Your search keyword '"Liuling Yan"' showing total 8 results

1. A semi-dominant NLR allele causes whole-seedling necrosis in wheat

Author

Brett F. Carver, Lei Lei, Haiyan Jia, Junpeng Deng, Shulin Xue, Ragupathi Nagarajan, Zhengqiang Ma, Shuxia Peng, Tian Li, Liuling Yan, and Min Fan

Subjects

0106 biological sciences, Programmed cell death, Necrosis, Regular Issue, Positional cloning, Physiology, Plant Science, Plant disease resistance, Stem rust, 01 natural sciences, 03 medical and health sciences, Genetics, medicine, Allele, Alleles, Triticum, 030304 developmental biology, Disease Resistance, Plant Diseases, 0303 health sciences, biology, Effector, Point mutation, food and beverages, biology.organism_classification, Molecular biology, Seedlings, medicine.symptom, 010606 plant biology & botany

Abstract

Programmed cell death (PCD) and apoptosis have key functions in development and disease resistance in diverse organisms; however, the induction of necrosis remains poorly understood. Here, we identified a semi-dominant mutant allele that causes the necrotic death of the entire seedling (DES) of wheat (Triticum aestivum L.) in the absence of any pathogen or external stimulus. Positional cloning of the lethal allele mDES1 revealed that this premature death via necrosis was caused by a point mutation from Asp to Asn at amino acid 441 in a nucleotide-binding leucine-rich repeat protein containing nucleotide-binding domain and leucine-rich repeats. The overexpression of mDES1 triggered necrosis and PCD in transgenic plants. However, transgenic wheat harboring truncated wild-type DES1 proteins produced through gene editing that exhibited no significant developmental defects. The point mutation in mDES1 did not cause changes in this protein in the oligomeric state, but mDES1 failed to interact with replication protein A leading to abnormal mitotic cell division. DES1 is an ortholog of Sr35, which recognizes a Puccinia graminis f. sp. tritici stem rust disease effector in wheat, but mDES1 gained function as a direct inducer of plant death. These findings shed light on the intersection of necrosis, apoptosis, and autoimmunity in plants.

Published

2020

2. A semi-dominant NLR allele causes whole-seedling necrosis in wheat.

Author

Haiyan Jia, Shulin Xue, Lei Lei, Min Fan, Shuxia Peng, Tian Li, Nagarajan, Ragupathi, Carver, Brett, Zhengqiang Ma, Junpeng Deng, and Liuling Yan

Published

2021

3. Genetic and Molecular Characterization of the VRN2 Loci in Tetraploid Wheat

Author

G. Tranquilli, Jorge Dubcovsky, Liuling Yan, Chin-Shang Li, and Assaf Distelfeld

Subjects

Genetics, education.field_of_study, Physiology, Population, food and beverages, Locus (genetics), Plant Science, Vernalization, Biology, Genetic variation, Copy-number variation, Allele, Ploidy, education, Gene

Abstract

Winter wheat (Triticum spp.) varieties require long exposures to low temperatures to flower, a process called vernalization. The VRN2 locus includes two completely linked zinc finger-CCT domain genes (ZCCT1 and ZCCT2) that act as flowering repressors down-regulated during vernalization. Deletions or mutations in these two genes result in the elimination of the vernalization requirement in diploid wheat (Triticum monococcum). However, natural allelic variation in these genes has not been described so far in polyploid wheat (tetraploid Triticum turgidum and hexaploid Triticum aestivum). A tetraploid wheat population segregating for both VRN-A2 and VRN-B2 loci facilitated the characterization of different alleles. Comparisons between functional and nonfunctional alleles revealed that both ZCCT1 and ZCCT2 genes are able to confer vernalization requirement and that different ZCCT genes are functional in different genomes. ZCCT1 and ZCCT2 proteins from nonfunctional vrn2 alleles have mutations at arginine amino acids at position 16, 35, or 39 of the CCT domain. These positions are conserved between CCT and HEME ACTIVATOR PROTEIN2 (HAP2) proteins, supporting a model in which the action of CCT domains is mediated by their interactions with HAP2/HAP3/HAP5 complexes. This study also revealed natural variation in gene copy number, including a duplication of the functional ZCCT-B2 gene and deletions or duplications of the complete VRN-B2 locus. Allelic variation at the VRN-B2 locus was associated with a partially dominant effect, which suggests that variation in the number of functional ZCCT genes can be used to expand allelic diversity for heading time in polyploid wheat and, hopefully, improve its adaptation to different environments.

Published

2008

4. Regulation of VRN-1 Vernalization Genes in Normal and Transgenic Polyploid Wheat

Author

Artem Loukoianov, Liuling Yan, Ann E. Blechl, Jorge Dubcovsky, and Alexandra Sanchez

Subjects

Genetics, biology, Physiology, fungi, food and beverages, Plant Science, Vernalization, Meristem, biology.organism_classification, Polyploid, Transcription (biology), Arabidopsis, Allele, Ploidy, Gene

Abstract

Vernalization, the requirement of a long exposure to low temperatures to accelerate flowering, is an essential adaptation of plants to cold winters. The vernalization gene VRN-1 plays an important role in this process in diploid (Triticum monococcum) and polyploid wheat (Triticum aestivum). We have recently shown that the diploid wheat VRN-Am1 gene was similar to the Arabidopsis (Arabidopsis thaliana L. Heynh.) APETALA1 meristem identity gene. We also showed that dominant Vrn-Am1 alleles were the result of loss-of-function mutations in regulatory regions recognized by a VRN-1 repressor, likely VRN-2. This model predicts that only the dominant Vrn-1 allele will be transcribed in lines carrying both recessive and dominant alleles. Here, we confirm this prediction in young isogenic lines of hexaploid wheat carrying different dominant Vrn-A1, Vrn-B1, and Vrn-D1 alleles, and also in heterozygous VRN-1 diploid wheat plants. However, a few weeks later, transcripts from the recessive alleles were also detected in both the polyploid and heterozygous diploid spring plants. Transcription of the recessive alleles was preceded by a reduction of the transcript levels of VRN-2. These results suggest that the dominant Vrn-1 allele or a gene regulated by VRN-1 down-regulates the VRN-2 repressor facilitating the transcription of the recessive alleles in unvernalized plants. We also show here that the level of VRN-1 transcripts in early developmental stages is critical for flowering initiation. A reduction of VRN-1 transcript levels by RNA interference delayed apex transition to the reproductive stage, increased the number of leaves, and delayed heading time by 2 to 3 weeks. We hypothesize that the coordinated transcription of dominant and recessive alleles may contribute to an earlier attainment of the VRN-1 transcript level threshold required to trigger flowering initiation in polyploid wheat.

Published

2005

5. Comparative Sequence Analysis of Colinear Barley and Rice Bacterial Artificial Chromosomes

Author

Wusirika Ramakrishna, Carlos S. Busso, Jeffrey L. Bennetzen, Bryan A. Shiloff, Liuling Yan, Jorge Dubcovsky, and Phillip SanMiguel

Subjects

Chromosomes, Artificial, Bacterial, Physiology, Sequence analysis, Restriction Mapping, Molecular Sequence Data, Plant Biology & Botany, Arabidopsis, Plant Science, Biology, Genome, Chromosomes, Homology (biology), Gene mapping, Genetics, Bacterial artificial chromosome, Oryza sativa, Agricultural and Veterinary Sciences, Structural gene, Bacterial, food and beverages, Hordeum, Oryza, Sequence Analysis, DNA, DNA, Plant, Biological Sciences, Artificial, Hordeum vulgare, Sequence Analysis, Genome, Plant, Research Article

Abstract

Colinearity of a large region from barley (Hordeum vulgare) chromosome 5H and rice (Oryza sativa) chromosome 3 has been demonstrated by mapping of several common restriction fragment-length polymorphism clones on both regions. One of these clones, WG644, was hybridized to rice and barley bacterial artificial chromosome (BAC) libraries to select homologous clones. One BAC from each species with the largest overlapping segment was selected by fingerprinting and blot hybridization with three additional restriction fragment-length polymorphism clones. The complete barley BAC 635P2 and a 50-kb segment of the rice BAC 36I5 were completely sequenced. A comparison of the rice and barley DNA sequences revealed the presence of four conserved regions, containing four predicted genes. The four genes are in the same orientation in rice, but the second gene is in inverted orientation in barley. The fourth gene is duplicated in tandem in barley but not in rice. Comparison of the homeologous barley and rice sequences assisted the gene identification process and helped determine individual gene structures. General gene structure (exon number, size, and location) was largely conserved between rice and barley and to a lesser extent with homologous genes in Arabidopsis. Colinearity of these four genes is not conserved in Arabidopsis compared with the two grass species. Extensive similarity was not found between the rice and barley sequences other than within the exons of the structural genes, and short stretches of homology in the promoters and 3′ untranslated regions. The larger distances between the first three genes in barley compared with rice are explained by the insertion of different transposable retroelements.

Published

2001

6. The Localization and Expression of the Class II Starch Synthases of Wheat1

Author

Xiusheng Chu, Matthew K. Morell, Peter R. Shewry, Sandra J. Hey, Behjat Kosar-Hashemi, Zhongyi Li, Liuling Yan, Rudi Appels, Sadequr Rahman, B. C. Clarke, Grégory Mouille, and Johnathan A. Napier

Subjects

biology, Physiology, Starch, cDNA library, food and beverages, Plant Science, Isozyme, Endosperm, Nucleic acid thermodynamics, chemistry.chemical_compound, Biochemistry, chemistry, Complementary DNA, Gene expression, Genetics, biology.protein, Starch synthase

Abstract

The starch granules of hexaploid wheat (Triticum aestivum) contain a group of three proteins known as SGP-1 (starch granule protein-1) proteins, which have apparent molecular masses of 100, 108, and 115 kD. The nature and role of these proteins has not been defined previously. We demonstrate that these polypeptides are starch synthases that are present in both the starch granule and the soluble fraction at the early stages of wheat endosperm development, but that are exclusively granule bound at mid and late endosperm development. A partial cDNA clone encoding a fragment of the 100-kD protein was obtained by screening a wheat endosperm cDNA expression library using monoclonal antibodies. Three classes of cDNA were subsequently isolated from a wheat endosperm cDNA library by nucleic acid hybridization and were shown to encode the 100-, 108-, and 115-kD proteins. The cDNA sequences are highly homologous to class II starch synthases and have the highest homology with the maize SSIIa (starch synthase IIa) gene. mRNA for the SGP-1 proteins was detected in the leaf, pre-anthesis florets, and endosperm of wheat and is highly expressed in the leaf and in the grain during the early to mid stages of development. We discuss the roles of the SGP-1 proteins in starch biosynthesis in wheat.

Published

1999

7. Genetic and Molecular Characterization of the VRN2 Loci in Tetraploid Wheat.

Author

Distelfeld, Assaf, Tranquilli, Gabriela, Chengxia Li, Liuling Yan, and Dubcovsky, Jorge

Subjects

WHEAT varieties, VERNALIZATION, WINTER wheat, PLANT growth, GERMINATION

Abstract

Winter wheat (Triticuni spp.) varieties require long exposures to low temperatures to flower, a process called vernalization. The VRN2 locus includes two completely linked zinc finger-CCT domain genes (ZCCTTI. and ZCCT2) that act as flowering repressors down-regulated during vernalization. Deletions or mutations in these two genes result in the elimination of the vernalization requirement in diploid wheat (Triticuin monococcurn). However, natural allelic variation in these genes has not been described so far in polyploid wheat (tetraploid Triticuni turgidum and hexaploid Triticum aestivum). A tetraploid wheat population segregating for both VRN-A2 and VRN-B2 loci facilitated the characterization of different alleles. Comparisons between functional and nonfunctional alleles revealed that both ZCCT1 and ZCCT2 genes are able to confer vernalization requirement and that different ZCCT genes are functional in different genomes. ZCCTI and ZCCT2 proteins from nonfunctional vrn2 alleles have mutations at arginine amino acids at position 16, 35, or 39 of the CCT domain. These positions are conserved between CCT and HEME ACTIVATOR PROTEIN2 (HAP2) proteins, supporting a model in which the action of CCT domains is mediated by their interactions with HAP2/HAP3/HAP5 complexes. This study also revealed natural variation in gene copy number, including a duplication of the functional ZCCT-B2 gene and deletions or duplications of the complete VRN-B2 locus. Allelic variation at the VRN-B2 locus was associated with a partially dominant effect, which suggests that variation in the number of functional ZCCT genes can be used to expand allelic diversity for heading time in polyploid wheat and, hopefully, improve its adaptation to different environments. [ABSTRACT FROM AUTHOR]

Published

2009

8. Regulation of VRN-1 Vernalization Genes in Normal and Transgenic Polyploid Wheat.

Author

Loukoianov, Artem, Liuling Yan, Blechl, Ann, Sanchez, Alexandra, and Dubcovsky, Jorge

Subjects

VERNALIZATION, FORCING (Plants), EFFECT of temperature on plants, FLOWERING of plants, FROST resistance of plants, ARABIDOPSIS

Abstract

Vernalization, the requirement of a long exposure to low temperatures to accelerate flowering, is an essential adaptation of plants to cold winters. The vernalization gene VRN-1 plays an important role in this process in diploid (Triticum monococcum) and polyploid wheat (Triticum aestivum). We have recently shown that the diploid wheat VRNAm1 gene was similar to the Arabidopsis (Arabidopsis thaliana L. Heynh.) APETALA1 meristem identity gene. We also showed that dominant Vrn-Am1 alleles were the result of loss-of-function mutations in regulatory regions recognized by a VRN-1 repressor, likely VRN-2. This model predicts that only the dominant Vrn-1 allele will be transcribed in lines carrying both recessive and dominant alleles. Here, we confirm this prediction in young isogenic lines of hexaploid wheat carrying different dominant Vrn-A1, Vrn-B1, and Vrn-D1 alleles, and also in heterozygous VRN-1 diploid wheat plants. However, a few weeks later, transcripts from the recessive alleles were also detected in both the polyploid and heterozygous diploid spring plants. Transcription of the recessive alleles was preceded by a reduction of the transcript levels of VRN-2. These results suggest that the dominant Vrn-1 allele or a gene regulated by VRN-1 down-regulates the VRN-2 repressor facilitating the transcription of the recessive alleles in unvernalized plants. We also show here that the level of VRN-1 transcripts in early developmental stages is critical for flowering initiation. A reduction of VRN-1 transcript levels by RNA interference delayed apex transition to the reproductive stage, increased the number of leaves, and delayed heading time by 2 to 3 weeks. We hypothesize that the coordinated transcription of dominant and recessive alleles may contribute to an earlier attainment of the VRN-1 transcript level threshold required to trigger flowering initiation in polyploid wheat. [ABSTRACT FROM AUTHOR]

Published

2005