The Plant Journal最新文献

Maize has undergone remarkable domestication and shows striking differences in architecture and ear morphology compared to its wild progenitor, called teosinte. However, our understanding of the genetic mechanisms underlying the ear morphology differences between teosinte and cultivated maize is still limited. In this study, we explored the genetic basis of ear-related traits at both early and mature stages by analyzing a population derived from a cross between Mo17 and a teosinte line, mexicana. We identified 31 quantitative trait loci (QTLs) associated with four IM-related and four ear-related traits, with 27 QTLs subjected to selection during the domestication process. Several key genes related to ear development were found under selection, including KN1 and RA1. Analysis of gene expression in the IM of developing ears from the population revealed the prominent roles of cis-variants in gene regulation. We also identified a large number of trans-eQTLs responsible for gene expression variation, and enrichment analysis on a trans-eQTL hotspot revealed the possible involvement of the sulfur metabolic pathway in controlling ear traits. Integrating the expression and phenotypic mapping data, we pinpointed several candidate genes potentially influencing ear development. Our findings advance the understanding of the genetic basis driving ear trait variation during maize domestication.

To enhance the breeding of new scab-resistant apple cultivars, a comprehensive understanding of the mechanisms governing major scab resistance genes is essential. Rvi12_Cd5 was previously identified as the best candidate gene for the Rvi12 scab resistance of the crab apple "Hansen's baccata #2" by gene prediction and in silico analysis. In the present study, Rvi12_Cd5 was used to transform the scab-susceptible apple cultivar "Gala Galaxy." Two constructs were prepared: the first carrying Rvi12_Cd5 under the control of a 35S promoter and E9 terminator, and the second carrying Rvi12_Cd5 under the control of its native promoter and terminator. All the transgenic lines were analyzed for T-DNA integration, copy number, and expression of Rvi12_Cd5 and phenotypically evaluated for scab resistance. The "Gala Galaxy" lines carrying the 35S promoter expressed Rvi12_Cd5 at a high level, showing partial to high resistance against a mixed inoculum of Venturia inaequalis, with symptoms ranging from class 0 to 3b on the Chevalier scale. The transgenic lines carrying the native promoter showed a lower expression of Rvi12_Cd5 compared with the 35S lines. Nevertheless, the low expression was sufficient to induce a resistance level comparable to that of the transgenic lines carrying the 35S promoter. These results indicate that Rvi12_Cd5 confers scab resistance to a susceptible apple cultivar and that even a low level of gene transcript can trigger a plant response to V. inaequalis infection. After HcrVf2 and Vr2-C, Rvi12_Cd5 is the third major apple scab resistance gene being functionally proven.

Volatile phenylpropenes comprise one of the largest groups of plant phenylalanine-derived volatiles that not only possess ecological roles but also exhibit numerous pharmacological activities. Despite their wide distribution in the plant kingdom, biosynthesis of only a small subset of these compounds has been discovered. Here, we elucidated yet unknown steps in the biosynthesis of isoelemicin and elemicin using carrot (Daucus carota subsp. sativus), which produces a wide spectrum of volatile phenylpropenes, as a model system. Comparative transcriptomic analysis combined with metabolic profiling of two carrot cultivars producing different spectrums and levels of phenylpropene compounds revealed that biosynthesis of isoelemicin and elemicin could proceed via the (iso)eugenol-independent pathway, which diverges from the lignin biosynthetic pathway after sinapyl alcohol. Moreover, in planta results showed that two different NADPH-dependent reductases, a newly identified 5-methoxy isoeugenol synthase (DcMIS) and previously characterized (iso)eugenol synthase (DcE(I)GS1), both of which use sinapyl acetate as a substrate, are responsible for the biosynthesis of immediate precursors of isoelemicin and elemicin, respectively. In contrast to penultimate reactions, the final steps in the formation of these phenylpropenes are catalyzed by the same newly characterized methyltransferase, S-adenosyl-l-methionine:5-methoxy(iso)eugenol O-methyltransferase, that methylates the para-hydroxyl group of their respective precursors, thus completing the (iso)eugenol-independent route for the biosynthesis of isoelemicin and elemicin.

Energy is required for growth as well as for multiple cellular processes. During evolution, plants developed regulatory mechanisms to adapt energy consumption to metabolic reserves and cellular needs. Reduced growth is often observed under stress, leading to a growth-stress trade-off that governs plant performance under different conditions. In this work, we report that plants with reduced levels of the mitochondrial respiratory chain component cytochrome c (CYTc), required for electron transport coupled to oxidative phosphorylation and ATP production, show impaired growth and increased global expression of stress-responsive genes, similar to those observed after inhibiting the respiratory chain or the mitochondrial ATP synthase. CYTc-deficient plants also show activation of the SnRK1 pathway, which regulates growth, metabolism, and stress responses under carbon starvation conditions, even though their carbohydrate levels are not significantly different from wild-type. Notably, loss-of-function of the gene encoding the SnRK1α1 subunit restores the growth of CYTc-deficient plants, as well as autophagy, free amino acid and TOR pathway activity levels, which are affected in these plants. Moreover, increasing CYTc levels decreases SnRK1 pathway activation, reflected in reduced SnRK1α1 phosphorylation, with no changes in total SnRK1α1 protein levels. Under stress imposed by mannitol, the growth of CYTc-deficient plants is relatively less affected than that of wild-type plants, which is also related to the activation of the SnRK1 pathway. Our results indicate that SnRK1 function is affected by CYTc levels, thus providing a molecular link between mitochondrial function and plant growth under normal and stress conditions.

The distributions of monolignol glucosides (MLGs) in compression and opposite woods of Pinus thunbergii were assessed using cryo-time-of-flight secondary ion mass spectrometry to investigate their involvement in lignification. p-Glucocoumaryl alcohol (PG) was identified in the region of the differentiating xylem adjacent to the cambial zone only in compression wood, whereas coniferin (CF) was similarly localized in both compression and opposite woods. Their distribution from the phloem to the xylem was evaluated by high-performance liquid chromatography (HPLC) using serial tangential sections. Variations in storage amounts of CF and PG in the stem of P. thunbergii agreed with lignification stages of the tracheid, supporting the idea that MLGs act as a storage and transportation form of lignin precursors. The imaging of monolignol (ML)-dependent active lignification sites using fluorescence-tagged MLs supported distinct distribution patterns of MLGs for lignification in compression and opposite woods. Methylation-thioacidolysis was applied to compression and opposite wood samples to examine the structural difference between the guaiacyl (G) and p-hydroxyphenyl (H) units in lignin. Most of the H units in compression wood were detected as lignin end groups via thioacidolysis. PG was detected in opposite wood by HPLC; however, the H unit was not detected by thioacidolysis. The differences in ML and MLG distributions, enzyme activity, and resultant lignin structures between the G and H units suggest the possibility of individual mechanisms regulating the heterogeneous structures of G and H unit in lignin.

CLAVATA3/EMBRYO SURROUNDING REGION (CLE) peptides are 12-13 amino acid-long peptides that serve as positional signals in plants. The core CLE signaling module consists of a CLE peptide and a leucine-rich repeat receptor-like kinase, but in flowering plants, WUSCHEL-RELATED HOMEOBOX (WOX) transcription factors are also incorporated to form negative feedback loops that regulate stem cell maintenance in the shoot and root. It is not known when WOX genes were co-opted into CLE signaling pathways, only that mosses and liverworts do not require WOX for CLE-regulated stem cell activities. We identified 11 CLE-encoding genes in the Ceratopteris genome, including one (CrCLV3) most similar to shoot meristem CLE peptide CLAVATA3. We performed the first functional characterization of a fern CLE using techniques including RNAi knockdown and synthetic peptide dosage. We found that CrCLV3 promotes cell proliferation and stem cell identity in the gametophyte meristem. Importantly, we provide evidence for CrCLV3 regulation of the WOX gene CrWOXA during the developmental stage when female gametangium formation begins. These discoveries open a new avenue for CLE peptide research in the fern and clarify the evolutionary timeline of CLE-WOX signaling in land plants.

Apple is an important economic species affected by abiotic stress, such as salt and drought. LRR-RLKs play a key role in plant responses to stress, although their physiological functions under abiotic stress are not yet fully understood. Autophagy is a highly conserved process in eukaryotes, which plays a vital role in drought and salt stress responses. In this study, overexpression of MdLRR-RLK1 in apple promoted plant growth and development and increased salt and drought stress tolerance. MdLRR-RLK1 interacts with MdATG3 in vivo and in vitro, and MdATG3 ubiquitinates and degrades MdLRR-RLK1. Intriguingly, MdLRR-RLK1 and MdATG3 enhance salt and drought tolerance through increasing autophagy. Moreover, MdATG3 interacts with MdATG8F and MdATG8I-like in apple. These findings reveal the interaction between MdLRR-RLK1 and MdATG3, suggesting mechanisms that regulate apple growth and resistance to abiotic stress.

Tiller number is a crucial determinant that significantly influences the productivity and reproductive capacity of forage. The regeneration potential, biomass production, and seed yield of perennial forage species are highly reliant on the development of tillering. Strigolactones (SLs) are recently discovered carotenoid-derived phytohormones that play a crucial role in the regulation of tillering in annual crops. However, the modulation of tiller growth in perennial forage by SLs remains insufficiently investigated. In this study, we identified two alleles of the SLs biosynthesis gene, DgCCD7^A and DgCCD7^D, which encode CAROTENOID CLEAVAGE DIOXYGENASE 7 (CCD7), from two distinct subspecies of orchardgrass (Dactylis glomerata) exhibiting contrasting tillering phenotype and SLs content. The functionality of the DgCCD7^A allele derived from high-tillering phenotypic orchardgrass was found to be diminished compared to that of DgCCD7^D from the low-tillering type in rescuing the increased branching phenotype of CCD7-defective mutants in Arabidopsis and rice (Oryza sativa). Notably, the introduction of DgCCD7^A in rice resulted in an increase in tiller number without significantly compromising grain yield. Moreover, we demonstrated that the L309P variation in DgCCD7^A is a rare natural variant exclusively found in orchardgrass. Our findings revealed that DgCCD7^A, a rare favorable natural variation of CCD7 in orchardgrass, holds significant potential for breeding application in improving the plant architecture of perennial forage and crops.

Dense planting of single-cross hybrids contributes to maize yield increase over the past decades. Leaf angle, an important agronomic trait relevant to planting density, plays a fundamental role in light penetration into the canopy and photosynthetic efficiency. Leaf angle is a key parameter of plant architecture in the concept of smart canopy. Maize smart-canopy-like plant architecture exhibits optimal leaf angle, resulting in erect upper leaves and intermediate or horizontal lower leaves. Leaf angle regulation is a promising way forward in the breeding of varieties with canopy ideotypes. In this review, we first describe the relationship between maize polarity axes and leaf angle formation. Then, we revisit advances in the mutant and quantitative genetics research of maize leaf angle, highlighting the biological implications of transcription factors for maize leaf angle regulation. We underscore that KNOX family is essential for the blade-sheath boundary establishment and brassinosteroid pathway components as well as regulator ZmRAVL1 serve as key hubs of the transcriptional hierarchy governing maize leaf angle formation. We also suggest potential avenues for manipulating maize leaf angles across canopy layers.

Phytosulfokine (PSK) is a plant growth-promoting peptide hormone that is perceived by its cell surface receptors PSKR1 and PSKR2 in Arabidopsis. Plants lacking the PSK receptors show phenotypes consistent with PSK signaling repressing some plant defenses. To gain further insight into the PSK signaling mechanism, comprehensive transcriptional profiling of Arabidopsis treated with PSK was performed, and the effects of PSK treatment on plant defense readouts were monitored. Our study indicates that PSK's major effect is to downregulate defense-related genes; it has a more modest effect on the induction of growth-related genes. WRKY transcription factors (TFs) emerged as key regulators of PSK-responsive genes, sharing commonality with a pathogen-associated molecular pattern (PAMP) responses, flagellin 22 (flg22), but exhibiting opposite regulatory directions. These PSK-induced transcriptional changes were accompanied by biochemical and physiological changes that reduced PAMP responses, notably mitogen-activated protein kinase (MPK) phosphorylation (previously implicated in WRKY activation) and the cell wall modification of callose deposition. Comparison with previous studies using other growth stimuli (the sulfated plant peptide containing sulfated tyrosine [PSY] and Pseudomonas simiae strain WCS417) also reveals WRKY TFs' overrepresentations in these pathways, suggesting a possible shared mechanism involving WRKY TFs for plant growth–defense trade-off.