Microbiome-Assisted Carrion Preservation Aids Larval Development in a Burying Beetle

Microbiome-Assisted Carrion Preservation Aids Larval Development in a Burying Beetle

Microbiome-assisted carrion preservation aids larval development in a burying beetle Shantanu P. Shuklaa,1, Camila Plataa, Michael Reicheltb, Sandra Steigerc, David G. Heckela, Martin Kaltenpothd, Andreas Vilcinskasc,e, and Heiko Vogela,1 aDepartment of Entomology, Max Planck Institute for Chemical Ecology, 07745 Jena, Germany; bDepartment of Biochemistry, Max Planck Institute for Chemical Ecology, 07745 Jena, Germany; cInstitute of Insect Biotechnology, Justus-Liebig-University of Giessen, 35392 Giessen, Germany; dEvolutionary Ecology, Institute of Organismic and Molecular Evolution, Johannes Gutenberg University, 55128 Mainz, Germany; and eDepartment Bioresources, Fraunhofer Institute for Molecular Biology and Applied Ecology, 35394 Giessen, Germany Edited by Nancy A. Moran, The University of Texas at Austin, Austin, TX, and approved September 18, 2018 (received for review July 30, 2018) The ability to feed on a wide range of diets has enabled insects to their larvae, thereby modifying the carcass substantially (12, 23, 26, diversify and colonize specialized niches. Carrion, for example, is 27). Application of oral and anal secretions is hypothesized to highly susceptible to microbial decomposers, but is kept palatable support larval development (27), to transfer nutritive enzymes (21, several days after an animal’s death by carrion-feeding insects. Here 28, 29), transmit mutualistic microorganisms to the carcass (10, 21, we show that the burying beetle Nicrophorus vespilloides preserves 22, 30), and suppress microbial competitors through their antimi- – carrion by preventing the microbial succession associated with car- crobial activity (11, 23, 31 34). The secretions inhibit several Gram- rion decomposition, thus ensuring a high-quality resource for their positive and Gram-negative bacteria, yeasts, and molds (11, 31, 35), developing larvae. Beetle-tended carcasses showed no signs of deg- and the beetles up-regulate transcription of antimicrobial peptides radation and hosted a microbial community containing the beetles’ and lysozymes in the presence of the carcass (36, 37). Nevertheless, gut microbiota, including the yeast Yarrowia. In contrast, untended beetle-prepared carcasses host a diverse bacterial community (Xanthomonadaceae, Enterobacteriaceae, Enterococcaceae, Por- carcasses showed visual and olfactory signs of putrefaction, and their phyromonadaceae) and a yeast-dominated fungal community that microbial community consisted of endogenous and soil-originating ’ is transmitted to the larvae (10, 21). microbial decomposers. This regulation of the carcass bacterial and Apart from the proliferation of microbial competitors, other ECOLOGY fungal community and transcriptomic profile was associated with features of carrion degradation (such as loss of nutrients or accu- lower concentrations of putrescine and cadaverine (toxic polyamines mulation of toxic metabolites) can also impact beetle fitness (12, 26). associated with carcass putrefaction) and altered levels of proteases, Despite these challenges, burying beetles convert this protein-rich lipases, and free amino acids. Beetle-tended carcasses develop a resource into a benign, nourishing nursery for their developing lar- biofilm-like matrix housing the yeast, which, when experimentally vae. However, the microbial and biochemical basis of carrion utili- removed, leads to reduced larval growth. Thus, tended carcasses zation, especially in comparison with untended carcasses, remains hosted a mutualistic microbial community that promotes optimal poorly understood. Dermal bacterial communities of beetle-smeared larval development, likely through symbiont-mediated extraintesti- nal digestion and detoxification of carrion nutrients. The adaptive Significance preservation of carrion coordinated by the beetles and their symbi- onts demonstrates a specialized resource-management strategy Ephemeral diets such as carrion are high-quality resources that through which insects modify their habitats to enhance fitness. are susceptible to microbial spoilage. Carrion-feeding insects that breed on decaying carcasses must overcome challenges arising insect nutrition | gut microbiota | symbiosis | fungus | resource competition from competing microbes. Here we report that a carrion-feeding burying beetle preserves carcasses by regulating its microbial nsects exploit a wide range of diets, and their ability to adapt to growth, resulting in changes in its biochemical properties in- Ichallenging environments and to form symbiotic associations cluding the reduction of toxic polyamines associated with pu- with microorganisms has enabled them to occupy specialized trefaction and nutrient loss. The beetle’s microbial symbionts niches (1–4). Some specialist insects feed on ephemeral and form a biofilm-like matrix on carcasses, which is important for nutritionally rich diets such as cadavers, dung, and fruits that are optimal larval development. The beetles and their microbiome susceptible to degradation by microbial competitors (5). Ne- thus coordinate a specialized adaptive strategy of carrion man- crophagous beetles (family Silphidae) have evolved several agement, enabling them to preserve carrion quality and support physiological and behavioral adaptations in response to resource larval growth in a challenging resource such as carrion. competitors (6–8) and host a conserved and characteristic gut microbiome (9, 10). Loss of carrion quality and presence of Author contributions: S.P.S. designed research; S.P.S., C.P., and M.R. performed research; microbial competitors can have negative effects on insect fitness S.S. provided insects; H.V. contributed new reagents/analytic tools; S.P.S., C.P., M.R., and (11–13), but necrophagous insects also introduce microbes to H.V. analyzed data; and S.P.S., S.S., D.G.H., M.K., A.V., and H.V. wrote the paper. carrion and greatly accelerate nutrient turnover (14). Un- The authors declare no conflict of interest. regulated microbial growth can render the carrion unpalatable This article is a PNAS Direct Submission. and toxic through the accumulation of microbial metabolites, This open access article is distributed under Creative Commons Attribution-NonCommercial- nitrogenous products such as putrescine and cadaverine (poly- NoDerivatives License 4.0 (CC BY-NC-ND). amines that give decomposing meat its characteristic smell), Data deposition: RNAseq data reported in this paper have been deposited in the Euro- acids, phenols, and alcohols (15–20). It remains unclear how pean Nucleotide Archive under accession numbers PRJEB28282 (complete study), ERS2658424–ERS2658429 (eukaryotic RNAseq data), and ERS2658430–ERS2658435 (pro- these insects and their antimicrobial strategies of carrion man- karyotic RNAseq data). The 16S rRNA and ITS amplicon sequencing datasets and result agement (10, 11, 21–26) affect carrion properties, which enable files have been deposited at Edmond, the open access data repository of the Max Planck the utilization of aging, decomposing carcasses. Society (https://edmond.mpdl.mpg.de/imeji/collection/uDvLDpF3wEUOX6ay). The burying beetle Nicrophorus vespilloides (Coleoptera; Silphi- 1To whom correspondence may be addressed. Email: [email protected] or hvogel@ice. dae) uses small cadavers for breeding and is seemingly immune to mpg.de. any ill effects of feeding on aging, buried carcasses. Beetles prepare This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10. carcasses by removing hair or feathers, burying, rolling, smearing 1073/pnas.1812808115/-/DCSupplemental. them with oral and anal secretions, and creating a feeding cavity for www.pnas.org/cgi/doi/10.1073/pnas.1812808115 PNAS Latest Articles | 1of6 Downloaded by guest on September 24, 2021 carcasses differ from untended carcasses (22). However, early A Jaccard Bray-Curtis Unweighted UniFrac decomposition of carcasses is driven by endogenous microbiota (38), and the full extent of differences in the bacterial and fungal communities between decomposing and beetle-tended carcasses remains unexplored. It is also unknown if (and how) beetles “preserve” carrion to support larval development. The surface of Axis 2 (24.4 %) Axis 2 (16.7 %) beetle-prepared carcasses comprises a matrix (10), comparable to Axis 2 (17.8 %) biofilms on decomposing cadavers (15). Using this matrix, this study compares the microbiome and the transcriptome of beetle- tended and untended carcasses. We also investigate whether B Axis 1 (38.7 %) Axis 1 (47.5 %) Axis 1 (29.5 %) preparation of carcasses by the beetles affects levels of toxic Others polyamines (putrescine and cadaverine), free amino acids, and Xanthomonadaceae;Wohlfahrtiimonas C digestive enzymes. We find that the beetles regulate the microbial Xanthomonadaceae;Rhodanobacter Jaccard Streptococcaceae;Lactococcus community of carcasses by supporting the growth of mutualists Staphylococcaceae;Staphylococcus that aid optimal larval development, constituting an adaptive Sphingobacteriales;Sphingobacteriaceae carrion management strategy by the beetles. Sphingobacteriaceae;Sphingobacterium Sphingobacteriaceae;Pedobacter Rhodobacteraceae;Paracoccus Results Rhizobiales;Brucellaceae Axis 2 (14.1 %) Characteristics of Tended and Untended Carcasses. To investigate Pseudomonadaceae;Pseudomonas Porphyromonadaceae;Dysgonomonas the effect of the burying beetles’ preparation of carcasses on Neisseriaceae;Vitreoscilla Axis 1 (25.3 %) their microbial and biochemical properties, we compared tended Moraxellaceae;Psychrobacter carcasses (those

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