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2. The lichen genus Villophora (Teloschistaceae, Ascomycota)

Author

L. G. Sancho, Majbrit Zeuthen Søgaard, Ulrik Søchting, and Ulf Arup

Subjects
0106 biological sciences, 0303 health sciences, Subfamily, biology, Ascomycota, South America, Tayloriellina, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Caloplaca, 030308 mycology & parasitology, 03 medical and health sciences, Raesaeneniana, Genus, Botany, Key (lock), Antarctica, Chile, Lichen, Teloschistaceae, Southern Hemisphere, Ecology, Evolution, Behavior and Systematics
Abstract

The Southern Hemisphere lichen genus Villophora in subfamily Teloschistoideae is analyzed based on DNA sequence data. Six species are described, five of which are new to science: V. darwiniana and V. wallaceana grow on lignum and bark in southern Patagonia and Tierra del Fuego; V. onas and V. patagonica are lichenicolous or saxicolous on rocks in southern Patagonia; V. rimicola is saxicolous in Antarctica. Based on a three-gene DNA analysis, Tayloriellina is shown to be closely related to Villophora, and Tayloriellina microphyllina is established as a new combination. A key is provided to all species of the two genera. Raesaeneniana maulensis is combined into Villophora.

Published
2021

4. Symbiosis at its limits: ecophysiological consequences of lichenization in the genus Prasiola in Antarctica

Author

Sergio Pérez-Ortega, Beatriz Fernández-Marín, Claudia Colesie, Ana Pintado, José Manuel Laza, José Ignacio García-Plazaola, L. G. Sancho, Asunción de los Ríos, Marina López-Pozo, Alicia V Perera-Castro, Miren Irati Arzac, and Ana Sáenz-Ceniceros

Subjects
biology, Lichens, Antarctic Regions, Context (language use), Plant Science, Photosynthetic pigment, Original Articles, Verrucariaceae, biology.organism_classification, Desiccation tolerance, chemistry.chemical_compound, Symbiosis, chemistry, Chlorophyta, Botany, Prasiola, Lichen, Desiccation, Ecosystem
Abstract

Background and Aims Lichens represent a symbiotic relationship between at least one fungal and one photosynthetic partner. The association between the lichen-forming fungus Mastodia tessellata (Verrucariaceae) and different species of Prasiola (Trebouxiophyceae) has an amphipolar distribution and represents a unique case study for the understanding of lichen symbiosis because of the macroalgal nature of the photobiont, the flexibility of the symbiotic interaction and the co-existence of free-living and lichenized forms in the same microenvironment. In this context, we aimed to (1) characterize the photosynthetic performance of co-occurring populations of free-living and lichenized Prasiola and (2) assess the effect of the symbiosis on water relations in Prasiola, including its tolerance of desiccation and its survival and performance under sub-zero temperatures. Methods Photochemical responses to irradiance, desiccation and freezing temperature and pressure–volume curves of co-existing free-living and lichenized Prasiola thalli were measured in situ in Livingston Island (Maritime Antarctica). Analyses of photosynthetic pigment, glass transition and ice nucleation temperatures, surface hydrophobicity extent and molecular analyses were conducted in the laboratory. Key Results Free-living and lichenized forms of Prasiola were identified as two different species: P. crispa and Prasiola sp., respectively. While lichenization appears to have no effect on the photochemical performance of the alga or its tolerance of desiccation (in the short term), the symbiotic lifestyle involves (1) changes in water relations, (2) a considerable decrease in the net carbon balance and (3) enhanced freezing tolerance. Conclusions Our results support improved tolerance of sub-zero temperature as the main benefit of lichenization for the photobiont, but highlight that lichenization represents a delicate equilibrium between a mutualistic and a less reciprocal relationship. In a warmer climate scenario, the spread of the free-living Prasiola to the detriment of the lichen form would be likely, with unknown consequences for Maritime Antarctic ecosystems.

Published
2019

5. UV-A protection in mosses growing in continental Antarctica

Author

Daniel Kulle, B. Schroeter, Stefan Pannewitz, T. G. Allan Green, and L. G. Sancho

Subjects
Sunlight, Ceratodon purpureus, UVA Radiation, biology, Fluorometer, Botany, Terrestrial vegetation, General Agricultural and Biological Sciences, biology.organism_classification, Ozone depletion, Chlorophyll fluorescence
Abstract

The simple structure of mosses, a major component of Antarctic terrestrial vegetation, has led to suggestions that they might be exceptionally sensitive to enhanced UV from the ozone hole. The results presented here show that the mosses Ceratodon purpureus and Bryum subrotundifolium are resistant to UV-A and that the latter species can rapidly change its protection to suit the UV environment. The studies were made using a UV-A PAM chlorophyll fluorescence fluorometer that allowed absorption of UV-A before arrival at the chloroplast (i.e. UV-A shielding) to be estimated. Both C. purpureus and B. subrotundifolium have sun and shade forms that differ markedly in colour and their protection from UV-A. Shade forms of B. subrotundifolium, initially low in UV-A protection, achieve full, sun-form levels in about 6 days when exposed to ambient sunlight. These results, taken with other recent studies, suggest that not only are Antarctic mosses well protected from ambient UV, but are also as adaptable to incident UV as higher plants.

Published
2005

6. Photosynthetic Performance of Two Closely Related Umbilicaria Species in Central Spain: Temperature as a Key Factor

Author

B. Schroeter, L. G. Sancho, and Fernando Valladares

Subjects
Horticulture, Dry weight, Range (biology), Botany, Respiration, Biology, Photosynthesis, Lichen, Water content, Ecology, Evolution, Behavior and Systematics, Photosynthetic photon flux, Thallus
Abstract

Net photosynthesis (NP) and dark respiration (DR) of thalli of the lichen species Umbilicaria grisea and U. freyi growing together in the same habitat the Sierra de Guadarrama, central Spain, were measured under controlled conditions in the laboratory and under natural conditions in the field over a range of photosynthetic photon flux densities (PPFD), thallus temperatures and thallus water contents. Laboratory experiments revealed that the photosynthetic response to PPFD at optimum thallus water content is very similar in both species. The light compensation points of NP increased from PPFD of c. 20 µmol m−2 s−1 at 0°C up to c. 100 µmol m−2 s−1 PPFD at 25°C. In both species light saturation was not reached up to 700 µmol m−2 s−1 PPFD except at 0°C. By contrast, the temperature dependence of CO2 gas exchange differed substantially between U. grisea and U. freyi. Both species gave significant rates at 0°C. Optimal temperatures of NP were always higher in U. grisea at various PPFD levels if the samples were kept at optimal thallus water content. NP showed maximal rates at 95% dw in U. grisea and 110% dw in U. freyi respectively. In U. grisea a much stronger depression of NP was observed with only 5% of maximal NP reached at 180% dw. At all PPFD and temperature combinations U. freyi showed higher rates of NP and more negative rates of DR if calculated on a dry weight basis. This was also true under natural conditions at the same site, when U. freyi was always more productive than U. grisea. The differences in the photosynthetic response to temperature between both species correlated well with the different distribution patterns of both species. The possibility of genetic control of the physiological performance of these species and its influence on their distribution patterns and autecology is discussed.

Published
1997

7. Diversity of endosymbiotic Nostoc in Gunnera magellanica from Tierra del Fuego, Chile [corrected]

Author

M A, Fernández-Martínez, A, de Los Ríos, L G, Sancho, and S, Pérez-Ortega

Subjects
Magnoliopsida, Molecular Sequence Data, Biodiversity, Chile, Nostoc, Symbiosis, Phylogeny
Abstract

Global warming is causing ice retreat in glaciers worldwide, most visibly over the last few decades in some areas of the planet. One of the most affected areas is the region of Tierra del Fuego (southern South America). Vascular plant recolonisation of recently deglaciated areas in this region is initiated by Gunnera magellanica, which forms symbiotic associations with the cyanobacterial genus Nostoc, a trait that likely confers advantages in this colonisation process. This symbiotic association in the genus Gunnera is notable as it represents the only known symbiotic relationship between angiosperms and cyanobacteria. The aim of this work was to study the genetic diversity of the Nostoc symbionts in Gunnera at three different, nested scale levels: specimen, population and region. Three different genomic regions were examined in the study: a fragment of the small subunit ribosomal RNA gene (16S), the RuBisCO large subunit gene coupled with its promoter sequence and a chaperon-like protein (rbcLX) and the ribosomal internal transcribed spacer (ITS) region. The identity of Nostoc as the symbiont was confirmed in all the infected rhizome tissue analysed. Strains isolated in the present study were closely related to strains known to form symbioses with other organisms, such as lichen-forming fungi or bryophytes. We found 12 unique haplotypes in the 16S rRNA (small subunit) region analysis, 19 unique haplotypes in the ITS region analysis and 57 in the RuBisCO proteins region (rbcLX). No genetic variability was found among Nostoc symbionts within a single host plant while Nostoc populations among different host plants within a given sampling site revealed major differences. Noteworthy, interpopulation variation was also shown between recently deglaciated soils and more ancient ones, between eastern and western sites and between northern and southern slopes of Cordillera Darwin. The cell structure of the symbiotic relationship was observed with low-temperature scanning electron microscopy, showing changes in morphology of both cyanobiont cells (differentiate more heterocysts) and plant cells (increased size). Developmental stages of the symbiosis, including cell walls and membranes and EPS matrix states, were also observed.

Published
2012

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