FtNAC31, a Tartary buckwheat NAC transcription factor, enhances salt and drought tolerance in transgenic Arabidopsis

Molecular mechanisms underlying abiotic stress responses in buckwheat

Plants have endured evolutionary changes for hundreds of years under the impact of increasing abiotic and biotic stress due to increasing human activities over the past centuries. Scientists have been working to understand the molecular mechanisms of plant responses to severe environmental stress, as plants have complex molecular arrangements to respond and adapt to abiotic stress, including drought, cold, and heat stress. Buckwheat (Fagopyrum spp.) is a resilient pseudocereal known for its nutritional value and adaptability to various environmental conditions, making it an essential crop in sustainable agriculture. It is particularly noted for its gluten-free nature and high-quality protein content, which benefit those with gluten sensitivities. However, recent studies revealed that buckwheat cultivation faces significant challenges from abiotic stressors such as drought, salinity, temperature extremes, and heavy metal toxicity, which can adversely affect its growth and yield. We have acknowledged key genes and factors in regulating complex responses and tolerance of plants in response to abiotic stresses. We compiled new data about diverse mechanisms by which different Fagopyrum species manage abiotic stress, encompassing physiological, biochemical, and molecular adaptations. As global food production demands rise, effective management strategies for these stress factors are increasingly critical for optimising buckwheat production and ensuring food security in a changing climate.

Distribution of runs of homozygosity in Lactuca species and its implications for plant breeding and evolutionary conservation

Runs of homozygosity (ROH) have been extensively investigated to uncover the genomic inbred regions that reflect past population and breeding histories. In this study, we have explored the distribution and number of ROH in different Lactuca species including the cultivated lettuce varieties and their wild relatives. Next generation sequencing (NGS) technology provides the unique opportunity to study the genomes with resolution up to per-base-pair and we could compute ROH in the highest accuracy using NGS data. Our study reveals that Lactuca sativa has the longest average ROH length and fewest number of ROHs, while wild species show shorter, more numerous ROHs as expected. We found that these cultivated varieties exhibit relatively stable number of ROH and ROH lengths, with the largest median ROH count observed in Oilseed and the largest average ROH length in Crisphead. There is a significant proportion of medium-length ROHs (100 kb-1 Mb) enriched in L. sativa and L. serriola, with the highest number observed in L. serriola, while L. saligna has more short ROHs (< 10 KB), and the highest number of ROHs in the 10 KB-100 KB range were observed in Butterhead, with Stalk and Oilseed showing fewer and shorter ROHs overall. It suggests that Stalk and Oilseed were still in a process of breeding. The comparison between PLINK computation and our developed in-house algorithm shows that PLINK tends to detect longer ROH, whereas our algorithm adopts a more conservative approach, resulting in fewer and shorter ROH segments detected with higher precision more suitable for NGS data. We further analyze the distribution of ROH hotspots with a higher frequency occurred across cultivated species genomes, which has identified key genes such as DREB2B, NHL12, RPV1, and EIX2, which play crucial roles in plant stress tolerance and immune responses, enhancing adaptability to extreme environments and providing resistance to various diseases. These findings provide fresh scientific insights into lettuce breeding, germplasm conservation, and sustainable production, highlighting the importance of understanding and managing genetic diversity in global agricultural practices.

The Seed-Specific Rutin-Degrading Enzyme FtBGLU29 is a Key Factor Promoting the Accumulation of the Bitter Compound Quercetin in Tartary Buckwheat

Rutin-degrading enzymes play a crucial role in catalyzing the hydrolysis of rutin (quercetin 3-O-rutinoside) into the bitter compound quercetin, contributing significantly to the bitterness of Tartary buckwheat (Fagopyrum tataricum) (TB). Mitigating this bitterness is vital for improving the palatability and marketability of TB products. In this study, we integrated genomic and transcriptomic data with molecular docking analyses to identify 12 potential rutin-degrading enzymes in TB. Among them, FtBGLU29 exhibited a stable binding affinity for rutin and significantly higher expression levels, specifically in TB seeds. This unique expression was confirmed through Native-PAGE and MALDI-TOF/TOF-MS, which identified FtBGLU29 as the predominant rutin-degrading enzyme in TB seeds. In vitro hydrolysis experiments revealed that FtBGLU29 efficiently catalyzes the conversion of rutin to quercetin upon the hydration of TB flour. Functional studies showed that FtBGLU29 overexpression in TB seeds significantly enhanced the rutin hydrolysis rate relative to the control group (p < 0.05). In conclusion, this study establishes FtBGLU29 as a key enzyme in the degradation of rutin in TB seeds, highlighting its critical role in enhancing the enzymatic conversion efficiency and potentially reducing the bitterness of TB products.

Changes in the Content of Dietary Fiber, Flavonoids, and Phenolic Acids in the Morphological Parts of Fagopyrum tataricum (L.) Gaertn Under Drought Stress

BACKGROUND

Tartary buckwheat is a plant recognized for its resistance to various environmental stresses. Due to its valuable source of phenolic compounds, Fagopyrum tataricum is also characterized as a medicinal plant; therefore, the aim of this study was to investigate the drought stress for the levels of phenolic compounds in the morphological parts of the plant.

METHODS

This experiment was conducted in 7 L pots under laboratory conditions. Phenolic compounds were identified using a UHPLC-MS chromatography system. Antioxidant activity was assessed using well-known methods, including the DPPH scavenging activity and ferrous ion chelating activity.

RESULTS

In Tartary buckwheat leaves, stems, seeds, and husks, 57 phenolic compounds were identified, with a predominance of quercetin 3-rutinoside, quercetin, kaempferol-3-rutinoside, kaempferol, and derivatives of coumaric acid. It was observed that the Tartary buckwheat samples subjected to drought stress exhibited a slight decrease in the majority of individual phenolic compounds.

CONCLUSIONS

The measurement of biological parameters indicated that plant regeneration after drought stress demonstrated a rapid recovery, which can be a positive response to the progression of climate changes.

Enhancing rutin accumulation in Tartary buckwheat through a novel flavonoid transporter protein FtABCC2

Tartary buckwheat (Fagopyrum tataricum) is an annual coarse cereal from the Polygonaceae family, known for its high content of flavonoid compounds, particularly rutin. But so far, the mechanisms of the flavonoid transport and storage in Tartary buckwheat (TB) remain largely unexplored. This study focuses on ATP-binding cassette transporters subfamily C (ABCC) members, which are crucial for the biosynthesis and transport of flavonoids in plants. The evolutionary and expression pattern analyses of the ABCC genes in TB identified an ABCC protein gene, FtABCC2, that is highly correlated with rutin synthesis. Subcellular localization analysis revealed that FtABCC2 protein is specifically localized to the vacuole membrane. Heterologous expression of FtABCC2 in Saccharomyces cerevisiae confirmed that its transport ability of flavonoid glycosides such as rutin and isoquercetin, but not the aglycones such as quercetin and dihydroquercetin. Overexpression of FtABCC2 in TB hairy root lines resulted in a significant increase in total flavonoid and rutin content (P < 0.01). Analysis of the FtABCC2 promoter revealed potential cis-acting elements responsive to hormones, cold stress, mechanical injury and light stress. Overall, this study demonstrates that FtABCC2 can efficiently facilitate the transport of rutin into vacuoles, thereby enhancing flavonoids accumulation. These findings suggest that FtABCC2 is a promising candidate for molecular-assisted breeding aimed at developing high-flavonoid TB varieties.

Overexpression of a Fragaria vesca NAM, ATAF, and CUC (NAC) Transcription Factor Gene (FvNAC29) Increases Salt and Cold Tolerance in Arabidopsis thaliana

The NAC (NAM, ATAF1/2, CUC2) family of transcription factors (TFs) is a vital transcription factor family of plants. It controls multiple parts of plant development, tissue formation, and abiotic stress response. We cloned the FvNAC29 gene from Fragaria vesca (a diploid strawberry) for this research. There is a conserved NAM structural domain in the FvNAC29 protein. The highest homology between FvNAC29 and PaNAC1 was found by phylogenetic tree analysis. Subcellular localization revealed that FvNAC29 is localized onto the nucleus. Compared to other tissues, the expression level of FvNAC29 was higher in young leaves and roots. In addition, Arabidopsis plants overexpressing FvNAC29 had higher cold and high-salinity tolerance than the wild type (WT) and unloaded line with empty vector (UL). The proline and chlorophyll contents of transgenic Arabidopsis plants, along with the activities of the antioxidant enzymes like catalase (CAT), peroxidase (POD), and superoxide dismutase (SOD) under 200 mM NaCl treatment or -8 °C treatment, were higher than those activities of the control. Meanwhile, malondialdehyde (MDA) and the reactive oxygen species (ROS) content were higher in the WT and UL lines. FvNAC29 improves transgenic plant resistance to cold and salt stress by regulating the expression levels of AtRD29a, AtCCA1, AtP5CS1, and AtSnRK2.4. It also improves the potential to tolerate cold stress by positively regulating the expression levels of AtCBF1, AtCBF4, AtCOR15a, and AtCOR47. These findings suggest that FvNAC29 may be related to the processes and the molecular mechanisms of F. vesca response to high-salinity stress and LT stress, providing a comprehensive understanding of the NAC TFs.

Picea wilsonii NAC31 and DREB2A Cooperatively Activate ERD1 to Modulate Drought Resistance in Transgenic Arabidopsis

The NAC family of transcription factors (TFs) regulate plant development and abiotic stress. However, the specific function and response mechanism of NAC TFs that increase drought resistance in Picea wilsonii remain largely unknown. In this study, we functionally characterized a member of the PwNAC family known as PwNAC31. PwNAC31 is a nuclear-localized protein with transcriptional activation activity and contains an NAC domain that shows extensive homology with ANAC072 in Arabidopsis. The expression level of PwNAC31 is significantly upregulated under drought and ABA treatments. The heterologous expression of PwNAC31 in atnac072 Arabidopsis mutants enhances the seed vigor and germination rates and restores the hypersensitive phenotype of atnac072 under drought stress, accompanied by the up-regulated expression of drought-responsive genes such as DREB2A (DEHYDRATION-RESPONSIVE ELEMENT BINDING PROTEIN 2A) and ERD1 (EARLY RESPONSIVE TO DEHYDRATION STRESS 1). Yeast two-hybrid and bimolecular fluorescence complementation assays confirmed that PwNAC31 interacts with DREB2A and ABF3 (ABSCISIC ACID-RESPONSIVE ELEMENT-BINDING FACTOR 3). Yeast one-hybrid and dual-luciferase assays showed that PwNAC31, together with its interaction protein DREB2A, directly regulated the expression of ERD1 by binding to the DRE element of the ERD1 promoter. Collectively, our study provides evidence that PwNAC31 activates ERD1 by interacting with DREB2A to enhance drought tolerance in transgenic Arabidopsis.

Gene Cloning and Characterization of Transcription Factor FtNAC10 in Tartary Buckwheat (Fagopyrum tataricum (L.) Gaertn.)

NAC transcription factors play a significant role in plant stress responses. In this study, an NAC transcription factor, with a CDS of 792 bp encoding 263 amino acids, was cloned from Fagopyrum tataricum (L.) Gaertn. (F. tataricum), a minor cereal crop, which is rich in flavonoids and highly stress resistant. The transcription factor was named FtNAC10 (NCBI accession number: MK614506.1) and characterized as a member of the NAP subgroup of NAC transcriptions factors. The gene exhibited a highly conserved N-terminal, encoding about 150 amino acids, and a highly specific C-terminal. The resulting protein was revealed to be hydrophilic, with strong transcriptional activation activity. FtNAC10 expression occurred in various F. tataricum tissues, most noticeably in the root, and was regulated differently under various stress treatments. The over-expression of FtNAC10 in transgenic Arabidopsis thaliana (A. thaliana) seeds inhibited germination, and the presence of FtNAC10 enhanced root elongation under saline and drought stress. According to phylogenetic analysis and previous reports, our experiments indicate that FtNAC10 may regulate the stress response or development of F. tataricum through ABA-signaling pathway, although the mechanism is not yet known. This study provides a reference for further analysis of the regulatory function of FtNAC10 and the mechanism that underlies stress responses in Tartary buckwheat.

A Transcription Factor SlNAC4 Gene of Suaeda liaotungensis Enhances Salt and Drought Tolerance through Regulating ABA Synthesis

The NAC (NAM, ATAF1/2 and CUC2) transcription factors are ubiquitously distributed in plants and play critical roles in the construction of plant organs and abiotic stress response. In this study, we described the cloning of a Suaeda liaotungensis K. NAC transcription factor gene SlNAC4, which contained 1450 bp, coding a 331 amino acid. We found that SlNAC4 was highly expressed in stems of S. liaotungensis, and the expression of SlNAC4 was considerably up-regulated after salt, drought, and ABA treatments. Transcription analysis and subcellular localization demonstrated that the SlNAC4 protein was located both in the nucleus and cytoplasm, and contained a C-terminal transcriptional activator. The SlNAC4 overexpression Arabidopsis lines significantly enhanced the tolerance to salt and drought treatment and displayed obviously increased activity of antioxidant enzymes under salt and drought stress. Additionally, transgenic plants overexpressing SlNAC4 had a significantly higher level of physiological indices. Interestingly, SlNAC4 promoted the expression of ABA metabolism-related genes including AtABA1, AtABA3, AtNCED3, AtAAO3, but inhibited the expression of AtCYP707A3 in overexpression lines. Using a yeast one-hybrid (Y1H) assay, we identified that the SlNAC4 transcription factor could bind to the promoters of those ABA metabolism-related genes. These results indicate that overexpression of SlNAC4 in plants enhances the tolerance to salt and drought stress by regulating ABA metabolism.

Effects of salt stress on root morphology, carbon and nitrogen metabolism, and yield of Tartary buckwheat

This study aims to clarify the effects of different concentrations of sodium chloride on the carbon and nitrogen metabolism and yield of Tartary buckwheat. The salt-sensitive cultivar Yunqiao 2 was pot-grown and treated with four salt concentrations including 0, 2, 4, and 6 g kg^-1. The root morphology index increased from seedling stage to maturate stage. The content of soluble protein in the leaves reached the maximum at the anthesis stage, and the other substances content and the enzymes activity related to carbon and nitrogen metabolism reached the maximum at the grain filling stage. The root morphology index, root activity; invertase, amylase, sucrose synthase, and sucrose phosphate synthase activities; nitrate-nitrogen, ammonium nitrogen, and soluble protein content; and nitrate reductase and glutamate synthase activities increased first and reached the maximum at 2 g kg^-1 treatment and then decreased with increasing salt stress concentration. The content of soluble sugars and sucrose and the activity of glutamate dehydrogenase increased continuously with increasing salt concentration, and reached the maximum in the 6 g kg^-1 treatment. The grain number per plant, 100-grain weight, and yield per plant increased first and reached the maximum at 2 g kg^-1 treatment and then decreased with increasing salt stress concentration. In summary, moderate salt stress (2 g kg^-1) can promote the root growth, increase the content of carbon and nitrogen metabolism-related substances and enzyme activity, and increase the yield per plant of Tartary buckwheat.