Plant Responses to Climate Change

Ongoing climate change poses a great risk to the natural environment and the sustainability of agriculture [...].

Contribution 1 explored the role that autophagy-related genes (ATGs) have in regulating and even improving plant tolerance to abiotic stresses.Autophagy is an evolutionarily conserved self-degradative process in all eukaryotic cells and plays many physiological roles in maintaining cellular homeostasis.However, the biological mechanisms and action of ATGs under abiotic stresses remain unclear.Specifically, the authors showed how the up-regulation of the gene MsATG13 enhanced cold tolerance in alfalfa (Medicago sativa L.) through the modulation of autophagy and antioxidant levels.This gene seems to activate other key ATGs, increasing antioxidant levels and reducing the accumulation of ROS in response to cold.These results demonstrate that autophagy plays an important role in plant survival under abiotic stress.
Contribution 2 revealed how the core component of the circadian clock, MtLHY (the Late Elongated Hypocotyl orthologue) is responsible for salt stress tolerance in Medicago truncatula.The circadian clock is an internal time mechanism that synchronizes the physiological response of an organism to its surroundings, including changing environmental conditions.In this study, the authors showed how the expression of MtLHY increases salt stress tolerance in M. truncatula through flavonoid biosynthesis, while mediating Na + /K + homeostasis and inhibiting ROS production.These results show an existing link between the circadian clock and plant responses to stresses.
Contribution 3 studied the single and combined effects of drought and elevated air [CO 2 ] (eCO 2 ) on the transcriptomic machinery of two Coffea genotypes (from the two species that support global coffee trade): Coffea canephora Pierre ex A. Froehner cv.Conilon Clone 153 (CL153) and C. arabica L. cv.Icatu Vermelho (Icatu).The authors showed a predominance of protective and ROS-scavenging genes, directly or indirectly related to ABA signaling pathways involved in tolerance responses, although with different regulatory mechanisms in Icatu and CL153.Moderate drought had a minor impact on the number of transcripts differentially regulated in these plants, contrary to severe water deficit.Additionally, it was found that elevated eCO 2 attenuated the impacts of drought in the two genotypes but especially in Icatu, in agreement with the contrasting physiological tolerance responses previously reported in these genotypes.Contribution 4 explored the effects of individual and combined stress (osmotic + heat stress) in the tolerance responses of 33 kale accessions (Brassica oleracea var.acephala).The authors showed that the more tolerant accessions had higher basal contents of proline, total soluble sugars, glucosinolates, and heat shock proteins and higher transcript levels of NAC and DREB transcription factors.On the contrary, sensitive accessions were characterized by a high basal content of fructans.These findings can be further used as markers for screening heat-and drought-tolerant kale cultivars.
Contribution 5 reported the effects that a moderate change in temperature had on plant immune response, through Ca 2+ /calmodulin-mediated signaling.Plants use hormones to respond to environmental changes.Ca 2+ signaling plays an important role in the adaptation to abiotic stresses, but the underlying mechanisms involved in this process are still scarcely known.The authors showed how AtSR1/CAMTA3, a Ca 2+ /CaM receptor, is involved in increased temperature-mediated stomatal defense and apoplastic immunity.Together with other studies, this suggests that Ca 2+ signaling acts as a general defense response to pathogen infection in the context of temperature.
Contribution 6 was focused on the action of pathogenesis-related (PR) proteins under pathogen attack or infection.Specifically, the authors aimed to understand if these genes act to defend tomato plants against infection by the spotted wilt virus (TSWV), one of the most important plant viruses in the world.This study identified and characterized forty-five candidate genes, with some, such as PR-10 and Sw-5b, up-regulated upon infection.These findings lead to a better understanding of how systemic necrosis occurs upon infection by the tomato spotted wilt tospovirus, which could aid in the future development of new antiviral approaches.
Contribution 7 explored the molecular mechanism of salt tolerance in rapeseed (Brassica napus L.), comparing two varieties with significant differences in salt tolerance: Zhongshuang 11 (ZS11), a conventional rapeseed variety, which is sensitive to salt stress, and Huayouza 62 (H62), an elite rapeseed cultivar, widely planted in China.Several differentially expressed metabolites and key differentially expressed genes were identified through metabolomics and transcriptomics analysis, revealing vast differences in the two varieties and a high mechanism of tolerance to salt, especially in H62.Specifically, several candidate genes of non-specific lipid transporters (nsLTPs) were identified as important for salt tolerance since they were significantly up-regulated as the salt concentration increased, especially in the salt-tolerant H62.
Contribution 8 studied the molecular mechanisms underlying rapeseed's response to high light (HL) stress, namely the potential roles of anthocyanins and jasmonic acid (JA) in plant adaptations.Although light is an essential environmental factor for plant growth and development, HL is also a stress factor, although scarcely studied.This work showed that plants under HL, up-regulated genes that were involved in the regulation and biosynthesis of anthocyanins and JA.In accordance, the accumulation of anthocyanins, which act as photoprotectants, was significantly promoted under HL conditions.In agreement with the positive regulatory role of JA in anthocyanin biosynthesis, this study suggests that JA plays a key role in the responses of rapeseed seedlings to HL, contributing to the development of HL-tolerant rapeseed plants.
Contribution 9 studied how the allelic diversity of growth-regulating factors (GRF), a family of plant-specific transcription factors with roles in plant growth, development, and stress response, changed between bread wheat (Triticum aestivum L.) and ancestral wheat accessions.The authors identified a rare allele in a world wheat collection, associated with earlier heading and higher grain filling, which is suggested to be an ancestral adaptation of local landraces in the Black Sea region.Together with the finding of other unique mutations, this study reveals the importance of ex situ conservation for the preservation of unique genetic alleles.
Contribution 10 reviewed the impact of drought stress on root exudates and associated microbiomes, discussing how they help plants to successfully respond to drought.The authors highlight how root exudates play an important role in the recruitment of mycor-rhizal fungi and plant growth-promoting rhizobacteria (PGPR), with implications for plant tolerance against environmental stresses.However, the crosstalk between root-associated microbiomes and root exudates, as well as the construction of beneficial microbial consortia in agriculture still presents great challenges.Therefore, a deeper understanding of root exudates and soil microbiomes is vital for disentangling their role in plant fitness and sustainable agriculture.

Future Perspectives
This Special Issue progresses our understanding of the molecular mechanisms underlying the responses of plants to abiotic stresses and highlights that multiple and complex processes are involved, including signaling pathways, transcription, translation, and posttranslational modifications.Despite the remarkable research involved in this Special Issue combining transcriptomics, genetics, and other approaches, there are still much scope for plant research.Further studies should clarify the key relationships between abiotic stresses and how they interact individually and in combination [3].Current research on plant tolerance is also, generally, focused on vegetative parts.Therefore, more studies are needed to understand the impacts of abiotic stressors on other key plant components such as the flowers, which are highly sensitive to environmental changes [6].Together with emerging solutions such as genome editing and the advance in artificial intelligence, this would be key in aiding sustainable agriculture and the food requirements of the ever-increasing human population.