Your search keyword '"Li, Yong-Fang"' showing total 7 results

1. Deciphering the genome of Simplicillium aogashimaense to understand its mechanisms against the wheat powdery mildew fungus Blumeria graminis f. sp. tritici

Author

Zhu, Mo, Duan, Xiao, Cai, Pengkun, Li, Yong-fang, and Qiu, Zongbo

Published

2022

2. Temporal expression study of miRNAs in the crown tissues of winter wheat grown under natural growth conditions

Author

Wang, Menglei, Yang, Chenhui, Wei, Kangning, Zhao, Miao, Shen, Liqiang, Ji, Jie, Wang, Li, Zhang, Daijing, Guo, Junqiang, Zheng, Yun, Yu, Juanjuan, Zhu, Mo, Liu, Haiying, and Li, Yong-Fang

Published

2021

3. An improved method of constructing degradome library suitable for sequencing using Illumina platform

Author

Li, Yong-Fang, Zhao, Miao, Wang, Menglei, Guo, Junqiang, Wang, Li, Ji, Jie, Qiu, Zongbo, Zheng, Yun, and Sunkar, Ramanjulu

Published

2019

4. Comparative transcriptome and translatome analysis in contrasting rice genotypes reveals differential mRNA translation in salt-tolerant Pokkali under salt stress.

Author

Li, Yong-Fang, Zheng, Yun, Vemireddy, Lakshminarayana R., Panda, Sanjib Kumar, Jose, Smitha, Ranjan, Alok, Panda, Piyalee, Govindan, Ganesan, Cui, Junxia, Wei, Kangning, Yaish, Mahmoud W., Naidoo, Gnanambal Charmaine, and Sunkar, Ramanjulu

Subjects

*TRANSCRIPTOMES, *MESSENGER RNA, *SOIL salinity, *SOIL composition, *GENOMES, RICE genetics

Abstract

Background: Soil salinity is one of the primary causes of yield decline in rice. Pokkali (Pok) is a highly salt-tolerant landrace, whereas IR29 is a salt-sensitive but widely cultivated genotype. Comparative analysis of these genotypes may offer a better understanding of the salinity tolerance mechanisms in rice. Although most stress-responsive genes are regulated at the transcriptional level, in many cases, changes at the transcriptional level are not always accompanied with the changes in protein abundance, which suggests that the transcriptome needs to be studied in conjunction with the proteome to link the phenotype of stress tolerance or sensitivity. Published reports have largely underscored the importance of transcriptional regulation during salt stress in these genotypes, but the regulation at the translational level has been rarely studied. Using RNA-Seq, we simultaneously analyzed the transcriptome and translatome from control and salt-exposed Pok and IR29 seedlings to unravel molecular insights into gene regulatory mechanisms that differ between these genotypes. Results: Clear differences were evident at both transcriptional and translational levels between the two genotypes even under the control condition. In response to salt stress, 57 differentially expressed genes (DEGs) were commonly upregulated at both transcriptional and translational levels in both genotypes; the overall number of up/downregulated DEGs in IR29 was comparable at both transcriptional and translational levels, whereas in Pok, the number of upregulated DEGs was considerably higher at the translational level (544 DEGs) than at the transcriptional level (219 DEGs); in contrast, the number of downregulated DEGs (58) was significantly less at the translational level than at the transcriptional level (397 DEGs). These results imply that Pok stabilizes mRNAs and also efficiently loads mRNAs onto polysomes for translation during salt stress. Conclusion: Under salt stress, Pok is more efficient in maintaining cell wall integrity, detoxifying reactive oxygen species (ROS), translocating molecules and maintaining photosynthesis. The present study confirmed the known salt stress-associated genes and also identified a number of putative new salt-responsive genes. Most importantly, the study revealed that the translational regulation under salinity plays an important role in salt-tolerant Pok, but such regulation was less evident in the salt-sensitive IR29. [ABSTRACT FROM AUTHOR]

Published

2018

5. Phased secondary small interfering RNAs in Panax notoginseng.

Author

Chen, Kun, Liu, Li, Zhang, Xiaotuo, Yuan, Yuanyuan, Ren, Shuchao, Guo, Junqiang, Wang, Qingyi, Liao, Peiran, Li, Shipeng, Cui, Xiuming, Li, Yong-Fang, and Zheng, Yun

Subjects

LOCUS (Genetics), SMALL interfering RNA, PANAX, NUCLEOTIDE sequence, MEDICINAL plants, BIOINFORMATICS

Abstract

Background: Recent results demonstrated that either non-coding or coding genes generate phased secondary small interfering RNAs (phasiRNAs) guided by specific miRNAs. Till now, there is no studies for phasiRNAs in Panax notoginseng (Burk.) F.H. Chen (P. notoginseng), an important traditional Chinese herbal medicinal plant species. Methods: Here we performed a genome-wide discovery of phasiRNAs and its host PHAS loci in P. notoginseng by analyzing small RNA sequencing profiles. Degradome sequencing profile was used to identify the trigger miRNAs of these phasiRNAs and potential targets of phasiRNAs. We also used RLM 5'-RACE to validate some of the identified phasiRNA targets. Results: After analyzing 24 small RNA sequencing profiles of P. notoginseng, 204 and 90 PHAS loci that encoded 21 and 24 nucleotide (nt) phasiRNAs, respectively, were identified. Furthermore, we found that phasiRNAs produced from some pentatricopeptide repeat-contain (PPR) genes target another layer of PPR genes as validated by both the degradome sequencing profile and RLM 5'-RACE analysis. We also found that miR171 with 21 nt triggers the generations of 21 nt phasiRNAs from its conserved targets. Conclusions: We validated that some phasiRNAs generated from PPRs and TASL genes are functional by targeting other PPRs in trans. These results provide the first set of PHAS loci and phasiRNAs in P. notoginseng, and enhance our understanding of PHAS in plants. [ABSTRACT FROM AUTHOR]

Published

2018

6. Genome-wide identification of the Phaseolus vulgaris sRNAome using small RNA and degradome sequencing.

Author

Formey D, Iñiguez LP, Peláez P, Li YF, Sunkar R, Sánchez F, Reyes JL, and Hernández G

Subjects

Conserved Sequence, Databases, Genetic, Gene Expression Regulation, Plant, Gene Regulatory Networks, MicroRNAs analysis, MicroRNAs metabolism, Phaseolus metabolism, Phylogeny, Plant Proteins metabolism, RNA, Plant metabolism, RNA, Small Interfering analysis, RNA, Small Interfering metabolism, Phaseolus genetics, Plant Proteins genetics, RNA, Plant analysis, Sequence Analysis, RNA methods

Abstract

Background: MiRNAs and phasiRNAs are negative regulators of gene expression. These small RNAs have been extensively studied in plant model species but only 10 mature microRNAs are present in miRBase version 21, the most used miRNA database, and no phasiRNAs have been identified for the model legume Phaseolus vulgaris. Thanks to the recent availability of the first version of the common bean genome, degradome data and small RNA libraries, we are able to present here a catalog of the microRNAs and phasiRNAs for this organism and, particularly, we suggest new protagonists in the symbiotic nodulation events., Results: We identified a set of 185 mature miRNAs, including 121 previously unpublished sequences, encoded by 307 precursors and distributed in 98 families. Degradome data allowed us to identify a total of 181 targets for these miRNAs. We reveal two regulatory networks involving conserved miRNAs: those known to play crucial roles in the establishment of nodules, and novel miRNAs present only in common bean, suggesting a specific role for these sequences. In addition, we identified 125 loci that potentially produce phased small RNAs, with 47 of them having all the characteristics of being triggered by a total of 31 miRNAs, including 14 new miRNAs identified in this study., Conclusions: We provide here a set of new small RNAs that contribute to the broader knowledge of the sRNAome of Phaseolus vulgaris. Thanks to the identification of the miRNA targets from degradome analysis and the construction of regulatory networks between the mature microRNAs, we present here the probable functional regulation associated with the sRNAome and, particularly, in N2-fixing symbiotic nodules.

Published

2015

7. Transcriptome analysis of heat stress response in switchgrass (Panicum virgatum L.).

Author

Li YF, Wang Y, Tang Y, Kakani VG, and Mahalingam R

Subjects

Gene Expression Regulation, Plant, Heat-Shock Response genetics, Heat-Shock Response physiology, Oryza genetics, Oryza physiology, Panicum physiology, Plant Proteins genetics, Transcriptome, Triticum genetics, Triticum physiology, Panicum genetics

Abstract

Background: Global warming predictions indicate that temperatures will increase by another 2-6°C by the end of this century. High temperature is a major abiotic stress limiting plant growth and productivity in many areas of the world. Switchgrass (Panicum virgatum L.) is a model herbaceous bioenergy crop, due to its rapid growth rate, reliable biomass yield, minimal requirements of water and nutrients, adaptability to grow on marginal lands and widespread distribution throughout North America. The effect of high temperature on switchgrass physiology, cell wall composition and biomass yields has been reported. However, there is void in the knowledge of the molecular responses to heat stress in switchgrass., Results: We conducted long-term heat stress treatment (38°/30°C, day/night, for 50 days) in the switchgrass cultivar Alamo. A significant decrease in the plant height and total biomass was evident in the heat stressed plants compared to controls. Total RNA from control and heat stress samples were used for transcriptome analysis with switchgrass Affymetrix genechips. Following normalization and pre-processing, 5365 probesets were identified as differentially expressed using a 2-fold cutoff. Of these, 2233 probesets (2000 switchgrass unigenes) were up-regulated, and 3132 probesets (2809 unigenes) were down-regulated. Differential expression of 42 randomly selected genes from this list was validated using RT-PCR. Rice orthologs were retrieved for 78.7% of the heat stress responsive switchgrass probesets. Gene ontology (GOs) enrichment analysis using AgriGO program showed that genes related to ATPase regulator, chaperone binding, and protein folding was significantly up-regulated. GOs associated with protein modification, transcription, phosphorus and nitrogen metabolic processes, were significantly down-regulated by heat stress., Conclusions: Plausible connections were identified between the identified GOs, physiological responses and heat response phenotype observed in switchgrass plants. Comparative transcriptome analysis in response to heat stress among four monocots - switchgrass, rice, wheat and maize identified 16 common genes, most of which were associated with protein refolding processes. These core genes will be valuable biomarkers for identifying heat sensitive plant germplasm since they are responsive to both short duration as well as chronic heat stress treatments, and are also expressed in different plant growth stages and tissue types.

Published

2013