Signaling mechanisms in pattern-triggered immunity (PTI)

BIK1 and ATL31/6 are essential for fucoidan hydrolysate-triggered stomatal closure in Arabidopsis

Immune responses are initiated when pattern recognition receptors (PRRs) detect microbial molecular patterns. One such response is stomatal closure, which restricts the entry of bacterial pathogens into plants. We previously found that the fucoidan enzymatic hydrolysate (FEH) prepared from Sargassum hemiphyllum acts as a non-microbial elicitor, triggering various immune responses in Arabidopsis. However, the signaling mechanisms underlying FEH-triggered immunity remain unexplored. In this study, we show that the anion channel SLAC1 is essential for FEH-induced stomatal immunity in Arabidopsis. However, FEH signaling bypasses CERK1, which perceives chitin and several carbohydrate ligands, as well as BAK1, which functions as a co-receptor for multiple PRRs. Instead, the cytoplasmic kinase BIK1 and ubiquitin ligases ATL31/6 (regulators of BIK1 stability) were essential, with bik1 and atl31/6 mutants showing impaired FEH-induced stomatal closure. Additionally, FEH treatment promotes the degradation of CPK28. Together, these findings reveal a distinct FEH recognition mechanism engaging conserved signaling components (BIK1, ATL31/6) and SLAC1 to activate stomatal immunity, highlighting an unidentified recognition receptor complex for this non-microbial polysaccharide elicitor. This work advances understanding of plant immune diversification and FEH's potential as an agricultural protectant.

Molecular Insights into Rice Immunity: Unveiling Mechanisms and Innovative Approaches to Combat Major Pathogens

Rice (Oryza sativa) is a globally important crop that plays a central role in maintaining food security. This scientific review examines the critical role of genetic disease resistance in protecting rice yields, dissecting at the molecular level how rice plants detect and respond to pathogen attacks while evaluating modern approaches to developing improved resistant varieties. The analysis covers single-gene-mediated and multi-gene resistance systems, detailing how on one hand specific resistance proteins, defense signaling components, and clustered loci work together to provide comprehensive protection against a wide range of pathogens and yet their production is severely impacted by pathogens such as Xanthomonas oryzae (bacterial blight) and Magnaporthe oryzae (rice blast). The discussion extends to breakthrough breeding technologies currently revolutionizing rice improvement programs, including DNA marker-assisted selection for accelerating traditional breeding, gene conversion methods for introducing new resistance traits, and precision genome editing tools such as CRISPR/Cas9 for enabling targeted genetic modifications. By integrating advances in molecular biology and genomics, these approaches offer sustainable solutions to safeguard rice yields against evolving pathogens.

OsEDS1 and OsPAD4 Are Involved in Brown Planthopper Resistance in Rice

The crucial roles of the lipase-like protein enhanced disease susceptibility 1 (EDS1) and phytoalexin deficient 4 (PAD4) in disease resistance in Arabidopsis have been identified. However, their function in rice (Oryza sativa L.) resistance to brown planthopper (BPH, Nilaparvata lugens Stål), the most notorious pest of rice, remains unknown. In this study, the transcript levels of OsEDS1 and OsPAD4 were rapidly altered by BPH infestation. Mutation in either OsPAD4 or OsEDS1 resulted in increased rice susceptibility to BPH, which was associated with increased honeydew excretion and an increased host preference of BPH. Furthermore, mutation in either OsPAD4 or OsEDS1 led to decreased basal levels of salicylic acid (SA) and jasmonic acid (JA) in the absence of BPH, along with the depressed expression of the defense-responsive genes OsPAL, OsICS1, OsPR1a, OsLOX1, OsAOS1 and OsJAZ11 involved in SA and JA biosynthesis and signaling. The BPH infestation-mediated elevation of SA levels and the expression of SA biosynthesis and signaling genes was dampened in eds1 and pad4 plants, whereas BPH infestation-mediated depressions of JA levels and the expression of JA biosynthesis and signaling genes were reversed in eds1 and pad4 plants. Taken together, our findings indicated that both OsPAD4 and OsEDS1 positively regulate rice resistance to BPH.

Exploring effector candidates in Rhynchosporium commune: insights into their expression dynamics during barley infection

Rhynchosporium commune is a fungal pathogen responsible for causing scald disease in barley, leading to significant yield losses and reduced grain quality in susceptible cultivars. Effector proteins secreted by R. commune play crucial roles in manipulating host defenses and facilitating infection. Hence, this study aimed to identify and characterize effector candidates (ECs) in R. commune using a comprehensive bioinformatics approach combined with experimental validation. Initially, a dataset of 12,211 genes from the R. commune strain UK7 genome was analyzed to identify potential ECs, resulting in the selection of 48 candidate proteins. These candidates were further validated using RNA-Seq analysis, which confirmed significant expression of 27 ECs during infection. Our analysis re-identified key effectors, including CZT06923 and CZT13833, with 100% identity to NIP3 and NIP2, respectively, in R. commune. Novel ECs, such as CZT07600, CZT13755, and CZT13375, were identified with lower identity to NIP2, suggesting potential variants. Additionally, structural analysis revealed that CZT07873 EC indicates significant structural similarity to known fungal effector. qRT-PCR validation confirmed the differential expression of CZS93219 and CZT13755, with peak expression at 9 and 12 dpi, respectively. This comprehensive approach enhances our understanding of R. commune's pathogenic mechanisms and provides insights into potential targets for developing disease management strategies in barley cultivation.

The Magnaporthe oryzae effector MoCHT1 targets and stabilizes rice OsLLB to suppress jasmonic acid synthesis and enhance infection

Rice blast disease caused by Magnaporthe oryzae (M. oryzae) poses a serious threat to rice security worldwide. This filamentous pathogen modulates rice defense responses by secreting effectors to facilitate infection. The phytohormone jasmonic acid (JA) plays crucial roles in the response to rice blast fungus, however, how M. oryzae disrupts JA-mediated resistance in rice is not well understood. In this study, we identify a new effector, a chloroplast-targeting protein (MoCHT1), from M. oryzae. Knocking out MoCHT1 decreases virulence, whereas heterologous expression of MoCHT1 in rice compromises disease resistance. MoCHT1 interacts with a rice LESION AND LAMINA BENDING (OsLLB) protein, a negative regulator of JA biosynthesis in the chloroplast. Loss-of-function of OsLLB leads to increased JA accumulation, thereby improving resistance to rice blast. The interaction between MoCHT1 and OsLLB results in the inhibition of OsLLB degradation, consequently reducing JA accumulation, thereby impairing JA content and decreasing plant disease resistance. Overall, this study reveals the molecular mechanism by which M. oryzae utilizes MoCHT1 to subvert rice JA signaling, broadening our understanding of how pathogens circumvent host immune responses by manipulating plant defense hormone biosynthesis.

Genome-wide identification and characterization of pathogenesis related protein 1 gene family in Brassica juncea

Pathogenesis related protein 1 (PR1) family are key players of plant defence response against pathogens, however, their role in Brassica juncea is not fully understood. Here, we performed genome wide identification and characterization of PR1 gene family in B. juncea. A total of 43 members of BjuPR1 gene family were identified in mustard genome, designated as BjuPR1-1 to BjuPR1-43. Based on phylogenetic analysis, Bju-PR1 proteins were grouped into five primary clusters (I-V) according to their conserved motifs and gene structures. The BjuPR1 genes consist of 1 to 5 coding exons, and a total of 10 conserved motifs have been identified, with motif 2 appearing in nearly all PR1 proteins. Domain analysis revealed that CAP domain is highly conserved across BjuPR1 proteins along with caveolin-binding motif (CMD), and CAPE cleavage motif. Chromosomal mapping showed that 43 BjuPR1 genes were distributed on 13 of the 18 mustard chromosomes. Promoter analysis of BjuPR1 gene family showed multiple growth, hormone-responsive, biotic and abiotic stress-responsive elements. Expression analysis showed distinct expression pattern of BjuPR1 after biotic, abiotic and hormonal treatments. This study provides comprehensive information on PR1 gene family in B. juncea which can be further used for their functional validation.

Physiological and molecular profiling unveils oat (Avena sativa L.) defense mechanisms against powdery mildew

Oat powdery mildew, caused by Blumeria graminis f. sp. avenae (Bga), poses a serious threat to oat production, yet the underlying resistance mechanisms remain largely unclear. In this study, we investigated early-stage defense responses in resistant (BY642) and susceptible (BY119) oat varieties following Bga inoculation using cytological observations, physiological and hormonal measurements, and transcriptomic analysis. Microscopy revealed that Bga penetrates oat tissues directly through epidermal cells rather than stomata. BY642 exhibited a rapid and robust defense characterized by reactive oxygen species (ROS) accumulation and hypersensitive response, tightly regulated by an efficient antioxidant system to prevent cellular damage. Hormone profiling indicated a salicylic acid (SA)-dominated signaling pathway in BY642, accompanied by suppression of jasmonic acid (JA) responses. Transcriptome profiling showed early activation of photosynthesis-related pathways, metabolic reprogramming, and immune-related networks, including MAPK cascades and WRKY transcription factors. Hub genes such as AsGSTU6 and AsWRKY50 were identified as key contributors to resistance. These findings suggest that BY642 employs a coordinated defense strategy integrating ROS dynamics, SA signaling, and transcriptional regulation, providing novel insights into the molecular basis of powdery mildew resistance and potential targets for oat breeding.

PcMYB44 regulated host resistance to Botryosphaeria dothidea through activation of lignin biosynthesis and disease-resistance gene expression in pear

Pear ring rot disease, the pathogen of Botryosphaeria dothidea causes significant threat to the healthy development of the pear industry, therefore the exploration of disease-resistant gene resources is crucial for disease prevention and control. Members of the R2R3-MYB subfamily play important roles in regulating pathogen resistance in plants, however the gene function in regulating host resistance in pear remains unclear. In this study, the role of PcMYB44 were investigated in regulating host resistance disease in pear calli using both forward and reverse genetic approaches. Overexpression of PcMYB44 positively regulates the disease resistance, whereas knockout of PcMYB44 results in a phenotype with decreased resistance. Our results further demonstrated that PcMYB44 could directly affect lignin content and resistance to fungal diseases by regulating the PcmiR397-PcLACs module and lignin biosynthesis gene expression levels. Additionally, overexpressing PcMYB44 also elevated expression levels of key genes of JA/SA/ET pathway. The obtained results revealed that PcMYB44 regulated host resistance to ring rot disease through synergistic regulation the lignification and activating disease-resistance gene expression of JA/SA/ET defense pathways as a underlying secondary mechanism, which provide valuable genetic resources for molecular breeding for disease resistance.

The Boeremia exigua BeAA9 Lytic Polysaccharide Monooxygenase Is a Key Virulence Factor in Mulberry Infection

Boeremia exigua, a phytopathogen responsible for spot diseases on leaves and stems, significantly threatens the health of a wide range of plants. Understanding its pathogenic mechanisms is essential for effective mulberry disease control. In this study, B. exigua GXH1 was isolated from mulberry leaves exhibiting symptoms of spot disease. Infection of mulberry seedlings by B. exigua led to significantly increased levels of defense enzyme activities (superoxide dismutase, peroxidase, catalase, phenylalanine ammonia-lyase), indicating that B. exigua triggers a strong immune response in the host. B. exigua infection in mulberry leaves resulted in abundant hyphae and vesicular structures in the intercellular spaces and epidermal layers. Whole-genome sequencing of B. exigua unveiled a 34.33 Mb genome containing 12,060 coding genes, including a notable abundance of carbohydrate-active enzymes. Transcriptome analysis during mulberry infection revealed 509 upregulated and 335 downregulated genes, with a particular enrichment in genes related to carbohydrate metabolism and redox processes. Notably, the lytic polysaccharide monooxygenase AUXILIARY ACTIVITY FAMILY 9 gene (BeAA9), which is localized to the plasma membrane, was highly upregulated in mulberry leaves infested by B. exigua. Knockout of BeAA9 led to a significant reduction in the pathogenicity of B. exigua. Furthermore, BeAA9 transient expression in Nicotiana benthamiana suppressed BCL2 Associated X Protein (BAX)-induced cell death and reactive oxygen species bursts, while its overexpression diminished plant resistance to Botrytis cinerea and downregulated the expression of plant immune genes. These findings identify BeAA9 as a key virulence factor in B. exigua GXH1, shedding light on its role in suppressing plant immunity.

Systems Biology of Streptophyte Cell Evolution

More than 500 million years ago, a streptophyte algal population established a foothold on land and started terraforming Earth through an unprecedented radiation. This event is called plant terrestrialization and yielded the Embryophyta. Recent advancements in the field of plant evolutionary developmental biology (evo-devo) have propelled our knowledge of the closest algal relatives of land plants, the zygnematophytes, highlighting that several aspects of plant cell biology are shared between embryophytes and their sister lineage. High-throughput exploration determined that routes of signaling cascades, biosynthetic pathways, and molecular physiology predate plant terrestrialization. But how do they assemble into biological programs, and what do these programs tell us about the principal functions of the streptophyte cell? Here, we make the case that streptophyte algae are unique organisms for understanding the systems biology of the streptophyte cell, informing on not only the origin of embryophytes but also their fundamental biology.

Evolutional, expressional and functional analysis of WRKY gene family reveals that PbeWRKY16 and PbeWRKY31 contribute to the Valsa canker resistance in Pyrus betulifolia

The WRKY transcription factor family plays a crucial role in regulating plant growth and stress responses. However, there are few studies on the regulation of resistance to Valsa canker. In this study, a comprehensive analysis of WRKY genes across 19 plant species was conducted. The potential members of Valsa canker resistance regulation were identified via functional validation. A total of 1641 WRKY genes could be categorized into seven groups. WRKY family members show subfamily- and species-specific expansions. In Rosaceae, Group II-d and II-e were rapidly expanded, which mainly originated based from whole genome duplication (WGD). Cis-element analysis and protein interaction network prediction underscored that most WRKYs respond to stress signals. Based on expressional investigation and Weighted Gene Co-expression Network Analysis (WGCNA), 9 WRKY genes in Pyrus betulaefolia were screened as candidates for Valsa canker resistance regulation. Functional analysis further demonstrated that PbeWRKY16 and PbeWRKY31 regulate the expression of genes involved in salicylic acid (SA) biosynthesis and transport, thereby enhancing resistance to Valsa canker and activating immune responses. Our results provide a foundation for understanding the evolutionary mechanisms of the WRKY gene family and screened potential family members on Valsa canker resistance regulation.

Enhancing plant resistance to tobacco mosaic virus through the combined application of Verticillium dahliae Aspf2-like protein and microelements

BACKGROUND

Tobacco mosaic virus (TMV) poses a significant threat to global agriculture, infecting economically vital crops such as tobacco, tomato, pepper, and potato. Previous studies have suggested that the Verticillium dahliae Aspf2-like protein (VDAL) enhances plant resistance to TMV. This study investigated the preventive and therapeutic effects of VDAL, with and without microelements, on TMV resistance by analyzing plant hormone levels, defense related enzyme activities, and transcriptomic responses.

RESULTS

Plants were subjected to six experimental treatments: CK0 (untreated control, no TMV or VDAL treatment), CK (TMV inoculated control), T1 (preventive VDAL treatment), T2 (preventive VDAL + microelements), CT1 (therapeutic VDAL treatment), and CT2 (therapeutic VDAL + microelements). TMV inoculation (CK) significantly increased (P < 0.05) TMV content, jasmonic acid (JA), salicylic acid (SA) levels, and activities of defense related enzymes, including benzoic acid 2-hydroxylase (BA2H), peroxidase (POD), polyphenol oxidase (PPO), and superoxide dismutase (SOD), compared to CK0. Both preventive treatments (T1 and T2) effectively reduced TMV content and enhanced JA, SA, and defense related enzyme activities. Notably, the microelement-supplemented preventive treatment (T2) showed 37.73% greater reduction in TMV content compared to T1. Similarly, the therapeutic applications, CT2 reduced the TMV content by 32.50% than CT1. Treatments T2 and CT2 also increased the contents of JA by 5.48% and 2.88%, respectively compared to their respective controls. Transcriptomic analysis revealed that these treatments activated plant-pathogen interaction pathways and pathogen-associated molecular pattern-triggered immunity (PTI), with significant upregulation of key defense related genes (e.g., CALM, BAK1, PTI6, and WRKY33), indicating a robust antiviral defense response.

CONCLUSION

Overall, we conclude that the synergistic application of VDAL and microelements significantly enhances plant resistance to TMV through coordinated activation of phytohormone signaling, defense enzymes, and immune-related gene expression. This combined approach offers an effective, eco-friendly alternative for sustainable management of viral diseases in agricultural crops. © 2025 Society of Chemical Industry.

Enhanced Disease Susceptibility1 Regulates Immune Response in Lotus japonicus

Enhanced disease susceptibility1 (EDS1) is a key node in the plant immune signaling network, regulating salicylic acid (SA) levels and other immune responses in Arabidopsis thaliana. We previously reported that modulation of SA by AGD2-like defense response protein 1 (ALD1) has been shown to influence the immune response in Lotus japonicus, but the role of LjEDS1 in this species remains unclear. Here, we identified and characterized the LjEDS1 gene in L. japonicus. The LjEDS1 protein contains a lipase-like domain and an EP domain similar to the Arabidopsis EDS1 protein. Subcellular localization studies revealed that the LjEDS1 protein is distributed in both the cytoplasm and nucleus. Heterologous expression of LjEDS1 in the Arabidopsis ateds1 mutant increased resistance to Pseudomonas syringae pv. Tomato (Pst) strain DC3000. In L. japonicus, roots of the ljeds1 mutants exhibited heightened susceptibility to Ralstonia solanacearum, with increased lesion areas and bacterial titers. Conversely, the overexpression of LjEDS1 reduced the lesion areas and bacterial titers in roots infected with R. solanacearum compared to those in the wild-type. Gene expression analysis showed that LjEDS1 regulates defense-related, basal immunity, and oxidative stress response genes in L. japonicus roots. These findings establish LjEDS1 as an important regulator of disease resistance in L. japonicus.

Endophytic and Rhizospheric Microorganisms: An Alternative for Sustainable, Organic, and Regenerative Bioinput Formulations for Modern Agriculture

Large amounts of chemical fertilizers are still used to suppress pathogens and boost agricultural productivity and food generation. However, their use can cause harmful environmental imbalance. Furthermore, plants typically absorb limited amounts of the nutrients provided by chemical fertilizers. Recent studies are recommending the use of microbiota present in the soil in different formulations, considering that several microorganisms are found in nature in association with plants in a symbiotic, antagonistic, or synergistic way. This ecological alternative is positive because no undesirable significant alterations occur in the environment while stimulating plant nutrition development and protection against damage caused by control pathogens. Therefore, this review presents a comprehensive discussion regarding endophytic and rhizospheric microorganisms and their interaction with plants, including signaling and bio-control processes concerning the plant's defense against pathogenic spread. A discussion is provided about the importance of these bioinputs as a microbial resource that promotes plant development and their sustainable protection methods aiming to increase resilience in the agricultural system. In modern agriculture, the manipulation of bioinputs through Rhizobium contributes to reducing the effects of greenhouse gases by managing nitrogen runoff and decreasing nitrous oxide. Additionally, mycorrhizal fungi extend their root systems, providing plants with greater access to water and nutrients.

The Magnaporthe oryzae effector MoBys1 suppresses rice immunity by targeting OsCAD2 to manipulate host jasmonate and lignin metabolism

Rice blast disease caused by Magnaporthe oryzae poses a severe threat to rice production. To counteract M. oryzae, plants synthesize jasmonate (JA) and lignin, two primary defense-related metabolites, to initiate defense programs. However, the mechanism through which M. oryzae modulates JA- and lignin-mediated plant immunity remains unclear. In this study, a novel M. oryzae effector, MoBys1, was identified as being involved in pathogenesis. Knockout of MoBys1 in M. oryzae significantly reduced its infection ability. Conversely, overexpression of MoBys1 in rice impaired the rice defense response. MoBys1 localizes to the plant cytoplasm and nucleus and interacts with rice cinnamyl alcohol dehydrogenase 2 (OsCAD2), an enzyme that catalyzes lignin biosynthesis. While OsCAD2 mutants exhibited weakened defenses, overexpression lines demonstrated enhanced resistance, highlighting the critical role of OsCAD2 in blast resistance. Furthermore, OsCAD2 functions as a transcription factor regulating a wide range of biological processes, including JA and lignin signaling pathways. The interaction between MoBys1 and OsCAD2 promotes OsCAD2 degradation, leading to reduced lignin and JA accumulation. These findings uncover a novel counter-defense mechanism by which M. oryzae employs the effector MoBys1 to degrade OsCAD2 and suppress host defense-related metabolite accumulation during infection.

Plant Signaling Hormones and Transcription Factors: Key Regulators of Plant Responses to Growth, Development, and Stress

Plants constantly encounter a wide range of biotic and abiotic stresses that adversely affect their growth, development, and productivity. Phytohormones such as abscisic acid, jasmonic acid, salicylic acid, and ethylene serve as crucial regulators, integrating internal and external signals to mediate stress responses while also coordinating key developmental processes, including seed germination, root and shoot growth, flowering, and senescence. Transcription factors (TFs) such as WRKY, NAC, MYB, and AP2/ERF play complementary roles by orchestrating complex transcriptional reprogramming, modulating stress-responsive genes, and facilitating physiological adaptations. Recent advances have deepened our understanding of hormonal networks and transcription factor families, revealing their intricate crosstalk in shaping plant resilience and development. Additionally, the synthesis, transport, and signaling of these molecules, along with their interactions with stress-responsive pathways, have emerged as critical areas of study. The integration of cutting-edge biotechnological tools, such as CRISPR-mediated gene editing and omics approaches, provides new opportunities to fine-tune these regulatory networks for enhanced crop resilience. By leveraging insights into transcriptional regulation and hormone signaling, these advancements provide a foundation for developing stress-tolerant, high-yielding crop varieties tailored to the challenges of climate change.

A novel key virulence factor, FoSSP71, inhibits plant immunity and promotes pathogenesis in Fusarium oxysporum f. sp. cubense

Fusarium wilt of banana (Musa spp.), caused by Fusarium oxysporum f. sp. cubense (Foc), poses a significant threat to the global banana industry. Particularly, tropical race 4 of Foc exhibits high pathogenicity toward the major commercial banana cultivar Cavendish, and there are no effective control measures available. Here, we characterize a novel effector protein, FoSSP71, from Foc, which was significantly induced during the early stages of the Foc4 banana interaction and could suppress BAX-triggered programmed cell death in Nicotiana benthamiana. Transient expression of FoSSP71 in N. benthamiana leaves could weaken the upregulation expression of genes involved in the SA signaling pathway induced by flg22 and significantly reduce both reactive oxygen species bursts and callose accumulation. To verify the function of FoSSP71, a FoSSP71 deletion mutant was created. The FoSSP71 deletion mutant displayed a reduced growth rate in F. oxysporum and a marked reduction in virulence toward bananas compared to the wild type (WT). Furthermore, the expression levels of PR3 and PR10 were significantly downregulated in bananas infected with the ΔFoSSP71 strain compared to bananas infected with the WT strain. These findings indicate that FoSSP71 is essential for Foc4 pathogenicity and plays a key virulence role during Fusarium invasion. Therefore, FoSSP71 presents a potential target for future Fusarium wilt control, offering a scientific foundation for breeding disease-resistant banana varieties and developing novel control measures.IMPORTANCEEffector proteins are critical virulence factors for fungi, playing essential roles during the fungal infection of plants. In this study, we identified a novel effector protein, FoSSP71, which is an important regulatory protein involved in the invasion of bananas by Fusarium oxysporum f. sp. cubense race 4 (Foc4). Understanding its regulatory mechanisms is necessary. Our research indicates that FoSSP71 is an essential virulence factor for Foc4, as it suppresses plant immune responses by inhibiting the accumulation of reactive oxygen species and callose. The Foc4 mutant lacking FoSSP71 showed significantly reduced pathogenicity toward bananas, demonstrating that FoSSP71 is a potential target for controlling banana wilt disease. These findings provide a scientific basis for breeding banana varieties resistant to wilt disease and for developing new disease control strategies, which are crucial for the sustainable development of the global banana industry.

Transcriptomic analysis of early stages of 'Candidatus Liberibacter asiaticus' infection in susceptible and resistant species after inoculation by Diaphorina citri feeding on young shoots

Huanglongbing (HLB) is a devastating disease of citrus plants caused by the non-culturable phloem-inhabiting bacterium Candidatus Liberibacter ssp., being Ca. Liberibacter asiaticus (CLas) the most aggressive species. CLas is vectored by the psyllid Diaphorina citri and introduced into sieve cells, establishing a successful infection in all Citrus species. Partial or complete resistance has been documented in the distant relatives Murraya paniculata and Bergera koenigii, respectively, providing excellent systems to investigate the molecular basis of HLB-resistance. It has been shown previously that the first weeks after bacterial release into the phloem are critical for the establishment of the bacterium. In this study, a thorough transcriptomic analysis of young flushes exposed to CLas-positive and negative psyllids has been performed in Citrus × sinensis, as well as in the aforementioned resistant species, along the first eight weeks after exposure. Our results indicate that the resistant species do not deploy a classical immunity response upon CLas recognition. Instead, transcriptome changes are scarce and only a few genes are differentially expressed when flushes exposed to CLas-positive and negative psyllid are compared. Functional analysis suggests that primary metabolism and other basic cellular functions could be rewired in the resistant species to limit infection. Transcriptomes of young flushes of the three species are very different, supporting the existence of distinct biochemical niches for the bacterium. These findings suggest that both intrinsic metabolic inadequacies to CLas survival, as well as inducible reprogramming of physiological functions upon CLas recognition, could orchestrate together restriction of bacterial multiplication in these resistant hosts.

Structural and Functional Analysis of the Lectin-like Protein Llp1 Secreted by Ustilago maydis upon Infection of Maize

The biotrophic fungus Ustilago maydis, which causes smut disease in maize, secretes numerous proteins upon plant colonization. Some of them, termed effectors, help to evade plant defenses and manipulate cellular processes within the host. The function of many proteins specifically secreted during infection remains elusive. In this study, we biochemically characterized one such protein, UMAG_00027, that is highly expressed during plant infection. We show that UMAG_00027 is a secreted protein with a lectin-like fold and therefore term it Llp1 (lectin-like-protein 1). Llp1 decorated the fungal cell wall of cells grown in axenic culture or proliferating in planta, which is in agreement with its potential sugar-binding ability. We were unable to identify the precise sugar moieties that are bound by Llp1. CRISPR/Cas9-mediated deletion of llp1 reveals that the gene is not essential for fungal virulence. A structural search shows the presence of several other lectin-like proteins in U. maydis that might compensate for the function of Llp1 in ∆llp1 mutants. We therefore speculate that Llp1 is part of a family of lectin-like proteins with redundant functions.

Modulation of plant transcription factors and priming of stress tolerance by plant growth-promoting bacteria: a systematic review

BACKGROUND

Plant growth-promoting bacteria (PGPB) have been shown to improve plant growth and stress tolerance through mechanisms including improved access to nutrients and biotic competition with pathogens. As such, the use of PGPB can help to address challenges to crop productivity, but information on interactions between PGPB and their plant hosts, especially at the level of gene regulation, is distributed across diverse studies involving several different plants and PGPB.

SCOPE

For this review, we analysed recent research publications reporting specifically on plant transcription factor (TF) expression in association with PGPB, to determine if there are any common findings and to identify gaps that offer opportunities for focused future research.

CONCLUSIONS

The inoculation of plants with PGPB elicits a dynamic and temporal response. Initially, there is an upregulation of defence-responsive TFs, followed by their downregulation in an intermediate phase, and finally, another upregulation, providing longer term stress tolerance. PGPB priming activates plant defences in the form of induced systemic resistance (ISR), often via the MAMP/MAPK pathways and involving one or more of the major plant hormone-signalling pathways and their crosstalk. Following PGPB priming, the TF families most commonly reported as expressed across different plants and for different pathogens are ERF and WRKY, while the TFs most commonly expressed across different plants for different abiotic stresses are ERF and DREB. There were inconsistencies between studies regarding the timing of the shift from the initial phase to the intermediate phase, and some of the TFs expressed during this process have not been fully characterized. This calls for more research to investigate the regulatory functions and phases of TF expression, to enhance crop resilience. Most reports on abiotic stresses have focused on salinity and drought, with fewer studies addressing nutrient deficiency, heavy metals, flooding and other stresses, highlighting the need for further research in these areas.

Proteomic Landscape of Pattern Triggered Immunity in the Arabidopsis Leaf Apoplast

The apoplast is a critical interface in plant-pathogen interactions particularly in the context of pattern-triggered immunity (PTI), which is initiated by recognition of microbe-associated molecular patterns (PAMPs). Our study characterizes the proteomic profile of the Arabidopsis apoplast during PTI induced by flg22, a 22 amino acid bacterial flagellin epitope, to elucidate the output of PTI. Apoplastic washing fluid (AWF) was extracted with minimal cytoplasmic contamination for LC-MS/MS analysis. We observed consistent identification of PTI enriched and depleted peptides across replicates with limited correlation between total protein abundance and transcript abundance. We observed topological bias in peptide recovery of receptor-like kinases with peptides predominantly recovered from their ectodomains. Notably, tetraspanin 8, an exosome marker, was enriched in PTI samples. We additionally confirmed increased concentrations of exosomes during PTI. This study enhances our understanding of the proteomic changes in the apoplast during plant immune responses and lays the groundwork for future investigations into the molecular mechanisms of plant defense under recognition of pathogen molecular patterns.

Plant Defense Responses to Insect Herbivores Through Molecular Signaling, Secondary Metabolites, and Associated Epigenetic Regulation

Over millions of years of interactions, plants have developed complex defense mechanisms to counteract diverse insect herbivory strategies. These defenses encompass morphological, biochemical, and molecular adaptations that mitigate the impacts of herbivore attacks. Physical barriers, such as spines, trichomes, and cuticle layers, deter herbivores, while biochemical defenses include the production of secondary metabolites and volatile organic compounds (VOCs). The initial step in the plant's defense involves sensing mechanical damage and chemical cues, including herbivore oral secretions and herbivore-induced VOCs. This triggers changes in plasma membrane potential driven by ion fluxes across plant cell membranes, activating complex signal transduction pathways. Key hormonal mediators, such as jasmonic acid, salicylic acid, and ethylene, orchestrate downstream defense responses, including VOC release and secondary metabolites biosynthesis. This review provides a comprehensive analysis of plant responses to herbivory, emphasizing early and late defense mechanisms, encompassing physical barriers, signal transduction cascades, secondary metabolites synthesis, phytohormone signaling, and epigenetic regulation.

Comparative Proteomic Analysis of Popcorn Genotypes Identifies Differentially Accumulated Proteins Associated with Resistance Pathways to Southern Leaf Blight Disease

Southern leaf blight (SLB), caused by Bipolaris maydis, poses a significant threat to maize and popcorn production. To understand the molecular mechanisms underlying SLB resistance, we conducted a high-throughput proteomic analysis comparing SLB-resistant (L66) and SLB-susceptible (L51) popcorn genotypes at four and ten days after inoculation (DAI). A total of 717 proteins were identified, with 151 differentially accumulated proteins (DAPs) between the genotypes. Eighteen DAPs exhibited the same regulatory pattern in both the SLB-resistant and SLB-susceptible genotypes at four (R4/S4) and ten (R10/S10) DAI. The protein-protein interaction (PPI) network of differentially accumulated proteins (DAPs) linked to SLB resistance and susceptibility enriched specific metabolic pathways in the SLB response, including photosynthesis, ribosome, ascorbate and aldarate metabolism, glutathione metabolism, and carbon metabolism. Proteins such as photosystem II 11 kD protein (B4FRJ4, PSB27-1), which was up-regulated at both time points (R4/S4 and R10/S10), and 60S acidic ribosomal protein P0 (A0A1D6LEZ7, RPP0B), which was unique to the resistant genotype at both time points (R4 and R10), highlighted the importance of maintaining photosynthetic efficiency and protein synthesis during pathogen attack. Additionally, dehydroascorbate reductase like-3 (B4F817, DHAR3) was consistently up-regulated at both time points in resistant genotypes, emphasizing its role in redox balance and ROS detoxification. In contrast, glyceraldehyde-3-phosphate dehydrogenase (K7UGF5, GAPC2), a glycolytic enzyme, was unique to the susceptible genotype, suggesting its involvement in managing energy metabolism under stress conditions. Our findings suggest that resistance to SLB in popcorn involves a combination of enhanced photosynthetic repair, redox homeostasis, and ribosomal protein activity, providing new potential molecular targets, such as DHAR3 and RPP0B, for genetic improvement in SLB resistance. These results offer valuable insights into breeding programs aimed at developing SLB-resistant popcorn varieties.

PP2C Phosphatase Pic6 Suppresses MAPK Activation and Disease Resistance in Tomato

Type 2C protein phosphatases (PP2Cs) are essential for regulating plant immune responses to pathogens. Our study focuses on the tomato PP2C-immunity associated candidate 6 (Pic6), elucidating its role in negatively regulating pattern-triggered immunity (PTI) signaling pathways in tomato. Using reverse-transcription quantitative polymerase chain reaction (RT-qPCR), we observed that treatment with microbe-associated molecular patterns (MAMPs)-flg22 and flgII-28-significantly increased Pic6 mRNA levels in wild-type (RG-PtoR) tomato plants. Pic6 features a conserved N-terminal kinase-interacting motif (KIM) and a C-terminal PP2C domain. We produced variants of Pic6 with mutations in these regions, demonstrating their involvements in negatively regulating tomato immunity. Agrobacterium-mediated transient overexpression of Pic6 resulted in enhanced growth of the bacterial pathogen Pseudomonas syringae pathovar tomato (Pst) strain DC3000ΔhopQ1-1 compared with a yellow fluorescent protein (YFP) control. Additionally, Pic6 overexpression inhibited mitogen-activated protein kinase (MAPK) activation in response to flg22 and flgII-28 treatments. Importantly, Pic6 exhibited phosphatase activity and interacted with tomato Mkk1/Mkk2 proteins and dephosphorylated them in a KIM-dependent manner. Furthermore, we generated RG-pic6 loss-of-function mutants by CRISPR/Cas9, revealing that the absence of Pic6 heightened MAPK activity and increased resistance to Xanthomonas euvesicatoria strain 85-10 (Xe 85-10) when compared with the wild-type (RG-PtoR) plants. Transcript analyses showed that after flg22/flgII-28 treatment, PTI-reporter genes NAC and Osmotin were significantly upregulated in RG-pic6 mutants in comparison to the wild-type (RG-PtoR) plants. Overall, our findings indicate that Pic6 acts as a negative regulator of MAPK signaling and plays a pivotal role in modulating tomato immunity against bacterial pathogens. [Formula: see text] Copyright © 2025 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Pseudomonas syringae lytic transglycosylase HrpH interacts with host ubiquitin ligase ATL2 to modulate plant immunity

Pseudomonas syringae deploys a type III secretion system (T3SS) to deliver effector proteins to facilitate infection of plant cells; however, little is known about the direct interactions between T3SS components and plants. Here, we show that the specialized lytic transglycosylase (SLT) domain of P. syringae pv. tomato (Pst) DC3000 T3SS component HrpH is necessary for effector translocation. HrpH and its SLT domain induce host cell death and suppress pattern-triggered immunity (PTI). Transgenic hrpH-Arabidopsis plants exhibit decreased PTI responses and enhanced susceptibility to Pst DC3000ΔhrcQ-U. HrpH suppresses salicylic acid (SA) signaling and interacts with the E3 ubiquitin ligase ATL2 via its SLT domain, independent of its catalytic glutamate. ATL2 silencing indicates that ATL2 is required for basal resistance to bacterial infection, HrpH-triggered cell death, and suppressing MAPK and SA signaling. Our findings highlight that beyond serving as a lytic transglycosylase for effector delivery, HrpH targets an E3 ligase to modulate plant immunity.

Transcriptional time-course analysis during ash dieback infection revealed different responses in tolerant and susceptible Fraxinus excelsior genotypes

Hymenoscyphus fraxineus, the causal agent of Ash Dieback (ADB), has been introduced to eastern Europe in the 1990s from where it spread causing decline in European ash populations. However, the genetic basis of the molecular response in tolerant and susceptible ash trees to this disease is still largely unknown. We performed RNA-sequencing to study the transcriptomic response to the disease in four ash genotypes (ADB-tolerant FAR3 and FS36, and ADB-susceptible UW1 and UW2), during a time-course of 7, 14, 21, and 28 days post-inoculation, including mock-inoculated trees as control samples for each sampling time point. The analysis yielded 395 and 500 Differentially Expressed Genes (DEGs) along the response for ADB-tolerant FAR3 and FS36, respectively, while ADB-susceptible UW1 and UW2 revealed 194 and 571 DEGs, respectively, with most DEGs found exclusively in just one of the genotypes. DEGs shared between tolerant genotypes FAR3 and FS36, included genes involved in the production of phytoalexins and other secondary metabolites with roles in plant defense. Moreover, we identified an earlier expression of genes involved in both pattern- and effector-triggered immunity (PTI and ETI) in ADB-tolerant genotypes, while in ADB-susceptible genotypes both responses were delayed (late response). Overall, these results revealed different transcriptomic expression patterns not only between ADB-tolerant and ADB-susceptible genotypes, but also within these two groups. This hints to individual responses in the natural tolerance to ADB, possibly revealing diversified strategies across ash genotypes.

Effects of microbial biocontrol agents on tea plantation microecology and tea plant metabolism: a review

The quality of fresh tea leaves is crucial to the final product, and maintaining microbial stability in tea plantations is essential for optimal plant growth. Unique microbial communities play a critical role in shaping tea flavor and enhancing plant resilience against biotic stressors. Tea production is frequently challenged by pests and diseases, which can compromise both yield and quality. While biotic stress generally has detrimental effects on plants, it also activates defense metabolic pathways, leading to shifts in microbial communities. Microbial biocontrol agents (MBCAs), including entomopathogenic and antagonistic microorganisms, present a promising alternative to synthetic pesticides for mitigating these stresses. In addition to controlling pests and diseases, MBCAs can influence the composition of tea plant microbial communities, potentially enhancing plant health and resilience. However, despite significant advances in laboratory research, the field-level impacts of MBCAs on tea plant microecology remain insufficiently explored. This review provides insights into the interactions among tea plants, insects, and microorganisms, offering strategies to improve pest and disease management in tea plantations.

Dressed Up to the Nines: The Interplay of Phytohormones Signaling and Redox Metabolism During Plant Response to Drought

Plants must effectively respond to various environmental stimuli to achieve optimal growth. This is especially relevant in the context of climate change, where drought emerges as a major factor globally impacting crops and limiting overall yield potential. Throughout evolution, plants have developed adaptative strategies for environmental stimuli, with plant hormones and reactive oxygen species (ROS) playing essential roles in their development. Hormonal signaling and the maintenance of ROS homeostasis are interconnected, playing indispensable roles in growth, development, and stress responses and orchestrating diverse molecular responses during environmental adversities. Nine principal classes of phytohormones have been categorized: auxins, brassinosteroids, cytokinins, and gibberellins primarily oversee developmental growth regulation, while abscisic acid, ethylene, jasmonic acid, salicylic acid, and strigolactones are the main orchestrators of environmental stress responses. Coordination between phytohormones and transcriptional regulation is crucial for effective plant responses, especially in drought stress. Understanding the interplay of ROS and phytohormones is pivotal for elucidating the molecular mechanisms involved in plant stress responses. This review provides an overview of the intricate relationship between ROS, redox metabolism, and the nine different phytohormones signaling in plants, shedding light on potential strategies for enhancing drought tolerance for sustainable crop production.

Plasmodiophora brassicae Effector PbPE23 Induces Necrotic Responses in Both Host and Nonhost Plants

Plasmodiophora brassicae is an obligate biotroph that causes clubroot disease in cruciferous plants, including canola and Arabidopsis. In contrast to most known bacterial, oomycete, and fungal pathogens that colonize at the host apoplastic space, the protist P. brassicae establishes an intracellular colonization within various types of root cells and secretes a plethora of effector proteins to distinct cellular compartments favorable for the survival and growth of the pathogen during pathogenesis. Identification and functional characterization of P. brassicae effectors has been hampered by the limited understanding of this unique pathosystem. Here, we report a P. brassicae effector, PbPE23, containing a serine/threonine kinase domain, that induces necrosis after heterologous expression by leaf infiltration in both host and nonhost plants. Although PbPE23 is an active kinase, the kinase activity itself is not required for triggering necrosis in plants. PbPE23 shows a nucleocytoplasmic localization in Nicotiana benthamiana, and its N-terminal 25TPDPAQKQ32 sequence, resembling the contiguous hydrophilic TPAP motif and Q-rich region in many necrosis and ethylene inducing peptide 1-like proteins from plant-associated microbes, is required for the induction of necrosis. Furthermore, transcript profiling of PbPE23 reveals its high expression at the transition stages from primary to secondary infection, suggesting its potential involvement in the development of clubroot disease.

A novel type III effector RipBU from Ralstonia solanacearum suppresses plant immunity and promotes peanut susceptibility

A predicted peanut R. solanacearum T3E RS_T3E_Hyp6 was identified as a definite T3E and renamed as RipBU. It is relative conserved in 31 R. solanacearum strains. Deletion of RipBU in R. solanacearum HA4-1 strain caused the attenuate pathogenicity in peanut, and complementarity of RipBU recovered the virulence of ΔRipBU mutant strain. Transient expression of RipBU decreased the level of chlorophyll, resulting in leaf chlorosis and suppressed flg22-triggered reactive oxygen species (ROS) burst and the expression of pattern-triggered immunity (PTI) marker genes in the leaves of Nicotiania benthamiana. Subcellular localization observation showed that RipBU localizes to chloroplasts in tobacco cells. RipBU significantly increased the jasmonic acid (JA) content and the expressions of JA-signaling marker genes in tobacco leaves, while significantly decreased the salicylic acid (SA) level and the expressions of SA-signaling marker genes. RipBU contained a putative lipase domain, and mutation of which abolished the ability of RipBU to induce tobacco leaf chlorosis and peanut wilt, while still localized to chloroplasts. Our study reveals the virulence function of RipBU that suppresses plant immunity by inhibiting PTI and SA signaling, and promoting JA signaling.

A type II secreted subtilase from commensal rhizobacteria cleaves immune elicitor peptides and suppresses flg22-induced immune activation

Plant roots grow in association with a community of microorganisms collectively known as the rhizosphere microbiome. Immune activation in response to elicitors like the flagellin-derived epitope flg22 restricts bacteria on plant roots but also inhibits plant growth. Some commensal root-associated bacteria are capable of suppressing the plant immune response to elicitors. In this study, we investigated the ability of 165 root-associated bacteria to suppress flg22-induced immune activation and growth restriction. We demonstrate that a type II secreted subtilase, which we term immunosuppressive subtilase A (IssA), from Dyella japonica strain MF79 cleaves the immune elicitor peptide flg22 and suppresses immune activation. IssA homologs are found in other plant-associated commensals, with particularly high conservation in the order Xanthomonadales. This represents a novel mechanism by which commensal microbes modulate flg22-induced immunity in the rhizosphere microbiome.

Defense-Related Enzyme Activities and Metabolomic Analysis Reveal Differentially Accumulated Metabolites and Response Pathways for Sheath Blight Resistance in Rice

Rice sheath blight (RSB), caused by the pathogenic fungus Rhizoctonia solani, poses a significant threat to global food security. The defense mechanisms employed by rice against RSB are not well understood. In our study, we analyzed the interactions between rice and R. solani by comparing the phenotypic changes, ROS content, and metabolite variations in both tolerant and susceptible rice varieties during the early stages of fungal infection. Notably, there were distinct phenotypic differences in the response to R. solani between the tolerant cultivar Zhengdao22 (ZD) and the susceptible cultivar Xinzhi No.1 (XZ). We observed that the activities of five defense-related enzymes in both tolerant and susceptible cultivars changed dynamically from 0 to 72 h post-infection with R. solani. In particular, the activities of superoxide dismutase and peroxidase were closely associated with resistance to RSB. Metabolomic analysis revealed 825 differentially accumulated metabolites (DAMs) between the tolerant and susceptible varieties, with 493 DAMs responding to R. solani infection. Among these, lipids and lipid-like molecules, organic oxygen compounds, phenylpropanoids and polyketides, organoheterocyclic compounds, and organic acids and their derivatives were the most significantly enriched. One DAM, P-coumaraldehyde, which responded to R. solani infection, was found to effectively inhibit the growth of R. solani, Magnaporthe grisea, and Ustilaginoidea virens. Additionally, multiple metabolic pathways, including amino acid metabolism, carbohydrate metabolism, metabolism of cofactors and vitamins, and metabolism of terpenoids and polyketides, are likely involved in RSB resistance. Our research provides valuable insights into the molecular mechanisms underlying the interaction between rice and R. solani.

Harnessing Single-Cell and Spatial Transcriptomics for Crop Improvement

Single-cell and spatial transcriptomics technologies have significantly advanced our understanding of the molecular mechanisms underlying crop biology. This review presents an update on the application of these technologies in crop improvement. The heterogeneity of different cell populations within a tissue plays a crucial role in the coordinated response of an organism to its environment. Single-cell transcriptomics enables the dissection of this heterogeneity, offering insights into the cell-specific transcriptomic responses of plants to various environmental stimuli. Spatial transcriptomics technologies complement single-cell approaches by preserving the spatial context of gene expression profiles, allowing for the in situ localization of transcripts. Together, single-cell and spatial transcriptomics facilitate the discovery of novel genes and gene regulatory networks that can be targeted for genetic manipulation and breeding strategies aimed at enhancing crop yield, quality, and resilience. This review highlights significant findings from recent studies, discusses the expanding roles of these technologies, and explores future opportunities for their application in crop improvement.

The PpPep2-Triggered PTI-like Response in Peach Trees Is Mediated by miRNAs

Plant diseases diminish crop yields and put the world's food supply at risk. Plant elicitor peptides (Peps) are innate danger signals inducing defense responses both naturally and after external application onto plants. Pep-triggered defense networks are compatible with pattern-triggered immunity (PTI). Nevertheless, in complex regulatory pathways, there is crosstalk among different signaling pathways, involving noncoding RNAs in the natural response to pathogen attack. Here, we used Prunus persica, PpPep2 and a miRNA-Seq approach to show for the first time that Peps regulate, in parallel with a set of protein-coding genes, a set of plant miRNAs (~15%). Some PpPep2-regulated miRNAs have been described to participate in the response to pathogens in various plant-pathogen systems. In addition, numerous predicted target mRNAs of PpPep2-regulated miRNAs are themselves regulated by PpPep2 in peach trees. As an example, peach miRNA156 and miRNA390 probably have a role in plant development regulation under stress conditions, while others, such as miRNA482 and miRNA395, would be involved in the regulation of resistance (R) genes and sulfate-mediated protection against oxygen free radicals, respectively. This adds to the established role of Peps in triggering plant defense systems by incorporating the miRNA regulatory network and to the possible use of Peps as sustainable phytosanitary products.

Linear β-1,2-glucans trigger immune hallmarks and enhance disease resistance in plants

Immune responses in plants are triggered by molecular patterns or elicitors, recognized by plant pattern recognition receptors. Such molecular patterns are the consequence of host-pathogen interactions, and the response cascade activated after their perception is known as pattern-triggered immunity (PTI). Glucans have emerged as key players in PTI, but the ability of certain glucans to stimulate defensive responses in plants remains understudied. This work focused on identifying novel glucan oligosaccharides as molecular patterns. The ability of various microorganism-derived glucans to trigger PTI responses was tested, revealing that specific microbial-derived molecules, such as short linear β-1,2-glucans, trigger this response in plants by increasing the production of reactive oxygen species (ROS), mitogen-activated protein kinase phosphorylation, and differential expression of defence-related genes in Arabidopsis thaliana. Pre-treatments with β-1,2-glucan trisaccharide (B2G3) improved Arabidopsis defence against bacterial and fungal infections in a hypersusceptible genotype. The knowledge generated was then transferred to the monocotyledonous model species maize and wheat, demonstrating that these plants also respond to β-1,2-glucans, with increased ROS production and improved protection against fungal infections following B2G3 pre-treatments. In summary, as with other β-glucans, plants perceive β-1,2-glucans as warning signals which stimulate defence responses against phytopathogens.

Disrupted oxylipin biosynthesis mitigates pathogen infections and pest infestations in cotton (Gossypium hirsutum)

Cotton (Gossypium hirsutum) is the world's most important fiber crop, critical to global textile industries and agricultural economies. However, cotton yield and harvest quality are undermined by the challenges introduced from invading pathogens and pests. Plant-synthesized oxylipins, specifically 9-hydroxy fatty acids resulting from 9-lipoxygenase activity (9-LOX), enhance the growth and development of many microbes and pests. We hypothesized that targeted disruption of 9-LOX-encoding genes in cotton could bolster crop resilience against prominent agronomic threats. Fusarium oxysporum f. sp. vasinfectum (FOV), Aphis gossypii (cotton aphid), and tobacco rattle virus induced the expression of 9-oxylipin biosynthesis genes, suggesting that the 9-LOX gene products were susceptibility factors to these stressors. Transiently disrupting the expression of the 9-LOX-encoding genes by virus-induced gene silencing significantly reduced target transcript accumulation, and this correlated with impaired progression of FOV infections and a significant decrease in the fecundity of cotton aphids. These findings emphasize that the cotton 9-LOX-derived oxylipins are leveraged by multiple pathogens and pests to enhance their virulence in cotton, and reducing the expression of 9-LOX-encoding genes can benefit cotton crop vitality.

Distinct profiles of plant immune resilience revealed by natural variation in warm temperature-modulated disease resistance among Arabidopsis accessions

Elevated temperature suppresses the plant defence hormone salicylic acid (SA) by downregulating the expression of master immune regulatory genes CALMODULIN BINDING PROTEIN 60-LIKE G (CBP60g) and SYSTEMIC ACQUIRED RESISTANCE DEFICIENT1 (SARD1). However, previous studies in Arabidopsis thaliana plants have primarily focused on the accession Columbia-0 (Col-0), while the genetic determinants of intraspecific variation in Arabidopsis immunity under elevated temperature remain unknown. Here we show that BASIC HELIX LOOP HELIX 059 (bHLH059), a thermosensitive SA regulator at nonstress temperatures, does not regulate immune suppression under warmer temperatures. In agreement, temperature-resilient and -sensitive Arabidopsis accessions based on disease resistance to the bacterial pathogen Pseudomonas syringae pv. tomato (Pst) DC3000 did not correlate with bHLH059 polymorphisms. Instead, we found that temperature-resilient accessions exhibit varying CBP60g and SARD1 expression profiles, potentially revealing CBP60g/SARD1-dependent and independent mechanisms of immune resilience to warming temperature. We identified thermoresilient accessions that exhibited either temperature-sensitive or -insensitive induction of the SA biosynthetic gene ICS1 (direct target gene of CBP60g and SARD1) and SA hormone levels. Collectively, this study has unveiled the intraspecific diversity of Arabidopsis immune responses under warm temperatures, which could aid in predicting plant responses to climate change and provide foundational knowledge for climate-resilient crop engineering.

Dual Transcriptome Analysis Reveals the Changes in Gene Expression in Both Cotton and Verticillium dahliae During the Infection Process

Cotton is often threatened by Verticillium wilt caused by V. dahliae. Understanding the molecular mechanism of V. dahlia-cotton interaction is important for the prevention of this disease. To analyze the transcriptome profiles in V. dahliae and cotton simultaneously, the strongly pathogenic strain Vd592 was inoculated into cotton, and the infected cotton roots at 36 h and 3 d post infection were subjected to dual RNA-seq analysis. For the V. dahliae, transcriptomic analysis identified 317 differentially expressed genes (DEGs) encoding classical secreted proteins, which were up-regulated at least at one time point during infection. The 317 DEGs included 126 carbohydrate-active enzyme (CAZyme) and 108 small cysteine-rich protein genes. A pectinesterase gene (VDAG_01782) belonging to CAZyme, designated as VdPE1, was selected for functional validation. VdPE1 silencing by HIGS (host-induced gene silencing) resulted in reduced disease symptoms and the increased resistance of cotton to V. dahliae. For the cotton, transcriptomic analysis found that many DEGs involved in well-known disease resistance pathways (flavonoid biosynthesis, plant hormone signaling, and plant-pathogen interaction) as well as PTI (pattern-triggered immunity) and ETI (effector-triggered immunity) processes were significantly down-regulated in infected cotton roots. The dual RNA-seq data thus potentially connected the genes encoding secreted proteins to the pathogenicity of V. dahliae, and the genes were involved in some disease resistance pathways and PTI and ETI processes for the susceptibility of cotton to V. dahliae. These findings are helpful in the further characterization of candidate genes and breeding resistant cotton varieties via genetic engineering.

A novel protein elicitor (Cs08297) from Ciboria shiraiana enhances plant disease resistance

Ciboria shiraiana is a necrotrophic fungus that causes mulberry sclerotinia disease resulting in huge economic losses in agriculture. During infection, the fungus uses immunity elicitors to induce plant tissue necrosis that could facilitate its colonization on plants. However, the key elicitors and immune mechanisms remain unclear in C. shiraiana. Herein, a novel elicitor Cs08297 secreted by C. shiraiana was identified, and it was found to target the apoplast in plants to induce cell death. Cs08297 is a cysteine-rich protein unique to C. shiraiana, and cysteine residues in Cs08297 were crucial for its ability to induce cell death. Cs08297 induced a series of defence responses in Nicotiana benthamiana, including the burst of reactive oxygen species (ROS), callose deposition, and activation of defence-related genes. Cs08297 induced-cell death was mediated by leucine-rich repeat (LRR) receptor-like kinases BAK1 and SOBIR1. Purified His-tagged Cs08297-thioredoxin fusion protein triggered cell death in different plants and enhanced plant resistance to diseases. Cs08297 was necessary for sclerotial development, oxidative-stress adaptation, and cell wall integrity but negatively regulated virulence of C. shiraiana. In conclusion, our results revealed that Cs08297 is a novel fungal elicitor in fungi inducing plant immunity. Furthermore, its potential to enhance plant resistance provides a new target to control agricultural diseases biologically.

Interactive regulation of immune-related resistance genes with salicylic acid and jasmonic acid signaling in systemic acquired resistance in the Xanthomonas-Brassica pathosystem

Pathogen-responsive immune-related genes (resistance genes [R-genes]) and hormones are crucial mediators of systemic acquired resistance (SAR). However, their integrated functions in regulating SAR signaling components in local and distal leaves remain largely unknown. To characterize SAR in the Xanthomonas campestris pv. campestris (Xcc)-Brassica napus pathosystem, the responses of R-genes, (leaf and phloem) hormone levels, H2O2 levels, and Ca2+ signaling-related genes were assessed in local and distal leaves of plants exposed to four Xcc-treatments: Non-inoculation (control), only secondary Xcc-inoculation in distal leaves (C-Xcc), only primary Xcc-inoculation in local leaves (Xcc), and both primary and secondary Xcc-inoculation (X-Xcc). The primary Xcc-inoculation provoked disease symptoms as evidenced by enlarged destructive necrosis in the local leaves of Xcc and X-Xcc plants 7 days post-inoculation. Comparing visual symptoms in distal leaves 5 days post-secondary inoculation, yellowish necrotic lesions were clearly observed in non Xcc-primed plants (C-Xcc), whereas no visual symptom was developed in Xcc-primed plants (X-Xcc), demonstrating SAR. Pathogen resistance in X-Xcc plants was characterized by distinct upregulations in expression of the PAMP-triggered immunity (PTI)-related kinase-encoding gene, BIK1, the (CC-NB-LRR-type) R-gene, ZAR1, and its signaling-related gene, NDR1, with a concurrent enhancement of the kinase-encoding gene, MAPK6, and a depression of the (TIR-NB-LRR-type) R-gene, TAO1, and its signaling-related gene, SGT1, in distal leaves. Further, in X-Xcc plants, higher salicylic acid (SA) and jasmonic acid (JA) levels, both in phloem and distal leaves, were accompanied by enhanced expressions of the SA-signaling gene, NPR3, the JA-signaling genes, LOX2 and PDF1.2, and the Ca2+-signaling genes, CAS and CBP60g. However, in distal leaves of C-Xcc plants, an increase in SA level resulted in an antagonistic depression of JA, which enhanced only SA-dependent signaling, EDS1 and NPR1. These results demonstrate that primary Xcc-inoculation in local leaves induces resistance to subsequent pathogen attack by upregulating BIK1-ZAR1-mediated synergistic interactions with SA and JA signaling as a crucial component of SAR.

Exploring the role of levan in plant immunity to pathogens: A review

This review article delves into the intricate relationship between levan, a versatile polysaccharide, and its role in enhancing plant resistance against pathogens. By exploring the potential applications of levan in agriculture and biotechnology, such as crop protection, stress tolerance enhancement, and biotechnological innovations, significant advancements in sustainable agriculture are uncovered. Despite challenges in optimizing application methods and addressing regulatory hurdles, understanding the mechanisms of levan-mediated plant immunity offers promising avenues for future research. This review underscores the implications of utilizing levan to develop eco-friendly solutions, reduce reliance on chemical pesticides, and promote sustainable agricultural practices. Ultimately, by unraveling the pivotal role of levan in plant-pathogen interactions, this review sets the stage for transformative innovations in agriculture and highlights the path towards a more resilient and sustainable agricultural future.

CmPIF8-CmERF27-CmACS10-mediated ethylene biosynthesis modulates red light-induced powdery mildew resistance in oriental melon

Powdery mildew is a serious fungal disease in protected melon cultivation that affects the growth, development and production of melon plants. Previous studies have shown that red light can improve oriental melon seedlings resistance to powdery mildew. Here, after inoculation with Podosphaera xanthii, an obligate fungal pathogen eliciting powdery mildew, we found that red light pretreatment increased ethylene production and this improved the resistance of melon seedlings to powdery mildew, and the ethylene biosynthesis gene CmACS10 played an important role in this process. By analysing the CmACS10 promoter, screening yeast one-hybrid library, it was found that CmERF27 positively regulated the expression of CmACS10, increased powdery mildew resistance and interacted with PHYTOCHROME INTERACTING FACTOR8 (CmPIF8) at the protein level to participate in the regulation of ethylene biosynthesis to respond to the red light-induced resistance to P. xanthii, Furthermore, CmPIF8 also directly targeted the promoter of CmACS10, negatively participated in this process. In summary, this study revealed the specific mechanism by which the CmPIF8-CmERF27-CmACS10 module regulates red light-induced ethylene biosynthesis to resist P. xanthii infection, elucidate the interaction between light and plant hormones under biological stress, provide a reference and genetic resources for breeding of disease-resistant melon plants.

Regulatory balance between ear rot resistance and grain yield and their breeding applications in maize and other crops

BACKGROUND

Fungi are prevalent pathogens that cause substantial yield losses of major crops. Ear rot (ER), which is primarily induced by Fusarium or Aspergillus species, poses a significant challenge to maize production worldwide. ER resistance is regulated by several small effect quantitative trait loci (QTLs). To date, only a few ER-related genes have been identified that impede molecular breeding efforts to breed ER-resistant maize varieties.

AIM OF REVIEW

Our aim here is to explore the research progress and mine genic resources related to ER resistance, and to propose a regulatory model elucidating the ER-resistant mechanism in maize as well as a trade-off model illustrating how crops balance fungal resistance and grain yield. Key Scientific Concepts of Review: This review presents a comprehensive bibliometric analysis of the research history and current trends in the genetic and molecular regulation underlying ER resistance in maize. Moreover, we analyzed and discovered the genic resources by identifying 162 environmentally stable loci (ESLs) from various independent forward genetics studies as well as 1391 conservatively differentially expressed genes (DEGs) that respond to Fusarium or Aspergillus infection through multi-omics data analysis. Additionally, this review discusses the syntenies found among maize ER, wheat Fusariumhead blight (FHB), and rice Bakanaedisease (RBD) resistance-related loci, along with the significant overlap between fungal resistance loci and reported yield-related loci, thus providing valuable insights into the regulatory mechanisms underlying the trade-offs between yield and defense in crops.

Diversity and Evolution of NLR Genes in Citrus Species

NLR genes are crucial components of the effector-triggered immunity (ETI) system, responsible for recognizing pathogens and initiating immune responses. Although NLR genes in many plant species have been extensively studied, the diversity of NLR genes in citrus remains largely unknown. Our analysis revealed significant variations in the copy numbers of NLR genes among these species. Gene duplication and recombination were identified as the major driving forces behind this diversity. Additionally, horizontal gene transfer (HGT) emerged as the principal mechanism responsible for the increase in NLR gene copy number in A. buxifolia. The citrus NLR genes were classified into four categories: TIR-NBS-LRR (TNL), CC-NBS-LRR (CNL), RPW8-NBS-LRR (RNL), and NL. Our findings indicate that TNL, RNL, and CNL genes originated from NL genes through the acquisition of TIR and RPW8 domains, along with CC motifs, followed by the random loss of corresponding domains. Phylogenetic analysis suggested that citrus NLR genes originated alongside the species and underwent adaptive evolution, potentially playing crucial roles in the global colonization of citrus. This study provides important insights into the diversity of citrus NLR genes and serves as a foundational dataset for future research aimed at breeding disease-resistant citrus varieties.

Activation of an atypical plant NLR with an N-terminal deletion initiates cell death at the vacuole

Plants evolve nucleotide-binding leucine-rich repeat receptors (NLRs) to induce immunity. Activated coiled-coil (CC) domain containing NLRs (CNLs) oligomerize and form apparent cation channels promoting calcium influx and cell death, with the alpha-1 helix of the individual CC domains penetrating the plasma membranes. Some CNLs are characterized by putative N-myristoylation and S-acylation sites in their CC domain, potentially mediating permanent membrane association. Whether activated Potentially Membrane Localized NLRs (PMLs) mediate cell death and calcium influx in a similar way is unknown. We uncovered the cell-death function at the vacuole of an atypical but conserved Arabidopsis PML, PML5, which has a significant deletion in its CCG10/GA domain. Active PML5 oligomers localize in Golgi membranes and the tonoplast, alter vacuolar morphology, and induce cell death, with the short N-terminus being sufficient. Mutant analysis supports a potential role of PMLs in plant immunity. PML5-like deletions are found in several Brassicales paralogs, pointing to the evolutionary importance of this innovation. PML5, with its minimal CC domain, represents the first identified CNL utilizing vacuolar-stored calcium for cell death induction.

Genetic Independence of Naturally Correlated Variation in Resistance to Endemic and Novel Pathogens

The emergence of new diseases is an urgent concern, but hosts can also vary in resistance to pathogens that are novel to them, facilitating evolutionary rescue. However, little is known about the genetic source for polymorphic resistance to novel pathogens or its relationship to defences against endemic diseases. With anther-smut disease from wild plant populations, we used selection experiments and genetic analyses to show that resistances to novel and endemic pathogens are genetically independent, despite being positively correlated in nature. Moreover, novel-pathogen resistance presented a much simpler genetic basis and more rapid response to selection. We demonstrate that polymorphic resistance to a newly introduced disease is genetically determined and not an extension of defences against the related endemic pathogen, challenging the conventional view of nonhost resistance.

Pseudomonas syringae pv. actinidiae Unique Effector HopZ5 Interacts with GF14C to Trigger Plant Immunity

The bacterial canker of kiwifruit caused by Pseudomonas syringae pv. actinidiae (Psa) is the most devastating disease threatening the global kiwifruit production. This pathogen delivers multiple effector proteins into plant cells to resist plant immune responses and facilitate their survival. Here, we focused on the unique effector HopZ5 in Psa, which previously has been reported to have virulence functions. In this study, our results showed that HopZ5 could cause macroscopic cell death and trigger a serious immune response by agroinfiltration in Nicotiana benthamiana, along with upregulated expression of immunity-related genes and significant accumulation of reactive oxygen species and callose. Subsequently, we confirmed that HopZ5 interacted with the phosphoserine-binding protein GF14C in both the nonhost plant N. benthamiana (NbGF14C) and the host plant kiwifruit (AcGF14C), and silencing of NbGF14C compromised HopZ5-mediated cell death, suggesting that GF14C plays a crucial role in the detection of HopZ5. Further studies showed that overexpression of NbGF14C both markedly reduced the infection of Sclerotinia sclerotiorum and Phytophthora capsica in N. benthamiana, and overexpression of AcGF14C significantly enhanced the resistance of kiwifruit against Psa, indicating that GF14C positively regulates plant immunity. Collectively, our results revealed that the virulence effector HopZ5 could be recognized by plants and interact with GF14C to activate plant immunity.

Antagonistic regulation of plant NLR-mediated autoimmunity by E3 ligase pairs

KEY MESSAGE

Two plant U-box E3 ligases, PUB5 and PUB44, antagonistically regulate the NLR receptor SUMM2-mediated autoimmunity in Arabidopsis, indicating a new regulatory mechanism for fine-tuning plant immunity.

A Mitogen-Activated Protein Kinase Pathway Is Required for Bacillus amyloliquefaciens PMB05 to Enhance Disease Resistance to Bacterial Soft Rot in Arabidopsis thaliana

When a plant is infected by a pathogen, endogenous immune responses are initiated. When the initiation of these defense responses is induced by a pathogen-associated molecular pattern (PAMP) of a pathogen, it is called PAMP-triggered immunity (PTI). Previous studies have shown that Bacillus amyloliquefaciens PMB05 can enhance PTI signals and improve disease control of bacterial soft rot and wilt in Arabidopsis thaliana. In the context of controlling bacterial wilt disease, the involvement of a mitogen-activated protein kinase (MAPK) signaling pathway has been established. Nevertheless, it remains unclear whether this pathway is also required for B. amyloliquefaciens PMB05 in controlling bacterial soft rot. In this study, A. thaliana ecotype Columbia (Col-0) and its mutants on a MAPK pathway-related pathway were used as a model and established that the ability of B. amyloliquefaciens PMB05 to control soft rot requires the participation of the MAPK pathway. Moreover, the enhancement of disease resistance by PMB05 is highly correlated with the activation of reactive oxygen species generation and stomata closure, rather than callose deposition. The spray inoculation method was used to illustrate that PMB05 can enhance stomatal closure, thereby restricting invasion by the soft rot bacterium. This control mechanism has also been demonstrated to require the activation of the MAPK pathway. This study demonstrates that B. amyloliquefaciens PMB05 can accelerate stomata closure via the activation of the MAPK pathway during PTI, thereby reducing pathogen invasion and achieving disease resistance against bacterial soft rot.