Diversity and abundance of nematode-trapping fungi from decaying litter in terrestrial, freshwater and mangrove habitats

Nematode-trapping fungi are ubiquitous in terrestrial habitats in dung, soils, litter and woody debris and they also occur in freshwater, but only one species has been found in marine habitats. The purpose of this study was therefore to investigate whether nematode-trapping fungi occurred in mangrove habitats. To achieve this we assessed the diversity of nematode-trapping fungi on decaying litter from mangroves, freshwater and terrestrial habitats (22 sites) in Hong Kong. Composite samples (n = 1,320) of decaying litter (wood and leaves) were examined and a total of 31 species of nematode-trapping fungi belonging to four genera, Arthrobotrys, Monacrosporium, and Dactylella were recorded. Twenty-nine species reported in this study are new records for Hong Kong and 16 species are new records from mangrove habitats worldwide. Nematode trapping fungi are therefore present in marine environments. Commonly encountered taxa were Arthrobotrys oligospora and Monacrosporium thaumasium which are abundant in all habitats. A. oligospora, M. thaumasium and Arthrobotrys musiformis were frequent (F > 10%). Twenty-six species were rare (0.16–9.32%). Species richness and diversity was higher in terrestrial than in freshwater and mangrove habitats (ANOVA, P < 0.001). A higher mean diversity was observed on decaying leaves as compared to decaying wood in all habitats (P < 0.001). Based on Shannon diversity index, it was also observed that taxa characterized by adhesive nets were more frequent in all habitats. This can be explained by the fact that these taxa may have a better competitive saprotrophic ability which would allow them to compete favourably in nutrient limited environments. Abiotic factors that could be linked to differences in species diversity between decaying wood and leaves are also discussed.     

The influence of saprophytic competition on nematode predation by nematode-trapping fungi

Competivive stress imposed by common soil saprophytes may cause an increase in predation by the nematode-trapping fungi, Arthrobotrys oligospora and Monacrosporium cionopagum, on the bacteria-feeding nematode Acrobeloides buetschli. Nematode-trapping species grown with saprophytic competitors in an artificial soil substrate increased their trapping activity compared to control cultures. The results support the hypothesis that competition stimulates the predatory activity of nematode-trapping fungi as an adaptation to overcome their low competitive saprophytic ability.     

Attraction of Pinewood Nematode to Endoparasitic Nematophagous Fungus Esteya vermicola

The investigations on attraction of nematodes to nematophagous fungi have mostly dealt with the nematode-trapping species. Esteya vermicola is the endoparasitic fungus of pinewood nematode (PWN) with high infection activity. In the present study, the attraction of PWNs to E. vermicola was investigated. It was confirmed that the living mycelia and exudative substances of E. vermicola were attractive to PWN. Compared with the nematode-trapping fungus A. brochopaga as well as nematode-feeding fungus B. cinerea, E. vermicola showed the significantly strongest attraction ability to nematode. It therefore appeared that the attraction ability reflects the dependence of the fungi on nematodes for nutrients. Furthermore, a new method was developed and used in the study to confirm the effect of volatile substances for the attraction of nematode to fungi. The results suggested that the attractive substances were consisted of avolatile exudative and volatile diffusing compounds.     

The STRIPAK component SipC is involved in morphology and cell-fate determination in the nematode-trapping fungus Duddingtonia flagrans

The striatin-interacting phosphatase and kinase (STRIPAK) complex is a highly conserved eukaryotic signaling hub involved in the regulation of many cellular processes. In filamentous fungi, STRIPAK controls multicellular development, hyphal fusion, septation, and pathogenicity. In this study, we analyzed the role of the STRIPAK complex in the nematode-trapping fungus Duddingtonia flagrans which forms three-dimensional, adhesive trapping networks to capture Caenorhabditis elegans. Trap networks consist of several hyphal loops which are morphologically and functionally different from vegetative hyphae. We show that lack of the STRIPAK component SipC (STRIP1/2/HAM-2/PRO22) results in incomplete loop formation and column-like trap structures with elongated compartments. The misshapen or incomplete traps lost their trap identity and continued growth as vegetative hyphae. The same effect was observed in the presence of the actin cytoskeleton drug cytochalasin A. These results could suggest a link between actin and STRIPAK complex functions.     

Ion Beam Mutagenesis in Arthrobotrys oligospora Enhances Nematode-Trapping Ability

The nematode-trapping fungus Arthrobotrys oligospora is able to produce extracellular protease that degrades the body walls of parasitic nematode larvae found in livestock and immobilizes the nematodes. Our aim was to obtain a strain of A. oligospora with a strong ability to trap nematodes by production of high levels of extracellular protease. A wild type strain of A. oligospora was subjected to mutagenic treatments involving low-energy ion beam implantation to generate mutants. Among these mutants, A. oligospora N showed high efficiency in trapping nematodes and was also able to secrete more extracellular protease, helping it to penetrate and digest the body walls of larvae. This work represents the first application of low-energy ion beams to generate mutations in a nematode-trapping fungus, and provides a new method of obtaining a fungus with high potential application.     

Linoleic acid — The nematicidal principle of several nematophagous fungi and its production in trap-forming submerged cultures

Linoleic acid was shown to be the only detectable nematicidal agent in the mycelial extracts of several predacious fungi of the genus Arthrobotrys. Although the compound is present in saprophytic cultures, induction of trap formation by nematodes or phenylalnyl-valine caused a significant increase in its production. In submerged cultures, the number of traps formed by Arthrobotrys conoides and Arthrobotrys oligospora was directly correlated to the increase of the concentration of linoleic acid. In A. conoides, the ratio of ergosterol to linoleic acid decreased from 2.6 in saprophytic cultures to 1.1 in trap-forming cultures induced with nematodes. Linoleic acid exhibited nematicidal activities towards the free-living nematode Caenorhabditis elegans with an LD₅₀ value of 5 g/ml.     

Induction of trap formation in nematode‐trapping fungi by bacteria‐released ammonia

A total of 11 bacterial strains were assayed for bacteria‐induced trap formation in the nematode‐trapping fungus Arthrobotrys oligospora YMF1·01883 with two‐compartmented Petri dish. These strains were identified on the basis of their 16S rRNA gene sequences. Volatile organic compounds (VOCs) of eight isolates were extracted using solid‐phase micro‐extraction (SPME) and their structures were identified based on gas chromatography‐mass spectrometry (GC‐MS). At the same time, all isolates were used for quantitative measurement of ammonia by the indophenol blue method. The effects of pure commercial compounds on inducement of trap formation in A. oligospora were tested. Taken together, results demonstrated that the predominant bacterial volatile compound inducing trap formation was ammonia. Meanwhile, ammonia also played a role in other nematode‐trapping fungi, including Arthrobotrys guizhouensis YMF1·00014, producing adhesive nets; Dactylellina phymatopaga YMF1·01474, producing adhesive knobs; Dactylellina cionopaga YMF1·01472, producing adhesive columns and Drechslerella brochopaga YMF1·01829, producing constricting rings.     

Response of nematode-trapping fungi to organic substrates in a coastal grassland soil

To understand why Arthrobotrys oligospora and other nematode-trapping fungi are common and sometimes abundant in the coastal grassland soils of the Bodega Marine Reserve (BMR, Sonoma County, CA), we examined how resident trapping fungi responded to the addition of eight organic substrates (lupine leaves, grass leaves, dead isopods, dead moth larvae, isopod faeces, deer faeces, shrimp shells, and powdered chitin). We were especially interested in the effects of dead isopods because isopods are abundant at BMR and because previous studies had documented strong responses of A. oligospora to other arthropods (dead moth larvae). Soil from BMR was packed into vials (40 g dry mass equivalent per vial with water potential at −230 kPa and bulk density at 0.9 g cm⁻³), and one substrate or no substrate was added to the soil surface. After 30 d at 20 °C, trapping fungi were quantified by dilution plating and most probable number procedures. The response of A. oligospora was inversely related to substrate carbon:nitrogen (C:N) ratio: substrates with low C:N ratios (dead isopods, lupine leaves, dead moth larvae) usually caused large increases in A. oligospora whereas those with higher C:N ratios (isopod faeces, deer faeces, grass leaves) did not. An exception was chitin powder, which had a low C:N ratio, but which did not cause A. oligospora to proliferate. Responses of A. oligospora were directly related to the quantity of nitrogen added with each substrate, and those substrates that caused large increases in resident nematodes usually caused large increases in A. oligospora. Other trapping fungi did not respond as strongly as A. oligospora.     

The influence of trap type on evaluating population structure of the semifossorial and social rodent <Emphasis Type="Italic">Octodon degus</Emphasis>

Trap type may influence captures of individuals in different age-sex categories in small mammal studies, resulting in biased population and demographic information. We deployed 4 live trap types at burrow systems of the rodent, Octodon degus Molina, 1782, in central Chile to determine trap efficacy in capturing individuals of 6 demographic categories. We captured 2672 individuals in 17 709 trap days (15.1% trapping success). Tomahawks were the most efficient trap capturing half of individuals during both years, followed by mesh Sherman traps, large Sherman traps, and medium Sherman traps in 2005. All trap types equally sampled sexes. Large and medium Sherman traps provided similar demographic structure, where half of the individuals captured were pups; Tomahawk traps sampled more adults than pups. Relative captures of pups were similar across different trap types, suggesting that pups are equally sampled by each of the deployed trap types. Relative captures of adults were lower in Sherman traps, suggesting that this age class avoided solid-walled traps. For Octodon degus, the sole use of Tomahawk traps may produce sufficient, unbiased demographic data. Only 4 trap mortalities occurred (0.15%). Researchers may minimize trap mortality without compromising sufficient demographic sampling by trapping during peak animal activity.     

Demography,density, and survival of an endemic and near threatened cottontail<Emphasis Type="Italic">Sylvilagus cunicularius</Emphasis> in central Mexico

A 3-year live trapping investigation was carried out in a temperate forest in central Tlaxcala, México from 2002 to 2004. During a total of 504 trap nights, 87Silvilagus cunicularius Waterhouse, 1848 individuals were captured and marked, and age-specific survival models using demographic parameters were tested using the JOLLYAGE program. We evaluated population density of this species over a 1-year period. The age structure of the population varied among years, and the proportion of adults was relatively constant among years, whereas the proportion of juvenile showed high fluctuations. The sex ratio of juveniles that were recaptured as adults, did not differ from unity neither did the sex ratio for adults. We found no sex bias among cottontails during all 3 years of the study. When data for both sexes were combined, mean survival probability of juveniles was lower than that of adults. Although our line transect counts showed a mean density of 27 ± 5.4 individuals per km², the obtained results from trapping suggests that this species is low in abundance at La Malinche. Further studies are needed to evaluate demographical aspects of this species at different protected and unprotected areas to obtain robust information about their status.     

Development of a new shape of pheromone trap for the bean bug, <Emphasis Type="Italic">Riptortus pedestris</Emphasis> (Hemiptera: Alydidae)

Riptortus pedestris F. [=R. clavatus (Thunberg)] is one of the most serious pests affecting the cultivation of sweet persimmon, which is one of the most important export fruits in Korea. A pheromone-baited trap has been used in attempts to control this pest. In this study, the development of a more efficient pheromone-baited trap for R. pedestris was pursued by investigating three different shapes of traps: the fish trap, the pyramidal trap, and the symmetry trap. The fish trap, which is the only one commercially available, captured the lowest number of R. pedestris, and the pyramidal trap showed moderate capture efficacy. The symmetry trap captured significantly greater numbers of R. pedestris adults (ca. 6 and 28 times more than the pyramidal and fish trap, respectively). Significantly increased trapping efficacy of the symmetry trap would be useful for mass trapping of R. pedestris.     

Do Organic Amendments Enhance the Nematode-Trapping Fungi Dactylellina haptotyla and Arthrobotrys oligospora?

Soil cages (polyvinyl chloride pipe with mesh-covered ends) were used to determine how the quantity of two organic amendments affected the nematode-trapping fungi Dactylellina haptotyla and Arthrobotrys oligospora, which were studied independently in two different vineyards. Each cage contained 80 cm³ of field soil (120 g dry weight equivalent), fungal inoculum (two alginate pellets, each weighing 1.9 mg and containing assimilative hyphae of one fungus), and dried grape or alfalfa leaves (0, 360, or 720 mg equivalent to 0, 4,500, or 9,000 kg/ha) with a C:N of 28:1 and 8:1, respectively. Cages were buried in the vineyards, recovered after 25 to 39 days, and returned to the laboratory where fungus population density and trapping were quantified. Dactylellina haptotyla population density and trapping were most enhanced by the smaller quantity of alfalfa amendment and were not enhanced by the larger quantity of alfalfa amendment. Arthrobotrys oligospora population density was most enhanced by the larger quantity of alfalfa amendment, but A. oligospora trapped few or no nematodes, regardless of amendment. Trapping and population density were correlated for D. haptotyla but not for A. oligospora.     

Intracellular Proteolytic Activity in Mycelia of Arthrobotrys oligospora Bearing Mycoparasitic or Nematode Trapping Structures

Persson, Y., and Friman, E. 1993. Intracellular proteolytic activity in mycelia of Arthrobotrys oligospora bearing mycoparasitic or nematode trapping structures. Experimental Mycology 17, 182-190. The fungus Arthrobotrys oligospora parasitizes other fungi with the aid of coils and captures and digests nematodes by means of adhesive traps. We have compared proteolytic activities of mycelial extracts from coils and traps with those of vegetative hyphae. A. oligospora produced a number of proteases active at both alkaline and acidic pH. Coil extract had significantly higher proteolytic activity than extracts of vegetative hyphae. Several coil culture-specific bands were found after substrate gel electrophoresis. Pepstatin-sensitive proteolytic activity at acidic pH was higher in coil extract than in normal mycelial extracts, although the total proteolytic activity was the same. No proteolytic activity was connected solely to mycelial extracts with traps and no enhancement of proteolytic activity was observed during infection of nematodes.     

Anfälligkeit von entomopathogenen Nematoden gegenüber nematodenfangenden und endoparasitären Pilzen

Abstract Susceptibility of entomopathogenic nematodes to nematode-trapping and endoparasitic fungi
Laboratory tests in petri dishes demonstrated that the nematode-trapping fungi Arthrobotrys superba and A. robusta preyed upon the entomopathogenic nematodes Steinernema bibionis, S. feltiae and a species of Heterohabditis. Up to 100% of the nematodes were trapped 48 h after application. Large differences existed in the time required for trapping as well as for mortality after trapping and was dependent on the fungal or nematode species studied. Arthrobotrys robusta , reduced S. bibionis densities in sand-block bioassay chambers. The prior introduction of a microphagous nematode, Panagrellus redivivus , to induce trap formation caused a 52% reduction in S. bibionis levels.
The endoparasitic fungi Harposporium anguillulae and Drechmeria coniospora did not parasitize the entomopathogenic nematodes in petri dish tests. However, Verticillium balanoides , was shown to be a parasite of S. bibionis. Predivivus and a mycophagous species of Ditylenchus were more quickly parasitized than S. bibionis , with parasitism reaching 100, 90 and 30% after 42 days, respectively. In the sand-block chambers V. balanoides did not reduce the, number of recovered S. bibionis juveniles after 14 or 28 days.     

Comparison of different trapping methods for surveillance of mosquito vectors of West Nile virus in Rhône Delta,France

Five trapping methods were compared for monitoring potential vectors of the West Nile virus in four areas in the Camargue Plain of France: carbon dioxide traps, bird‐baited traps, gravid traps, resting boxes, and human landing catches. A total of 73,721 specimens, representing 14 species, was trapped in 2006. Results showed significant differences in species and abundance between the type of traps. Many more specimens were collected using CO₂ traps than any other method, with an average of 212 specimens per night per trap (p<0.05). Culex pipiens was the most abundant species collected (36.8% of total with CO₂ traps), followed by Aedes caspius (22.7%), Anopheles hyrcanus (18.3%), Culex modestus (18.3%), and Aedes detritus (3.2%). Bird‐baited traps captured only eight specimens per night per trap on average, mainly Cx. pipiens (89.9%). The species collected and their abundance are influenced by the trap location, at ground or canopy level. Culex pipiens was twice as abundant in the canopy as on the ground, whereas it was the opposite for Ae. caspius, An. hyrcanus, and Ae. detritus. Culex modestus was equally abundant at both levels. Resting boxes and gravid traps were much less efficient, capturing around 0.3 specimens per night per trap. Results are discussed in relation to West Nile virus surveillance.