Data from: Desiccation resistance and micro-climate adaptation: cuticular hydrocarbon signatures of different Argentine ant supercolonies across California
Cuticular hydrocarbons (CHCs), the dominant fraction of the insects’ epicuticle and the primary barrier to desiccation, form the basis for a wide range of chemical signaling systems. In eusocial insects, CHCs are key mediators of nestmate recognition, and colony identity appears to be maintained thr...
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Zusammenfassung: | Cuticular hydrocarbons (CHCs), the dominant fraction of the insects’
epicuticle and the primary barrier to desiccation, form the basis for a
wide range of chemical signaling systems. In eusocial insects, CHCs are
key mediators of nestmate recognition, and colony identity appears to be
maintained through a uniform CHC profile. In the unicolonial Argentine ant
Linepithema humile, an unparalleled invasive expansion has led to vast
supercolonies whose nestmates can still recognize each other across
thousands of miles. CHC profiles are expected to display considerable
variation as they adapt to fundamentally differing environmental
conditions across the Argentine ant’s expanded range, yet this variation
would largely conflict with the considerably extended nestmate recognition
based on CHC uniformity. To shed light on these seemingly contradictory
selective pressures, we attempt to decipher which CHC classes enable
adaptation to such a wide array of environmental conditions and contrast
them with the overall CHC profile uniformity postulated to maintain
nestmate recognition. n-Alkanes and n-alkenes showed the largest
adaptability to environmental conditions most closely associated with
desiccation, pointing at their function for water-proofing. Trimethyl
alkanes, on the other hand, were reduced in environments associated with
higher desiccation stress. However, CHC patterns correlated with
environmental conditions were largely overriden when taking overall CHC
variation across the expanded range of L. humile into account, resulting
in conserved colony-specific CHC signatures. This delivers intriguing
insights into the hierarchy of CHC functionality integrating both
adaptation to a wide array of different climatic conditions and the
maintenance of a universally accepted chemical profile. |
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DOI: | 10.6078/d1ft43 |