Diversity of transactivation regions of DMRT1 in vertebrates.

BACKGROUND: Doublesex and mab-3 related transcription factor (DMRT) 1, commonly found in all vertebrates, regulates the transcription of genes involved in the masculinization and maintenance of gonadal somatic cells and/or germline cell development. DMRT1 has a DNA-binding domain called the DM domain and a transcription regulatory region. Unlike the former, there is little knowledge about the latter transcription regulatory region. This study aimed to identify the transcription activation regions of DMRT1 from four species: humans and mice (mammals), leopard geckos (reptiles), and medaka (teleost fish), adding perspectives on evolutionary conservation and diversity. METHODS AND RESULTS: For each species, several expression plasmids of deletion mutants were constructed, and the resultant plasmid and a DMRT1-driven luciferase reporter were co-transfected into cultured cells to measure transactivation ability. The key point of this analysis is that the transactivation ability was normalized by quantifying the expression levels of DMRT1 variants using the HiBiT tag. As a result, two to three transactivation regions were suggested to exist in the C-terminal region of the DM domain in all four species. Among seven regions in DMRT1, the fourth region from the N-terminus contributed to transactivation common to the four species, and the sixth and seventh regions on the C-terminal side differed depending on the species. CONCLUSIONS: These findings indicated that the regions involved in the transactivation ability of DMRT1 could subtly change during evolution, indicating diversity in transactivation domains.

Correlation Between Subgenome-biased DNA Loss and DNA Transposon Activation Following Hybridization in the Allotetraploid Xenopus Frogs.

In certain tetraploid species resulting from interspecific hybridization, one parent's subgenome is known to selectively undergo DNA loss. The molecular mechanisms behind this remain unclear. In our study, we compared the genomes of a standard diploid species with two allotetraploid species from the Xenopus genus, both possessing L (longer) and S (shorter) homoeologous subgenomes. We observed substantial gene losses and intergenic DNA deletions in both the S and L subgenomes of the tetraploid species. Gene losses were around 1,000 to 3,000 for L and 4,000 to 6,000 for S, with especially prominent losses in the S subgenome. Many of these losses likely occurred shortly after interspecific hybridization in both L/S subgenomes. We also deduced frequent large inversions in the S subgenome. Upon reassessing transposon dynamics using updated genome databases, we reaffirmed heightened DNA transposon activity during the hybridization, as previously reported. We next investigated whether S subgenome-biased DNA loss could be correlated with the activation of DNA transposons following hybridization. Notably, distinct patterns were observed in the dynamics of DNA transposons between the L and S subgenomes. Several DNA transposon subfamilies correlated positively with DNA deletions in the S subgenome and negatively in the L subgenome. Based on these results, we propose a model that, upon and after hybridization between two related diploid Xenopus species, the mixture of their genomes resulted in the derepression of DNA transposons, especially in the S subgenome, leading to selective DNA loss in the S subgenome.

Promoter generation for the chimeric sex-determining gene dm-W in Xenopus frogs.

Many sex-determining genes (SDGs) were generated as neofunctionalized genes through duplication and/or mutation of gonadal formation-related genes. We previously identified dm-W as an SDG in the African clawed frog Xenopus laevis and found that a partial duplication of the masculinization gene dmrt1 created the neofunctionalized dm-W after allotetraploidization by interspecific hybridization. The allotetraploid Xenopus species have two dmrt1 genes, dmrt1.L and dmrt1.S. Xenopus laevis dm-W has four exons: two dmrt1.S-derived exons (exons 2 and 3) and two other exons (noncoding exon 1 and exon 4). Our recent work revealed that exon 4 originated from a DNA transposon, hAT-10. Here, to clarify when and how the noncoding exon 1 and its coexisting promoter evolved during the establishment of dm-W after allotetraploidization, we newly determined nucleotide sequences of the dm-W promoter region from two other allotetraploid species, X. largeni and X. petersii, and performed an evolutionary analysis. We found that dm-W acquired a new exon 1 and TATA-type promoter in the common ancestor of the three allotetraploid Xenopus species, resulting in the deletion of the dmrt1.S-derived TATA-less promoter. In addition, we demonstrated that the TATA box contributes to dm-W promoter activity in cultured cells. Collectively, these findings suggest that this novel TATA-type promoter was important for the establishment of dm-W as a sex-determining gene, followed by the degeneration of the preexisting promoter.

Heat shock factor 1 induces a short burst of transcription of the clock gene Per2 during interbout arousal in mammalian hibernation.

During winter hibernation, a diverse range of small mammals can enter prolonged torpor. They spend the nonhibernation season as a homeotherm but the hibernation season as a heterotherm. In the hibernation season, chipmunks (Tamias asiaticus) cycle regularly between 5 and 6 days-long deep torpor with a body temperature (Tb) of 5 to 7 °C and interbout arousal of ∼20 h, during which, their Tb returns to the normothermic level. Here, we investigated Per2 expression in the liver to elucidate the regulation of the peripheral circadian clock in a mammalian hibernator. In the nonhibernation season, as in mice, heat shock factor 1, activated by elevated Tb during the wake period, activated Per2 transcription in the liver, which contributed to synchronizing the peripheral circadian clock to the Tb rhythm. In the hibernation season, we determined that the Per2 mRNA was at low levels during deep torpor, but Per2 transcription was transiently activated by heat shock factor 1, which was activated by elevated Tb during interbout arousal. Nevertheless, we found that the mRNA from the core clock gene Bmal1 exhibited arrhythmic expression during interbout arousal. Since circadian rhythmicity is dependent on negative feedback loops involving the clock genes, these results suggest that the peripheral circadian clock in the liver is nonfunctional in the hibernation season.

Neofunctionalization of a Noncoding Portion of a DNA Transposon in the Coding Region of the Chimerical Sex-Determining Gene dm-W in Xenopus Frogs.

Most vertebrate sex-determining genes (SDGs) emerge as neofunctionalized genes through duplication and/or mutation of ancestral genes that are involved with sexual differentiation. We previously demonstrated dm-W to be the SDG in the African clawed frog Xenopus laevis and found that a portion of this gene emerged from the masculinization gene dmrt1 after allotetraploidization by interspecific hybridization between two ancestral species around 17-18 Ma. dm-W has four exons consisting of a noncoding exon 1, dmrt1-derived exons 2 and 3, and an orphan exon 4 (Ex4) of unknown origin that includes coding sequence (CDS). In this study, we searched for the origin of Ex4 and investigated the function of the CDS of this exon. We found that the Ex4-CDS is derived from a noncoding portion of the hAT-10 family of DNA transposon. Evolutionary analysis of transposons and determination of the Ex4 sequences from three other species indicated that Ex4 was generated before the diversification of most or all extant allotetraploid species in subgenus Xenopus, during which time we hypothesize that transposase activity of this hAT superfamily was active. Using DNA-protein binding and transfection assays, we further demonstrate that the Ex4-encoded amino acid sequence increases the DNA-binding ability and transrepression activity of DM-W. These findings suggest that the conversion of the noncoding transposon sequence to the CDS of dm-W contributed to neofunctionalization of a new chimeric SDG in the ancestor of the allotetraploid Xenopus species, offering new insights into de novo origin and functional evolution of chimerical genes.

Formulation of Bicelles Based on Lecithin-Nonionic Surfactant Mixtures.

Bicelles have been intensively studied for use as drug delivery carriers and in biological studies, but their preparation with low-cost materials and via a simple process would allow their use for other purposes as well. Herein, bicelles were prepared through a semi-spontaneous method using a mixture of hydrogenated soybean lecithin (SL) and a nonionic surfactant, polyoxyethylene cholesteryl ether (ChEO10), and then we investigated the effect of composition and temperature on the structure of bicelles, which is important to design tailored systems. As the fraction of ChEO10 (XC) was increased, a bimodal particle size distribution with a small particle size of several tens of nanometers and a large particle size of several hundred nanometers was obtained, and only small particles were observed when XC ≥ 0.6, suggesting the formation of significant structure transition (liposomes to bicelles). The small-angle neutron scattering (SANS) spectrum for these particles fitted a core-shell bicelle model, providing further evidence of bicelle formation. A transition from a monomodal to a bimodal size distribution occurred as the temperature was increased, with this transition taking place at lower temperatures when higher SL-ChEO10 concentrations were used. SANS showed that this temperature-dependent size change was reversible, suggesting the SL-ChEO10 bicelles were stable against temperature, hence making them suitable for several applications.

Circadian transcription factor HSF1 regulates differential HSP70 gene transcription during the arousal-torpor cycle in mammalian hibernation.

Mammalian hibernation is a seasonal phenomenon. The hibernation season consists of torpor periods with a reduced body temperature (Tb), interrupted by euthermic arousal periods (interbout arousal, IBA). The physiological changes associated with hibernation are assumed to be under genetic control. However, the molecular mechanisms that govern hibernation-associated gene regulation are still unclear. We found that HSP70 transcription is upregulated in the liver of nonhibernating (summer-active) chipmunks compared with hibernating (winter-torpid) ones. In parallel, HSF1, the major transcription factor for HSP70 expression, is abundant in the liver-cell nuclei of nonhibernating chipmunks, and disappears from the nuclei of hibernating ones. Moreover, during IBA, HSF1 reappears in the nuclei and drives HSP70 transcription. In mouse liver, HSF1 is regulated by the daily Tb rhythm, and acts as a circadian transcription factor. Taken together, chipmunks similarly use the Tb rhythm to regulate gene expression via HSF1 during the torpor-arousal cycle in the hibernation season.

Epigenetic regulation of hibernation-associated HP-20 and HP-27 gene transcription in chipmunk liver.

The chipmunk hibernation-related proteins (HPs) HP-20 and HP-27 are components of a 140-kDa complex that dramatically decreases in the blood during hibernation. The HP-20 and HP-27 genes are expressed specifically in the liver and are downregulated in hibernating chipmunks. Hibernation-associated physiological changes are assumed to be under genetic control. Therefore, to elucidate the molecular mechanisms of hibernation, here we examined the mechanisms behind the altered HP-20 and HP-27 gene expression in nonhibernating versus hibernating chipmunks. Chromatin immunoprecipitation (ChIP) analyses revealed that histone H3 on the HP-20 and HP-27 gene promoters was highly acetylated at lysine (K) 9 and K14 and highly trimethylated at K4 in the liver of nonhibernating chipmunks, while these active histone modifications were nearly absent in hibernating chipmunks. Furthermore, histone acetyltransferases and a histone methyltransferase were associated with the HP-20 and HP-27 gene promoters primarily in nonhibernating chipmunks. Consistent with a previous finding that HNF-1 and USF can activate HP-20 and HP-27 gene transcription by binding to the proximal promoter region, ChIP-quantitative PCR (qPCR) analyses revealed that significantly less HNF-1 and USF were bound to these gene promoters in hibernating than in nonhibernating chipmunks. These findings collectively indicated that the hibernation-associated HP-20 and HP-27 gene expression is epigenetically regulated at the transcriptional level by the binding of HNF-1 and USF to their proximal promoters, and that histone modification has a key role in hibernation-associated transcriptional regulation.

HNF-4 participates in the hibernation-associated transcriptional regulation of the chipmunk hibernation-related protein gene.

The chipmunk hibernation-related protein 25 (HP-25) is involved in the circannual control of hibernation in the brain. The liver-specific expression of the HP-25 gene is repressed in hibernating chipmunks under the control of endogenous circannual rhythms. However, the molecular mechanisms that differentially regulate the HP-25 gene during the nonhibernation and hibernation seasons are unknown. Here, we show that the hibernation-associated HP-25 expression is regulated epigenetically. Chromatin immunoprecipitation analyses revealed that significantly less hepatocyte nuclear receptor HNF-4 bound to the HP-25 gene promoter in the liver of hibernating chipmunks compared to nonhibernating chipmunks. Concurrently in the hibernating chipmunks, coactivators were dissociated from the promoter, and active transcription histone marks on the HP-25 gene promoter were lost. On the other hand, small heterodimer partner (SHP) expression was upregulated in the liver of hibernating chipmunks. Overexpressing SHP in primary hepatocytes prepared from nonhibernating chipmunks caused HNF-4 to dissociate from the HP-25 gene promoter, and reduced the HP-25 mRNA level. These results suggest that hibernation-related HP-25 expression is epigenetically regulated by the binding of HNF-4 to the HP-25 promoter, and that this binding might be modulated by SHP in hibernating chipmunks.

BCL11B gene heterozygosity causes weight loss accompanied by increased energy consumption, but not defective adipogenesis, in mice.

BCL11B is a zinc finger-type transcription factor that regulates the development of the white adipose tissue (WAT), skin, central nervous system, and immune system. BCL11B is required for proper adipocyte differentiation, and BCL11B-/- embryos at E19.5 have very low amounts of the subcutaneous WAT. Here, we demonstrated that BCL11B+/- mice have lower body weight than BCL11B+/+ mice, whereas the expression of adipogenic marker genes in the WAT was comparable between BCL11B+/+ and BCL11B+/- mice. Histological analysis indicated that BCL11B+/- mice fed a high-fat diet have much smaller white adipocytes and lipid droplets in the WAT and liver, respectively. In addition, BCL11B+/- mice had increased energy consumption under both standard and high-fat diets. Thus, this study identifies BCL11B as a regulator of energy metabolism, and it is unlikely that BCL11B functions in the WAT contribute to energy metabolism in BCL11B+/- mice.

Identification of BCL11B as a regulator of adipogenesis.

The differentiation of preadipocytes into adipocytes is controlled by several transcription factors, including peroxisome proliferator-activated receptor γ (PPARγ) and CCAAT/enhancer-binding protein α (C/EBPα), which are known as master regulators of adipogenesis. BCL11B is a zinc finger-type transcription factor that regulates the development of the skin and central nervous and immune systems. Here, we found that BCL11B was expressed in the white adipose tissue (WAT), particularly the subcutaneous WAT and that BCL11B(-/-) mice had a reduced amount of subcutaneous WAT. During adipogenesis, BCL11B expression transiently increased in 3T3-L1 preadipocytes and mouse embryonic fibroblasts (MEFs). The ability for adipogenesis was reduced in BCL11B knockdown 3T3-L1 cells and BCL11B(-/-) MEFs, whereas the ability for osteoblastogenesis was unaffected in BCL11B(-/-) MEFs. Luciferase reporter gene assays revealed that BCL11B stimulated C/EBPß activity. Furthermore, the expression of downstream genes of the Wnt/ß-catenin signaling pathway was not suppressed in BCL11B(-/-) MEFs during adipogenesis. Thus, this study identifies BCL11B as a novel regulator of adipogenesis, which works, at least in part, by stimulating C/EBPß activity and suppressing the Wnt/ß-catenin signaling pathway.

Disruption of Th2a and Th2b genes causes defects in spermatogenesis.

The variant histones TH2A and TH2B are abundant in the testis, but their roles in spermatogenesis remain elusive. Here, we show that male mutant mice lacking both Th2a and Th2b genes were sterile, with few sperm in the epididymis. In the mutant testis, the lack of TH2B was compensated for by overexpression of H2B, whereas overexpression of H2A was not observed, indicating a decrease in the total histone level. Mutant mice exhibited two defects: incomplete release of cohesin at interkinesis after meiosis I and histone replacement during spermiogenesis. In the mutant testis, secondary spermatocytes at interkinesis accumulated and cohesin was not released normally, suggesting that the retained cohesion of sister chromatids delayed the subsequent entry into meiosis II. In addition, impaired chromatin incorporation of TNP2 and degenerated spermatids were observed in the mutant testis. These results suggest that a loss of TH2A and TH2B function in chromatin dynamics or a decrease in the total histone levels causes defects in both cohesin release and histone replacement during spermatogenesis.

Histone variants enriched in oocytes enhance reprogramming to induced pluripotent stem cells.

Expression of Oct3/4, Sox2, Klf4, and c-Myc (OSKM) can reprogram somatic cells into induced pluripotent stem cells (iPSCs). Somatic cell nuclear transfer (SCNT) can also be used for reprogramming, suggesting that factors present in oocytes could potentially augment OSKM-mediated induction of pluripotency. Here, we report that two histone variants, TH2A and TH2B, which are highly expressed in oocytes and contribute to activation of the paternal genome after fertilization, enhance OSKM-dependent generation of iPSCs and can induce reprogramming with Klf4 and Oct3/4 alone. TH2A and TH2B are enriched on the X chromosome during the reprogramming process, and their expression in somatic cells increases the DNase I sensitivity of chromatin. In addition, Xist deficiency, which was reported to enhance SCNT reprogramming efficiency, stimulates iPSC generation using TH2A/TH2B in conjunction with OSKM, but not OSKM alone. Thus, TH2A/TH2B may enhance reprogramming by introducing processes that normally operate in zygotes and during SCNT.

Use of solid phase microextraction (SPME) for profiling the volatile metabolites produced by Glomerella cingulata.

The profile of volatile organic compounds (VOCs) released from Glomerella cingulata using solid phase microextraction (SPME) with different fibers, Polydimethylsiloxane (PDMS), Polydimethylsiloxane/Divinylbenzene (PDMS/DVB), Carboxen/Polydimethylsiloxane (CAR/PDMS) and Divinylbenzene/Carboxen/Polydimethylsiloxane (DVB/CAR/PDMS), was investigated. C4-C6 aliphatic alcohols were the predominant fraction of VOCs isolated by CAR/PDMS fiber. Sesquiterpene hydrocarbons represented 20.3% of VOCs isolated by PDMS fiber. During the growth phase, Ochracin was produced in the large majority of VOCs. 3-Methylbutanol and phenylethyl alcohol were found in the log phase of it. Alcohols were found in cultures of higher age, while sesquiterpenes were found to be characteristic of initial growth stage of G. cingulata.

USF is involved in the transcriptional regulation of the chipmunk HP-25 gene.

The hibernation-specific HP-25 gene is expressed specifically in the liver of the chipmunk, a hibernating species of the squirrel family, and exists as a pseudogene in the tree squirrel, a nonhibernating species. Our previous studies have revealed two positively acting transcriptional regulatory regions in the 5'-flanking region of the chipmunk HP-25 gene, one from -260 to -80 and another from -80 to -59, and a pivotal role for hepatocyte nuclear factor-4 (HNF-4), which binds to the proximal regulatory region, in HP-25's liver-specific transcription. A database search for transcription factor binding sites in the distal regulatory region indicated the presence of two potential binding sites for upstream stimulatory factor (USF): one between -161 and -156 and the other between -143 and -138. In an electrophoretic mobility shift assay (EMSA), in vitro-translated USF bound only to the sequence from -143 to -138. USF did not bind the corresponding sequence of the tree squirrel HP-25 gene, which has two base substitutions. Transient transfection studies in COS-7 cells showed that USF could activate the transcription of the chipmunk HP-25 gene, and that tree squirrel-type base substitutions in the USF-binding site aborted the transactivation by USF. By chromatin immunoprecipitation (ChIP) analysis, we confirmed that USF bound to the promoter region of the HP-25 gene in the chipmunk liver, and not in the kidney or heart. These results indicate that USF is involved in the transcriptional regulation of the chipmunk HP-25 gene in the liver, and that the base substitutions in the USF-binding site contribute to the lack of HP-25 gene expression in the tree squirrel.

CpG methylation at the USF-binding site is important for the liver-specific transcription of the chipmunk HP-27 gene.

The chipmunk hibernation-specific HP-27 gene is expressed specifically in the liver and has a CpG-poor promoter. To reveal how the liver-specific transcription of the HP-27 gene is regulated, we performed yeast one-hybrid screening of a chipmunk liver cDNA library. A 5'-flanking sequence of the HP-27 gene, extending from -170 to -140 and containing an E-box (5'-CACGTG-3'), is essential for the liver-specific transcription of HP-27. We used this sequence as bait and found that a ubiquitously expressed transcription factor, USF (upstream stimulatory factor), bound to the E-box. In COS-7 cells, USF activated transcription from the HP-27 gene promoter. We then used bisulphite genomic sequencing to analyse the methylation status of the four CpG dinucleotides that lie in the 5'-flanking sequence of the HP-27 gene up to -450, to investigate how the ubiquitously expressed USF activates transcription of the HP-27 gene only in the liver, while its transcription is repressed elsewhere. The only difference in methylation in the tissues tested was in the CpG dinucleotide in the USF-binding site, which was hypomethylated in the liver, but highly methylated in the kidney and heart. The specific methylation of the CpG dinucleotide at the USF-binding site impeded both the binding of USF and its transcriptional activation of the HP-27 gene. Chromatin immunoprecipitation using anti-USF antibodies revealed that USF bound to the HP-27 gene promoter in the liver, but not in the kidney or heart. Thus CpG methylation at the USF-binding site functions in establishing and maintaining tissue-specific transcription from the CpG-poor HP-27 gene promoter.

Five new nortropane alkaloids and six new amino acids from the fruit of Morus alba LINNE growing in Turkey.

Investigation of the constituents of the fruits of Morus alba LINNE (Moraceae) afforded five new nortropane alkaloids (1-5) along with nor-psi-tropine (6) and six new amino acids, morusimic acids A-F (7-12). The structures of the new compounds were determined to be 2alpha,3beta-dihydroxynortropane (1), 2beta,3beta-dihydroxynortropane (2), 2alpha,3beta,6exo-trihydroxynortropane (3), 2alpha,3beta,4alpha-rihydroxynortropane (4), 3beta,6exo-dihydroxynortropane (5), (3R)-3-hydroxy-12-[(1S,4S)-4-[(1S)-1-hydroxyethyl]-pyrrolidin-1-yll-dodecanoic acid-3-O-beta-D-glucopyranoside (7), (3R)-3-hydroxy-12-[(1S,4S)-4-[(1S)-1-hydroxyethyl]-pyrrolidin-1-yll-dodecanoic acid (8), (3R)-3-hydroxy-12-1(1R,4R,5S)-4-hydroxy-5-methyl-piperidin-1-yll-dodecanoic acid-3-O-beta-D-glucopyranoside (9), (3R)-3-hydroxy-12-[(1R,4R,5S)-4-hydroxy-5-methyl-piperidin-1-yll-dodecanoic acid (10), (3R)-3-hydroxy-12-[(1R,4R,5S)-4-hydroxy-5-hydroxymethyl-piperidin-1-yl]-dodecanoic acid-3-O-beta-D-glucopyranoside (11), and (3R)-3-hydroxy-12-[(1R,4S,5S)-4-hydroxy-5-methyl-piperidin-1-yl]-dodecanoic acid (12) on the basis of spectral and chemical data.