Abstract
Global warming is becoming a significant problem for food security, particularly in the Mediterranean basin. The use of molecular techniques to study gene-level responses to environmental changes in non-model organisms is increasing and may help to improve the mechanistic understanding of durum wheat response to elevated CO2 and high temperature. With this purpose, we performed transcriptome RNA sequencing (RNA-Seq) analyses combined with physiological and biochemical studies in the flag leaf of plants grown in field chambers at ear emergence. Enhanced photosynthesis by elevated CO2 was accompanied by an increase in biomass and starch and fructan content, and a decrease in N compounds, as chlorophyll, soluble proteins, and Rubisco content, in association with a decline of nitrate reductase and initial and total Rubisco activities. While high temperature led to a decline of chlorophyll, Rubisco activity, and protein content, the glucose content increased and starch decreased. Furthermore, elevated CO2 induced several genes involved in mitochondrial electron transport, a few genes for photosynthesis and fructan synthesis, and most of the genes involved in secondary metabolism and gibberellin and jasmonate metabolism, whereas those related to light harvesting, N assimilation, and other hormone pathways were repressed. High temperature repressed genes for C, energy, N, lipid, secondary, and hormone metabolisms. Under the combined increases in atmospheric CO2 and temperature, the transcript profile resembled that previously reported for high temperature, although elevated CO2 partly alleviated the downregulation of primary and secondary metabolism genes. The results suggest that there was a reprogramming of primary and secondary metabolism under the future climatic scenario, leading to coordinated regulation of C-N metabolism towards C-rich metabolites at elevated CO2 and a shift away from C-rich secondary metabolites at high temperature. Several candidate genes differentially expressed were identified, including protein kinases, receptor kinases, and transcription factors.
Highlights
Wheat is one of the most widely cultivated crop plants along the world and is basic for human nutrition in many areas
We extend precedent quantitative reverse transcription-PCR (qRT-PCR) information, limited to genes related to primary C and N metabolism (Vicente et al, 2015a), with transcriptome-wide RNA sequencing technologies (RNA-Seq) analysis combined with functional data to better understand the crop behavior under changing climate conditions
Shoot biomass was promoted by 17% by elevated [CO2] (EC), while no differences in leaf dry weight were observed with an elevation of [CO2] or temperature
Summary
Wheat is one of the most widely cultivated crop plants along the world and is basic for human nutrition in many areas. RNA-Seq studies in wheat are rapidly increasing (Duan et al, 2012; Oono et al, 2013; IWGSC, 2014; Kumar et al, 2015; Pingault et al, 2015; Curci et al, 2017) thanks to the reconstruction of the whole transcriptome by using de novo assembly of short paired-end (PE) reads. This is interesting for non-model organisms, such as durum wheat, due to the scarcity of sequences available in public databases. The transcript data sets generated in RNA-Seq experiments are large and complex (Grabherr et al, 2011), needing bioinformatics knowledge and computation facilities to process the data
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