Project description:Due to limited bio-availability of Fe, plants evolved adaptive alterations in development regulated at the transcriptional level. We investigated the early transcriptional response to Fe deficiency. A hydroponic system was used that allows bulk transferring of plantsand rapid Fe removal with little mechanical damage to the root systems.

Project description:<p>Mechanical force is critical for the development and remodeling of bone. Here we report that mechanical force regulates the production of the metabolite asymmetric dimethylarginine (ADMA) via regulating the hydrolytic enzyme dimethylarginine dimethylaminohydrolase 1 (Ddah1) expression in osteoblasts. The presence of -394 4N del/ins polymorphism of Ddah1 and higher serum ADMA concentration are negatively associated with bone mineral density. Global or osteoblast-specific deletion of Ddah1 leads to increased ADMA level but reduced bone formation. Further molecular study unveils that mechanical stimulation enhances TAZ/SMAD4-induced Ddah1 transcription. Deletion of Ddah1 in osteoblast-lineage cells fails to respond to mechanical stimulus-associated bone formation. Taken together, the study reveals mechanical force is capable of down-regulating ADMA to enhance bone formation.</p>

Project description:Expression profiling of two-weeks-old wild type, nar1-4/- and nbp35-3/- mutant seedlings. The cytosolic Fe -S cluster assembly pathway is involved in cytosolic and nucleus Fe-S protein maturation. The nar1 mutant was identified by the screeing for abnormal transcription feature in endosperm.We performed genome-wide transcriptional profiling of weak allele nar1-4/- using microarrays to estimate whether the cytosolic Fe -S cluster assembly could affect on the transcriptional profile even in vegetative tissues.

Project description:Calcium (Ca2+) is one of the essential mineral nutrients for plant growth and development. However, the effects of long-term Ca2+ deficiency in orphan crops such as tef (Zucc.) Trotter] which accumulate high levels of Fe in the grains remained unknown. Tef is a staple crop for nearly 70 million people in East Africa, particularly Ethiopia and Eritrea. It is rich in mineral nutrients (Ca+2, Fe, Zn and Mn), vitamins and essential amino acids. In this study, tef plants were grown in hydroponic solution containing optimum (1 mM) or low (0.01 mM) Ca2+ and plant growth parameters and whole genome transcriptome were analyzed. Ca+2-deficient plants exhibited symptoms including leaf necrosis, leaf curling, and growth stunting. Ca2+ deficiency significantly decreased root and shoot Ca+2, potassium (K) and copper content in both root and shoots while it significantly increased root iron (Fe2+) content, suggesting the role of Ca2+ in the uptake and/or translocation of these minerals. Transcriptomic analysis using RNA-seq revealed that members of Ca2+ channels including the cyclic nucleotide-gated channels (CNGC) and glutamate receptor-like channels (GLRs), Ca2+-transporters, Ca2+-binding proteins (CBP) and Ca2+-dependent protein kinases (CDPK) were differentially regulated by Ca+2 treatment. Moreover, several Fe/metal transporters including members of vacuolar Fe transporters (VIT), yellow stripe-like (YSL), natural resistance-associated macrophage protein (NRAMP) and oligo-peptide transporters (OPT) were differentially regulated between shoot and root in response to Ca2+ treatment. Taken together, our findings suggest that Ca2+ deficiency affects plant growth and mineral accumulation by regulating the transcriptomes of several transporters and signaling genes.

Project description:Fe deficiency stimulates a coordinated response involving reduction, transport and redistribution of Fe in the roots. The expression of genes regulated by Fe deficiency in the two contrasting Arabidopsis thaliana ecotypes, Tsu-1 and Kas-1, shows that different ecotypes can respond in diverse ways, with different Fe regulated overrepresented categories. We use microarrays to analyze the Fe deficiency responses of contrasting Arabidopsis thaliana ecotypes (Tsu-1 and Kas-1).

Project description:Expression profiling of two-weeks-old wild type, nar1-4/- and nbp35-3/- mutant seedlings. The cytosolic Fe -S cluster assembly pathway is involved in cytosolic and nucleus Fe-S protein maturation. The nar1 mutant was identified by the screeing for abnormal transcription feature in endosperm.We performed genome-wide transcriptional profiling of weak allele nar1-4/- using microarrays to estimate whether the cytosolic Fe -S cluster assembly could affect on the transcriptional profile even in vegetative tissues. Two biological replicate were performed using two weeks seedling of wild type, nar1-4/- and nbp35-3/-. RNA was extracted using the RNeasy mini kit(QIAGEN).

Project description:Proteins regulate gene expression by controlling mRNA biogenesis, localization, translation and decay. Identifying the composition, diversity and function of mRNPs (mRNA protein complexes) is essential to understanding these processes. In a global survey of S. cerevisiae mRNA binding proteins we identified 120 proteins that cross-link to mRNA, including 66 new mRNA binding proteins. These include kinases, RNA modification enzymes, metabolic enzymes, and tRNA and rRNA metabolism factors. These proteins show dynamic subcellular localization during stress, including assembly into stress granules and P-bodies (Processing-bodies). CLIP (cross-linking and immunoprecipitation) analyses of the P-body components Pat1, Lsm1, Dhh1 and Sbp1 identified sites of interaction on specific mRNAs revealing positional binding preferences and co-assembly preferences. Taken together, this work defines the major yeast mRNP proteins, reveals widespread changes in their subcellular location during stress, and begins to define assembly rules for P-body mRNPs. CLIP-seq analysis of Dhh1, Lsm1, Pat1 and Sbp1

Project description:Autologous blood-derived products such as platelet-rich plasma (PRP) or autologous-conditioned plasma (ACP) have been used for managing symptoms of knee osteoarthritis (OA); however, the outcomes are highly variable due to limited information about the characteristics of these products, and how they impact clinical responses. We hypothesized that the clinical response ACP in patients with knee OA will correlate with the biologic activity and composition of the ACP administered. To test our hypothesis, we enrolled 51 patients with mild-moderate knee OA. We collected clinical information at baseline, and patient reported outcomes at 6 weeks and 6 months after ACP injection. We evaluated the composition of ACP by multiplex ELISA, and the biologic activity of the same aliquots using an in vitro biologic assay paired with gene expression analyses. Patients were stratified as responders and non-responders to ACP based on achievement of minimal clinically important differences in patient reported outcomes collected at 6 weeks and 6 months. RNA sequencing revealed that ACP modulates inflammatory responses in a co-culture of macrophages and fibroblast-like synoviocytes (fibroblasts); using this data, we selected specific genes to evaluate the biologic activity of ACP in vitro. Comparison of ACP from responders and non-responders revealed differences in the composition and activity of ACP between these groups. By integrating clinical and multi-omics data, we uncovered changes in the composition and biologic activity of ACP that may correlate with outcomes in knee OA patients.

Project description:The aim of this study is to demonstrate that mechanical unloading via SMG will induce a higher osteoarthritic-like gene profile in bioengineered meniscal cartilage from healthy female MFC versus healthy male MFC. This would serve as the molecular basis for early onset of knee osteoarthritis in females

Project description:Iron toxicity is one of the most common mineral disorders affecting Oryza sativa production in flooded lowland fields. Efforts have been made to develop new rice varieties tolerant to Fe toxicity (+Fe). Oryza meridionalis is an endemic from Northern Australia and grows in regions with Fe rich soils, which may provide Fe tolerance genes and mechanisms that can be used for adaptive breeding. Aiming to understand tolerance mechanisms in rice, we screened a population of interspecific introgression lines (IL) from a cross between O. sativa and O. meridionalis for the identification of QTLs contributing to Fe excess tolerance. Six putative QTLs were identified. A line carrying one introgression from O. meridionalis on chromosome 9 associated with one QTL for leaf bronzing score was identified as tolerant in terms of lipid peroxidation and electrolyte leakage despite presenting very high shoot Fe concentrations. Further physiological, biochemical, ionomic and transcriptomic analyses showed that the IL tolerance could be partly explained by Fe partitioning between the leaf sheath and culm. After the in silico construction of an interspecific hybrid genome to map the sequences from transcriptomic analysis, we identified 47 and 27 genes from O. meridionalis up and down-regulated, respectively, by Fe treatment on the tolerant IL. Among possible genes associated with shoot-based tolerance, we identified metallothionein-like proteins, genes from glutathione S-transferase family and transporters from ABC and Major Facilitator Superfamily. This is the first work to demonstrate that introgressions of O. meridionalis in O. sativa genome confer increased tolerance to +Fe