Your search keyword '"Huotari, Tea"' showing total 9 results

1. Elevation and plant species identity jointly shape a diverse arbuscular mycorrhizal fungal community in the High Arctic.

Author

Rasmussen, Pil U., Abrego, Nerea, Roslin, Tomas, Öpik, Maarja, Sepp, Siim‐Kaarel, Blanchet, F. Guillaume, Huotari, Tea, Hugerth, Luisa W., and Tack, Ayco J. M.

Subjects

FUNGAL communities, PLANT species, GROUND cover plants, ALTITUDES, VESICULAR-arbuscular mycorrhizas, EXTREME environments, PLANT colonization

Abstract

Summary: Knowledge about the distribution and local diversity patterns of arbuscular mycorrhizal (AM) fungi are limited for extreme environments such as the Arctic, where most studies have focused on spore morphology or root colonization. We here studied the joint effects of plant species identity and elevation on AM fungal distribution and diversity.We sampled roots of 19 plant species in 18 locations in Northeast Greenland, using next generation sequencing to identify AM fungi. We studied the joint effect of plant species, elevation and selected abiotic conditions on AM fungal presence, richness and composition.We identified 29 AM fungal virtual taxa (VT), of which six represent putatively new VT. Arbuscular mycorrhizal fungal presence increased with elevation, and as vegetation cover and the active soil layer decreased. Arbuscular mycorrhizal fungal composition was shaped jointly by elevation and plant species identity.We demonstrate that the Arctic harbours a relatively species‐rich and nonrandomly distributed diversity of AM fungi. Given the high diversity and general lack of knowledge exposed herein, we encourage further research into the diversity, drivers and functional role of AM fungi in the Arctic. Such insight is urgently needed for an area with some of the globally highest rates of climate change. [ABSTRACT FROM AUTHOR]

Published

2022

2. Accounting for species interactions is necessary for predicting how arctic arthropod communities respond to climate change.

Author

Abrego, Nerea, Roslin, Tomas, Huotari, Tea, Ji, Yinqiu, Schmidt, Niels Martin, Wang, Jiaxin, Yu, Douglas W., and Ovaskainen, Otso

Subjects

CLIMATE change, BIOTIC communities, SPECIES distribution, SPECIES, ARTHROPODA

Abstract

Species interactions are known to structure ecological communities. Still, the influence of climate change on biodiversity has primarily been evaluated by correlating individual species distributions with local climatic descriptors, then extrapolating into future climate scenarios. We ask whether predictions on arctic arthropod response to climate change can be improved by accounting for species interactions. For this, we use a 14‐year‐long, weekly time series from Greenland, resolved to the species level by mitogenome mapping. During the study period, temperature increased by 2°C and arthropod species richness halved. We show that with abiotic variables alone, we are essentially unable to predict species responses, but with species interactions included, the predictive power of the models improves considerably. Cascading trophic effects thereby emerge as important in structuring biodiversity response to climate change. Given the need to scale up from species‐level to community‐level projections of biodiversity change, these results represent a major step forward for predictive ecology. [ABSTRACT FROM AUTHOR]

Published

2021

3. Higher host plant specialization of root-associated endophytes than mycorrhizal fungi along an arctic elevational gradient.

Author

Abrego, Nerea, Huotari, Tea, Tack, Ayco J. M., Lindahl, Björn D., Tikhonov, Gleb, Somervuo, Panu, Schmidt, Niels Martin, Ovaskainen, Otso, and Roslin, Tomas

Subjects

*MYCORRHIZAL fungi, *ENDOPHYTIC fungi, *PLANT-fungus relationships, *FUNGAL communities, *HOST plants, *BIOTIC communities, *ENDOPHYTES

Abstract

How community-level specialization differs among groups of organisms, and changes along environmental gradients, is fundamental to understanding the mechanisms influencing ecological communities. In this paper, we investigate the specialization of root-associated fungi for plant species, asking whether the level of specialization varies with elevation. For this, we applied DNA barcoding based on the ITS region to root samples of five plant species equivalently sampled along an elevational gradient at a high arctic site. To assess whether the level of specialization changed with elevation and whether the observed patterns varied between mycorrhizal and endophytic fungi, we applied a joint species distribution modeling approach. Our results show that host plant specialization is not environmentally constrained in arctic rootassociated fungal communities, since there was no evidence for changing specialization with elevation, even if the composition of root-associated fungal communities changed substantially. However, the level of specialization for particular plant species differed among fungal groups, root-associated endophytic fungal communities being highly specialized on particular host species, and mycorrhizal fungi showing almost no signs of specialization. Our results suggest that plant identity affects associated mycorrhizal and endophytic fungi differently, highlighting the need of considering both endophytic and mycorrhizal fungi when studying specialization in root-associated fungal communities. [ABSTRACT FROM AUTHOR]

Published

2020

4. Accounting for environmental variation in co‐occurrence modelling reveals the importance of positive interactions in root‐associated fungal communities.

Author

Abrego, Nerea, Roslin, Tomas, Huotari, Tea, Tack, Ayco J. M., Lindahl, Björn D., Tikhonov, Gleb, Somervuo, Panu, Schmidt, Niels Martin, and Ovaskainen, Otso

Subjects

FUNGAL communities, BIOTIC communities, ENVIRONMENTAL auditing, PLANT communities, MYCORRHIZAL fungi, ECTOMYCORRHIZAS

Abstract

Understanding the role of interspecific interactions in shaping ecological communities is one of the central goals in community ecology. In fungal communities, measuring interspecific interactions directly is challenging because these communities are composed of large numbers of species, many of which are unculturable. An indirect way of assessing the role of interspecific interactions in determining community structure is to identify the species co‐occurrences that are not constrained by environmental conditions. In this study, we investigated co‐occurrences among root‐associated fungi, asking whether fungi co‐occur more or less strongly than expected based on the environmental conditions and the host plant species examined. We generated molecular data on root‐associated fungi of five plant species evenly sampled along an elevational gradient at a high arctic site. We analysed the data using a joint species distribution modelling approach that allowed us to identify those co‐occurrences that could be explained by the environmental conditions and the host plant species, as well as those co‐occurrences that remained unexplained and thus more probably reflect interactive associations. Our results indicate that not only negative but also positive interactions play an important role in shaping microbial communities in arctic plant roots. In particular, we found that mycorrhizal fungi are especially prone to positively co‐occur with other fungal species. Our results bring new understanding to the structure of arctic interaction networks by suggesting that interactions among root‐associated fungi are predominantly positive. [ABSTRACT FROM AUTHOR]

Published

2020

5. SPIKEPIPE: A metagenomic pipeline for the accurate quantification of eukaryotic species occurrences and intraspecific abundance change using DNA barcodes or mitogenomes.

Author

Ji, Yinqiu, Huotari, Tea, Roslin, Tomas, Schmidt, Niels Martin, Wang, Jiaxin, Yu, Douglas W., and Ovaskainen, Otso

Subjects

*BAR codes, *BIOTIC communities, *SHOTGUN sequencing, *PIPELINES, *ENVIRONMENTAL monitoring, *DNA

Abstract

The accurate quantification of eukaryotic species abundances from bulk samples remains a key challenge for community ecology and environmental biomonitoring. We resolve this challenge by combining shotgun sequencing, mapping to reference DNA barcodes or to mitogenomes, and three correction factors: (a) a percent‐coverage threshold to filter out false positives, (b) an internal‐standard DNA spike‐in to correct for stochasticity during sequencing, and (c) technical replicates to correct for stochasticity across sequencing runs. The SPIKEPIPE pipeline achieves a strikingly high accuracy of intraspecific abundance estimates (in terms of DNA mass) from samples of known composition (mapping to barcodes R2 =.93, mitogenomes R2 =.95) and a high repeatability across environmental‐sample replicates (barcodes R2 =.94, mitogenomes R2 =.93). As proof of concept, we sequence arthropod samples from the High Arctic, systematically collected over 17 years, detecting changes in species richness, species‐specific abundances, and phenology. SPIKEPIPE provides cost‐efficient and reliable quantification of eukaryotic communities. [ABSTRACT FROM AUTHOR]

Published

2020

6. Flower‐visitor communities of an arcto‐alpine plant—Global patterns in species richness, phylogenetic diversity and ecological functioning.

Author

Tiusanen, Mikko, Huotari, Tea, Hebert, Paul D. N., Andersson, Tommi, Asmus, Ashley, Bêty, Joël, Davis, Emma, Gale, Jennifer, Hardwick, Bess, Hik, David, Körner, Christian, Lanctot, Richard B., Loonen, Maarten J. J. E., Partanen, Rauni, Reischke, Karissa, Saalfeld, Sarah T., Senez‐Gagnon, Fanny, Smith, Paul A., Šulavík, Ján, and Syvänperä, Ilkka

Subjects

*POLLINATION, *GENETIC barcoding, *DRYAS, *MOUNTAIN plants, *PLANT phylogeny, *FLOWERS

Abstract

Pollination is an ecosystem function of global importance. Yet, who visits the flower of specific plants, how the composition of these visitors varies in space and time and how such variation translates into pollination services are hard to establish. The use of DNA barcodes allows us to address ecological patterns involving thousands of taxa that are difficult to identify. To clarify the regional variation in the visitor community of a widespread flower resource, we compared the composition of the arthropod community visiting species in the genus Dryas (mountain avens, family Rosaceae), throughout Arctic and high‐alpine areas. At each of 15 sites, we sampled Dryas visitors with 100 sticky flower mimics and identified specimens to Barcode Index Numbers (BINs) using a partial sequence of the mitochondrial COI gene. As a measure of ecosystem functioning, we quantified variation in the seed set of Dryas. To test for an association between phylogenetic and functional diversity, we characterized the structure of local visitor communities with both taxonomic and phylogenetic descriptors. In total, we detected 1,360 different BINs, dominated by Diptera and Hymenoptera. The richness of visitors at each site appeared to be driven by local temperature and precipitation. Phylogeographic structure seemed reflective of geological history and mirrored trans‐Arctic patterns detected in plants. Seed set success varied widely among sites, with little variation attributable to pollinator species richness. This pattern suggests idiosyncratic associations, with function dominated by few and potentially different taxa at each site. Taken together, our findings illustrate the role of post‐glacial history in the assembly of flower‐visitor communities in the Arctic and offer insights for understanding how diversity translates into ecosystem functioning. [ABSTRACT FROM AUTHOR]

Published

2019

7. Assessing changes in arthropod predator–prey interactions through DNA‐based gut content analysis—variable environment, stable diet.

Author

Eitzinger, Bernhard, Abrego, Nerea, Gravel, Dominique, Huotari, Tea, Vesterinen, Eero J, and Roslin, Tomas

Subjects

PREDATION, WOLF spiders, GASTROINTESTINAL content analysis, SPIDERS -- Food, DNA analysis, PARDOSA

Abstract

Analysing the structure and dynamics of biotic interaction networks and the processes shaping them is currently one of the key fields in ecology. In this paper, we develop a novel approach to gut content analysis, thereby deriving a new perspective on community interactions and their responses to environment. For this, we use an elevational gradient in the High Arctic, asking how the environment and species traits interact in shaping predator–prey interactions involving the wolf spider Pardosa glacialis. To characterize the community of potential prey available to this predator, we used pitfall trapping and vacuum sampling. To characterize the prey actually consumed, we applied molecular gut content analysis. Using joint species distribution models, we found elevation and vegetation mass to explain the most variance in the composition of the prey community locally available. However, such environmental variables had only a small effect on the prey community found in the spider's gut. These observations indicate that Pardosa exerts selective feeding on particular taxa irrespective of environmental constraints. By directly modelling the probability of predation based on gut content data, we found that neither trait matching in terms of predator and prey body size nor phylogenetic or environmental constraints modified interaction probability. Our results indicate that taxonomic identity may be more important for predator–prey interactions than environmental constraints or prey traits. The impact of environmental change on predator–prey interactions thus appears to be indirect and mediated by its imprint on the community of available prey. [ABSTRACT FROM AUTHOR]

Published

2019

8. Protax‐fungi: a web‐based tool for probabilistic taxonomic placement of fungal internal transcribed spacer sequences.

Author

Abarenkov, Kessy, Somervuo, Panu, Nilsson, R. Henrik, Kirk, Paul M., Huotari, Tea, Abrego, Nerea, and Ovaskainen, Otso

Subjects

PLANT species, BIOLOGICAL classification, FUNGI, CRYPTOGAMS, EUKARYOTES, NUCLEOTIDE sequence

Abstract

Summary: Incompleteness of reference sequence databases and unresolved taxonomic relationships complicates taxonomic placement of fungal sequences. We developed Protax‐fungi, a general tool for taxonomic placement of fungal internal transcribed spacer (ITS) sequences, and implemented it into the PlutoF platform of the UNITE database for molecular identification of fungi. With empirical data on root‐ and wood‐associated fungi, Protax‐fungi reliably identified (with at least 90% identification probability) the majority of sequences to the order level but only around one‐fifth of them to the species level, reflecting the current limited coverage of the databases. Protax‐fungi outperformed the Sintax and Rdb classifiers in terms of increased accuracy and decreased calibration error when applied to data on mock communities representing species groups with poor sequence database coverage. We applied Protax‐fungi to examine the internal consistencies of the Index Fungorum and UNITE databases. This revealed inconsistencies in the taxonomy database as well as mislabelling and sequence quality problems in the reference database. The according improvements were implemented in both databases. Protax‐fungi provides a robust tool for performing statistically reliable identifications of fungi in spite of the incompleteness of extant reference sequence databases and unresolved taxonomic relationships. [ABSTRACT FROM AUTHOR]

Published

2018

9. Related herbivore species show similar temporal dynamics.

Author

Blanchet, F. Guillaume, Roslin, Tomas, Kimura, Masahito T., Huotari, Tea, Kaartinen, Riikka, Gripenberg, Sofia, and Tack, Ayco J. M.

Subjects

HERBIVORES, BIOTIC communities, ECOSYSTEMS, BIODIVERSITY, GENETIC speciation

Abstract

Abstract: Within natural communities, different taxa display different dynamics in time. Why this is the case we do not fully know. This thwarts our ability to predict changes in community structure, which is important for both the conservation of rare species in natural communities and for the prediction of pest outbreaks in agriculture. Species sharing phylogeny, natural enemies and/or life‐history traits have been hypothesized to share similar temporal dynamics. We operationalized these concepts into testing whether feeding guild, voltinism, similarity in parasitoid community and/or phylogenetic relatedness explained similarities in temporal dynamics among herbivorous community members. Focusing on two similar datasets from different geographical regions (Finland and Japan), we used asymmetric eigenvector maps as temporal variables to characterize species‐ and community‐level dynamics of specialist insect herbivores on oak (Quercus). We then assessed whether feeding guild, voltinism, similarity in parasitoid community and/or phylogenetic relatedness explained similarities in temporal dynamics among taxa. Species‐specific temporal dynamics varied widely, ranging from directional decline or increase to more complex patterns. Phylogeny was a clear predictor of similarity in temporal dynamics at the Finnish site, whereas for the Japanese site, the data were uninformative regarding a phylogenetic imprint. Voltinism, feeding guild and parasitoid overlap explained little variation at either location. Despite the rapid temporal dynamics observed at the level of individual species, these changes did not translate into any consistent temporal changes at the community level in either Finland or Japan. Overall, our findings offer no direct support for the notion that species sharing natural enemies and/or life‐history traits would be characterized by similar temporal dynamics, but reveal a strong imprint of phylogenetic relatedness. As this phylogenetic signal cannot be attributed to guild, voltinism or parasitoids, it will likely derive from shared microhabitat, microclimate, anatomy, physiology or behaviour. This has important implications for predicting insect outbreaks and for informing insect conservation. We hope that future studies will assess the generality of our findings across plant‐feeding insect communities and beyond, and establish the more precise mechanism(s) underlying the phylogenetic imprint. [ABSTRACT FROM AUTHOR]

Published

2018