Die Ultrastruktur des Penetrationsvorganges von Olpidium brassicae an Kohlrabi-Wurzeln

Zusammenfassung Olpidium brassicae durchdringt mit einem schlauchförmingen, umwandeten Penetrationsfortsatz die Wirtszellwand und durchwächst damit auch das Lumen toter Wirtszellen. Beim Eindringen in das Wirtscytoplasma treten zwei verschiedene Typen von Wirt-Parasit-Reaktionen auf: in plasmareichen Zellen bildet der Wirt eine Callosity in einer unregelmäßigen Einstülpung des Plasmalemmas in das Cytoplasma, in plasmaarmen Calyptrazellen entsteht dagegen ein Rohr aus unbekanntem stark osmophilen Material. Der Pilzprotoplast durchbricht auf unbekannte Weise das Wirtsplasmalemma und tritt in beiden Fällen als von einer einfachen Plasmamembran umgebenes Plasmodium ins Cytoplasma des Wirtes ein.

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Ultrastructure of the penetration process into roots of Brassica oleracea by Olpidium brassicae

Summary Olpidium brassicae penetrates the host cell wall with a wall-coated penetration tube, which too is able to grow through the lumen of dead host cells. Two host-parasite reactions are observed: plasmarich host cells are forming a callosity at the point of penetration, calyptra cells containing only little cytoplasm are forming a strongly osmiophilous tube. The host plasmalemma is penetrated by the fungus protoplast, which in each case finally is located in the host cytoplasm as a plasmodium coated by a single membrane only.

     

Intra-specific variation in wild Brassica oleracea for aphid-induced plant responses and consequences for caterpillar–parasitoid interactions

Herbivore-induced plant responses not only influence the initiating attackers, but also other herbivores feeding on the same host plant simultaneously or at a different time. Insects belonging to different feeding guilds are known to induce different responses in the host plant. Changes in a plant’s phenotype not only affect its interactions with herbivores but also with organisms higher in the food chain. Previous work has shown that feeding by a phloem-feeding aphid on a cabbage cultivar facilitates the interaction with a chewing herbivore and its endoparasitoid. Here we study genetic variation in a plant’s response to aphid feeding using plants originating from three wild Brassica oleracea populations that are known to differ in constitutive and inducible secondary chemistry. We compared the performance of two different chewing herbivore species, Plutella xylostella and M. brassicae, and their larval endoparasitoids Diadegma semiclausum and M. mediator, respectively, on plants that had been infested with aphids (Brevicoryne brassicae) for 1 week. Remarkably, early infestation with B. brassicae enhanced the performance of the specialist P. xylostella and its parasitoid D. semiclausum, but did not affect that of the generalist M. brassicae, nor its parasitoid M. mediator. Performance of the two herbivore–parasitoid interactions also varied among the cabbage populations and the effect of aphid infestation marginally differed among the three populations. Thus, the effect of aphid infestation on the performance of subsequent attackers is species specific, which may have concomitant consequences for the assembly of insect communities that are naturally associated with these plants.     

A tritrophic approach to the preference–performance hypothesis involving an exotic and a native plant

Exotic plants often generate physical and chemical changes in native plant communities where they become established. A major challenge is to understand how novel plants may affect trophic interactions in their new habitats, and how native herbivores and their natural enemies might respond to them. We compared the oviposition preference and offspring performance of the crucifer specialist, Pieris brassicae, on an exotic plant, Bunias orientalis, and on a related native plant, Sinapis arvensis. Additionally, we studied the response of the parasitoid, Cotesia glomerata to herbivore-induced plant volatiles (HIPV) and determined the volatile blend composition to elucidate which compound(s) might be involved in parasitoid attraction. On both host plants we also compared the parasitism rate of P. brassicae by C. glomerata. Female butterflies preferred to oviposit on the native plant and their offspring survival and performance was higher on the native plant compared to the exotic. Although, headspace analysis revealed qualitative and quantitative differences in the volatile blends of both plant species, C. glomerata did not discriminate between the HIPV blends in flight-tent bioassays. Nevertheless, parasitism rate of P. brassicae larvae was higher on the native plant under semi-field conditions. Overall, P. brassicae oviposition preference may be more influenced by bottom-up effects of the host plant on larval performance than by top-down pressure exerted by its parasitoid. The potential for dietary breadth expansion of P. brassicae to include the exotic B. orientalis and the role of top-down processes played by parasitoids in shaping herbivore host shifts are further discussed.     

Risk Assessment Studies: Detailed Host Range Testing of Wild-Type Cabbage Moth, Mamestra brassicae (Lepidoptera: Noctuidae), Nuclear Polyhedrosis Virus

The host range of a multiply enveloped nuclear polyhedrosis virus (NPV) (Baculoviridae) isolated from the cabbage moth, Mamestra brassicae (Lepidoptera: Noctuidae), was determined by challenging a wide range of insect species with high (10⁶ polyhedral inclusion bodies) and low (10³ polyhedral inclusion bodies) doses of the virus. The identity of the progeny virus was confirmed by dot blotting. Analysis of 50% lethal dose was carried out on selected species, and the progeny virus was identified by using restriction enzyme analysis and Southern blotting. Other than the Lepidoptera, none of the species tested was susceptible to M. brassicae NPV. Within the Lepidoptera, M. brassicae NPV was infective to members of four families (Noctuidae, Geometridae, Yponomeutidae, and Nymphalidae). Of 66 lepidopterous species tested, M. brassicae NPV was cross-infective to 32 of them; however, 91% of the susceptible species were in the Noctuidae. The relevance of host range data in risk assessment studies is discussed.     

Differences in the susceptibility of five herbivore species and developmental stages to tomato resistance induced by methyl jasmonate treatment

We compared the susceptibility of five herbivores to tomato resistance induced by methyl jasmonate (MeJA) treatment. We tested for lethal effects against five herbivores (Spodoptera litura, Mamestra brassicae, Frankliniella occidentalis, Tetranychus urticae, and Henosepilachna vigintioctopunctata) at various MeJA concentrations. The mortality of all five herbivores increased significantly with increasing MeJA concentration. The 25 % lethal concentration was 0.03 μM for both first-instar larvae of S. litura and third-instar larvae of M. brassicae, 0.51 μM for third-instar larvae of S. litura, 0.76 μM for adult T. urticae, 2.4 μM for first-instar larvae of F. occidentalis, and 5.7 μM for first-instar larvae of H. vigintioctopunctata. Thus, the degree of susceptibility to MeJA-induced resistance of tomato was first-instar larvae of S. litura = third-instar larvae of M. brassicae > third-instar larvae of S. litura ≈ adult T. urticae > first-instar larvae of F. occidentalis > first-instar larvae of H. vigintioctopunctata. Mortality of first-instar larvae of M. brassicae was >90 % at all concentrations. Mortality of fourth-instar larvae of H. vigintioctopunctata (<7 %) was similar to that of the control at all MeJA concentrations. We also detected statistically significant weight loss of the surviving lepidopteran larvae, increased larval duration of F. occidentalis and H. vigintioctopunctata, and reduced egg production by T. urticae grown on MeJA-treated tomato, suggesting that the MeJA-induced resistance can control these herbivores, but effectiveness is different on different species and growth stage. Feeding by both M. brassicae and H. vigintioctopunctata larvae activated JA-inducible genes in tomato.     

Systematics and evolutionary history of the Asterotricha group of the genus Onosma (Boraginaceae) in central and southern Europe inferred from AFLP and nrDNA ITS data

Onosma is a species-rich genus with complicated patterns of morphological and karyological variation, and controversial taxonomic treatments. In the present study we focused on the Asterotricha group, one of three major infrageneric groups, in the area of central and southern Europe. Ribosomal internal transcribed spacer (ITS) sequences and amplified fragment length polymorphism (AFLP) markers were used to assess species differentiation and relationships, and to gain insight into the evolutionary history of the group. ITS data supported the monophyly of the asterotrichous taxa. Six genetically differentiated entities were resolved by AFLP markers, corresponding to O. echioides, O. heterophylla s.l., O. thracica including O. rigida, O. malkarmayorum, O. taurica, and O. stellulata. Onosma stellulata is identified as the most differentiated lineage within the Asterotricha group, which is consistent with its unique chromosome number. Within O. heterophylla s.l., recognition of O. viridis as a species distinct from O. heterophylla s.str. is supported. On the other hand, O. tornensis appears to be conspecific with O. viridis. Inferring from the patterns of genetic diversity and divergence, the evolutionary history of O. heterophylla s.l. is discussed. Genetic variation within the polymorphic Apennine–Dalmatian O. echioides is almost continuous and shaped by isolation by distance, thus none of the previous intraspecific taxonomic concepts are valid. The assumed hybrid origin of O. malkarmayorum is supported, and its affinity to potential ancestors, O. heterophylla s.l. and O. thracica incl. O. rigida, is indicated. Future studies of asterotrichous Onosma species should focus on diversity centers in the eastern Mediterranean and Asia Minor, to build up a comprehensive taxonomic concept of the group and to clarify its evolution.     

Ubiquitous associations and a peak fall prevalence between apicomplexan symbionts and reef corals in Florida and the Bahamas

Although apicomplexans are a widely recognized and important parasitic group, little is known about those associated with invertebrates, such as reef-building scleractinian corals. To resolve the potential impact of apicomplexans on coral health, it is first necessary to further describe this group of putative parasites and determine their prevalence among host species. Here, it was hypothesized that apicomplexan prevalence would vary seasonally, similar to what occurs in other marine apicomplexans as well as some coral symbionts. To test this, Caribbean scleractinian species Porites astreoides, Montastraea (=Orbicella) annularis, M. (=O.) faveolata, and Siderastrea siderea were sampled seasonally from two reefs each in the Florida Keys and the Bahamas for 9- and 5.5-year periods, respectively. Utilizing a PCR-based screening assay, apicomplexan DNA was detected from most Floridian (80.1 %: n = 555/693) and Bahamian (90.7 %: n = 311/343) coral tissue samples collected over these multi-year periods. Furthermore, apicomplexan DNA was detected from nearly all (98.7 %: n = 78/79) single polyps sampled at multiple locations within six M. faveolata colonies, indicating little to no intracolonial variation in the screening assay. Mixed-model logistic regression was utilized to determine the effects of season, host species, and reef on apicomplexan prevalence. The model identified a significant seasonal effect, with the highest apicomplexan prevalence occurring during fall. There also was a large effect of host species, with apicomplexan prevalence significantly lower among S. siderea colonies relative to the other species. While reef did not have a significant effect in the full model, there was a significant difference in apicomplexan prevalence between Floridian and Bahamian reefs for S. siderea, implying regional differences in this host species. Despite seasonal and species-specific differences in prevalence, apicomplexans are ubiquitous constituents of these particular scleractinian coral species from Florida and the Bahamas.     

Biology and host range of Omolabus piceus, a weevil rejected for biological control for Schinus terebinthifolius in the USA

Surveys for biological control agents of the invasive weed Schinus terebinthifolius (Anacardiaceae) discovered two Omolabus weevils (Coleoptera: Attelabidae) feeding on the plant in its native range. Molecular and morphological analysis indicated that one of these species consistently fed on the target weed and the other species fed more broadly. Aspects of the biology and host range of the more specific species, Omolabus piceus (Germar) were examined to determine its suitability as a biological control agent of S. terebinthifolius in the USA. Adults feed on newly formed leaves, and eggs, larvae and pupae develop in curled fragments of leaves, called nidi. Larvae consumed an average of 11.3 (±0.4) mg throughout their development which required 15.1 (±0.2) days. An average of 31.6 (±2.7) eggs were laid per female during their 23.8 (±2.2) day lifetime, after a 3.4 (±1.0) day preoviposition period. In no-choice tests, O. piceus adults fed and oviposited on all tested native North American, Caribbean and agricultural Anacardiaceae species except for M. indica. The field host-range of O. piceus, as determined by samples of host use in the native range, included three Schinus, two Lithrea and one Anacardium species. Therefore, we do not recommend O. piceus for biological control of S. terebinthifolius in the USA. However, the utilization of this species in other infested areas such as Hawaií and Australia should be considered.     

Olpidium species parasitic in the roots of cucurbitaceous plants

A chytridiaceous fungus was found parasitic in the roots of cucurbitaceous plants in Varanasi during December–March. Morphology and development of the vegetative and reproductive structures and its parasitism confined to the cucurbitaceous host plants as revealed by inoculation studies, indicated it as a variant isolate of Olpidium brassicae (Woronin) Dangeard. Association of the pathogen with mosaic virus-infected cucurbit vines indicated its possible role in the transmission of pumpkin and bottle gourd mosaic viruses.     

Patterns of parasitoid host utilization and development across a range of temperatures: implications for biological control of an invasive forest pest

Although climate change frequently has been linked to observed shifts in the distributions or phenologies of species, little is known about the potential effects of varying temperatures on parasitoids and their relationships with hosts. Using the egg parasitoid Oobius agrili (Hymenoptera: Encyrtidae) we examined host utilization patterns of this species across a range of temperatures (20–35 °C) to explore how changing climate could affect the interaction with its host—the emerald ash borer (EAB) (Coleoptera: Buprestidae), a serious invasive forest pest that has killed tens of millions of ash (Fraxinus spp.) trees in North America. Results from our study showed that the window of host susceptibility to O. agrili parasitism declined significantly from 14.8 to 2.6 days in an inverse second-order relationship with increasing exposure temperatures from 20 to 35 °C. In contrast, parasitoid host attack rate changed in a bell-shaped second-order relationship—i.e., increased with temperatures from 20 to 25 °C, but decreased at about the same rate when temperatures increased from 30 to 35 °C. This range of temperatures also significantly affected the development and mortality of immature parasitoids with 35 °C resulting in 100 % mortality. There was little mortality (0–4.5 %) and no significant differences in the percentage (20.9–34.9 %) of immature O. agrili that entered diapause (as mature larvae) at 20, 25, and 30 °C. However, there were significant differences in the time event of adult wasp emergence within this temperature range. The median time for 50 % of immature O. agrili emerging as adults at 20, 25, and 30 °C were 38, 18, and 17 days after parental wasp oviposition, respectively. Together these findings indicate that the non-linear and unequal temperature effects on these host utilization parameters are likely to result in differential host parasitism rates, and thus could reduce the efficacy of this parasitoid in suppressing host populations due to climate change (global warming and extreme heat).     

Multiparasitism of stink bug eggs: competitive interactions between Ooencyrtus pityocampae and Trissolcus agriope

Females of Trissolcus agriope (Platygastridae) avoid host (Brachynema signatum) eggs parasitized by conspecifics or Ooencyrtus pityocampae (Encyrtidae), but females of the latter species will superparasitize and multiparasitize, although they mostly attack unparasitized eggs. Females of T. agriope were more efficient in the laboratory and parasitized more hosts in 24 and 48 h. In multiparasitized hosts, O. pityocampae was a superior larval competitor and could complete also development as a facultative hyperparasitoid. When females of both species foraged together, T. agriope parasitized significantly more than O. pityocampae, about 50 % in both cases, although O. pityocampae almost doubled its parasitism rate as the exposure period was lengthened from 24 to 48 h. When O. pityocampae followed T. agriope in sequential foraging bouts, the former species successfully parasitized more hosts than the latter. The advisability of co-releases of both species to improve biological control of first generation B. signatum in Iranian pistachio orchards is discussed.     

Ecological fits, mis-fits and lotteries involving insect herbivores on the invasive plant, Bunias orientalis

Exotic plants bring with them traits that evolved elsewhere into their new ranges. These traits may make them unattractive or even toxic to native herbivores, or vice versa. Here, interactions between two species of specialist (Pieris rapae and P. brassicae) and two species of generalist (Spodoptera exigua and Mamestra brassicae) insect herbivores were examined on two native crucifer species in the Netherlands, Brassica nigra and Sinapis arvensis, and an exotic, Bunias orientalis. Bu. orientalis originates in eastern Europe and western Asia but is now an invasive pest in many countries in central Europe. P. rapae, P. brassicae and S. exigua performed very poorly on Bu. orientalis, with close to 100% of larvae failing to pupate, whereas survival was much higher on the native plants. In choice experiments, the pierid butterflies preferred to oviposit on the native plants. Alternatively, M. brassicae developed very poorly on the native plants but thrived on Bu. orientalis. Further assays with a German Bu. orientalis population also showed that several specialist and generalist herbivores performed very poorly on this plant, with the exception of Spodoptera littoralis and M. brassicae. Bu. orientalis produced higher levels of secondary plant compounds (glucosinolates) than B. nigra but not S. arvensis but these do not appear to be important factors for herbivore development. Our results suggest that Bu. orientalis is a potential demographic ‘trap’ for some herbivores, such as pierid butterflies. However, through the effects of an evolutionary ‘lottery’, M. brassicae has found its way through the plant’s chemical ‘minefield’.     

Erysiphe azerbaijanica and E. linderae: Two new powdery mildew species (Erysiphales) belonging to the Microsphaera lineage of Erysiphe

Two new species, Erysiphe azerbaijanica on Castanea sativa and E. linderae on Lindera praecox, both belonging to the Microsphaera lineage of the genus Erysiphe are described based on morphological and molecular data. Erysiphe azerbaijanica is distinguished from other Erysiphe species occurring on Castanea spp. by its cylindrical conidia with a length/width ratio of 2–3.6, longer conidiophore, and foot-cells. Molecular analyses indicated that this species forms a clade of its own, supporting the morphological observations. Molecular phylogenetic analyses showed that E. blasti s. lat. is divided into two genetically differentiated groups associated with different host species. Based on the sequence differences in the 28S rRNA gene and ITS region, connected with differences in the number and length of appendages, the fungus on L. praecox is described as a new species, E. linderae.     

Ophiostoma quercus: An unusually diverse and globally widespread tree-infecting fungus

Ophiostoma quercus (Ascomycota, Ophiostomatales) is a globally widespread, insect-vectored fungus that colonizes a wide diversity of hardwood and conifer hosts. Although the fungus is considered to be non-pathogenic, it is closely related to the fungi that cause Dutch elm disease. We examined the global diversity of O. quercus based on a ribosomal RNA marker and three unlinked gene regions. The fungus exhibited substantial morphological diversity. In addition, O. quercus had high genetic diversity in every continent from which it was collected, although the fungus was most diverse in Eurasia. There was no evidence of geographical clustering of haplotypes based on phylogenetic and network analyses. In addition, the phylogenetic trees generated based on the different markers were non-congruent. These results suggest that O. quercus has been repeatedly moved around the globe, because of trade in wood products, and that the fungal species most likely outcrosses regularly. The high genetic diversity of the fungus, as well as its ability to utilize a wide variety of arthropod vectors and colonize a tremendous diversity of tree host species makes O. quercus truly unique among ophiostomatoid fungi.     

The flagellar apparatus and striated rhizoplast of the zoospore ofOlpidium brassicae

Summary The flagellar apparatus and its associated structures of the zoospore ofOlpidium brassicae are described and compared with observations of other zoospores of the uniflagellatePhycomycetes. The zoospore ofO. brassicae is shown to have an extensive cone-shaped rhizoplast fused to both the functional and the vestigial kinetosomes. Three-dimensional reconstructions were made of the kinetosomal region. The vestigial kinetosome differs from the functional, as it only has triplet bundles of microtubules and it lacks a system of props. The proximal termination of the central pair of flagellar microtubules occurs within the axoneme. No terminal plate is observed. The occurrence of dictyosomes in theChytridiales, Monoblepharidales, andHyphochytriales is discussed and it is concluded that a dictyosome may be present in the encysting zoospore and the maturing zoosporangium ofO. brassicae but only vestiges of a dictyosome are to be found in the free-swimming zoospore.     

The systematics and population genetics of Opisthorchis viverrini sensu lato: implications in parasite epidemiology and bile duct cancer

Together with host and environmental factors, the systematics and population genetic variation of Opisthorchis viverrini may contribute to recorded local and regional differences in epidemiology and host morbidity in opisthorchiasis and cholangiocarcinoma (CCA). In this review, we address recent findings that O. viverrini comprises a species complex with varying degrees of population genetic variation which are associated with specific river wetland systems within Thailand as well as the Lao PDR. Having an accurate understanding of systematics is a prerequisite for a meaningful assessment of the population structure of each species within the O. viverrini complex in nature, as well as a better understanding of the magnitude of genetic variation that occurs within different species of hosts in its life cycle. Whether specific genotypes are related to habitat type(s) and/or specific intermediate host species are discussed based on current available data. Most importantly, we focus on whether there is a correlation between incidence of CCA and genotype(s) of O. viverrini. This will provide a solid basis for further comprehensive investigations of the role of genetic variation within each species of O. viverrini sensu lato in human epidemiology and genotype related morbidity as well as co-evolution of parasites with primary and secondary intermediate species of host.     

The zoospore ofOlpidium brassicae

Summary The ultrastructure of the zoospore ofOlpidium brassicae is described and compared with observations made of other zoospores of the uniflagellatePhycomycetes. The zoospore ofO. brassicae is characterized by an extensive, cone-shaped rhizoplast and a lack of a nuclear cap, as well as a side-body complex or a rumposome. Vacuoles which contain osmiophilic material are termed gamma-like particles. Three-dimensional reconstructions based on serial sectioning were made of the organelles in the region of the nucleus, showing that the zoospore ofO. brassicae contains one or at most two elaborately branched mitochondria. Microbodies have a high degree of interconnection and are in intimate association with the mitochondrion, lipid drops, and the nuclear envelope.     

<Emphasis Type="Italic">Alternaria brassicae</Emphasis> interactions with the model Brassicaceae member <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> closely resembles those with Mustard (<Emphasis Type="Italic">Brassica juncea</Emphasis>)

Alternaria leaf blight, a disease of oilseed Brassicas is caused by a necrotrophic phytopathogenic fungus Alternaria brassicae. The details of its pathogenesis and defence responses elicited in the host upon infection have not been thoroughly investigated. Here, Arabidopsis accession Gre-0 was identified to be highly susceptible to A. brassicae. A comparative histopathological analysis for disease progression and plant responses to A. brassicae in Arabidopsis and Brassica juncea revealed significant similarities between the two compatible pathosystems. Interestingly, in both the compatible hosts, ROS accumulation, cell death and callose deposition correlated with the development of the disease. Based on our results we propose that Arabidopsis-Alternaria brassicae can be an apt model pathosystem since it emulates the dynamics of the pathogen interaction with its natural host- Brassicas. The existing genetic diversity in Arabidopsis can be a starting point to screen for variation in responses to Alternaria leaf blight. Furthermore, several tools available for Arabidopsis can facilitate the dissection of genetic and molecular basis of resistance.     

Stable,fertile somatic hybrids between <Emphasis Type="Italic">Sinapis alba</Emphasis> and <Emphasis Type="Italic">Brassica juncea</Emphasis> show resistance to <Emphasis Type="Italic">Alternaria brassicae</Emphasis> and heat stress

Wild relatives of Brassica are a rich reservoir of genes that are invaluable for the improvement of cultivated species. Sinapis alba is a close relative of crop Brassicas that possesses several desirable traits such as tolerance to Alternaria black spot disease, heat stress, insect pests and nematodes. This study is aimed at developing and characterizing hybrids between Brassica juncea and S. alba with the ultimate goal of transferring genes for tolerance to Alternaria brassicae and heat stress, the traits that are lacking in cultivated Brassica. We generated three hybrids between B. juncea and S. alba through protoplast fusion. The hybridity was confirmed through cytology and molecular markers. While two of the hybrids were symmetric, the third one was asymmetric and had greater resemblance to B. juncea. Hybrids showed some characteristic features of the parents and were fully male and female fertile and also set seeds upon back crossing with the parent species. In vitro leaf assay and field inoculation studies revealed that the hybrids are highly resistant to A. brassicae. Besides, hybrids set seeds at temperature of >?38 °C when parents failed to produce seeds indicating that hybrids possess heat tolerance. These stable hybrids provide a reliable genetic resource for transfer of genes from S. alba into cultivated Brassica species.