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Forests are under threat from pests, pathogens, and changing climate. A major forest pathogen worldwide is the hemibiotroph Dothistroma septosporum , which causes dothistroma needle blight (DNB) of pines. While D. septosporum uses effector proteins to facilitate host infection, it is currently unclear whether any of these effectors are recognised by immune receptors to activate the host immune system. Such information is needed to identify and select disease resistance against D. septosporum in pines. We predicted and investigated apoplastic D. septosporum candidate effectors (DsCEs) using bioinformatics and plant-based experiments. We discovered DsCEs that trigger cell death in the angiosperm Nicotiana spp., indicative of a hypersensitive defence response and suggesting their recognition by immune receptors in non-host plants. In a first for foliar forest pathogens, we developed a novel protein infiltration method to show that tissue-cultured pine shoots can respond with a cell death response to a DsCE, as well as to a reference cell death-inducing protein. The conservation of responses across plant taxa suggests that knowledge of pathogen–angiosperm interactions may also be relevant to pathogen–gymnosperm interactions. These results contribute to our understanding of forest pathogens and may ultimately provide clues to disease immunity in both commercial and natural forests.

Dothistroma needle blight, caused by Dothistroma septosporum, has increased in incidence and severity over the last few decades and is now one of the most important global diseases of pines. Disease resistance breeding could be accelerated by knowledge of pathogen virulence factors and their host targets. However, this is hindered due to inefficient targeted gene disruption in D. septosporum, which is required for virulence gene characterisation. Here we report the first successful application of CRISPR/Cas9 gene editing to a Dothideomycete forest pathogen, D. septosporum. Disruption of the dothistromin pathway regulator gene AflR, with a known phenotype, was performed using nonhomologous end-joining repair with an efficiency of >90%. Transformants with a range of disruption mutations in AflR were produced. Disruption of Ds74283, a D. septosporum gene encoding a secreted cell death elicitor, was also achieved using CRISPR/Cas9, by using a specific donor DNA repair template to aid selection where the phenotype was unknown. In this case, 100% of screened transformants were identified as disruptants. In establishing CRISPR/Cas9 as a tool for gene editing in D. septosporum, our research could fast track the functional characterisation of candidate virulence factors in D. septosporum and helps set the foundation for development of this technology in other forest pathogens.

Cyclaneusma needle cast, caused by Cyclaneusma minus , affects Pinus species world wide. Previous studies suggested the presence of two distinct morphotypes in New Zealand, ‘verum’ and ‘simile’. Traditional mycological analyses revealed a third morphotype with clear differences in colony morphology and cardinal growth rates at varying temperatures. Genome sequencing of eight C. minus isolates provided further evidence of the existence of a third morphotype, named as ‘novus’ in this study. To further analyse these morphotypes, we predicted candidate effector proteins for all eight isolates, and also characterized a cell-death eliciting effector family, Ecp32, which is present in other pine phytopathogens. In concordance with their distinct classification into three different morphotypes, the number of Ecp32 family members differed, with patterns of pseudogenization in the ‘simile’ morphotype, and some members being found exclusively either in the ‘simile’ or ‘verum’ morphotypes. We also showed that the Ecp32 family proteins trigger cell death in non-host Nicotiana species, and, as previously demonstrated in other plant pathogens, the Ecp32 family proteins in C. minus adopt a β-trefoil fold. These analyses provide further evidence that the three morphotypes might be distinct species that need formal descriptions. Understanding the geographical range of different Cyclaneusma species and variations in virulence and pathogenicity will provide a better understanding of pine needle diseases and enable the development of more durable methods to control this disease.

Dothistroma needle blight, Cyclaneusma needle blight and red needle cast are devastating foliar pine diseases caused by the fungi Dothistroma septosporum and Cyclaneusma minus and the oomycete Phytophthora pluvialis, respectively. These pathogens colonise the host apoplast, secreting effector proteins to promote infection and disease. If these effectors are recognised by corresponding host resistance proteins, they activate the plant immune system to stop pathogen growth. We aimed to identify and characterise effectors that are common to all three pathogens. Using D. septosporum as a starting point, three candidate effectors (CEs) were investigated: Ds69335 (a CAP protein) and Ds131885, both of which have sequence and structural similarity to CEs of C. minus and P. pluvialis, and Ds74283, which adopts a β-trefoil fold and has structural rather than sequence similarity to CEs from all three pathogens. Notably, of the CEs investigated, Ds74283 and Ds131885, as well as their homologues from C. minus and P. pluvialis, elicited chlorosis or cell death in Nicotiana species, with Ds131885 and its homologues also triggering cell death in Pinus radiata. In line with these observed responses being related to activation of the plant immune system, the chlorosis triggered by Ds131885 and its homologues was compromised in a Nicotiana benthamiana mutant lacking the extracellular immune system co-receptor, SOBIR1. Such cross-kingdom, plant immune system-activating effectors, whether similar in sequence or structure, might ultimately enable the selection or engineering of durable, broad-spectrum resistance against foliar pine pathogens

Fulvia fulva and Dothistroma septosporum are closely related apoplastic pathogens with similar lifestyles but different hosts: F. fulva is a pathogen of tomato, whilst D. septosporum is a pathogen of pine trees. In 2012, the first genome sequences of these pathogens were published, with F. fulva and D. septosporum having highly fragmented and near‐complete assemblies, respectively. Since then, significant advances have been made in unravelling their genome architectures. For instance, the genome of F. fulva has now been assembled into 14 chromosomes, 13 of which have synteny with the 14 chromosomes of D. septosporum, suggesting these pathogens are even more closely related than originally thought. Considerable advances have also been made in the identification and functional characterization of virulence factors (e.g., effector proteins and secondary metabolites) from these pathogens, thereby providing new insights into how they promote host colonization or activate plant defence responses. For example, it has now been established that effector proteins from both F. fulva and D. septosporum interact with cell‐surface immune receptors and co‐receptors to activate the plant immune system. Progress has also been made in understanding how F. fulva and D. septosporum have evolved with their host plants, whilst intensive research into pandemics of Dothistroma needle blight in the Northern Hemisphere has shed light on the origins, migration, and genetic diversity of the global D. septosporum population. In this review, we specifically summarize advances made in our understanding of the F. fulva–tomato and D. septosporum–pine pathosystems over the last 10 years. In this review we summarize advances from the last decade in understanding the molecular basis of how the closely related fungal pathogens Fulvia fulva and Dothistroma septosporum interact with their respective tomato and pine hosts.

Phytophthora agathidicida, the causal agent of kauri dieback, secretes RXLR effector proteins to promote host colonisation. One of these, PaRXLR40, was previously shown to suppress immune responses in Nicotiana benthamiana, but its mechanism of action and contribution to virulence remained unclear. To investigate PaRXLR40 function, we used comparative approaches in N. benthamiana and Agathis australis (kauri), including RNA interference (RNAi), transient expression assays, confocal microscopy, yeast two-hybrid screens, and infection assays. We also examined host protein interactors and tested mutant variants to evaluate functional domains. Silencing PaRXLR40 reduced P. agathidicida colonization in N. benthamiana and A. australis. PaRXLR40 interacted with a host BTB/ARM domain protein (ARIA), previously implicated in abscisic acid (ABA) signalling. ARIA suppressed immunity and promoted infection, while interacting with NbSOG1, a DNA damage-associated transcription factor that enhanced resistance when overexpressed. External application of ABA enhanced P. agathidicida infection in both hosts, supporting the hypothesis that PaRXLR40 may hijack host ABA signalling through ARIA to promote susceptibility. Our findings show that PaRXLR40 targets ARIA to manipulate host immunity and promote virulence. The interaction between ARIA and SOG1 suggests PaRXLR40 may interfere with host transcriptional reprogramming. PaRXLR40 represents a potential target for future RNAi-based strategies to reduce kauri dieback.

Dothistroma septosporum (Ds) and Fulvia fulva (Ff; previously called Cladosporium fulvum) are two closely related Dothideomycete fungal species that cause Dothistroma needle blight in pine and leaf mold in tomato, respectively. During host colonization, these pathogens secrete virulence factors termed effectors to promote infection. In the presence of corresponding host immune receptors, however, these effectors activate plant defenses, including a localized cell death response that halts pathogen growth. We identified two effector protein families, Ecp20 and Ecp32, which are conserved between the two pathogens. The Ecp20 family has four paralogues in both species, while the Ecp32 family has four paralogues in D. septosporum and five in F. fulva. Both families have members that are highly expressed during host infection. Members of the Ecp20 family have predicted structural similarity to proteins with a β-barrel fold, including the Alt a 1 allergen from Alternaria alternata, while members of the Ecp32 family have predicted structural similarity to proteins with a β-trefoil fold, such as trypsin inhibitors and lectins. Using Agrobacterium tumefaciens-mediated transient transformation assays, each family member was assessed for its ability to trigger cell death in leaves of the non-host species Nicotiana benthamiana and N. tabacum. Using this approach, FfEcp20-2, DsEcp20-3 and FfEcp20-3 from the Ecp20 family, and all members from the Ecp32 family, except for the Ds/FfEcp32-4 pair, triggered cell death in both species. This cell death was dependent on secretion of the effectors to the apoplast. In line with recognition by an extracellular immune receptor, cell death triggered by Ds/FfEcp20-3 and FfEcp32-3 was compromised in N. benthamiana silenced for BAK1 or SOBIR1, which encode extracellular co-receptors involved in transducing defense response signals following apoplastic effector recognition. We then investigated whether DsEcp20-3 and DsEcp20-4 triggered cell death in the host species Pinus radiata by directly infiltrating purified protein into pine needles. Strikingly, as in the non-host species, DsEcp20-3 triggered cell death, while DsEcp20-4 did not. Collectively, our study describes two new candidate effector families with cell death-eliciting activity from D. septosporum and F. fulva and provides evidence that members of these families are recognized by plant immune receptors.

Leaf mould, caused by Fulvia fulva, is a devastating disease of tomato plants. In many commercial tomato cultivars, resistance to this disease is governed by the Cf-9 locus, which comprises five paralogous genes (Cf-9A–9E) that encode receptor-like proteins. Two of these proteins contribute to resistance: Cf-9C recognizes the previously identified F. fulva effector Avr9 and provides resistance during all plant growth stages, while Cf-9B recognises the yet-unidentified F. fulva effector Avr9B and provides mature plant resistance only. In recent years, F. fulva strains have emerged that have overcome the Cf-9 locus, with Cf-9C circumvented through Avr9 deletion. To understand how Cf-9B is circumvented, we set out to identify Avr9B. Comparative genomics, in planta transient expression assays and gene complementation experiments were used to identify Avr9B, while gene sequencing was used to assess Avr9B allelic variation across a worldwide strain collection. A strict correlation between Avr9 deletion and resistance-breaking mutations in Avr9B was observed in strains recently collected from Cf-9 cultivars, whereas Avr9 deletion but no mutations in Avr9B were observed in older strains. This research showcases how F. fulva has evolved to sequentially break down the two functional resistance genes of the complex Cf-9 locus and highlights that this locus now has limited value for controlling leaf mould disease in worldwide commercial tomato production.

Forests are under threat from pests, pathogens, and changing climate. One of the major forest pathogens worldwide is Dothistroma septosporum, which causes dothistroma needle blight (DNB) of pines. D. septosporum is a hemibiotrophic fungus related to well-studied Dothideomycete pathogens, such as Cladosporium fulvum. These pathogens use small secreted proteins, termed effectors, to facilitate the infection of their hosts. The same effectors, however, can be recognised by plants carrying corresponding immune receptors, resulting in resistance responses. Hence, effectors are increasingly being exploited to identify and select disease resistance in crop species. In gymnosperms, however, such research is scarce. We predicted and investigated apoplastic D. septosporum candidate effectors (DsCEs) using bioinformatics and plant-based experiments. We discovered secreted proteins that trigger cell death in the angiosperm Nicotiana spp., suggesting their recognition by immune receptors in non-host plants. In a first for foliar forest pathogens, we also developed a novel protein infiltration method to show that tissue-cultured pine shoots can respond with a cell death response to one of our DsCEs, as well as to a reference cell death-inducing protein. These results contribute to our understanding of forest pathogens and may ultimately provide clues to disease immunity in both commercial and natural forests. Competing Interest Statement The authors have declared no competing interest.

Covid-19 is an infective respiratory illness caused by a novel virus, which might present different degrees of severity: from mild or even asymptomatic carriers to severe pneumonia, requiring intubation and intensive care unit (ICU) management. SARS-CoV-2 may cause also central nervous system involvement, including psychiatric manifestations. Some cases of psychosis apparently covid-related have been reported since the start of the pandemic; we will briefly review some of them here, then we will report a case concerning a patient with emerging psychosis during the disease caused by the virus. Our case describes a man with no prior personal or familiar psychiatric history, who developed delusion and a post-traumatic stress symptoms (PTSS) which required hospitalization in a psychiatric unit. The patient was treated with antipsychotic medications and underwent a brief follow-up.