Your search keyword '"Sproll L"' showing total 11 results

1. All-clear for gourmets: truffles not radioactive

Author

Büntgen, U., primary, Jäggi, M., additional, Stobbe, U., additional, Tegel, W., additional, Sproll, L., additional, Eikenberg, J., additional, and Egli, S., additional

Published

2016

2. Ideas and perspectives: truffles not radioactive

Author

Büntgen, U., primary, Jäggi, M., additional, Stobbe, U., additional, Tegel, W., additional, Sproll, L., additional, Eikenberg, J., additional, and Egli, S., additional

Published

2015

3. Drought-induced decline in Mediterranean truffle harvest

Author

Büntgen, U., Egli, S., Camarero, Jesús Julio, Fischer, E. M., Stobbe, U., Kauserud, H., Tegel, W., Sproll, L., Stenseth, Nils Christian, Büntgen, U., Egli, S., Camarero, Jesús Julio, Fischer, E. M., Stobbe, U., Kauserud, H., Tegel, W., Sproll, L., and Stenseth, Nils Christian

Published

2012

4. Ideas and perspectives: truffles not radioactive.

Author

Büntgen, U., Jäggi, M., Stobbe, U., Tegel, W., Sproll, L., Eikenberg, J., and Egli, S.

Subjects

RADIOACTIVITY, FOREST ecology, MUSHROOMS, CONSUMERS, CULTIVATORS

Abstract

Although ranging among the most expensive gourmet foods, it remains unclear if Burgundy truffles (Tuber aestivum) accumulate radioactivity at a harmful level comparable to other fungi. Here, we measure the 137Cs in 82 T. aestivum fruitbodies from Switzerland, Germany, France, Italy and Hungary. All specimens reveal insignificant radiocaesium concentrations, thus providing an all clear for truffle hunters and cultivators in Europe as well as dealers and customers from around the world. Our results are particularly relevant in the light of recent cultivation efforts and the fact that forest ecosystems are still highly contaminated with 137Cs, for which mushrooms are the main pathways to human diets. [ABSTRACT FROM AUTHOR]

Published

2015

5. The fall of the summer truffle: Recurring hot, dry summers result in declining fruitbody production of Tuber aestivum in Central Europe.

Author

Steidinger BS, Büntgen U, Stobbe U, Tegel W, Sproll L, Haeni M, Moser B, Bagi I, Bonet JA, Buée M, Dauphin B, Martínez-Peña F, Molinier V, Zweifel R, Egli S, and Peter M

Subjects

Seasons, Trees, Europe, Ascomycota physiology, Mycorrhizae physiology

Abstract

Global warming is pushing populations outside their range of physiological tolerance. According to the environmental envelope framework, the most vulnerable populations occur near the climatic edge of their species' distributions. In contrast, populations from the climatic center of the species range should be relatively buffered against climate warming. We tested this latter prediction using a combination of linear mixed effects and machine learning algorithms on an extensive, citizen-scientist generated dataset on the fruitbody productivity of the Burgundy (aka summer) truffle (Tuber aestivum Vittad.), a keystone, ectomycorrhizal tree-symbiont occurring on a wide range of temperate climates. T. aestivum's fruitbody productivity was monitored at 3-week resolution over up to 8 continuous years at 20 sites distributed in the climatic center of its European distribution in southwest Germany and Switzerland. We found that T. aestivum fruitbody production is more sensitive to summer drought than would be expected from the breadth of its species' climatic niche. The monitored populations occurring nearly 5°C colder than the edge of their species' climatic distribution. However, interannual fruitbody productivity (truffle mass year -1 ) fell by a median loss of 22% for every 1°C increase in summer temperature over a site's 30-year mean. Among the most productive monitored populations, the temperature sensitivity was even higher, with single summer temperature anomalies of 3°C sufficient to stop fruitbody production altogether. Interannual truffle productivity was also related to the phenology of host trees, with ~22 g less truffle mass for each 1-day reduction in the length of the tree growing season. Increasing summer drought extremes are therefore likely to reduce fruiting among summer truffle populations throughout Central Europe. Our results suggest that European T. aestivum may be a mosaic of vulnerable populations, sensitive to climate-driven declines at lower thresholds than implied by its species distribution model., (© 2022 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2022

6. Hidden fairy rings and males-Genetic patterns of natural Burgundy truffle (Tuber aestivum Vittad.) populations reveal new insights into its life cycle.

Author

Staubli F, Imola L, Dauphin B, Molinier V, Pfister S, Piñuela Y, Schürz L, Sproll L, Steidinger BS, Stobbe U, Tegel W, Büntgen U, Egli S, and Peter M

Subjects

Humans, Male, Animals, Symbiosis, Life Cycle Stages, Ascomycota genetics, Mycorrhizae genetics

Abstract

Burgundy truffles are heterothallic ascomycetes that grow in symbiosis with trees. Despite their esteemed belowground fruitbodies, the species' complex lifecycle is still not fully understood. Here, we present the genetic patterns in three natural Burgundy truffle populations based on genotyped fruitbodies, ascospore extracts and ectomycorrhizal root tips using microsatellites and the mating-type locus. Distinct genetic structures with high relatedness in close vicinity were found for females (forming the fruitbodies) and males (fertilizing partner as inferred from ascospore extracts), with high genotypic diversity and annual turnover of males, suggesting that ephemeral male mating partners are germinating ascospores from decaying fruitbodies. The presence of hermaphrodites and the interannual persistence of a few males suggest that persistent mycelia may sporadically also act as males. Only female or hermaphroditic individuals were detected on root tips. At one site, fruitbodies grew in a fairy ring formed by a large female individual that showed an outward growth rate of 30 cm per year, with the mycelium decaying within the ring and being fertilized by over 50 male individuals. While fairy ring structures have never been shown for truffles, the genetics of Burgundy truffle populations support a similar reproductive biology as those of other highly prized truffles., (© 2022 The Authors. Environmental Microbiology published by Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2022

7. Eco-archaeological excavation techniques reveal snapshots of subterranean truffle growth.

Author

Büntgen U, Peter M, Tegel W, Stobbe U, Elburg R, Sproll L, Molinier V, Čejka T, Isaac EL, and Egli S

Subjects

Germany, Seasons, Mycorrhizae

Abstract

Despite its status as a highly-prized and coveted fungi in gastronomy, many aspects of the subterranean life cycle of the Burgundy truffle (Tuber aestivum) are still unknown, because in situ observations of the formation and maturation of truffle fruitbodies remain difficult. Here, we adopted a suite of archaeological fine-scale excavating techniques to provide unique spatiotemporal snapshots of Burgundy truffle growth at three sites in southern Germany. We also recorded the relative position, fresh weight, maturity level and genotype composition of all excavated fruitbodies. Varying by a factor of thousand, the fresh weight of 73 truffle ranged from 0.1 to 103.2 g, with individual maturity levels likely representing different life cycle stages from completely unripe to fully ripe and even decaying. While only a slightly positive relationship between fruitbody weight and maturity level was found, our results suggest that genetically distinct specimens can exhibit different life cycle stages at the same period of time and under the same environmental conditions. We therefore argue that truffles are likely able to grow, mature and ripe simultaneously between early summer and late winter of the following year. Our case study should encourage further eco-archaeological truffle excavations under different biogeographic settings and at different seasons of the year to gain deeper insights into the fungi's subterranean ecology. The expected cross-disciplinary findings will help truffle hunters and farmers to improve their harvest practices and management strategies., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Crown Copyright © 2021. Published by Elsevier Ltd. All rights reserved.)

Published

2021

8. New Insights into the Complex Relationship between Weight and Maturity of Burgundy Truffles (Tuber aestivum).

Author

Büntgen U, Bagi I, Fekete O, Molinier V, Peter M, Splivallo R, Vahdatzadeh M, Richard F, Murat C, Tegel W, Stobbe U, Martínez-Peña F, Sproll L, Hülsmann L, Nievergelt D, Meier B, and Egli S

Subjects

Hungary, Soil, Switzerland, Symbiosis, Ascomycota growth & development, Fruiting Bodies, Fungal growth & development, Life Cycle Stages

Abstract

Despite an increasing demand for Burgundy truffles (Tuber aestivum), gaps remain in our understanding of the fungus' overall lifecycle and ecology. Here, we compile evidence from three independent surveys in Hungary and Switzerland. First, we measured the weight and maturity of 2,656 T. aestivum fruit bodies from a three-day harvest in August 2014 in a highly productive orchard in Hungary. All specimens ranging between 2 and 755 g were almost evenly distributed through five maturation classes. Then, we measured the weight and maturity of another 4,795 T. aestivum fruit bodies harvested on four occasions between June and October 2015 in the same truffière. Again, different maturation stages occurred at varying fruit body size and during the entire fruiting season. Finally, the predominantly unrelated weight and maturity of 81 T. aestivum fruit bodies from four fruiting seasons between 2010 and 2013 in Switzerland confirmed the Hungarian results. The spatiotemporal coexistence of 7,532 small-ripe and large-unripe T. aestivum, which accumulate to ~182 kg, differs from species-specific associations between the size and ripeness that have been reported for other mushrooms. Although size-independent truffle maturation stages may possibly relate to the perpetual belowground environment, the role of mycelial connectivity, soil property, microclimatology, as well as other abiotic factors and a combination thereof, is still unclear. Despite its massive sample size and proof of concept, this study, together with existing literature, suggests consideration of a wider ecological and biogeographical range, as well as the complex symbiotic fungus-host interaction, to further illuminate the hidden development of belowground truffle fruit bodies., Competing Interests: Competing Interests: We have the following interests: István Bagi and Oszkár Fekete are employed by Truffleminers Ltd. However, there are no patents, products in development or marketed products to declare. This does not alter our adherence to all the PLOS ONE policies on sharing data and materials, as detailed online in the guide for authors.

Published

2017

9. Fine-scale genetic structure of natural Tuber aestivum sites in southern Germany.

Author

Molinier V, Murat C, Baltensweiler A, Büntgen U, Martin F, Meier B, Moser B, Sproll L, Stobbe U, Tegel W, Egli S, and Peter M

Subjects

DNA, Fungal genetics, Fruiting Bodies, Fungal, Genes, Mating Type, Fungal genetics, Genetic Markers, Genetic Variation, Genotype, Germany, Ascomycota genetics, Mycorrhizae genetics

Abstract

Although the Burgundy truffle (Tuber aestivum) is an ectomycorrhizal fungus of important economic value, its subterranean life cycle and population biology are still poorly understood. Here, we determine mating type and simple sequence repeat (SSR) maternal genotypes of mapped fruiting bodies to assess their genetic structure within two naturally colonized forest sites in southern Germany. Forty-one genotypes were identified from 112 fruiting bodies. According to their mating types, the maternal genotypes were aggregated only in one population. Genotypic diversity of individuals that mostly were small and occurred in 1 out of 2 years of sampling was high. Although these results suggested a ruderal colonization strategy, some genets spread several hundred meters. This result indicates that, besides sexual spore dispersal, vegetative growth or spreading by mycelial propagules contributes to dissemination. In one site, fewer individuals with a tendency to expand genets belonging to only one genetic group were observed. In the second site, numerous small individuals were found and were grouped into two clearly differentiated genetic groups that were spatially intermingled. Forest characteristics and disturbances are possible reasons for the observed genetic patterns. Our findings contribute to a better understanding of the biology of one of the most widespread and commercially important truffle species. This knowledge is critical for establishing and maintaining sustainable long-term truffle cultivations.

Published

2016

10. New evidence for the symbiosis between Tuber aestivum and Picea abies.

Author

Stobbe U, Stobbe A, Sproll L, Tegel W, Peter M, Büntgen U, and Egli S

Subjects

Germany, Ascomycota physiology, Mycorrhizae physiology, Picea microbiology, Symbiosis

Abstract

The Burgundy truffle (Tuber aestivum Vittad.), an ectomycorrhizal fungus living in association with host plants, is one of the most exclusive delicacies. The symbiosis with deciduous oak, beech, and hazel dominates our concept of truffle ecophysiology, whereas potential conifer hosts have rarely been reported. Here, we present morphological and molecular evidence of a wildlife T. aestivum symbiosis with Norway spruce (Picea abies Karst.) and an independent greenhouse inoculation experiment, to confirm our field observation in southwest Germany. A total of 27 out of 50 P. abies seedlings developed T. aestivum ectomycorrhizae with a mean mycorrhization rate of 19.6 %. These findings not only suggest P. abies to be a productive host species under suitable biogeographic conditions but also emphasize the broad ecological amplitude and great symbiotic range of T. aestivum. While challenging common knowledge, this study demonstrates a significant expansion of the species' cultivation potential to the central European regions, where P. abies forests occur on calcareous soils.

Published

2013

11. Potential and limitations of Burgundy truffle cultivation.

Author

Stobbe U, Egli S, Tegel W, Peter M, Sproll L, and Büntgen U

Subjects

Europe, Plants microbiology, Ascomycota growth & development, Food Microbiology methods, Mycorrhizae growth & development

Abstract

Burgundy truffles (Tuber aestivum syn. Tuber uncinatum) are the highly prized fruit bodies of subterranean fungi always occurring in ectomycorrhizal symbiosis with host plants. Successful cultivation can be achieved through artificial mycorrhization and outplanting of mostly oaks and hazel on suitable terrain. Here, we review ecological requirements, the influence of environmental factors, and the importance of molecular techniques for a successful cultivation of T. aestivum across Europe. The historical background and current knowledge of T. aestivum cultivation are discussed in light of its socioeconomic relevance.

Published

2013