Your search keyword '"Xia LQ"' showing total 4 results

1. A cotton (Gossypium hirsutum) DRE-binding transcription factor gene, GhDREB, confers enhanced tolerance to drought, high salt, and freezing stresses in transgenic wheat.

Author

Gao SQ, Chen M, Xia LQ, Xiu HJ, Xu ZS, Li LC, Zhao CP, Cheng XG, and Ma YZ

Subjects

Amino Acid Sequence, Base Sequence, Electrophoretic Mobility Shift Assay, Gossypium drug effects, Gossypium growth & development, Molecular Sequence Data, Plant Proteins chemistry, Plant Proteins genetics, Plant Proteins metabolism, Plants, Genetically Modified drug effects, Plants, Genetically Modified growth & development, Reverse Transcriptase Polymerase Chain Reaction, Sequence Alignment, Triticum drug effects, Triticum growth & development, Droughts, Freezing, Gossypium genetics, Plant Proteins physiology, Plants, Genetically Modified genetics, Sodium Chloride pharmacology, Triticum genetics

Abstract

A cotton (G. hirsutum L.) dehydration responsive element binding protein gene, GhDREB, which encodes a 153 amino acid protein containing a conserved AP2/EREBP domain, was isolated from the cDNA library of cotton cv. Simian 3 by a yeast one-hybrid system. RNA blot analysis showed that the GhDREB gene was induced in cotton seedlings by drought, high salt and cold stresses. An electrophoretic mobility shift assay (EMSA) indicated that the GhDREB protein bound specifically to the DRE core element (A/GCCGAC) in vitro. Two expression vectors containing the GhDREB gene with either of the Ubiqutin or rd29A promoters were constructed and transferred into wheat (Triticum aestivum L.) by bombardment. Fifty-eight Ubi::GhDREB and 17 rd29A::GhDREB T(0) plants of Yangmai (36 plants) and Lumai (39 plants) were identified by PCR analysis, respectively. Southern blot and RT-PCR analyses showed that two or three copies of the GhDREB were integrated into the Yangmai 10 genome and were expressed at the transcriptional level, and three or four copies were integrated into the Lumai 23 genome. Functional analysis indicated that the transgenic plants had improved tolerance to drought, high salt, and freezing stresses through accumulating higher levels of soluble sugar and chlorophyll in leaves after stress treatments. No phenotype differences were observed between transgenic plants and their non-transgenic controls. These results indicated that GhDREB might be useful in improving wheat stress tolerance through genetic engineering.

Published

2009

2. Isolation and molecular characterization of the Triticum aestivum L. ethylene-responsive factor 1 (TaERF1) that increases multiple stress tolerance.

Author

Xu ZS, Xia LQ, Chen M, Cheng XG, Zhang RY, Li LC, Zhao YX, Lu Y, Ni ZY, Liu L, Qiu ZG, and Ma YZ

Subjects

Amino Acid Sequence, Arabidopsis genetics, Base Sequence, Cloning, Molecular, Cold Temperature, Gene Expression Regulation, Plant, Mitogen-Activated Protein Kinase 1 metabolism, Molecular Sequence Data, Nuclear Localization Signals chemistry, Phosphorylation, Plant Proteins chemistry, Plant Proteins genetics, Plants, Genetically Modified metabolism, Plants, Genetically Modified microbiology, Sequence Alignment, Sodium Chloride metabolism, Nicotiana genetics, Trans-Activators chemistry, Trans-Activators genetics, Triticum microbiology, Triticum physiology, Plant Proteins metabolism, Trans-Activators metabolism, Triticum metabolism

Abstract

ERF transcription factors play important roles in regulating gene expression under abiotic and biotic stresses. The first member of the ERF gene family in wheat (Triticum aestivum L.) was isolated by screening a drought-induced cDNA library and designated as T. aestivum ethylene-responsive factor 1 (TaERF1), which encoded a putative protein of 355 amino acids with a conserved DNA-binding domain and a conserved N-terminal motif (MCGGAIL). The TaERF1 gene was located on chromosome 7A. Protein interaction assays indicated that TaERF1, with a putative phosphorylation site (TPDITS) in the C-terminal region, was a potential phosphorylation substrate for TaMAPK1 protein kinase. Deletion of the N-terminal motif enhanced the interaction of TaERF1 with TaMAPK1. The predicted TaERF1 protein contained three putative nuclear localization signals (NLSs), and three NLSs modulated synergistically the activity of subcellular localization. As a trans-acting factor, TaERF1 was capable of binding to the GCC-box and CRT/DRE elements in vitro, and of trans-activating reporter gene expression in tobacco (Nicotiana tabacum L.) leaves. Transcription of the TaERF1 gene was induced not only by drought, salinity and low-temperature stresses and exogenous ABA, ethylene and salicylic acid, but also by infection with Blumeria graminis f. sp. tritici. Furthermore, overexpression of TaERF1 activated stress-related genes, including PR and COR/RD genes, under normal growth conditions, and improved pathogen and abiotic stress tolerance in transgenic plants. These results suggested that the TaERF1 gene encodes a GCC-box and CRT/DRE element binding factor that might be involved in multiple stress signal transduction pathways.

Published

2007

3. Isolation and characterization of Viviparous-1 genes in wheat cultivars with distinct ABA sensitivity and pre-harvest sprouting tolerance.

Author

Yang Y, Ma YZ, Xu ZS, Chen XM, He ZH, Yu Z, Wilkinson M, Jones HD, Shewry PR, and Xia LQ

Subjects

Alleles, Alternative Splicing, Base Sequence, Genotype, Molecular Sequence Data, Mutagenesis, Insertional, Plant Proteins chemistry, Plant Proteins metabolism, RNA, Messenger chemistry, RNA, Messenger metabolism, Sequence Alignment, Sequence Analysis, DNA, Sequence Deletion, Triticum drug effects, Triticum physiology, Abscisic Acid pharmacology, Plant Growth Regulators pharmacology, Plant Proteins genetics, Triticum genetics

Abstract

Pre-harvest sprouting (PHS) of wheat reduces the quality and economic value of grain, and increasing PHS tolerance is one of the most important traits in wheat breeding. Two new Vp-1B alleles related to PHS tolerance were identified on the 3BL chromosome of bread wheat and were designated Vp-1Bb and Vp-1Bc. Sequence analysis showed that Vp-1Bb has a 193 bp insertion and Vp-1Bc has a 83 bp deletion located in the third intron region of the Vp-1B gene, and that they shared 95.43% and 97.89% similarity, respectively, with the sequence of AJ400713 (Vp-1Ba) at the nucleotide level. Their sequences were deposited in the GenBank under the accession numbers DQ517493 and DQ517494. Semi-quantitative RT-PCR analysis showed that alternatively spliced transcripts of the Vp-1A, Vp-1B, and Vp-1D homologues were present and there were no differences in the splicing patterns or abundances of Vp-1A and Vp-1D from embryos 35 d after pollination between PHS-tolerant and -susceptible cultivars. Although Vp-1Ba, Vp-1Bb, and Vp-1Bc could each produce a set of transcripts, only one was correctly spliced and had the capacity to encode the full-length VP1 protein and was more highly expressed with Vp-1Bb and Vp-1Bc than with Vp-1Ba. Comparison of the expression patterns of Vp-1Ba, Vp-1Bb, and Vp-1Bc on different days after pollination also revealed that the expression of these genes was developmentally regulated. Furthermore, genotypes with different levels of tolerance to PHS respond differently to ABA exposure and differences in transcript levels of Vp-1Ba, Vp-1Bb, and Vp-1Bc were observed after ABA treatment. The results indicated that insertion or deletion in the third intron region might affect the expression of the Vp-1B gene and its sensitivity to ABA, and thus resistance to PHS.

Published

2007

4. Molecular and biochemical characterization of puroindoline a and b alleles in Chinese landraces and historical cultivars.

Author

Chen F, He ZH, Xia XC, Xia LQ, Zhang XY, Lillemo M, and Morris CF

Subjects

Amino Acid Sequence, Amino Acid Substitution, Arginine metabolism, Base Sequence, Biomarkers, China, DNA, Plant chemistry, DNA, Plant isolation & purification, Electrophoresis, Polyacrylamide Gel, Gene Deletion, Gene Frequency, Genes, Plant, Genetic Variation, Genotype, Molecular Sequence Data, Plant Proteins chemistry, Plant Proteins isolation & purification, Polymorphism, Genetic, Seeds genetics, Sequence Analysis, DNA, Serine metabolism, Species Specificity, Triticum physiology, Alleles, Plant Proteins genetics, Plant Proteins metabolism, Triticum genetics, Triticum metabolism

Abstract

Kernel hardness that is conditioned by puroindoline genes has a profound effect on milling, baking and end-use quality of bread wheat. In this study, 219 landraces and 166 historical cultivars from China and 12 introduced wheats were investigated for their kernel hardness and puroindoline alleles, using molecular and biochemical markers. The results indicated that frequencies of soft, mixed and hard genotypes were 42.7, 24.3, and 33.0%, respectively, in Chinese landraces and 45.2, 13.9, and 40.9% in historical cultivars. The frequencies of PINA null, Pinb-D1b and Pinb-D1p genotypes were 43.8, 12.3, and 39.7%, respectively, in hard wheat of landraces, while 48.5, 36.8, and 14.7%, respectively, in historical hard wheats. A new Pinb-D1 allele, designated Pinb-D1t, was identified in two landraces, Guangtouxianmai and Hongmai from the Guizhou province, with the characterization of a glycine to arginine substitution at position 47 in the coding region of Pinb gene. Surprisingly, a new Pina-D1 allele, designated Pina-D1m, was detected in the landrace Hongheshang, from the Jiangsu province, with the characterization of a proline to serine substitution at position 35 in the coding region of Pina gene; it was the first novel mutation found in bread wheat, resulting in a hard endosperm with PINA expression. Among the PINA null genotypes, an allele designed as Pina-D1l, was detected in five landraces with a cytosine deletion at position 265 in Pina locus; while another novel Pina-D1 allele, designed as Pina-D1n, was identified in six landraces, with the characterization of an amino acid change from tryptophan-43 to a 'stop' codon in the coding region of Pina gene. The study of puroindoline polymorphism in Chinese wheat germplasm could provide useful information for the further understanding of the molecular basis of kernel hardness in bread wheat.

Published

2006