Molecular identification and characterization of Elsinoë murrayae (Synonym: Sphaceloma murrayae) from weeping willow

Sphaceloma murrayae is a significant fungal pathogen of Salix spp. It causes greyish‐white leaf spots, which were reported worldwide except in China. Its morphological characteristics were described in the early literature; however, there is a lack of molecular information pertaining to this fungus. This study identified and characterized three fungal isolates that obtained from weeping willow leaf spots in China. Based on disease symptoms, morphological characteristics and single nomenclature rules for fungi, these isolates are proposed to be new combinations of Elsinoë murrayae (Synonym: S. murrayae). Phylogenetic analysis that combined internal transcribed spacer (ITS), large subunit (LSU), RBP2 and TEF1‐α DNA sequences indicated that E. murrayae isolates and Elsinoë salicina—another Elsinoë sp. isolated from Salix sp.—were distinguishable species. With trypan blue staining and stereomicroscopic observation, we found that large‐scale cell death occurred at 2 days postinoculation (dpi) and slight disease symptoms started at 3 dpi when the conidia were inoculated on Salix babylonica leaves. Pathogenicity analysis revealed that three isolates can successfully infect mature leaves of S. babylonica, Salix fragilis and Salix suchowensis, but not Salix matsudana. In addition, a necrosis‐ and ethylene‐inducing‐like proteins’ (NLP) gene, named EmNLP1, was cloned. The cytotoxicity of EmNLP1 was confirmed by transient assay in tobacco. During infection, EmNLP1 dramatically peaked at 2 dpi and maintained a high‐level expression in the necrosis lesion growing stage.     

Isolation and characterization of microsatellite loci in the avocado thrips Scirtothrips perseae (Thysanoptera: Thripidae)

The recent invasion of California by avocado thrips, Scirtothrips perseae, has had a serious economic impact on the Californian avocado industry. Here we report the isolation and characterization of six microsatellite loci for S. perseae, four of which were highly polymorphic (number of observed alleles ranged from three to 13 and expected heterozygosity from 0.31 to 0.87). These markers will be used to investigate the invasion history and route of entry into California of S. perseae. Three of the six loci successfully amplified in other Scirtothrips and Neohydatothrips species.     

Identification and Characterization of Colletotrichum spp. affecting Fruit after Harvest in Brazil

Colletotrichum spp. cause anthracnose in various fruits post‐harvest and are a particularly important problem in tropical and subtropical fruits. The disease in fruits of avocado, guava, papaya, mango and passion fruit has been reported to be caused by C. gloeosporioides, and in banana by C. musae. In subtropical and temperate crops such apple, grape, peach and kiwi, the disease is caused by C. acutatum. The variation in pathogenic, morphological, cultural and molecular characteristics of Brazilian isolates of Colletotrichum acutatum Simmonds and isolates from post‐harvest decays of avocado, banana, guava, papaya, mango and passion fruit was evaluated. The fruits were inoculated with mycelium of C. acutatum, Colletotrichum spp. and C. musae on a disc of potato dextrose agar. The morphological, cultural and molecular characteristics studied were conidia morphology, colony growth at different temperatures, colony coloration and PCR with primers CaInt2 and ITS4 for C. acutatum and CgInt and ITS4 for C. gloeosporioides. C. acutatum was pathogenic to avocado, guava, papaya, mango and passion fruit, but it was not pathogenic to banana. The morphological, cultural and molecular studies indicated that the avocado, papaya, mango and passion fruit isolates were C. gloeosporioides. The natural guava isolate was identified as C. acutatum, which had not been found previously to produce anthracnose symptoms on guava in Brazil.     

Characterization and Pathogenicity of Colletotrichum gloeosporioides and C. karstii Causing Preharvest Disease on Citrus sinensis in Italy

During the period from 2010 to 2013 preharvest symptoms were detected on different cultivars of sweet orange in six orchards in Catania, Siracusa and Enna provinces, Southern Italy. A total of 56 monosporic fungal isolates were obtained, and among these, 44 were identified as Colletotrichum gloeosporioides and 12 as C. karstii through morphological and molecular analysis. PCR with primers ITS1 and ITS4, primers TubGF1 and TubGR specific for β‐tubulin gene, primers GDF‐GDR, specific for Glyceraldehyde‐3‐phosphate dehydrogenase (GAPDH) gene, were used to confirm the identification of Colletotrichum isolates from citrus. The ITS1‐5.8S‐ITS2 region, a portion of approximately 500 bp of β‐tubulin gene and a fragment of 220 bp of GAPDH gene of the isolates were sequenced and analysed with the BLASTn program. Koch's postulates were fulfilled by pathogenicity tests carried out on fruit of ‘Tarocco Scirè’ and ‘Tarocco Nucellare’ with representative isolates of C. gloeosporioides and C. karstii. Field surveys and pathogenicity tests revealed significant differences in fruit susceptibility between ‘Tarocco Scirè’ and ‘Tarocco Nucellare’ and in virulence between the fungal species. To our knowledge, this is the first report on the emergence of Colletotrichum spp. causing anthracnose in preharvest conditions.     

Evaluation of factors influencing augmentative releases of Chrysoperla carnea for control of Scirtothrips perseae in California avocado orchards

Weekly releases of Chrysoperla carnea for control of Scirtothrips perseae were evaluated in replicated field plots in two commercial avocado orchards in southern California, USA. Two release techniques and rates commonly employed by commercial pest control advisors who routinely use this generalist predator for S. perseae control were assessed. Release technique one utilized C. carnea eggs glued to paper squares that were stapled to leaves of experimental trees at a rate of 41,000 eggs per ha. Release technique two used a motorized backpack sprayer to apply a dry mixture of lacewing eggs and larvae to trees at a rate of 514,501 per ha. Pest populations were monitored by making bi-weekly population counts of S. perseae larvae and adults on leaves, and adult densities were simultaneously monitored in each experimental plot with yellow sticky cards. In the laboratory, degree-day accumulation until death of immature C. carnea was determined at temperatures representative of field conditions when predators were provisioned with varying amounts of food or different food types. Preference for S. perseae instars by first, second, and third instar C. carnea was assessed in the laboratory, and intraguild predation towards larvae and adult females of a co-occurring generalist predatory thrips, Franklinothrips orizabensis, was investigated along with intraspecific predation rates. Both release strategies failed to significantly reduce S. perseae populations in comparison to non-treated control plots. Approximately 35–96% of C. carnea eggs and larvae applied with the motorized sprayer landed on the ground. C. carnea larvae lived for approximately 1–2 days when provisioned with either no food, an avocado leaf or avocado pollen. Longevity was extended to 14–15 days when prey was provided. C. carnea larvae showed no preference for first or second instar S. perseae, all predator instars attacked first instar F. orizabensis, but only second and third instar C. carnea managed attacks on second instar F. orizabensis larvae. No adult female F. orizabensis were attacked and no attacks by F. orizabensis on C. carnea were recorded. Second instar C. carnea engaged in the highest levels of intraspecific predation.     

Outbreak of Phytophthora cinnamomi causing severe decline of avocado trees in southern Turkey

Since the summer 2017, severe decline symptoms have been observed on 10- to 25-year-old avocado trees in almost all commercial orchards planted in the Mediterranean coastal region of Turkey. Young, newly planted trees in infected orchards were also affected by the disease. Affected trees showed wilting, leaf discoloration, defoliation and severe dieback. Some trees were completely desiccated. Although fine roots of symptomatic trees usually were decayed, reddish brown cankers also occurred on taproots and lateral roots of heavily infected trees. The pathogens were isolated from necrotic root and soil samples of symptomatic trees, using selective medium and soil baiting, and were identified based on morphological features and DNA sequences of the internal transcribed spacer (ITS) region. One isolate each of Phytophthora cryptogea and P. palmivora was identified, while all other isolates were P. cinnamomi. In addition, a subcortical fan-shaped mycelium, characteristic of Armillaria spp., was observed in the stem base of a symptomatic tree and identified as Armillaria gallica by DNA sequences of the internal transcribed spacer (ITS) and the translational elongation factor 1-α (EF 1-α) gene regions. Pathogenicity of Phytophthora isolates was tested by stem inoculation on one-year-old avocado seedlings. Two months after inoculation, canker lesions developed on stems of seedlings inoculated by any of the three Phytophthora spp. In contrast, collenchyma callus formed over the wound points on control plants over the same time period. This is the first report of P. cinnamomi, P. cryptogea, P. palmivora and A. gallica causing root rot of avocado trees in Turkey. In addition, P. cryptogea and A. gallica are reported for the first time associated with disease on this host. Due to the severe symptoms and widespread occurrence, P. cinnamomi should be considered a potential threat to avocado cultivation and natural ecosystems of this region of Turkey.     

Elsinoë fawcettii and Elsinoë australis: the fungal pathogens causing citrus scab

Elsinoë fawcettii and E. australis are important pathogens of citrus. Both species are known to produce red or orange pigments, called elsinochrome. Elsinochrome is a nonhost‐selective phytotoxin and is required for full fungal virulence and lesion formation. This article discusses the taxonomy, epidemiology, genetics and pathology of the pathogens. It also provides a perspective on the cellular toxicity, biosynthetic regulation and pathological role of elsinochrome phytotoxin. Taxonomy: Elsinoë fawcettii (anamorph: Sphaceloma fawcettii) and E. australis (anamorph: S. australis) are classified in the Phylum Ascomycota, Class Dothideomycetes, Order Myriangiales and Family Elsinoaceae. Host range: Elsinoë fawcettii causes citrus scab (formerly sour orange scab and common scab) on various species and hybrids in the Rutaceae family worldwide, whereas E. australis causes sweet orange scab, primarily on sweet orange and some mandarins, and has a limited geographical distribution. Disease symptoms: Citrus tissues infested with Elsinoë often display erumpent scab pustules with a warty appearance. Toxin production: Elsinochrome and many perylenequinone‐containing phytotoxins of fungal origin are grouped as photosensitizing compounds that are able to absorb light energy, react with oxygen molecules and produce reactive oxygen species, such as superoxide and singlet oxygen. Elsinochrome has been documented to cause peroxidation of cell membranes and to induce rapid electrolyte leakage from citrus tissues. Elsinochrome biosynthesis and conidiation are coordinately regulated in E. fawcettii, and the environmental and physiological inducers commonly involved in both processes have begun to be elucidated.     

Identification of the pathogen responsible for tea white scab disease

Tea white scab disease commonly occurs in high-altitude tea-growing areas worldwide. Both Elsinoe leucospila and Phyllosticta theaefolia have been reported as the pathogen responsible for this disease. To conclusively identify the causative agent, samples were collected from plants infected with tea white scab disease in high-altitude tea gardens in southern China. Fungal isolates obtained from the infected material were identified based on morphological characteristics, comparisons of ITS, 18S rDNA, RPB2 and LSU sequences, and pathogenicity tests. Both Elsinoe sp. and Phyllosticta sp. were isolated from the collected samples with rates of 6% and 35%, respectively. On potato dextrose agar medium, Phyllosticta sp. grew faster and sporulated more than E. leucospila. However, only E. leucospila caused symptoms similar to those of tea white scab disease. In contrast, Phyllosticta sp. infections resulted in large necrotic spots. Therefore, E. leucospila appears to be the pathogen responsible for tea white scab disease, whereas Phyllosticta sp. is a hyperparasitic fungus that infects the diseased plant tissue. The high isolation rate of Phyllosticta sp. due to its rapid growth and considerable sporulation may have led to the erroneous identification of this fungus as the cause of tea white scab disease. Our findings may be useful for future investigations of this disease, particularly regarding the development of improved prevention and/or control measures.     

Internal Transcribed Spacer Sequence Analysis of Puccinia helianthi Schw. and Its Application in Detection of Sunflower Rust

Two basidiomycete‐specific primers ITS1‐F and ITS4‐B were used in identification of the genus Puccinia. The primers showed good specificity for the genus with an 816‐bp product that was amplified exclusively. Twenty sequences of internal transcribed spacer (ITS) regions of Puccinia helianthi isolates from China remain unchanged. The whole ITS length (including ITS1 sequence 194 bp, 5.8S rRNA gene 156 bp, ITS2 sequence 206 bp) was 556 bp. By comparing the aligned ITS sequences of several Puccinia isolates from China, Spain and the United States, ITS homogeneity among these sunflower rust isolates was >99%. Genetic homology and phylogeny of P. helianthi with other Puccinia spp. was investigated. Nineteen sequences of rDNA ITS1 and ITS2 were determined and used as phylogenetic markers. Phylogenetic analysis of ITS regions showed that Puccinia spp. of sunflower was clustered in one clade with P. komarovii and P. violae, divergent from Puccinia spp. of Chrysanthemum, P. tenaceti of tansy (Tanacetum vulgare) and Puccina spp. of big sagebrush (Artemisia tridentate) indicating sunflower rust had distant phylogenetic relationships with other Compositae rusts. With the specified primers SR‐1 and SR‐2, either from purified urediniospores or symptomless (but infected) sunflower leaves could be examined specifically. Therefore, results of this study help in detection and polygenetic study of rust fungi occurring on sunflower.     

Endophytic fungi associated with the Antarctic grass <Emphasis Type="Italic">Deschampsia antarctica</Emphasis> Desv. (<Emphasis Type="Italic">Poaceae</Emphasis>)

Deschampsia antarctica Desv. (Poaceae) represents one of the two vascular plants that have colonized the Antarctic continent, which is usually exposed to extreme environmental conditions. In this work, we have characterized the endophytic fungi associated with the leaves of D. antarctica. Endophytic fungi were recovered from 91 individual plants from different points of Admiralty Bay at King George Island, Antarctica. A total of 26 fungal isolates were obtained from 273 leaf fragments. All isolates were identified by analysis of the sequences of the internal transcribed spacer region (ITS) of the rDNA. Alternaria and Phaeosphaeria were the most frequent genera associated with the plant. Other fungal isolates were identified as Entrophospora sp. and several undescribed Ascomycete species. An interesting result was obtained for the isolates UFMGCB 215 and UFMGCB 262, which were related to fungi associated with bryophytes present in boreal ecosystems. Some isolates showed low identity in the ITS sequences to sequences of fungal species deposited in GenBank, suggesting that these fungi could be new species. This work is the first report on fungal endophytes associated with leaves of the Antarctic grass D. antarctica.     

Predation behaviors of Franklinothrips orizabensis (Thysanoptera: Aeolothripidae) towards Scirtothrips perseae and Heliothrips haemorrhoidalis (Thysanoptera: Thripidae)

The foraging behaviors of predatory female Franklinothrips orizabensis Johansen towards Scirtothrips perseae Nakahara and Heliothrips haemorrhoidalis (Bouché) in avocado leaf arenas were videotaped and analyzed. F. orizabensis encountered and attacked more second instar S. perseae with 80% (n=113) attacks on this life stage being observed compared to 20% on first instars (n=28) when equal numbers of these prey were presented simultaneously. However, there was no significance difference by life stage for the probability of being attacked after being encountered. Successful attacks by F. orizabensis only occurred against propupal H. haemorrhoidalis (n=6) that lacked protective fecal droplets, 65% of prey encounters were with this life stage, and 6% of encounters with propupae resulted in attacks. Second instar H. haemorrhoidalis larvae bearing protective droplets were encountered less frequently and were not attacked when contacted even though equal numbers of both stages were presented simultaneously. Consequently, the mean proportion of the time spent grooming by F. orizanbensis females attacking immature H. haemorrhoidalis was four times greater than that for females attacking S. perseae larvae even though there was no significant difference in mean time (s) spent in each grooming bout. Significant differences in mean consumption times by F. orizabensis existed across life stages and prey species. Consumption times were shortest for first instar S. perseae larvae, intermediate for second instars, and longest for H. haemorrhoidalis propupae. Mean consumption times for sequentially attacked second instar S. perseae declined significantly indicating satiation of predators. Predators would spend on average approximately 7–13 s probing leaves with mouthparts and feeding on fluids; a behavior that on average occupied 2–5% of their time. This result may explain observed mortality of F. orizabensis in the laboratory and field when this predator forages on avocado leaves that have been treated with insecticides that exhibit translaminar activity.     

Foreign exploration for Scirtothrips perseae Nakahara (Thysanoptera: Thripidae) and associated natural enemies on avocado (Persea americana Miller)

Scirtothrips perseae Nakahara was discovered attacking avocados in California, USA, in 1996. Host plant surveys in California indicated that S. perseae has a highly restricted host range with larvae being found only on avocados, while adults were collected from 11 different plant species. As part of a management program for this pest, a “classical” biological control program was initiated and foreign exploration was conducted to delineate the home range of S. perseae, to survey for associated natural enemies and inventory other species of phytophagous thrips on avocados grown in Mexico, Guatemala, Costa Rica, the Dominican Republic, Trinidad, and Brazil. Foreign exploration efforts indicate that S. perseae occurs on avocados grown at high altitudes (>1500 m) from Uruapan in Mexico south to areas around Guatemala City in Guatemala. In Costa Rica, S. perseae is replaced by an undescribed congener as the dominant phytophagous thrips on avocados grown at high altitudes (>1300 m). No species of Scirtothrips were found on avocados in the Dominican Republic, Trinidad, or Brazil. In total, 2136 phytophagous thrips were collected and identified, representing over 47 identified species from at least 19 genera. The significance of these species records is discussed. Of collected material 4% were potential thrips biological control agents. Natural enemies were dominated by six genera of predatory thrips (Aeolothrips, Aleurodothrips, Franklinothrips, Leptothrips, Scolothrips, and Karnyothrips). One genus each of parasitoid (Ceranisus) and predatory mite (Balaustium) were found. Based on the results of our sampling techniques, prospects for the importation of thrips natural enemies for use in a “classical” biological control program in California against S. perseae are not promising.     

Population genetics of Scirtothrips perseae: tracing the origin of a recently introduced exotic pest of Californian avocado orchards, using mitochondrial and microsatellite DNA markers

The Californian avocado industry has recently been impacted by the establishment of three exotic arthropod pests that are native to Mexico and Central America. Establishment of all three pests is thought to have resulted from illegal movement of host plants (avocado) into California. To identify likely sources and routes of entry of such pest invasions, we examined the population genetics of the most recent invader, avocado thrips [Scirtothrips perseae Nakahara (Thysanoptera: Thripidae)], using mitochondrial DNA (mtDNA) and microsatellite markers. The mtDNA sequences revealed three geographically distinct and divergent lineages, of which the mtDNA haplotypes of Californian individuals were most closely related to populations in the center of the pest's native range. Analysis of allele frequencies at four microsatellite loci added resolution, indicating Coatepec Harinas, Mexico, as the most likely source of the Californian population. Statistically, we did not detect any bottleneck in population size associated with the invasion of California. However, estimates of the effective population size of the invading population suggest that a severe bottleneck occurred, indicating that the quantity of host‐plant material entering California was small. Our findings implicate Coatepec Harinas, a large avocado germplasm and breeding center, as the most likely source of the introduced Californian population of S. perseae and as a likely source of previous and future avocado pest introductions. Efforts to identify natural enemies of S. perseae for biological control should focus on Coatepec Harinas and immediate surrounds. Moreover, identification of the source of invasive pests enables the establishment and enforcement of plant quarantine and free‐trade protocols.     

First Report of Phytophthora Foliar Blight on Florida Hopbush (Dodonaea viscosa) in Italy

During 2010, a new foliar blight was detected on potted Dodonaea viscosa cv. Purpurea plants in two nurseries in Catania (Italy). On the basis of morphological and cultural features, the pathogen was identified as Phytophthora palmivora. The internal transcribed spacer (ITS)‐rDNA sequence of a representative Phytophthora isolate from hopbush showed 99% identity with other ITS sequences of different P. palmivora isolates available in GenBank, thus confirming the morpho‐cultural identification. Koch’s postulates were fulfilled by pathogenicity tests on potted D. viscosa cv. Purpurea seedlings. To our knowledge, this is the first report of P. palmivora foliar blight disease on D. viscosa.     

Molecular phylogenetics of the genus <Emphasis Type="Italic">Physalia</Emphasis> (Cnidaria: Siphonophora) in New Zealand coastal waters reveals cryptic diversity

Physalia is a genus of pelagic colonial hydrozoans often known by common names such as ‘Portuguese-man-of-war’ or ‘bluebottle’. Siphonophore systematists generally recognise only a single species in this genus, Physalia physalis, however the name Physalia utriculus is also still in common use, which has led to considerable taxonomic confusion. With some morphological variation between global regions there is the possibility that this genus holds a substantial amount of cryptic variation. We seek to examine the genetic structure of Physalia present in New Zealand coastal waters. Fifty-four specimens collected from 13 locations around New Zealand and Australia were sequenced for both mitochondrial cytochrome c oxidase I (COI) and the first internal transcribed spacer (ITS1) of the nuclear ribosomal cistron. Sequences were analysed using maximum likelihood and split decomposition neighbour networks to determine conflict between clans (the unrooted analog of clades). Three clans were identified from both the COI and ITS sequences. The results are complex and clans are not consistent between the two genes. Nevertheless, it seems that there is substantial cryptic diversity amongst Physalia present in New Zealand coastal waters.     

How do <Emphasis Type="Italic">Neoseiulus californicus</Emphasis> (Acari: Phytoseiidae) females penetrate densely webbed spider mite nests?

The persea mite Oligonychus perseae is a pest of avocado trees that builds extremely dense webbed nests that protect them against natural enemies, including phytoseiid mites. Nests have one or two marginal entrances that are small and flattened. The predatory mite Neoseiulus californicus co-occurs with O. perseae in the avocado orchards of the south–east of Spain. Penetration inside nests through the entrances by this predator is thought to be hindered by its size and its globular-shaped body. However, in the field it has repeatedly been found inside nests that were clearly ripped. Perhaps penetration of the nests has been facilitated by nest wall ripping caused by some other species or by unfavourable abiotic factors. However, to assess whether N. californicus is also able to enter the nest of O. perseae by itself, we carried out laboratory experiments and made a short film. They show how this predator manages to overcome the webbed wall, and that it can penetrate and forage inside nests of O. perseae. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Genotypic characterization of Brochothrix spp. isolated from meat,poultry and fish

Aim: To study genotypic diversity of isolates of Brochothrix thermosphacta recovered from meat, poultry and fish. Methods and Results: A total of 27 bacteria isolated from 19 samples of meat, poultry and fish were identified phenotypically and genotypically using PCR amplification of 16S‐23S rDNA intergenic transcribed spacer (ITS‐PCR), repetitive sequence‐based PCR (rep‐PCR) and 16S rDNA sequencing. Using ITS‐PCR, all bacteria showed the same DNA profile as the reference strains of Br. thermosphacta, allowing typing of the isolates at species level. Using 16S rDNA sequencing, all isolates were identified, at genus and species level, as Br. thermosphacta. Identification as Br. campestris was observed with a lower, but very close, level of similarity. Rep‐PCR was more discriminatory than ITS‐PCR and allowed differentiation of four subgroups among the isolates. Conclusion: Minor genotypic differences among Br. thermosphacta strains from meat, poultry and fish were observed. Significance and Impact of the Study: A rudimentary exploration of genotypic differences of Br. thermosphacta from meat, poultry and fish resulted in preliminary confirmation of the suitability of ITS‐PCR for typing Br. thermosphacta and confirmed the value of rep‐PCR fingerprinting to discriminate between Br. thermosphacta strains.     

Development of a Genotyping Method for Potato Scab Pathogens Based on Multiplex PCR

Scab disease significantly damages potato and other root crops. Streptomyces scabiei, S. acidiscabiei, and S. turgidiscabiei are the best-known causal agents of this disease. We have developed a novel genotyping method for these potato scab pathogens using multiplex PCR, whose benefits include rapid and easy detection of multiple species. We designed a species-specific primer set (6 primers, 3 pairs) for the 16S rRNA genes and 16S–23S ITS regions of these potato scab pathogens. The specificity of the primer set was confirmed by testing 18 strains containing potato scab pathogens, other Streptomyces species, and strains of other genera. The application of the developed method to potato field soil and potato tissue samples resulted in the clear detection and identification of pathogens. Since this method is applicable to a large number of environmental samples, it is expected to be useful for a high-throughput analysis of soil and plant tissues of scab disease.     

Predatory behaviors of Neoseiulus californicus and Galendromus helveolus (Acari: Phytoseiidae) attacking Oligonychus perseae (Acari: Tetranychidae)

Predatory behaviors of Neoseiulus californicus (McGregor) and Galendromus helveolus (Chant) attacking Oligonychus perseae Tuttle, Baker and Abbatiello on avocado leaves were videotaped and analyzed. Behaviors were recorded for “fresh” predators that were used ≤ 48 hr post receipt from a commercial insectary and “cold stored” predators that were maintained at 12°C for ≈ 14 days. Fresh and cold stored G. helveolus were observed to attack O. perseae only after invading webbed nests. Conversely, fresh and cold stored N. californicus employed three different modes of predatory attack: (1) intercepting and attacking migrant O. perseae outside of web nests; (2) attacking prey through nest webbing; or (3) invading and attacking O. perseae inside nests. Predatory efficacy of both N. californicus and G. helveolus was reduced following cold storage, as both species engaged in certain predatory behaviors less frequently in comparison to predators that were not stored at low temperatures. Our observed results for N. californicus and G. helveolus attacking O. perseae are interpreted in relation to the chaetotaxy hypothesis, which proposes that phytoseiid invasion efficiency and propensity of webbed nests is facilitated by dorsal setal lengths. This revised version was published online in July 2006 with corrections to the Cover Date.     

Phytophthora Species Infecting Hardy Ornamentals in Nurseries and the Managed Environment in Scotland

Between 2002 and the end of 2009, more than 4000 samples from hardy ornamental plants, collected in surveys for Phytophthora ramorum, were examined to establish the occurrence and diversity of Phytophthora species in Scotland. The samples were gathered from more than 77 plant genera in nurseries, gardens and amenity landscapes. Fifteen different Phytophthora spp. were isolated and identified either by polymerase chain reaction (PCR) or by sequencing of the ITS1, 5.8S subunit and ITS2 region of the ribosomal RNA gene. The most widespread Phytophthora spp. were P. ramorum and P. syringae, followed by P. cactorum, P. kernoviae, P. plurivora, P. cambivora, P. citrophthora, P. taxon ‘Pgchlamydo’, P. pseudosyringae and some single isolates of P. cinnamomi, P. cryptogea, P. gonapodyides, P. nicotianae and P. hibernalis. One isolate did not match any known species. In relation to the number of samples, Phytophthora was found more frequently in trade premises than in gardens or amenity landscapes and the species diversity was higher, highlighting the risks involved in plant trade.