Project description:Helianthus tuberosus L., known as the Jerusalem Artichoke, is a hexaploid plant species, adapted to low nutrient soils, that accumulates high levels of inulin in its tubers. Inulin is a fructose-based polysaccharide used either as dietary fiber or for the production of bioethanol. Key enzymes involved in inulin biosynthesis are well known. However, the gene networks underpinning tuber development and inulin accumulation in H. tuberous remain elusive. To fill this gap, we selected 6,365 ESTs from a H. tuberosus library to set up a microarray platform and record their expression across three tuber developmental stages, when rhizomes start enlarging (T0), at maximum tuber elongation rate (T3) and at tuber physiological maturity (Tm), in “VR” and “K8-HS142”clones. The former was selected as an early tuberizing, the latter as a late-tuberizing clone. We quantified inulin and starch levels, and q-RT PCR confirmed the expression of key genes accounting for inulin biosynthesis. The microarray analysis revealed that the differences in morphological and physiological traits between tubers of the two clones are genetically determined since T0 and that is relatively low the number of differentially expressed ESTs across the stages shared between the clones (93). The expression of ESTs for sucrose:sucrose 1-fructosyltransferase (1-SST) and fructan:fructan 1-fructosyltransferase (1-FFT), the two critical genes for fructans polymerization, resulted to be temporarily synchronized and mirror the progress of inulin accumulation and stretching. The expression of ESTs for starch biosynthesis was insignificant throughout the developmental stages of the clones in line with the negligible level of starch into their mature tubers, where inulin was the dominant polysaccharide. Overall, our study disclosed candidate genes underpinning the development and storage of carbohydrates in the tubers of two H. tuberosus clones. A model according to which the steady state levels of 1-SST and 1-FFT transcripts are developmentally controlled and might represent a limiting factor for inulin accumulation has been provided. Our finding may have significant repercussions for breeding clones with improved levels of inulin for food and chemical industry.

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Project description:Kluyveromyces marxianus is a non-conventional yeast with outstanding physiological characteristics and a high potential for lignocellulosic ethanol production. However, achieving high ethanol produc-tivities implies overcoming several biotechnological challenges as the cellular inhibition caused by the inhibitors present in the medium. In this work, the adaptation of K. marxianus SLP1 to increase the tolerance to a mix of inhibitory compounds was carried out using the adaptive laboratory evolution (ALE) strategy. As a result of the ALE adaptation process, an improved K. marxianus strain (P8) was obtained after 8 serial passes. The fermentative and physiological parameters evidenced a better response of the P8 strain against the synergistic effect of multiple inhibitors. The P8 strain reduced the lag phase from 12 to 4 h, increasing 40% the biomass and improving 16-fold the volumetric eth-anol productivity. To test the transcriptional dynamics for the adaptation process, we performed a differential gene expression analysis in control conditions; the results showed that the basal gene expression in P8 changes, suggesting the biological capability of K. marxianus to activate the ad-aptative prediction mechanism. This study demonstrates the rapid adaptability of K. marxianus SLP1 to stressful environments, making this yeast a promising candidate to produce lignocellulosic ethanol.