Molecular Characterization and Expression Analysis of TaZFP15, a C_2H_2-Type Zinc Finger Transcription Factor Gene in Wheat (Triticum aestivum L.)

Based on sequencing of part clones in a root subtractive cDNA library, an expressed sequence tag （EST） sharing high similarity to a rice C2H2 zinc finger transcription factor （ZFP15） was obtained in wheat. Through bioinformatics approach, the wheat C2H2-type ZFP gene referred to TaZFP15 has been identified and characterized. As a full-length cDNA of 670 bp, TaZFP15 has an open reading frame of 408 bp and encodes a 135-aa polypeptide. TaZFP15 contains two C2H2 zinc finger domains and each one has a conserved motif QALGGH. The typical L-box, generally identified in the C2H2 type transcription factors, has also been found in TaZFP15. Phylogenetic analysis suggested that TaZFP15 shares high similarities with rice ZFP15 （GenBank accession no. AY286473）, maize ZFP （GenBank accession no. NM_001159094） and a subset of other zinc-finger transcription factor genes in plant species. The expression of TaZFP15 was up-regulated by starved-Pi stress, showing a pattern to be gradually elevated along with the progression of the Pi-stress in a 23-h treatment regime. Similarly, the transcripts of TaZFP15 in roots were also induced by nitrogen deficiency, and abiotic stresses of drought and salinity. No responses of TaZFP15 were detected in roots to nutrition deficiencies of P, Zn, and Ca, and the external treatment of abscisic acid （ABA）. TaZFP15 could be specifically amplified in genome A, B, and D, and without variability in the sequences, suggesting that TaZFP15 has multi-copies in the homologous hexaploid species. Transgenic analysis in tobacco revealed that up-regulation of TaZFP15 could significantly improve plant dry mass accumulation via increasing the plant phosphorus acquisition capacity under Pi-deficiency condition. The results suggested that TaZFP15 is involved in mediation of signal transductions of diverse external stresses.

Myocardin-related transcription factor A cooperates with brahmarelated gene 1 to activate P-selectin transcription

Expression of P-selectin in injured or activated endothelia cells serves as a permissive step towards leukocyte recruitment and perpetuation of inflammation in the pathogenesis of atherosclerosis.P-selectin can be induced by pro-inflammatory stimuli via the transcription factor NF-κB,but the epigenetic mechanisms remain incompletely understood.Previously we reported that myocardin-related transcription factor A（MRTF-A）mediates the transactivation of a slew of adhesion molecules by oxidized low-density lipoprotein（oxLDL）,likely through a crosstalk with brahma-related gene 1（BRGl）,a chromatin remodeling protein.Here,we show that MRTF-A was both sufficient and necessary for the transactivation of P-selectin gene in endothelial cells treated with TNF-α.Depletion of MRTF-A using small interfering RNA（siRNA）abrogated the binding of BRGl on the P-selectin promoter.Overexpression of BRG1 up-regulated the activity of P-selectin promoter activity while BRGl knockdown attenuated P-selectin expression.Finally,BRGl silencing suppressed the accumulation of acetylated histone H3 and methylated histone H3K4,and altered the binding of NF-κB on the P-selectin promoter.Therefore,our data demonstrate an essential role for MRTF-A and BRGl in P-selectin transactivation in endothelial cells.

Genome-wide analyses on transcription factors and their potential microRNA regulators involved in maize male fertility

Anther development is a programmed biological process crucial to plant male reproduction. Genomewide analyses on the functions of transcriptional factor(TF) genes and their microRNA(miRNA) regulators contributing to anther development have not been comprehensively performed in maize. Here, using published RNA-Seq and small RNA-Seq(sRNA-Seq) data from maize anthers at ten developmental stages in three genic male-sterility(GMS) mutants(ocl4, mac1, and ms23) and wild type W23, as well as newly sequenced maize anther transcriptomes of ms7-6007 and lob30 GMS mutants and their WT lines, we analyzed and found 1079 stage-differentially expressed(stage-DE) TF genes that can be grouped into six(premeiotic, meiotic, postmeiotic, premeiotic-meiotic, premeiotic-postmeiotic, and meiotic-postmeiotic clusters) expression clusters. Functional enrichment combined with cytological and physiological analyses revealed specific functions of genes in each expression cluster. In addition, 118 stage-DE miRNAs and99 miRNA-TF gene pairs were identified in maize anthers. Further analyses revealed the regulatory roles of zma-miR319 and zma-miR159 as well as ZmMs7 and ZmLOB30 on ZmGAMYB expression. Moreover,ZmGAMYB and its paralog ZmGAMYB-2 were demonstrated as novel maize GMS genes by CRISPR/Cas9 knockout analysis. These results extend our understanding on the functions of miRNA-TF gene regulatory pairs and GMS TF genes contributing to male fertility in plants.

Expression pattern and function analyses of the MADS thranscription factor genes in wheat(Triticum aestivum L.) under phosphorusstarvation condition

supported by the National Natural Science Foundation of China （31201674 and 31371618）;the National Transgenic Major Program, China （2011ZX08008）

Constitutively Expressed αB—Crystallin in Heat Schock Transcription Factor 1 Knockout Mice Myocardium

Objective-To investigate the effects of heat shock transcription factor 1) gene on the constitutivety expressed αB-CrystaUin (aBC) in mice myocardium. Methods-The expression levels of constitutive aBC in HSF1 knockout (hsf1 - /- ) and HSFl wild type (As/1 + /+) mice myocardium were evaluated by western blot and immunohistochemistry. Results : The αBC levels in hsfl -/- and hsfl +/+ were 68. 42±4. 16, 100. 00±7. 58, respectively (P<0. 05, cytoso-lic fraction) , and 20. 53±1. 01, 37. 55±1. 91, respectively (P<0. 05, pellet fraction). The aBC signals decreased significantly in hsfl -/- myocardium when compared with those in hsfl +/+ myocardium stained with fluorescence immunohistochemistry. Conclusion-HSF1 is an important, but not the only factor, which mediates the constitutively expressed aBC.

Over-Expression of ICE1 Gene in Transgenic Rice Improves Cold Tolerance

ICE1, an Arabidopsis thaliana transcription factor gene, was cloned by RT-PCR and successfully transformed into rice variety Kenjiandao 10 by the Agrobacterium-mediated transformation method. PCR amplification and Southern blot analysis indicated that ICE1 had been integrated into rice genome. Compared with the non-transgenic plants, the transgenic plants exhibited high resistance to hygromycin B and were consistent with the Mendelian inheritance of a single copy of the transgenic ICE1. Under the low temperature stress, the transgenic plants showed the lower mortality rate and the increased proline content. These results suggest that the Arabidopsis ICE1 is functional in rice and the over-expression of ICE1 improves the tolerance to cold stress in rice.

Epidemiology and molecular genetics of congenital cataracts

Congenital cataract is a crystallin severe blinding disease and genetic factors in disease development are important. Crystallin growth is under a combination of genes and their products in time and space to complete the coordination role of the guidance. Congenital cataract-related genes, included crystallin protein gene (CRYAA, CRYAB, CRYBA1/A3, CRYBA4, CRYBB1, CRYBB2, CRYBB3, CRYGC, CRYGD, CRYGS), gap junction channel protein gene (GJA1, GJA3, GJA8), membrane protein gene (GJA3, GJA8, MIP, LIM2), cytoskeletal protein gene (BF-SP2), transcription factor genes (HSF4, MAF, PITX3, PAX6), ferritin light chain gene (FTL), fibroblast growth factor (FGF) and so on. Currently, there are about 39 genetic loci isolated to which primary cataracts have been mapped, although the number is constantly increasing and depends to some extent on definition. We summarized the recent advances on epidemiology and genetic locations of congenital cataract in this review.

Studies on Cloning and Transformation of CBF1 Gene of Maize Grass

[Objective]It is revealed whether the similar maize transcriptional activator in CBF1 gene is regulatory cold resistance gene to lay the foundation for breeding new transgenic Forage Maize Varieties with high cold resistance ability.[Methods]In the present paper,the transcriptional factor gene CBF1 was Successfully cloned by PCR from the leaves of Arabidopsis.The sequence was preliminarily analyzed and plant expression vector was constructed.Then with agrobacterium-mediated transgene technique,CBF1 gene was introduced into maize SAUMZ1.[Results]PCR assay revealed that the CBF1 gene was integrated in the maize grass SAUMZ1 genome.Under different low temperature treatment,the relative electrolyte leakage percentage of transgenic plant was lower than Control.[Conclusion] The results showed that the cold-resistance of maize grass SAUMZ1 enhanced after transforming CBF1 gene.

Transfer DREB into Lolium perenne L. to improve its drought tolerance

A method of Agrobacterium tumefaciens mediated transformation for perennial ryegrass was developed using the calli of ryegrass derived from mature enrbryos. The calli were inoculated with a disarmed A. tumefaciens strain EHA105 harboring binary vector p2328. Vector p2328 contained transcription factor DREB1B and neomycin phosphotransferase （npt H） genes which were driven by promoters of rd29B and CaMV35S, respectively. The inoculated calli were selected on paromomycin- or kanamycin-containing media till the established plants being transferred to soil. Six tmnsgenic plants with DREB1B had been obtained from perennial ryegrass strain Tove. PCR and Southern-blotting showed that npt Ⅱ and DREBIB genes were integrated in perennial ryegrass genome. Stress treatment confirmed that transgenic plants with higher drought tolerance were obtained.

Identification of WRKY Transcription Factors Related to Saikosaponin Biosynthesis in Adventitious Roots of Bupleurum chinense

Objective To identify the genes of WRKY transcription factors（TFs） from roots of Bupleurum chinense and genes that potentially regulate saikosaponin（SS） biosynthesis.Methods Firstly,the subfamily cluster analysis was mainly based on Arabidopsis thaliana WRKYs for 27 putative WRKY TFs selected from previous transcriptome sequencing data.Secondly,qPCR was used to screen such genes of WRKY TFs that could be induced by NaCI and PEG6000 in adventitious roots of B.chinense.Meanwhile,saikosaponins（SSs） in treated adventitious roots were determined by HPLC.The roots were collected at 0,2,4,8,12,24,48,and 72 h after treatments,and 120 h only for PEG.Finally,the tissue-specific expression was analyzed on screened genes by qPCR.Results The 27 genes were grouped into three categories：There were nine in Group Ⅰ,15 in Group Ⅱ,and two in Group Ⅲ.Four genes of WRKYTFs,BCWRKY6,BCWRKY16,BCWRKY32,and BCWRKY35 were obviously induced by NaCI in adventitious roots of B.chinense,while only BCWRKY32 was induced by PEG.The content of SSs increased at different levels in NaCI and PEG6000 treatment.Three genes including BCWRKY6,BCWRKY32,and BCWRKY35,expressed most in roots,were similar to the accumulation pattern of SS.Conclusion The three WRKY genes,BCWRKY6,BCWRKY32,and BCWRKY35,may be involved in the biosynthesis of SS.

Genetics of congenital heart defects in DiGeorge syndrome

Background Di George syndrome（DGS） is the most common microdeletion syndrome in humans and a disorder caused by a defect in chromosome 22. Almost 80% of DGS patients manifest congenital heart defects（CHD）, which are highly variable and severe. However, the genetics of CHD in DGS remain elusive. This review concludes that the TBX1 gene plays a critical role in cardiovascular defects, involving many additional genes, such as Six1, Eya1, Fgf8, Fox, and Shh. Concerning the variable manifestations of CHD in DGS,additional modifiers have been shown of involvement, such as Wnt, MOZ, micro RNAs, VEGF, and CRK.Knowledge of the genetics underlying CHD in DGS has the potential to early detection and treatment of this disease.