Plant root stem cells and their surrounding microenvironment,namely the stem cell niche,are hypersensitive to DNA damage.However,the molecular mechanisms that help maintain the genome stability of root stem cells rema...Plant root stem cells and their surrounding microenvironment,namely the stem cell niche,are hypersensitive to DNA damage.However,the molecular mechanisms that help maintain the genome stability of root stem cells remain elusive.Here we show that the root stem cells in the skbl(Shk1 kinase binding protein 1) mutant undergoes DNA damage-induced cell death,which is enhanced when combined with a lesion of the Ataxia-telangiectasia mutated(ATM) or the ATM/RAD3-related(ATR) genes,suggesting that the SKBI plays a synergistically effect with ATM and ATR in DNA damage pathway.We also provide evidence that SKBI is required for the maintenance of quiescent center(QC),a root stem cell niche,under DNA damage treatments.Furthermore,we report decreased and ectopic expression of SHORTROOT(SHR) in response to DNA damage in the skbl root tips,while the expression of SCARECROW(SCR) remains unaffected.Our results uncover a new mechanism of plant root stem cell maintenance under DNA damage conditions that requires SKB1.展开更多
Sulfur is an essential macronutrient for plants with numerous biological functions. However, the influence of sulfur nutrient availability on the regulation of root development remains largely unknown. Here, we report...Sulfur is an essential macronutrient for plants with numerous biological functions. However, the influence of sulfur nutrient availability on the regulation of root development remains largely unknown. Here, we report the response of Arabidopsis thaliana L. root development and growth to different levels of sulfate, demonstrating that low sulfate levels promote the primary root elongation. By using various reporter lines, we examined in vivo IAA level and distribution, cell division,and root meristem in response to different sulfate levels.Meanwhile the dynamic changes of in vivo cysteine, glutathione,and IAA levels were measured. Root cysteine, glutathione, and IAA levels are positively correlated with external sulfate levels in the physiological range, which eventually affect root system architecture. Low sulfate levels also downregulate the genes involved in auxin biosynthesis and transport, and elevate the accumulation of PLT1 and PLT2. This study suggests that sulfate level affects the primary root elongation by regulating the endogenous auxin level and root stem cell niche maintenance.展开更多
L-Cysteine plays a prominent role in sulfur metabo- lism of plants. However, its role in root development is largely unknown. Here, we report that L-cysteine reduces primary root growth in a dosage-dependent manner. E...L-Cysteine plays a prominent role in sulfur metabo- lism of plants. However, its role in root development is largely unknown. Here, we report that L-cysteine reduces primary root growth in a dosage-dependent manner. Elevating cellular L-cysteine level by exposing Arabidopsis thaliana seedlings to high L-cysteine, buthionine sulphoximine, or O-acetylserine leads to altered auxin maximum in root tips, the expression of quiescent center cell marker as well as the decrease of the auxin carriers PIN1, PIN2, PIN3, and PIN7 of primary roots. We also show that high L-cysteine significantly reduces the protein level of two sets of stem cell specific transcription factors PLETHORA1/2 and SCR/SHR. However, L-cysteine does not downregulate the transcript level of PiNs, PLTs, or SCR/SHR, suggesting that an uncharacterized post-transcriptional mechanism may regulate the accumulation of PIN, PLT, and SCR/SHR proteins and auxin transport in the root tips. These results suggest that endogenous L-cysteine level acts to maintain root stem cell niche by regulating basal- and auxin-induced expression of PLT1/2 and 5CR/SHR. L-Cysteine may serve as a link between sulfate assimilation and auxin in regulating root growth.展开更多
文摘Plant root stem cells and their surrounding microenvironment,namely the stem cell niche,are hypersensitive to DNA damage.However,the molecular mechanisms that help maintain the genome stability of root stem cells remain elusive.Here we show that the root stem cells in the skbl(Shk1 kinase binding protein 1) mutant undergoes DNA damage-induced cell death,which is enhanced when combined with a lesion of the Ataxia-telangiectasia mutated(ATM) or the ATM/RAD3-related(ATR) genes,suggesting that the SKBI plays a synergistically effect with ATM and ATR in DNA damage pathway.We also provide evidence that SKBI is required for the maintenance of quiescent center(QC),a root stem cell niche,under DNA damage treatments.Furthermore,we report decreased and ectopic expression of SHORTROOT(SHR) in response to DNA damage in the skbl root tips,while the expression of SCARECROW(SCR) remains unaffected.Our results uncover a new mechanism of plant root stem cell maintenance under DNA damage conditions that requires SKB1.
基金supported by grants from the National Natural Science Foundation of China (90917004 and 31140056)
文摘Sulfur is an essential macronutrient for plants with numerous biological functions. However, the influence of sulfur nutrient availability on the regulation of root development remains largely unknown. Here, we report the response of Arabidopsis thaliana L. root development and growth to different levels of sulfate, demonstrating that low sulfate levels promote the primary root elongation. By using various reporter lines, we examined in vivo IAA level and distribution, cell division,and root meristem in response to different sulfate levels.Meanwhile the dynamic changes of in vivo cysteine, glutathione,and IAA levels were measured. Root cysteine, glutathione, and IAA levels are positively correlated with external sulfate levels in the physiological range, which eventually affect root system architecture. Low sulfate levels also downregulate the genes involved in auxin biosynthesis and transport, and elevate the accumulation of PLT1 and PLT2. This study suggests that sulfate level affects the primary root elongation by regulating the endogenous auxin level and root stem cell niche maintenance.
文摘L-Cysteine plays a prominent role in sulfur metabo- lism of plants. However, its role in root development is largely unknown. Here, we report that L-cysteine reduces primary root growth in a dosage-dependent manner. Elevating cellular L-cysteine level by exposing Arabidopsis thaliana seedlings to high L-cysteine, buthionine sulphoximine, or O-acetylserine leads to altered auxin maximum in root tips, the expression of quiescent center cell marker as well as the decrease of the auxin carriers PIN1, PIN2, PIN3, and PIN7 of primary roots. We also show that high L-cysteine significantly reduces the protein level of two sets of stem cell specific transcription factors PLETHORA1/2 and SCR/SHR. However, L-cysteine does not downregulate the transcript level of PiNs, PLTs, or SCR/SHR, suggesting that an uncharacterized post-transcriptional mechanism may regulate the accumulation of PIN, PLT, and SCR/SHR proteins and auxin transport in the root tips. These results suggest that endogenous L-cysteine level acts to maintain root stem cell niche by regulating basal- and auxin-induced expression of PLT1/2 and 5CR/SHR. L-Cysteine may serve as a link between sulfate assimilation and auxin in regulating root growth.
