Dothistroma spp. in Western Ukraine and Georgia

Dothistroma needle blight (DNB) is among the most serious foliar diseases affecting Pinus spp. globally. Infected needles were collected from potential host species in four locations in western Ukraine and in four locations in eastern Georgia during spring–summer 2015 to update the knowledge on pathogen distribution in these countries. Dothistroma spp. were detected using isolation, sequencing and species‐specific priming (SSPP) PCR. Two new hosts for Dothistroma spp. were recorded in western Ukraine: D. septosporum on Pinus nigra var. australica and D. pini on P. nigra var. mollet. D. septosporum was found on 15‐year‐old P. strobus in western Ukraine. New hosts for D. septosporum were recorded in Georgia on 5‐ to 10‐year‐old naturally regenerated P. sylvestris var. hamata and on 40‐ to 50‐year‐old P. ponderosa trees. D. pini was found for the first time in Georgia on 30‐ to 40‐year‐old P. nigra trees. The work confirmed the presence of both D. septosporum and D. pini in western Ukraine and Georgia, and demonstrated new hosts for both Dothistroma species.     

The hosts and geographic range of Dothistroma needle blight in Slovakia

The occurrence and distribution of Dothistroma needle blight (DNB) were studied in 2014–2017 around Slovakia. A total of 84 localities, both native and planted, were investigated, and the presence of DNB was confirmed in 73 of them. In all positive locations, symptoms typical of DNB were observed and the Dothistroma species was confirmed using species‐specific primers either from fungal cultures or directly from needles. Both Dothistroma species—D. septosporum and D. pini—were identified. Both species occurred together in 29 locations, only D. septosporum in 42 and only D. pini in two locations. The host range of D. septosporum included 10 pine species and two spruce species. The host range of D. pini comprised the same number of pine hosts but only one spruce species. Five pine hosts, P. aristata, P. coulteri, P. densiflora, P. jeffreyi, P. × schwerinii, and one spruce host P. abies are new hosts species of D. pini. P. densiflora and Picea pungens have earlier been reported to be susceptible for DNB. In this study, D. septosporum was found from both tree species.     

Artificial inoculation and susceptibility of Pinus armandii to Dothistroma septosporum

Dothistroma needle blight (DNB) is a serious needle disease of conifers that primarily affects pine species (Pinus spp.). Dothistroma septosporum is one of the DNB pathogens that has a diverse range of host species excluding Pinus armandii. In 15 inoculated P. armandii seedlings, D. septosporum acervuli were observed in 43 infected needles of ten seedlings with a mean disease severity of 1.11% at 25 weeks after inoculations, demonstrating the potential of D. septosporum to cause symptoms on the needles of P. armandii via artificial inoculation. The disease severity of P. armandii was similar to the positive control, Pinus nigra (median 0.75 for P. armandii to 0.70 for P. nigra), thus, P. armandii acts under artificial conditions as a susceptible host species.     

New host and country records of the Dothistroma needle blight pathogens from Europe and Asia

Dothistroma needle blight (DNB) is a serious disease of pines (Pinus spp.), with a worldwide distribution. It is caused by the ascomycete fungi Dothistroma septosporum (teleomorph: Mycosphaerella pini) and Dothistroma pini (teleomorph unknown). Recently, DNB was found on Pinus peuce in Austria, Pinus pallasiana in Ukraine and the European part of south-western Russia, as well as on Pinus radiata and Pinus wallichiana in Bhutan. Based on DNA sequence comparisons of the internal transcribed spacer and β-tubulin gene regions, isolates from Austria and Bhutan were identified as D. septosporum, while isolates from Ukraine and south-western Russia were identified as D. pini. Additional isolates studied from Pinus mugo in Hungary confirmed the presence of D. septosporum in this country. The record of D. septosporum on exotic P. peuce in Austria represents a new host report of this needle blight pathogen in Europe. Likewise, DNB and the associated pathogen, D. septosporum are reported from Bhutan, eastern Himalayas, for the first time. In addition, D. pini was found in two European countries and on a new host, P. pallasiana. These European records represent the only reports of D. pini from outside the north-central USA. Morphological examination of selected specimens from different hosts and countries showed that D. septosporum and D. pini overlap in the length of their conidia, while the width is slightly wider in D. pini than in D. septosporum. The differences in conidial width are so small, however, that identification of the two Dothistroma species solely based on morphology is virtually impossible. The new host and country records provided here are consistent with the continuing trend of reports of the DNB pathogens from new hosts and new geographical areas during the last two decades, particularly in the northern hemisphere.     

The hemibiotrophic lifestyle of the fungal pine pathogen Dothistroma septosporum

Dothistroma needle blight is a forest disease of increasing international importance due to its ability to kill as well as to retard the growth of pines. It is caused by fungi in the genus Dothistroma that produce dothistromin, a non‐host selective toxin and virulence factor that is involved in necrosis of pine tissue. Recent studies of the genome of one of the main pathogenic species, Dothistroma septosporum, showed that it contains many similarities to that of the biotroph Cladosporium fulvum, including the presence of candidate biotrophic effector genes, which supported the hypothesis that D. septosporum has a hemi‐biotrophic lifestyle. Using Pinus radiata as a host, we used a combination of microscopy, histological and molecular tools to further test this hypothesis and to determine the stage of the disease cycle in which dothistromin toxin is produced. The results showed a biotrophic‐type phase in which the fungus grew over the needle surface, penetrated through stomatal pores and colonized epistomatal chambers. The subsequent necrotrophic phase was characterized by colonization of the mesophyll and production of dothistromin, with a >100‐fold increase in dothistromin levels from early necrotic lesion to sporulating lesion stages. This is consistent with the role of dothistromin as a virulence factor that is involved in lesion expansion.     

Needle blight of pine caused by two species of Dothistroma in Hungary

Dothistroma septosporum and D. pini cause the serious pine needle disease, Dothistroma needle blight (DNB). Of these, D. septosporum has a global distribution, while D. pini is known only from the USA, Russia, Ukraine and France. During a study of D. septosporum isolates from Pinus nigra in Hungary, microsatellite markers revealed the presence of a second Dothistroma species. The aim of this study was to identify the DNB pathogens occurring in Hungary using four different molecular techniques. These included sequencing of the rDNA ITS region, a species‐specific ITS‐RFLP, mating type primers and a diagnostic microsatellite marker, Doth_A. Results showed that both D. septosporum and D. pini occur in Hungary and that both DNB pathogens were present on the same trees and in some cases, the same needles. Mating types MAT1 and MAT2 of D. septosporum were shown to be present in Hungary, but only the MAT2 of D. pini was found. In addition, examination of needles with DNB symptoms from Russia revealed the presence of D. pini on Pinus pallasiana and P. nigra as well as on a new host, Pinus mugo. The molecular markers applied in this study were sufficiently robust to identify and differentiate between the two DNB pathogens, both in culture and directly from needles. They will consequently be useful to document the geographical range and to monitor the spread of D. septosporum and D. pini in future studies.     

Predicting the severity of Dothistroma on Pinus radiata under current climate in New Zealand

Despite being a damaging foliar disease of Pinus species little research has characterised spatial variation in disease severity of Dothistroma needle blight at a macroscale. Using an extensive dataset describing Dothistroma needle blight severity (S_sev) on plantation grown Pinus radiata stands distributed widely across New Zealand the objectives of this research were to (i) develop a regression model describing S_sev, (ii) use this model to identify key drivers of S_sev, their functional form and relative importance, and (iii) develop spatial predictions of S_sev for New Zealand P. radiata under current climate. Using an independent validation dataset, the final model accounted for 72% of the variance in S_sev using four significant (P < 0.001) explanatory variables and an isotrophic exponential model to account for the spatial covariance in the data. S_sev was most sensitive to mean air temperature from November to April (T_Nov-Apr), followed by mean relative humidity from October to April (RH_Oct-Apr), mean total November rainfall (P_Nov), and then stand age (A). There was a quadratic correlation between A and S_sev with S_sev increasing to a maxima at 12 years before declining. S_sev exponentially increased to a threshold with increases in both P_Nov and RH_Oct-Apr. The relationship between S_sev and T_Nov-Apr was quadratic with S_sev increasing to a maximum at T_Nov-Apr of 15.5 °C before declining at higher values of T_Nov-Apr. Spatial predictions of S_sev varied widely throughout New Zealand. Values of S_sev were highest in moderately warm wet environments in the North Island, and on the west coast of the South Island. In contrast, relatively low values of S_sev were predicted in drier eastern and southern regions of New Zealand.     

Short-term effects of hexazinone applications on woody species diversity in young loblolly pine (Pinus taeda) plantations

Data from four studies determining the susceptibility of woody plant species to foliar applications of several rates of liquid hexazinone (Velpar L®) were used to examine the short-term effects of the herbicide on woody species diversity in young loblolly pine plantations. Woody species diversity, as measured by four similarity measures between pretreatment and post-treatment species importance or diversity, decreased significantly with increasing hexazinone rate. Woody species shown to be among the most susceptible (sumacs (Rhus spp.) and oaks (Quercus spp.)), and least susceptible (loblolly and other pines, and Vaccinium spp.) to hexazinone in previous herbicide screening trials decreased and increased in importance, respectively. Differences in similarity measures between the no-hexazinone treatment and the 1.0 × hexazinone rate (1.2 to 1.5 kg a.i./ha depending on the study location) 2 years after herbicide application were small.     

Dothistroma septosporum on firs (Abies spp.) in the northern Baltics

In the spring of 2008, Dothistroma septosporum, a damaging quarantine pathogen of pine foliage, was documented in Järvselja (southeastern Estonia), apparently for the first time, on white fir (Abies concolor). Thus, a new host species and genus for the fungus were recorded. Infection of white fir by D. septosporum, and also of some other fir species, was monitored annually on a transect proceeding from southeastern Estonia to northern Latvia. As a result, D. septosporum was detected also on silver fir (Abies alba). It is not clear why this fungus with a worldwide distribution appeared on this new host genus definitely in northern Europe.     

Predicting potential and actual distribution of sudden oak death in Oregon: Prioritizing landscape contexts for early detection and eradication of disease outbreaks

An isolated outbreak of the emerging forest disease sudden oak death was discovered in Oregon forests in 2001. Despite considerable control efforts, disease continues to spread from the introduction site due to slow and incomplete detection and eradication. Annual field surveys and laboratory tests between 2001 and 2009 confirmed a total of 802 infested locations. Here, we apply two invasive species distribution models (iSDMs) of sudden oak death establishment and spread risk to target early detection and control further disease spread in Oregon forests. The goal was to develop (1) a model of potential distribution that estimates the level and spatial variability of disease establishment and spread risk for western Oregon, and (2) a model of actual distribution that quantifies the relative likelihood of current invasion in the quarantine area. Our predictions were based on four groups of primary parameters that vary in space and time: climate conditions, topographical factors, abundance and susceptibility of host vegetation, and dispersal pressure. First, we used multi-criteria evaluation to identify large-scale areas at potential risk of infection. We mapped and ranked host abundance and susceptibility using geospatial vegetation data developed with gradient nearest neighbor imputation. The host vegetation and climate variables were parameterized in accordance to their epidemiological importance and the final appraisal scores were summarized by month to represent a cumulative spread risk index, standardized as five categories from very low to very high risk. Second, using the field data for calibration we applied the machine-learning method, maximum entropy, to predict the actual distribution of the sudden oak death epidemic. The dispersal pressure incorporated in the statistical model estimates the force of invasion at all susceptible locations, allowing us to quantify the relative likelihood of current disease incidence rather than its potential distribution. Our predictions show that 65 km² of forested land was invaded by 2009, but further disease spread threatens more than 2100 km² of forests across the western region of Oregon (very high and high risk). Areas at greatest risk of disease spread are concentrated in the southwest region of Oregon where the highest densities of susceptible host species exist. This research identifies high priority locations for early detection and invasion control and illustrates how iSDMs can be used to analyze the actual versus potential distribution of emerging infectious disease in a complex, heterogeneous ecosystem.     

Comparison of histological responses and tissue damage expansion between resistant and susceptible Pinus thunbergii infected with pine wood nematode Bursaphelenchus xylophilus

Pine wilt disease caused by the pine wood nematode (PWN), Bursaphelenchus xylophilus, has been epidemic and has had disastrous impacts on pine forests and forest ecosystems in eastern Asia. Many pine species in this area are susceptible to this disease. Pinus thunbergii is particularly susceptible. In Japan, tree breeders have selected surviving trees from severely damaged forests as resistant candidates, and have finally established several resistant varieties of P. thunbergii. However, this breeding procedure requires much time and effort due to the lack of physiological and phenotypical information about resistance. To investigate the resistance mechanisms of selected P. thunbergii, we compared histochemical responses, tissue damage expansion, and PWN distribution in resistant and susceptible clones of P. thunbergii after PWN inoculation. The results suggested that the mechanisms of resistance are as follows: damage expansion in the cortex, cambium, and xylem axial resin canals are retarded in resistant trees soon after inoculation, probably due to the induction of wall protein-based defenses. Suppression of PWN reproduction was particularly caused by inhibition of damage expansion in the cambium. The slow expansion of damage in each tissue provides time for the host to complete the biosynthesis of lignin in the walls of cells that surround the damaged regions. This lignification of cell walls is assumed to effectively inhibit the migration and reproduction of the PWNs. The mechanism of initial damage retardation is presumed to be a key for resistance.     

Assessing forest vulnerability and the potential distribution of pine beetles under current and future climate scenarios in the Interior West of the US

The aim of our study was to estimate forest vulnerability and potential distribution of three bark beetles (Curculionidae: Scolytinae) under current and projected climate conditions for 2020 and 2050. Our study focused on the mountain pine beetle (Dendroctonus ponderosae), western pine beetle (Dendroctonus brevicomis), and pine engraver (Ipspini). This study was conducted across eight states in the Interior West of the US covering approximately 2.2 million km² and encompassing about 95% of the Rocky Mountains in the contiguous US. Our analyses relied on aerial surveys of bark beetle outbreaks that occurred between 1991 and 2008. Occurrence points for each species were generated within polygons created from the aerial surveys. Current and projected climate scenarios were acquired from the WorldClim database and represented by 19 bioclimatic variables. We used Maxent modeling technique fit with occurrence points and current climate data to model potential beetle distributions and forest vulnerability. Three available climate models, each having two emission scenarios, were modeled independently and results averaged to produce two predictions for 2020 and two predictions for 2050 for each analysis. Environmental parameters defined by current climate models were then used to predict conditions under future climate scenarios, and changes in different species’ ranges were calculated. Our results suggested that the potential distribution for bark beetles under current climate conditions is extensive, which coincides with infestation trends observed in the last decade. Our results predicted that suitable habitats for the mountain pine beetle and pine engraver beetle will stabilize or decrease under future climate conditions, while habitat for the western pine beetle will continue to increase over time. The greatest increase in habitat area was for the western pine beetle, where one climate model predicted a 27% increase by 2050. In contrast, the predicted habitat of the mountain pine beetle from another climate model suggested a decrease in habitat areas as great as 46% by 2050. Generally, 2020 and 2050 models that tested the three climate scenarios independently had similar trends, though one climate scenario for the western pine beetle produced contrasting results. Ranges for all three species of bark beetles shifted considerably geographically suggesting that some host species may become more vulnerable to beetle attack in the future, while others may have a reduced risk over time.     

Effect of ground cover management on Thysanoptera (thrips) in clementine mandarin orchards

Conservation biological control by means of ground cover offers an interesting alternative to chemical control. A complex of Thysanoptera (thrips) species inhabits citrus, some of which are considered pests. This study investigated the effect of ground cover management on thrips species composition, distribution, and seasonal abundance in four commercial clementine mandarin (Citrus clementina Tanaka) orchards. Three soil management systems were compared: resident vegetation, Festuca arundinacea Schreber (Poales: Poaceae), and bare soil. Cover management affected thrips species diversity and abundance. Two of the main species causing fruit damage in Spanish citrus, Frankliniella occidentalis (Pergande) and Thrips tabaci Lindeman, were abundant in the resident ground cover. However, their abundance was strongly depressed in the F. arundinacea cover. The resident vegetation cover could provide a range of suitable host plants supporting populations of potential thrips pest species beyond the citrus blooming period. The F. arundinacea cover, which hosted Poaceae-specific thrips species, could also provide alternative food sources for Phytoseiidae mites. These predatory mites could reduce populations of potential thrips and other citrus pests below economic injury level. Our results confirm the suitability of F. arundinacea as a cover crop for clementine mandarins.     

Variation in host usage among geographic populations of Leptinotarsa decemlineata,the Colorado potato beetle

Insect herbivores can become extensive invaders if they are able to undergo host expansions onto widely-grown agricultural host plants. An important yet unresolved question is whether all herbivore populations are equally able to utilize new host plants or if populations may be geographically structured, that is only a subset has the potential to undergo a host range expansion and become widely invasive. We examined if derived and ancestral geographic populations of L. decemlineata or Colorado potato beetle, varied in host preference and performance on both wild (Solanum rostratum) and cultivated (Solanum tuberosum) host plants. Sampling from six different North American regions (3 ancestral and 2 derived), we performed two full-factorial experiments to test for differences in host preference, acceptance, and performance on S. rostraum and S. tuberosum. Our results reveal the development of new (cultivated) host associations within pest populations of L. decemlineata following its geographic expansion. Pest beetles (i.e., Vermont populations) discriminated less between host plants and grew faster than all other beetle population on both host species. The Vermont beetles also developed faster on leaves than all other populations. The greater general preference, acceptance, and performance of Vermont beetles on all host types underscores the virulence of the pest form of the beetle and may help to explain the absence of pest incidence within the ancestral regions of L. decemlineata.     

THE DEVELOPMENT PATTERN OF DOTHISTROMA NEEDLE BLIGHT AND ITS CONTROL

From field investigations and inoculations,Dothistroma pini,the pathogen ofDothistroma needle blight was found to overwinter as mycelium and unmatured acervuli in infectedneedles.The conidia were spreaded mainly by rain splash.The disease became widespread by trans-porting discased seedlings and seions conidia spread throughout the growing season,but mainlyfrom May to July.The diseade was found in both stand locations in each summer of investigation.The outbreak severity was serious in pure stands of susceptible pine and mixed stands with largecomponents of suseeotuble pine.but slight in mixed stands of unsusceptible species with small com-ponents of suseeptible hosts.The disease was less severe in pruned stands than in unpruned stands.The disease was most serious near the infection centre.indoor and outdoor tests,it was shown thatChlorothalonil smoke,Chlorothalonil spray and Thiram and Asomate sprays were effective controlfungicides.     

Patterns of niche filling and expansion across the invaded ranges of <Emphasis Type="Italic">Halyomorpha halys</Emphasis> in North America and Europe

Studies of realized niche shift and model transferability in alien species usually ignore the potential effects of source populations and different invaded-range environments on niche lability. We incorporate our detailed knowledge of the native-range source populations and global introduction history of brown marmorated stink bug (Halyomorpha halys) to examine intraspecific variation in realized niche expansion and unfilling, and to investigate how niche modelling approaches are affected by that variation. Realized niche dynamics of H. halys were analyzed using an ordination method, ecological niche models (ENMs), and occurrence records from (1) East Asia, (2) North America, (3) Europe, (4) native-range source populations for North America and Europe introductions, and (5) global range. Patterns of niche filling and expansion were observed across the invaded ranges of H. halys in North America and Europe: niche unfilling (42.7 %) and expansion (0.0 %) in North America, and unfilling (80.5 %) and expansion (28.0 %) in Europe. Some invasive populations have expanded into climatically novel areas in central Europe. Results presented here provide evidence that H. halys has not yet occupied all suitable climatic habitats in North America and Europe that resemble its native range, and the central USA and most parts of Europe appear to be most at risk of H. halys spread in near future. When realized niche shifts dominated by niche unfilling, fully capturing species’ requirement by basing ENMs on native range may be more important for accurate invasion forecasts than non-native models. Caution is warranted when using the source population to estimate invasion potential.     

Dothistroma Needle Blight in Slovenia is caused by two cryptic species: Dothistroma pini and Dothistroma septosporum

Dothistroma Needle Blight (DNB) has been known in Slovenia since 1971, but the disease symptoms have intensified in recent years. With this study, the DNB symptoms in Slovenia are for the first time connected to both phytopathogenic Dothistroma species: D. pini and D. septosporum. Based on the ITS‐rDNA comparisons, the Slovenian isolates of D. pini group with the D. pini isolates from France, Hungary and the USA and not with the D. pini isolates from Russia and Ukraine. Both mating types MAT1 and MAT2 of D. septosporum are present in Slovenia, while for D. pini, only MAT2 was found. The current widespread occurrence of D. pini in native forest stands indicates the prolonged presence of this species in Slovenia.     

Beobachtungen über Wechselwirkungen dreier Nadelpilze der Kiefer in vitro

Interactions in vitro among three pine needle fungi . Interactions in vitro among Lophodermium pinastri, Naemacyclus niveus and Dothistroma pini, all fungi on conifers, were related to their various host spectra. The results were remarkably conformable, with those species which were mutually tolerant in vitro being joint colonisers of many host species and vice versa.     

Interaction between light and drought affect performance of Asian tropical tree species that have differing topographic affinities

We studied two pairs of congeneric species (Dipterocarpus hispidus, Dipterocarpus zeylanicus, Mesua ferrea, and Mesua nagassarium). These species are canopy trees of rain forest in south-west Sri Lanka that exhibit differing topographic affinities. We hypothesized that topographic affinity is related to successional status and species ability to endure drought. We tested for these changes by measuring morphology of seedlings growing with each other in differing combinations of light and water. We constructed shade houses with a range of photosynthetic photon flux densities (PFD) and red:far red (R:FR) ratios. Two watering regimes within shade treatments created soil conditions that were either evermoist or periodically dry. Seedlings of the four species were inter-planted at equal spacing within large flats. They were allowed to grow amongst each other for a 2-year period. The more shade-intolerant Dipterocarpus spp. exhibited greater morphological responsiveness to increases in irradiance than the more shade-tolerant Mesua spp. We also demonstrate that all four species differ substantially from each other when morphological attributes (height, dry mass, leaf area) are compared together. Differences among these four species can be logically explained by their sequential competitive exclusion in relation to increasingly limited resources of light and soil water. In high light and evermoist soil conditions D. zeylanicus performs best. Under deep shade Mesua spp. have greater height than Dipterocarpus spp. When soil water is limiting, and the level of shade intermittent, M. nagassarium has greater height than the other three species. These results conform to species observed topographic distribution in the forest. Further studies are needed of wild populations growing across a range of forest sites to confirm whether these four species differ when grown under natural field conditions.     

Melampsora and Marssonina pathogens of poplars and willows in New Zealand

New Zealand has hosted three Melampsora species attacking poplars (Populus spp.), namely, Melampsora larici-populina, Melampsora medusae and for a single season, Melampsora medusae-populina, a unique interspecific hybrid. The predominant species, M. larici-populina, over-winters via larch and each year new races appear causing defoliation of previously rust-resistant cultivars. Melampsora medusae also occurs in some seasons following over-wintering on certain hosts or by aerial transport from Australia. Willows (Salix spp.) host four Melampsora species, Melampsora coleosporioides, Melampsora epitea var. epitea and two unidentified species attacking Salix viminalis and Salix daphnoides/Salix incana× open pollinated hybrids, respectively. The host range and pathogenicity of these species have remained static as no breakdown in host resistance has been observed. The anthracnose fungi, Marssonina brunnea and Marssonina castagnei on poplar, and Marssonina salicicola on tree willows occur throughout New Zealand. All three species can cause severe defoliation of susceptible cultivars in moist districts where annual rainfall exceeds 1000 mm. Although all form abundant microconidia during autumn, the Drepanopeziza states have never been observed in New Zealand. During an unusually wet summer (199–93), a new strain of Marssonina salicicoa appeared which defoliated the previously resistant cultivar, salix matsudana × salix alba cv. 1002 The importance of monitoring the morphological (conidial dimensions, DNA fingerprints) and physiological (host range and pathogenicity) attributes of local populations of Melampsora and Marssonina species is discussed.