Constitutive mutants for orotidine 5 phosphate decarboxylase and dihydroorotic acid dehydrogenase in Saccharomyces cerevisiae

A mutant yeast constitutive for synthesis of both dihydroorotic acid dehydrogenase and orotidine 5' phosphate decarboxylase has been isolated. This phenotype is due to a single gene unlinked to any of the five genes of the pyrimidine pathway. This gene, called ppr1, induces the unlinked genes ural and ura3. Non-chromosomal cloned ura3 is also under the control of ppr1.

Retinoic acid induces TGFbeta-dependent autocrine fibroblast growth

To evaluate the role of murine TFIID subunit TAF4 in activation of cellular genes by all-trans retinoic acid (T-RA), we have characterized the T-RA response of taf4(lox/-) and taf4(-/-) embryonic fibroblasts. T-RA regulates almost 1000 genes in taf4(lox/-) cells, but less than 300 in taf4(-/-) cells showing that TAF4 is required for T-RA regulation of most, but not all cellular genes. We further show that T-RA-treated taf4(lox/-) cells exhibit transforming growth factor (TGF)beta-dependent autocrine growth and identify a set of genes regulated by loss of TAF4 and by T-RA corresponding to key mediators of the TGFbeta signalling pathway. T-RA rapidly and potently induces expression of connective tissue growth factor (CTGF) via a conserved DR2 type response element in its proximal promoter leading to serum-free autocrine growth. These results highlight the role of TAF4 as a cofactor in the cellular response to T-RA and identify the genetic programme of a novel cross talk between the T-RA and TGFbeta pathways that leads to deregulated cell growth.

NSD3, a new SET domain-containing gene, maps to 8p12 and is amplified in human breast cancer cell lines

We describe the isolation and characterization of NSD3, the third member of a gene family including Nsd1 and NSD2. Murine Nsd1 was isolated in a search for proteins that interact with the ligand-binding domain of retinoic acid receptor alpha. NSD2 (also known as WHSC1 and MMSET) is located in the Wolf-Hirschhorn syndrome (WHS) critical region on 4p16.3 and is involved in multiple myeloma with t(4;14) translocations. The proteins Nsd1, NSD2, and NSD3 are highly similar within a block of about 700 amino acids. This block contains several conserved domains, such as the SET domain and the PHD finger, present in proteins involved in development and/or chromatin reorganization. The NSD3 gene consists of an 8.5-kb transcript composed of 23 coding exons and spans >90 kb of genomic DNA. NSD3 maps to chromosome band 8p12 and is amplified in several tumor cell lines and primary breast carcinomas.

Common properties of nuclear body protein SP100 and TIF1alpha chromatin factor: role of SUMO modification

The SP100 protein, together with PML, represents a major constituent of the PML-SP100 nuclear bodies (NBs). The function of these ubiquitous subnuclear structures, whose integrity is compromised in pathological situations such as acute promyelocytic leukemia (APL) or DNA virus infection, remains poorly understood. There is little evidence for the occurrence of actual physiological processes within NBs. The two NB proteins PML and SP100 are covalently modified by the ubiquitin-related SUMO-1 modifier, and recent work indicates that this modification is critical for the regulation of NB dynamics. In exploring the functional relationships between NBs and chromatin, we have shown previously that SP100 interacts with members of the HP1 family of nonhistone chromosomal proteins and that a variant SP100 cDNA encodes a high-mobility group (HMG1/2) protein. Here we report the isolation of a further cDNA, encoding the SP100C protein, that contains the PHD-bromodomain motif characteristic of chromatin proteins. We further show that TIF1alpha, a chromatin-associated factor with homology to both PML and SP100C, is also modified by SUMO-1. Finally, in vitro experiments indicate that SUMO modification of SP100 enhances the stability of SP100-HP1 complexes. Taken together, our results suggest an association of SP100 and its variants with the chromatin compartment and, further, indicate that SUMO modification may play a regulatory role in the functional interplay between the nuclear bodies and chromatin.

Heterochromatin formation in mammalian cells: interaction between histones and HP1 proteins

Members of the heterochromatin protein 1 (HP1) family are silencing nonhistone proteins. Here, we show that in P19 embryonal carcinoma (EC) nuclei, HP1 alpha, beta, and gamma form homo- and heteromers associated with nucleosomal core histones. In vitro, all three HP1s bind to tailed and tailless nucleosomes and specifically interact with the histone-fold of histone H3. Furthermore, HP1alpha interacts with the linker histone H1. HP1alpha binds to H3 and H1 through its chromodomain (CD) and hinge region, respectively. Interestingly, the Polycomb (Pc1/M33) CD also interacts with H3, and HP1alpha and Pc1/M33 binding to H3 is severely impaired by CD mutations known to abrogate HP1 and Polycomb silencing in Drosophila. These results define a novel function for the conserved CD and suggest that HP1 self-association and histone binding may play a crucial role in HP1-mediated heterochromatin assembly.

Bonus, a Drosophila homolog of TIF1 proteins, interacts with nuclear receptors and can inhibit betaFTZ-F1-dependent transcription

The Drosophila bonus (bon) gene encodes a homolog of the vertebrate TIF1 transcriptional cofactors. bon is required for male viability, molting, and numerous events in metamorphosis including leg elongation, bristle development, and pigmentation. Most of these processes are associated with genes that have been implicated in the ecdysone pathway, a nuclear hormone receptor pathway required throughout Drosophila development. Bon is associated with sites on the polytene chromosomes and can interact with numerous Drosophila nuclear receptor proteins. Bon binds via an LxxLL motif to the AF-2 activation domain present in the ligand binding domain of betaFTZ-F1 and behaves as a transcriptional inhibitor in vivo.

Conserved interaction between distinct Kruppel-associated box domains and the transcriptional intermediary factor 1

The Krüppel-associated box (KRAB) domain, originally identified as a 75-aa sequence present in numerous Krüppel-type zinc-finger proteins, is a potent DNA-binding-dependent transcriptional repression domain that is believed to function through interaction with the transcriptional intermediary factor 1 (TIF1) beta. On the basis of sequence comparison and phylogenetic analysis, we have recently defined three distinct subfamilies of KRAB domains. In the present study, individual members of each subfamily were tested for transcriptional repression and interaction with TIF1 beta and two other closely related family members (TIF1 alpha and TIF1 gamma). All KRAB variants were shown, (i) to repress transcription when targeted to DNA through fusion to a heterologous DNA-binding domain in mammalian cells, and (ii) to interact specifically with TIF1 beta, but not with TIF1 alpha or TIF1 gamma. Taken together, these results implicate TIF1 beta as a common transcriptional corepressor for the three distinct subfamilies of KRAB zinc-finger proteins and suggest a high degree of conservation in the molecular mechanism underlying their transcriptional repression activity.

Correlation of the exon/intron organization to the conserved domains of the mouse transcriptional corepressor TIF1beta

TIF1beta, a member of the transcriptional intermediary factor 1 family, has been reported to function as a corepressor for the large class of KRAB domain-containing zinc finger proteins of the Krüppel type. In this study, we report the genomic organization and nucleotide sequence of the mouse TIF1beta gene. This gene comprises 17 coding exons located within 7 kb of genomic DNA. Exon sizes vary from 37 bp (exon 10) to 901 bp (exon 1), and intron sizes range from 71 bp to 1843 bp. All introns have the conserved GT and AG dinucleotides present at the donor and acceptor sites, respectively. The functional/homology regions of the TIF1beta protein are encoded by distinct exons. The amino-terminal RING finger is encoded by two exons interrupted by a small intron. The B boxes lie within individual exons. Similarly to the RING finger, the PHD finger is encoded by two exons. Three exons constitute the carboxy-terminal bromodomain, and their position correlates well with the secondary structure elements of the domain as predicted by computer modeling. Taken together, these results will facilitate the genetic manipulation of TIF1beta for future in vivo structure-function studies.

Mice lacking the transcriptional corepressor TIF1beta are defective in early postimplantation development

TIF1beta, a member of the transcriptional intermediary factor 1 family, has been reported to function as a corepressor for the large class of KRAB domain-containing zinc finger proteins of the Kruppel type. To address the biological function of TIF1beta, we have generated TIF1beta-deficient mice by gene disruption. TIF1beta protein was detected in wild-type but not TIF1beta(−/−) blastocysts. Homozygous mutant embryos, which developed normally until the blastocyst stage and underwent uterine implantation, were arrested in their development at the early egg-cylinder stage at about embryonic day (E) 5.5 and were completely resorbed by E8.5. Taken together, these results provide genetic evidence that TIF1beta is a developmental regulatory protein that exerts function(s) essential for early postimplantation development.

Interaction with members of the heterochromatin protein 1 (HP1) family and histone deacetylation are differentially involved in transcriptional silencing by members of the TIF1 family

Mammalian TIF1alpha and TIF1beta (KAP-1/KRIP-1) are related transcriptional intermediary factors that possess intrinsic silencing activity. TIF1alpha is believed to be a euchromatic target for liganded nuclear receptors, while TIF1beta may serve as a co-repressor for the large family of KRAB domain-containing zinc finger proteins. Here, we report an association of TIF1beta with both heterochromatin and euchromatin in interphase nuclei. Co-immunoprecipitation of nuclear extracts shows that endogenous TIF1beta, but not TIF1alpha, is associated with members of the heterochromatin protein 1 (HP1) family. However, in vitro, both TIF1alpha and TIF1beta interact with and phosphorylate the HP1 proteins. This interaction involves a conserved amino acid motif, which is critical for the silencing activity of TIF1beta but not TIF1alpha. We further show that trichostatin A, an inhibitor of histone deacetylases, can interfere with both TIF1 and HP1 silencing. The silencing activity of TIF1alpha appears to result chiefly from histone deacetylation, whereas that of TIF1beta may be mediated via both HP1 binding and histone deacetylation.

Expression of the transcriptional intermediary factor TIF1alpha during mouse development and in the reproductive organs

Nuclear receptors are important regulators of development and reproduction whose action can be modulated by transcriptional intermediary factors (TIFs). In situ hybridization was used to investigate the expression pattern of the putative nuclear receptor mediator TIF1alpha during mouse embryogenesis and adult life. TIF1alpha is ubiquitously expressed until midgestation. At 12.5 gestational days, TIF1alpha is preferentially expressed in the developing central and peripheral nervous system. Differential expression persists until perinatal stages, with high expression in the brain, nasal epithelium and within proliferating regions of the kidney and teeth. In the adult, TIF1alpha expression is predominant in both the male and female gonads. Immunogold electron microscopy revealed that TIF1alpha protein is most abundant in the nuclei of male germ cells at various stages of their maturation.

Structural basis for engineering of retinoic acid receptor isotype-selective agonists and antagonists

BACKGROUND

Many synthetic retinoids have been generated that exhibit a distinct pattern of agonist/antagonist activities with the three retinoic acid receptors (RARalpha, RARbeta and RARgamma). Because these retinoids are selective tools with which to dissect the pleiotropic functions of the natural pan-agonist, retinoic acid, and might constitute new therapeutic drugs, we have determined the structural basis of their receptor specificity and compared their activities in animal and yeast cells.

RESULTS

There are only three divergent amino acid residues in the ligand binding pockets (LBPs) of RARalpha, RARbeta and RARgamma. We demonstrate here that the ability of monospecific (class I) retinoid agonists and antagonists to bind to and induce or inhibit transactivation by a given isotype is directly linked to the nature of these residues. The agonist/antagonist potential of class II retinoids, which bind to all three RARs but depending on the RAR isotype have the potential to act as agonists or antagonists, was also largely determined by the three divergent LBP residues. These mutational studies were complemented by modelling, on the basis of the three-dimensional structures of the RAR ligand-binding domains, and a comparison of the retinoid agonist/antagonist activities in animal and yeast cells.

CONCLUSIONS

Our results reveal the rational basis of RAR isotype selectivity, explain the existence of class I and II retinoids, and provide a structural concept of ligand-mediated antagonism. Interestingly, the agonist/antagonist characteristics of retinoids are not conserved in yeast cells, suggesting that yeast co-regulators interact with RARs in a different way than the animal cell homologues do.

The putative nuclear receptor mediator TIF1alpha is tightly associated with euchromatin

Ligand-dependent transcriptional regulation by nuclear receptors is believed to be mediated by intermediary factors (TIFs) acting on remodelling of the chromatin structure and/or the activity of the transcriptional machinery. The putative transcriptional mediator TIF1alpha is a nuclear protein kinase that has been identified via its interaction with liganded nuclear receptors, including retinoic acid (RAR), retinoid X (RXR) and estrogen (ER) receptors. Here, we demonstrate that TIF1alpha is a non-histone chromosomal protein tightly associated with highly accessible euchromatic regions of the genome. Immunofluorescence confocal microscopy reveals that TIF1alpha exhibits a finely granular distribution in euchromatin of interphase nuclei, while it is mostly excluded from condensed chromatin and metaphase chromosomes. Immunoelectron microscopy shows that, in contrast to the heterochromatin protein HP1alpha, most of TIF1alpha is associated with euchromatin, where it is preferentially localised on regions known to be sites for RNA polymerase II (perichromatin fibrils and borders between euchromatin and heterochromatin). Early mouse embryos as well as embryonal carcinoma (EC) and embryonic stem (ES) cells express high levels of TIF1alpha. These levels dramatically decrease during organogenesis and upon differentiation of P19 EC cells, indicating that TIF1alpha is preferentially expressed in undifferentiated pluripotent cells in the course of development. Therefore, TIF1alpha could belong to a novel class of chromatin-associated TIFs that facilitate the access of transregulators (e.g. liganded nuclear receptors) to their cognate sites in target genes, thereby participitating in the epigenetic control of transcription during embryonic development and cell differentiation.

Role of the essential yeast protein PSU1 in p6anscriptional enhancement by the ligand-dependent activation function AF-2 of nuclear receptors

Nuclear receptors (NRs) can function as ligandinducible transregulators in both mammalian and yeast cells, indicating that important features of transcriptional control have been conserved throughout evolution. We report here the isolation and characterization of an essential yeast protein of unknown function, PSU1, which exhibits properties expected for a co-activator/mediator of the ligand-dependent activation function AF-2 present in the ligand-binding domain (LBD, region E) of NRs. PSU1 interacts in a ligand-dependent manner with the LBD of several NRs, including retinoic acid (RARalpha), retinoid X (RXRalpha), thyroid hormone (TRalpha), vitamin D3 (VDR) and oestrogen (ERalpha) receptors. Importantly, both in yeast and in vitro, these interactions require the integrity of the AF-2 activating domain. When tethered to a heterologous DNA-binding domain, PSU1 can activate transcription on its own. By using yeast reporter cells that express PSU1 conditionally, we show that PSU1 is required for transactivation by the AF-2 of ERalpha. Taken together these data suggest that in yeast, PSU1 is involved in ligand-dependent transactivation by NRs. Sequence analysis revealed that in addition to a highly conserved motif found in a family of MutT-related proteins, PSU1 contains several alpha-helical leucine-rich motifs sharing the consensus sequence LLxPhiL (x, any amino acid; Phi, hydrophobic amino acid) in regions that elicit either transactivation or NR-binding activity.

TIF1gamma, a novel member of the transcriptional intermediary factor 1 family

The Anaphase-Promoting Complex/Cyclosome (APC/C) is an ubiquitin ligase that functions during mitosis. Here we identify the transcriptional regulator, Transcriptional Intermediary Factor 1γ, TIF1γ as an APC/C-interacting protein that regulates APC/C function. TIF1γ is not a substrate for APC/C-dependent ubiquitylation but instead, associates specifically with the APC/C holoenzyme and Cdc20 to affect APC/C activity and progression through mitosis. RNA interference studies indicate that TIF1γ knockdown results in a specific reduction in APC/C ubiquitin ligase activity, the stabilization of APC/C substrates, and an increase in the time taken for cells to progress through mitosis from nuclear envelope breakdown (NEBD) to anaphase. TIF1γ knockdown cells are also characterized by the inappropriate presence of cyclin A at metaphase, and an increase in the number of cells that fail to undergo metaphase-to-anaphase transition. Expression of a siRNA-resistant TIF1γ species relieves the mitotic phenotype imposed by TIF1γ knockdown and allows for mitotic progression. Binding studies indicate that TIF1γ is also a component of the APC/C-Mitotic Checkpoint Complex (MCC), but is not required for MCC dissociation from the APC/C once the Spindle Assembly Checkpoint (SAC) is satisfied. TIF1γ inactivation also results in chromosome misalignment at metaphase, and SAC activation; inactivation of the SAC relieves the mitotic block imposed by TIF1γ knockdown. Together these data define novel functions for TIF1γ during mitosis and suggest that a reduction in APC/C ubiquitin ligase activity promotes SAC activation.

TIF1gamma, a novel member of the transcriptional intermediary factor 1 family

We report the cloning and characterization of a novel member of the Transcriptional Intermediary Factor 1 (TIF1) gene family, human TIF1gamma. Similar to TIF1alpha and TIF1beta, the structure of TIF1beta is characterized by multiple domains: RING finger, B boxes, Coiled coil, PHD/TTC, and bromodomain. Although structurally related to TIF1alpha and TIF1beta, TIF1gamma presents several functional differences. In contrast to TIF1alpha, but like TIF1beta, TIF1 does not interact with nuclear receptors in yeast two-hybrid or GST pull-down assays and does not interfere with retinoic acid response in transfected mammalian cells. Whereas TIF1alpha and TIF1beta were previously found to interact with the KRAB silencing domain of KOX1 and with the HP1alpha, MODI (HP1beta) and MOD2 (HP1gamma) heterochromatinic proteins, suggesting that they may participate in a complex involved in heterochromatin-induced gene repression, TIF1gamma does not interact with either the KRAB domain of KOX1 or the HP1 proteins. Nevertheless, TIF1gamma, like TIF1alpha and TIF1beta, exhibits a strong silencing activity when tethered to a promoter. Since deletion of a novel motif unique to the three TIF1 proteins, called TIF1 signature sequence (TSS), abrogates transcriptional repression by TIF1gamma, this motif likely participates in TIF1 dependent repression.

Retinoic acid receptors interact physically and functionally with the T:G mismatch-specific thymine-DNA glycosylase

The pleiotropic effects of retinoids are mediated by nuclear receptors that are activated by 9-cis- or all-trans-retinoic acid to function as ligand-dependent transcription factors. In a yeast one-hybrid screen for proteins capable of interacting with native retinoic acid receptor (RAR), we have isolated the T:G mismatch-specific thymine-DNA glycosylase (TDG), which initiates the repair of T:G mismatches caused by spontaneous deamination of methylated cytosines. Here, we report that TDG can interact with RAR and the retinoid X receptor (RXR) in a ligand-independent manner, both in yeast and in vitro. Mapping of the binding sites revealed interaction with a region of the ligand binding domain harboring alpha-helix 1 in both RAR and RXR. In transient transfection experiments, TDG potentiated transactivation by RXR from a direct repeat element spaced by one nucleotide (DR1) and by RXR/RAR heterodimers from a direct repeat element spaced by five nucleotides (DR5). In vitro, TDG enhanced RXR and RXR/RAR binding to their response elements. These data indicate that TDG is not only a repair enzyme, but could also function in the control of transcription.

The putative cofactor TIF1alpha is a protein kinase that is hyperphosphorylated upon interaction with liganded nuclear receptors

Ligand-induced gene activation by nuclear receptors (NRs) is a complex process requiring dissociation of corepressors and recruitment of coactivators. The putative transcriptional intermediary factor TIF1alpha has been previously characterized as a nuclear protein that interacts directly with the AF-2 ligand-dependent activating domain present in the ligand-binding domain of numerous steroid and nonsteroid receptors, including the estrogen (ERalpha) and retinoid X (RXRalpha) receptors. We report here that TIF1alpha is both a phosphoprotein and a protein kinase. TIF1alpha coexpressed in COS-1 cells with RXRalpha or ERalpha is phosphorylated and becomes hyperphosphorylated upon ligand treatment. This hyperphosphorylation requires the binding of TIF1alpha to transcriptionally active NRs since it is prevented by mutations either in the core (alpha-helix 12 of the ligand-binding domain) of the AF-2 activating domains of RXRalpha and ERalpha or in the NR box of TIF1alpha that are known to prevent TIF1alpha-NR interactions. Thus, TIF1alpha is a phosphoprotein that undergoes ligand-dependent hyperphosphorylation as a consequence of nuclear receptor binding. We further show that purified recombinant TIF1alpha possesses intrinsic kinase activity and that, in addition to autophosphorylation, TIF1alpha selectively phosphorylates the transcription factors TFIIEalpha, TAFII28, and TAFII55 in vitro. These latter results raise the possibility that TIF1alpha may act, at least in part, by phosphorylating and modifying the activity of components of the transcriptional machinery.

Two distinct nuclear receptor interaction domains in NSD1, a novel SET protein that exhibits characteristics of both corepressors and coactivators

NSD1, a novel 2588 amino acid mouse nuclear protein that interacts directly with the ligand-binding domain (LBD) of several nuclear receptors (NRs), has been identified and characterized. NSD1 contains a SET domain and multiple PHD fingers. In addition to these conserved domains found in both positive and negative Drosophila chromosomal regulators, NSD1 contains two distinct NR interaction domains, NID-L and NID+L, that exhibit binding properties of NIDs found in NR corepressors and coactivators, respectively. NID-L, but not NID+L, interacts with the unliganded LBDs of retinoic acid receptors (RAR) and thyroid hormone receptors (TR), and this interaction is severely impaired by mutations in the LBD alpha-helix 1 that prevent binding of corepressors and transcriptional silencing by apo-NRs. NID+L, but not NID-L, interacts with the liganded LBDs of RAR, TR, retinoid X receptor (RXR), and estrogen receptor (ER), and this interaction is abrogated by mutations in the LBD alpha-helix 12 that prevent binding of coactivators of the ligand-induced transcriptional activation function AF-2. A novel variant (FxxLL) of the NR box motif (LxxLL) is present in NID+L and is required for the binding of NSD1 to holo-LBDs. Interestingly, NSD1 contains separate repression and activation domains. Thus, NSD1 may define a novel class of bifunctional transcriptional intermediary factors playing distinct roles in both the presence and absence of ligand.

The yeast Ada complex mediates the ligand-dependent activation function AF-2 of retinoid X and estrogen receptors

Nuclear receptors can function as ligand-inducible transregulators in both mammalian and yeast cells, indicating that important features of control of transcription have been conserved throughout evolution. Here, we report the isolation and characterization of a yeast protein that exhibits properties expected for a coactivator/mediator of the ligand-dependent activation function AF-2 present in the ligand-binding domain (LBD, region E) of the retinoid X (RXRalpha) and estrogen (ERalpha) receptors. This protein is identical to Ada3, a component of the yeast Ada coactivator complex. We demonstrate that: (1) the region encompassing residues 347-702 of Ada3 interacts with the LBD of RXRalpha and ERalpha in a ligand-dependent manner in yeast; (2) this interaction corresponds to a direct binding and requires the integrity of the core of the AF-2 activating domain (AF-2 AD) of both RXRalpha and ERalpha; (3) Ada3 as well as Ada2 and Gcn5, two other components of the Ada complex, are required for maximal AF-2 activity in yeast; and (4) Ada3 is able to enhance the AF-2 activity of RXRalpha and ERalpha when overexpressed in yeast and mammalian cells. Taken together, these data indicate that ligand-dependent transactivation by RXRalpha and ERalpha in yeast is mediated at least in part by the Ada complex, in which the Ada3 subunit directly binds to the holoreceptor LBD.

TIF1alpha: a possible link between KRAB zinc finger proteins and nuclear receptors

Ligand-induced gene activation by nuclear receptors (NRs) is thought to be mediated by transcriptional intermediary factors (TIFs), that interact with their ligand-dependent AF-2 activating domain. Included in the group of the putative AF-2 TIFs identified so far is TIF1alpha, a member of a new family of proteins which contains an N-terminal RBCC (RING finger-B boxes-coiled coil) motif and a C-terminal bromodomain preceded by a PHD finger. In addition to these conserved domains present in a number of transcriptional regulatory proteins, TIF1alpha was found to contain several protein-protein interaction sites. Of these, one specifically interacts with NRs bound to their agonistic ligand and not with NR mutants that are defective in the AF-2 activity. Immediately adjacent to this 'NR box', TIF1alpha contains an interaction site for members of the chromatin organization modifier (chromo) family, HP1alpha and MOD1, which both are heterochromatinic proteins. Finally, TIF1alpha also has a binding site for KRAB silencing domains of C2H2 zinc finger proteins. TIF1beta, another member of the TIF1 gene family, has some interacting partners in common with TIF1alpha. TIF1beta can interact with HP1alpha, MOD1 and KRAB domains, but apparently not with NRs. Both TIF1alpha and TIF1beta repress transcription when fused to a DNA binding domain in transiently transfected mammalian cells. A model discussing the potential function(s) of TIF1s in the control of transcription at the level of the chromatin template will be presented.

Ligand-dependent interaction between the estrogen receptor and the human homologues of SWI2/SNF2

The human SNF2alpha (or hbrm) and SNF2beta (or BRG1) proteins have previously been shown to enhance transcriptional activation by nuclear receptors (NRs) in cultured human cells, and to be present in SWI/SNF complexes which are thought to be involved in control of transcription by facilitating remodelling of chromatin templates. Using the yeast two-hybrid system, we now demonstrate that the N-terminal regions of hSNF2alpha and hSNF2beta, preceding the DNA-dependent ATPase domain, specifically interact with the region of the estrogen receptor (ER) which includes the ligand binding domain and the ligand-dependent activation function AF-2. These interactions are increased by estrogen, but not by the ER AF-2 antagonist hydroxytamoxifen. Furthermore, mutants of ER that lack AF-2 activity are unable to interact with hSNF2alpha and -beta. These results suggest that the human homologues of the yeast SWI2/SNF2 protein may participate in the enhancement of transcription by the ER in vivo through interactions with the AF-2 activating domain, thus leading to ligand-dependent remodelling of chromatin templates.

A possible involvement of TIF1 alpha and TIF1 beta in the epigenetic control of transcription by nuclear receptors

Nuclear receptors (NRs) are ligand-inducible transcription factors that mediate complex effects on development, differentiation and homeostasis. They regulate the transcription of their target genes through binding to cognate DNA sequences as homodimers or heterodimers. The molecular mechanisms underlying transcriptional activation by NRs are still poorly understood, although intermediary factors (mediators) appear to be involved in mediating the transactivation functions of NRs. TIF1 has been identified previously as a protein that interacts specifically with the ligand binding domain of several nuclear receptors, both in yeast and in vitro. The characteristics of these interactions have led us to suggest that TIF1 might be a mediator of the NR ligand-inducible activation function AF-2. Using a two-hybrid screening in yeast, we have now identified two TIF1-binding proteins, mHP1 alpha and mMOD1, that are mouse homologues of the Drosophila heterochromatinic protein 1. Using mHP1 alpha as a bait in a second two-hybrid screening, we have isolated cDNAs encoding proteins that are also very likely to be involved in chromatin structure and function, as well as a protein structurally and functionally related to TIF1 (renamed TIF1 alpha), which was named TIF1 beta. Here we discuss how the function of members of the TIF1 family in the control of transcription could be exerted at the level of the structure of the chromatin template.

Ligand-dependent interaction of nuclear receptors with potential transcriptional intermediary factors (mediators)

The activity of the ligand-inducible activation function 2 (AF-2) contained in the ligand binding domain (LBD) of nuclear receptors (NRs) is thought to be mediated by transcriptional intermediary factors (TIFs). We have recently reported the isolation and characterization of two novel mouse proteins, designated TIF1 and mSUG1, that interact in a ligand-dependent fashion with the LBD (region E) of several NRs in vivo as well as in vitro. Remarkably, these interactions require the conserved core motif of the AF-2 activating domain (AF-2 AD) and can be blocked by AF-2 antagonists. TIF1 and mSUG1 might therefore represent TIFs/mediators for the ligand-dependent AF-2 of NRs. By comparing the interaction properties of these two putative TIFs with different NRs including the oestrogen (ER), thyroid hormone (TR), vitamin D3 (VDR), retinoic acid (RAR alpha) and retinoid X (RXR) receptors, we demonstrate that: (i) RXR alpha efficiently interacts with TIF1, but not with mSUG1, whereas TR alpha interacts much more efficiently with mSUG1 than with TIF1, and RAR alpha, VDR and ER efficiently interact with both TIF1 and mSUG1; (ii) the amphipathic alpha helix core of AF-2 AD is differentially involved in the interactions of RAR alpha with TIF1 and mSUG1; and (iii) the AF-2 AD cores of RAR alpha and ER are similarly involved in their interaction with TIF1, but not with mSUG1. Thus the interaction interfaces between the various NRs and either TIF1 or mSUG1 may vary depending on the nature of both the receptor and the putative mediator of its AF-2 function. We discuss the possible roles of TIF1 and mSUG1 as mediators of the transcriptional activity of the AF-2 of NRs.

Differential ligand-dependent interactions between the AF-2 activating domain of nuclear receptors and the putative transcriptional intermediary factors mSUG1 and TIF1

Using a yeast two-hybrid system we report the isolation of a novel mouse protein, mSUG1, that interacts with retinoic acid receptor alpha (RAR alpha) both in yeast cells and in vitro in a ligand- and AF-2 activating domain (AF-2 AD)-dependent manner and show that it is a structural and functional homologue of the essential yeast protein SUG1. mSUG1 also efficiently interacts with other nuclear receptors, including oestrogen (ER), thyroid hormone (TR), Vitamin D3 (VDR) and retinoid X (RXR) receptors. By comparing the interaction properties of these receptors with mSUG1 and TIF1, we demonstrate that: (i) RXR alpha efficiently interacts with TIF1, but not with mSUG1, whereas TR alpha interacts much more efficiently with mSUG1 than with TIF1, and RAR alpha, VDR and ER efficiently interact with mSUG1 and TIF1; (ii) the amphipathic alpha-helix core of the AF-2 AD is differentially involved in interactions of RAR alpha with mSUG1 and TIF1; (iii) the AF-2 AD cores of RAR alpha and ER are similarly involved in their interaction with TIF1, but not with mSUG1. Thus, the interaction interfaces between the different receptors and either mSUG1 or TIF1 may vary depending on the nature of the receptor and the putative mediator of its AF-2 function. We discuss the possibility that mSUG1 and TIF1 may mediate the transcriptional activity of the AF-2 of nuclear receptors through different mechanisms.

The N-terminal part of TIF1, a putative mediator of the ligand-dependent activation function (AF-2) of nuclear receptors, is fused to B-raf in the oncogenic protein T18

Nuclear receptors (NRs) bound to response elements mediate the effects of cognate ligands on gene expression. Their ligand-dependent activation function, AF-2, presumably acts on the basal transcription machinery through intermediary proteins/mediators. We have isolated a mouse nuclear protein, TIF1, which enhances RXR and RAR AF-2 in yeast and interacts in a ligand-dependent manner with several NRs in yeast and mammalian cells, as well as in vitro. Remarkably, these interactions require the amino acids constituting the AF-2 activating domain conserved in all active NRs. Moreover, the oestrogen receptor (ER) AF-2 antagonist hydroxytamoxifen cannot promote ER-TIF1 interaction. We propose that TIF1, which contains several conserved domains found in transcriptional regulatory proteins, is a mediator of ligand-dependent AF-2. Interestingly, the TIF1 N-terminal moiety is fused to B-raf in the mouse oncoprotein T18.

Activation function 2 (AF-2) of retinoic acid receptor and 9-cis retinoic acid receptor: presence of a conserved autonomous constitutive activating domain and influence of the nature of the response element on AF-2 activity

A motif essential for the transcriptional activation function 2 (AF-2) present in the E region of retinoic acid receptor (RAR) alpha and 9-cis retinoic acid receptor (RXR) alpha has been characterized as an amphipathic alpha-helix whose main features are conserved between transcriptionally active members of the nuclear receptor superfamily. This conserved motif, which can activate autonomously in the absence of ligand in animal and yeast cells, can be swapped between nuclear receptors without affecting the ligand dependency for activation of transcription, thus indicating that a ligand-dependent conformational change is necessary to reveal the AF-2 activation potential within the E region of the nuclear receptor. Interestingly, we show that the precise nature of the direct repeat response element to which RAR/RXR heterodimers are bound can affect the activity of the AF-2s of the heterodimeric partners, as well as the relative efficiency with which all-trans and 9-cis retinoic acids activate the RAR partner.

A highly conserved region in the hormone-binding domain of the human estrogen receptor functions as an efficient transactivation domain in yeast

Human estrogen receptor (hER) mutants which activate transcription in the absence of hormone were isolated by random mutagenesis and genetic selection in the yeast Saccharomyces cerevisiae. Twenty constitutive hER mutants defining ten different alleles were selected. All sequence changes resulted in truncations of the receptor within a 123-amino-acid (aa) segment (aa 270 to 393) spanning the D region and the N-terminal part of region E which contains the hormone-binding domain (HBD). Transactivation assays using both the constitutive hER mutants and a series of deleted receptor derivatives generated in vitro revealed that the N-terminal part of region E, between aa 302 and 339, contains an efficient transcriptional activation function which is constitutively active in yeast. The location of this transactivation function in hER is similar to that of the tau 2 activation function of the glucocorticoid receptor and corresponds to a sequence which is highly conserved among the steroid hormone receptors. Thus, a conserved region exists in the HBD of the hER which can function as an autonomous transactivation domain.

Homo- and heterodimers of the retinoid X receptor (RXR) activated transcription in yeast

The polymorphic nature of sequences which act as retinoic acid response elements (RAREs and RXREs) in transactivation assays in mammalian cells, suggests that elements consisting of a direct repetition of a half site motif, separated by 1 to 5 base pairs (DR1 to DR5), are targets for retinoic acid (RA) signalling. In a previous report we showed that in yeast cells, heterodimers of the retinoic acid receptors RAR alpha and RXR alpha were required for efficient transcription of a reporter gene containing a DR5 element [Heery et al., (1993); Proc. Natl. Acad. Sci. USA, 90: 4281-4285]. Here we report that DR1 to DR5 elements containing a direct repeat of the 5'-AGGTCA-3' motif, and an inverted repeat of the same sequence with no spacer (IR0), behave as RAREs in yeast cells coexpressing RAR alpha and RXR alpha, albeit with different efficacies. Heterodimer activity was strongest on a DR5 reporter gene, and the strength of activation of the reporter series (DR5 > DR1 > DR3 > DR2 = IR0 = DR4) correlated with the ability of the heterodimer to bind to the corresponding sequences in vitro. Significantly, a reporter containing a DR1 element was selectively and efficiently activated in yeast cells expressing only RXR alpha. This activity was dependent on the induction by 9-cis retinoic acid of an activation function (AF-2) located in the RXR alpha ligand binding domain. In addition, a strong synergistic activity of RXR alpha was observed on a reporter containing the putative RXR element (RXRE) from the rat CRBPII gene promoter. Thus, RXR alpha can function independently as a transcription factor, in the absence of RARs or other heteromeric partners. Similarly, homodimers of RAR alpha selectively stimulated the transcription of a DR5 reporter in a ligand-dependent manner, but less efficiently than RAR alpha/RXR alpha heterodimers.

The 5' untranslated region of the PPR1 regulatory gene dictates rapid mRNA decay in yeast

In Saccharomyces cerevisiae, the mRNA encoded by the PPR1 gene is very unstable (t1/2 = 1 min), whereas the mRNA encoded by the URA3 gene is relatively stable (t1/2 = 10 min). To identify cis-acting sequences that dictate mRNA decay rates in yeast, we have constructed PPR1/URA3 gene fusions and measured the half-lives of the resulting chimeric transcripts. The mRNA containing the URA3 coding region fused to the untranslated regions (UTR) of PPR1 decayed at a rate similar to the native PPR1 mRNA, suggesting that the instability of the PPR1 mRNA is not linked to its coding sequence. When the 5'-UTR of PPR1 was replaced by the 5'-UTR of URA3, the chimeric transcript was strongly stabilized, indicating that the 5'-UTR of PPR1 is required for the rapid decay of its mRNA. Fusion of this PPR1 5'-UTR to the URA3 coding region was sufficient to destabilize the chimeric mRNA. We conclude that the PPR1 5'-UTR contains sequence(s) that can promote rapid mRNA decay in yeast.

Efficient transactivation by retinoic acid receptors in yeast requires retinoid X receptors

All-trans and 9-cis retinoic acids are natural derivatives of vitamin A that modulate gene expression as a consequence of binding to nuclear retinoic acid receptors (RARs) and retinoid X receptors (RXRs). RXRs form heterodimers with RARs in vitro, and such complexes display enhanced binding affinities for cognate DNA response elements. As yeast is devoid of endogenous RARs and RXRs, we used this organism to investigate whether transactivation in vivo requires RAR/RXR heterodimers. Using a domain-swapping approach, we demonstrate that chimeric RAR alpha 1 and RXR alpha containing the DNA-binding domain of the estrogen receptor activate transcription of a cognate reporter gene in yeast, independently of each other. These activities result from an inducible transcription activation function located in the ligand-binding domains of RAR alpha 1 and RXR alpha and a constitutive activation function located in the A/B region of RAR alpha 1. The inducible activation function of RXR alpha is induced exclusively by 9-cis-retinoic acid in this system. Transactivation of a reporter gene containing a retinoic acid response element by RAR alpha was considerably increased by RXR alpha, even in the absence of ligand. Optimal induction was achieved with 9-cis-retinoic acid, which stimulates the activity of both receptors. This study illustrates the utility of yeast to investigate signal transduction by retinoids in the absence of endogenous RARs, RXRs, and detectable retinoic acid isomerization.

Estradiol-inducible squelching and cell growth arrest by a chimeric VP16-estrogen receptor expressed in Saccharomyces cerevisiae: suppression by an allele of PDR1

We have constructed and characterized a flexible system for analyzing the phenomenon of squelching and estrogen receptor function in the yeast Saccharomyces cerevisiae. The A/B region of the human estrogen receptor was replaced with the transcriptional activating domain of VP16 and expressed in yeast cells from high-copy-number plasmids. Addition of hormone resulted in an immediate inhibition of expression (squelching) of a chromosomally integrated GAL1:lacZ reporter gene and the eventual arrest of cell growth (toxicity). In order to determine whether a relationship exists between toxicity and squelching, mutations were made in this chimeric receptor (VEO) and their effects on transcriptional activation, squelching, and toxicity were compared. A direct correlation was found between mutations in VEO that reduced VP16 transactivation ability in yeast cells and those that reduced both squelching and toxicity. Surprisingly, mutations in the DNA binding domain (DBD) of VEO dramatically reduced squelching and completely relieved toxicity, suggesting a role for the DBD in squelching and strengthening the correlation between squelching and toxicity. To demonstrate the utility of this system for carrying out genetic selection, a plasmid-based yeast genomic bank was screened for genes that can relieve the toxicity of VEO by means of an elevated copy number, resulting in the repeated cloning of an allele of the PDR1 (pleiotropic drug resistance) gene. We present evidence that mutations in PDR1 can modulate the intracellular availability of estradiol by the same mechanism that leads to multiple drug resistance in yeast cells. Taken together, our results provide evidence that cell growth arrest occurs when squelching exceeds a certain threshold and that strong squelching requires both a DBD and a transcriptional activating domain. Furthermore, we show that growth arrest can provide a useful phenotype for carrying out the genetic analysis of both squelching and estrogen receptor function in yeast cells.

Functional analysis of the human estrogen receptor using a phenotypic transactivation assay in yeast

We have constructed yeast strains in which the expression of the Saccharomyces cerevisiae URA3 gene is induced by the human estrogen receptor (hER). Promoter sequences required for both basal and activated transcription of URA3 were replaced with one or three estrogen-response elements (EREs) positioned upstream of the native TATA box. These constructs were each integrated at the TRP1 locus of a yeast strain in which the natural URA3 gene had been deleted, and the integrants were transformed with low- or high-copy-number shuttle plasmids expressing wild-type or truncated derivatives of hER. Transformants were assayed for growth on uracil-deficient medium plus or minus estradiol (E2), for resistance to 5-fluoroorotic acid (5-FOA) and for activity of OMPdecase (orotidine-5'-monophosphate decarboxylase), the product of the URA3 gene. We show that the growth and 5-FOA-resistance (5-FOAR) phenotypes of these strains are strictly dependent upon the function of the receptor derivatives. Induction of URA3, measured by OMPdecase activity, was observed over a 20- to 2500-fold range depending on the receptor derivative, its expression level and the number of EREs in the responsive promoter. Both one- and three-ERE reporter strains expressing the full-length receptor are completely E2-dependent for growth, and display a 5-FOAR phenotype in the absence of the hormone. We demonstrate that the individual hER transactivation functions, TAF1 and TAF2, are both functional in yeast, and that the hormone-dependent TAF2 is the more potent activator on our reporters. We show that hER displays strong homosynergism in yeast, and discuss the contributions of the two TAFs in hER synergism.(ABSTRACT TRUNCATED AT 250 WORDS)

Ligand dependence of estrogen receptor induced changes in chromatin structure

To determine whether the human estrogen receptor requires ligand to bind to its cognate estrogen receptor element (ERE) in vivo, we have examined the structure of chromatin at a chromosomally integrated ERE-URA3 reporter gene in yeast, and the influence of ligand bound and ligand free estrogen receptors on that structure. Using indirect end-labelling to map DNaseI and micrococcal nuclease sensitive sites, we found that receptor induced alterations in chromatin structure were completely dependent upon the presence of estradiol. These same alterations in chromatin structure were induced by a truncated estrogen receptor with both TAF-1 and TAF-2 transactivation functions deleted, suggesting that DNA binding per se disrupts chromatin structure. These results support models in which the estrogen receptor requires ligand to bind to the ERE in vivo.

Promoter specificity of the two transcriptional activation functions of the human oestrogen receptor in yeast

We have previously demonstrated that the human oestrogen receptor (hER) contains two transcriptional activation functions located in the N-terminal region (TAF-1) and in the hormone binding domain (TAF-2), which can act both independently and synergistically in a promoter- and cell-specific manner in animal cells. We have also demonstrated that hER can activate transcription from chimaeric oestrogen-responsive GAL1 promoters in yeast, and shown that transcriptional activation was due to TAF-1, whereas TAF-2 showed little, if any, transcriptional activity on these promoters. By using a more complex promoter derived from the URA3 gene, we now show that TAF-2 is also active in yeast, and that the activities of TAF-1 and TAF-2 are promoter-context-specific in yeast. We also confirm that the agonistic activity of 4-hydroxytamoxifen (OHT) can be ascribed to the activity of TAF-1.

cis- and trans-acting regulatory elements of the yeast URA3 promoter

Expression of the yeast pyrimidine biosynthetic gene, URA3, is induced three- to fivefold in response to uracil starvation, and this regulation is mediated by the transcriptional activator PPR1 (pyrimidine pathway regulator 1). In this study, we have analyzed the regulatory elements of the URA3 promoter by DNase I footprinting, using partially purified yeast cell extracts, by deletion mutagenesis, and by 5'-end mapping of RNA transcripts. Two DNA-binding activities have been detected, and at least four distinct cis-acting regions have been identified. A region rich in poly(dA-dT) serves as an upstream promoter element necessary for the basal level of URA3 expression. A 16-base-pair sequence with dyad symmetry acts acts as a uracil-controlled upstream activating site (UASURA) and shows a specific binding only with cell extracts from strains overproducing PPR1. This in vitro binding does not require dihydroorotic acid, the physiological inducer of URA3. The TATA region appears to be composed of two functionally distinct (constitutive and regulatory) elements. Two G + A-rich regions surrounding this TATA box bind an unidentified factor called GA-binding factor. The 5' copy, GA1, is involved in PPR1 induction and overlaps the constitutive TATA region. The 3' region, GA2, is necessary for maximal expression. Neither of these GA sequences acts as a UAS in a CYC1-lacZ context. The promoters of the unlinked but coordinately regulated URA1 and URA4 genes contain highly conserved copies of the UASURA sequence, which prompted us to investigate the effects of many point mutations within this UASURA sequence on PPR1-dependent binding. In this way, we have identified the most important residues of this binding site and found that a nonsymmetrical change of these bases is sufficient to prevent the specific binding and to suppress the UASURA activity in vivo. In addition, we showed that UASURA contains a constitutive activating element which can stimulate transcription from a heterologous promoter independently of dihydroorotic acid and PPR1.

Yeast promoters URA1 and URA3. Examples of positive control

Transcription of the two unlinked structural genes URA1 and URA3 of Saccharomyces cerevisiae is positively regulated by the gene product PPR1. We have used S1 digestion and primer extension mapping to investigate the RNAs produced in different genetic backgrounds: wild-type, ppr1 deletion mutants, constitutively induced and non-inducible ppr1 mutants. Results show that each structural gene specifies multiple messenger RNA classes with different 5'-terminal sequences. The basal level of these transcripts does not require a functional PPR1 gene. Induction of URA1 results from an even increase of the level of synthesis of all the transcripts in contrast to that of URA3 which is effected by selectively increasing the levels of synthesis of one subset of transcripts. The PPR1-mediated control was also studied in the foreign genetic background of Schizosaccharomyces pombe using autonomously replicating hybrid plasmids carrying the gene URA1 or URA3 along with the regulatory gene PPR1, either in a constitutive or non-inducible allelic form. The 5' ends of the transcripts URA1 and URA3 made in S. pombe map upstream from the initiation sites used in S. cerevisiae. In contrast to S. cerevisiae, in S. pombe the URA3 but not URA1 transcripts respond to the PPR1-induction. We have identified a minimal control region for the PPR1-specific induction of URA1, that includes sequences located between the T-A-T-A box and the translation start codon. This region contains sequence features in common with URA3. There is an extensive alternating Pu:Py region including the T-A-T-A box of both promoters and an eight base-pair exact homology; further downstream, there is another 11 base-pair highly conserved sequence which either overlaps or lies in close proximity to the unregulated start sites of URA1 in S. pombe and of URA3 in S. cerevisiae. A positive regulatory model taking into accounts all these observations is presented.

Yeast regulatory gene PPR1. II. Chromosomal localization, meiotic map, suppressibility, dominance/recessivity and dosage effect

The Saccharomyces cerevisiae gene PPR1 encodes a positive regulator of the expression of the two unlinked structural genes URA1 and URA3. The gene has been mapped to a position 6.5 cM from the centromere of chromosome XII. Uninducible alleles have been selected and used to establish a meiotic map. Suppressible alleles have been identified. The sequencing of a suppressible allele confirms the nonsense nature of the mutation as well as the reading frame deduced from the nucleotide sequence. No evidence of intracistronic complementation was found, and enzymatic analysis of leaky mutants did not reveal any mutations dissociating regulation of URA1 from that of URA3. Three in vitro-constructed deletions of PPR1 have been integrated at the chromosomal locus, giving strains with a completely negative phenotype. These deletion mutants display the wild-type basal level of URA1 and URA3 expression and show a semi-dominant phenotype in heteroallelic ppr1+/ppr1-delta diploids. Amplifying PPR1 by introduction into yeast on a multicopy vector increases the induction factor of URA1 and URA3 expression. These results show that the extent of regulation of the two structural genes is dependent on the concentration of the active PPR1 protein.

In vivo transcription of a eukaryotic regulatory gene

The PPR1 gene encodes the positive regulator of the URA1 and URA3 genes in yeast. Its transcription product is a 2.9-kb polyadenylated RNA with an extremely short half-life of 1 min. The induced or non-induced cell contains approximately 0.1 molecules of PPR1 RNA, a constitutive level which is not altered by changing the number of structural genes to be regulated. The DNA sequence of a 399-bp AccI-Bg/II fragment including 180 nucleotides of the 5'-flanking region of the gene PPR1 has been determined. By S1 mapping we present evidence that the 5' non-coding region of the PPR1 mRNA is heterogeneous in length. The 5' termini of the different RNAs map 20, 36, 45 and 50 nucleotides upstream from the translation start codon. The sequence indicates that the only open translation phase begins with an AUG codon that is preceded by two out-of-frame AUG triplets. This particular structure of the 5'-terminal sequence of the transcripts of PPR1 is discussed in relation to both their stability and translational efficiency.

Cloning of a eukaryotic regulatory gene

From a pool of hybrid plasmids carrying Sau3A fragments representing the entire yeast (S. cerevisiae) genome, a DNA fragment containing the regulatory gene PPRI was cloned by complementation of a non-inducible ppr1 mutation which confers to the cells an increased sensitivity to 6-azauracil. Cells containing the cloned DNA regained the ability to induce the synthesis of URA1 and URA3 gene products controlled by PPR1. A physical map has been constructed and the study of subcloned restriction endonuclease fragments from the original yeast DNA fragment allowed us to localize the wile-type PPR1 regulatory gene within a 3 kilobase-pair region. The ppr1 RNA level was measured and the hybridization data indicate in a wild-type strain a low efficiency of transcription of PPR1 as compared to the structural URA3 gene, without effect of inducing conditions.

Interference of nonsense mutations with eukaryotic messenger RNA stability

The fine structure map of the yeast URA 3 gene was established by meiotic recombination, and amber nonsense mutations were located at different points on the map. The effect of the length of the labeling time on the specific radioactivity of ura 3 messenger RNA and on its repartition between poly(A)-RNA and RNA not containing poly(A) has been followed in nonsense mutants. Nonsense mutations reduce the messenger level without lowering its instantaneous rate of synthesis. The strength of the reduction depends on the position of the nonsense codon within the locus and concerns essentially the accumulation of polyadenylylated ura 3 mRNA.