Desiccation Resistance and Micro-Climate Adaptation: Cuticular Hydrocarbon Signatures of Different Argentine Ant Supercolonies Across California

Buellesbach, Jan; Whyte, Brian A.; Cash, Elizabeth; Gibson, Joshua D.; Scheckel, Kelsey J.; Sandidge, Rebecca; Tsutsui, Neil D.

doi:10.1007/s10886-018-1029-y

Cited by 27 publications

(33 citation statements)

References 59 publications

(74 reference statements)

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“…Our study is the first social insect study to link variation in cuticular hydrocarbons with variation in colony productivity, although previous social insect studies have linked variation in cuticular hydrocarbons to worker survival (Sprenger et al 2018) or to climatic or biotic variation (Menzel et al 2017;Buellesbach et al 2018;Sprenger et al 2018 Interestingly, we found similar linear selection patterns using both definitions, as all significant linear estimates were in the same direction between the two definitions (Figure 3, Supplement table 2). This suggests that the hydrocarbon profile optima are largely aligned for the production of both reproductives and workers in our study population.…”

Section: Discussionsupporting

confidence: 59%

“…), diet, and environmental conditions experienced by the colonies. Such control in particular is valuable given the complexity of social insect colonies (Linksvayer 2006;Kronauer & Libbrecht 2018) and the sensitivity of the hydrocarbon profile to changes in the environment or diet (Francis et al 1989;vander Meer et al 1989;Liang & Silverman 2000;Tissot et al 2001;Buczkowski et al 2005;van Zweden et al 2009;Pavković-Lučić et al 2016;Menzel et al 2017;Buellesbach et al 2018). Although future field studies would be beneficial, in particular to identify how variation in cuticular hydrocarbons affects colony productivity in a natural setting, a field study on a similar scale as our study is likely not feasible.…”

Section: Discussionmentioning

confidence: 95%

“…Knowledge of the fitness consequences of trait variation is necessary to characterize the type (e.g., directional, stabilizing, or disruptive) and strength of natural selection acting on a trait (Lande & Arnold 1983;Arnold & Wade 1984;Janzen & Stern 1998;Morrissey & Sakrejda 2013). Variation in the social insect hydrocarbon profile may affect individual survival and colony productivity by affecting desiccation resistance (Gordon 2013;Buellesbach et al 2018;Sprenger et al 2018;Friedman et al 2019) or by influencing chemical communication among nestmates and the collective behavior of the colony (Lahav et al 2001;Green & Gordon 2003;Martin & Drijfhout 2009a;Liebig 2010;Buellesbach et al 2018).…”

Section: Introductionmentioning

confidence: 99%

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Ant cuticular hydrocarbons are heritable and associated with variation in colony productivity

Walsh

Pontieri

d’Ettorre

et al. 2019

Preprint

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In social insects, cuticular hydrocarbons function in nestmate recognition and also provide a waxy barrier against desiccation, but basic evolutionary genetic features, including the heritability of hydrocarbon profiles and how they are shaped by natural selection are largely unknown. We used a new pharaoh ant (Monomorium pharaonis) laboratory mapping population to estimate the heritability of individual cuticular hydrocarbons, genetic correlations between hydrocarbons, and fitness consequences of phenotypic variation in the hydrocarbons. Individual hydrocarbons had low to moderate estimated heritability, indicating that some compounds provide more information about genetic relatedness and can also better respond to natural selection. Strong genetic correlations between compounds are likely to constrain independent evolutionary trajectories, which is expected given that many hydrocarbons share biosynthetic pathways. Variation in cuticular hydrocarbons was associated with variation in colony productivity, with some hydrocarbons experiencing strong directional selection. Altogether, our study builds on our knowledge of the genetic architecture of the social insect hydrocarbon profile and demonstrates that hydrocarbon variation is shaped by natural selection.

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Section: Discussionsupporting

confidence: 59%

Section: Discussionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

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Ant cuticular hydrocarbons are heritable and associated with variation in colony productivity

Walsh

Pontieri

d’Ettorre

et al. 2019

Preprint

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“…Therefore, these changes may reflect a physical response of the CHC blend to dryness rather than a physiological mechanism to control water loss. Indeed, these CHC changes would reduce overall waterproofing, although some authors found that alkenes also increase with temperature [22,52].…”

Section: Discussionmentioning

confidence: 99%

Cuticle Hydrocarbons Show Plastic Variation under Desiccation in Saline Aquatic Beetles

Botella‐Cruz

Velasco

Millán

et al. 2021

Insects

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In the context of aridification in Mediterranean regions, desiccation resistance and physiological plasticity will be key traits for the persistence of aquatic insects exposed to increasing desiccation stress. Control of cuticular transpiration through changes in the quantity and composition of epicuticular hydrocarbons (CHCs) is one of the main mechanisms of desiccation resistance in insects, but it remains largely unexplored in aquatic ones. We studied acclimation responses to desiccation in adults of two endemic water beetles from distant lineages living in Mediterranean intermittent saline streams: Enochrus jesusarribasi (Hydrophilidae) and Nebrioporus baeticus (Dytiscidae). Cuticular water loss and CHC composition were measured in specimens exposed to a prior non-lethal desiccation stress, allowed to recover and exposed to a subsequent desiccation treatment. E. jesusarribasi showed a beneficial acclimation response to desiccation: pre-desiccated individuals reduced cuticular water loss rate in a subsequent exposure by increasing the relative abundance of cuticular methyl-branched compounds, longer chain alkanes and branched alkanes. In contrast, N. baeticus lacked acclimation capacity for controlling water loss and therefore may have a lower physiological capacity to cope with increasing aridity. These results are relevant to understanding biochemical adaptations to drought stress in inland waters in an evolutionary and ecological context.

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“…Nongenetic factors contributing to CHC diversity could potentially overshadow the detectable impact of individual biosynthesis genes, hampering attempts to fully resolve the explicit contributions of each individual gene. Several studies have revealed a remarkable adaptability of CHC profiles to diverse biotic and abiotic conditions in different insect taxa (e.g., Rajpurohit et al 2017;Buellesbach et al 2018b;Menzel et al 2018). Also, since CHC biosynthesis is linked to the uptake of amino acids (Dillwith et al 1982;Chase et al 1990) and has been shown to be influenced by several metabolic pathways, such as the citric acid cycle and fatty acid synthesis (Barber et al 2005;Blomquist and Bagnères 2010), diet can contribute to variations in CHC profiles as well (e.g., Fedina et al 2012).…”

Section: Phenotypic Plasticity and Nongenetic Factorsmentioning

confidence: 99%

Advances in deciphering the genetic basis of insect cuticular hydrocarbon biosynthesis and variation

2020

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Cuticular hydrocarbons (CHCs) have two fundamental functions in insects. They protect terrestrial insects against desiccation and serve as signaling molecules in a wide variety of chemical communication systems. It has been hypothesized that these pivotal dual traits for adaptation to both desiccation and signaling have contributed to the considerable evolutionary success of insects. CHCs have been extensively studied concerning their variation, behavioral impact, physiological properties, and chemical compositions. However, our understanding of the genetic underpinnings of CHC biosynthesis has remained limited and mostly biased towards one particular model organism (Drosophila). This rather narrow focus has hampered the establishment of a comprehensive view of CHC genetics across wider phylogenetic boundaries. This review attempts to integrate new insights and recent knowledge gained in the genetics of CHC biosynthesis, which is just beginning to incorporate work on more insect taxa beyond Drosophila. It is intended to provide a stepping stone towards a wider and more general understanding of the genetic mechanisms that gave rise to the astonishing diversity of CHC compounds across different insect taxa. Further research in this field is encouraged to aim at better discriminating conserved versus taxon-specific genetic elements underlying CHC variation. This will be instrumental in greatly expanding our knowledge of the origins and variation of genes governing the biosynthesis of these crucial phenotypic traits that have greatly impacted insect behavior, physiology, and evolution.

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Desiccation Resistance and Micro-Climate Adaptation: Cuticular Hydrocarbon Signatures of Different Argentine Ant Supercolonies Across California

Cited by 27 publications

References 59 publications

Ant cuticular hydrocarbons are heritable and associated with variation in colony productivity

Ant cuticular hydrocarbons are heritable and associated with variation in colony productivity

Cuticle Hydrocarbons Show Plastic Variation under Desiccation in Saline Aquatic Beetles

Advances in deciphering the genetic basis of insect cuticular hydrocarbon biosynthesis and variation

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