Project description:To explore the mechanism of selective degradation of lignocellulose components by P. incarnate T-7, TMT labeling quantitative proteomic analysis was performed to explore the differential expression of secretory proteins of P. incarnate T-7 by submerged fermentation on poplar wood substrate relative to glucose substrates

Project description:Drought is a major cause of crop yield loss worldwide. Plants can adopt different mechanisms to survive under water deficit, where stomatal closure leads to CO2 limitation. This requires increased dissipation of light energy as heat by non-photochemical quenching (NPQ), changes in the structural configuration of light-harvesting complexes, or changes in the mode of photosynthetic electron flow (i.e. linear vs. cyclic). Under field conditions, where light intensity can change rapidly, this problem becomes even more challenging. Particularly the slow release from photoprotection (NPQ relaxation) was recently shown to cause significant loss of potential yield. We analyzed the acclimation of two different wheat varieties and compared their molecular acclimation strategy to Arabidopsis under moderate drought stress at a slow soil dehydration rate, mimicking realistic field conditions. We monitored their photosynthetic activity under fluctuating light intensities and integrated functional and structural data, based on a detailed analysis of photosynthetic parameters combined with biochemical analysis and unbiased shot-gun proteomics. Contrary to previous models based on the damage of photosynthetic complexes as consequence of drought, we found that plants actively preserve and fine-tune their photosynthetic machinery under drought to adjust the photosynthetic electron transfer to fast changes of light intensity. Strikingly, Arabidopsis and wheat use different molecular strategies for this acclimation. While clear differences in NPQ relaxation and phosphorylation levels of photosynthetic proteins were observed in wheat, Arabidopsis modified the light energy distribution among photosynthetic complexes without changing PSII-LHCII phosphorylation. The fine-tuning of NPQ relaxation can therefore represent a potential trait for crop breeding.

Project description:Colorectal cancer (CRC) is a leading cause of cancer-related death. Diagnosis at an early stage can greatly improve the patient outcome. Therefore, developing sensitive and specific non-invasive screening and diagnostic methods has a tremendous potential to combat the disease.

Project description:Colorectal cancer (CRC) is a leading cause of cancer-related death. Diagnosis at an early stage can greatly improve the patient outcome. Therefore, developing sensitive and specific non-invasive screening and diagnostic methods has a tremendous potential to combat the disease.

Project description:Bud dormancy is a crucial stage in perennial trees and allows survival over winter and optimal subsequent flowering and fruit production. Environmental conditions, and in particular temperature, have been shown to influence bud dormancy. Recent work highlighted some physiological and molecular events happening during bud dormancy in trees. However, we still lack a global understanding of transcriptional changes happening during bud dormancy. We conducted a fine tune temporal transcriptomic analysis of sweet cherry (Prunus avium L.) flower buds from bud organogenesis until the end of bud dormancy using next-generation sequencing. We observe that buds in organogenesis, paradormancy, endodormancy and ecodormancy are characterised by distinct transcriptional states, and associated with different pathways. We further identified that endodormancy can be separated in two phases based on its transcriptomic state: early and late endodormancy. We also found that transcriptional profiles of just 7 genes are enough to predict the main cherry tree flower buds dormancy stages. Our results indicate that transcriptional changes happening during dormancy are robust and conserved between different sweet cherry cultivars. Our work also sets the stage for the development of a fast and cost effective diagnostic tool to molecularly define the flower bud stage in cherry trees.

Project description:Grapes are a valuable fruit and an important economic crop in the world, where wine production is a major industry. In grapevine, the environmental regulation of bud dormancy varies among its diverse genotypes. Certain grapevine genotypes become dormant in response to decreasing photoperiod and others require low temperature or both environmental cues to induce dormancy. This study used a proteomic approach to gain an understanding of the underlying molecular events involved in bud dormancy commitment.

Project description:Merlot bud dormancy RNAseq

Project description:Seasonal bud dormancy progression

Project description:Synechococcus KAC 102, KAC 105, KAC 106, KAC 108 and KAC 114 genome sequencing

Project description:Perennial plants alternate between periods of active growth and periods of dormancy. Prerequisite to bud dormancy is the formation of an apical bud. Short day photoperiod in the fall induces bud formation in poplar. Transgenic plants overexpressing the bZIP transcription factor FD do not stop growing and do not form a bud. In order to better understand the molecular events leading to bud formation, we used microarrays to compare the transcriptomes of shoot tips of poplars overexpressing FD and wild type plants (1) grown under long day conditions and (2) collected after 3 weeks under short day conditions