Assessing the Capacity of High-resolution Commercial Satellite Imagery for Grapevine Downy Mildew Detection and Surveillance in New York state.

Grapevine downy mildew (GDM), caused by the oomycete Plasmopara viticola, can cause 100% yield loss and vine death under conducive conditions. High resolution multispectral satellite platforms offer the opportunity to track rapidly spreading diseases like GDM over large, heterogeneous fields. Here, we investigate the capacity of PlanetScope (3 m) and SkySat (50 cm) imagery for season-long GDM detection and surveillance. A team of trained scouts rated GDM severity and incidence at a research vineyard in Geneva, NY, USA from June to August of 2020, 2021, and 2022. Satellite imagery acquired within 72 hours of scouting was processed to extract single-band reflectance and vegetation indices (VIs). Random forest models trained on spectral bands and VIs from both image datasets could classify areas of high and low GDM incidence and severity with maximum accuracies of 0.85 (SkySat) and 0.92 (PlanetScope). However, we did not observe significant differences between VIs of high and low damage classes until late July-early August. We identified cloud cover, image co-registration, and low spectral resolution as key challenges to operationalizing satellite-based GDM surveillance. This work establishes the capacity of spaceborne multispectral sensors to detect late-stage GDM and outlines steps towards incorporating satellite remote sensing in grapevine disease surveillance systems.

First Report of Phytophthora cinnamomi causing root rot of avocado trees in Greece.

In September 2023, thirty declining 30-year-old avocado (Persea americana) trees ('Hass' grafted on 'Zutano' seedlings) were detected in a 1.5-ha orchard in the island of Crete (Chania region). Crown symptoms encompassed wilting and leaf chlorosis, advancing to defoliation and extensive dieback. Tap and feeder roots decayed and brown discoloration of root tissues was evident on heavily infected trees. The disease was severe and widespread, resulting in a 5% mortality rate among 300 trees. The pathogen was isolated with a modified soil baiting technique (Ferguson and Jeffers, 1999). Surface disinfected avocado fruits were immersed in water containing soil samples. Following a period of 2 to 8 days, tissue fragments from the resulting necrotic lesions on the fruit surface were transferred on ΡΑRP medium and subsequently incubated at 20°C (Ferguson and Jeffers, 1999). Three isolates (AV2, AV12 and AV11a) were obtained by transferring single hyphal tips to new Petri dishes containing V8 juice agar. They were grown at 20˚C and used for identification after 10 days. Isolates formed coralloid colonies with abundant clustered spherical hyphal swellings and terminal or intercalary (ratio 1:5) thick-walled chlamydospores measuring 20 to 36 µm (avg 29±0.8 µm) with characteristic thick walls (avg 1.2±0.2 µm). Sporangia, produced in non-sterile soil-extract water, were ovoid to obpyriform, persistent, non-papillate, 32 to 81 µm (avg 56±4.8 µm) long and 20 to 42 µm (avg 31±3.2 µm) wide (n=100). Isolates were heterothallic as they did not produce oospores in single cultures. Based on the morphological traits the isolates were identified as Phytophthora cinnamomi (Erwin and Ribeiro 1996). The internal transcribe spacer region (ITS) including ITS1, 5.8S rDNA region, and ITS2 as well as the cytochrome c oxidase subunit I (coxI) gene of the three representative isolates wereamplified with ITS1/ITS4 and FM83/FM84 primers, respectively (White et al. 1990; Martin and Tooley 2003), and sequenced (GenBank acc. PP506613 to PP506615 and PQ063867 to PQ063869, respectively). BLAST search revealed almost 100% identity with the sequences of P. cinnamomi ex-isotype isolate (KC478663 and KU899315 respectively). Pathogenicity tests using isolate AV2 were conducted following the soil infestation method (Jung et al. 1996) using six-year-old avocado 'Zutano' seedlings. Six non-inoculated plants treated with vermiculite-multivitamin juice mixture were used as controls. Plants (1 m tall) were grown in pots under greenhouse conditions and watered regularly. Six weeks post inoculation, all inoculated trees showed chlorosis, wilting and root rot, while control plants remained symptomless. Symptoms were similar to those observed in the field and the pathogen was re-isolated and molecularly identified as previously described. This study presents the first documented occurrence of P. cinnamomi, widely regarded as the most destructive avocado pathogen globally, on avocado crops in Greece (Rodger et al. 2019). Additionally, this marks the first recorded presence of this pathogen on the island of Crete, regardless of the host species. The accurate identification of Phytophthora species associated with avocado root rot is essential for implementing an effective disease management strategy, particularly in the selection of appropriate disease-resistant rootstocks.

Full-length ITS amplicon sequencing resolves Phytophthora species in surface waters used for orchard irrigation in California's San Joaquin Valley.

Diverse Phytophthora species, including many important plant pathogens, have been widely detected among surface water irrigation sources. In the past decade, metabarcoding has been used to characterize waterborne Phytophthora populations. Metabarcoding typically involves amplification of portions of the nuclear ribosomal internal transcribed spacer (ITS)1 or ITS2 from Phytophthora species, followed by indexed high throughput sequencing. However, full-length sequences of the entire ITS region are required for resolution of many Phytophthora species. We used metabarcoding with PacBio sequencing of full-length ITS amplicons to analyze populations of Phytophthora in waterways of the Stockton East Water District (SEWD) in the northern San Joaquin Valley of California. This approach yielded species-level resolution of many members of the Phytophthora community. Results were compared to those obtained by using ITS1 or ITS2 regions alone and were found to provide superior species resolution for P. pini, P. capsici, and P. gregata. Samples were collected throughout the 2021 irrigation season from five waterways across the SEWD. Thirty-eight Phytophthora species were detected in the waterways, including tree-crop pathogens P. acerina, P. cactorum, P. pini, P. ×cambivora, P. niederhauserii, P. mediterranea, and P. taxon walnut. These pathogenic species were detected throughout the SEWD during most of the irrigation season. The results demonstrated the utility of full-length ITS amplicon sequencing for identifying Phytophthora species in environmental samples and suggested that some disease risk may be incurred by orchardists irrigating with SEWD water. Additional epidemiological studies will be required to critically evaluate this risk.

Integrating multilocus phylogeny and morphological analysis reveals the prevalence of Phytophthora meadii (McRae) associated with abnormal leaf fall disease of Hevea brasiliensis in India.

The Oomycetes fungus Phytophthora spp. which causes Abnormal leaf fall (ALF) disease poses a significant threat as one of the most devastating diseases affecting rubber trees in India. A total of 30 Phytophthora isolates were obtained from ALF-affected samples collected during the Southwest monsoon season of Kerala. The colony morphology of Phytophthora isolates revealed eight different types of growth patterns, with stellate, stellate striated, and petaloid patterns growing rapidly, whereas chrysanthemum pattern grew slowly. Sporangia were papillate to non-papillate in various shapes, and sporangiophores exhibited simple, simple sympodial, or irregularly branching patterns. Highly virulent isolates exhibited petaloid morphology and rapid growth rates. Regardless of their virulence, all isolates showed susceptibility to the fungicide metalaxyl. Under in vitro conditions, the highly virulent isolate (R17) from rubber caused severe infections in chili, brinjal, and tomato with brown water-soaked lesions. Sequence analysis and multi-locus phylogeny of Internal transcribed spacer (ITS), cCytochrome c oxidase 1 (COX 1), Heat shock protein 90 (HSP 90), and Ribosomal protein L10 (RPL 10) confirmed the pathogen as Phytophthora meadii. A comprehensive understanding of both morphological and molecular traits of P. meadii is crucial for precise identification and future genetic variability studies.

Untargeted metabolomic analysis reveals a potential role of saponins in the partial resistance of pea (Pisum sativum) against a root rot pathogen, Aphanomyces euteiches.

In soil-borne diseases, the plant-pathogen interaction begins as soon as the seed germinates and develops into a seedling. Aphanomyces euteiches, an oomycete, stays dormant in soil and gets activated by sensing the host through chemical signals present in the root exudates. The composition of plant exudates may, thus, play an important role during the early phase of infection. To better understand the role of root exudates in plant resistance, we investigated the interaction between partially resistant lines (PI660736 and PI557500) and susceptible pea cultivars (CDC Meadow and AAC Chrome) against Aphanomyces euteiches during the pre-invasion phase. The root exudates of two sets of cultivars clearly distinguished from each other in inducing oospore germination. PI557500 root exudate not only had diminished induction but also inhibited the oospore germination. The contrast between the root exudates of resistance and susceptible cultivars was reflected in their metabolic profiles. Data from fractionation and oospore germination inhibitory experiments identified a group of saponins that accumulated differentially in susceptible and resistant cultivars. We detected 56 saponins and quantified 44 of them in pea root and 30 from root exudate; the majority of them, especially Soyasaponin I and dehydrosoyasaponin I with potent in vitro inhibitory activities, were present in significantly higher amounts in both roots and root exudates of PI660736 and PI557500 as compared to Meadow and Chrome. Our results provide evidence for saponins as deterrents against Aphanomyces euteiches, which might have contributed to the resistance against root rot in the studied pea cultivars.

Population Structure of Phytophthora infestans in Israel Changes Frequently Due to the Import of Asymptomatic Late Blight-Infected Potato Seed Tubers from Europe.

Late blight, caused by the oomycete Phytophthora infestans, is a devastating disease of potato worldwide. In Israel, potatoes are grown twice a year, in autumn and spring, with late blight causing extensive damage in both seasons. While tuber seeds for the autumn planting are produced locally, seed tubers for the spring planting are imported from Europe due to dormancy of local tubers. Here, we demonstrate that seed tubers imported from Europe for the spring season carry asymptomatic infection with EU genotypes of P. infestans, which alters the population structure of the pathogen each spring. The proportion of imported tubers carrying asymptomatic infections ranged between 1.2 and 3.75%, varying by year and cultivar. Asymptomatic tubers produced late blight-infected sprouts about one month after planting. The sporangia produced on these sprouts served as primary inoculum, causing intensive foliage attacks on neighboring plants. When sprout-infected plants were uprooted and the mother tuber was washed, sliced, and placed in moistened dishes at 18 °C, profuse sporulation of P. infestans developed on the slices' surfaces within 1-2 days. The dominant genotype of P. infestans in the autumn season in Israel is 23A1, but genotypes in the following spring season changed to include 13A2 or 36A2. Surprisingly, genotype 43A1, which might be resistant to CAA and OSBPI fungicides and appeared in Europe in 2022, emerged in Israel in spring 2024. The immigrating genotypes do not persist in the country, allowing 23A1 to regain predominance in the following autumn. Long-term monitoring data suggest that the population structure of P. infestans changes yearly but temporarily due to the import of new genotypes from Europe.

Reduction of Phytophthora palmivora plant root infection in weak electric fields.

The global food security crisis is partly caused by significant crop losses due to pests and pathogens, leading to economic burdens. Phytophthora palmivora, an oomycete pathogen, affects many plantation crops and costs over USD 1 billion each year. Unfortunately, there is currently no prevention plan in place, highlighting the urgent need for an effective solution. P. palmivora produces motile zoospores that respond to weak electric fields. Here, we show that external electric fields can be used to reduce root infection in two plant species. We developed two original essays to study the effects of weak electric fields on the interaction between P. palmivora's zoospores and roots of Arabidopsis thaliana and Medicago truncatula. In the first configuration, a global artificial electric field is set up to induce ionic currents engulfing the plant roots while, in the second configuration, ionic currents are induced only locally and at a distance from the roots. In both cases, we found that weak ionic currents (250-550 µA) are sufficient to reduce zoospore attachment to Arabidopsis and Medicago roots, without affecting plant health. Moreover, we show that the same configurations decrease P. palmivora mycelial growth in Medicago roots after 24 h. We conclude that ionic currents can reduce more than one stage of P. palmivora root infection in hydroponics. Overall, our findings suggest that weak external electric fields can be used as a sustainable strategy for preventing P. palmivora infection, providing innovative prospects for agricultural crop protection.

Characterization of three non-canonical N-glycosylation motifs indicates Nglyco-A reduces DNA N6-methyladenine and Nglyco-D alters G/F actin ratio in Phytophthora sojae.

Asparagine (Asn, N)-linked glycosylation is an abundant post-translational modification in which Asn, typically in Nglyco-X-S/T; X ≠ P motifs, are modified with N-glycans. It has essential regulatory roles in multicellular organisms. In this study, we systematically investigate the function of three N-glycosylation motifs (Nglyco-A, Nglyco-D and Nglyco-S) previously identified in Phytophthora sojae, through site-directed mutagenesis and functional assays. In P. sojae expressing glycosylation-dead variants pre-PsDMAP1N70A (Nglyco-A motif) or PsADFN64A (Nglyco-D motif), zoospore release or cyst germination is impaired. In particular, the pre-PsDMAP1N70A mutant reduces DNA methylation levels, and the PsADFN64A mutant disrupts the actin forms, which could explain the decrease in pathogenicity after N-glycosylation is destroyed. Similarly, P. sojae expressing PsNRXN132A (Nglyco-S motif) shows increased sensitivity to H2O2 and heat. Through autophagy or 26S proteasome pathway inhibition assays, we found that unglycosylated pre-PsDMAP1N70A and PsADFN64A are degraded via the 26S proteasome pathway, while the autophagy pathway is responsible for PsNRXN132A clearance. These findings demonstrate that glycosylation of these motifs regulates the stability and function of glycoproteins necessary for P. sojae growth, reproduction and pathogenicity, which expands the scope of known N-glycosylation regulatory functions in oomycetes.

From glycans to green biotechnology: exploring cell wall dynamics and phytobiota impact in plant glycopathology.

Filamentous plant pathogens, including fungi and oomycetes, pose significant threats to cultivated crops, impacting agricultural productivity, quality and sustainability. Traditionally, disease control heavily relied on fungicides, but concerns about their negative impacts motivated stakeholders and government agencies to seek alternative solutions. Biocontrol agents (BCAs) have been developed as promising alternatives to minimize fungicide use. However, BCAs often exhibit inconsistent performances, undermining their efficacy as plant protection alternatives. The eukaryotic cell wall of plants and filamentous pathogens contributes significantly to their interaction with the environment and competitors. This highly adaptable and modular carbohydrate armor serves as the primary interface for communication, and the intricate interplay within this compartment is often mediated by carbohydrate-active enzymes (CAZymes) responsible for cell wall degradation and remodeling. These processes play a crucial role in the pathogenesis of plant diseases and contribute significantly to establishing both beneficial and detrimental microbiota. This review explores the interplay between cell wall dynamics and glycan interactions in the phytobiome scenario, providing holistic insights for efficiently exploiting microbial traits potentially involved in plant disease mitigation. Within this framework, the incorporation of glycobiology-related functional traits into the resident phytobiome can significantly enhance the plant's resilience to biotic stresses. Therefore, in the rational engineering of future beneficial consortia, it is imperative to recognize and leverage the understanding of cell wall interactions and the role of the glycome as an essential tool for the effective management of plant diseases.

Combining single-gene-resistant and pyramided cultivars of perennial crops in agricultural landscapes compromises pyramiding benefits in most production situations.

While resistant cultivars are valuable in safeguarding crops against diseases, they can be rapidly overcome by pathogens. Numerous strategies have been proposed to delay pathogen adaptation (evolutionary control), while still ensuring effective protection (epidemiological control). For perennial crops, multiple resistance genes can be deployed 1) in the same cultivar (pyramiding strategy), in single-gene-resistant cultivars grown 2) in the same field (mixture strategy) or 3) in different fields (mosaic strategy), or 4) in hybrid strategies that combine the three previous options. In addition, the spatial scale at which resistant cultivars are deployed can affect the plant-pathogens interaction: small fields are thought to reduce pest density and disease transmission. Here we used the spatially-explicit stochastic model landsepi to compare the evolutionary and epidemiological control across spatial scales and deployment strategies relying on two major resistance genes. Our results, broadly focused on resistance to downy mildew of grapevine, show that the evolutionary control provided by the pyramiding strategy is at risk when single-gene-resistant cultivars are concurrently planted in the landscape (hybrid strategies), especially at low mutation probability. Moreover, the effectiveness of pyramiding compared to hybrid strategies is influenced by whether the adapted pathogen pays a fitness cost across all hosts or only for unnecessary virulence, particularly when the fitness cost is high rather than intermediate. Finally, field size did not affect model outputs for a wide range of mutation probabilities and associated fitness costs. The socio-economic policies favoring the adoption of optimal resistant management strategies are discussed.

Histone (de)acetylation in epigenetic regulation of Phytophthora pathobiology.

Phytophthora species are oomycetes that have evolved a broad spectrum of biological processes and improved strategies to cope with host and environmental challenges. A growing body of evidence indicates that the high pathogen plasticity is based on epigenetic regulation of gene expression linked to Phytophthora's rapid adjustment to endogenous cues and various stresses. As 5mC DNA methylation has not yet been identified in Phytophthora, the reversible processes of acetylation/deacetylation of histone proteins seem to play a pivotal role in the epigenetic control of gene expression in oomycetes. To explore this issue, we review the structure, diversity, and phylogeny of histone acetyltransferases (HATs) and histone deacetylases (HDACs) in six plant-damaging Phytophthora species: P. capsici, P. cinnamomi, P. infestans, P. parasitica, P. ramorum, and P. sojae. To further integrate and improve our understanding of the phylogenetic classification, evolutionary relationship, and functional characteristics, we supplement this review with a comprehensive view of HATs and HDACs using recent genome- and proteome-level databases. Finally, the potential functional role of transcriptional reprogramming mediated by epigenetic changes during Phytophthora species saprophytic and parasitic phases under nitro-oxidative stress is also briefly discussed.

Rapid Detection of Viral, Bacterial, Fungal, and Oomycete Pathogens on Tomatoes with Microneedles, LAMP on a Microfluidic Chip, and Smartphone Device.

Rapid detection of plant diseases before they escalate can improve disease control. Our team has developed rapid nucleic acid extraction methods with microneedles and combined these with loop-mediated amplification (LAMP) assays for pathogen detection in the field. In this work, we developed LAMP assays for early blight (Alternaria linariae, A. alternata, and A. solani) and bacterial spot of tomato (Xanthomonas perforans) and validated these LAMP assays and two previously developed LAMP assays for tomato spotted wilt virus and late blight. Tomato plants were inoculated, and disease severity was measured. Extractions were performed using microneedles, and LAMP assays were run in tubes (with hydroxynaphthol blue) on a heat block or on a newly designed microfluidic slide chip on a heat block or a slide heater. Fluorescence on the microfluidic chip slides was visualized using EvaGreen and photographed on a smartphone. Plants inoculated with X. perforans or tomato spotted wilt virus tested positive prior to visible disease symptoms, whereas Phytophthora infestans and A. linariae were detected at the time of visual disease symptoms. LAMP assays were more sensitive than PCR, and the limit of detection was 1 pg of DNA for both A. linariae and X. perforans. The LAMP assay designed for early blight detected all three species of Alternaria that infect tomato and is thus an Alternaria spp. assay. This study demonstrates the utility of rapid microneedle extraction followed by LAMP on a microfluidic chip for rapid diagnosis of four important tomato pathogens.

Phytophthora polonica and Phytophthora hydropathica from Clade 9 Associated with Alder Decline in Bulgaria.

A number of Phytophthora species have been identified as destructive plant pathogens and invasive species. They have the potential to affect a wide range of host plants and cause diseases in agricultural and forest ecosystems. Two Phytophthora species from rhizosphere soil samples collected from declining Alnus glutinosa in Bulgaria were isolated in the autumn of 2022. They were identified as Phytophthora polonica and Phytophthora hydropathica according to the DNA sequence analysis of the ITS region, as well as their morphological and physiological characteristics. The pathogenicity of both species to common and gray alder was evaluated by the inoculation of detached leaves and cuttings. Experimental data proved that P. polonica and P. hydropathica are able to cause leaf necrosis not only on A. glutinosa from which they were derived, but also on A. incana. No significant deference in the aggressiveness of the studied isolates from both Phytophthora species against the two tested plants was observed. Therefore, P. polonica and P. hydropathica were determined as potential threats for alder ecosystems in the country. This is the first report for the isolation of P. polonica in Bulgaria and represents the most southeastern point of the species distribution in Europe.

Distinct small RNAs are expressed at different stages of Phytophthora capsici and play important roles in development and pathogenesis.

Small RNAs (sRNAs) are important non-coding RNA regulators that play key roles in the development and pathogenesis of plant pathogens, as well as in other biological processes. However, whether these abundant and varying sRNAs are involved in Phytophthora development or infection remains enigmatic. In this study, sRNA sequencing of 4 asexual stages of Phytophthora capsici (P. capsici), namely, as mycelia (HY), sporangia (SP), zoospores (ZO), cysts (CY), and pepper infected with P. capsici (IN), were performed, followed by sRNA analysis, microRNA (miRNA) identification, and miRNA target prediction. sRNAs were mainly distributed at 25-26 nt in HY, SP, and ZO but distributed at 18-34 nt in CY and IN. 92, 42, 176, 39, and 148 known miRNAs and 15, 19, 54, 13, and 1 novel miRNA were identified in HY, SP, ZO, CY, and IN, respectively. It was found that the expression profiles of known miRNAs vary greatly at different stages and could be divided into 4 categories. Novel miRNAs mostly belong to part I. Gene ontology (GO) analysis of known miRNA-targeting genes showed that they are involved in the catalytic activity pathway, binding function, and other biological processes. Kyoto Encyclopedia of Gene and Genome (KEGG) analysis of novel miRNA-targeting genes showed that they are involved in the lysine degradation pathway. The expression of candidate miRNAs was validated using quantitative reverse transcription-polymerase chain reaction (qRT-PCR), and miRNAs were downregulated in PcDCL1 or PcAGO1 mutants. To further explore the function of the detected miRNAs, the precursor of a novel miRNA, miR91, was knockout by CRISPR-Cas9, the mutants displayed decreased mycelial growth, sporangia production, and zoospore production. It was found that 503142 (Inositol polyphosphate 5-phosphatase and related proteins) can be predicted as a target of miR91, and the interaction between miR91 and 503142 was verified using the tobacco transient expression system. Overall, our results indicate that the diverse and differentially expressed sRNAs are involved in the development and pathogenesis of P. capsici.

Fast, Easy, and Comprehensive Techniques for Microscopic Observations of Fungal and Oomycete Organisms Inside the Roots of Herbaceous and Woody Plants.

The roots of herbaceous and woody plants growing in soil are complex structures that are affected by both natural and artificial fungal colonization to various extents. To obtain comprehensive information about the overall distribution of fungi or oomycetes inside a plant root system, rapid, effective, and reliable screening methods are required. To observe both fine roots, i.e., a common site for penetration of fungi and oomycetes, and mature roots, different techniques are required to overcome visual barriers, such as root browning or tissue thickening. In our protocol, we propose using fast, cost-effective, and non-harmful methods to localize fungal or oomycete structures inside plant roots. Root staining with a fluorescent dye provides a quick initial indication of the presence of fungal structures on the root surfaces. The protocol is followed by clearing and staining steps, resulting in a deeper insight into the root tissue positioning, abundance, and characteristic morphological/reproductive features of fungal or oomycete organisms. If required, the stained samples can be prepared by using freeze-drying for further observations, including advanced microscopic techniques. Key features • The protocol enhances tissue-clearing techniques employing KOH or NaOH and is applicable to a broad range of roots from different plant species. • Hydroxides are mixed with hydrogen peroxide to obtain an efficient bleaching solution, which effectively clears roots without causing significant tissue damage. • The protocol could also be used for staining of fungi or oomycetes localized both on the root surface or inside the root tissues. • Simple combination of non-fluorescent methyl blue and fluorescent solophenyl flavine dyes allows the observation of fungal organisms in both brightfield and fluorescence microscopy.

The Need and Opportunity to Update the Inventory of Plant Pathogenic Fungi and Oomycetes in Mexico.

Mexico generates specific phytosanitary regulations for each product and origin to prevent the entry of quarantine pests and/or delay their spread within the national territory, including fungi and oomycetes. Phytosanitary regulations are established based on available information on the presence or absence of these pathogens in the country; however, the compilation and precise analysis of reports is a challenging task due to many publications lacking scientific rigor in determining the presence of a taxon of phytosanitary interest in the country. This review evaluated various studies reporting the presence of plant pathogenic fungi and oomycetes in Mexico and concluded that some lists of diseases and phytopathogenic organisms lack technical-scientific basis. Thus, it highlights the need and presents an excellent opportunity to establish a National Collection of Fungal Cultures and a National Herbarium for obligate parasites, as well as to generate a National Database of Phytopathogenic Fungi and Oomycetes present in Mexico, supported by the combination of morphological, molecular, epidemiological, pathogenicity, symptom, and micrograph data. If realized, this would have a direct impact on many future applications related to various topics, including quarantines, risk analysis, biodiversity studies, and monitoring of fungicide resistance, among others.

Phytophthora pseudocryptogea Is Associated with Root and Crown Rot of Nursery-Grown Common Sage in Hungary.

In October 2009, necrotic bark lesions at the root collar and lower stem associated with root rot, reduced growth, and wilting were observed on container-grown 2-year-old common sage (Salvia officinalis L. 'Icterina') in two ornamental nurseries in Somogy and Zala counties in Hungary. The disease occurred at a frequency of 15-20% (100 to 150 symptomatic plants in each nursery). A P. cryptogea-like species was isolated consistently from necrotic root collars of many plants on carrot (CA) PARPB agar. Six isolates from the nursery in Zala county and three isolates from the nursery in Somogy county were deposited in the culture collection of Plant Protection Institute (Budapest, Hungary). All developed slightly petaloid colonies on CA agar. Chlamydospores and gametangia were not present in single and dual culture combinations of isolates. Radial colony growth was the fastest at 25°C (6.8 to 7.4 mm/day) and no growth occurred above 34°C. On mycelial discs floating in nonsterile stream water, persistent, nonpapillate, mostly ovoid to obpyriform sporangia (37.4±3.5 to 47.8±4.6 µm long and 22.3±2.6 to 29.2±3.7 µm wide) and hyphal swellings were produced abundantly. Pathogenicity of one selected isolate from each nursery was tested on 3-month-old seedlings of S. officinalis 'Icterina' in 2010. Isolates were grown for 4 weeks at 20°C on autoclaved millet grains moistened with CA broth. Infested and uninfested grains were mixed with autoclaved soil (30 cm3 grain/liter), and the mixes were used as potting media for transplanting five treated and five control plants per isolate, respectively. Plants were kept in a growth room (20-25°C, 16/8 h dark/light). Pots were flooded for 24 hours on the 1st day and every 2 weeks. All and only treated plants showed symptoms of wilt associated with basal stem and root necrosis within three weeks. The trial was repeated with the same result. The pathogen could be reisolated only from the treated plants. Identity of isolates from nurseries and inoculated plants was confirmed recently by amplification and sequence analysis of the rDNA internal transcribed spacers (ITS) and gene regions of cytochrome c oxidase subunit I (coxI) and ß-tubulin (tub) according to Jung et al. (2017). BLASTn searches showed 100% identity and only 97.3-99.0% similarity to the corresponding sequences of authenthic P. pseudocryptogea and P. cryptogea strains, respectively (e.g., GenBank accession nos. KP288336-KP288342, KP288370-KP288372, KP288386-KP288392, MN872725, MN872776). Sequences of the 9 field isolates were deposited in GenBank under accession nos. OR771701-OR771709 (ITS), OR787508-OR787516 (coxI) and OR787517-OR787525 (tub). P. pseudocryptogea was delineated from P. cryptogea sensu lato (Safaiefarahani et al. 2015), which has been reported from S. officinalis in the United States (Koike 1997), and S. leucantha (Cacciola et al. 2002) and S. officinalis (Garibaldi et al. 2015) in Italy. The known natural hosts of P. pseudocryptogea includes plant species in families other than Lamiaceae (cf. Aloi et al. 2023), but it was pathogenic on the lamiaceous Plectranthus scutellarioides in artificial inoculations (Christova 2020). The pathogen is present in European nurseries (Antonelli et al. 2023). This is the first report of P. pseudocryptogea on S. officinalis in Hungary. The causal agent threatens the production of sages and other ornamentals, and its spread in Hungary should be prevented by proper disease management and phytosanitary actions.

First global report of Hyaloperonospora brassicae in commercial broccoli and cabbage microgreens.

Microgreens are a nutrient-dense enhancement to modern diets (Choe et al. 2018), whose small production footprint in protected systems facilitates rapid crop turnover and distribution to population centers. Eleven of the 25 most broadly grown microgreens are brassicas (Choe et al. 2018). In November 2023, kale, broccoli (H009B), and cabbage (H009C) microgreen crops in Michigan were observed with downy mildew, at disease severities of 3%, 40%, and 20% foliage on 10 x 16 cm seeded blocks of plants, respectively. These crops shared a germination chamber for at least three days, which was maintained at approximately 22℃ in very humid, dark conditions. Chlorosis and grayish, sunken necrosis characterized symptoms on cotyledon surfaces (Fig. 1). In humid conditions, thick, white-light gray sporulation was present on adaxial cotyledon surfaces, accompanied by sparse sporulation on abaxial surfaces and hypocotyls. Severely diseased plants were stunted and approximately 50% gradually succumbed to downy mildew. On microscopic examination, a Hyaloperonospora spp. was tentatively identified, with long sporangiophores that dichotomously branched 3 to 6 times and hyaline sporangia borne singly on flexuous terminal sterigmata (Fig. 2). Sporangia were round to oval, with average length of 23.1 (range 16.0 to 28.3) µm; width of 20.0 (15.0 to 25.6) µm; and average length:width of 1.2 (1.0 to 1.4); (n = 97 for all). Sporangia dislodged rapidly if disturbed or as humidity decreased. Two pathogenicity tests were initiated on two sequential days. Two cotyledons from originally infected broccoli and cabbage were suspended, abaxial-side down, on coarse mesh over an open 60-mm plate of pregerminated brassica seeds on a water-saturated filter, inside a sealed, clear plastic box. Boxes contained only one type of originally diseased host, with 15 to 20 seeds of transfer varieties in unique dishes. Boxes were incubated in the dark for 2 days at 19°C with a wet paper towel atop the cotyledons. Before removal, cotyledons were lightly brushed across the surfaces of the seedlings they were just suspended above. Seedlings were grown in boxes in the presence of indirect, ambient light for 9.5 hr/day for an additional 5 days before pathogen sporulation was apparent. Filter paper was resaturated as needed. Noninoculated control plants, maintained separate from inoculated plants, were asymptomatic throughout the experiments. Total disease incidence in transfer varieties was 43.5% of 'Graffiti' cauliflower, 18.7% and 15.7% of 'Nixon' and 'Blue Vantage' cabbage; 11.8% of 'Red Russian' kale, and 6.0% of 'Ironman' broccoli, combined from two experiments. All varieties listed had at least one plant successfully infected in both pathogenicity tests. Sporulation on transfer hosts was morphologically identical to originally affected crops. Sporangiophores and sporangia were removed from H009B broccoli and H009C cabbage plants using surface sterilized forceps, placed directly into DNA extraction tubes containing buffer CD1 (Qiagen PowerSoil Pro), then kit instructions were followed. Extracts were utilized as template for ITS and cox1 PCR amplification, using DreamTaq Mastermix and ITS4/6 (45 cycles; White et al. 1990) and Levup/Levlo primers (30 cycles; Robideau et al. 2011). Cycling conditions were as published, with the number of cycles indicated by primer set. Each reaction yielded a single amplicon of approximately 1000 and 700 bp, for ITS and cox1, respectively,. Amplicons were cleaned using ExoSap-IT and submitted for Sanger sequencing, using ITS6 and Levup as sequencing primers (Robideau et al. 2011; White et al. 1990). After quality trimming, amplicons shared >98.5% identity with H. brassicae (NCBI Genbank accession MG757792 or reference genome CANTFL010000892.1). Sequences were submitted to Genbank (PP093830, PP093831, PP776812, PP776813). This is the first report of downy mildew, caused by H. brassicae, in commercial brassica microgreens, crops with vast nutritional value and expanding production.

First Report of Globisporangium ultimum Causing Pythium Damping-off and Root Rot on Pepper in Guizhou, China.

Pepper (Capsicum annuum L.) is a popular vegetable and condiment consumed around the world. In the Guizhou Province of China, peppers are the most commonly grown crop on 300,000 planted hectares. A variety of diseases routinely occur on peppers in this province, resulting in yield losses (Liu et al., 2022). Root rot is one of the most common symptoms and produces poor root growth and wilting of pepper. In April 2023, symptomatic pepper plants displaying stunting, dwarfism, wilting, and root browning were collected from five fields in Guizhou, with disease incidence ranging from 10% to 20%. The collected rotten roots were cleaned with sterilize distilled water and placed in selective V8 juice agar (V8A) medium (15% clarified V8 juice with 2.5 g/L CaCO3 and 2% agar) containing nystatin, ampicillin, rifampicin, and miconazole, and incubated at 25℃ for 1 to 2 days (Morita and Tojo, 2007). Eight isolates with similar colony morphology were transferred to V8A medium via hyphal tipping, and incubated at 25℃ in the dark. Colony and sexual structures were observed using a microscope. Mycelium was aseptate and formed white cottony colonies. Globose, intercalary, or terminal hyphal swellings were observed with a diameter of 20.5 to 25 µm (average: 22 µm), and aplerotic oospores had a diameter of 15 to 20 µm (average: 17.5 µm) with a wall thickness of approximately 2 µm. Three representative isolates HSLJ-3, LJG-1, and LJY-2 were chosen for further molecular identification. Sequences of the internal transcribed spacer (ITS) and mitochondrial cytochrome c oxidase subunit 1 (cox1) genes were identified using primer sets ITS4/ITS5 (White et al., 1990) and OomCoxI-Levup/OomCoxI-Levlo (Robideau et al., 2011), respectively. All sequences were deposited in GenBank (accession nos. OR554005, PP083310, and PP083420 for ITS, and OR529247, PP093821 and PP093822 for cox1). BLAST analysis revealed all ITS and cox1 sequences exhibited 100% identity with Globisporangium ultimum (Pythium ultimum) isolate BR850 (GenBank accession nos. HQ643892.1 and HQ708933.1 for ITS and cox1, respectively). Phylogenetic analysis was performed by the maximum-likelihood method on the CIPRES web portal (https://www.phylo.org/portal2/login!input.action, accessed on 9 January 2024). For pathogenicity tests, each isolate was cultured in V8A medium containing 50 autoclaved wheat seeds at 25℃ for 7 days. Budding pepper seedling (cv. Huaxi) was transplanted into a 0.4 L pot containing sterilized commercial potting mix (Seedling Cultivation Substrate, Hunan Xianghui Agricultural E-commerce Co., Ltd.) which was saturated with deionized water. Eight infected and non-infected wheat seeds were placed near the roots of five pepper seedlings, respectively. Plants were placed in an artificial climate chamber, with a 14 h photoperiod and approximately 75% relative humidity at 25℃. After 14 days, inoculated seedlings showed symptoms of stunting, wilting, and rotting roots similar to those observed in the field. No disease was observed on the non-inoculated control plants. The pathogen was isolated from infected pepper roots and confirmed as G. ultimum by morphological and molecular analyses as previously described. This is the first report of G. ultimum causing root rot on pepper in Guizhou, China. This finding is critical to the discover of treatment options for this pathogen, thereby improving management practices to reduce yield losses in pepper.

Sensitivity of Globisporangium ultimum to the fungicide metalaxyl is enhanced by the infection with a toti-like mycovirus.

In recent years, numerous oomycete mycoviruses have been discovered; however, very few studies have focused on their effects on the host oomycete phenotype. In this study, we investigated the impact of toti-like Pythium ultimum RNA virus 2 (PuRV2) infection on the phytopathogenic soil-borne oomycete Globisporangium ultimum, which serves as a model species for Globisporangium and Pythium, specifically the UOP226 isolate in Japan. We generated a PuRV2-free isogenic line through hyphal tip isolation using high-temperature culture and subsequently compared the phenotypic characteristics and gene expression profiles of UOP226 and the PuRV2-free isogenic line. Our findings revealed that the metalaxyl sensitivity of UOP226 was greater than that of the PuRV2-free isogenic line, whereas the mycelial growth rate and colony morphology remained unchanged in the absence of the fungicide. Furthermore, transcriptome analyses using RNA-seq revealed significant downregulation of ABC-type transporter genes, which are involved in fungicide sensitivity, in UOP226. Our results suggest that PuRV2 infection influences the ecology of G. ultimum in agricultural ecosystems where metalaxyl is applied.