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The Chemical Ecology of the Fungus-Farming Termite Symbiosis

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The Chemical Ecology of the Fungus-Farming Termite Symbiosis Natural Product Reports View Article Online REVIEW View Journal The chemical ecology of the fungus-farming termite symbiosis† Cite this: DOI: 10.1039/d1np00022e Suzanne Schmidt, a Sara Kildgaard, a Huijuan Guo, b Christine Beemelmanns b and Michael Poulsen *a Covering: September 1972 to December 2020 Explorations of complex symbioses have often elucidated a plethora of previously undescribed chemical compounds that may serve ecological functions in signalling, communication or defence. A case in point is the subfamily of termites that cultivate a fungus as their primary food source and maintain complex bacterial communities, from which a series of novel compound discoveries have been made. Here, we summarise the origins and types of 375 compounds that have been discovered from the symbiosis over Creative Commons Attribution-NonCommercial 3.0 Unported Licence. the past four decades and discuss the potential for synergistic actions between compounds within the Received 1st April 2021 complex chemical mixtures in which they exist. We go on to highlight how vastly underexplored the DOI: 10.1039/d1np00022e diversity and geographic distribution of the symbiosis is, which leaves ample potential for natural product rsc.li/npr discovery of compounds of both ecological and medical importance. 1 Introduction 3.2.5 Alkaloids and N-containing heterocycles 2 The fungus-farming termite symbiosis 3.3 Bacterial symbionts 3 Natural products reported from the termite symbiosis 3.3.1 Polyketides This article is licensed under a 3.1 The fungus-farming termite host 3.3.2 Non-ribosomally synthesized peptides 3.1.1 Antimicrobial peptides 3.3.3 PKS–NRPS hybrids 3.1.2 Benzoquinones and sesquiterpenoids 3.4 Pseudoxylaria stowaway fungus 3.2 Termitomyces 3.5 Analysis of symbiont communities Open Access Article. Published on 19 August 2021. Downloaded 9/29/2021 2:07:25 PM. 3.2.1 Fatty acids 4 Prospects for defence potential and novel natural 3.2.2 Phenolic acids product discovery 3.2.3 Flavonoids 5 Author contributions 3.2.4 Terpenes and volatiles 6 Conicts of interest 7 Acknowledgements 8 Notes and references aSection for Ecology and Evolution, Department of Biology, University of Copenhagen, Universitetsparken 15, 2100 Copenhagen, Denmark. E-mail: [email protected] bLeibniz Institute for Natural Product Research and Infection Biology e.V., Hans-Knoll-¨ Institute (HKI), Beutenbergstraße 11a, 07745 Jena, Germany 1 Introduction † Electronic supplementary information (ESI) available: Table 1: a comprehensive overview of the 375 natural products that have been discovered from termites, Natural products represent structurally and functionally diverse Termitomyces, bacteria, complex communities and Pseudoxylaria. These natural molecules that exhibit a plethora of functional roles in signal- products were identied by an extensive screening of literature and is the rst ling, communication, or defence in the natural context within in-depth investigation into all natural products associated with this termite which they are produced.1,2 Hosts may produce their own symbiosis. The table includes molecular formula, mass, compound name, defensive compounds, while symbiont-derived natural products natural product class, termite host (when known), producing organism, country the source material was found in, method of identication and the articles that might serve as vital mediators between hosts and their antag- have discovered the compound from sources related to the fungus-growing onists by conferring protection directly through biological termites symbiosis. Subsequently, hundreds of articles were screened for activity3 or indirectly by stimulating host immune systems to antimicrobial activities linked to each individual natural product, or lack improve protection during infection.4 Despite increasing thereof. If possible, the presumed mode of action(s) and reported synergies are scientic interest, the precise functions of secreted natural indicated as are other known bioactivities. The references associated to products, their possible targets and modes of action, and bioactivities, mode of action and synergies are reported in the “Reference” column indicated by (no.). An asterisk (*) Indicates that the compound was synergies between compounds within complex chemical found from multiple symbiosis sources. See DOI: 10.1039/d1np00022e mixtures remain mostly unknown. In contrast, ecology and This journal is © The Royal Society of Chemistry 2021 Nat. Prod. Rep. View Article Online Natural Product Reports Review genome-mining driven exploration of complex host-symbiont ecology and pharmacological perspective. As both the fungus- associations using state-of-the-art analytical dereplication growing termite and ant symbioses rely on the successful tools has proven to be a successful strategy for the discovery protection of a fungal cultivar, their primary food source, of novel chemical scaffolds and bioactivities.5–8 Amongst the microbial symbionts are likely to act as defensive partners many symbiosis-related model systems, fungus-farming and thus as prolic natural product sources for novel insects have been intensively studied, both from a chemical chemistry.2,6–8 Fungus-farming termites (Macrotermitinae, Termitidae: Blattodea) engage in a symbiosis with a fungal cultivar (genus Suzanne Schmidt has a BSc in Termitomyces; Agaricales: Lyophyllaceae) that they have co- Biology and in 2018 obtained her – evolved with since the origin of fungiculture 30 mya.9 12 In MSc in Human Biology from the addition, termite guts and fungus combs harbour diverse and University of Copenhagen, Den- co-adapted microbiomes that play roles in plant biomass mark. She did her MSc thesis – decomposition and potentially prophylaxis.13 16 Symbiont work at the Section of Forensic Genetics at the Department of Forensic Medicine. In 2019, she Christine Beemelmanns received joined Prof. Michael Poulsen's her diploma in chemistry at the group at the Section for Ecology RWTH Aachen in 2006. Aer and Evolution, Department of a one-year research stay in the Biology, University of Copenha- group of Prof. Mikiko Sodeoka at gen as a PhD student, and her RIKEN (Wako-Shi, Japan) she PhD project focuses on natural products produced by the fungus- then performed her PhD under farming termite fungal crop, Termitomyces. the supervision of Prof. Hans- Creative Commons Attribution-NonCommercial 3.0 Unported Licence. Dr Sara Kildgaard holds an MSc Ulrich Reissig with a fellowship in Engineering in Advanced and of the Fonds der Chemischen Applied Chemistry from The Industrie and the Studienstiung Technical University of Denmark des Deutschen Volkes. Aer two (DTU), where she also did her postdoctoral stay in the group of PhD in analytical natural Prof. Keisuke Suzuki at the Tokyo Institute of Technology (Tokyo, product chemistry as part of the Japan) and Prof. Jon Clardy at Harvard Medical School (USA), EU-funded project PharmaSea, supported by fellowships from the German Exchange Service and This article is licensed under a with the thesis entitled Discovery German National Academy of Sciences Leopoldina, she joined the of Marine Bioactive Natural Leibniz Institute for Natural Product Research and Infection Biology Products. Aer a short postdoc at (Jena, Germany) as a junior research group leader in the end of the Technical University of Den- 2013. Her research focuses of the isolation, characterization and Open Access Article. Published on 19 August 2021. Downloaded 9/29/2021 2:07:25 PM. mark, she joined Prof. Michael total synthesis of microbial signalling molecules. Poulsen's group at the Section for Ecology and Evolution, Depart- Michael Poulsen is a Professor in ment of Biology, University of Copenhagen in 2018 to investigate the Evolution of Microbial chemical compounds of bacterial and fungal origins in fungus- Symbiosis at the Department of farming termites. In 2020, she began her current position as Biology, University of Copenha- a Research Scientist at Lundbeck. gen, Denmark. Poulsen received Dr Huijuan Guo studied biotech- his MSc in biology from the nology in China from 2000 to Department of Biology, Arhus˚ 2004, and natural product University (Denmark) in 2001, chemistry at Institute of Micro- and his PhD from the University biology, Chinese Academy of of Copenhagen in 2005. He Science from 2004 to 2009. In subsequently did ve years of 2009, she joined the group of postdoc work with Prof. Cameron Prof. Wilhelm Boland at Max- R. Currie at the Department of Planck-Institute for Chemical Bacteriology, UW-Madison (USA), and returned to the University of Ecology (MPI-CE) for her doctoral Copenhagen in 2010, where he leads the Social and Symbiotic thesis in Chemistry. In 2014, she Evolution Group and heads the Section for Ecology and Evolution. joined the group of Dr Christine His work focuses on the evolutionary origin and stability of Beemelmanns at the Hans-Knoll¨ symbiosis, including defensive associations that involve natural Institute (HKI) for her postdoc research. Her main research focuses products for antimicrobial defence. on chemical mediator(s) from ecosystems and their pharmaceutical applications. Nat. Prod. Rep. This journal is © The Royal Society of Chemistry 2021 View Article Online Review Natural Product Reports complementarity ensures near-complete plant biomass younger workers that ingest it along with asexual Termitomyces decomposition with contribution from the termite-nurtured spores from mature parts of the fungus comb, and this process fungal garden and gut microbiomes.17,18 Consequently,
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