Project description:Salinity is a pressing issue causing widespread crop loss, prompting plants to adapt through changes in gene expression. This study investigated the role of the non-tandem CCCH zinc finger protein gene AtC3H3 in Arabidopsis in response to salt stress. AtC3H3, a gene from the non-TZF gene family and known for its RNA-binding and ribonuclease activity, was found to be upregulated under osmotic stresses such as high salt and drought. When overexpressed in Arabidopsis, AtC3H3 led to increased tolerance to salt stress, not drought stress. qRT-PCR analysis showed that the expression of both well-known ABA-dependent salt stress-responsive genes, such as RAB18, RD29B, and RD22, and representative ABA-independent salt stress-responsive genes, such as DREB2A and DREB2B, was significantly higher in AtC3H3 OXs than WT under NaCl treatment, indicating its involvement in both ABA-dependent and ABA-independent signaling pathways. mRNA-Seq analysis using NaCl-treated WT and AtC3H3 OXs revealed no potential target mRNAs of the RNase function of AtC3H3, suggesting that the potential targets of AtC3H3 might be non-coding RNAs, not mRNAs. The study conclusively demonstrates that AtC3H3 plays a crucial role in salt stress tolerance by influencing the expression of salt stress-responsive genes. These findings have opened a new avenue for understanding plant stress mechanisms and suggest potential strategies for enhancing crop resilience to salinity.

Project description:We characterized the biological and molecular functions of AtC3H17, a unique Arabidopsis gene encoding a non-tandem CCCH zinc finger protein, in plant development. To investigate the downstream regulatory mechanisms of AtC3H17, whole genome microarray expression profiling was carried out. The experiment was designed to identify differentially expressed genes between WT and AtC3H17-overexpressing transgenic plants (AtC3H17 OXs) grown for 14 days under SD growth conditions. Interestingly, the most up-regulated genes were 12S seed storage globulin genes, CRUCIFERIN A (CRA1) and CRUCIFERIN 3 (CRU3), and seed oil-body protein genes such as OLEOSIN 1 (OLEO1) and OLEO2 in AtC3H17 OXs compared with WT. We performed quantitative RT-PCR and confirmed that transcription levels of CRU3, OLEO1, OLEO2, and 2S seed storage albumin 1 (At2S1) were higher in AtC3H17 OX seedlings than in WT seedlings. Differentially expressed genes between WT and AtC3H17 OX at 14 days after germination under SD conditions (8-h-light and 16-h-dark cycle) were explored in whole genome level. Two AtC3H17 OX samples were compared to WT sample as a control.

Project description:We performed a transcriptomic analysis of Pi starvation responses in Arabidopsis thaliana (Columbia-0) wild type plants under phosphate starvation stress and in plants with altered PHR1(-like) activity, comparing mutants of phr1 and phr1-phl1 grown in phosphate-lacking medium. Results show the central role of PHR1 and functionally redundant members of its family in the control of transcriptional responses to Pi starvation.

Project description:Pi availability is a significant limiting factor for plant growth in both natural and agricultural systems. To cope with such limiting conditions, plants have adapted developmental and biochemical strategies to enhance Pi acquisition and to avoid starvation. A myriad of genes that are involved in the regulation and display of these strategies have been identified. However, the possible epigenetic components regulating the phosphate starvation responses have not been thoroughly investigated. DNA methylation is a major epigenetic mark involved in diverse biological processes and it may play a critical role in Pi starvation stress adaptation, also changes in DNA methylation can lead to a unique gene expression pattern in response to specific developmental and environmental conditions. Here in we demonstrate that non-CpG DNA methylation is required for proper expression of a number of Pi-limitation responsive genes in Arabidopsis thaliana and results in altered morphologic and physiologic phosphate starvation responses.Our data suggest that DNA methylation is involved in the modulation of Pi starvation responses via the transcriptional regulation of a set of phosphate-starvation responsive genes.

Project description:Pi availability is a significant limiting factor for plant growth in both natural and agricultural systems. To cope with such limiting conditions, plants have adapted developmental and biochemical strategies to enhance Pi acquisition and to avoid starvation. A myriad of genes that are involved in the regulation and display of these strategies have been identified. However, the possible epigenetic components regulating the phosphate starvation responses have not been thoroughly investigated. DNA methylation is a major epigenetic mark involved in diverse biological processes and it may play a critical role in Pi starvation stress adaptation, also changes in DNA methylation can lead to a unique gene expression pattern in response to specific developmental and environmental conditions. Here in we demonstrate that non-CpG DNA methylation is required for proper expression of a number of Pi-limitation responsive genes in Arabidopsis thaliana and results in altered morphologic and physiologic phosphate starvation responses.Our data suggest that DNA methylation is involved in the modulation of Pi starvation responses via the transcriptional regulation of a set of phosphate-starvation responsive genes. Analysis of 8 different treatments, 2 different Organs (Root and Shoot), 2 different Phosphate treatments (High Pi, Low Pi), 2 different Times (Short Term, Long Term), 2 biological replicates for treatment

Project description:This study evaluates whether different pre-treatments (+Pi, -Pi and +Phi) influences the phosphate starvation transcriptional response triggered by a bacterial synthetic community in Arabidopsis seedlings.

Project description:We performed a transcriptomic analysis of Pi starvation responses in Arabidopsis thaliana (Columbia-0) wild type plants under phosphate starvation stress and in plants with altered PHR1(-like) activity, comparing mutants of phr1 and phr1-phl1 grown in phosphate-lacking medium. Results show the central role of PHR1 and functionally redundant members of its family in the control of transcriptional responses to Pi starvation. The analysis was performed in wild-type plants grown for seven days in complete (+Pi) and Pi-lacking (-Pi) Johnson solid media and the single phr1 and double phr1-phl1 mutants grown for 7 days in –Pi medium. Three independent biological samples of total RNA from shoot and root were hybridized separately.

Project description:In many eukaryotes, mRNAs containing specific AU-rich motifs are regulated by proteins of the tristetraprolin (TTP) family, which bind to these motifs through a tandem zinc finger (TZF) domain. This binding leads to promotion of subsequent deadenylation and decay, partly through a conserved carboxyl-terminal CNOT1 binding domain. We explored the physiological role of the single TTP family member (TtpA) expressed in Dictyostelium discoideum. This study shows the effect of an insertional mutation in the TZF domain (ttpA-C240ins), which disrupted the TZF RNA binding domain, evaluated in amebae in axenic conditions in growth medium during surface culture, and during short term (2 and 6 hours) nutrient deprivation. RNA-Seq analysis was performed on WT and mutant cells in parallel during this short time course.

Project description:Plant vacuoles serve as the primary intracellular compartments for inorganic phosphate (Pi) storage. Passage of Pi across vacuolar membranes plays a critical role in buffering the cytoplasmic Pi level against fluctuations of external Pi and metabolic activities. Here we demonstrate that the SPX-MFS proteins, designated as Phosphate Transporter 5 family (PHT5), also named Vacuolar Phosphate Transporter (VPT), function as vacuolar Pi transporters. Based on 31P-magnetic resonance spectroscopy analysis, Arabidopsis pht5;1 loss-of-function mutants accumulate less Pi and exhibit a lower vacuolar-to-cytoplasmic Pi ratio than controls. Conversely, overexpression of PHT5 leads to massive Pi sequestration into vacuoles and altered regulation of Pi starvation-responsive genes. Furthermore, we show that heterologous expression of OsSPX-MFS1, the rice PHT5 homolog, mediates Pi influx to yeast vacuoles. Our findings uncover a group of Pi transporters in vacuolar membranes that regulate the cytoplasmic Pi homeostasis required for the fitness of plant growth. 10-day seedlings grown on Pi-sufficient medium or followed by 1-day or 3-day Pi starvation, shoot RNA and root RNA were extracted separately

Project description:RNA-binding preference of the Roquin-1 CCCH-type zinc finger