Phylogeny of the genus Loxospora s.l. (Sarrameanales, Lecanoromycetes, Ascomycota), with Chicitaea gen. nov. and five new combinations in Chicitaea and Loxospora.

Loxospora is a genus of crustose lichens containing 13 accepted species that can be separated into two groups, based on differences in secondary chemistry that correlate with differences in characters of the sexual reproductive structures (asci and ascospores). Molecular phylogenetic analyses recovered these groups as monophyletic and support their recognition as distinct genera that differ in phenotypic characters. Species containing 2'-O-methylperlatolic acid are transferred to the new genus, Chicitaea Guzow-Krzem., Kukwa & Lendemer and four new combinations are proposed: C.assateaguensis (Lendemer) Guzow-Krzem., Kukwa & Lendemer, C.confusa (Lendemer) Guzow-Krzem., Kukwa & Lendemer, C.cristinae (Guzow-Krzem., Lubek, Kubiak & Kukwa) Guzow-Krzem., Kukwa & Lendemer and C.lecanoriformis (Lumbsch, A.W. Archer & Elix) Guzow-Krzem., Kukwa & Lendemer. The remaining species produce thamnolic acid and represent Loxospora s.str. Haplotype analyses recovered sequences of L.elatina in two distinct groups, one corresponding to L.elatina s.str. and one to Pertusariachloropolia, the latter being resurrected from synonymy of L.elatina and, thus, requiring the combination, L.chloropolia (Erichsen) Ptach-Styn, Guzow-Krzem., Tønsberg & Kukwa. Sequences of L.ochrophaea were found to be intermixed within the otherwise monophyletic L.elatina s.str. These two taxa, which differ in contrasting reproductive mode and overall geographic distributions, are maintained as distinct, pending further studies with additional molecular loci. Lectotypes are selected for Lecanoraelatina, Pertusariachloropolia and P.chloropoliaf.cana. The latter is a synonym of Loxosporachloropolia. New primers for the amplification of mtSSU are also presented.

Lichens and associated fungi from Glacier Bay National Park, Alaska.

Lichens are widely acknowledged to be a key component of high latitude ecosystems. However, the time investment needed for full inventories and the lack of taxonomic identification resources for crustose lichen and lichenicolous fungal diversity have hampered efforts to fully gauge the depth of species richness in these ecosystems. Using a combination of classical field inventory and extensive deployment of chemical and molecular analysis, we assessed the diversity of lichens and associated fungi in Glacier Bay National Park, Alaska (USA), a mixed landscape of coastal boreal rainforest and early successional low elevation habitats deglaciated after the Little Ice Age. We collected nearly 5000 specimens and found a total of 947 taxa, including 831 taxa of lichen-forming and 96 taxa of lichenicolous fungi together with 20 taxa of saprotrophic fungi typically included in lichen studies. A total of 98 species (10.3% of those detected) could not be assigned to known species and of those, two genera and 27 species are described here as new to science: Atrophysma cyanomelanos gen. et sp. nov., Bacidina circumpulla, Biatora marmorea, Carneothele sphagnicola gen. et sp. nov., Cirrenalia lichenicola, Corticifraga nephromatis, Fuscidea muskeg, Fuscopannaria dillmaniae, Halecania athallina, Hydropunctaria alaskana, Lambiella aliphatica, Lecania hydrophobica, Lecanora viridipruinosa, Lecidea griseomarginata, L. streveleri, Miriquidica gyrizans, Niesslia peltigerae, Ochrolechia cooperi, Placynthium glaciale, Porpidia seakensis, Rhizocarpon haidense, Sagiolechia phaeospora, Sclerococcum fissurinae, Spilonema maritimum, Thelocarpon immersum, Toensbergia blastidiata and Xenonectriella nephromatis. An additional 71 'known unknown' species are cursorily described. Four new combinations are made: Lepra subvelata (G. K. Merr.) T. Sprib., Ochrolechia minuta (Degel.) T. Sprib., Steineropsis laceratula (Hue) T. Sprib. & Ekman and Toensbergia geminipara (Th. Fr.) T. Sprib. & Resl. Thirty-eight taxa are new to North America and 93 additional taxa new to Alaska. We use four to eight DNA loci to validate the placement of ten of the new species in the orders Baeomycetales, Ostropales, Lecanorales, Peltigerales, Pertusariales and the broader class Lecanoromycetes with maximum likelihood analyses. We present a total of 280 new fungal DNA sequences. The lichen inventory from Glacier Bay National Park represents the second largest number of lichens and associated fungi documented from an area of comparable size and the largest to date in North America. Coming from almost 60°N, these results again underline the potential for high lichen diversity in high latitude ecosystems.

Biatoraalnetorum (Ramalinaceae, Lecanorales), a new lichen species from western North America.

Biatoraalnetorum S. Ekman & Tønsberg, a lichenised ascomycete in the family Ramalinaceae (Lecanorales, Lecanoromycetes), is described as new to science. It is distinct from other species of Biatora in the combination of mainly three-septate ascospores, a crustose thallus forming distinctly delimited soralia that develop by disintegration of convex pustules and the production of atranorin in the thallus and apothecia. The species is known from the Pacific Northwest of North America, where it inhabits the smooth bark of Alnusalnobetulasubsp.sinuata and A.rubra. Biatoraalnetorum is also a new host for the lichenicolous ascomycete Sclerococcumtoensbergii Diederich.

Molecular analyses uncover the phylogenetic placement of the lichenized hyphomycetous genus Cheiromycina.

The genus Cheiromycina is one of the few genera of lichenized hyphomycetes for which no sexual reproductive stages have been observed. The genus includes species from boreal to temperate regions of the Northern Hemisphere where it is found growing on bark or wood. Congeners in Cheiromycina are characterized by a noncorticate thallus, nearly immersed in the substrate and presenting powdery unpigmented sporodochia, and containing chlorococcoid photobionts. The relationships of members of Cheiromycina with other fungi are not known. Here we inferred the phylogenetic placement of Cheiromycina using three loci (nuSSU, nuLSU, and mtSSU) representing C. flabelliformis, the type species for the genus, C. petri, and C. reimeri. Our results revealed that the genus Cheiromycina is found within the family Malmideaceae (Lecanorales) where members formed a monophyletic clade sister to the genera Savoronala and Malmidea. This phylogenetic placement and the relationships of Cheiromycina with other lichenized hyphomycetous taxa are here discussed.

Molecular Evidence of Apatococcus, including A. fuscideae sp. nov., as Photobiont in the Genus Fuscidea.

The knowledge of the taxonomy and classification of algae (including lichenized) has recently increased rapidly, but there are still many gaps. We aimed to 1) identify the Fuscidea photobionts by locating their taxonomic positions in the green algal classification, and 2) to resolve their interspecific relationships. The lichenized algae were examined based on morphological observations of axenic isolates as well as molecular studies of 18S and ITS nrDNA sequences. Analysis of the secondary structure of the ITS2 operon complemented these investigations. We found that the Fuscidea photobionts were placed within the Trebouxiophyceae, related to Apatococcus lobatus (Chodat) J.B.Petersen. Phylogenetic analyses revealed one clade nesting free-living and lichenized Apatococcus F.Brand which comprised six different lineages in the ITS phylogeny. The lichenized alga associated with the investigated Fuscidea species, except for F. lightfootii (Sm.) Coppins & James, represents a hitherto unknown lineage within Apatococcus. Fuscidea lightfootii was lichenized with a separate lineage within Apatococcus, together with free-living members, which were already known from Genbank sequences. All retrieved groups within Apatococcus were rather different in their ITS sequences, thus most likely corresponding to different species. The most common photobiont of Fuscidea species, Apatococcus fuscideae A.Beck & Zahradn., was described as new to science.

Morphological, chemical and species delimitation analyses provide new taxonomic insights into two groups of Rinodina.

The genus Rinodina (Physciaceae), with approximately 300 species, has been subject to few phylogenetic studies. Consequently taxonomic hypotheses in Rinodina are largely reliant on phenotypic data, while hypotheses incorporating DNA dependent methods remain to be tested. Here we investigate Rinodina degeliana/R. subparieta and the Rinodina mniaraea group, which previously have not been subjected to comprehensive molecular and phenotypic studies. We conducted detailed morphological, anatomical, chemical, molecular phylogenetic and species delimitation studies including 24 newly sequenced specimens. We propose that Rinodina degeliana and R. subparieta are conspecific and that chemical morphs within the R. mniaraea group should be recognized as distinct species. We also propose the placement of the recently described genus Oxnerella in Physciaceae.

Molecular systematics of the wood-inhabiting, lichen-forming genus Xylographa (Baeomycetales, Ostropomycetidae) with eight new species.

The ascomycete genus Xylographa includes some of the most abundant species of wood-inhabiting lichenized fungi in boreal and temperate regions. It has never been monographed and little is known of its species diversity and evolutionary relationships. Based on a morphological and secondary metabolite-based assessment of material from North and South America, Europe and Asia, we generated a three-locus phylogeny based on sequences of the internal transcribed spacer, 28S nuclear rDNA and mitochondrial small subunit rDNA. We analyzed the data within the context of putatively related genera in the order Baeomycetales. Xylographa is a strongly supported monophyletic group closely related to Lithographa and Ptychographa, as well as rock-dwelling and lichenicolous species of Rimularia s.lat. The evolution of linearized ascomata in Xylographa appears to have enabled ascomata to grow laterally, and patterns of lateral growth are diagnostic. We recognize twenty species in Xylographa and provide a thorough revision of nomenclature. The following eight species are new: Xylographa bjoerkii T. Sprib., X. constricta T. Sprib., X. erratica T. Sprib., X. lagoi T. Sprib. & Pérez-Ortega, X. schofieldii T. Sprib., X. septentrionalis T. Sprib., X. stenospora T. Sprib. & Resl and X. vermicularis T. Sprib. The combinations Lambiella insularis (Nyl.) T. Sprib. and Xylographa carneopallida (Räsänen) T. Sprib. are newly proposed. Xylographa constricta from southern South America represents the first known case of secondary de-lichenization in the Baeomycetales. Xylographa parallela s.str. is confirmed as bipolar on the basis of sequenced collections from both southern Chile and the northern Hemisphere.

Convergent evolution of a symbiotic duet: the case of the lichen genus Polychidium (Peltigerales, Ascomycota).

PREMISE OF THE STUDY: Thallus architecture has long been a powerful guide for classifying lichens and has often trumped photobiont association and ascomatal type, but the reliability of these characters to predict phylogenetic affinity has seldom been tested. The cyanolichen genus Polychidium unites species that have strikingly similar gross morphology but consort with different photobiont genera. If Polychidium were found to be monophyletic, photobiont switching among closely related species would be suggested. If, however, species were found to arise in different lineages, a convergent body plan and ascomatal type evolution would be inferred. METHODS: We tested the monophyly of Polychidium with a multilocus phylogeny based on nuclear and mitochondrial sequence data from all known Peltigeralean families and reconstructed ancestral states for specific thallus architecture and ascomatal ontogeny types relative to Polychidium and other clades. KEY RESULTS: We found that Polychidium consists of two species groups that arose independently in different suborders within the Peltigerales, associated with Nostoc and Scytonema photobionts, respectively. We infer from ancestral character state reconstruction that dendroid thallus architecture evolved independently in these two lineages. CONCLUSIONS: The independent development of similar dendroid thallus architecture in different fungal suborders with different photobionts represents a clear and previously overlooked example of convergent evolution in lichens. Our results also suggest a pattern of character state conservation, loss, and reversion in ascomatal ontogeny types, hitherto considered conserved traits useful for higher level ascomycete systematics.