DOCSLIB.ORG

Mycorrhizae in Forest Tree Nurseries Michelle M

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

Mycorrhizae in Forest Tree Nurseries Michelle M. Cram and R. Kasten Dumroese Mycorrhizae are symbiotic fungus­ The intensive commercial seedling root associations. The colonization of production for reforestation typically roots by mycorrhizal fungi can benefit suppresses or delays colonization of the host by improving nutrient and water seedlings by mycorrhizal fungi. Fumiga­ uptake. In exchange, the host plant provides tion used to control pests can limit and the mycorrhizal fungi carbohydrates (car­ sometimes remove mycorrhizal fungi bon) from photosynthesis. A substantial from the upper 15 to 30 cm (6 to 12 portion of this carbon is ultimately trans­ in) of soil for weeks to several months. ferred to the rhizosphere and is estimated Some fungicides have also been found to to account for up to 15 percent of the suppress mycorrhizae development, espe­ organic matter in forest soils. Under most cially systemic fungicides (for example, environmental conditions, trees and other triadimefon) and fungicides applied as plants are naturally colonized by mycor­ soil drenches (for example, azoxystrobin, rhizal fungi. These mycorrhizal associations iprodione). High fertilization rates have are highly complex and dynamic, a result also been known to suppress mycorrhizae of the great diversity of mycorrhizal fungi, development, particularly when the fertil­ hosts, and terrestrial systems that interact izer is high in phosphorus (greater than and evolve with changes in hosts and 150 ppm). Despite the negative effect Figure I.6—Pisolithus tinctorius forms a yellow- environmental conditions. these common nursery treatments have on brown (ocher) mantle on pine feeder roots. Photo by mycorrhizae, the benefits of fertilization Michelle M. Cram, USDA Forest Service. Two types of mycorrhizae are found and pest control often outweigh the delay on trees: ectomycorrhizae and arbuscular of mycorrhizae formation on seedlings. mycorrhizae (syn. endomycorrhizae). Ectomycorrhizal fungi enter the root be­ tween cortex cells and often form a thick mantle outside of the short feeder roots that is visible to the naked eye (fig. I.6). Forest tree species with ectomycorrhizae include pine, firs, spruce, hemlock, oak, hickory, alder, and beech. Arbuscular mycorrhizal fungi enter the root cells and cannot be seen without the aid of a microscope (fig. I.7). Arbuscular mycorrhizae are especially effective at transferring carbon to soil in the form of glomalin, a sticky glue­like substance that is estimated to provide 30 to 40 percent of the carbon found in soils. Forest tree species with arbuscular mycorrhizae include cedars, cypress, ju­ nipers, redwoods, maple, ash, dogwoods, sycamore, yellow­poplar, and sweetgum. Agricultural crops used by forest nurser­ ies as cover crops also form arbuscular Figure I.7—Arbuscular mycorrhizal fungi within western redcedar root cells. Photo by Michael P. Amaranthus, Mycorrhizal Applications, Inc. mycorrhizae. 20 Forest Nursery Pests Mycorrhizae in Forest Tree Nurseries Ectomycorrhizal fungi are able to requires careful testing of a particular in hardwood beds following fumigation, infest fumigated fields or containers via mycorrhizal inoculant to ensure a positive container operations, or as requested by windblown spores produced by mush­ benefit­to­cost ratio before operational use. their clients. rooms and puffballs growing within or Artificial inoculation with mycorrhi­ Mycorrhizal fungi may be purchased, near the nurseries. These ectomycorrhizal zal fungi in the nursery is used to increase usually in the form of spore inoculum. fungi are often well­adapted to intensive seedling performance in situations known These products typically are applied in nursery systems. Thelephora terrestris is by researchers and managers to have the nursery as a dry granular to soil or common in most North American nurser­ consistently positive results. Pisolithus media before sowing or as a drench after ies (fig. I.8). In the Pacific Northwest, tinctorius, an ectomycorrhizal fungus, germination. Some container media are Laccaria laccata and Inocybe lacera are has been known to increase survival and sold with mycorrhizal fungi or spores also common forest nursery colonizers. growth of pine and oak seedlings on strip incorporated. It may be difficult to find In contrast, arbuscular mycorrhizal fungi mine spoils in the Eastern United States commercial products that contain only produce soilborne spores that are unlikely (fig. I.9). Artificial inoculation with ar­ one species of mycorrhizal fungi. Many to colonize container growing media and buscular mycorrhizal fungi (for example, products often combine multiple species can be slower to recolonize fumigated Glomus intraradices) for species such as of mycorrhizal fungi, other biological soils. This delay in colonization can limit incense cedar, redwood, giant sequoia, organisms (for example, bacteria and production of species highly dependent and western redcedar significantly Trichoderma spp.), and nutrients, making on arbuscular mycorrhizae. increase seedling density and growth in each ingredient’s benefit difficult to as­ Artificial inoculation with mycor­ the nursery, and survival and early growth sess. When testing mycorrhizal products rhizal fungi can be beneficial for a variety after outplanting on some sites. Many that also contain nutrients, it is imperative of tree seedlings and sites; however, other examples exist of nurseries that use to include a nutrient control to determine there are many documented cases in artificial inoculation of mycorrhizal fungi if seedling response is caused by the fungi which artificial inoculation resulted in no measurable benefit or significant losses in seedling survival and growth. The symbiotic association between plants and mycorrhizal fungi requires a balanced exchange of carbon to expanded nutrient and water uptake to be mutually benefi­ cial. If the environmental conditions that plants are growing in are fully adequate for growth, then mycorrhizal fungi may add little benefit to offset their carbon use. Rapid colonization of seedlings by mycorrhizal fungi naturally present in the nursery or at a typical outplanting site may also render artificial inoculation un­ necessary. Results of artificial inoculation will vary greatly depending on the host, species or strain of mycorrhizal fungi, and environmental conditions of the nursery and outplanting sites. The complexity of interactions between mycorrhizal as­ Figure I.8—Thelephora terrestris fruiting bodies on Figure I.9—Pisolithus tinctorius (Pt) fruiting bodies sociations and environmental conditions slash pine. Photo from USDA Forest Service Archive. form under a Virginia pine originally inoculated with Pt and planted on a strip-mine spoil. Photo by Michelle M. Cram, USDA Forest Service. Forest Nursery Pests 21 Mycorrhizae in Forest Tree Nurseries or the nutrients. Managers interested in soil under desired tree species and mixed increase arbuscular mycorrhizae levels in using or testing a particular mycorrhizal with container media before sowing host the subsequent summer crops. In forest species may have to special order a single seeds, such as alfalfa and grasses. After tree nurseries, more information is needed species product. the host plants have matured and are well on the interactions of mycorrhizae, cover infected (assistance from university or crop, tree species, and application timing Some nurseries produce their own State extension services may be required to deploy a rotational cropping system mycorrhizal inoculum. Ectomycorrhizal to determining the presence and species), for managing seedlings dependent on inoculum is made by grinding up the the soil and host roots can be cut up and arbuscular mycorrhizae. fruiting bodies (puffballs, truffles, etc.) added to container media (10 percent by and adding the spores to soil, dusting The potential of mycorrhizae to volume) or applied to beds before sowing. seeds, or mixing the inoculum with water positively affect seedlings survival and and drenching containers or beds after Common cover crops used in bareroot growth will continue to draw efforts at germination (fig. I.10). Nurseries that forest nurseries for 1­ to 2­year rotations using artificial and cultural techniques to use pesticides known to suppress mycor­ can help boost arbuscular mycorrhizae produce a superior mycorrhizal seedling. rhizae should delay artificial inoculation populations and increase organic matter A better understanding of the mycorrhizal until after the pesticide applications content. This increase in mycorrhizal system for each nursery, tree species, and are finished. The primary limitation to fungi, however, will most likely be lost outplanting site is needed to determine producing ectomycorrhizal inoculum is if fumigation occurs between cover the best cultural or artificial inoculation finding sufficient quantities of fruiting cropping and seedling production. Many practices. Ultimately, any practices used bodies. In contrast, arbuscular mycor­ nurseries that fumigate in the fall will in forest nurseries must increase seedling rhizal inoculum can be grown in pots use a winter cover crop, such as rye performance and have an acceptable with fast growing host plants. Original grass and oats, as living mulch. Winter benefit­to­cost ratio. inoculum is collected in the field from cover crops in other agriculture systems Selected References Allen, M.F.; Swenson, W.; Querejeta, J.I.; Egerton­Warburton, L.M.; Treseder, K.K. 2003. Ecology of mycorrhizae: a conceptual
Recommended publications
  • Fertility-Dependent Effects of Ectomycorrhizal Fungal Communities on White Spruce Seedling Nutrition

    Fertility-Dependent Effects of Ectomycorrhizal Fungal Communities on White Spruce Seedling Nutrition

    Mycorrhiza (2015) 25:649–662 DOI 10.1007/s00572-015-0640-9 ORIGINAL PAPER Fertility-dependent effects of ectomycorrhizal fungal communities on white spruce seedling nutrition Alistair J. H. Smith II1 & Lynette R. Potvin2 & Erik A. Lilleskov2 Received: 14 January 2015 /Accepted: 6 April 2015 /Published online: 24 April 2015 # Springer-Verlag Berlin Heidelberg (outside the USA) 2015 Abstract Ectomycorrhizal fungi (EcMF) typically colonize manganese, and Atheliaceae sp. had a negative relationship with nursery seedlings, but nutritional and growth effects of these P content. Findings shed light on the community and species communities are only partly understood. To examine these ef- effects on seedling condition, revealing clear functional differ- fects, Picea glauca seedlings collected from a tree nursery natu- ences among dominants. The approach used should be scalable rally colonized by three dominant EcMF were divided between to explore function in more complex communities composed of fertilized and unfertilized treatments. After one growing season unculturable EcMF. seedlings were harvested, ectomycorrhizas identified using DNA sequencing, and seedlings analyzed for leaf nutrient concentra- Keywords Stoichiometry . Ectomycorrhizal fungal tion and content, and biomass parameters. EcMF community community effects . Nitrogen . Phosphorus . Micronutrients . structure–nutrient interactions were tested using nonmetric mul- Amphinema . Atheliaceae . Thelephora terrestris . tidimensional scaling (NMDS) combined with vector analysis of Greenhouse foliar nutrients and biomass. We identified three dominant spe- cies: Amphinema sp., Atheliaceae sp., and Thelephora terrestris. NMDS+envfit revealed significant community effects on seed- Introduction ling nutrition that differed with fertilization treatment. PERM ANOVA and regression analyses uncovered significant species Seedlings regenerating naturally or artificially are influenced by effects on host nutrient concentration, content, and stoichiometry.
  • Mycorrhization Helper Bacteria Associated with the Douglas Fir-Laccaria Laccata Symbiosis: Effects in Aseptic and in Glasshouse Conditions R Duponnois, J Garbaye

    Mycorrhization Helper Bacteria Associated with the Douglas Fir-Laccaria Laccata Symbiosis: Effects in Aseptic and in Glasshouse Conditions R Duponnois, J Garbaye

    Mycorrhization helper bacteria associated with the Douglas fir-Laccaria laccata symbiosis: effects in aseptic and in glasshouse conditions R Duponnois, J Garbaye To cite this version: R Duponnois, J Garbaye. Mycorrhization helper bacteria associated with the Douglas fir-Laccaria laccata symbiosis: effects in aseptic and in glasshouse conditions. Annales des sciences forestières, INRA/EDP Sciences, 1991, 48 (3), pp.239-251. hal-00882751 HAL Id: hal-00882751 https://hal.archives-ouvertes.fr/hal-00882751 Submitted on 1 Jan 1991 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Original article Mycorrhization helper bacteria associated with the Douglas fir-Laccaria laccata symbiosis: effects in aseptic and in glasshouse conditions R Duponnois J Garbaye 1 BIOSEM, Laboratoire de Technologie des Semences, Avenue du Bois de l’Abbé, F-49070 Beaucouzé; 2INRA, Centre de Recherches Forestières de Nancy, Champenoux, F-54280 Seichamps, France (Received 8 October 1990; accepted 19 December 1990) Summary — A range of bacterial isolates from Laccaria laccata mycorrhizas and sporocarps were tested for their effect on ectomycorrhizal development of Douglas fir with L laccata. The experiments were carried out in aseptic conditions and in the glasshouse under summer and winter conditions.
  • An Ectomycorrhizal Thelephoroid Fungus of Malaysian Dipterocarp Seedlings

    An Ectomycorrhizal Thelephoroid Fungus of Malaysian Dipterocarp Seedlings

    Journal of Tropical Forest Science 22(4): 355–363 (2010) Lee SS et al. AN ECTOMYCORRHIZAL THELEPHOROID FUNGUS OF MALAYSIAN DIPTEROCARP SEEDLINGS Lee SS*, Thi BK & Patahayah M Forest Research Institute Malaysia, 52109 Kepong, Selangor Darul Ehsan, Malaysia Received April 2010 LEE SS, THI BK & PATAHAYAH M. 2010. An ectomycorrhizal thelephoroid fungus of Malaysian dipterocarp seedlings. The ectomycorrhizal Dipterocarpaceae are among the most well-known trees in the tropics and this is the most important family of timber trees in Malaysia and South-East Asia. Recent studies and molecular data reveal that members of the Thelephoraceae are common ectomycorrhizal fungi associated with the Dipterocarpaceae. The suspected thelephoroid fungus FP160 was isolated from ectomycorrhizal roots of a Shorea parvifolia (Dipterocarpaceae) seedling and kept in the Forest Research Institute Malaysia (FRIM) culture collection. In subsequent inoculation experiments it was able to form morphologically similar ectomycorrhizas with seedlings of two other dipterocarps, namely, Hopea odorata and S. leprosula, and the exotic fast-growing legume, Acacia mangium. A taxonomic identity of this fungus would benefit its possible use in inoculation and planting programmes. This information is also important to expand our limited knowledge of Malaysian mycodiversity. In this paper the morphological characteristics of the ectomycorrhizas formed by FP160 with H. odorata and A. mangium are described and the fungus identified using molecular methods as a member of the family Thelephoraceae, most likely a Tomentella sp. It was not possible to identify the fungus more precisely due to the limited number of sequences available for tropical Thelephoraceae in the public databases. Keywords: Acacia mangium, Dipterocarpaceae, ectomycorrhizas, ITS, Thelephoraceae LEE SS, THI BK & PATAHAYAH M.
  • Low Soil Temperature and Efficacy of Ectomycorrhizal Fungi

    Low Soil Temperature and Efficacy of Ectomycorrhizal Fungi

    LOW SOIL TEMPERATURE AND EFFICACY OF ECTOMYCORRHIZAL FUNGI by LYNN HUSTED B.Sc, University of British Columbia, 1969 M.Sc., University of British Columbia, 1982 A THESIS SUBMITTED IN PARTIAL FULFILMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY in THE FACULTY OF GRADUATE STUDIES FOREST SCIENCE DEPARTMENT We accept this thesis as conforming to the required standard THE UNIVERSITY OF BRITISH COLUMBIA September 1991 (c) Lynn Husted, 1991 In presenting this thesis in partial fulfilment of the requirements for an advanced degree at the University of British Columbia, I agree that the Library shall make it freely available for reference and study. I further agree that permission for extensive copying of this thesis for scholarly purposes may be granted by the head of my department or by his or her representatives. It is understood that copying or publication of this thesis for financial gain shall not be allowed without my written permission. Department of The University of British Columbia Vancouver, Canada Date DE-6 (2/88) ABSTRACT The influence of root-zone temperature on the efficacy of various ectomycorrhizal fungi, i.e., their ability: (1) to colonize roots in a nursery environment, (2) to persist and colonize new roots in the field and (3) to improve the growth, nutrition, and physiology of white spruce (Picea glauca (Moench) Voss) seedlings, was examined in controlled environment experiments using water baths to regulate root-zone temperature. Eight-week-old non-mycorrhizal seedlings were inoculated with 13 different inocula (1 forest floor inoculum, 12 specific fungi), then transplanted into 6, 16, or 26°C peat:vermiculite mixes for 8 weeks.
  • Ectomycorrhizal Fungal Community Structure in a Young Orchard of Grafted and Ungrafted Hybrid Chestnut Saplings

    Ectomycorrhizal Fungal Community Structure in a Young Orchard of Grafted and Ungrafted Hybrid Chestnut Saplings

    Mycorrhiza (2021) 31:189–201 https://doi.org/10.1007/s00572-020-01015-0 ORIGINAL ARTICLE Ectomycorrhizal fungal community structure in a young orchard of grafted and ungrafted hybrid chestnut saplings Serena Santolamazza‑Carbone1,2 · Laura Iglesias‑Bernabé1 · Esteban Sinde‑Stompel3 · Pedro Pablo Gallego1,2 Received: 29 August 2020 / Accepted: 17 December 2020 / Published online: 27 January 2021 © The Author(s) 2021 Abstract Ectomycorrhizal (ECM) fungal community of the European chestnut has been poorly investigated, and mostly by sporocarp sampling. We proposed the study of the ECM fungal community of 2-year-old chestnut hybrids Castanea × coudercii (Castanea sativa × Castanea crenata) using molecular approaches. By using the chestnut hybrid clones 111 and 125, we assessed the impact of grafting on ECM colonization rate, species diversity, and fungal community composition. The clone type did not have an impact on the studied variables; however, grafting signifcantly infuenced ECM colonization rate in clone 111. Species diversity and richness did not vary between the experimental groups. Grafted and ungrafted plants of clone 111 had a diferent ECM fungal species composition. Sequence data from ITS regions of rDNA revealed the presence of 9 orders, 15 families, 19 genera, and 27 species of ECM fungi, most of them generalist, early-stage species. Thirteen new taxa were described in association with chestnuts. The basidiomycetes Agaricales (13 taxa) and Boletales (11 taxa) represented 36% and 31%, of the total sampled ECM fungal taxa, respectively. Scleroderma citrinum, S. areolatum, and S. polyrhizum (Boletales) were found in 86% of the trees and represented 39% of total ECM root tips. The ascomycete Cenococcum geophilum (Mytilinidiales) was found in 80% of the trees but accounted only for 6% of the colonized root tips.
  • Ectomycorrhizal Fungal Communities at Forest Edges 93, 244–255 IAN A

    Ectomycorrhizal Fungal Communities at Forest Edges 93, 244–255 IAN A

    Journal of Blackwell Publishing, Ltd. Ecology 2005 Ectomycorrhizal fungal communities at forest edges 93, 244–255 IAN A. DICKIE and PETER B. REICH Department of Forest Resources, University of Minnesota, St Paul, MN, USA Summary 1 Ectomycorrhizal fungi are spatially associated with established ectomycorrhizal vegetation, but the influence of distance from established vegetation on the presence, abundance, diversity and community composition of fungi is not well understood. 2 We examined mycorrhizal communities in two abandoned agricultural fields in Minnesota, USA, using Quercus macrocarpa seedlings as an in situ bioassay for ecto- mycorrhizal fungi from 0 to 20 m distance from the forest edge. 3 There were marked effects of distance on all aspects of fungal communities. The abundance of mycorrhiza was uniformly high near trees, declined rapidly around 15 m from the base of trees and was uniformly low at 20 m. All seedlings between 0 and 8 m distance from forest edges were ectomycorrhizal, but many seedlings at 16–20 m were uninfected in one of the two years of the study. Species richness of fungi also declined with distance from trees. 4 Different species of fungi were found at different distances from the edge. ‘Rare’ species (found only once or twice) dominated the community at 0 m, Russula spp. were dominants from 4 to 12 m, and Astraeus sp. and a Pezizalean fungus were abundant at 12 m to 20 m. Cenococcum geophilum, the most dominant species found, was abundant both near trees and distant from trees, with lowest relative abundance at intermediate distances. 5 Our data suggest that seedlings germinating at some distance from established ecto- mycorrhizal vegetation (15.5 m in the present study) have low levels of infection, at least in the first year of growth.
  • Mycorrhization Between Cistus Ladanifer L. and Boletus Edulis Bull Is Enhanced by the Mycorrhiza Helper Bacteria Pseudomonas Fluorescens Migula

    Mycorrhization Between Cistus Ladanifer L. and Boletus Edulis Bull Is Enhanced by the Mycorrhiza Helper Bacteria Pseudomonas Fluorescens Migula

    Mycorrhiza (2016) 26:161–168 DOI 10.1007/s00572-015-0657-0 ORIGINAL ARTICLE Mycorrhization between Cistus ladanifer L. and Boletus edulis Bull is enhanced by the mycorrhiza helper bacteria Pseudomonas fluorescens Migula Olaya Mediavilla1,2 & Jaime Olaizola2 & Luis Santos-del-Blanco1,3 & Juan Andrés Oria-de-Rueda1 & Pablo Martín-Pinto1 Received: 30 April 2015 /Accepted: 16 July 2015 /Published online: 26 July 2015 # Springer-Verlag Berlin Heidelberg 2015 Abstract Boletus edulis Bull. is one of the most economically work was to optimize an in vitro protocol for the mycorrhizal and gastronomically valuable fungi worldwide. Sporocarp synthesis of B. edulis with C. ladanifer by testing the effects of production normally occurs when symbiotically associated fungal culture time and coinoculation with the helper bacteria with a number of tree species in stands over 40 years old, Pseudomonas fluorescens Migula. The results confirmed suc- but it has also been reported in 3-year-old Cistus ladanifer cessful mycorrhizal synthesis between C. ladanifer and L. shrubs. Efforts toward the domestication of B. edulis have B. edulis. Coinoculation of B. edulis with P. fluorescens dou- thus focused on successfully generating C. ladanifer seedlings bled within-plant mycorrhization levels although it did not associated with B. edulis under controlled conditions. Micro- result in an increased number of seedlings colonized with organisms have an important role mediating mycorrhizal sym- B. edulis mycorrhizae. B. edulis mycelium culture time also biosis, such as some bacteria species which enhance mycor- increased mycorrhization levels but not the presence of my- rhiza formation (mycorrhiza helper bacteria). Thus, in this corrhizae. These findings bring us closer to controlled B.
  • Boletus Edulis and Cistus Ladanifer: Characterization of Its Ectomycorrhizae, in Vitro Synthesis, and Realised Niche

    Boletus Edulis and Cistus Ladanifer: Characterization of Its Ectomycorrhizae, in Vitro Synthesis, and Realised Niche

    UNIVERSIDAD DE MURCIA ESCUELA INTERNACIONAL DE DOCTORADO Boletus edulis and Cistus ladanifer: characterization of its ectomycorrhizae, in vitro synthesis, and realised niche. Boletus edulis y Cistus ladanifer: caracterización de sus ectomicorrizas, síntesis in vitro y área potencial. Dª. Beatriz Águeda Hernández 2014 UNIVERSIDAD DE MURCIA ESCUELA INTERNACIONAL DE DOCTORADO Boletus edulis AND Cistus ladanifer: CHARACTERIZATION OF ITS ECTOMYCORRHIZAE, in vitro SYNTHESIS, AND REALISED NICHE tesis doctoral BEATRIZ ÁGUEDA HERNÁNDEZ Memoria presentada para la obtención del grado de Doctor por la Universidad de Murcia: Dra. Luz Marina Fernández Toirán Directora, Universidad de Valladolid Dra. Asunción Morte Gómez Tutora, Universidad de Murcia 2014 Dª. Luz Marina Fernández Toirán, Profesora Contratada Doctora de la Universidad de Valladolid, como Directora, y Dª. Asunción Morte Gómez, Profesora Titular de la Universidad de Murcia, como Tutora, AUTORIZAN: La presentación de la Tesis Doctoral titulada: ‘Boletus edulis and Cistus ladanifer: characterization of its ectomycorrhizae, in vitro synthesis, and realised niche’, realizada por Dª Beatriz Águeda Hernández, bajo nuestra inmediata dirección y supervisión, y que presenta para la obtención del grado de Doctor por la Universidad de Murcia. En Murcia, a 31 de julio de 2014 Dra. Luz Marina Fernández Toirán Dra. Asunción Morte Gómez Área de Botánica. Departamento de Biología Vegetal Campus Universitario de Espinardo. 30100 Murcia T. 868 887 007 – www.um.es/web/biologia-vegetal Not everything that can be counted counts, and not everything that counts can be counted. Albert Einstein Le petit prince, alors, ne put contenir son admiration: -Que vous êtes belle! -N´est-ce pas, répondit doucement la fleur. Et je suis née meme temps que le soleil..
  • Zur Pilzflora Der Eilenriede in Hannover - Zweiter Teil

    Zur Pilzflora Der Eilenriede in Hannover - Zweiter Teil

    Ber. naturhist. Ges. Hannover 132 151-187 Hannover 1990 Zur Pilzflora der Eilenriede in Hannover - Zweiter Teil - (Erster Teil in: Ber. Naturhist. Ges. Hannover 125. 1982: 269-307) von Knut WÖLDECKE unter Mitarbeit von Gerhard HOYER, Günter KLEINERT und Klaus WÖLDECKE mit einer Tabelle Zusammenfassung: Diese Arbeit gliedert sich in drei Abschnitte: 1. Historisches: Die Auffindung zweier Quellen (GRAEFF 1862, TUHTEN 1848) eröffnet einen ersten Einblick in die Kenntnis der Pilzflora der Eilenriede in der Mitte des 19. Jahrhunderts. Der Teil über Pilze aus der umfangreichen Eilenriede-Flora GRAEFF k (79 Pilze umfassend) wird erstmals veröffentlicht und kommentiert. 2. Nachträge: Fortgesetzte Studien und die Auswertung weiterer Quellen (vgl. WÖL­ DECKE 1 9 8 2 ) ließen die Zahl der beobachteten Pilzarten auf 1125 ansteigen. Die Eilen­ riede gehört zu den pilzfloristisch am längsten und kontinuierlichsten besuchten Unter­ suchungsgebieten in der Bundesrepublik Deutschland. Eine ähnlich große Artenvielfalt in einem Waldkomplex vergleichbarer Größe konnte im Bundesgebiet nur sehr selten nachgewiesen werden. Ferner werden vier rezente Pilzvergesellschaftungen aus der Eilenriede und ihren Randzonen vorgestellt. 3. Veränderungen in der Pilzflora: Zahlreiche Faktoren — u.a. Grundwasserabsen­ kung und Eutrophierung — haben seit der Mitte des 20. Jahrhunderts, besonders aber in den letzten zwanzig Jahren, zu gravierenden Veränderungen in der Pilzflora geführt. Die verborgene Lebensweise der Pilze erschwert den Nachweis von Veränderungen in der Zusammensetzung der Pilzflora. Als Maß für Veränderungen wird der Anteil der seit mindestens 20 Jahren in der Eilenriede nicht mehr beobachteten Arten der Roten Liste Großpilze Niedersachsens und Bremens an den insgesamt bisher im Stadtwald gefundenen Rote-Liste-Arten verwendet. Danach ergibt sich, daß 107 von 249, das sind etwa 43 % der Arten seit 20 Jahren verschollen sind; von den Mykorrhiza-Pilzen sind 65 von 118, das sind etwa 55 %, verschollen.
  • Ectomycorrhizal Fungal Assemblages of Nursery-Grown Scots Pine Are Influenced by Age of the Seedlings

    Ectomycorrhizal Fungal Assemblages of Nursery-Grown Scots Pine Are Influenced by Age of the Seedlings

    Article Ectomycorrhizal Fungal Assemblages of Nursery-Grown Scots Pine are Influenced by Age of the Seedlings Maria Rudawska * and Tomasz Leski Institute of Dendrology, Polish Academy of Sciences, Parkowa 5, 62-035 Kórnik, Poland; [email protected] * Correspondence: [email protected] Abstract: Scots pine (Pinus sylvestris L.) is the most widely distributed pine species in Europe and is relevant in terms of planted areas and harvest yields. Therefore, each year the demand for planting stock of Scots pine is exceedingly high, and large quantities of seedlings are produced annually throughout Europe to carry out reforestation and afforestation programs. Abundant and diverse ectomycorrhizal (ECM) symbiosis is critical for the success of seedlings once planted in the field. To improve our knowledge of ECM fungi that inhabit bare-root nursery stock of Scots pine and understand factors that influence their diversity, we studied the assemblages of ECM fungi present across 23 bare-root forest nurseries in Poland. Nursery stock samples were characterized by a high level of ECM colonization (nearly 100%), and a total of 29 ECM fungal taxa were found on 1- and 2- year-old seedlings. The diversity of the ECM community depended substantially on the nursery and age of the seedlings, and species richness varied from 3–10 taxa on 1-year-old seedlings and 6–13 taxa on 2-year-old seedlings. The ECM fungal communities that developed on the studied nursery stock were characterized by the prevalence of Ascomycota over Basidiomycota members on 1-year-old seedlings. All ecological indices (diversity, dominance, and evenness) were significantly affected by age of the seedlings, most likely because dominant ECM morphotypes on 1-year-old seedlings (Wilcoxina mikolae) were replaced by other dominant ones (e.g., Suillus luteus, Rhizopogon roseolus, Thelephora terrestris, Hebeloma crustuliniforme), mostly from Basidiomycota, on 2-year-old seedlings.
  • Thelephora Anthocephala Thelephora ≡ Anthocephala Var

    Thelephora Anthocephala Thelephora ≡ Anthocephala Var

    © Demetrio Merino Alcántara [email protected] Condiciones de uso Thelephora anthocephala (Bull.) Fr., Epicr. syst. mycol. (Upsaliae): 535 (1838) [1836-1838] Foto Dianora Estrada Thelephoraceae, Thelephorales, Incertae sedis, Agaricomycetes, Agaricomycotina, Basidiomycota, Fungi ≡ Clavaria anthocephala Bull., Herb. Fr. (Paris) 6: tab. 452 (1786) ≡ Merisma anthocephalum (Bull.) Sw., K. Vetensk-Acad. Nya Handl. 32: 84 (1811) = Merisma clavulare Fr., Observ. mycol. (Havniae) 1: 156 (1815) = Merisma foetidum var. anthocephala (Bull.) Pers., Syn. meth. fung. (Göttingen) 2: 584 (1801) ≡ Phylacteria anthocephala (Bull.) Pat., Hyménomyc. Eur. (Paris): 154 (1887) ≡ Phylacteria anthocephala (Bull.) Pat., Hyménomyc. Eur. (Paris): 154 (1887) f. anthocephala ≡ Phylacteria anthocephala f. incrustans-resupinata Bourdot & Galzin, Bull. trimest. Soc. mycol. Fr. 40(1): 123 (1924) ≡ Phylacteria anthocephala f. repens Bourdot & Galzin, Bull. trimest. Soc. mycol. Fr. 40(1): 123 (1924) ≡ Phylacteria anthocephala (Bull.) Pat., Hyménomyc. Eur. (Paris): 154 (1887) var. anthocephala ≡ Phylacteria anthocephala var. clavularis (Fr.) Bourdot & Galzin, Bull. trimest. Soc. mycol. Fr. 40(1): 122 (1924) = Phylacteria clavularis (Fr.) Bigeard & H. Guill., Fl. Champ. Supér. France (Chalon-sur-Saône) 2: 452 (1913) = Phylacteria terrestris var. digitata Bourdot & Galzin, Bull. trimest. Soc. mycol. Fr. 40(1): 126 (1924) = Thelephora americana (Peck) Sacc., Syll. fung. (Abellini) 16: 183 (1902) ≡ Thelephora anthocephala (Bull.) Fr., Epicr. syst. mycol. (Upsaliae): 535 (1838) [1836-1838] f. anthocephala ≡ Thelephora anthocephala f. incrustans-resupinata (Bourdot & Galzin) Corner, Beih. Nova Hedwigia 27: 40 (1968) ≡ Thelephora anthocephala f. repens (Bourdot & Galzin) Corner, Beih. Nova Hedwigia 27: 40 (1968) ≡ Thelephora anthocephala var. americana (Peck) Corner, Beih. Nova Hedwigia 27: 40 (1968) ≡ Thelephora anthocephala (Bull.) Fr., Epicr. syst. mycol. (Upsaliae): 535 (1838) [1836-1838] var.
  • Arbuscular Mycorrhizas: Producing and Applying Arbuscular Mycorrhizal Inoculum

    Arbuscular Mycorrhizas: Producing and Applying Arbuscular Mycorrhizal Inoculum

    Arbuscular Mycorrhizas: Producing and Applying Arbuscular Mycorrhizal Inoculum M. Habte and N. W. Osorio Department of Tropical Plant and Soil Sciences Acknowledgments the United States Department of Agriculture, nor the We are grateful to Dr. Mark Brundrett, who generously author shall be liable for any damage or injury resulting gave us permission to use his drawings, including the from the use of or reliance on the information contained one on the cover, in this publication. in this publication or from any omissions to this publi­ This work was funded by the Hawaii Renewable cation. Mention of a company, trade, or product name Resources Extension Program, supported by RREA or display of a proprietary product does not imply ap­ Smith-Lever 3D funds from CSREES/USDA. proval or recommendation of the company or product to the exclusion of others that may also be suitable. About this publication This information may be updated in more recent The information contained herein is subject to change publications posted on the CTAHR Web site, <www2. or correction. Procedures described should be consid­ ctahr.hawaii.edu>. For information on obtaining addi­ ered as suggestions only. To the knowledge of the au­ tional copies of this book, contact the Publications and thor, the information given is accurate as of July 2001. Information Office, CTAHR–UHM, 3050 Maile Way Neither the University of Hawaii at Manoa, the UH (Gilmore Hall 119), Honolulu, HI 96822; 808-956-7036; College of Tropical Agriculture and Human Resources, 808-956-5966 (fax); e-mail <ctahrpub@ hawaii.edu>. Table of contents Arbuscular mycorrhizal associations .........................................................................