TLP-mediated global transcriptional repression after double-strand DNA breaks slows down DNA repair and induces apoptosis.

Transcription and DNA damage repair act in a coordinated manner. Recent studies have shown that double-strand DNA breaks (DSBs) are repaired in a transcription-coupled manner. Active transcription results in a faster recruitment of DSB repair factors and expedites DNA repair. On the other hand, transcription is repressed by DNA damage through multiple mechanisms. We previously reported that TLP, a TATA box-binding protein (TBP) family member that functions as a transcriptional regulator, is also involved in DNA damage-induced apoptosis. However, the mechanism by which TLP affects DNA damage response was largely unknown. Here we show that TLP-mediated global transcriptional repression after DSBs is crucial for apoptosis induction by DNA-damaging agents such as etoposide and doxorubicin. Compared to control cells, TLP-knockdown cells were resistant to etoposide-induced apoptosis and exhibited an elevated level of global transcription after etoposide exposure. DSBs were efficiently removed in transcriptionally hyperactive TLP-knockdown cells. However, forced transcriptional shutdown using transcriptional inhibitors α-amanitin and 5,6-dichloro-1-ß-D-ribofuranosylbenzimidazole (DRB) slowed down DSB repair and resensitized TLP-knockdown cells to etoposide. Taken together, these results indicate that TLP is a critical determinant as to how cells respond to DSBs and triggers apoptosis to cells that have sustained DNA damage.

TBP-like Protein (TLP) Disrupts the p53-MDM2 Interaction and Induces Long-lasting p53 Activation.

Stress-induced activation of p53 is an essential cellular response to prevent aberrant cell proliferation and cancer development. The ubiquitin ligase MDM2 promotes p53 degradation and limits the duration of p53 activation. It remains unclear, however, how p53 persistently escapes MDM2-mediated negative control for making appropriate cell fate decisions. Here we report that TBP-like protein (TLP), a member of the TBP family, is a new regulatory factor for the p53-MDM2 interplay and thus for p53 activation. We found that TLP acts to stabilize p53 protein to ensure long-lasting p53 activation, leading to potentiation of p53-induced apoptosis and senescence after genotoxic stress. Mechanistically, TLP interferes with MDM2 binding and ubiquitination of p53. Moreover, single cell imaging analysis shows that TLP depletion accelerates MDM2-mediated nuclear export of p53. We further show that a cervical cancer-derived TLP mutant has less p53 binding ability and lacks a proliferation-repressive function. Our findings uncover a role of TLP as a competitive MDM2 blocker, proposing a novel mechanism by which p53 escapes the p53-MDM2 negative feedback loop to modulate cell fate decisions.

Ubiquitin-proteasome-dependent degradation of TBP-like protein is prevented by direct binding of TFIIA.

Although the majority of gene expression is driven by TATA-binding protein (TBP)-based transcription machinery, it has been reported that TBP-related factors (TRFs) are also involved in the regulation of gene expression. TBP-like protein (TLP), which is one of the TRFs and exhibits the highest affinity to TFIIA among known proteins, has recently been showed to have significant roles in gene regulation. However, how the level of TLP is maintained in vivo has remained unknown. In this study, we explored the mechanism by which TLP protein is turned over in vivo and the factor that maintains the amount of TLP. We showed that TLP is rapidly degraded by the ubiquitin-proteasome system and that tight interaction with TFIIA results in protection of TLP from ubiquitin-proteasome-dependent degradation. The half-life of TLP was shown to be less than a few hours, and the proteasome inhibitor MG132 specifically suppressed TLP degradation. Moreover, knockdown and over-expression experiments showed that TFIIA is engaged in stabilization of TLPin vivo. Thus, we showed a novel characteristic of TLP, that is, interaction with TFIIA is essential to suppress proteasome-dependent turnover of TLP, providing a further insight into TLP-governed gene regulation.

TBP-like protein (TLP) represses myogenesis via inhibition of the myogenin promoter.

TBP-like protein (TLP) is one of the metazoan-restricted transcription factors participating in development and differentiation, though the molecular mechanism by which TLP regulates these processes remains unclear. In this study, we investigated the relationship between TLP and myogenesis of mouse C2C12 myoblasts. We found that TLP gene expression decreases during myogenic differentiation. Overexpression and knockdown of TLP revealed that the levels of muscle-specific myosin heavy chain and the myogenic transcription factor myogenin are downregulated by TLP. TLP inhibits the progression of morphological change from myoblasts to myotubes, thereby suppressing myogenesis. We further show that TLP represses the promoter activity of myogenin. The proximal AT-rich sequence of the myogenin promoter is responsible for TLP-mediated transcriptional repression. The results of this study suggest that TLP inhibits myogenesis through downregulation of the myogenin gene.

TBP-like protein (TLP) interferes with Taspase1-mediated processing of TFIIA and represses TATA box gene expression.

TBP-TFIIA interaction is involved in the potentiation of TATA box-driven promoters. TFIIA activates transcription through stabilization of TATA box-bound TBP. The precursor of TFIIA is subjected to Taspase1-directed processing to generate α and ß subunits. Although this processing has been assumed to be required for the promoter activation function of TFIIA, little is known about how the processing is regulated. In this study, we found that TBP-like protein (TLP), which has the highest affinity to TFIIA among known proteins, affects Taspase1-driven processing of TFIIA. TLP interfered with TFIIA processing in vivo and in vitro, and direct binding of TLP to TFIIA was essential for inhibition of the processing. We also showed that TATA box promoters are specifically potentiated by processed TFIIA. Processed TFIIA, but not unprocessed TFIIA, associated with the TATA box. In a TLP-knocked-down condition, not only the amounts of TATA box-bound TFIIA but also those of chromatin-bound TBP were significantly increased, resulting in the stimulation of TATA box-mediated gene expression. Consequently, we suggest that TLP works as a negative regulator of the TFIIA processing and represses TFIIA-governed and TATA-dependent gene expression through preventing TFIIA maturation.

Activity of the upstream TATA-less promoter of the p21(Waf1/Cip1) gene depends on transcription factor IIA (TFIIA) in addition to TFIIA-reactive TBP-like protein.

TATA-binding protein-like protein (TLP) binds to transcription factor IIA (TFIIA) with high affinity, although the significance of this binding is poorly understood. In this study, we investigated the role of TFIIA in transcriptional regulation of the p21(Waf1/Cip1) (p21) gene. It has been shown that TLP is indispensable for p53-activated transcription from an upstream TATA-less promoter of the p21 gene. We found that mutant TLPs having decreased TFIIA-binding ability exhibited weakened transcriptional activation function for the upstream promoter. Activity of the upstream promoter was enhanced considerably by an increased amount of TFIIA in a p53-dependent manner, whereas activity of the TATA-containing downstream promoter was enhanced only slightly. TFIIA potentiated the upstream promoter additively with TLP. Although TFIIA is recruited to both promoters, activity of the upstream promoter was much more dependent on TFIIA. Recruitment of TFIIA and TLP to the upstream promoter was augmented in etoposide-treated cells, in which the amount of TFIIA-TLP complex is increased, and TFIIA-reactive TLP was required for the recruitment of both factors. It was confirmed that etoposide-stimulated transcription depends on TLP. We also found that TFIIA-reactive TLP acts to decrease cell growth rate, which can be explained by interaction of the p21 promoter with the transcription factors that we examined. The results of the present study suggest that the upstream TATA-less promoter of p21 needs TFIIA and TFIIA-reactive TLP for p53-dependent transcriptional enhancement.

Interaction between transactivation domain of p53 and middle part of TBP-like protein (TLP) is involved in TLP-stimulated and p53-activated transcription from the p21 upstream promoter.

TBP-like protein (TLP) is involved in transcriptional activation of an upstream promoter of the human p21 gene. TLP binds to p53 and facilitates p53-activated transcription from the upstream promoter. In this study, we clarified that in vitro affinity between TLP and p53 is about one-third of that between TBP and p53. Extensive mutation analyses revealed that the TLP-stimulated function resides in transcription activating domain 1 (TAD1) in the N-terminus of p53. Among the mutants, #22.23, which has two amino acid substitutions in TAD1, exhibited a typical mutant phenotype. Moreover, #22.23 exhibited the strongest mutant phenotype for TLP-binding ability. It is thus thought that TLP-stimulated and p53-dependent transcriptional activation is involved in TAD1 binding of TLP. #22.23 had a decreased transcriptional activation function, especially for the upstream promoter of the endogenous p21 gene, compared with wild-type p53. This mutant did not facilitate p53-dependent growth repression and etoposide-mediated cell-death as wild-type p53 does. Moreover, mutation analysis revealed that middle part of TLP, which is requited for p53 binding, is involved in TLP-stimulated and p53-dependent promoter activation and cell growth repression. These results suggest that activation of the p21 upstream promoter is mediated by interaction between specific regions of TLP and p53.

Interplay between two myogenesis-related proteins: TBP-interacting protein 120B and MyoD.

Gene expression in myogenesis is governed by multiple myogenic factors including MyoD. Previously, we demonstrated that TBP-interacting protein 120B (TIP120B) promotes in vitro myogenesis through its anti-ubiquitination ability. In this study, we investigated interplay between MyoD and TIP120B. Mouse C2C12 cells subjected to myotube differentiation contained increased amounts of TIP120B and MyoD. Dexamethasone, which inhibits myogenic signaling, decreased the amounts of those proteins. Mouse and human TIP120B promoters, which carry multiple E-box motifs, were potentiated by MyoD. In the human TIP120B, a proximal E-box binds to MyoD in vitro and exhibits MyoD-dependent transcription activation function. Expression of the endogenous TIP120B gene was correlated with the level of MyoD in different types of muscle-related cells. Furthermore, MyoD binds specifically to a proximal E-box-carrying promoter region in chromatin. Proteasome-sensitive MyoD was increased and decreased by overexpression and knockdown of TIP120B, respectively. Moreover, stability of MyoD was increased by TIP120B. The results suggest that MyoD and TIP120B potentiate each other at gene expression and post-translation levels, respectively, which may promote myogenesis cooperatively.

TATA-binding protein (TBP)-like protein is required for p53-dependent transcriptional activation of upstream promoter of p21Waf1/Cip1 gene.

TATA-binding protein-like protein (TLP) is involved in development, checkpoint, and apoptosis through potentiation of gene expression. TLP-overexpressing human cells, especially p53-containing cells, exhibited a decreased growth rate and increased proportion of G(1) phase cells. TLP stimulated expression of several growth-related genes including p21 (p21(Waf1/Cip1)). TLP-mediated activation of the p21 upstream promoter in cells was shown by a promoter-luciferase reporter assay. The p53-binding sequence located in the p21 upstream promoter and p53 itself are required for TLP-mediated transcriptional activation. TLP and p53 bound to each other and synergistically enhanced activity of the upstream promoter. TLP specifically activated transcription from the endogenous upstream promoter, and p53 was required for this activation. Etoposide treatment also resulted in activation of the upstream promoter as well as nuclear accumulation of TLP and p53. Moreover, the upstream promoter was associated with endogenous p53 and TLP, and the p53 recruitment was enhanced by TLP. The results of the present study suggest that TLP mediates p53-governed transcriptional activation of the p21 upstream promoter.

Mouse Wee1 gene is repressed by Krüppel-like factor 3 (KLF3) via interaction with multiple upstream elements.

Wee1 protein kinase represses CDK1 required for G(2)/M transition. The mouse wee1 promoter contains multiple CACCC-boxes between -306 and +1 that can bind to Krüppel-like factor 3 (KLF3) transcriptional repressor. We found that increasing amounts of intracellular KLF3 decreased the amount of wee1 mRNA. A promoter reporter assay demonstrated that wee1 promoter activity was repressed by KLF3 overexpression. Elimination of the first and fourth CACCC-boxes suppressed KLF3-governed transcriptional repression. A gel-shift assay demonstrated that KLF3 binds to the first, third, and fourth CACCC-boxes with various strengths. Moreover, KLF3 was suggested to interact with the wee1 regulatory region in a physiological condition. Therefore, we concluded that KLF3 is a transcriptional repressor for wee1 gene. In a previous study, we demonstrated that TBP-like protein (TLP) inhibits wee1 promoter function. In this study, we found that the chromosomal wee1 gene is also down-regulated by KLF3. Since KLF3-repressed wee1 promoter function was further inhibited by TLP overexpression regardless of the inhibition degree of KLF3, we propose that TLP and KLF3 repress wee1 promoter independently.

TATA-binding Protein (TBP)-like Protein Is Engaged in Etoposide-induced Apoptosis through Transcriptional Activation of Human TAp63 Gene.

Accumulating evidence indicates that TBP (TATA-binding protein)-like protein (TLP) contributes to the regulation of stress-mediated cell cycle checkpoint and apoptotic pathways, although its physiological target genes have remained elusive. In the present study, we have demonstrated that human TAp63 is one of the direct transcriptional target genes of TLP. Enforced expression of TLP results in the transcriptional induction of the endogenous TAp63, but not of the other p53 family members such as TAp73 and p53. Consistent with these results, small interference RNA-mediated knockdown led to a significant down-regulation of the endogenous TAp63. Luciferase reporter assay and chromatin immunoprecipitation analysis revealed that the genomic region located at positions -487 to -29, where +1 represents the transcriptional initiation site of TAp63, is required for TLP-dependent transcriptional activation of TAp63 and also TLP is efficiently recruited onto this region. Additionally, cells treated with anti-cancer drug etoposide underwent apoptosis in association with the transcriptional enhancement of TAp63 in a p53-independent manner, and the knockdown of the endogenous TLP reduced etoposide-induced apoptosis through repression of TAp63 expression. Taken together, our present study identifies a TLP-TAp63 pathway that is further implicated in stress-induced apoptosis.

Identification of MAFbx as a myogenin-engaged F-box protein in SCF ubiquitin ligase.

Myogenesis is conducted by transcription factors including MyoD and myogenin. Myogenin is known to be polyubiquitinated by SCF (Skp1/Cullin 1/F-box protein) followed by proteasomal degradation, though the participating F-box protein is remaining unidentified. In this study, we found that myogenin in differentiated myoblasts is destabilized by muscle atrophy-inducing dexamethasone and that MAFbx (muscle atrophy F-box protein) is increased in atrophying myotubes. MAFbx overexpression resulted in MG132-sensitive reduction of myogenin. Myogenin had a MAFbx-recognition motif and interacted with MAFbx. MAFbx activated polyubiquitination of myogenin. The results of this study suggest that MAFbx functions as an F-box protein for ubiquitination of myogenin.

Rapid proteasomal degradation of transcription factor IIB in accordance with F9 cell differentiation.

We found that the levels of all general transcription factors (GTFs) for RNA polymerase II decreased in F9 cells when the cells were subjected to a differentiation procedure. Different from other GTFs, decrease of TFIIB during the differentiation was suppressed by addition of a proteasome inhibitor, MG132. The half-life of TFIIB in the differentiated cells was remarkably reduced compared with that in the undifferentiated cells. Moreover, it was demonstrated that TFIIB is a poly-ubiquitinated protein. Results of this study suggest that components of the transcription machinery decreased in accordance with cell differentiation and that TFIIB is specifically and rapidly degraded by the ubiquitin-proteasome pathway.

Chromosomal position, structure, expression, and requirement of genes for chicken transcription factor IIA.

Transcription factor IIA (TFIIA) is one of the general transcription factors for RNA polymerase II and composed of three subunits, TFIIAalpha, TFIIAbeta and TFIIAgamma. TFIIAalpha and TFIIAbeta are encoded by a single gene (TFIIAalphabeta) and mature through internal cleavage of TFIIAalphabeta. In this study, we found that structures of TFIIAalphabeta and TFIIAgamma are highly homologous with each mammalian counterpart. Exon-intron organizations of the human and chicken TFIIA genes were also homologous. The sequence of the cleavage region of the chicken TFIIAalphabeta precursor protein was fitted to the consensus cleavage recognition site. It was thus demonstrated that TFIIA is conserved in vertebrates. TFIIA proteins are present ubiquitously in chicken tissues. Fluorescent in situ hybridization revealed that TFIIAalphabeta and TFIIAgamma genes are located in chromosome 5 and a mini-chromosome, respectively. We generated semi-knockout chicken DT40 cells for TFIIAalphabeta and TFIIAgamma genes with high homologous recombination efficiencies, whereas we failed to establish double-knockout cells for each gene. It is thought that both genes for TFIIA are required in vertebrates. TFIIA siRNA resulted in deceleration of cell growth rate, suggesting that, consistent with those of knockout assays, TFIIA is associated with cell growth regulation.

TBP-interacting protein 120B (TIP120B)/cullin-associated and neddylation-dissociated 2 (CAND2) inhibits SCF-dependent ubiquitination of myogenin and accelerates myogenic differentiation.

Despite fast protein degradation in muscles, protein concentrations remain constant during differentiation and maintenance of muscle tissues. Myogenin, a basic helix-loop-helix-type myogenic transcription factor, plays a critical role through transcriptional activation in myogenesis as well as muscle maintenance. TBP-interacting protein 120/cullin-associated neddylation-dissociated (TIP120/CAND) is known to bind to cullin and negatively regulate SCF (Skp1-Cullin1-F-box protein) ubiquitin ligase, although its physiological role has not been elucidated. We have identified a muscle-specific isoform of TIP120, named TIP120B/CAND2. In this study, we found that TIP120B is not only induced in association with myogenic differentiation but also actively accelerates the myogenic differentiation of C2C12 cells. Although myogenin is a short lived protein and is degraded by a ubiquitin-proteasome system, TIP120B suppressed its ubiquitination and subsequent degradation of myogenin. TIP120B bound to cullin family proteins, especially Cullin 1 (CUL1), and was associated with SCF complex in cells. It was demonstrated that myogenin was also associated with SCF and that CUL1 small interference RNA treatment inhibited ubiquitination of myogenin and stabilized it. TIP120B was found to break down the SCF-myogenin complex. Consequently suppression of SCF-dependent ubiquitination of myogenin by TIP120B, which leads to stabilization of myogenin, can account for the TIP120B-directed accelerated differentiation of C2C12 cells. TIP120B is proposed to be a novel regulator for myogenesis.

Transcriptional repression of the mouse wee1 gene by TBP-related factor 2.

TBP-related factor 2 (TRF2), one of the TBP family proteins, is involved in various cellular functions through its transcription stimulation activity. We previously reported that TRF2 is involved in reduction of wee1 mRNA in genotoxin-treated chicken cells. In this study, we investigated the role of TRF2 in wee1 gene expression. It was found that wee1 mRNA was decreased in hydroxyurea-treated NIH3T3 cells. Mouse wee1 promoter activity was repressed by TRF2 in mouse and chicken cells. Chromatin immunoprecipitation and plasmid immunoprecipitation analyses revealed that TRF2 is recruited to the wee1 promoter in accordance with the transcriptional repression. A mutant TRF2 that lacks TFIIA-binding capacity lost its repressive function. This mutant was less recruited to the wee1 promoter than was the wild-type one, and provided a decline in promoter-recruited TFIIA. Data in this study suggest that transcription repressive activity of TRF2 to wee1 promoter needs association with the promoter and TFIIA.

TATA-binding protein-related factor 2 is localized in the cytoplasm of mammalian cells and much of it migrates to the nucleus in response to genotoxic agents.

TBP (TATA-binding protein)-related factor 2 (TRF2) regulates transcription during a nuber of cellular processes. We previously demonstrated that it is localized in the cytoplasm and is translocated to the nucleus by DNA-damaging agents. However, the cytoplasmic localization of TRF2 is controversial. In this study, we reconfirmed its cytoplasmic localization in various ways and examined its nuclear migration. Stresses such as heat shock, redox agents, heavy metals, and osmotic shock did not affect localization whereas genotoxins such as methyl methanesulfonate (MMS), cisplatin, etoposide, and hydroxyurea caused it to migrate to the nucleus. Adriamycin, mitomycin C and gamma-rays had no obvious effect. We determined optimal conditions for the nuclear migration. The proportions of cells with nuclei enriched for TRF2 were 25-60% and 5-10% for stressed cells and control cells, respectively. Nuclear translocation was observed after 1 h, 4 h and 12 h for cisplatin, etoposide and MMS and hydroxyurea, respectively. The association of TRF2 with the chromatin and promoter region of the proliferating cell nuclear antigen (PCNA) gene, a putative target of TRF2, was increased by MMS treatment. Thus TRF2 may be involved in genotoxin-induced transcriptional regulation.

Evaluation of the performance of two carbodiimide-based cyanine dyes for detecting changes in mRNA expression with DNA microarrays.

Microarrays have been extensively used to investigate genome-wide expression patterns. Although this technology has been tremendously successful, several practical issues would benefit from improvements in design. Here we describe a novel, efficient labeling methodology that uses carbodiimide-linked cyanine dyes to directly chemically label cDNA derived from mouse total RNA. Using this protocol, it takes only 10 min at 70 degrees C to complete the cDNA labeling reaction. The directly labeled cDNAs can then be hybridized to 70-mer mouse oligonucleotide arrays for expression profiling studies. Microarray analyses indicate that these cDNAs are uniformly labeled and produce higher signal intensities than conventional enzymatic direct labeling methods and comparable signal intensities to those obtained by conventional indirect labeling methods. Furthermore, verification of our microarray data using a reverse transcription PCR (RT-PCR) method indicates good agreement between the two methods. Thus, we conclude that our simplified cyanine-carbodiimide labeling method, which does not rely on the incorporation of modified nucleotides, will provide a reliable, quicker, and potentially cheaper alternative to established labeling techniques for gene expression analyses.

Bombyx Y-box protein BYB facilitates specific DNA interaction of various DNA binding proteins independently of the cold shock domain.

A new member of the Y-box protein family of the silkworm Bombyx mori (BYB) was co-purified with the fibroin gene enhancer-binding protein FMBP-1, and stimulated the binding of FMBP-1 to its cognate DNA element. However, the stimulatory effect was not specific to FMBP-1, BYB also enhancing the binding of mammalian transcription factors OTF2, SP1 and AP2 to their specific binding elements. Besides the above transcription regulatory factors, BYB facilitated the binding of basal transcription factor TBP, and enhanced transcription from the adenovirus 2 major late promoter in a reconstituted transcription system. Moreover, BYB stimulated the reactions of some restriction endonucleases under cold conditions. The C-terminal region of BYB was sufficient for these stimulatory effects, and the highly conserved cold shock domain (CSD) in the N-terminal region was dispensable. GST-pull down experiments showed that the C-terminal region could interact with DNA independently of the CSD. The above results suggest that the C-terminal region of BYB causes the active interaction of various DNA binding proteins with their targets. Such a function of the C-terminal region of BYB may partly explain the functional diversity of Y-box proteins.

Specific interaction with transcription factor IIA and localization of the mammalian TATA-binding protein-like protein (TLP/TRF2/TLF).

TBP-like protein (TLP) is structurally similar to the TATA-binding protein (TBP) and is thought to have a transcriptional regulation function. Although TLP has been found to form a complex with transcription factor IIA (TFIIA), the in vivo functions of TFIIA for TLP are not clear. In this study, we analyzed the interaction between TLP and TFIIA. We determined the biophysical properties for the interaction of TLP with TFIIA. Dissociation constants of TFIIA versus TLP and TFIIA versus TBP were 1.5 and 10 nm, respectively. Moreover, the dissociation rate constant of TLP and TFIIA (1.2 x 10(-4)/m.s was significantly lower than that of TBP (2.1 x 10(-3)/m.s). These results indicate that TLP has a higher affinity to TFIIA than does TBP and that the TLP-TFIIA complex is much more stable than is the TBP-TFIIA complex. We found that TLP forms a dimer and a trimer and that these multimerizations are inhibited by TFIIA. Moreover, TLP mutimers were more stable than a TBP dimer. We determined the amounts of TLPs in the nucleus and cytoplasm of NIH3T3 cells and found that the molecular number of TLP in the nucleus was only 4% of that in the cytoplasm. Immunostaining of cells also revealed cytoplasmic localization of TLP. We established cells that stably express mutant TLP lacking TFIIA binding ability and identified the amino acids of TLP required for TFIIA binding (Ala-32, Leu-33, Asn-37, Arg-52, Lys-53, Lys-78, and Arg-86). Interestingly, the level of TFIIA binding defective mutant TLPs in the nucleus was much higher than that of the wild-type TLP and TFIIA-interactable mutant TLPs. Immunostaining analyses showed consistent results. These results suggest that the TFIIA binding ability of TLP is required for characteristic cytoplasmic localization of TLP. TFIIA may regulate the intracellular molecular state and the function of TLP through its property of binding to TLP.