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Climate change and associated extreme weather events are a threat not only for agricultural
yields but the plant kingdom in general. Therefore, there is a great necessity to better
understand the plants' intrinsic mechanisms to combat heat stress. The plant heat stress
response already has been investigated in many studies, including the role of HSFA1
transcription factors as the central regulators. Other aspects such as the initial perception of
heat and the role of heat-induced changes in plant metabolism are rather unknown.
In this thesis, the natural variation of 250 different accessions of Arabidopsis thaliana was
investigated regarding the temperature-dependent accumulation of raffinose and
triacylglycerols. A connection between these phenotypes and respective genotypes was
established using genome-wide association studies. As a result, the candidate gene
TREHALOSE-6-PHOSPHATE SYNTHASE 1 (TPS1), was identified. Enzymatic TPS1 is responsible
for the synthesis of trehalose 6-phosphate (T6P), which serves as an indicator and regulator
of sucrose homeostasis.
Subsequent analyses using tps1 tilling mutants demonstrated a link between T6P metabolism
and an increased accumulation of various soluble carbohydrates and starch, including
raffinose both under control conditions and during heat exposure. Furthermore, the mutant
lines displayed enhanced thermotolerance and survival rates following long-term heat stress.
Transcriptome analyses, however, did not show any difference in the regulation of canonical
heat stress-associated genes. Instead, genes related to photosynthesis were overrepresented
among the differentially upregulated genes in tps1 tilling lines during heat exposure. In this
work, a direct connection of T6P signaling, sucrose homeostasis, and thermotolerance is
shown for the first time.
In a second project, two Arabidopsis thaliana accessions (Oberursel-0, accession ID: 7276;
Nieps-0, accession ID: 7268) showing distinct capacities to acquire short-term
thermotolerance were compared to identify the putative causative regulators or mechanisms
that lead to the different levels of thermotolerance.
An examination of the transcriptomes of 7268 and 7276 showed that several hundreds of
genes were already differentially regulated within 10 minutes of exposure to 32 °C or 34 °C.
Among these, several genes associated with sulfur metabolism were more highly induced in
the more thermotolerant accession 7268. However, experimental as well as genetic
manipulation of sulfur availability and metabolism did not result in altered thermotolerance.
In addition to sulfur-related genes, most of the canonical heat stress-associated genes were
more highly expressed in 7268 than in 7276. While we could not identify a causative regulator
or mechanism of differential thermotolerances, the data strongly suggests that 7268 either
has a higher overall sensitivity, i.e., the heat stress response is initiated at lower temperatures,
or stronger overall heat stress response when exposed to a certain elevated temperature.