The molecular and genetic characterization of the MADS box transcription factor {\it Drosophila\/} MEF2

The myocyte enhancer factor (MEF)-2 family of transcription factors has been implicated in the regulation of muscle transcription in vertebrates, but the precise position of these regulators within the genetic hierarchy leading to myogenesis is unclear. The MEF2 proteins bind to a conserved A/T-rich DNA sequence present in numerous muscle-specific genes, and they are expressed in the cells of the developing somites and in the embryonic heart at the onset of muscle formation in mammals. The MEF2 genes belong to the MADS box family of transcription factors, which control specific programs of gene expression in species ranging from yeast to humans. Each MEF2 family member contains two highly conserved protein motifs, the MADS domain and the MEF2-specific domain, which together provide the MEF2 factors with their unique DNA binding and dimerization properties. In an effort to further define the function of the MEF2 proteins, and to evaluate the degree of conservation shared among these factors and the phylogenetic pathways that they regulate, we sought to identify MEF2 family members in other species. In Drosophila, a homolog of the vertebrate MEF2 genes was identified and termed D-mef2. The D-MEF2 protein binds to the consensus MEF2 element and can activate transcription through tandem copies of that site. During Drosophila embryogenesis, D-MEF2 is specific to the mesoderm germ layer of the developing embryo and becomes expressed in all muscle cell types within the embryo. The role of D-mef2 in Drosophila embryogenesis was examined by generating a loss-of-function mutation in the D-mef2 gene. In embryos homozygous for this mutant allele, somatic, cardiac, and visceral muscles fail to differentiate, but precursors of these myogenic lineages are normally specified and positioned. These results demonstrate that different muscle cell types share a common myogenic differentiation program controlled by MEF2 and suggest that this program has been conserved from Drosophila to mammals. ^

Regulation of XMyoDa transcription by the binding of XMEF2A to the TATA box

MEF2 is a $\underline{\rm m}$yocyte-specific $\underline{\rm e}$nhancer-binding $\underline{\rm f}$actor that binds a conserved DNA sequence, CTA(A/T)$\sb4$TAG. A MEF2 binding site in the XMyoDa promoter overlaps with the TATA box and is required for muscle specific expression. To examine the potential role of MEF2 in the regulation of MyoD transcription during early development, the appearance of MEF2 binding activity in developing Xenopus embryos was analyzed with the electrophoretic mobility shift assay. Two genes were isolated from a X. Laevis stage 24 cDNA library that encode factors that bind the XMyoDa TFIID/MEF2 site. Both genes are highly homologous to each other, belong to the MADS ($\underline{\rm M}$CM1-$\underline{\rm A}$rg80-agamous-$\underline{\rm d}$eficiens-$\underline{\rm S}$RF) protein family, and most highly related to the mammalian MEF2A gene, hence they are designated as XMEF2A1 and XMEF2A2. Proteins encoded by both cDNAs form specific complexes with the MEF2 binding site and show the same binding specificity as the endogenous MEF2 binding activity. XMEF2A transcripts accumulate preferentially in developing somites after the appearance of XMyoD transcripts. XMEF2 protein begins to accumulate in somites at tailbud stages. Transcriptional activation of XMyoD promoter by XMEF2A required only the MADS box and MEF2-specific domain when XMEF2A is bound at the TATA box. However, a different downstream transactivation domain was required when XMEF2A activates transcription through binding to multiple upstream sites. These results suggest that different activation mechanisms are involved, depending on where the factor is bound. Mutations in several basic amino acid clusters in the MADS box inhibit DNA binding suggesting these amino acids are essential for DNA binding. Mutation of Thr-20 and Ser-36 to the negatively charged amino acid residue, aspartic acid, abolish DNA binding. XMEF2A activity may be regulated by phosphorylation of these amino acids. A dominant negative mutant was made by mutating one of the basic amino acid clusters and deleting the downstream transactivation domain. In vivo roles of MEF2 in the regulation of MyoD transcription were investigated by overexpression of wild type MEF2 and dominant negative mutant of XMEF2A in animal caps and assaying for the effects on the level of expression of MyoD genes. Overexpression of MEF2 activates the transcription of endogenous MyoD gene family while expression of a dominant negative mutant reduces the level of transcription of XMRF4 and myogenin genes. These results suggest that MEF2 is downstream of MyoD and Myf5 and that MEF2 is involved in maintaining and amplifying expression of MyoD and Myf5. MEF2 is upstream of MRF4 and myogenin and plays a role in activating their expression. ^

Phosphorylation in the regulation of muscle-specific transcription

The contents of this dissertation include studies on the mechanisms by which FGF and growth factor down-stream kinases inactivate myogenin; characterization of myogenin phosphorylation and its role in regulation of myogenin activity; analysis the C-terminal transcriptional activation domain of myogenin; studies on the nuclear localization of myogenin and characterization of proteins that interact with PKC.^ Activation of muscle transcription by the MyoD family requires their heterodimerization with ubiquitous bHLH proteins such as the E2A gene products E12 and E47. I have shown that dimerization with E2A products potentiates phosphorylation of myogenin at serine 43 in its amino-terminus and serine 170 in the carboxyl-terminal transcription activation domains. Mutations of these sites resulted in enhanced transcriptional activity of myogenin, suggesting that their phosphorylation diminishes myogenin's transcriptional activity. Consistent with the role of phosphorylation at serine 170, analysis of the carboxyl-terminal transcriptional activation domain by deletion has revealed a stretch of residues from 157 to 170 which functions as a negative element for myogenin activity.^ In addition to inducing phosphorylation of myogenin, E12 also localizes myogenin to the nucleus. The DNA binding and dimerization mutants of myogenin show various deficiencies in nuclear localization. Cotransfection of E12 with the DNA binding mutants, but not a dimerization mutant, greatly enhances their nuclear binding. These data suggest that the nuclear localization signal is located in the DNA binding region and myogenin can also be nuclear localized by virtue of dimerizing with a nuclear protein.^ FGF is one of the most potent inhibitors of myogenesis and activates many down-stream pathways to exert its functions. One of these pathway is the MAP kinase pathway. Studies have shown that Raf-1 and Erk-1 kinase inactivate transactivation by myogenin and E proteins independent of DNA binding. The other is the PKC pathway. In transfected cells, FGF induces phosphorylation of thr-87 that maps to the previously identified PKC sites in the DNA binding domain of myogenin. Myogenin mutant T-N87 could resist the inhibition directed to the bHLH domain by FGF, suggesting that FGF inactivates myogenin by inducing phosphorylation of this site. In C2 myotubes, where FGF receptors are lost, the phosphatase inhibitor, okadaic acid, and phorbal ester PdBu, can also induce the phosphorylation of thr-87. This result supports the previous observation and suggests that in myotubes, other mechanisms, such as innervation, may inactivate myogenin through PKC induced phosphorylation.^ Many functions of PKC have been well documented, yet, little is known about the activators or effectors of PKC or proteins that mediate PKC nuclear localizations. Identification of PKC binding proteins will help to understand the molecular mechanism of PKC function. Two proteins that interact with the C kinase (PICKS) have been characterized, PICK-1 and PICK-2. PICK1 interacts with two conserved regions in the catalytic domain of PKC. It is localized to the perinuclear region and is phosphorylated in response to PKC activation. PICK2 is a novel protein with homology to the heat shock protein family. It interacts extensively with the catalytic domain of PKC and is localized in the cytoplasm in a punctate pattern. PICK1 and PICK2 may play important roles in mediating the actions of PKC. ^

Functional characterization of transcription factor USF

USF, Upstream Stimulatory Factor, is a family of ubiquitous transcription factors that contain highly conserved basic helix-loop-helix leucine zipper DNA binding domains and recognize the core DNA sequence CACGTG. In human and mouse, two members of the USF family, USF1 and USF2, encoded by two different genes, contribute to the USF activity. In order to gain insights into the mechanisms by which USFs function as transcriptional activators, different approaches were used to map the domains of USF2 responsible for nuclear localization and transcriptional activation. Two stretches of amino acids, one in the basic region of the DNA binding domain, the other in a highly conserved N-terminal region, were found to direct nuclear localization independently of one another. Two distinct activation domains were also identified. The first one, located in the conserved N-terminal region that overlaps the C-terminal nuclear localization signal, functioned only in the presence of an initiator element in the promoter of the reporter. The second, in a nonconserved region, activated transcription in the absence of an initiator element or when fused to a heterologous DNA binding domain. These results suggest that USF2 functions in different promoter contexts by selectively utilizing different activation domains.^ The deletion analysis of USF2 also identified two dominant negative mutants of USF, one lacking the activation domain, the other lacking the basic domain. The latter proved useful for testing the direct involvement of USFs in the transcriptional activation mediated by the viral protein IE62.^ To investigate the biological function of USFs, foci and colony formation assays were used to study the growth regulation by USFs. It was found that USFs had a strong antagonistic effect on cellular transformation mediated by the bHLH/LZ protein Myc. This effect required the DNA binding activity of either USF 1 or USF2. Moreover, USF2, but not USF1 or other mutants of USFs, was also found to have strong inhibitory effect on the cellular transformation by E1a and on the growth of HeLa cells. These results demonstrate that USFs could potentially regulate growth through two mechanisms, one by antagonizing the function of Myc in cellular transformation, the other by mediating a more general growth inhibitory effect. ^

The role of the amino terminus of Bacillus subtilis sigmaK in transcription initiation

The sigma (σ) subunit of eubacterial RNA polymerase (RNAP) is required for specific recognition of promoter DNA sequences and transcription initiation. Regulation of bacterial gene expression can be achieved by modulating a factor activity. The Bacillus subtilis sporulation a σ factor, σ K, controls gene expression of the late sporulation regulon. σ K is synthesized as an inactive precursor protein, pro-σ K, with a 20 amino acid pro sequence. Proteolytic processing of the pro sequence produces the active form, σK, which is able to bind to the core subunits of RNAP to direct gene expression. Thus, the pro sequence renders σK inactive in vivo. After processing, the amino terminus of σK consists of region 1.2, which is conserved among various σ factors. To understand the role of the amino terminus of σK, namely the pro sequence and region 1.2, mutagenesis of both regions was pursued. NH 2-terminal truncations of pro-σK were constructed to address how the pro sequence silences σK activity. The work described here shows that the pro sequence inhibits the ability of σ K to associate with the core subunits and that a deletion of only six amino acids of the pro sequence is sufficient to activate pro-σ K for DNA binding and transcription initiation to levels similar to σ K. Additionally, site directed mutagenesis was used to obtain single amino acid substitutions in region 1.2 to address the role of region 1.2 in σ K transcriptional activity. Two mutations were isolated, converting a lysine (K) to an alanine (A) at position three, and an asparagine (N) to a tyrosine (Y) at position five, both of which alter the efficiency of transcription initiation by RNAP containing the mutant σKs. Surprisingly, σ KK3A increased transcript production when compared to wild type. This increase is due to improvement in DNA affinity and increased stability of RNAP-DNA promoter open complexes. σKN5Y showed a decrease in transcription activity that is related to defects in the ability of RNAP to make the transition from the closed to open RNAP-DNA complex. Results of both the pro sequence and region 1.2 analyses indicate that the amino terminus of σK is important for transcription activity and this work adds to the increasing body of evidence that the amino termini of many σ factors modulate transcription initiation by RNAP. ^

The role of conserved region 1 of Escherichia coli sigma-70 in transcription initiation

The sigma (σ) subunit of eubacterial RNA polymerase is essential for initiation of transcription at promoter sites. σ factor directs the RNA polymerase core subunits ( a2bb′ ) to the promoter consensus elements and thereby confers selectivity for transcription initiation. The N-terminal domain (region 1.1) of Escherichia coli σ70 has been shown to inhibit DNA binding by the C-terminal DNA recognition domains when σ is separated from the core subunits. Since DNA recognition by RNA polymerase is the first step in transcription, it seemed plausible that region 1 might also influence initiation processes subsesquent to DNA binding. This study explores the functional roles of regions 1.1 and 1.2 of σ70 in transcription initiation. Analysis in vitro of the transcriptional properties of a series of N-terminally truncated σ70 derivates revealed a critical role for region 1.1 at several key stages of initiation. Deletion of the first 75 to 100 amino acids of σ70 (region 1.1) resulted in both a slow rate of transition from a closed promoter complex to a DNA-strand-separated open complex, as well as a reduced efficiency of transition from the open complex to a transcriptionally active open complex. These effects were partially reversed by addition of a polypeptide containing region 1.1 in trans. Therefore, region 1.1 not only modulates DNA binding but is important for efficient transcription initiation, once a closed complex has formed. A deletion of the first 133 amino acids which removes both regions 1.1 and 1.2 resulted in arrest of initiation at the earliest closed complex, suggesting that region 1.2 is required for open complex formation. Mutagenesis of region 1.1 uncovered a mechanistically important role for isoleucine at position 53 (I53). Substitution of I53 with alanine created a σ factor that associated with the core subunits to form holoenzyme, but the holoenzyme was severely deficient for promoter binding. The I53A phenotype was suppressed in vivo by truncation of five amino acids from the C-terminus of σ 70. These observations are consistent with a model in which σ 70I53A fails to undergo a critical conformational change upon association with the core subunits, which is needed to expose the DNA-binding domains and confer promoter recognition capability upon holoenzyme. To understand the basis of the autoinhibitory properties of the σ70 N-terminal domain, in the absence of core RNA polymerase, a preliminary physical assessment of the interdomain interactions within the σ70 subunit was launched. Results support a model in which N-terminal amino acids are in close proximity to residues in the C-terminus of the σ 70 polypeptide. ^

Transcription factor SEF: Purification and functional characterization

Cytokine-induced transcription of the serum amyloid A3 (SAA3) gene promoter requires a transcriptional enhancer that contains three functional elements: two C/EBP-binding sites and a third site that interacts with a constitutively expressed transcription factor, SAA3 enhancer factor (SEF). Deletion or site-specific mutations in the SEF-binding site drastically reduced SAA3 promoter activity, strongly suggesting that SEF is important in SAA3 promoter function. To further elucidate its role in the regulation of the SAA3 gene, we purified SEF from HeLa cell nuclear extracts to near homogeneity by using conventional liquid chromatography and DNA-affinity chromatography. Ultraviolet cross-linking and Southwestern experiments indicated that SEF consisted of a single polypeptide with an apparent molecular mass of 65 kDa. Protein sequencing, oligonucleotide competition and antibody supershift experiments identified SEF as transcription factor LBP-1c/CP2/LSF. Cotransfection of SEF expression plasmid with SAA3-luciferase reporter resulted in 3- to 5-fold activation of SAA3 promoter. Interestingly, when SEF-transfected cells were treated with either conditioned medium (CM) or interleukin (IL) 1, the SAA3 promoter was synergistically activated in a dose-dependent manner. Furthermore, when SEF-binding site was mutated, the response of SAA3 promoter to IL-1 or CM stimulation was abolished or drastically decreased, suggesting that SEF may functionally cooperate with an IL-1-inducible transcription factor. Indeed, our functional studies showed that NFκB is a key transcription factor that mediates the IL-1-induced expression of SAA3 gene, and that SEF can synergize with NFκBp65 to activate SAA3 promoter. By coimmunoprecipitation experiments, we found that SEF could specifically interact with NFκBp65, and that the association of these two factors was enhanced upon IL-1 and CM stimulation. This suggests that the molecular basis for the functional synergy between SEF and NFκB may be due to the ability of SEF to physically interact with NPκB. In addition to its interaction with SEF, NFκB-dependent activation also requires the weak κB site in the C element and its interaction with C/EBP. Besides its role in regulating SAA3 gene expression, we provide evidence that SEF could also bind in a sequence-specific manner to the promoters of α2-macroglobulin, Aα fibrinogen, and 6–16 genes and to an intronic enhancer of the human Wilm's tumor 1 gene, suggesting a functional role in the regulation of these genes. By coimmunoprecipitation experiments, we determined that SEF could specifically associate with both Stat3 and Stat2 upon cytokine stimulation. To examine the functional roles of such interactions, we evaluated the effects of SEF on the transcriptional regulation of two reporter genes: Aα fibrinogen and 6–16, which are IL-6- and interferon-α-responsive, respectively. Our results showed that cotransfection of SEF expression plasmid can activate the expression of Aα fibrinogen gene and 6–16 gene. Moreover, SEF can dramatically enhance the interferon-α-induced expression of 6–16 gene and IL-6-induced expression of Aα fibrinogen gene, suggesting that SEF may functionally cooperate with ISGF3 and Stat3 to mediate interferon-α and IL-6 signaling. ^ Our findings that SEF can interact with multiple cytokine-inducible transcription factors to mediate the expression of target genes open a new avenue of investigation of cooperative transcriptional regulation of gene expression, and should further our understanding of differential gene expression in response to a specific stimulus. In summary, our data provide evidence that SEF can mediate the signaling of different cytokines by interacting with various cytokine-inducible transcription factors. ^

Digital multitext editions from scratch to electronic performance. Transcription and collation routines transformed in a flexible database system

The poster demonstrates the preparatory steps of a digital multi-text edition that are abstracted from the experiences made in the Parzival Project, based at the University of Bern, the Berlin-Brandenburg Academy of Sciences and the University of Erlangen. This edition of Wolfram von Eschenbach’s German Grail novel, written shortly after 1200 and transmitted during several centuries in ca. hundred witnesses, has now been completed by more than a half of the textual corpus. As the text is transmitted in medieval manuscripts the witnesses have to be transcribed according to specific encoding rules. The transcriptions then are collated following certain ideas and concepts of how the transmission process could have developed. The transcriptions and collations finally have to be transferred to a digital edition that allows the users to explore the characteristics of single witnesses as well as the history of a text, which is delivered in variants and in different versions. A dynamically organized database offering various components and adapted to the needs of diverse user-profiles is nowadays the right tool for this purpose.

Digital multi-text editions from scratch to electronic performance. Transcription and collation routines transformed in a flexible database system

The poster demonstrates the preparatory steps of a digital multi-text edition that are abstracted from the experiences made in the Parzival Project, based at the University of Bern, the Berlin-Brandenburg Academy of Sciences and the University of Erlangen. This edition of Wolfram von Eschenbach’s German Grail novel, written shortly after 1200 and transmitted during several centuries in ca. hundred witnesses, has now been completed by more than a half of the textual corpus.

Helicobacter pylori Inhibits Dendritic Cell Maturation via Interleukin-10-Mediated Activation of the Signal Transducer and Activator of Transcription 3 Pathway.

Helicobacter pylori infects the human gastric mucosa causing a chronic infection that is the primary risk factor for gastric cancer development. Recent studies demonstrate that H. pylori promotes tolerogenic dendritic cell (DC) development indicating that this bacterium evades the host immune response. However, the signaling pathways involved in modulating DC activation during infection remain unclear. Here, we report that H. pylori infection activated the signal transducer and activator of transcription 3 (STAT3) pathway in murine bone marrow-derived DCs (BMDCs) and splenic DCs isolated ex vivo. Isogenic cagA-, cagE-, vacA- and urease-mutants exhibited levels of phosphoSTAT3 that were comparable to in the wild-type (WT) parent strain. H. pylori-infected BMDCs produced increased immunosuppressive IL-10, which activated STAT3 in an autocrine/paracrine fashion. Neutralization of IL-10 prevented H. pylori-mediated STAT3 activation in both BMDCs and splenic DCs. In addition, anti-IL-10 treatment of infected H. pylori-BMDCs was associated with increased CD86 and MHC II expression and enhanced proinflammatory IL-1β cytokine secretion. Finally, increased CD86 and MHC II expression was detected in H. pylori-infected STAT3 knockout DCs when compared to WT controls. Together, these results demonstrate that H. pylori infection induces IL-10 secretion in DCs, which activates STAT3, thereby modulating DC maturation and reducing IL-1β secretion. These findings identify a host molecular mechanism by which H. pylori can manipulate the innate immune response to potentially favor chronic infection and promote carcinogenesis. © 2014 S. Karger AG, Basel.

Suprasellar chordoid neoplasm with expression of thyroid transcription factor 1: evidence that chordoid glioma of the third ventricle and pituicytoma may form part of a spectrum of lineage-related tumors of the basal forebrain.

Chordoid glioma of the third ventricle is a rare neuroepithelial tumor characterized by a unique histomorphology and exclusive association with the suprasellar/third ventricular compartment. Variously interpreted as either astrocytic- or ependymal-like, and speculatively ascribed to the lamina terminalis/subcommissural organ, its histogenesis remains, nevertheless, unsettled. Here, we report on a suprasellar chordoid glioma occurring in a 52-year-old man. Although displaying otherwise typical morphological features, the tumor was notable for expression of thyroid transcription factor 1, a marker of tumors of pituicytic origin in the context of the sellar region. We furthermore found overlapping immunoprofiles of this example of chordoid glioma and pituicytic tumors (pituicytoma and spindle cell oncocytoma), respectively. Specifically, phosphorylated ribosomal protein S6, a marker of mTOR pathway activation, was expressed in both groups. Based on these findings, we suggest that chordoid glioma and pituicytic tumors may form part of a spectrum of lineage-related neoplasms of the basal forebrain.