First report of Didymella macrostoma causing calyx-end rot of pear (Pyrus communis) in The Netherlands.

Pear (Pyrus communis) is an important fruit crop in the Netherlands, with a total production of 400,000 tons in 2020, and 'Conference' is the main pear cultivar that comprises 80% of total pear production area. In the Netherlands, pears are kept in controlled atmosphere cold storage (-0.5°C) up to 11 months after harvest. Calyx-end rot incidences of 1% to 5% were observed on 'Conference' pears from different orchards in surveys from 2019-2021 in packing houses in the Netherlands. Infections showed 1 to 3 cm brown necrosis. Lesions were round, slightly sunken and next to or including part of the calyx. To isolate the causal agent, fruit were rinsed with sterile water, lesions were sprayed with 70% ethanol until droplet runoff, the skin was removed aseptically with a scalpel, and tissue under the lesion was isolated and placed onto Potato Dextrose Agar (PDA) (Oxoid, UK). The PDA plates were incubated at 20°C in the dark, and hyphal tip isolates were transferred to fresh PDA plates. Colonies on PDA were rosy-whitish to peach-colored. Colonies grown on oat meal agar (OA) under UV light were peach to red color, aerial mycelium sparse, and produced a pink to salmon colored conidial matrix. Conidia were irregular-ellipsoidal to allantoid, smooth, hyaline and usually with one or several gutulles. Conidia were sometimes one septate and measured 15.2±2.8 x 4.0±0.7 µm (n =14), but mostly aseptate and measured 7.9±1.7 x 3.2±0.6 µm (n =100). The fungus was morphologically identical to Didymella macrostoma (syn. Phoma macrostoma) (Boerema et al. 2004; Hou et al. 2020). The identity of four representative isolates, WURR-206, WURR-223, WURR-227 and WURR-308, from affected pears from four orchards in the Netherlands, was determined by multilocus gene sequencing. To this end, genomic DNA was extracted using the LGC Mag Plant Kit (Berlin, Germany) in combination with the Kingfisher method (Waltham, MA). Sequences of the internal transcribed spacer (ITS) region of ribosomal DNA, the large-subunit rRNA (LSU) region, partial sequences of beta-tubulin (TUB) and the translation elongation factor 1-alpha (TEF1) gene region were amplified with primers ITS1/ITS4 (White et al. 1990), LROR/LR5 (Vilgalys and Hester 1990), Btub2Fd/Btub4Rd (Woudenberg et al. 2009) and EF1-983F/EF1-1567R (Rehner and Buckley 2005), respectively. Sequences were deposited under GenBank accession numbers ON077588-ON077591 (ITS), ON113487-ON113490 (LSU), ON098515-ON098518 (TUB) and ON098519-ON098522 (TEF1). MegaBLAST analysis revealed that the ITS, LSU, TUB sequences matched with 100% identity to culture collection sequences of Didymella macrostoma in GenBank MH854841 (ITS), MH866341 (LSU), MN983895 (TUB). The TEF1 sequences matched with 99.7% identity to TEF sequence of Didymella macrostoma MT454020. Subsequently, Koch's postulates were performed on 10 'Conference' pears per isolate (WURR-206, WURR-223, WURR-227 and WURR-308). Fruits wiped with 70% ethanol were inoculated in pathogenicity tests with an agar disk (5 mm diameter) of D. macrostoma prepared from the actively growing edge of 14-day-old cultures grown on PDA. Inoculated fruits were sealed in plastic bags and were incubated in darkness at 20°C. Typical symptoms appeared 7-10 days after inoculation on all pears. PDA-only controls remained symptomless. Fungal colonies isolated from the lesions and cultured on PDA morphologically resembled the original isolate from the infected pears. The identity of the re-isolations was confirmed as D. macrostoma by sequencing, thus completing Koch's postulates. To the best of our knowledge, this is the first report of D. macrostoma causing calyx-end rot of pears. The identification of this causal agent is important knowledge necessary for developing control measures for postharvest diseases of pear.

Filamentous actin accumulates during plant cell penetration and cell wall plug formation in Phytophthora infestans.

The oomycete Phytophthora infestans is the cause of late blight in potato and tomato. It is a devastating pathogen and there is an urgent need to design alternative strategies to control the disease. To find novel potential drug targets, we used Lifeact-eGFP expressing P. infestans for high resolution live cell imaging of the actin cytoskeleton in various developmental stages. Previously, we identified actin plaques as structures that are unique for oomycetes. Here we describe two additional novel actin configurations; one associated with plug deposition in germ tubes and the other with appressoria, infection structures formed prior to host cell penetration. Plugs are composed of cell wall material that is deposited in hyphae emerging from cysts to seal off the cytoplasm-depleted base after cytoplasm retraction towards the growing tip. Preceding plug formation there was a typical local actin accumulation and during plug deposition actin remained associated with the leading edge. In appressoria, formed either on an artificial surface or upon contact with plant cells, we observed a novel aster-like actin configuration that was localized at the contact point with the surface. Our findings strongly suggest a role for the actin cytoskeleton in plug formation and plant cell penetration.

Actin dynamics in Phytophthora infestans; rapidly reorganizing cables and immobile, long-lived plaques.

The actin cytoskeleton is a dynamic but well-organized intracellular framework that is essential for proper functioning of eukaryotic cells. Here, we use the actin binding peptide Lifeact to investigate the in vivo actin cytoskeleton dynamics in the oomycete plant pathogen Phytophthora infestans. Lifeact-eGFP labelled thick and thin actin bundles and actin filament plaques allowing visualization of actin dynamics. All actin structures in the hyphae were cortically localized. In growing hyphae actin filament cables were axially oriented in the sub-apical region whereas in the extreme apex in growing hyphae, waves of fine F-actin polymerization were observed. Upon growth termination, actin filament plaques appeared in the hyphal tip. The distance between a hyphal tip and the first actin filament plaque correlated strongly with hyphal growth velocity. The actin filament plaques were nearly immobile with average lifetimes exceeding 1 h, relatively long when compared to the lifetime of actin patches known in other eukaryotes. Plaque assembly required ∼30 s while disassembly was accomplished in ∼10 s. Remarkably, plaque disassembly was not accompanied with internalization and the formation of endocytic vesicles. These findings suggest that the functions of actin plaques in oomycetes differ from those of actin patches present in other organisms.

Effect of Flumorph on F-Actin Dynamics in the Potato Late Blight Pathogen Phytophthora infestans.

Oomycetes are fungal-like pathogens that cause notorious diseases. Protecting crops against oomycetes requires regular spraying with chemicals, many with an unknown mode of action. In the 1990s, flumorph was identified as a novel crop protection agent. It was shown to inhibit the growth of oomycete pathogens including Phytophthora spp., presumably by targeting actin. We recently generated transgenic Phytophthora infestans strains that express Lifeact-enhanced green fluorescent protein (eGFP), which enabled us to monitor the actin cytoskeleton during hyphal growth. For analyzing effects of oomicides on the actin cytoskeleton in vivo, the P. infestans Lifeact-eGFP strain is an excellent tool. Here, we confirm that flumorph is an oomicide with growth inhibitory activity. Microscopic analyses showed that low flumorph concentrations provoked hyphal tip swellings accompanied by accumulation of actin plaques in the apex, a feature reminiscent of tips of nongrowing hyphae. At higher concentrations, swelling was more pronounced and accompanied by an increase in hyphal bursting events. However, in hyphae that remained intact, actin filaments were indistinguishable from those in nontreated, nongrowing hyphae. In contrast, in hyphae treated with the actin depolymerizing drug latrunculin B, no hyphal bursting was observed but the actin filaments were completely disrupted. This difference demonstrates that actin is not the primary target of flumorph.

An actin mechanostat ensures hyphal tip sharpness in Phytophthora infestans to achieve host penetration.

Filamentous plant pathogens apply mechanical forces to pierce their hosts surface and penetrate its tissues. Devastating Phytophthora pathogens harness a specialized form of invasive tip growth to slice through the plant surface, wielding their hypha as a microscopic knife. Slicing requires a sharp hyphal tip that is not blunted at the site of the mechanical interaction. How tip shape is controlled, however, is unknown. We uncover an actin-based mechanostat in Phytophthora infestans that controls tip sharpness during penetration. Mechanical stimulation of the hypha leads to the emergence of an aster-like actin configuration, which shows fast, local, and quantitative feedback to the local stress. We evidence that this functions as an adaptive mechanical scaffold that sharpens the invasive weapon and prevents it from blunting. The hyphal tip mechanostat enables the efficient conversion of turgor into localized invasive pressures that are required to achieve host penetration.

A slicing mechanism facilitates host entry by plant-pathogenic Phytophthora.

Phytophthora species, classified as oomycetes, are among the most destructive plant pathogens worldwide and pose a substantial threat to food security. Plant pathogens have developed various methods to breach the cuticle and walls of plant cells. For example, plant-pathogenic fungi use a 'brute-force' approach by producing a specialized and fortified invasion organ to generate invasive pressures. Unlike in fungi, the biomechanics of host invasion in oomycetes remains poorly understood. Here, using a combination of surface-deformation imaging, molecular-fracture sensors and modelling, we find that Phytophthora infestans, Phytophthora palmivora and Phytophthora capsici slice through the plant surface to gain entry into host tissues. To distinguish this mode of entry from the brute-force approach of fungi that use appressoria, we name this oomycete entry without appressorium formation 'naifu' invasion. Naifu invasion relies on polarized, non-concentric, force generation onto the surface at an oblique angle, which concentrates stresses at the site of invasion to enable surface breaching. Measurements of surface deformations during invasion of artificial substrates reveal a polarized mechanical geometry that we describe using a mathematical model. We confirm that the same mode of entry is used on real hosts. Naifu invasion uses actin-mediated polarity, surface adherence and turgor generation to enable Phytophthora to invade hosts without requiring specialized organs or vast turgor generation.