Cryptocercus Genomes Expand Knowledge of Adaptations to Xylophagy and Termite Sociality

Alun R C Jones; Alina A Mikhailova; Cédric Aumont; Juliette Berger; Cong Liu; Shulin He; Zongqing Wang; Sylke Winkler; Erich Bornberg-Bauer; Frédéric Legendre; Dino P McMahon; Mark C Harrison

doi:10.1093/gbe/evag028

Cryptocercus Genomes Expand Knowledge of Adaptations to Xylophagy and Termite Sociality

Alun R C Jones
, Alina A Mikhailova
, Cédric Aumont
, Juliette Berger
, Cong Liu
, Shulin He
, Zongqing Wang
, Sylke Winkler
, Erich Bornberg-Bauer
, Frédéric Legendre
, Dino P McMahon
, Mark C Harrison

Universität Münster
Newcastle University
Bundesanstalt für Materialforschung und -prüfung (BAM)
Freie Universität Berlin
Muséum National d’Histoire Naturelle
Sorbonne University
Okinawa Institute of Science and Technology
Chongqing Normal University
Southwest University
Max Planck Institute of Molecular Cell Biology and Genetics

Research output: Contribution to journal › Article › peer-review

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Abstract

Subsociality and wood-eating or xylophagy are understood as key drivers in the evolution of eusociality in Blattodea (cockroaches and termites), two features observed in the cockroach genus Cryptocercus, the sister group of all termites. We analyze two high-quality genomes from this genus, C. punctulatus from North America and C. meridianus from Southeast Asia, to explore the evolutionary transitions to xylophagy and subsociality within Blattodea. Our analyses reveal evidence of relaxed selection in both Cryptocercus and termites, indicating that a reduction in effective population size may have occurred in their subsocial ancestors. These findings challenge the expected positive correlation between dN/dS ratios and social complexity, as Cryptocercus exhibits elevated dN/dS values that may exceed those of eusocial termites. Additionally, we infer a reduction in the number of Ionotropic Receptors and a change from uni- to bimodal methylation signatures in protein coding genes in a common ancestor of Cryptocercus and termites, mechanisms previously thought to have evolved with the emergence of eusociality in termites. Future studies incorporating additional genomic data from diverse blattodean species can further build on these findings and provide deeper insights into the molecular mechanisms driving transitions to xylophagy and eusociality.

Original language	English
Article number	evag028
Number of pages	15
Journal	Genome Biology and Evolution
Volume	18
Issue number	2
Early online date	6 Feb 2026
DOIs	https://doi.org/10.1093/gbe/evag028
Publication status	E-pub ahead of print - 6 Feb 2026

Bibliographical note

© The Author(s) 2026. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.

Funding

A.R.C.J. acknowledges support from the German Research Foundation (DFG) through grant BO 2544 / 15-1 to E.B.-B. This work was supported by French National Research Agency (ANR) grant no ANR-19-CE02-0023 (project Sociogenomics) to F.L. A.M. was supported by the DFG grant HA 8997/1-1 to MCH. C.A. was supported by the DFG grant MC 436/5-1 to DPM. We are grateful to the following members of the DcGC Dresden-concept Genome Center for their contribu- tions to genome sequencing: Nicola Gscheidel (Hi-C and TELL-Seq experiments), Wenhua Tan (ONT library preparation and sequencing), and Montserrat Palau de Miguel (optimization of gDNA extraction). We thank Joby Timm (Forest supervisor, USDA) for providing us with the authorization to collect Cryptocercus specimens in the George Washington and Jefferson National Forests.

Funders	Funder number
Deutsche Forschungsgemeinschaft	BO 2544 / 15-1
Agence Nationale de la Researche	HA 8997/1-1, MC 436/5-1, ANR-19-CE02-0023

Keywords

subsociality
Blattodea
xylophagy
termites
Cryptocercus
eusociality
chemoreceptors
methylation

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Harrison2026VoRFinal published version, 1.39 MBLicence: CC BY
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Cite this

Jones, A. R. C., Mikhailova, A. A., Aumont, C., Berger, J., Liu, C., He, S., Wang, Z., Winkler, S., Bornberg-Bauer, E., Legendre, F., McMahon, D. P., & Harrison, M. C. (2026). Cryptocercus Genomes Expand Knowledge of Adaptations to Xylophagy and Termite Sociality. Genome Biology and Evolution, 18(2), Article evag028. Advance online publication. https://doi.org/10.1093/gbe/evag028

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abstract = "Subsociality and wood-eating or xylophagy are understood as key drivers in the evolution of eusociality in Blattodea (cockroaches and termites), two features observed in the cockroach genus Cryptocercus, the sister group of all termites. We analyze two high-quality genomes from this genus, C. punctulatus from North America and C. meridianus from Southeast Asia, to explore the evolutionary transitions to xylophagy and subsociality within Blattodea. Our analyses reveal evidence of relaxed selection in both Cryptocercus and termites, indicating that a reduction in effective population size may have occurred in their subsocial ancestors. These findings challenge the expected positive correlation between dN/dS ratios and social complexity, as Cryptocercus exhibits elevated dN/dS values that may exceed those of eusocial termites. Additionally, we infer a reduction in the number of Ionotropic Receptors and a change from uni- to bimodal methylation signatures in protein coding genes in a common ancestor of Cryptocercus and termites, mechanisms previously thought to have evolved with the emergence of eusociality in termites. Future studies incorporating additional genomic data from diverse blattodean species can further build on these findings and provide deeper insights into the molecular mechanisms driving transitions to xylophagy and eusociality.",

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AU - He, Shulin

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N2 - Subsociality and wood-eating or xylophagy are understood as key drivers in the evolution of eusociality in Blattodea (cockroaches and termites), two features observed in the cockroach genus Cryptocercus, the sister group of all termites. We analyze two high-quality genomes from this genus, C. punctulatus from North America and C. meridianus from Southeast Asia, to explore the evolutionary transitions to xylophagy and subsociality within Blattodea. Our analyses reveal evidence of relaxed selection in both Cryptocercus and termites, indicating that a reduction in effective population size may have occurred in their subsocial ancestors. These findings challenge the expected positive correlation between dN/dS ratios and social complexity, as Cryptocercus exhibits elevated dN/dS values that may exceed those of eusocial termites. Additionally, we infer a reduction in the number of Ionotropic Receptors and a change from uni- to bimodal methylation signatures in protein coding genes in a common ancestor of Cryptocercus and termites, mechanisms previously thought to have evolved with the emergence of eusociality in termites. Future studies incorporating additional genomic data from diverse blattodean species can further build on these findings and provide deeper insights into the molecular mechanisms driving transitions to xylophagy and eusociality.

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ER -

Cryptocercus Genomes Expand Knowledge of Adaptations to Xylophagy and Termite Sociality

Abstract

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Keywords

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