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This study comprises a survey on ecology, morphology and taxonomy of parasitic fungi infecting Pteridophytes and Orchidaceae found by the author on several field trips to Western Panama as part of the project plant parasitic micro-fungi of Western Panama (ppMP). In Panama, approximately 9500 species of vascular plants are found. Of these, Orchidaceae are with ca. 1150 (ca. 12%) species by far the most speciose family. The Pteridophytes in Panama comprise ca. 940 species in 31 families. Most fungal pathogens on Orchidaceae in tropical regions were described from plants in culture or from material intercepted at borders by plant quarantine services and not from their natural habitats. Therefore, little is known about distribution and ecology of these pathogens in their natural range. The author determined and classified several hundred Orchidaceae-species and Pteridophytes at the sites selected in the context of the project. This work facilitated the identification of many host plants (at least to genus-level) even in sterile condition in the field. About 65 species of Pucciniales are known to infest Orchidaceae and ca. 38% of them are described from tropical America. All available types of Pucciniales on Orchidaceae in tropical America were studied and compared with 91 specimens of rust fungi on orchids collected by the author in Panama. Several hundred additional specimens housed in the BPI, almost all intercepted from plant quarantine services, were used for comparison. As result of this work, it is suggested to combine Uromyces stenorrhynchi Henn. to Sphenospora and, as this is the oldest epithet, to synonymize S. kevorkianii Linder, S. mera Cumm. and S. saphena Cumm. with it. Further, it could be demonstrated that Uredo aurantiaca Montemartini, U. cyrtopodii Syd. & P. Syd., U. epidendri Henn., U. guacae Mayor, U. gynandrearum Corda, U. lynchii (Berk.) Plowr., U. neopustulata Cumm. (≡U. pustulata Henn.), U. nigropuncta Henn., U. oncidii Henn., U. ornithidii F. Kern., Cif. & Thurst., and presumably U. scabies Cke., are anamorphs of this variable species. U. gynandrearum is the oldest anamorph-name for all these taxa. Therefore, it can be established that this rust infects more than 80 species of Orchidaceae in three subfamilies. In total, the anamorph of this species was collected by the author on 17 different species of Orchidaceae in Panama which, apart from one species, are all new hosts to science. The molecular data obtained by the author confirm this view, although more data, especially from material from the whole range of distribution of U. gynandrearum, are necessary. Puccinia spiranthicola Cumm. was found to be a synonym of P. cinnamomea Diet. & Holw. and was found by the author on three different Orchidaceae in two subfamilies. Uredo pleurothallidis Keissl. is now considered a synonym of U. wittmackiana Henn. and the latter as the anamorph of Puccinia oncidii Cumm. In the anamorph genus Uredo, a new species was found infecting at least five different species of Sobralia and Elleanthus (Sobraliinae) at different localities. Molecular data indicate it to be related to the currently polyphyletic Phakopsoraceae. For the rusts with suprastomatal sori on Orchidaceae, now separated from Hemileia and placed in the genus Desmosorus (nom. inval.), the current concept with only one taxon is rejected and the establishment of three subspecies is suggested. The complicated taxonomy is discussed and makes it necessary to validate the genus-name and make a new combination. Another Hemileia-anamorph species was found by the author and is considered to be new to science. This is the first species of this alliance in America on Orchidaceae. Molecular data obtained by the author confirm the separation of Desmosorus from Hemileia and the position of the new species. For rusts on Pteridophytes, a new species of Milesia, (teleomorph: Milesina) and a new anamorphic species of Uredinopsis was found, both on hosts hitherto not known. In Calidion, the presumable anamorph-genus of Uncol, the species C. cf. cenicafeae Salazar & Buriticá was found on several new hosts. Further, the teleomorph was found. Morphologically, this teleomorph did not agree with the description of Uncol by the author of the genus, although the anamorph characteristics left no doubt that it is Calidion. Apparently, the description of Uncol is inadequate, but cannot be improved, as the type is unavailable. Molecular data obtained by the author show this species to be closest to Desmosorus. For Uredo superficialis Speg., the anamorph of Desmella, nine new hosts in eight different fern families were found by the author and the collaborators of the ppMP-project. Ecological data indicate that this species includes different host specific races, which, however could not be distinguished morphologically. For all these rusts, a thorough discussion of the ecology in their habitats is given. In total, 21 LSU rDNA sequences from 6 different rust species on Orchidaceae and Pteridophytes were obtained and analyzed with the Maximum Parsimony and Minimum Evolution method. Here, the position of several groups could be confirmed, and some anamorphs could be assigned to different teleomorphic relationships. Within the Ascomycota and their anamorphs, several hitherto unknown species and species not known from these hosts or not known from Panama were found and analyzed. On Orchidaceae, the following fungi belonging to the Ascomycota are described, illustrated and discussed: In the Phyllachorales, a hitherto not known Phyllachora sp. was found on Oncidium warszewiczii Rchb. f. and was compared with the other species of this order currently known from Orchidaceae. In the Asterinaceae s. l. Lembosia cf. epidendri Meir. Silva & O. R. Pereia was found on Maxillaria crassifolia (Lindl.) Rchb. f., which is a new host and new host alliance for this fungus hitherto only known from Brazil. The fungus is described and compared with all species of Asterinaceae currently known on Orchidaceae. In the Meliolaceae, Meliola orchidacearum Cif. was found on Camaridium biolleyi (Schltr.) Schltr. and an Epidendrum sp. which are new hosts and new host alliances of this fungus which was hitherto only known from the Caribbean Islands. It is described, illustrated and compared with the type. In the Glomerellaceae, Glomerella cingulata and its anamorph Colletotrichum gloeosporioides were found on several hosts. The species is illustrated, described and compared with data from literature. In the anamorphic Mycosphaerellaceae, Pseudocercospora odontoglossii (Prill. & Delacr.) U. Braun, a species currently only known from culture, was found on the new host Pleurothallis imraei Lindl. It is illustrated, described and compared with data from literature. On ferns, the following other fungi are described, illustrated and discussed: A conspicuous undescribed form of Polycyclus was found by the author on Elaphoglossum ciliatum (C. Presl.) T. Moore (Dryopteridaceae) and Serpocaulon loriceum (L.) A. R. Sm. (Polypodiaceae). A conspectus of Parmulariaceae infecting ferns is given and demonstrated that Polycyclina should be synonymized under Polycyclus. Summing up, it can be assessed, especially for the Pucciniales, that the most speciose plant family in Panama carries remarkable few species of specific parasites, and that many of them seem to be distributed over a wide range of species which often are not closely related. One reason amongst others seems to be that parasites need a minimum density of host plants in a habitat to survive. As orchid species often occur with only few (and often small) individual plants at a given locality, the probability for a specific pathogen to infect a plant gets too low, hence high diversity by low abundance of hosts might be an impediment for specific pathogens. In this case, unspecific parasites, or such which are infecting larger alliances, are in advantage. Other reasons could be specific traits of orchids, like succulence and mycotrophy which might hamper fungal infections.
Fungi are an important component of every ecosystem but hardly considered in biodiversity monitoring projects. This thesis aims at characterizing fungal diversity, with an emphasis on epigeous fungi, encompassing different biogeographic zones and points in time. A main sampling area was established in the Taunus mountain range in Germany, which was sampled monthly over three years.
For testing species richness on spatial scale, the Taunus transect was compared with four other areas, which were assessed with lower sampling effort. One of these areas was Bulau in Germany, in which four excursions were made. Furthermore, two sampling events were performed in Somiedo in Spain and one sampling event in Kleinwalsertal in Austria. Already existing data of a two-year monitoring project in Panama next to the river Majagua were additionally used for comparison.
All these areas were investigated with a standardized sampling protocol focusing on macroscopically evident fungi and vascular plants using a time-restricted transect design. The transects consisted of strips, which were 500 m long and about 20 m broad, and were sampled for 2 hours at each single sampling event....
Tulasnella species (Tulasnellaceae, Cantharellales, Basidiomycota) form inconspicuous basidiomata on rotten branches or trunks of trees, difficult to find and recognize in nature. However, according to ultrastrucural and molecular data, species of Tulasnellaceae are the most frequent mycorrhriza forming fungi (mycobionts) of green, photosynthetic orchids worldwide. Species of Tulasnellaceae were also found as prominent mycobionts of the extraordinary diverse orchids in tropical montane rainforest of Southern Ecuador. Orchids obligately depend on mycobionts during the juvenile stage when the fungi have to deliver carbon to the non-photosynthetic protocorm and thus the fungi substantially influence the establishment of orchids in the wild. Species of Tulasnellaceae can acquire carbon from decaying bark or wood by specific saprotrophic capabilities as was recently proven through comparative genomics that included data on decay enzymes from Tulasnella cf. calospora isolated from orchid mycorrhizae (Anacamptis laxiflora, Italy). Thus, species of Tulasnellaceae can be saprotrophs and symbionts simultaneously.
It is currently under discussion, whether specific species of Tulasnella are required for seed germination and establishment of distinct terrestrial and epiphytic orchids in nature or if species of Tulasnella are generalists concerning their association with orchids. The inconsistences in species concepts and taxonomy of Tulasnella spp., however, strongly impede progress in this field of research. The aim of the present study was, therefore, to revise the species concepts by combining, for the first time, morphological and molecular data from basidiomata.
Specimens were collected in tropical Andean forest in Southern Ecuador and in temperate forests in Germany. Additional specimens were loaned from fungaria. In total, 205 specimens, corresponding to 16 own samples and 189 specimens from fungaria were analyzed. The mycobiont relationships of Tulasnella spp. with orchids from the sampling area in Ecuador were studied in populations of Epidendrum rhopalostele. The basis for molecular-phylogenetic analysis was completed by data obtained from own previous investigations on mycobionts from the investigation area and Tulasnella isolates from Australia.
30 morphospecies are illustrated and delimited by a morphological key based on traditional species concepts. Tulasnella andina from Ecuador and Tulasnella kirschneri from China are presented as species new to science. Tulasnella cruciata is described from herbarium material for the first time. Tulasnella aff. eichleriana and T. violea are reported for the first time from Ecuador. Molecular sequences of two Tulasnella spp. isolated from mycobionts of Epidendrum rhopalostele cannot be related to any morphological species concept. Statistical analyses suggest that conventional diagnostic using morphological characteristics is ambiguous for delimiting morphologically similar species.
For the first time sequences of the ITS-5.8S rDNA region were obtained after cloning from fresh basidiomata. Extraction of DNA from herbarium specimens was, however, unsuccessful. Sequences from 16 fresh basidiomata, six pure cultures, and sequences of orchids mycorrhizae (e.g. from Epidendrum rhopalostele) available in the database GenBank were analyzed. Proportional
variability of ITS-5.8S rDNA sequences within and among cultures and within and among specimens were used to designate morphospecies. Results suggest an intragenomic variation of less than 2 %, an intraspecific variation of up to 4 % and an interspecific divergence of more than 9 % for Tulasnella spp.
Four percent of intraspecific divergence was defined as a minimum threshold for delimiting phylogenetic species. This threshold corroborates the so far used 3 % to 5 % divergence in delimitation of operational taxonomic units of Tulasnella mycobionts.
Quite a number of sequences of Tulasnella are available in GenBank, mostly obtained from direct PCR amplification from orchid mycorrhizae. By including closely related sequences in the phylogenetic analysis, several morphological cryptic species of Tulasnella, mostly from Ecuador, were found. Arguments are given for molecular support of the new species Tulasnella andina and the established species Tulasnella albida, T. asymmetrica, T. eichleriana, T. tomaculum, and T. violea. Thus, by combining molecular and morphological data species concepts in Tulasnella are improved. The definitions of Tulasnella calospora and T. deliquescens, however, remain phylogenetically inconsistent.
The present investigation is a first step to expand our knowledge on the intraand interspecific morphological and molecular variability of Tulasnella spp. and to delimit species relevant for studies on ecology and communities of orchids and Tulasnellaceae.
The fungal genus Pestalotiopsis s.l. contains approximately 300 described species and is globally distributed. The monotypic genus Pestalotia is considered the closest relative of Pestalotiopsis s.l. This study aims to investigate the diversity and systematics within Pestalotiopsis s.l. and its relation to Pestalotia. Therefore, an integrative approach is used considering molecular phylogeny methods as well as examination of morphological characters.
Recently, Pestalotiopsis s.l. was split into three genera with the addition of the newly erected Neopestalotiopsis and Pseudopestalotiopsis. The species of these genera are usually saprotrophic, phytoparasitic, or endophytic, and have been isolated from soil, air, and many kinds of anorganic material. The asexual fruiting bodies appear on infected plant material as black acervuli that release conidia. The conidia are important to examine for morphological taxon recognition. The number of conidial cells is the feature that distinguishes Pestalotiopsis s.l. spp. with five celled conidia, from Pestalotia pezizoides with six celled conidia. However, the significance of morphological characters is controversially discussed among mycologists. In recent years, 55 new species were described based on minor genetic distances and marginal or no morphological differences. Thus, the value of certain morphological characters and genetic markers need to be reconsidered.
In this study, 102 herbarium specimens of 26 described species, with an emphasis on plant pathogenic species from North America, have been morphologically examined and documented through drawings and photographs. Morphological examination was complemented with a comprehensive molecular dataset obtained from 191 cultures representing the genera Neopestalotiopsis, Pestalotia, Pestalotiopsis, Pseudopestalotiopsis, and Truncatella. One novelty of this work is that, besides the well-established markers ITS, TEF1, and ß-tubulin, the protein-coding genes MCM7 and TSR1 were successfully sequenced and included in the analyses. Phylogenies using Maximum Likelihood and Bayesian inference methods of single loci and the combined dataset were calculated. By comparison of these phylogenies, MCM7 was identified as the most powerful one in terms of phylogenetic resolution and statistical support of nodes and is proposed as an additional barcoding marker in Pestalotiopsis s.l.
In Pestalotiopsis, species delimitation was tested using the Baysian Phylogenetics and Phylogeography (BP&P) program that tests an existing species scenario against Bayesian inference methods under a multispecies coalescent model. The program supported only ten species out of the predetermined 19 species scenario. Measurements of conidia for species detected by BP&P were explored using a TukeyHSD-Test in the program R to find means that are significantly different from each other. This test revealed that combinations of morphological characters are required to distinguish between the ten species found by BP&P.
Another purpose of this work was to clarify the status of Pestalotia with regard to Pestalotiopsis s.l. Therefore, fresh epitypic material of Pestalotia pezizoides, was collected, isolated, and cultivated. The molecular analysis of a combined dataset of the gene regions ITS and LSU for species of Amphisphaeriales nested P. pezizoides in the genus Seiridium. Thus, synonymy of Pestalotia with Seiridium is proposed here. This is supported by morphology of the conidia. Further, an epitype is proposed for the type species of Pestalotiopsis, P. maculans. On the other hand, the recently proposed epitype of P. adusta is rejected here as it conflicts with the taxonomic hypothesis obtained in this study and its introduction is inconsistent with the formal requirements for epitypification. A new topotypic specimen is proposed instead. Additionally, several nomenclatural changes become necessary in many species examined. These include three new combinations and six synonyms of species of Pestalotiopsis s.l.
The conclusion of this work is that morphological data have potential as a valuable, inexpensive and easy way to recognize species. However, it is not the best method for species discovery and delimitation bearing in mind that in microfungi and many other organisms, individual plasticity and analogous structures are inadequately investigated. By phylogenetic analyses of molecular sequence data, it is possible to compare a great amount of equivalent characters and to delimit species that are morphologically cryptic. This is especially important since species of Pestalotiopsis s.l. mostly lack sexual structures that are helpful for morphological species delimitation in other groups of fungi. Thus, the Genealogical Concordance Species Concept (GCSC) finds its application in many fungal taxa. Conflicts in the genealogy between phylogenetic trees of different markers are interpreted as recombination of the genetic material within a linage. Accordingly, the change from conflict to congruence in a set of different phylogenetic trees can be seen as the species limit. It can be expected that increased application of the GCSC will lead to further approximation of described species numbers to the real number of species, especially in complicated groups like asexual microfungi.
Soil fungal communities are an essential element in the terrestrial ecosystem, however their response to ongoing anthropogenic climate change is currently poorly understood. Fungi are one of the most abundant groups of microbes in soil, they are mainly responsible for the decomposition of organic matter (Baldrian et al., 2012; Buée et al., 2009). By binding carbon in soil, fungi thus maintain an important role in the global carbon cycle (Bardgett et al., 2008). Future climates are likely to influence the communities of belowground microbial organisms (Castro et al., 2010; Deacon et al., 2006). However, how these communities are affected in their diversity, composition, and function after environmental perturbation is insufficiently known.
Molecular techniques using high-throughput sequencing are presently revolutionizing the analysis of complex communities, such as soil fungi. High-throughput metabarcoding enables the recovery of DNA sequence data directly from environmental samples, and DNA sequences from entire communities present in these samples can be simultaneously recovered through massively parallel sequencing reactions (Bik et al., 2012; Taberlet et al., 2012b). This results in more accurate estimation of diversity and community composition and thus provides unprecedented insight into cryptic communities (Lindahl and Kuske, 2014). Yet, challenges associated with these novel techniques include the bioinformatic processing, and the ecological analyses of the large amount of sequence data generated. Most biologists without explicit training in bioinformatics spend a fair amount of time learning how to filter raw sequence data, and customize bioinformatics pipelines specific to their project. To improve the quality of data treatment, and decrease the time needed for the analyses, it is desirable to have bioinformatics pipelines that are easy to use, well explained to researchers not trained in bioinformatics, and adaptable to individual research needs...
Die Bromeliaceae umfassen mehr als 3.100 fast ausschließlich neotropische Arten. Bekannt für ihre außergewöhnliche ökologische Vielseitigkeit haben sich Bromelien erfolgreich in terrestrischen und epiphytischen Lebensräumen ausgebreitet.
Eine umfassende Untersuchung des Gefährdungsgrades aller Bromelienarten Panamas und Costa Ricas stand bisher noch aus und ist insbesondere aufgrund des großen Reichtums an Lebensräumen, der beide Länder auszeichnet, und den vielfältigen Veränderungen geboten.
Im Rahmen der vorliegenden Arbeit wurden während der insgesamt etwa achtmonatigen Feldarbeit 54 Exkursionen in Westpanama durchgeführt und Belege von 61% (126 Arten) der für Panama bekannten Arten gesammelt.
Auf der Basis der Feldarbeit und der in verschiedenen Herbarien durchgeführten Studien (Überprüfung und Digitalisierung von > 8.000 Aufsammlungen) wurden Diversität, Endemismus, Areale und räumliche Muster der Artenvielfalt der Bromeliaceae in Panama und Costa Rica erfasst, dokumentiert und analysiert.
Nur drei der derzeit bekannten acht Unterfamilien der Bromeliaceae finden sich in Panama und vier in Costa Rica. Zwanzig Arten werden hier erstmals für Panama gemeldet. Sechs bisher für Panama gemeldete Bromelienarten wurden als irrtümlich gemeldet identifiziert. Die Flora der Bromeliaceae umfasst nun 16 Gattungen und 206 Arten in Panama sowie 18 Gattungen und 199 Arten in Costa Rica.
33 Arten sind endemisch in Panama, 32 Arten in Costa Rica und 36 Arten sind auf das Gebiet beider Länder beschränkt. Die Gattung Werauhia hat ihr Diversitätszentrum in Panama (47 von insgesamt 87 Arten) und Costa Rica (59/87 Arten) und ist gleichzeitig die artenreichste Gattung in beiden Ländern.
In Panama treten 113 Arten (54,9 %) zwischen 1.000 und 2.000 Höhenmetern auf. Die Art mit der niedrigsten Höhengrenze ist Pitcairnia halophila, die am höchsten angetroffene Art ist Werauhia ororiensis.
Für jede der für Panama und Costa Rica (259 Arten) gemeldeten Bromelienarten wurde eine Verbreitungskarte erstellt; für die in beiden Ländern auftretenden 191 Arten wurde darüber hinaus die potenzielle Verbreitung modelliert.
In Panama ist der prämontane Regenwald mit 138 Arten (einschließlich 25 der insgesamt 33 endemischen Arten) die Holdridge-Vegetationszone mit der höchsten Anzahl an Bromelien. In Costa Rica hat der untere Bergregenwald einen besonders hohen Anteil endemischer Bromelien (13 von insgesamt 32 Arten).
In Panama und Costa Rica beherbergen mittlere Höhenlagen den größten Artenreichtum der Bromeliaceae mit Maximalwerten von etwa 125 Arten im Osten Costa Ricas und in Westpanama. Einige Regionen Panamas verfügen nicht über ausgewiesene Schutzgebiete, weisen jedoch einen hohen Artenreichtum an Bromelien auf (z.B. Teile Westpanamas, El Valle de Anton und benachbarte Gebiete sowie die Serranía de Cañazas).
In der hier vorgestellten Klassifizierung des Gefährdungsgrades gemäß den Richtlinien der IUCN werden für Panama 32 Arten als vom Aussterben bedroht (CR), 36 Arten als Stark Gefährdet (EN) und 36 Arten als Gefährdet (VU) eingestuft. In Costa Rica wird Aechmea aquilega als Ausgestorben (EX) eingeschätzt. Vier Arten werden als vom Aussterben bedroht (CR), 30 Arten als Stark Gefährdet (EN) und 39 Arten als Gefährdet (VU) klassifiziert.
In Panama wurden 184 Arten (89% der insgesamt 206 Arten) in Schutzgebieten nachgewiesen. 122 Arten (59%) wurden sowohl innerhalb als auch außerhalb und 19 Arten (9%) nur außerhalb von Schutzgebieten nachgewiesen. In Costa Rica kommen 182 Bromelienarten (91% der insgesamt 199 Arten) in Schutzgebieten vor, 168 Arten (84%) wurden sowohl innerhalb als auch außerhalb und 14 Arten (7%) nur außerhalb von Schutzgebieten nachgewiesen.
Die Schätzungen zeigen, dass die zu erwartende Gesamtzahl der Bromelienarten in Panama zwischen 224 und 250 Arten liegt, und die zu erwartende Gesamtzahl der Bromelienarten in Costa Rica liegt zwischen 207 und 221 Arten. Den Ergebnissen der Modellierung zufolge wird für eine Anzahl bisher nur für Costa Rica gemeldeter Arten das Auftreten in Panama mit erheblicher Wahrscheinlichkeit prognostiziert (z.B. Guzmania blassi, Werauhia ampla), wie auch umgekehrt das Vorkommen bisher nur für Panama bekannter Arten in Costa Rica (z.B. Aechmea strobilina, Pitcairnia kressii).
Der Erhalt der bestehenden Schutzgebiete sollte ein vorangiges Ziel sein. Darüber hinaus ist es wünschenswert, einige dieser Gebiete auszudehnen und neue Schutzgebiete auszuweisen, um biologisch hochdiverse Gebiete mit einem hohen Anteil endemischer Arten zu schützen.
Plant parasitic species of Asterinaceae and Microthyriaceae (Dothideomycetes, Ascomycota, Fungi) are inconspicuous foliicolous fungi with a mainly tropical distribution. They form black colonies on the surface of living leaves. Members of Asterinaceae and Microthyriaceae are characterized by shield-shaped, flat ascomata (thyriothecia) which grow completely superficially on the leaf cuticle. Microthyriaceae, Asterinaceae and other families of thyriothecia-forming ascomycetes belong to the class Dothideomycetes due to the presence of bitunicate asci. However, until today no consistent taxonomic concept nor molecular phylogenetic studies exist for the families of thyriothecioid ascomycetes. In the present thesis, 42 species belonging to 13 different anamorphic and teleomorphic genera of Asterinaceae, Microthyriaceae and ‘Pycnothyriales’ recently collected in Western Panama, are identified, described in detail and illustrated with drawings, transmission and scanning electron microscopical photographs. Among the 42 species, 37 species belong to the Asterinaceae, four species to the Microthyriaceae and one species to the from group ‘Pycnothyriales’. Two species of Asterinaceae are new to sience: Asterina gaiadendricola with an Asterostomella anamorph and Asterina schlegeliae with a Mahanteshamyces anamorph. Among the remaining species of Asterinaceae, 28 species represent new records for Panama: Asterina cestricola, A. ciferriana, A. consobrina, A. corallopoda, A. davillae with anamorph, A. diplocarpa, A. diplopoda, A. ekmanii, A. fuchsiae, A. manihotis, A. phenacis, A. radiofissilis with anamorph, A. siphocampyli, A. sponiae, A. stipitipodia with anamorph, A. styracina, A. tonduzii with anamorph, A. weinmanniae, A. zanthoxyli, Asterostomella dilleniicola, Asterolibertia licaniicola, Asterolibertia nodulosa, Cirsosia splendida with its Homalopeltis chrysobalani anamorph and Prillieuxina winteriana with its Leprieurina winteriana anamorph. The remaining 11 species of Asterinaceae probably respresent new species: Asterina spp. 1-8, Asterolibertia sp., Halbanina sp. and Mahanteshamyces sp. The four species of Microthyriaceae are new records for Panama: Maublanica uleana, Platypeltella irregularis, Platypeltella smilacis and Xenostomella tovarensis. The species Hemisphaeropsis magnoliae in the form group ‘Pycnothyriales’ is a new record for Panama. During this study, voucher material of 44 additional species of plant parasitic thyriothecioid ascomycetes was examined. Thereby, the number of species of Asterinaceae known for Panama since 2006 raises from four to 30, for Microthyriaceae respectively from zero to four and for ‘Pycnothyriales’ from zero to one. 21 of the presented species are new records for Central America and two species are new records for the American Continent. The presented 42 species parasitize 47 host plant species in 39 genera belonging to 28 plant families. For 23 fungal species, new host plant species are discovered. From those, seven belong to host plant genera not reported before to be parasitized by a member of Asterinaceae and Microthyriaceae: Burmeistera (Campanulaceae), Curatella and Davilla (Dilleniaceae), Greigia (Bromeliaceae), Hirtella (Chrysobalanaceae), Oxandra and Xylopia (Annonaceae). In this study, the first molecular phylogenetic approach in Asterinaceae is provided. For the first time, DNA was isolated from fresh material of Asterina spp. and their respective anamorphic stages on leaves in Panama. The hypothesis derived from SSU and LSU rDNA neighbour-joining analysis supports the monophyly of the Asterinaceae and suggests a close relationship to Venturiaceae within the class Dothideomycetes. The data obtained from the ppMP project (plant parasitic microfungi of Panama) indicate a constant but low abundance of plant parasitic thyriothecioid ascomycetes in natural plant communities in Panama, with Asterinaceae as the most species-rich and diverse family. Further collection activities in tropical regions worldwide will certainly increase our knowledge about species diversity and ecology of tropical plant parasitic thyriothecioid ascomycetes.
The division Ascomycota(Fungi) contains a large number of taxa known to reproduce only asexually by the formation of conidia or other non-motile propagules produced by mitotic cellular devisions. They are called anamorphic, mitosporic, asexual or conidial fungi and ecologically, they are often found associated with plant debris in different stages of decay. In general, saprobic anamorphs of ascomycetous affinities are poorly studied and their outstanding diversity is currently underexplored. Phylogenetic relationships are unknown for many of them and they are still largely underrepresented in the current phylogenetic classification system of Fungi, with many morphologically defined anamorphic taxa still awaiting taxonomic reassessment in the light of molecular approaches. The increasing usage of molecular markers combined with robust statistical methods has allowed their phylogenetic affinities to be revealed and to gradually incorporate many of them into the different taxonomic groups of the division Ascomycota. However, the phylogenetic placement and taxonomic status of a large number of saprobic taxa remain unresolved due to the lack of DNA sequence data.
The present dissertation aims to explore the rich but understudied diversity of those anamorphic fungi traditionally known as hyphomycetes that inhabit dead plant debris. It consists of five publications in which a polyphasic approach integrating morphological, developmental, cultural and molecular data was used to incorporate novel or incertae sedis taxa within Ascomycota and to make more sound decisions regarding their taxonomic status. Specific objectives include: 1. the collection, isolation and morphological characterization of selected anamorphic fungi representing putative new or interesting taxa of uncertain phylogenetic placement; 2. the generation of novel DNA sequence data to infer their phylogenetic relationships and to resolve their taxonomic affinities within Ascomycota; 3. the testing of any previously available morphologically based hypotheses on their putative position, generic placement or relationships with teleomorphic, pleomorphic or other anamorphic taxa; and 4. the determination of their generic validity, monophyly and taxonomic boundaries using molecular data and phylogenetic analyses methods.
Materials studied in these five projects consisted of specimens collected during field work carried out by the author or collaborators in different countries including USA, the Czech Republic and Panama between the years 2014 and 2017. The target substrates were dead leaves of different palm trees, dead wood and bark of pines and twigs or stems of unknown shrubs and woody vines that are all known to harbor a rich saprobic mycobiota. Putative novelties or anamorphic taxa with unknown or poorly studied phylogenetic affinities were selected for further morphological and molecular investigation. Micromorphological studies were based on fungal structures observed on natural substrate, herbarium specimens and in culture. DNA was extracted from cultures and PCR amplification followed by Sanger sequencing was carried out using relevant molecular markers employed in fungal phylogenetic studies. Newly obtained DNA sequence data were analyzed following a standard phylogenetic analysis pipeline and phylogenetic relationships were reconstructed using character-based methods such as Maximum Likelihood and Bayesian inference.
Conclusion is that anamorphic Ascomycota inhabiting dead plant debris represents a largely untapped source of biodiversity and information still in need of further exploration. A new capnodiaceous genus Castanedospora, seven new species named Taeniolella sabalicola, Hermatomyces bifurcatus, H. constrictus, H. megasporus, H. sphaericoides, H. verrucosus and Septonema lohmanii, and two new combinations, Castanedospora pachyanthicola and H. reticulatus, are proposed based on morphological and DNA sequence data. Molecular phylogenetics was confirmed as the tool of choice for the inference of relationships in novel or incertae sedis anamorphic fungi that are otherwise difficult to assess in the absence of a teleomorphic state. They were first resolved or revisited for several saprobic species such as Ernakulamia cochinensis, H. sphaericus, H. tucumanensis or Septonema fasciculare in a suitable framework for phylogenetic hypothesis testing. Molecular data allowed to fully incorporate all these taxa in Ascomycota, particularly within the classes Dothideomycetes and Sordariomycetes, and to provide a foundation for better taxonomic decisions on their classification. Large and polyphyletic genera such as Taeniolella, Sporidesmium and Septonema, partially treated in this work and containing mostly saprobic species of obscure affinities, remained in need of further investigation.
The fungal interaction with plants is a 400 million years old phenomenon, which presumably assisted in the plants’ establishment on land. In a natural ecosystem, all plant-ranging from large trees to sea-grasses-are colonized by fungal endophytes, which can be detected inter- and intracellularly within the tissues of apparently healthy plants, without causing obvious negative effects on their host. These ubiquitous and diverse microorganisms are likely playing important roles in plant fitness and development. However, the knowledge on the ecological functions of fungal root endophytes is scarce. Among possible functions of endophytes, they are implicated in mutualisms with plants, which may increase plant resistance to biotic stressors like herbivores and pathogens, and/or to abiotic factors like soil salinity and drought. Also, endophytes are fascinating microorganisms in regard to their high potential to produce a great spectrum of secondary metabolites with expected ecological functions. However, evidences suggest that the interactions between host plants and endophytes are not static and endophytes express different symbiotic lifestyles ranging from mutualism to parasitism, which makes difficult to predict the ecological roles of these cryptic microorganisms. To reveal the ecological function of fungal root endophytes, this doctoral thesis aims at assessing fungal root endophytes interactions with different plants and their effects on plant fitness, based on their phylogeny, traits, and competition potential in settings encompassing different abiotic contexts. To understand the cryptic implication of nonmycorrhizal endophytes in ecosystem processes, we isolated a diverse spectrum of fungal endophytes from roots of several plant species growing in different natural contexts and tested their effects on different model plants under axenic laboratory conditions. Additionally,we aimed at investigating the effect of abiotic and biotic variables on the outcome of interactions between fungal root endophytes and plants.
In summary, the morphological and physiological traits of 128 fungal endophyte strains within ten fungal orders were studied and artificial experimental systems were used to reproduce their interactions with three plant species under laboratory conditions. Under defined axenic conditions, most endophytes behaved as weak parasites, but their performance varied across plant species and fungal taxa. The variation in the interactions was partly explained by convergent fungal traits that separate groups of endophytes with potentially different niche preferences. According to my findings, I predict that the functional complementarity of strains is essential in structuring natural root endophytic communities. Additionally, the responses of plant-endophyte interactions to different abiotic factors, namely nutrient availability, light intensity, and substrate’s pH, indicate that the outcome of plant-fungus relationships may be robust to changes in the abiotic environment. The assessment of the responses of plant endophyte interactions to biotic context, as combinations of selected dominant root fungal endophytes with different degrees of trait similarity and shared evolutionary history, indicates that frequently coexisting root-colonizing fungi may avoid competition in inter-specific interactions by occupying specific niches, and that their interactions likely define the structure of root-associated fungal communities and influence the microbiome impacts on plant fitness.
In conclusion, my findings suggest that dominant fungal lineages display different ecological preferences and complementary sets of functional traits, with different niche preferences within root tissues to avoid competition. Also, their diverse effects on plant fitness is likely host-isolate dependent and robust to changes in the abiotic environment when these encompass the tolerance range of either symbiont.
Antagonistic and mutualistic species interactions provide important ecosystem functions affecting plant population dynamics and distribution. Many of these functions are important for the regeneration of plants, either by limiting or facilitating successful transition between life stages. Interactions can occur across the whole geographical range of a species and thereby encompass different environmental gradients, such as changes in temperature or water availability. Understanding the joint effects of species interactions and environmental factors on the regeneration of plants is key for understanding plant population dynamics under global change and could provide important recommendations for managing and conservation efforts.
My thesis aimed at advancing the knowledge of how species interactions depend on environmental conditions and jointly affect plant recruitment along the elevational distribution of plants. This thesis includes three chapters in which I studied the effects of animal seed deposition, seed predation, mycorrhizal and pathogenic fungi occurrences as well as abiotic and biotic environmental factors on the recruitment of Swiss stone pine (Pinus cembra). I conducted fieldwork in the Swiss Alps across the entire elevational distribution of the pine (1850 – 2250 m a.s.l). Over a period of three years, I recorded animal seed deposition by spotted nutcrackers (Nucifraga caryocatactes) and conducted seed translocation experiments. Further, I assessed fungal communities using DNA metabarcoding. I measured abiotic environmental factors such as temperature, water and light availability, pH, as well as biotic environmental factors such as distance to conspecific adults and ground vegetation cover. In my thesis, I used a broad range of community ecology approaches, from seed dispersal ecology to experimental plant ecology and microbial ecology.
First, I investigated the effects of environmental factors on four recruitment processes (i.e. seed deposition, seed predation, seed germination, seedling survival) of Swiss stone pine. Further, I aimed at identifying the most important recruitment processes potentially limiting pine regeneration across its elevational range. To investigate pine recruitment, I firstly tested how seed deposition, seed predation, seed germination and seedling survival were affected by the microhabitat characteristics ultimately determining where a seed arrives in the environment (i.e. canopy cover & ground vegetation cover). Secondly, I applied a sensitivity analysis to investigate which of the four recruitment processes poses limitation to the pines’ regeneration across its range. My results reveal that the importance of particular recruitment processes varies along the pines’ elevational range. I found that at the lower range margin and the distribution centre seed germination and seedling survival were the main limiting factors, whereas animal-mediated seed dispersal became especially important at the upper range margin. My study contributes to the field with a new approach for disentangling the relative importance of recruitment processes across environmental gradients and thereby could help to project how plant recruitment might respond to future changes in environmental conditions.
The second aim of my study was to investigate how abiotic and biotic environmental factors affect the occurrence of Swiss stone pine-associated pathogenic and mutualistic fungi by combining field measurements of environmental factors with a DNA metabarcoding approach. I identified potentially important fungal interaction partners of the pine and determined drivers shaping their occurrences. My results reveal that generalist fungi were not affected by abiotic and biotic environmental factors. However, specialist pathogens showed patterns according to the Janzen-Connell framework (i.e. accumulation of pathogen close to adult plants). Interestingly, I found evidence for an “inverse” Janzen-Connell effect, i.e. high abundance of a specialist mutualist close to adult plants, potentially mitigating effects of soil pathogens close to parent trees. Further, I found that pine-associated fungi are distributed widely within and beyond the range of their host plant, adding knowledge on how mutualisms and antagonisms might be affected when plants move their distributional range upwards.
Finally, I investigated how known and unknown plant-associated fungi affect the regeneration of Swiss stone pine in an environmental context. My results suggest that seedling establishment was most strongly affected by abiotic environmental factors, such as light availability and maximum summer temperature. Further, the results indicate that seedling survival was affected by biotic environmental factors, i.e. fungal agents, with high abundances of a known fungal pathogen co-occurring with low seedling survival rates. My results also reveal that known mycorrhizal partners as well as a large number of unknown fungal operational taxonomic units (OTUs) were associated with the survival of seedlings. My findings highlight the importance of plant-fungal interactions for plant recruitment and offer a feasible approach for the identification of hidden plant-fungal associations in highly complex DNA metabarcoding datasets. This approach offers a valuable tool for investigating plant-microbe interactions, ultimately helping to understand plant population dynamics.
My dissertation adds to a deeper understanding on the linkage between plant regeneration and species interactions, especially on how plant-animal and plant-fungal interactions in concert with environmental factors shape plant recruitment. My study reveals the importance of animal-mediated seed dispersal and fungal pathogens in plant recruitment with consequences for potential range shifts of plant species. My thesis has important implications for conservation and management efforts by informing on key species interactions under environmental change.