Tag: fungi

From Spider Silk to Science: A New Way to Access Hidden Fungal Diversity

A new study suggests that spider webs can serve as natural, non-destructive collectors of fungal material in agricultural ecosystems.

A new study published in the open-access Biodiversity Data Journal suggests that spider webs – particularly those incorporating environmental debris – can serve as natural, non-destructive collectors of fungal material in agricultural ecosystems. The findings show that viable fungi can be recovered from these structures, including lineages that may represent previously undocumented diversity.

“Spider webs are often overlooked structures in the environment, yet they can function as natural collectors of biological material. Our findings suggest that they can be used as a complementary approach to access microbial communities without disturbing the surrounding ecosystem.”

Thanakron Into (Student at Thammasat University)

Researchers from Thammasat University and the National Center for Genetic Engineering and Biotechnology (BIOTEC), Thailand, investigated whether the adhesive and particle-trapping properties of spider silk could be used to capture and culture fungi associated with airborne and environmental particles. Unlike DNA-based methods, which detect genetic material regardless of viability, this approach allows for the recovery of living organisms that can be further studied.

The study focused on tropical rice fields, using webs of the orb-weaving spider Cyclosa mulmeinensis, a species known for constructing distinctive “trashline” decorations – linear accumulations of plant fragments, insect remains, and other debris within the web. These structures can intercept a variety of particles, some of which may carry fungal propagules.

Representative orb webs of Cyclosa mulmeinensis illustrating web architecture and debris decoration. Image credit: Thanakron Into et al.

Webs were collected from rice-field embankments in Pathum Thani, Nakhon Nayok, and Phetchaburi provinces using sterile techniques. In the laboratory, material retained on the silk was gently removed and cultured, yielding 112 viable fungal isolates. These isolates were grouped into 23 taxa across six genera, including Alternaria, Aspergillus, Cladosporium, Fusarium, Penicillium, and Talaromyces.

“We were particularly surprised that many of the fungi recovered from the webs remained viable and could be cultured. This enables further investigation beyond presence or absence, including their biological characteristics.”

Thanakron Into
Locations of paddy fields where Cyclosa mulmeinensis spider webs were collected in Thailand (left). Composition of culturable fungal taxa across genera in individual sampled webs, expressed as the number of taxa recovered per web (right). Image credit: Thanakron Into et al.

Some genetic lineages – particularly within Cladosporium and Talaromyces – did not match currently described species in available databases, indicating that additional, undocumented diversity may be present in these systems.

Conventional approaches to fungal monitoring typically rely on soil, air, or plant sampling, or on molecular methods that may not distinguish between living and non-living material. In this context, spider webs may provide a useful supplementary sampling surface for capturing biologically relevant particles.

Because spider webs are naturally maintained and, in some species, periodically rebuilt, this method can be applied with minimal disturbance to both the organisms and their environment. Importantly, the spiders themselves were not harmed during sampling, as only small sections of the web were collected.

“The ability to recover living fungi from these naturally occurring structures adds a practical dimension to biodiversity studies. It provides a way to link environmental sampling with downstream biological work.”

Thanakron Into

The idea that something as familiar as a spider web could quietly capture a hidden layer of biodiversity highlights how much of the natural world remains overlooked in plain sight.

While further work is needed to evaluate how broadly this approach can be applied, the study demonstrates the potential of spider webs as an additional tool for exploring microbial diversity in agricultural landscapes. 

Diagram displaying an overview of the study. Image credit: Booppa Petcharad.

Original source:

Into T, Petcharad B, Boonyuen N, Chanklan R, Pannanusorn S, Mongkolsamrit S, Kobmoo N, Nuankaew S, Kwanthong P (2026) Spider webs as reservoirs of culturable fungal diversity: evidence from orb-weaving Cyclosa mulmeinensis spider in Thai rice agroecosystems. Biodiversity Data Journal 14: e187035. https://doi.org/10.3897/BDJ.14.e187035

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Inside the Hidden World of Spider-Attacking Fungi

Newly discovered groups of “zombie” fungi have been found to mummify spiders and adapt their physical forms.

Deep within the humid leaf litter of China and the dense canopies of Brazil’s Atlantic Forest, a silent ambush unfolds. 

While we often think of spiders as the ultimate predators of the undergrowth, they have an arch-nemesis: araneopathogenic fungi. These “zombie” fungi are capable of parasitising spiders by hijacking their bodies and consuming them from the inside out.

Two studies published in the open-access peer-reviewed scientific journals MycoKeys and IMA Fungus, respectively, offer insight into this macabre world of spider assassins.

In Southeast Asia, researchers led by Chen-xin Chang of the Guizhou University of Traditional Chinese Medicine have identified three new species of Gibellula fungi in China and Laos, which erupt from spiders in branch-like structures: Gibellula pseudopigmentosa, Gibellula pseudosolita, and Gibellula sinensis. These species are distinguished from one another by their slight variations in sexual reproductive structures and morphology. The below figure displays morphological plates, showing the three fungi species at both a macroscopic and microscopic level – notice their unique conidial heads and spore arrangements, coloured in blue.

  • Morphologies of Gibellula pseudopigmentosa, Gibellula pseudopigmentosa, Gibellula pseudosolita, and Gibellula sinensis. Photo credit: Chang et al.

To identify new species of spider-pathogenic fungi, the research group conducted field surveys in the forest leaf of China and Laos, where they collected specimens for detailed laboratory study. A combination of traditional microscopy and modern DNA sequencing rendered the discovery possible. The fungi’s sighting in Laos is particularly significant because it provides the first formal record of the Gibellula genus in the region. 

This study – published in MycoKeys – therefore serves to fill a major distributional gap in Southeast Asia, as well as expand our understanding of the morphological diversity within this group of spider-pathogenic fungi.

Meanwhile, in Brazil, a study led by Joao Paulo Machado De Araújo of the University of Copenhagen and the Royal Botanic Gardens of Kew, published in IMA Fungus, described a new species of Purpureocillium fungus belonging to the Purpureocillium atypicola group: Purpureocillium atlanticum. This fungus specifically targets trapdoor spiders inhabiting burrows on the forest floor, where it mummifies the host in white mycelia and subsequently emerges from its cephalothorax in the form of a purple fruiting body. 

The discovery was notably featured in The Guardian, where it was placed alongside other unusual botanical and fungal discoveries compiled by the Royal Botanic Gardens, Kew.

Phylogeny of hypocrealean fungi (A), highlighting the Purpureocillium atypicola complex (B) and morphology of the new species, P. atlanticum (C–G). Photo credit: Araújo et al.

Purpureocillium atypicola was originally recorded in Japan by Yasuda (1894), and was thought to be a single species found all over the world for over a century. The discovery of the Purpureocillium atlanticum in Brazil is significant because it finally confirms that Purpureocillium atypicola is actually a global complex of many unique species. 

To identify this new fungus, De Araújo’s research group used taxogenomics, a method which entailed bringing portable DNA sequencing gear directly into the Brazilian rainforest. By analysing the genetic code of the fungus and its environment immediately in the field, they were able to identify the specimen within just four days as opposed to waiting months for traditional lab results.

Both of these studies highlight the impressive diversity of spider-pathogenic fungi across distinct global environments. They additionally reveal the different evolutionary strategies of their respective species – while Purpureocillium atlanticum has adapted to infect underground trapdoor spiders by producing purple stalks to escape burrows, the Gibellula species represent the most diverse genus of spider parasites, found primarily in forest debris. 

As researchers continue to map these complex ecological networks, it becomes clear that preserving threatened biomes, including the Atlantic Forest and the jungles of Southeast Asia, is critical to expanding our knowledge in fungal taxonomy.

Original studies: 

Araújo JPM, Przelomska NAS, Smith RJ, Drechsler-Santos ER, Alves-Silva G, Martins-Cunha K, Hosoya T, Luangsa-ard JJ, Perrigo A, Repullés M, Matos-Maraví P, Woods R, Pérez-Escobar OA, Antonelli A (2025) A new species of Purpureocillium (Ophiocordycipitaceae) fungus parasitizing trapdoor spiders in Brazil’s Atlantic Forest and its associated microbiome revealed through in situ “taxogenomics”. IMA Fungus 16: e168534. https://doi.org/10.3897/imafungus.16.168534

Chang C-xin, Chen H, Loinheuang C, Dai Y-dong, Wang Y (2026) Morphological and phylogenetic analyses reveal three new species of Gibellula (Cordycipitaceae, Hypocreales) from spiders. MycoKeys 127: 135-154. https://doi.org/10.3897/mycokeys.127.177871

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Using AI to Uncover the Secret Lives of Fungi

AI holds the potential to automatically identify fungal versatility from the available scientific literature.

Fungi are the hidden architects of our ecosystems, acting as everything from helpful partners for plants to aggressive decomposers that recycle dead wood. However, many fungi don’t stick to just one job; they can switch lifestyles depending on their environment.  

Understanding this flexibility is vital for predicting how forests and farms will react to climate change. Unfortunately, the information researchers need is buried in decades of scientific papers that would take too long to comb through manually. 

A new study led by Northern Arizona University doctoral student Beatrice M. Bock and published in the open-access journal Research Ideas and Outcomes demonstrates how AI can solve this problem. By using a specialized language model called BioBERT, Bock developed an automated workflow that assesses scientific abstracts and accurately identifies whether a fungus has a single lifestyle or a dual, flexible one. 

A high-accuracy hack 

Bock said that for years, mycologists have relied on manual databases to track what different fungi do in the environment. While these tools are essential, they are difficult to keep updated as new research is published every day. 

“Manually identifying fungal versatility from the literature is time-consuming and difficult to scale. By using machine learning, we can now scan thousands of papers in just a few minutes to flag species that might be switching roles—such as a fungus that normally helps a plant grow but also turns into a decomposer when the plant dies.” 

Beatrice M. Bock

The pilot study tested four different AI models to see which was best at understanding the nuances of biological language. The top-performing model, BioBERT, achieved nearly 90% accuracy in identifying fungal lifestyles. 

What did BioBERT have that the other models didn’t? For one, it had the power of capitalization. Bock found that “cased” models—those that recognize capital letters—performed significantly better than those that did not. That’s likely because capital letters often signal species’ scientific names, like Fusarium, which are crucial for AI to understand the context of the research. 

The path ahead 

Bock said that in a commitment to transparency, she has made all the code and data available for free online, allowing other scientists to build upon her work and track traits in other organisms, like insects or plants. 

While Bock’s study focused on a small group of papers as a proof-of-concept, it opens the door for much larger projects. Future versions of the tool could predict how a fungus’s behavior might change under specific environmental conditions, such as drought or extreme heat. 

“As fungal trait databases continue to grow in importance for biodiversity assessments, automated text mining offers a path toward more efficient, consistent and comprehensive trait annotation.”

Beatrice M. Bock

Original sources:

Bock B (2026) Automated extraction of fungal trophic modes from literature using BioBERT: an open pilot workflow. Research Ideas and Outcomes 12: e176590. https://doi.org/10.3897/rio.12.e176590

Story originally published by: EurekAlert! (2026). Using AI to uncover the secret lives of fungi. [online] Available at: https://www.eurekalert.org/news-releases/1114462 [Accessed 2 Feb. 2026]. Republished with permission.

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Life on Mars? Lichens survive Martian simulation

Previously presumed uninhabitable, the Martian surface may be suitable for certain lichen species.

A thin atmosphere, freezing temperatures, and a barrage of radiation: the surface of Mars is hardly a prime holiday destination. But can any life survive there?

Known for their extreme tolerance to harsh environments such as Earth’s deserts and polar regions, lichens have long been considered a leading candidate for Martian survival. And, for the first time, researchers have demonstrated that certain species can survive Mars-like conditions, including exposure to ionising radiation, while maintaining a metabolically active state.

Published in the open-access journal IMA Fungus, a new study highlights the potential for lichens to survive and function on the Martian surface, challenging previous assumptions that the planet is uninhabitable.

Annotated design showing the set up of the experiment subjecting lichens to Mars-like conditions.
Experiment arrangement of vacuum chamber with the additional facility, including metal grate with lichens, cooling table, temperature, pressure and humidity sensors, X-ray lamp with the controller, CO2 valve with cylinder, controllers of vacuum chamber, pressure, cooling table, and computer.

But what exactly are lichens? It’s a little complicated. In fact, lichens are not a single organism, but rather a symbiotic association between a fungus and algae and/or cyanobacteria.

In this study, the fungal partner in lichen symbiosis remained metabolically active when exposed to Mars-like atmospheric conditions in darkness, including X-ray radiation levels expected on Mars over one year of strong solar activity.

Macro photograph of a lichen species.
Cetraria aculeata.

The research focuses on two lichen species (yes, there are lichen species despite them being a symbiosis), Diploschistes muscorum and Cetraria aculeata, selected for their differing traits. The lichens were exposed to Mars-like conditions for five hours in a simulation of the planet’s atmospheric composition, pressure, temperature fluctuations, and X-ray radiation.

The findings suggest that lichens, particularly D. muscorum, could potentially survive on Mars despite the high doses of X-ray radiation associated with solar flares and energetic particles reaching the planet’s surface. These results challenge the assumption that ionising radiation is an insurmountable barrier to life on Mars and set the stage for further research on the potential for extraterrestrial microbial and symbiotic survival.

“Our study is the first to demonstrate that the metabolism of the fungal partner in lichen symbiosis remained active while being in an environment resembling the surface of Mars. We found that Diploschistes muscorum was able to carry out metabolic processes and activate defense mechanisms effectively. 

“These findings expand our understanding of biological processes under simulated Martian conditions and reveal how hydrated organisms respond to ionizing radiation – one of the most critical challenges for survival and habitability on Mars. Ultimately, this research deepens our knowledge of lichen adaptation and their potential for colonizing extraterrestrial environments.”

Lead author of the paper, Kaja Skubała.

Further long-term studies investigating the impact of chronic radiation exposure on lichens have been recommended, as well as experiments assessing their survival in real Martian environments. 

Researchers from Jagiellonian University and the Space Research Centre of the Polish Academy of Sciences conducted the study with support from the National Science Centre, Poland, and the “Excellence Initiative – Research University” at the Faculty of Biology, Jagiellonian University.

Original study

Skubała K, Chowaniec K, Kowaliński M, Mrozek T, Bąkała J, Latkowska E, Myśliwa-Kurdziel B (2025) Ionizing radiation resilience: how metabolically active lichens endure exposure to the simulated Mars atmosphere. IMA Fungus 16: e145477. https://doi.org/10.3897/imafungus.16.145477

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Fungal Fairy Rings: the science behind the magic

Researchers explore the history, ecology, and impacts of these intriguing fungal formations.

A new review article published in the OA journal IMA Fungus sheds light on the phenomenon of fungal fairy rings, mysterious circular patterns of altered vegetation found in grasslands and forests. 

In the review, researchers Maurizio Zotti, Giuliano Bonanomi, and Stefano Mazzoleni from the University of Naples Federico II explore the history, ecology, and impacts of these intriguing fungal formations.

Fungal fairy rings (FFRs), they explain, occur when certain fungi grow radially outward through the soil from a central point, breaking down organic matter and affecting plant growth in distinctive circular patterns. While folklore once attributed these rings to magic, scientists now understand them as a natural process driven by underground fungal activity.

Cross-section of a fungal fairy ring (FFR) transect providing a visual representation of the mycelial mat distribution in the soil, with arrows representing growth direction.

In their paper, the researchers synthesise centuries of research on FFRs, from early observations in the 1800s to modern studies using cutting-edge genomic techniques. “The study of FFRs provides a valuable opportunity to delve deeper into the complex field of soil and fungal ecology, bridging multiple scientific disciplines such as mycology, microbiology, chemistry and botany,” they write.

Describing how different types of FFRs form and expand over time, the authors note that some persist for hundreds of years, reaching massive sizes: “In French grasslands, large FFRs of I. geotropa, with a diameter of 800 m, were estimated to be around 700 years old.”

Fungal fairy rings on grasslands.
FFRs of Agaricus crocodilinus in Monte Pratello subalpine grassland, Rivisondoli, Abruzzo, Italian Apennines. (Photo by Franco Carnevale).

The effects of FFRs vary substantially. Indeed, the study explores the various ways FFRs impact soil properties and plant communities as they spread. In some cases, the fungal activity leads to lush green rings of stimulated plant growth. In others, it causes bands of dead or stunted vegetation. 

FFRs don’t just affect plants; they also influence soil microbes. The review describes how “the development of FFR mycelial mats is associated with a general simplification of the bacterial community” in some cases, while other studies have found increased microbial diversity within fairy rings.

Fungal fairy ring examples.
FFR examples (left) and a comparison of soil densely occupied by mycelial mat vs. unaffected soil (right).

The researcher team emphasises that there is still much to learn about the ecological roles and formation mechanisms of FFRs. Several promising areas should be explored in future research, including investigating the volatile compounds produced by fairy ring fungi and using advanced sequencing methods to unravel how FFRs regulate species coexistence in soil and plant communities.

Concluding the study the authors assert that, while improved knowledge of FFRs may have removed some of their mystical aura, “such removal of thin magic halo has certainly not reduced the wonder for the beauty of nature in its ever surprisingly dynamic pattern and intertwined complex systems.”

Read the full research paper here.  

Original source

Zotti M, Bonanomi G, Mazzoleni S (2025) Fungal fairy rings: history, ecology, dynamics and engineering functions. IMA Fungus 16: e138320. https://doi.org/10.3897/imafungus.16.138320

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Top 10 new species of 2024

A countdown of our top 10 favourite species described as new to science in our journals this year.

2024 is almost over—can you believe it?

If you follow any of Pensoft’s social media accounts, you will know that we have been counting down our top 10 favourite species described as new-to-science in our journals this year.

The list is—of course—entirely arbitrary, but it is also a fun way to look back on a year in which several weird and wonderful animals, plants and fungi were discovered.

In this blog post, we will tell you more about each species, share some honourable mentions, and reveal our number 1 spot!

Honourable mentions

The league of legends crab

Gothus teemo and Teemo.

When it was time to name a tiny, ‘furry’ new species of gorilla crab from China, researchers drew unlikely inspiration from the video game League of Legends.

Gothus teemo was named after the character Teemo thanks to its distinctive appearance and has drawn a lot of attention from fans of the franchise.

Top-lane crab: new species named after League of Legends character

Published in Zoosystematics and Evolution.

the ancient shark

The new species is thought to have resembled a modern sandtiger shark (pictured).

Calling anything on this list a ‘new species’ is not accurate—rather, they are just new to published science. Nothing exemplifies this more than Palaeohypotodus bizzocoi, a long-extinct shark species that lived 65 million years ago, shortly after the fall of the dinosaurs.

What makes this discovery remarkable is that it was partially accidental. Find out how a 100-year-old box of teeth in Alabama led to the discovery of this ancient shark below.

New species of 65-million-year-old shark ‘accidentally’ discovered in Alabama

Published in Fossil Record.

the drone-discovered plant

Sometimes, it is the way in which a new species is discovered that makes it so special.

Such is the case for Schiedea waiahuluensis, a carnation species from Hawaii that is likely the first plant to be identified and collected using drone technology. Learn all about it below!

Botany from above: drone discovers new plant species in Hawaii

Published in PhytoKeys.

Top 10 new species of 2024

10: the crocodile newt

Tylototriton gaowangjienensis.

With its all-black colouration, Tylototriton gaowangjienensis, a crocodile newt from China, has drawn comparisons to Toothless from How to Train Your Dragon.

However, this alluring amphibian hides flashes of orange beneath its tail and toes! Find more pictures and information below.

Published in Herpetozoa.

9: the border-hopping bee

New bee species.
Male Hoplitis onosmaevae with unfolded proboscis.

Besides its adorable appearance, Hoplitis onosmaevae is remarkable due to its distribution. It is currently only known from a small region of the French Alps, and areas >2,000 km away in the mountains of Turkey and Iraq.

Another interesting aspect of Hoplitis onosmaevae is its specialised ecological niche: it is thought to only collect pollen from Onosma species. This narrow ecological niche makes it vulnerable to factors like climate change and changes in agricultural practices.

Rare bee species discovery links the French Alps to Turkey and Iraq

Published in Alpine Entomology.

8: the dung fungus

Metacampanella coprophila

Metacampanella coprophila is one of two new species described in a recent MycoKeys paper! Known from Mongolia, it grows in sheep dung in the summer.

Metacampanella is an important, recently defined genus in the Marasmiaceae family, expected to expand with future studies.

Published in MycoKeys.

7: the miracle plant

John L. Clark with Amalophyllon miraculum. Credit @phinaea on Instagram.

The discovery of Amalophyllon miraculum—in an area assumed to be a barren agricultural landscape of plant extinctions—represents an inspiration for biodiversity conservation. This “miracle” plant, as its name suggests, was found surviving in one of the small, isolated forest fragments that remain in the Centinela region of western Ecuador.

¡Que Vive Centinela! A tiny new plant species reaffirms the “miraculous” survival of Western Ecuador’s ravished biodiversity

Published in PhytoKeys.

6: the spiky frog

Pristimantis normaewingae.

This spiky amphibian was discovered on Cerro Candelaria, a mountain in the Tungurahua province. The discovery of this new species in the upper Rio Pastaza watershed suggests this area might be a centre of rapid evolution for these fascinating frogs.

Published in Evolutionary Systematics.

5: the giant tiny beetle

Clavicornaltica mataikanensis.

Entomologists and citizen scientists teamed up to discover this new species of flea beetle in the lush rainforests of Borneo. The discovery was made during a Taxon Expeditions trip, where non-scientist people got the chance to work alongside scientists to identify and describe new species.

What makes this discovery particularly exciting is the beetle’s size—it’s actually one of the largest among its relatives! Flea beetles that live in the leaf litter of tropical forests are typically much smaller, and as a result, we know very little about their ecology and diversity.

“Tiny, beautiful, and completely unknown animals”: Citizen scientists discover new beetles from the Borneo forest

Published in Biodiversity Data Journal.

4: the grumpy dwarf goby

A photograph of a red grumpy-looking fish on a black background.
The grumpy dwarf goby, Sueviota aethon.

Discovered in the Red Sea, the ‘grumpy dwarf goby’ (Sueviota aethon) was published as a new species in ZooKeys. You can probably guess how it earned its name! This tiny fish, measuring less than 2 centimetres long, sports a permanent frown thanks to its large canines and fierce expression. Despite its small size, the grumpy dwarfgoby is thought to be a fearsome predator in its coral reef habitat.

New ‘grumpy’ fish species discovered in the Red Sea

Published in ZooKeys.

3: the sun-shunning plant

Thismia malayana.

Thismia malayana is a mycoheterotrophic plant, meaning it doesn’t photosynthesise. Instead, it acts as a parasite, stealing carbon resources from the fungi on its roots!

By stealing nutrients from fungi, it can thrive in the low-light conditions of dense forest understories where its highly specialised flowers are pollinated by fungus gnats and other small insects.

Sun-shunning thief: new plant species robs underground fungi to survive

Published in PhytoKeys.

2: the ‘cute but deadly’ velvet worm

While the Tiputini velvet worm—Oroperipatus tiputini—may look friendly, it is an accomplished hunter that shoots a sticky substance from a pair of glands to trap its prey. This “living fossil” is a rare and unique invertebrate that evolved over 500 million years ago. The new species was discovered in the Ecuadorian Amazon at the Tiputini Biodiversity Station, which is part of the Yasuní Biosphere Reserve.

Cute but deadly: a new velvet worm species from Ecuador

Published in Zoosystematics and Evolution.

1: the starry night gecko

Here it is, our number 1 spot!

They say that life imitates art, and this new gecko species proves that to be true! Researchers in India have discovered a gecko with such a unique and beautiful colouration that they named it after painter Vincent van Gogh. The “Starry Night” gecko, or Cnemaspis vangoghi, was discovered in the Southern Western Ghats and stands out due to the male’s yellow head and forebody with light blue spots on the back, a striking combination reminiscent of the famous painting.

Discovering Van Gogh in the wild: scientists unveil a new gecko species

Published in ZooKeys.

Truffles and tulips: Pensoft and the 12th International Mycological Congress

Over 1,000 fungi enthusiasts gathered in Maastricht for the biggest mycology event of the year.

The Pensoft team had a fantastic time at the 12th International Mycological Congress in Maastricht, the Netherlands.

Organised by the International Mycological Association, together with the Dutch Mycological Society and the Westerdijk Fungal Biodiversity Institute, the four-day meeting saw around 1,400 fungi fanatics gather for the biggest mycology event of the year.

It all began with an opening ceremony complete with live music and stunning visuals, which set the stage for five days of research exchange and collaboration.

Pensoft welcomed faces new and old at a decorated stand featuring numerous illustrated materials designed by scientific illustrator Denitsa Peneva. Manning the stand were Prof Dr Lyubomir Penev (MycoKeys Founding Editor & Pensoft Founder and CEO) and Slavena Peneva (Pensoft Head of Graphic Design).

MycoKeys materials esigned by Denitsa Peneva.
Urmas Kõljalg and Lyubomir Penev.
Lyubomir Penev, Dmitry Schigel and Slavena Peneva.

The booth hosted a special gathering for MycoKeys editors, including Editor-in-Chief Prof Dr Thorsten Lumbsch, who were shown a video looking back on the history of the journal. Many long-time collaborators of Pensoft, such as Prof Dr Urmas Kõljalg of Pluto F and Dr Dmitry Schigel of Pluto F, also dropped by to say hello.

The congress provided the perfect opportunity to announce Pensoft’s new, exciting partnership with the International Mycological Association. This collaboration will see the IMAFungus journal move to the ARPHA platform, where it will benefit from cutting-edge publishing technology and workflows.

Several MycoKeys contributors presented and hosted keynote lectures, bridging sessions, and workshops across the seven major topics of the conference:

  • Cell biology, biochemistry and physiology
  • Environment, ecology and interactions
  • Evolution, biodiversity and systematics
  • Fungal pathogenesis and disease control
  • Genomics, genetics and molecular biology
  • Applied Mycology
  • Nomenclature

The full program can be found on the congress website.

The next International Mycology Congress will be held in Incheon, South Korea, in 2027. IMC13 already has an active website and the Pensoft team look forward to another exciting installment!

***

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Do all fungi matter? Yes, new study argues

Fungi that do not form fruiting bodies and that we cannot grow in the laboratory cannot be given scientific names. Does it make sense to ignore them?

Mention fungi, and most people will probably think of the mushrooms they pick in fall, or maybe the yeast they add when baking or making wine. Others will perhaps recall last week’s mouldy bread – or cucumbers gone bad in the refrigerator. Indeed, mycologists have studied these fungi as sources of food and fermentation but also decay and disease for centuries.

Sampling soil and sediments for fungal diversity not far from Göteborg, Sweden. Photo by Henrik Nilsson

But while we’re used to thinking of fungi as organisms that form physical structures such as fruiting bodies, or yeast-like life forms that we can grow in our kitchens or laboratories, it is gradually becoming clear that fungi don’t readily assort into only these two groups. DNA sequencing studies of environmental substrates such as soil are finding massive evidence of large groups of fungi that do not seem to form fruiting bodies and that we seem unable to grow in the lab – but that are there nonetheless. These groups are often called “dark fungi,” in analogy with the concept of “dark matter” in astronomy – something we know is out there, but that we cannot directly observe right now.

A new study in MycoKeys contrasts the accumulation of fungal species recovered using traditional mycological approaches with those recovered using environmental DNA sequencing over time. Even when allowing for various kinds of biases, the authors found that species discovery through environmental sequencing vastly outpaces traditional species recovery in a strongly increasing trend over the last five years. The authors conclude that dark fungi form a defining feature of the fungal kingdom.

Field work on the Tibetan Plateau. Photo by Wengang Kang

“And that’s where it gets interesting”, Henrik Nilsson at the University of Gothenburg, Sweden, and the lead author of the study, says. “Under the current rules of nomenclature, these fungi cannot be given scientific names – they cannot be described formally. And species and groups that cannot be named formally, well, they tend to fall between the cracks. They’re typically not considered in nature conservation initiatives. They are often left out from efforts to estimate the evolutionary history of fungi, and their ecological roles and associations are largely overlooked when we try to figure out how mass and energy flow in ecosystems. They’re essentially treated as if they didn’t exist.”

Examining minute fungal fruiting bodies not far from Stockholm, Sweden. Photo by Kristina Stenmarck

Second author Martin Ryberg at the University of Uppsala, Sweden chimes in, “And it’s not like we’re adding the few missing pieces to an otherwise nearly complete jigsaw puzzle. It seems to be the other way around. We’re talking about tens of large groups of fungi – and thousands upon thousands of species, some of which seem to be so common that we have yet to find a soil sample from which they’re absent. Indeed, we’re talking about what could well prove to be the dominant life style in the fungal kingdom.”

The mycological community has been debating whether the rules of fungal nomenclature should be modified to allow formal description of these dark fungi. So far, the matter has not been resolved in the affirmative. “I think our study shows that it’s time to stop that debate, like, right away,” Nilsson says. “What we should be debating is how we should describe them. What criteria must be fulfilled for a dark fungus to be given a formal scientific name? Clearly, formation of a fruiting body or growth in the laboratory can’t be part of those criteria.”

Field work in New Caledonia. Photo by Sten Anslan

Co-author Alice Retter of the University of Vienna, Austria explains, “We figured we’d kickstart the how debate by listing criteria that we think make sense – criteria that would be stringent enough to allow for only particularly well-vetted dark fungi to be described, upholding a high level of scientific rigor and reproducibility in the process. We blended our own observations with suggestions from the mycological community, culled from depositing a preprint of the manuscript at bioRxiv. We’re certainly not claiming that our suggestions form the final word in the debate. It’s more like they’re the first. We’re thinking that the mycological community will jointly be able to come up with a set of sound guiding principles on the matter – and here comes an initial set of well-meaning observations for nucleation.”

Field work in the German Alps. Photo by Vanessa Schulz

The authors advocate gentle modifications to the nomenclatural rules governing the naming of fungi to allow giving formal names to at least the most well-documented species and groups of dark fungi. The suggested modifications would, at present, exclude many rare or otherwise less well-documented dark fungi from formal description.

“But you don’t have to have a theory of everything to have a theory of something,” senior author Kessy Abarenkov of the Tartu Natural History Museum, Estonia asserts. “By establishing rules for what’s needed to describe dark fungi, and specifying when we’ll have to refrain from describing such species at present, mycologists can do what they do best: doggedly gather enough research data to warrant naming of the dark fungi, group by group, and species by species. It’s what mycology has excelled at for hundreds of years. It’s just the setting that’s a bit new.”

Drying soil samples immediately upon collection under field conditions in Norway. Photo by Sten Anslan

Sten Anslan, University of Tartu, continues: “Much is at stake, obviously. The current rules governing the naming of fungi have served mycology well for a long time. We don’t want to upend or overthrow them. But we fear that if they’re not updated in this particular regard, there’s a risk that they grow increasingly obsolete over time. Having a book of rules that govern maybe only some few percent of the organisms it was originally conceived to govern – the fungal kingdom – would seem untenable in the long run.”

Getting ready for DNA extraction from soil samples. Photo by Sten Anslan

Marisol Sanchez-Garcia of the Swedish Agricultural University concludes: “The nomenclatural aspects of dark fungi will presumably be discussed at some length at next year’s international mycological congress in Maastricht, the Netherlands. We’re hopeful that the mycological community will reach meaningful agreement on integration of the dark fungi into the rules of nomenclature. After all, mycologists are used to negotiating and solving non-trivial questions on a day-to-day basis, and this one is hardly any different. Being part of tackling a huge, more or less unknown group of organisms where precious little is set in stone and where the rules will have to be adapted over time for the endeavour to stay attuned to recent developments, well, that’s what makes being a mycologist so interesting and rewarding in my eyes.”

Research article:

Nilsson RH, Ryberg M, Wurzbacher C, Tedersoo L, Anslan S, Põlme S, Spirin V, Mikryukov V, Svantesson S, Hartmann M, Lennartsdotter C, Belford P, Khomich M, Retter A, Corcoll N, Gómez Martinez D, Jansson T, Ghobad-Nejhad M, Vu D, Sanchez-Garcia M, Kristiansson E, Abarenkov K (2023) How, not if, is the question mycologists should be asking about DNA-based typification. MycoKeys 96: 143-157. https://doi.org/10.3897/mycokeys.96.102669

Cultivated and wild bananas in northern Viet Nam threatened by а devastating fungal disease

For over 100 years, Fusarium, one of the most important fungal plant pathogens, has affected banana production worldwide.

Fusarium is one of the most important fungal plant pathogens, affecting the cultivation of a wide range of crops. All over the world, thousands of farmers suffer agricultural losses caused by Fusarium oxysporum f. sp. cubense (referred to as Foc for short), which directly affects their income, subsistence, and nourishment.

As a soil-borne fungus, Foc invades the root system, from where it moves into the vascular tissue that gradually deteriorates, until eventually the plant dies. What makes it particularly hard to deal with is that, even 20 years after all infected plants and tissue are removed, spores of it still remain in the soil.

One industry significantly affected by Foc is global banana export, largely dependent on the cultivation of members of the Cavendish subgroup, which are highly susceptible to some of the Foc strains.

For over 100 years, the fungus has affected banana production worldwide. Researchers predict it will continue spreading intensively in Asia, affecting important banana-producing countries such as China, the Philippines, Pakistan, and Viet Nam.

For Viet Nam, predictions on the impact of Foc for the future are dramatic: an estimated loss in the banana production area of 8% within the next five years, and up to 71% within the next 25 years. In particular, the recent rise of the novel TR4 strain has resulted in worldwide anxiety about the future of the well-known Cavendish banana and many other cultivars. Fusarium oxysporum f. sp. cubense is, however, not limited to TR4 or other well-known strains, like Race 1 or Race 2; it is a species complex that plant pathologists are yet to fully disentangle. 

In Viet Nam, like in the rest of Asia, Africa, Latin America, and the Caribbean, most bananas are consumed and traded locally, supporting rural livelihood. This means that any reduction in crop harvest directly affects local people’s income and nourishment. 

It has thus become necessary to find out what are the individual species causing the Fusarium wilt among Vietnamese bananas. Only by understanding which species are infecting the cultivated bananas can concrete measures be taken to control the future spreading of the disease to other regions.

Using DNA analyses and morphological characterization, an international team of researchers from Viet Nam (Plant Resources Center, Vietnam National University of Agriculture), Belgium (Meise Botanic Garden, KU Leuven, Bioversity Leuven, MUCL) and the Netherlands (Naturalis Biodiversity Center) investigated the identity of the Fusarium wilt infections. They recently published their joint research in the open-access, peer-reviewed journal MycoKeys.

The study shows that approximately 3 out of 4 Fusarium infections of the northern Vietnamese bananas are caused by the species F. tardichlamydosporum, which can be regarded as the typical Race 1 infections. Interestingly, Foc TR4 is not yet a dominant strain in northern Viet Nam, as the species causing the disease – F. odoratissimum – only accounts for 10% of the Fusarium infections. A similar proportion of Fusarium infections is caused by the species Fusarium cugenangense – considered to cause Race 2 infections among bananas.More importantly, Fusarium wilt was not only found in cultivated bananas: the disease seemed to also affect wild bananas. This finding indicates that wild bananas might function as a sink for Fusarium wilt from where reinfections towards cultivars could take place.

Research article:

Le Thi L, Mertens A, Vu DT, Vu TD, Anh Minh PL, Duc HN, de Backer S, Swennen R, Vandelook F, Panis B, Amalfi M, Decock C, Gomes SIF, Merckx VSFT, Janssens SB (2022) Diversity of Fusarium associated banana wilt in northern Viet Nam. MycoKeys 87: 53-76. https://doi.org/10.3897/mycokeys.87.72941

Lifting the veil over mysterious desert truffles: Terfezia’s ecology and diversity towards cultivation

Developing below the soil surface, desert truffles are hard to find. Recently, researchers of the University of Évora updated the number of known species of the desert truffle genus Terfezia occurring in Portugal from three to ten species. They thoroughly characterized their ecological preferences, adding new knowledge on Terfezia’s cryptic lifestyle. These findings are of major importance, as desert truffles have a high economic value. The study was published in the open-access journal MycoKeys.

In a caring, symbiotic relationship, mycorrhizal fungi live and feed in the roots of specific plants, while providing water and nutrients to their ‘companion’. In arid and semi-arid environments, mycorrhization processes are essential to the survival of both plants and fungi. Moreover, the fungus’ hyphal network, which spreads within the soil connecting several plant individuals, is of utmost importance to enhancing soil quality and fertility.

Researchers of the University of Évora in Portugal, led by biologist Celeste Santos e Silva, worked on Terfezia fungi, the most diverse and species-rich genus among desert truffles. Their study, published in the open-access journal MycoKeys, might prove particularly valuable to rural populations in the Mediterranean basin, where desert truffles, highly valued in local markets, are an important food source. Increasingly turning into an exquisite component of the Mediterranean diet, Terfezia products can also be very profitable. Furthermore, these fungi are essential for soil conservation, preventing erosion and desertification.

Desert truffles.

After 8 years of exhaustive field exploration in search of desert truffles and many hours in the molecular biology lab, the researchers noted some previously unknown trends in the ecology of Terfezia species. They recorded seven species that were new to Portugal, including two that are new to science – Terfezia lusitanica and Terfezia solaris-libera. This brings the number of Terfezia species known to be growing in the country to ten. Particularly important was the discovery of a broader ecological range for many of the studied species (e.g. Terfezia grisea). Adding valuable information about their possible hosts, symbionts and ecological constraints, these findings help open new opportunities for truffle cultivation.

“It is very difficult to identify all specimens given that the Terfezia species look so much alike, and molecular biology was absolutely fundamental here”, explains the researcher. “The technique was essential to update and solve problems about their taxonomy and the relationship between the species in the genus.”

Furthermore, the discoveries are also expected to positively impact the local communities by stimulating agriculture produce, business and even employment. 

Desert truffle production explained. Video by University of Évora

Knowledge gained in this research about the conditions in which different Terfezia species grow is an important step to desert truffle cultivation: the fungi are hard to find in the wild, which is why it would make a big difference – including financially – for local communities if they figure out a way to grow truffles themselves.

Within the project “Mycorrhization of Cistus spp with Terfezia arenaria (Moris) Trappe and its application in the production of desert truffles” (ALT20-03-0145-FEDER-000006), the researchers took a step forward towards achieving mycorrhizal association of desert truffles with perennial plants (rock roses), which would allow their mass production for various sectors such as food, medicine and soil recovery. This new form of production, assures the MED researcher and leader of the project, “will make it possible to create more jobs, reversing the current trend towards desertification in rural areas, while being a great tool for ecosystem recovery and restoration”.

Research article:


Santos-Silva C, Louro R, Natário B, Nobre T (2021) Lack of knowledge on ecological determinants and cryptic lifestyles hinder our understanding of Terfezia diversity. MycoKeys 84: 1-14. https://doi.org/10.3897/mycokeys.84.71372