Project description:LC-MS/MS dataset for marine sponges of disparate phylogeny collected from different geographical locations.

Project description:LC-MS/MS dataset for marine sponges of disparate phylogeny collected from different geographical locations.

Project description:This work represents the first epigenomic study carried out on saffron crocus. Five accessions of saffron, showing differences in tepal pigmentation, yield of saffron and flowering time, were analysed at the epigenetic level by applying a methylation-sensitive restriction enzyme-sequencing (MRE-seq) approach. Five accession-specific hypomethylomes plus a reference hypomethylome, generated by combining the sequence data from the single accessions, were obtained. Assembled sequences were annotated against existing online databases. In the absence of the Crocus genome, the rice genome was mainly used as the reference as it is the best annotated genome among monocot plants. Comparison of the hypomethylomes revealed many differentially methylated regions, confirming the high epigenetic variability present among saffron accessions, including sequences encoding for proteins that could be good candidates to explain the accessions’ alternative phenotypes. In particular, transcription factors involved in flowering process (MADS-box and TFL) and for the production of pigments (MYB) were detected. Finally, by comparing the generated sequences of the different accessions, a high number of SNPs, likely having arisen as a consequence of the prolonged vegetative propagation, were detected, demonstrating surprisingly high genetic variability. Gene ontology (GO) was performed to map and visualise sequence polymorphisms located within the GOs and to compare their distributions among different accessions. As well as suggesting the possible existence of alternative phenotypes with a genetic basis, a clear difference in polymorphic GO is present among accessions based on their geographic origin, supporting a possible signature of selection in the Indian accession with respect to the Spanish ones.

Project description:Aim: To identify the genes and non-coding RNAs (ncRNAs) involved in the neuroprotective actions of a dietary anti-oxidant (saffron) and of photobiomodulation. Methods: We used a previously published assay of photoreceptor damage, in which albino Sprague Dawley rats raised in dim cyclic illumination (12h 5 lux, 12h darkness) are challenged by 24h exposure to bright (1,000 lux) light. Experimental groups were protected against light damage by pretreatment with dietary saffron (1mg/kg/day for 21d) or photobiomodulation (10 J/cm2 at the eye, daily for 5d). RNA from 1 eye of each of 4 animals in each of the 6 experimental groups (control, light damage (LD), saffron, photobiomodulation (PBM), saffronLD, and PBMLD) was hybridized to Affymetrix rat genome ST arrays. Quantitative real-time PCR analysis of 14 selected genes was used to validate microarray results. Results: LD caused the regulation of 175 entities (genes and ncRNAs) beyond criterion levels (P < 0.05 in comparisons with controls, fold-change >2). PBM pretreatment reduced the expression of 126 of these 175 LD-regulated entities below criterion; saffron pretreatment reduced the expression of 53 entities (50 in common with PBM). In addition, PBM pretreatment regulated the expression of 67 entities not regulated by LD, while saffron pretreatment regulated 122 entities not regulated by LD (48 in common with PBM). PBM and saffron, given without LD, regulated genes and ncRNAs beyond criterion levels, but in lesser numbers than during their protective action. A high proportion of the entities regulated by LD (>90%) were known genes; by contrast, ncRNAs where prominent among the entities regulated by PBM and saffron in their neuroprotective roles (73% and 62% respectively). Conclusions: Given alone, saffron and (more prominently) PBM both regulated significant numbers of genes and ncRNAs. Given prior to retinal exposure to damaging light, thus while exerting their neuroprotective action, they regulated much larger numbers of entities, among which ncRNAs were prominent. Further, the downregulation of known genes and of ncRNAs was prominent in the protective actions of both neuroprotectants. These comparisons provide an overview of gene expression induced by two neuroprotectants and provide a basis for more focused study of their mechanisms. The were 3 biological repliactes of each of the following groups: Control, Saffron pretreated, Photobiomodulation pretreated, Light Damage, Saffron Light Damage and Photobiomodulation Light Damage. 18 chips in total were performed.

Project description:Maize rhizosphere bacteriome diversity

Project description:Arsenic (As) bioavailability in the rice rhizosphere is influenced by many microbial interactions, particularly by metal-transforming functional groups at the root-soil interface. This study was conducted to examine As-transforming microbes and As-speciation in the rice rhizosphere compartments, in response to two different water management practices (continuous and intermittently flooded), established on fields with high to low soil-As concentration. Microbial functional gene composition in the rhizosphere and root-plaque compartments were characterized using the GeoChip 4.0 microarray. Arsenic speciation and concentrations were analyzed in the rhizosphere soil, root-plaque, porewater and grain samples. Results indicated that intermittent flooding significantly altered As-speciation in the rhizosphere, and reduced methyl-As and AsIII concentrations in the pore water, root-plaque and rice grain. Ordination and taxonomic analysis of detected gene-probes indicated that root-plaque and rhizosphere assembled significantly different metal-transforming functional groups. Taxonomic non-redundancy was evident, suggesting that As-reduction, -oxidation and -methylation processes were performed by different microbial groups. As-transformation was coupled to different biogeochemical cycling processes establishing functional non-redundancy of rice-rhizosphere microbiome in response to both rhizosphere compartmentalization and experimental treatments. This study confirmed diverse As-biotransformation at root-soil interface and provided novel insights on their responses to water management, which can be applied for mitigating As-bioavailability and accumulation in rice grains.

Project description:To comprehensively characterize the genetic structure of the Druze population, we recruited and genotyped 40 parent-offspring trios from the Upper Galilee in Israel and the Golan Heights, attempting to capture different extended families (clans) across various geographical locations.

Project description:Comparative metabolomics analysis of three Amycolatopsis strains isolated from distant geographical locations.

Project description:Aim: To identify the genes and non-coding RNAs (ncRNAs) involved in the neuroprotective actions of a dietary anti-oxidant (saffron) and of photobiomodulation. Methods: We used a previously published assay of photoreceptor damage, in which albino Sprague Dawley rats raised in dim cyclic illumination (12h 5 lux, 12h darkness) are challenged by 24h exposure to bright (1,000 lux) light. Experimental groups were protected against light damage by pretreatment with dietary saffron (1mg/kg/day for 21d) or photobiomodulation (10 J/cm2 at the eye, daily for 5d). RNA from 1 eye of each of 4 animals in each of the 6 experimental groups (control, light damage (LD), saffron, photobiomodulation (PBM), saffronLD, and PBMLD) was hybridized to Affymetrix rat genome ST arrays. Quantitative real-time PCR analysis of 14 selected genes was used to validate microarray results. Results: LD caused the regulation of 175 entities (genes and ncRNAs) beyond criterion levels (P < 0.05 in comparisons with controls, fold-change >2). PBM pretreatment reduced the expression of 126 of these 175 LD-regulated entities below criterion; saffron pretreatment reduced the expression of 53 entities (50 in common with PBM). In addition, PBM pretreatment regulated the expression of 67 entities not regulated by LD, while saffron pretreatment regulated 122 entities not regulated by LD (48 in common with PBM). PBM and saffron, given without LD, regulated genes and ncRNAs beyond criterion levels, but in lesser numbers than during their protective action. A high proportion of the entities regulated by LD (>90%) were known genes; by contrast, ncRNAs where prominent among the entities regulated by PBM and saffron in their neuroprotective roles (73% and 62% respectively). Conclusions: Given alone, saffron and (more prominently) PBM both regulated significant numbers of genes and ncRNAs. Given prior to retinal exposure to damaging light, thus while exerting their neuroprotective action, they regulated much larger numbers of entities, among which ncRNAs were prominent. Further, the downregulation of known genes and of ncRNAs was prominent in the protective actions of both neuroprotectants. These comparisons provide an overview of gene expression induced by two neuroprotectants and provide a basis for more focused study of their mechanisms.

Project description:Background: Crocus sativus L. belongs to the Iridaceae family and its dried stigma, called saffron, is one of the world’s most expensive spice. C. sativus is also a famous medicinal plant on account of producing significant pharmaceutical apocarotenoids like crocins, crocetin, picrocrocin and safranal. These metabolites have been reported to play important pharmacological efficiency towards many diseases. However, the regulatory mechanism of saffron apocarotenoids biosynthesis and stigma specific accumulation remains poorly understood. Results: In this work, we performed deep transcriptomic sequencing and dynamic metabolomic profiling of different developmental stage stigmas, and firstly integrated the dynamic changes of apocarotenoids with dynamic transcriptomic data. As a result, a co-expression network was constructed, and 41 pathway genes, 5 TF genes were identified as hub genes probably participating in apocarotenoid biosynthesis, validated by qRT-PCR. The reliability of these results was validated by previous research of several genes, which were also screened out by the co-expression network. Conclusions: This work provides novel insights into the mechanism by which the apocarotenoids is synthesized and regulated. Such gene-to-apocarotenoid landscapes associated with different developmental stigma are fundamental of deeply understanding the biosynthesis and metabolic engineering of saffron apocarotenoids in the C. sativus and other plant.