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Guanghui Chen - One of the best experts on this subject based on the ideXlab platform.
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transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
BMC Genomics, 2020Co-Authors: Zhibo Zhou, Yake Yi, Guanghui ChenAbstract:BACKGROUND: Node is the central organ of transferring nutrients and ions in plants. Cadmium (Cd) induced crop pollution threatens the food safety. Breeding of low Cd accumulation cultivar is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 (low Cd accumulation cultivar) and Yuzhenxiang (high Cd accumulation cultivar). RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. RESULTS: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang, and node I had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4535 DEGs and 70 miRNAs between the two cultivars. Most genesrelated to the "transporter activity", such as OsIRT1, OsNramp5, OsVIT2, OsNRT1.5A, and OsABCC1, play roles in blocking the upward transport of Cd. Among the genes related to "response to stimulus", we identified OsHSP70 and OsHSFA2d/B2c in Xiangwanxian No. 12, but not in Yuzhenxiang, were all down-regulated by Cd stimulus. The up-regulation of miRNAs (osa-miR528 and osa-miR408) in Xiangwanxian No. 12 played a potent role in lowering Cd accumulation via down regulating the expression of candidate genes, such as bZIP, ERF, MYB, SnRK1 and HSPs. CONCLUSIONS: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang. Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar. MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs, to play a role in Cd stress response.
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Transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
2019Co-Authors: Guanghui Chen, Zhibo Zhou, Yake YiAbstract:Abstract Background: Node is the central organ of transferring nutrients and ions in plants. Cadmium (Cd) induced crop pollution threatens the food safety. Breeding of low Cd accumulation cultivar is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 (low Cd accumulation cultivar) and Yuzhenxiang (high Cd accumulation cultivar). RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. Results: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang , and node Ⅰ had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4,535 DEGs and 70 miRNAs between the two cultivars. Most genes related to the “transporter activity”, such as OsIRT1 , OsNramp5, OsVIT2 , OsNRT1.5A, and OsABCC1 , play roles in blocking the upward transport of Cd. Among the genes related to “response to stimulus”, we identified OsHSP70 and OsHSFA2d/B2c in Xiangwanxian No. 12 , but not in Yuzhenxiang , were all down-regulated by Cd stimulus. The up-regulation of miRNAs ( osa-miR528 and osa-miR408 ) in Xiangwanxian No. 12 played a potent role in lowering Cd accumulation via down regulating the expression of candidate genes, such as bZIP , ERF , MYB , SnRK1 and HSPs . Conclusions: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang . Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar . MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs , to play a role in Cd stress response.
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Transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
2019Co-Authors: Guanghui Chen, Zhibo Zhou, Yake YiAbstract:Abstract Background: Node is the central organ of xylem to phloem transfer of nutrients and ions in plants. Cadmium (Cd)-induced crop pollution threatens food safety. Breeding cultivar with low Cd accumulation is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 with low Cd accumulation and Yuzhenxiang with high Cd accumulation in the grains. RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. Results: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang, and node Ⅰ had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4,535 differentially expressed genes and 70 miRNAs between the two cultivars. Most genes (OsIRT1, OsNramp5, OsVIT2, OsNRT1.5A, and OsABCC1) related to the “transporter activity” play roles in blocking the upward transport of Cd in the low Cd-accumulative cultivar. Among the genes related to “response to stimulus”, we identified OsHSP70 and OsHSFA2d/B2c in Xiangwanxian No. 12, but not in Yuzhenxiang, were all down-regulated by Cd stimulus. The up-regulation of miRNAs (osa-miR528 and osa-miR408) played a potent role in lowering Cd accumulation via down regulation of genes, such as bZIP, ERF, MYB, SnRK1 and HSPs in Xiangwanxian No. 12 cultivar. Conclusions: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang. Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar. MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs, to play a role in stress response, which contribute to the response to Cd stress in rice.
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Transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
2019Co-Authors: Guanghui Chen, Zhibo Zhou, Yake YiAbstract:Abstract Background: Node is the central organ of xylem to phloem transfer of nutrients and ions in plants. Cadmium (Cd)-induced crop pollution threatens food safety. Breeding cultivar with low Cd accumulation is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 with low Cd accumulation and Yuzhenxiang with high Cd accumulation in the grains. RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. Results: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang , and node Ⅰ had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4,535 differentially expressed genes and 70 miRNAs between the two cultivars. Most genes ( OsIRT1 , OsNramp5, OsVIT2 , OsNRT1.5A, and OsABCC1 ) related to the “transporter activity” blocked the transport of Cd up to panicle and accumulation in grains of low Cd-accumulative cultivar. Among the genes related to “response to stimulus”, we identified OsHSP70 and OsHSFA2d/B2c in “X”, but not in “y”, were all down-regulated by Cd stimulus. The up-regulation of miRNAs ( osa-miR528 and osa-miR408 ) played a potent role in lowering Cd accumulation via down regulation of genes, such as bZIP , ERF , MYB , SnRK1 and HSPs in Xiangwanxian No. 12 cultivar. Conclusions: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang . Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar . MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs , to play a role in stress response, which contribute to the response to Cd stress in rice.
Yake Yi - One of the best experts on this subject based on the ideXlab platform.
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transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
BMC Genomics, 2020Co-Authors: Zhibo Zhou, Yake Yi, Guanghui ChenAbstract:BACKGROUND: Node is the central organ of transferring nutrients and ions in plants. Cadmium (Cd) induced crop pollution threatens the food safety. Breeding of low Cd accumulation cultivar is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 (low Cd accumulation cultivar) and Yuzhenxiang (high Cd accumulation cultivar). RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. RESULTS: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang, and node I had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4535 DEGs and 70 miRNAs between the two cultivars. Most genesrelated to the "transporter activity", such as OsIRT1, OsNramp5, OsVIT2, OsNRT1.5A, and OsABCC1, play roles in blocking the upward transport of Cd. Among the genes related to "response to stimulus", we identified OsHSP70 and OsHSFA2d/B2c in Xiangwanxian No. 12, but not in Yuzhenxiang, were all down-regulated by Cd stimulus. The up-regulation of miRNAs (osa-miR528 and osa-miR408) in Xiangwanxian No. 12 played a potent role in lowering Cd accumulation via down regulating the expression of candidate genes, such as bZIP, ERF, MYB, SnRK1 and HSPs. CONCLUSIONS: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang. Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar. MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs, to play a role in Cd stress response.
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Transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
2019Co-Authors: Guanghui Chen, Zhibo Zhou, Yake YiAbstract:Abstract Background: Node is the central organ of transferring nutrients and ions in plants. Cadmium (Cd) induced crop pollution threatens the food safety. Breeding of low Cd accumulation cultivar is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 (low Cd accumulation cultivar) and Yuzhenxiang (high Cd accumulation cultivar). RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. Results: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang , and node Ⅰ had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4,535 DEGs and 70 miRNAs between the two cultivars. Most genes related to the “transporter activity”, such as OsIRT1 , OsNramp5, OsVIT2 , OsNRT1.5A, and OsABCC1 , play roles in blocking the upward transport of Cd. Among the genes related to “response to stimulus”, we identified OsHSP70 and OsHSFA2d/B2c in Xiangwanxian No. 12 , but not in Yuzhenxiang , were all down-regulated by Cd stimulus. The up-regulation of miRNAs ( osa-miR528 and osa-miR408 ) in Xiangwanxian No. 12 played a potent role in lowering Cd accumulation via down regulating the expression of candidate genes, such as bZIP , ERF , MYB , SnRK1 and HSPs . Conclusions: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang . Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar . MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs , to play a role in Cd stress response.
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Transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
2019Co-Authors: Guanghui Chen, Zhibo Zhou, Yake YiAbstract:Abstract Background: Node is the central organ of xylem to phloem transfer of nutrients and ions in plants. Cadmium (Cd)-induced crop pollution threatens food safety. Breeding cultivar with low Cd accumulation is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 with low Cd accumulation and Yuzhenxiang with high Cd accumulation in the grains. RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. Results: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang, and node Ⅰ had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4,535 differentially expressed genes and 70 miRNAs between the two cultivars. Most genes (OsIRT1, OsNramp5, OsVIT2, OsNRT1.5A, and OsABCC1) related to the “transporter activity” play roles in blocking the upward transport of Cd in the low Cd-accumulative cultivar. Among the genes related to “response to stimulus”, we identified OsHSP70 and OsHSFA2d/B2c in Xiangwanxian No. 12, but not in Yuzhenxiang, were all down-regulated by Cd stimulus. The up-regulation of miRNAs (osa-miR528 and osa-miR408) played a potent role in lowering Cd accumulation via down regulation of genes, such as bZIP, ERF, MYB, SnRK1 and HSPs in Xiangwanxian No. 12 cultivar. Conclusions: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang. Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar. MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs, to play a role in stress response, which contribute to the response to Cd stress in rice.
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Transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
2019Co-Authors: Guanghui Chen, Zhibo Zhou, Yake YiAbstract:Abstract Background: Node is the central organ of xylem to phloem transfer of nutrients and ions in plants. Cadmium (Cd)-induced crop pollution threatens food safety. Breeding cultivar with low Cd accumulation is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 with low Cd accumulation and Yuzhenxiang with high Cd accumulation in the grains. RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. Results: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang , and node Ⅰ had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4,535 differentially expressed genes and 70 miRNAs between the two cultivars. Most genes ( OsIRT1 , OsNramp5, OsVIT2 , OsNRT1.5A, and OsABCC1 ) related to the “transporter activity” blocked the transport of Cd up to panicle and accumulation in grains of low Cd-accumulative cultivar. Among the genes related to “response to stimulus”, we identified OsHSP70 and OsHSFA2d/B2c in “X”, but not in “y”, were all down-regulated by Cd stimulus. The up-regulation of miRNAs ( osa-miR528 and osa-miR408 ) played a potent role in lowering Cd accumulation via down regulation of genes, such as bZIP , ERF , MYB , SnRK1 and HSPs in Xiangwanxian No. 12 cultivar. Conclusions: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang . Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar . MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs , to play a role in stress response, which contribute to the response to Cd stress in rice.
Zhibo Zhou - One of the best experts on this subject based on the ideXlab platform.
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transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
BMC Genomics, 2020Co-Authors: Zhibo Zhou, Yake Yi, Guanghui ChenAbstract:BACKGROUND: Node is the central organ of transferring nutrients and ions in plants. Cadmium (Cd) induced crop pollution threatens the food safety. Breeding of low Cd accumulation cultivar is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 (low Cd accumulation cultivar) and Yuzhenxiang (high Cd accumulation cultivar). RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. RESULTS: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang, and node I had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4535 DEGs and 70 miRNAs between the two cultivars. Most genesrelated to the "transporter activity", such as OsIRT1, OsNramp5, OsVIT2, OsNRT1.5A, and OsABCC1, play roles in blocking the upward transport of Cd. Among the genes related to "response to stimulus", we identified OsHSP70 and OsHSFA2d/B2c in Xiangwanxian No. 12, but not in Yuzhenxiang, were all down-regulated by Cd stimulus. The up-regulation of miRNAs (osa-miR528 and osa-miR408) in Xiangwanxian No. 12 played a potent role in lowering Cd accumulation via down regulating the expression of candidate genes, such as bZIP, ERF, MYB, SnRK1 and HSPs. CONCLUSIONS: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang. Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar. MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs, to play a role in Cd stress response.
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Transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
2019Co-Authors: Guanghui Chen, Zhibo Zhou, Yake YiAbstract:Abstract Background: Node is the central organ of transferring nutrients and ions in plants. Cadmium (Cd) induced crop pollution threatens the food safety. Breeding of low Cd accumulation cultivar is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 (low Cd accumulation cultivar) and Yuzhenxiang (high Cd accumulation cultivar). RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. Results: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang , and node Ⅰ had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4,535 DEGs and 70 miRNAs between the two cultivars. Most genes related to the “transporter activity”, such as OsIRT1 , OsNramp5, OsVIT2 , OsNRT1.5A, and OsABCC1 , play roles in blocking the upward transport of Cd. Among the genes related to “response to stimulus”, we identified OsHSP70 and OsHSFA2d/B2c in Xiangwanxian No. 12 , but not in Yuzhenxiang , were all down-regulated by Cd stimulus. The up-regulation of miRNAs ( osa-miR528 and osa-miR408 ) in Xiangwanxian No. 12 played a potent role in lowering Cd accumulation via down regulating the expression of candidate genes, such as bZIP , ERF , MYB , SnRK1 and HSPs . Conclusions: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang . Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar . MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs , to play a role in Cd stress response.
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Transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
2019Co-Authors: Guanghui Chen, Zhibo Zhou, Yake YiAbstract:Abstract Background: Node is the central organ of xylem to phloem transfer of nutrients and ions in plants. Cadmium (Cd)-induced crop pollution threatens food safety. Breeding cultivar with low Cd accumulation is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 with low Cd accumulation and Yuzhenxiang with high Cd accumulation in the grains. RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. Results: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang, and node Ⅰ had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4,535 differentially expressed genes and 70 miRNAs between the two cultivars. Most genes (OsIRT1, OsNramp5, OsVIT2, OsNRT1.5A, and OsABCC1) related to the “transporter activity” play roles in blocking the upward transport of Cd in the low Cd-accumulative cultivar. Among the genes related to “response to stimulus”, we identified OsHSP70 and OsHSFA2d/B2c in Xiangwanxian No. 12, but not in Yuzhenxiang, were all down-regulated by Cd stimulus. The up-regulation of miRNAs (osa-miR528 and osa-miR408) played a potent role in lowering Cd accumulation via down regulation of genes, such as bZIP, ERF, MYB, SnRK1 and HSPs in Xiangwanxian No. 12 cultivar. Conclusions: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang. Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar. MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs, to play a role in stress response, which contribute to the response to Cd stress in rice.
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Transcriptome analysis reveals the roles of Stem Nodes in cadmium transport to rice grain
2019Co-Authors: Guanghui Chen, Zhibo Zhou, Yake YiAbstract:Abstract Background: Node is the central organ of xylem to phloem transfer of nutrients and ions in plants. Cadmium (Cd)-induced crop pollution threatens food safety. Breeding cultivar with low Cd accumulation is a chance to resolve this universal problem. This study was performed to identify tissue specific genes involved in Cd accumulation in different rice Stem Nodes. Panicle node and the first node under panicle (node I) were sampled in two rice cultivars: Xiangwanxian No. 12 with low Cd accumulation and Yuzhenxiang with high Cd accumulation in the grains. RNA-seq analysis was performed to identify differentially expressed genes (DEGs) and microRNAs. Results: Xiangwanxian No. 12 had lower Cd concentration in panicle node, node I and grain compared with Yuzhenxiang , and node Ⅰ had the highest Cd concentration in the two cultivars. RNA seq analysis identified 4,535 differentially expressed genes and 70 miRNAs between the two cultivars. Most genes ( OsIRT1 , OsNramp5, OsVIT2 , OsNRT1.5A, and OsABCC1 ) related to the “transporter activity” blocked the transport of Cd up to panicle and accumulation in grains of low Cd-accumulative cultivar. Among the genes related to “response to stimulus”, we identified OsHSP70 and OsHSFA2d/B2c in “X”, but not in “y”, were all down-regulated by Cd stimulus. The up-regulation of miRNAs ( osa-miR528 and osa-miR408 ) played a potent role in lowering Cd accumulation via down regulation of genes, such as bZIP , ERF , MYB , SnRK1 and HSPs in Xiangwanxian No. 12 cultivar. Conclusions: Both panicle node and node I of Xiangwanxian No. 12 played a key role in blocking the upward transportation of Cd, while node I played a critical role in Yuzhenxiang . Distinct expression patterns of various transporter genes such as OsNRT1.5A, OsNramp5, OsIRT1, OsVIT2 and OsABCC1 resulted in differential Cd accumulation in different Nodes. Likewise, distinct expression patterns of these transporter genes are likely responsible for the low Cd accumulation in Xiangwanxian No. 12 cultivar . MiRNAs drove multiple transcription factors, such as OsbZIPs, OsERFs, OsMYBs , to play a role in stress response, which contribute to the response to Cd stress in rice.
Francesco Saccardo - One of the best experts on this subject based on the ideXlab platform.
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Adventitious shoot regeneration from leaf explants and Stem Nodes of Lilium
Plant Cell Tissue and Organ Culture, 2003Co-Authors: Loretta Bacchetta, Patrizio C. Remotti, Claudia Bernardini, Francesco SaccardoAbstract:A method for the regeneration of lily plantlets (Lilium spp.) through different morphogenic pathways is described. Plant regeneration was obtained from in vitro cultured leaves of four lily hybrids, cultured on Murashige and Skoog's basal medium supplemented with cytokinins (TDZ and BA) and auxins (NAA and IBA) at different concentrations. Direct shoot regeneration occurred with all tested media for the Asiatic lilies `Elite' and `Pollyanna' and also for the Oriental hybrid `Star Gazer'. Callus developed on TDZ-enriched medium from leaf segments of L. longiflorum cv. `Snow Queen' regenerated by direct organogenesis. This occurred on a medium with auxin/ cytokinin balance which was lower than other genotypes. There were fewer problems of sterilization with leaves from sprouted bulbs than in vitro scale culture. This suggests that the leaf-segments obtained in this way could be an alternative to the scales as a source of material for propagation. A protocol for micropropagation based on bulblets from in vitro shoot-tip-derived Stem Nodes was also used. The development of pseudo-bulbets is particularly advantageous since it allows for structures characterised by absent or low dormancy. Regenerated shoots have been rooted and successfully acclimatized to greenhouse conditions where they flowered after the second year giving plants with true-to-type shape and colour.
Loretta Bacchetta - One of the best experts on this subject based on the ideXlab platform.
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Adventitious shoot regeneration from leaf explants and Stem Nodes of Lilium
Plant Cell Tissue and Organ Culture, 2003Co-Authors: Loretta Bacchetta, Patrizio C. Remotti, Claudia Bernardini, Francesco SaccardoAbstract:A method for the regeneration of lily plantlets (Lilium spp.) through different morphogenic pathways is described. Plant regeneration was obtained from in vitro cultured leaves of four lily hybrids, cultured on Murashige and Skoog's basal medium supplemented with cytokinins (TDZ and BA) and auxins (NAA and IBA) at different concentrations. Direct shoot regeneration occurred with all tested media for the Asiatic lilies `Elite' and `Pollyanna' and also for the Oriental hybrid `Star Gazer'. Callus developed on TDZ-enriched medium from leaf segments of L. longiflorum cv. `Snow Queen' regenerated by direct organogenesis. This occurred on a medium with auxin/ cytokinin balance which was lower than other genotypes. There were fewer problems of sterilization with leaves from sprouted bulbs than in vitro scale culture. This suggests that the leaf-segments obtained in this way could be an alternative to the scales as a source of material for propagation. A protocol for micropropagation based on bulblets from in vitro shoot-tip-derived Stem Nodes was also used. The development of pseudo-bulbets is particularly advantageous since it allows for structures characterised by absent or low dormancy. Regenerated shoots have been rooted and successfully acclimatized to greenhouse conditions where they flowered after the second year giving plants with true-to-type shape and colour.
