Publications

4374

ABSTRACT “ Candidatus Liberibacter solanacearum” (Lso) is a highly destructive plant pathogen within the alpha-proteobacteria group. Multiple Lso haplotypes occur worldwide, each uniquely associated with a specific psyllid vector. Haplotypes A and B, found in the United States, cause serious damage to solanaceous crops and are transmitted by Bactericera cockerelli , known as the potato psyllid in a circulative and persistent manner. The psyllid gut is the first organ encountered by Lso and may act as a barrier to its transmission; however, the immune response of the gut to Lso infection remains largely uncharacterized. In this study, we examined autophagic responses in the gut of potato psyllids at early, mid, and late infection stages. Based on gene expression analyses, microscopic observations, and Western blotting, we found no clear evidence of autophagy induction despite Lso infection. Nevertheless, during mid and late phases of LsoB infection, we observed downregulation of the mechanistic target of rapamycin and decreased accumulation of ATG8-II. Notably, inducing autophagy with rapamycin significantly reduced LsoA titers in the psyllid guts after a 5-day acquisition access period and lowered transmission efficiency, while LsoB remained unaffected. These findings suggest that modulating autophagy in the gut of potato psyllids could be a promising strategy to limit LsoA acquisition and transmission, while highlighting LsoA and LsoB possess distinct molecular regulatory mechanisms in the psyllid gut. IMPORTANCE Liberibacters are devastating plant pathogens transmitted by psyllids. Because these bacteria are fastidious, the study of the molecular mechanisms involved in plant infection and transmission is difficult. Here, we determined that inducing autophagy in the potato psyllid can affect the acquisition and transmission of Lso haplotype A but not haplotype B. Comparing the host and vector responses to different liberibacters can help identify their transmission and infection mechanisms and find targets to disrupt these processes.

Abstract‘Candidatus Phytoplasma (Ca. P.) solani’ is associated with Bois noir (BN) of grapevine and stolbur of solanaceous plants and is primarily transmitted by Hyalesthes obsoletus Signoret. Four tuf‐a and five tuf‐b1 ‘Ca. P. solani’ strains were transmitted to tomato plants (cv. Micro‐Tom) to set the basis for studying molecular interactions between different strains of the pathogen and host plants. The strains were acquired by using bait‐plants and by capturing H. obsoletus adults on bindweed and stinging nettle in vineyards of Friuli Venezia Giulia (northeastern Italy) with a high prevalence of BN. Captured insects were forced to feed on healthy tomato plants to induce infection. All strains obtained from symptomatic plants and confirmed by real‐time PCR were maintained on tomato through grafting. Successively, the strains were characterised by macroscopic and microscopic symptoms induced in the host, Multi‐Locus Sequence Typing (MLST) based on tuf, secY, stamp, and vmp1 genes, in‐planta spread and multiplication patterns. Molecular typing distinguished the strains into five lineages comprised in three clusters: one including strains of tuf‐a genotype and two including strains of tuf‐b1 genotype. Quite different symptoms were induced on tomatoes by strains belonging to the two tuf genotypes; infection by tuf‐a strains resulted in plant decline around 95–100 days after grafting and absence of cauliflower‐like inflorescence with symptoms of phyllody and virescence, which were usually associated with tuf‐b1 strains. The different symptoms, the outcome of disease, and the ultrastructural observation performed on sieve elements suggested a higher virulence of tuf‐a strains in tomato. Overall, our results propose that genomic variability of ‘Ca. P. solani’ strains should be extensively explored to determine possible associations with type of symptoms and strain virulence.

ABSTRACT Huanglongbing (HLB), caused by Candidatus Liberibacter asiaticus (CLas), is the most devastating citrus disease worldwide. Developing effective therapies remains a major challenge, as CLas cannot be cultured in vitro and colonizes the host phloem systemically. This study presents a rapid, reproducible, and cost-effective in vivo platform for screening bacteriostatic and bactericidal compounds using CLas-infected citron (Citrus medica (L.) Osbeck) stem cuttings. Among seven citrus genotypes tested, citron stem cuttings exhibited superior rooting performance and uniform vegetative growth. Four propagation protocols were developed and assessed based on the dynamics of rooting and shoot growth, CLas colonization, and the response to oxytetracycline (OTC) treatment. CLas+ stem cuttings were treated with OTC via drenching at different developmental root stages. The roots or new vegetative flushes were sampled for bacterial quantification by qPCR. In Protocol 2, in which treatments were applied and sampled 14 and 35 days after planting (DAP) respectively, OTC-treated roots achieved the highest suppression of CLas and the lower incidence of CLas+ rooted cuttings compared to non-treated roots. Time-course analysis showed that OTC delayed bacterial establishment in root tissues, with maximal suppression observed at 35 DAP. The proposed protocols simulate the natural progression of systemic infection in citrus plants, allow the assessment of phytotoxicity, and offer a scalable technology that does not underestimate the efficacy of future bactericidal candidates. This platform significantly reduces time and cost compared to traditional seedling or nursery tree experiments and enhances the early-phase screening of antimicrobial compounds. Altogether, this stem cutting-based approach represents a biologically relevant, scalable tool to accelerate therapeutic discovery and strengthen integrated HLB management strategies.

Abstract Background Candidatus Phytoplasma infection is among the most destructive plant diseases, characterized by phyllody, witches broom, virescence etc. Sesame (Sesamum indicum L.), one of the oldest cultivated oilseed crops, valued for its nutritional and medicinal properties, is highly susceptible to phytoplasma infection, causing substantial annual yield losses. The present study aimed to investigate the metabolomic and molecular alterations in sesame plants as a consequence of phytoplasma infection in two distinct tissue types, leaves and flowers, using a multi-omics approach. Results The study revealed that phytoplasma infection significantly alters the expression of floral homeobox and meristem identity genes in an antagonistic manner, resulting in the development of leaf-like traits in floral tissues. Integrated analyses of transcriptomic and metabolomic datasets showed that control leaves, control flowers, infected leaves, and infected flowers each displayed distinct metabolomic and transcriptomic profiles. Metabolomic profiling demonstrated major changes in pathways such as porphyrin metabolism, brassinosteroid metabolism, and phenylpropanoid biosynthesis. Complementary KEGG pathway enrichment analysis of transcriptome data confirmed strong enrichment of secondary metabolite biosynthesis in both tissue types upon infection. Tissue-specific responses were evident. Floral tissues accumulated green pigments due to increased porphyrin biosynthesis and reduced degradation, while leaves showed simultaneous upregulation of both biosynthesis and breakdown pathways of porphyrins. Floral tissues exhibited stronger stress-associated responses, including upregulation of genes related to stress enzymes, phenylpropanoids, and lignification-related metabolites. In contrast, certain compounds such as lignans were specifically accumulated in leaves upon infection. These observations were further supported by biochemical, histological, and qRT-PCR assays. Conclusion This study provides the first clear evidence of tissue-specific metabolic reprogramming in sesame under Ca. Phytoplasma infection through integrated transcriptomic and metabolomic analyses. These findings improve our understanding of host-pathogen interactions and offer a basis for strategies to reduce phytoplasma-induced yield losses.

AbstractBACKGROUNDAutophagy is a conserved mechanism by which eukaryotic organisms defend against pathogen infection. However, the molecular mechanisms underlying the role of autophagy in the interactions of insect vectors with the phloem‐limited bacterial pathogen remain unclear. The citrus Huanglongbing (HLB)‐associated pathogen ‘Candidatus Liberibacter asiaticus’ (CLas) seriously endangers development of the citrus industry. It spreads via Diaphorina citri in a persistent and propagative manner.RESULTSIn this study, a total of 30 autophagy‐related genes (ATG) were identified in the D. citri genome, among which multiple genes were significantly regulated after CLas infection. Concurrently, CLas infection also leads to an increased number of autophagosomes and enhanced accumulation of ATG8‐II. Ultrastructural observations revealed the presence of bacterial‐like structures within autophagosomes in the midgut of CLas‐infected D. citri. Furthermore, both activation and inhibition of autophagy significantly influenced CLas titers. However, autophagy cannot completely eliminate CLas in D. citri. We identified a CLas effector, SDE4040 (CLIBASIA_04040), that interacts with DcATG8 and co‐localizes on autophagosomes in D. citri. Co‐expression of SDE4040 and DcATG8 induces autophagy in Spodoptera frugiperda (Sf9) cells.CONCLUSIONTaken together, these results indicate that CLas infection activates the autophagy pathway in D. citri, contributing to a reduction in bacterial titer. Our data also revealed that CLas may trigger complex interactions with the insect. © 2025 Society of Chemical Industry.

Abstract Citrus Huanglongbing (HLB) is the most destructive disease in citriculture, mainly caused by Candidatus Liberibacter asiaticus (CLas). However, the immune response of citrus to CLas at the cellular level remains to be elucidated. In this study, the first single-cell atlas of rough lemon (Citrus jambhiri Lush.) root apexes were generated using single-nucleus RNA sequencing at 20 weeks post-inoculation with CLas. According to gene expression patterns, the single-cell atlas was partitioned into 20 transcriptionally distinct clusters, and five cell types were identified within these clusters. A significant number of defense-related genes were co-upregulated across the five cell types following CLas infection, whereas genes involved in signal transduction pathways, such as tubulin beta-6 chain (TUBB1) and the phospholipase D alpha 1 (PLD1), were concurrently downregulated. Based on pseudotime trajectory analysis, the key pathways and genes involved in the coordination of cell differentiation and resistance in citrus under CLas infection were characterized. Following CLas infection, the development of phloem cells was significantly delayed, and the differentiation of cambium cells into xylem cells was evident. The expression of genes associated with lignin synthesis was significantly upregulated in these cells. The reduction in phloem cell differentiation and the enhanced differentiation of cambium cells into defense-related xylem cells may represent the primary vascular immune mechanisms exhibited by citrus plants in response to CLas infection. Additionally, DNA-binding one zinc finger transcription factor DOF2.4 was found to potentially serve dual roles in regulating vascular cell development and inducing plant resistance against CLas. In conclusion, this study collectively provides insights into the cellular innate immunity responses of citrus to CLas infection. These findings hold significant implications for the sustainable development of citriculture amidst the ongoing global HLB epidemic, and offer novel insights into vascular immunity and plant defense responses.