomeric foci. Interestingly, Gsp1p was found to interact genetically and physically with the telomeric component Sir4p. Taken together, these results suggest that the GSP1 pathway could regulate proper telomeric function in yeast through Sir4p.

Sir3 C-terminal domain involvement in the initiation and spreading of heterochromatin

Heterochromatin is nucleated at a specific site and subsequently spreads into distal sequences through multiple interactions between modified histones and nonhistone proteins. In the yeast Saccharomyces cerevisiae, these nonhistone proteins include Sir2, Sir3, and Sir4. We have previously shown that loss of the C-terminal Rap1 domain containing Sir3 and Sir4 association sites can be overcome by tethering a 144-amino-acid C-terminal domain (CTD) of Sir3 adjacent to the telomere. Here, we explore the substructure and functions of the CTD. We demonstrate that the CTD is the minimum domain for Sir3 homodimerization, a function that is conserved in related yeasts. However, CTD heterodimers associate at only low efficiencies and correspondingly have low levels of tethered silencing, consistent with an essential role for dimerization in tethered silencing. Six missense alleles were generated, with ctd-Y964A producing the most extreme phenotypes when tethered to the LexA binding sites. Although ctd-Y964A is capable of dimerization, telomere silencing is abrogated, indicating that the CTD serves a second essential function in silencing. Chromatin immunoprecipitation analyses of wild-type and ctd-Y964A mutant cells indicate an association of the CTD with the deacetylated histone tails of H3 and H4 that is necessary for the recruitment of Sir3. The efficiency of spreading depends upon the apparent stoichiometry and stability during the initiation event. The predicted Cdc6 domain III winged-helix structure may well be responsible for dimerization.

X-ray crystal structure of MENT: evidence for functional loop-sheet polymers in chromatin condensation

Most serpins are associated with protease inhibition, and their ability to form loop-sheet polymers is linked to conformational disease and the human serpinopathies. Here we describe the structural and functional dissection of how a unique serpin, the non-histone architectural protein, MENT (Myeloid and Erythroid Nuclear Termination stage-specific protein), participates in DNA and chromatin condensation. Our data suggest that MENT contains at least two distinct DNA-binding sites, consistent with its simultaneous binding to the two closely juxtaposed linker DNA segments on a nucleosome. Remarkably, our studies suggest that the reactive centre loop, a region of the MENT molecule essential for chromatin bridging in vivo and in vitro, is able to mediate formation of a loop-sheet oligomer. These data provide mechanistic insight into chromatin compaction by a non-histone architectural protein and suggest how the structural plasticity of serpins has adapted to mediate physiological, rather than pathogenic, loop-sheet linkages.

Sir2 represses endogenous polymerase II transcription units in the ribosomal DNA nontranscribed spacer

Silencing at the rDNA, HM loci, and telomeres in Saccharomyces cerevisiae requires histone-modifying enzymes to create chromatin domains that are refractory to recombination and RNA polymerase II transcription machineries. To explore how the silencing factor Sir2 regulates the composition and function of chromatin at the rDNA, the association of histones and RNA polymerase II with the rDNA was measured by chromatin immunoprecipitation. We found that Sir2 regulates not only the levels of K4-methylated histone H3 at the rDNA but also the levels of total histone H3 and RNA polymerase II. Furthermore, our results demonstrate that the ability of Sir2 to limit methylated histones at the rDNA requires its deacetylase activity. In sir2Delta cells, high levels of K4-trimethylated H3 at the rDNA nontranscribed spacer are associated with the expression of transcription units in the nontranscribed spacer by RNA polymerase II and with previously undetected alterations in chromatin structure. Together, these data suggest a model where the deacetylase activity of Sir2 prevents euchromatinization of the rDNA and silences naturally occurring intergenic transcription units whose expression has been associated with disruption of cohesion complexes and repeat amplification at the rDNA.

Expression of the Candida albicans morphogenesis regulator gene CZF1 and its regulation by Efg1p and Czf1p

The ability of Candida albicans to transit between different cellular morphologies is believed to be important for virulence. Morphological transitions occur in response to a variety of environmental signals. One such signal is encountered when cells are grown in a semisolid matrix. An important regulator of cellular morphology is the putative transcription factor CZF1. Here we demonstrate that transcription of CZF1 is responsive to growth parameters such as the temperature, carbon source, growth phase of cells, and the physical environment. In wild-type cells, a CZF1 transcript of about 4 kb was expressed when cells were grown embedded in semisolid agar medium, as well as in late exponential phase when cells were grown in liquid medium. Deletion of EFG1, a key regulator of morphogenesis, abolished CZF1 expression. Overexpression of CZF1 revealed that this gene also autoregulates its expression. Efg1p and Czf1p were shown by chromatin immunoprecipitation to act by binding to the promoter of CZF1. The coupling of environmental cues to the expression of a morphogenetic transcription factor may allow C. albicans to coordinate morphogenesis in response to specific conditions encountered in the human host.

Asi1 is an inner nuclear membrane protein that restricts promoter access of two latent transcription factors

Stp1 and Stp2 are homologous transcription factors in yeast that are synthesized as latent cytoplasmic precursors with NH₂-terminal regulatory domains. In response to extracellular amino acids, the plasma membrane–localized Ssy1–Ptr3–Ssy5 (SPS) sensor endoproteolytically processes Stp1 and Stp2, an event that releases the regulatory domains. The processed forms of Stp1 and Stp2 efficiently target to the nucleus and bind promoters of amino acid permease genes. In this study, we report that Asi1 is an integral component of the inner nuclear membrane that maintains the latent characteristics of unprocessed Stp1 and Stp2. In cells lacking Asi1, full-length forms of Stp1 and Stp2 constitutively induce SPS sensor–regulated genes. The regulatory domains of Stp1 and Stp2 contain a conserved motif that confers Asi1-mediated control when fused to an unrelated DNA-binding protein. Our results indicate that latent precursor forms of Stp1 and Stp2 inefficiently enter the nucleus; however, once there, Asi1 restricts them from binding SPS sensor–regulated promoters. These findings reveal an unanticipated role of inner nuclear membrane proteins in controlling gene expression.