Project description:Lotus japonicus is a model legume broadly used to study transcriptome regulation under different stress conditions and microorganism interaction. Understanding how this model plant respond gainst alkaline stress will certainly help to develop more tolerant cultivars in economically important Lotus species as well as in other legumes. In order to uncover the most important response mechanisms activated during alkaline stress, we explored by microarray analysis the transcriptome regulation occurring in the phenotypically contrasting ecotypes MG-20 and Gifu B-129 of L. japonicus after 21 days of alkaline stress.

Project description:Programmed cell suicide of infected bacteria, known as abortive infection (Abi), serves as a central immune defense strategy to prevent the spread of bacteriophage viruses and other invasive genetic elements across a population. Many Abi systems utilize bespoke cyclic nucleotide immune messengers generated upon infection to rapidly mobilize cognate death effectors. Here, we identify a large family of bacteriophage nucleotidyltransferases (NTases) which synthesize competitor cyclic dinucleotide (CDN) ligands and inhibit NAD-depleting TIR effectors activated through a linked STING CDN sensor domain (TIR-STING). Through a functional screen of NTase-adjacent phage genes, we uncover candidate inhibitors of host TIR-STING suicide signaling. Among these, we demonstrate that a virus MazG-like nucleotide pyrophosphatase, Atd1, depletes the starvation alarmone (p)ppGpp, revealing a role for the alarmone-activated host toxin MazF as a key executioner of TIR-driven abortive infection. Phage NTases and counter-defenses like Atd1 preserve host viability to ensure virus propagation, and may be exploited as tools to modulate TIR and STING immune responses.

Project description:Nelumbo, a perennial aquatic herbage that belongs to the family of Nelumbonaceae, comprises two extant species: N. nucifera Gaertn. and N. lutea (Wild.) Pers. Based on a previous study, N. nucifera is distributed in over Asia and Northern Australia while N. lutea is found in North America and northern of South America (1). N. nucifera can be divided into two cultivars including temperate lotus and tropical lotus based on its rhizome phenotype. The temperate lotus rhizome is expanded at the end of growth while tropical lotus root is of no significant enlargement during development (2). Normally, the temperate lotus root buds germinate in April, thereafter it takes several days from sowing to long roots and leaves. In mid-to-late may, vertical leaves rise out of the water, following July and August are the blooming period. Secondarily the first half of September is the final flowering period. The fruit ripening period is from late July to mid September, which is also the period of stem expansion and enrichment. After mid-October, it’s the dormant period, which is the lotus storage organ’s substance accumulation period. Thus the storage organ, mainly lotus rhizome, provides the energy for the lifecycle (Fig.1). Lotus rhizome, which is called metamorphic storage organ, is a kind of modified subterraneous stem, like potato (Solanum tuberosum) tuber and onion (Allium cepa L.) bulb (3). Most parts of lotus like rhizome, leaf, lotus seed and germ are used for traditional medicine (4). Rhizome especially is a kind of popular vegetable in Asia for its richness in nutrients including starch, proteins, vitamins (5). Nowadays it is a worldwide product in the form of the processed and semi-finished form like tea and vegetables. In general, the development of lotus rhizome can be classified into four stages: stolon stage, initial swelling, middle swelling, and later swelling stage (6, 7). The first three stages mainly focus on cell division and synthesis of some important carbohydrates, like starch, which play a critical part in the quantity and quality of rhizome, while accumulation of starch greatly increases at the last stage. Numerous studies have done in lotus to shed light on the environmental factors and morphometric indexes relevant to rhizome formation (8, 9). Short day light and low temperature promote tuber formation (10, 11). Also genes and proteins related to hormone, photoperiod (12, 13), starch synthesis (14, 15) and flowering time locus family genes were involved in the lotus rhizome formation (16). Previous studies include transcriptomics (6), genomics (17) and certain physiological researches, revealing numerous genes involved in photoperiod pathway, starch metabolism and hormone signal transduction, trying to make lotus a model plant of rhizome growth, while there is a lack of protein-level dynamic analysis and protein phosphorylation information, which is a strong proof for the dynamic processes in lotus rhizome. Proteomics is an indispensable method in storage organs research findings (18, 19), 2-DE and MALDI-TOF-TOF was employed to find some different protein profiles in fresh-cut lotus tuber before and after browning (20). And comparative proteomic was employed to analyze the Horsetail (Equisetum hyemale) underground stem to throw light upon the related proteins of developing rhizomes in ancient vascular plant Equisetum hyemale and different monocot species (21). Proteomics can also assist us in getting the changes of proteins in differently treated samples of potato tuber by using a LC-MS spectral-counting proteomics strategy (1), and shed light on the molecular basis of tuberization in potato to monitor differentially expressed proteins at different development stages (22). But the proteomic study of lotus rhizome enlargement hasn’t been reported now. Here, we employed comparative proteomics and phosphoproteomics to get proteins and its phosphorylation changes in the course of different rhizome development stages. Our data highlights some pathways, proteins and phosphorylated proteins during the development, and the difference between proteome and phosphoproteome in rhizome formation process.

Project description:Lotus japonicus is a model legume broadly used to study transcriptome regulation under different stress conditions and microorganism interaction. Understanding how this model plant protects itself against pathogens will certainly help to develop more tolerant cultivars in economically important Lotus species as well as in other legumes. In order to uncover the most important defense mechanisms activated upon bacterial attack, we explored by microarray analysis the transcriptome regulation occurring in the phenotypically contrasting ecotypes MG-20 and Gifu B-129 of L. japonicus after inoculation with the non-pathogenic strain Pseudomonas syringae DC3000 pv. tomato.

Project description:ALK is a tyrosine kinase receptor and oncogene in neuroblastoma (NB). The receptor is activated by the ALKAL2 ligand, but it is unknown whether missregulation of this ligand may play a role in NB carcinogenesis. To characterize the transcriptomic response to ALKAL2 in neuroblastoma cell lines, RNA-Seq was performed on NB1 and IMR32 human NB cell lines.

Project description:To identify the regulatory targets of the R2R3-Myb transcription factor, LjMyb14, the gene was constitutively over-expressed in Lotus japonicus under the Lotus ubiquitin promoter. The gene expression levels of three biological replicates of the Lotus japonicus (MG20) were averaged and compared to the the gene expression levels of three independent lines of Lotus japonicus japonicus constituitively over expressing LjMyb14 using the Lotus ubiquitin promoter.

Project description:To identify the regulatory targets of the R2R3-Myb transcription factor, LjMyb14, the gene was constitutively over-expressed in Lotus japonicus under the Lotus ubiquitin promoter.

Project description:Innate immunity in bacteria, plants and animals requires the specialized subset of TIR-domain proteins that are NAD+ hydrolases. Aggregation of these TIR proteins engages their enzymatic activity, but it is not known how this protein multimerization is regulated. Here, we discovered that TIR oligomerization is exquisitely controlled to prevent immune toxicity. We found that p38 propagates its own activation by promoting the feedforward expression and aggregation of the lone enzymatic TIR protein in the nematode C. elegans, TIR-1/SARM1. We performed a forward genetic screen to determine how the p38 positive feedforward loop is regulated. We discovered that the integrity of the specific lysosomal sub-compartment that expresses TIR-1/SARM1 is actively maintained to limit inappropriate aggregation of this protein and restrain toxic p38 immune activation. Thus, innate immune defenses in intestinal epithelial cells are regulated by specific control of TIR-1/SARM1 multimerization.

Project description:Innate immune responses in animals and plants involve receptors that recognize microbe-associated molecules. In animals, activation of the Toll-NFkappaB pathway involves the recruitment of a series of TIR-domain containing adaptors that activate NFkappaB transcription factors. Plants contain many TIR modules as part of a large multi-gene TIR-NBS-LRR R-gene innate immune defense system as well as TIR-motif containing genes that lack LRR and whose functions are unknown. Molecular interactions for any TIR module signaling pathway has yet to be shown. Here we investigated the functional role of a TIR module linked to a lectin-containing motif, TIR-Lec1 (TLec1). We show that TLec1 acts as a positive modulator of the systemic JA-dependent wound response. TLec1 transcripts are rapidly induced in a JA-independent pathway and insertional mutants that TLec1 transcripts fail to show the full systemic wound response

Project description:High-risk neuroblastoma (NB) is notoriously difficult to treat and is responsible for a disproportionate number of childhood deaths due to cancer. One long accepted indicator of high-risk NB and poor prognosis is amplification of the neural MYC (MYCN) oncogene, which is currently therapeutically intractable in this patient population. The identification of Anaplastic Lymphoma Kinase (ALK) as an oncogene in NB raised the possibility of using ALK tyrosine kinase inhibitors (TKIs) in the treatment of NB patients who harbor activating ALK mutations. The number of ALK-positive NB patients on primary diagnosis is in the range of 8-10%, a figure that increases substantially in the relapsed patient population. ALK signaling is activated by the ALKAL2 ligand located on the distal portion of chromosome 2, along with the ALK receptor and MYCN loci, in the ‘2p gain’ region that has been associated with NB. The question of whether dysregulation of ALK ligand may also play a role in NB has not been addressed, although notably, one of the first oncogenes described was the v-sis oncogene that shares more than 90% homology with the PDGF ligand. Therefore, we tested whether ALKAL ligand was able to potentiate NB progression in the absence of ALK mutation. We show here that overexpression of ALKAL2 is sufficient to drive rapid onset and penetrant Th-MYCN driven NB in the absence of ALK mutation, and that these tumours are sensitive to ALK TKI therapy. These results suggest that additional NB patients, such as those exhibiting 2p gain, may also benefit from ALK TKI based therapeutic intervention.