Project description:Maize is a globally important food and feed crop, and a low-phosphate (Pi) supply in the soil frequently limits maize yield in many areas. MicroRNAs (miRNAs) play important roles in the development and adaptation of plants to the environment. In this study, the spatio-temporal miRNA transcript profiling of the maize inbred line Q319 root and leaf in response to low Pi was analyzed with high-throughput sequencing technologies, and the expression patterns of certain target genes were detected by real-time RT-PCR. Complex small RNA populations were detected after low-Pi culture and displayed different patterns in the root and leaf. miRNAs identified as responding to Pi deficiency can be grouped into ‘early’ miRNAs that respond rapidly, and often non-specifically, to Pi deficiency, and ‘late’ miRNAs that alter the morphology, physiology or metabolism of plants upon prolonged Pi deficiency. The miR827-Nitrogen limitation adaptation (NLA)-mediated post-transcriptional pathway was conserved in response to Pi availability of maize, but the miR399-mediated post-transcriptional pathway was different from Arabidopsis. Abiotic stress-related miRNAs engaged in interactions of different signaling and/or metabolic pathways. Auxin-related miRNAs (zma-miR393, zma-miR160a/b/c, zma-miR160d/e/g, zma-miR167a/b/c/d and zma-miR164a/b/c/d/g) and their targets play important roles in promoting primary root growth, inhibiting lateral root development and retarding upland growth of maize when subjected to low Pi. The changes in expression of miRNAs and their target genes suggest that the miRNA regulation/alterations compose an important mechanism in the adaptation of maize to a low-Pi environment; certain miRNAs participate in root architecture modification via the regulation of auxin signaling. A complex regulatory mechanism of miRNAs in response to a low-Pi environment exists in maize, revealing obvious differences from that in Arabidopsis.

Project description:Deep sequencing of Arabidopsis thaliana small RNAs was conducted to reveal microRNAs (miRNAs) and other small RNAs that were differentially expressed in response to phosphate (Pi) deficiency. About 3.5 million sequence reads corresponding to 0.6-1.2 million unique sequence tags from each Pi-sufficient or -deficient root or shoot sample were mapped to the Arabidopsis genome. We showed that upon Pi deprivation, the expression of miR156, miR399, miR778 and miR827 was induced, whereas the expression of miR169, miR395 and miR398 was repressed. We found crosstalks coordinated by these miRNAs under different nutrient deficiencies. Moreover, we found a new miRNA family upregulated specifically by Pi deficiency. In addition to miRNAs, we identified one Pi starvation-induced DCL1-dependent small RNA derived from the long terminal repeat of a retrotransposon and a group of 19-nucleotide small RNAs corresponding to the 5' end of tRNA and expressed at a high level in Pi-starved roots. Interestingly, we observed an increased abundance of TAS4-derived trans-acting siRNAs (ta-siRNAs) in Pi-deficient shoots and uncovered an autoregulatory mechanism of PAP1/MYB75 via miR828 and TAS4-siR81(-) that regulates the biosynthesis of anthocyanin. This finding sheds light on the regulatory network between miRNA/ta-siRNA and its target gene. Of note, a substantial amount of miR399* accumulated under Pi deficiency. Like miR399, miR399* can move across the graft junction, implying a potential biological role for miR399*. This study represents a comprehensive expression profiling of Pi-responsive small RNAs and advances our understanding of the regulation of Pi homeostasis mediated by small RNAs. Keywords: Transcriptome analysis Examination of 4 samples from root and shoot tissues of Arabidopsis in either phosphate-sufficient or phosphate-deficient condition

Project description:Phosphorus (P) is an essential nutrient for plant growth and productivity. Due to soil fixation, however, phosphorus availability in soil is rarely sufficient to sustain high crop yields. Fertilizers are widely used to circumvent the limited bioavailability of phosphate (Pi) which led to a scenario of excessive soil P in agricultural soils. Whereas adaptive responses to Pi deficiency have been deeply studied, less is known about how plants adapt to Pi excess and how Pi excess might affect disease resistance. Here, we show that high Pi fertilization in rice plants, and subsequent Pi accumulation in leaves, enhances susceptibility to infection by Magnaporthe oryzae, the causal agent of the rice blast disease. Equally, MIR399f overexpression causes an increase in Pi content in rice leaves which results in enhanced susceptibility to M. oryzae. During pathogen infection, a weaker activation of defense-related genes occurs in rice plants accumulating Pi in leaves, a response that is in agreement with the phenotype of blast susceptibility observed in these plants. These data support that Pi, when in excess, compromises defense mechanisms in rice while demonstrating that miR399 functions as a negative regulator of rice immunity. The two signaling pathways, Pi signaling and defense signaling, must operate in a coordinated manner in controlling disease resistance. This information provides a basis to understand the molecular mechanisms involved in immunity in rice plants grown under a high Pi fertilization regime, an aspect that should be considered in management of the rice blast disease

Project description:Deep sequencing of Arabidopsis thaliana small RNAs was conducted to reveal microRNAs (miRNAs) and other small RNAs that were differentially expressed in response to phosphate (Pi) deficiency. About 3.5 million sequence reads corresponding to 0.6-1.2 million unique sequence tags from each Pi-sufficient or -deficient root or shoot sample were mapped to the Arabidopsis genome. We showed that upon Pi deprivation, the expression of miR156, miR399, miR778 and miR827 was induced, whereas the expression of miR169, miR395 and miR398 was repressed. We found crosstalks coordinated by these miRNAs under different nutrient deficiencies. Moreover, we found a new miRNA family upregulated specifically by Pi deficiency. In addition to miRNAs, we identified one Pi starvation-induced DCL1-dependent small RNA derived from the long terminal repeat of a retrotransposon and a group of 19-nucleotide small RNAs corresponding to the 5' end of tRNA and expressed at a high level in Pi-starved roots. Interestingly, we observed an increased abundance of TAS4-derived trans-acting siRNAs (ta-siRNAs) in Pi-deficient shoots and uncovered an autoregulatory mechanism of PAP1/MYB75 via miR828 and TAS4-siR81(-) that regulates the biosynthesis of anthocyanin. This finding sheds light on the regulatory network between miRNA/ta-siRNA and its target gene. Of note, a substantial amount of miR399* accumulated under Pi deficiency. Like miR399, miR399* can move across the graft junction, implying a potential biological role for miR399*. This study represents a comprehensive expression profiling of Pi-responsive small RNAs and advances our understanding of the regulation of Pi homeostasis mediated by small RNAs. Keywords: Transcriptome analysis

Project description:CCCH-type zinc finger (ZF) proteins comprise a diverse family of RNA- and DNA-binding regulators that play crucial roles in plant growth, development, and responses to stress. While tandem CCCH zinc finger (TZF) proteins have been extensively studied, the molecular functions of non-TZF members remain less understood. Here, we characterized Arabidopsis thaliana AtC3H26, a non-TZF CCCH protein and paralog of AtC3H3, and demonstrated its role as a ribonuclease (RNase) in salt stress tolerance and phosphate (Pi) homeostasis. In vitro assays confirmed that AtC3H26 degrades RNA substrates in a dose-dependent manner. mRNA sequencing of OX lines revealed a significant upregulation of phosphate starvation–responsive genes, including SPX1, PS2/PECP2, and SRG3/GDPD1, whereas small RNA sequencing identified the downregulation of miR399 and miR827, which are involved in the Pi starvation response. AtC3H26 OX plants accumulated higher Pi levels than wild type, suggesting that AtC3H26 modulates Pi accumulation. Collectively, these findings establish AtC3H26 as a novel cytoplasmic RNase that coordinates RNA turnover with stress and nutrient signaling in Arabidopsis.

Project description:Phosphorus is one of the most important macronutrients required for plant growth and development. The importance of phosphorylation modification in regulating phosphate (Pi) homeostasis in plants is emerging. We performed phosphoproteomic profiling to characterize proteins whose degree of phosphorylation is altered in response to Pi starvation in rice root.

Project description:Although phosphorus is one of the most important essential elements for plant growth and development, the epigenetic regulation of inorganic phosphate (Pi) signaling is poorly understood. In this study, we identified the high-mobility-group protein OsHMGB1 as a key regulator of phosphate homeostasis and plant growth in rice (Oryza sativa). OsHMGB1 expression is induced by Pi starvation and encodes a nucleus-localized protein. Relative to wild-type plants, Oshmgb1 mutant plants had lower Pi content in their leaves, whereas plants overexpressing OsHMGB1 had higher Pi content, indicating that OsHMGB1 positively regulates Pi accumulation. Transcriptome deep sequencing and chromatin immunoprecipitation followed by sequencing showed that OsHMGB1 regulated the expression of a series of phosphate starvation responsive (PSR) genes by binding to their promoters. Furthermore, Assay for Transposase-Accessible Chromatin followed by sequencing revealed that OsHMGB1 was involved in maintaining chromatin accessibility. Indeed, OsHMGB1 occupancy positively correlated with genome-wide chromatin accessibility and gene expression levels. Notably, we determined that OsHMGB1 interacted with RNA polymerase II to help regulate transcription, especially under low Pi conditions. Taken together, our results suggest that OsHMGB1 functions as a transcriptional facilitator, revealing a key epigenetic mechanism to regulate Pi homeostasis and fine-tune plant acclimation responses to Pi-limited environments.

Project description:Although phosphorus is one of the most important essential elements for plant growth and development, the epigenetic regulation of inorganic phosphate (Pi) signaling is poorly understood. In this study, we identified the high-mobility-group protein OsHMGB1 as a key regulator of phosphate homeostasis and plant growth in rice (Oryza sativa). OsHMGB1 expression is induced by Pi starvation and encodes a nucleus-localized protein. Relative to wild-type plants, Oshmgb1 mutant plants had lower Pi content in their leaves, whereas plants overexpressing OsHMGB1 had higher Pi content, indicating that OsHMGB1 positively regulates Pi accumulation. Transcriptome deep sequencing and chromatin immunoprecipitation followed by sequencing showed that OsHMGB1 regulated the expression of a series of phosphate starvation responsive (PSR) genes by binding to their promoters. Furthermore, Assay for Transposase-Accessible Chromatin followed by sequencing revealed that OsHMGB1 was involved in maintaining chromatin accessibility. Indeed, OsHMGB1 occupancy positively correlated with genome-wide chromatin accessibility and gene expression levels. Notably, we determined that OsHMGB1 interacted with RNA polymerase II to help regulate transcription, especially under low Pi conditions. Taken together, our results suggest that OsHMGB1 functions as a transcriptional facilitator, revealing a key epigenetic mechanism to regulate Pi homeostasis and fine-tune plant acclimation responses to Pi-limited environments.

Project description:Although phosphorus is one of the most important essential elements for plant growth and development, the epigenetic regulation of inorganic phosphate (Pi) signaling is poorly understood. In this study, we identified the high-mobility-group protein OsHMGB1 as a key regulator of phosphate homeostasis and plant growth in rice (Oryza sativa). OsHMGB1 expression is induced by Pi starvation and encodes a nucleus-localized protein. Relative to wild-type plants, Oshmgb1 mutant plants had lower Pi content in their leaves, whereas plants overexpressing OsHMGB1 had higher Pi content, indicating that OsHMGB1 positively regulates Pi accumulation. Transcriptome deep sequencing and chromatin immunoprecipitation followed by sequencing showed that OsHMGB1 regulated the expression of a series of phosphate starvation responsive (PSR) genes by binding to their promoters. Furthermore, Assay for Transposase-Accessible Chromatin followed by sequencing revealed that OsHMGB1 was involved in maintaining chromatin accessibility. Indeed, OsHMGB1 occupancy positively correlated with genome-wide chromatin accessibility and gene expression levels. Notably, we determined that OsHMGB1 interacted with RNA polymerase II to help regulate transcription, especially under low Pi conditions. Taken together, our results suggest that OsHMGB1 functions as a transcriptional facilitator, revealing a key epigenetic mechanism to regulate Pi homeostasis and fine-tune plant acclimation responses to Pi-limited environments.

Project description:Phosphate (Pi) deficiency severely affects crop yield. Modern high yielding rice genotypes are sensitive to Pi deficiency whereas traditional rice cultivars are naturally compatible to low Pi ecosystems. However, the underlying molecular mechanisms for low Pi tolerance in traditional genotypes remain largely elusive. To delineate the molecular mechanisms for low Pi tolerance, two contrasting rice genotypes - Dular (low Pi tolerant) and PB1 (low Pi sensitive) - have been selected. Comparative morphophysiological, global transcriptome and lipidome analyses of root and shoot tissues of both genotypes raised under Pi deficient and sufficient conditions revealed the potential low Pi tolerance mechanisms of traditional genotype. Most of the genes associated with enhanced internal Pi utilization (phospholipid remobilization) and modulation of root system architecture (RSA) are highly induced in traditional rice genotype, Dular. Higher reserve of phospholipid and greater accumulation of galactolipids under low Pi in Dular indicated its better internal Pi utilization. Furthermore, Dular also maintained better root growth than PB1 under low Pi resulting in larger root surface area due to increased lateral root density and root hair length. Genes involved in enhanced low Pi tolerance of traditional genotype can be exploited to improve the low Pi tolerance of modern high yielding rice cultivars.