Ecological immunology: do sexual attraction and immunity trade-off through a desaturase?

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Ecological immunology: do sexual attraction and immunity trade-off through a desaturase?

Ke Gao , Wout van der Heide , Daphne Muijderman , Sarah Nichols , Carmen Karwal , Peter Kuperus , Astrid T. Groot

Insect Science ›› 2025, Vol. 32 ›› Issue (1) : 290 -300.

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Insect Science ›› 2025, Vol. 32 ›› Issue (1) : 290 -300. DOI: 10.1111/1744-7917.13379

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Ecological immunology: do sexual attraction and immunity trade-off through a desaturase?

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Abstract

Given the limited availability of resources in nature, sexual attractiveness may trade off with immunocompetence, as the immunocompetence handicap hypothesis (ICHH) posits. In invertebrates, a direct link between trade-offs through hormonal/molecular effectors in sexual signals and immunity has not been found so far. Here, we assessed how variation in sexual signals affected parasite infection in two sex pheromone selected lines of the moth Chloridea virescens: an attractive line with a low ratio of 16:Ald/Z11-16:Ald and an unattractive line with a high ratio. When infecting these lines with an apicomplexan parasite, we found that the attractive Low line was significantly more susceptible to the parasite infection than the unattractive High line. Since the ratio difference between these two lines is determined by a delta-11-desturase, we hypothesized that this desaturase may have a dual role, i.e., in the quality of the sexual signal as well as an involvement in immune response, comparable to testosterone in vertebrates. However, when we used CRISPR/cas9 to knockout delta-11-desturase in the attractive Low line, we found that the pheromonal phenotype did change to that of the High line, but the infection susceptibility did not. Notably, when checking the genomic location of delta-11-desaturase in the C. virescens, we found that mucin is adjacent to delta-11-desaturase. When comparing the mucin sequences in both lines, we found four nonsynonymous SNPs in the coding sequence, as well as intronic variation between the two lines. These differences suggest that genetic hitchhiking may explain the variation in susceptibility to parasitic infection.

Keywords

Chloridea virescens / delta-11-desaturase / ICHH / parasite susceptibility / sex pheromone

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Ke Gao, Wout van der Heide, Daphne Muijderman, Sarah Nichols, Carmen Karwal, Peter Kuperus, Astrid T. Groot. Ecological immunology: do sexual attraction and immunity trade-off through a desaturase?. Insect Science, 2025, 32(1): 290-300 DOI:10.1111/1744-7917.13379

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Altizer, S.M.,Oberhauser, K.S. and Brower, L.P. (2000) Associations between host migration and the prevalence of a protozoan parasite in natural populations of adult monarch butterflies. Ecological Entomology,25,125–139.

[2]	Andersson, M. (1994) Sexual Selection. Princeton University Press.

[3]	Barton, N.H. (2000) Genetic hitchhiking. Philosophical Transactions of the Royal Society of London. Series B: Biological Sciences,355,1553–1562.

[4]	Bradley, C.A. and Altizer, S. (2005) Parasites hinder monarch butterfly flight: implications for disease spread in migratory hosts. Ecology Letters,8,290–300.

[5]	Cotter, S.C. and Shareefi, E.A. (2022) Nutritional ecology, infection and immune defence—exploring the mechanisms. Current Opinion in Insect Science,50,100862.

[6]	Cotter, S.C.,Simpson, S.J.,Raubenheimer, D. and Wilson, K. (2011) Macronutrient balance mediates trade-offs between immune function and life history traits. Functional Ecology,25,186–198.

[7]	Flatt, T.,Tu, M. and Tatar, M. (2005) Hormonal pleiotropy and the juvenile hormone regulation of Drosophila development and life history. BioEssays,27,999–1010.

[8]	Folstad, I. and Karter, A.J. (1992) Parasites, bright males, and the immunocompetence handicap. The American Naturalist,139,603–622.

[9]	Foster, S.P. and Anderson, K.G. (2015) Sex pheromones in mate assessment: analysis of nutrient cost of sex pheromone production by females of the moth Heliothis virescens. The Journal of Experimental Biology,218,1252–1258.

[10]	Galicia, A.,Cueva del Castillo, R. and Contreras-Garduño, J. (2014) Is sexual dimorphism in the immune response of Gryllodes sigillatus related to the quality of diet? International Scholarly Research Notices,2014,329736.

[11]	Gao, K.,Muijderman, D.,Nichols, S.,Heckel, D.G.,Wang, P.,Zalucki, M.P. et al. (2020a) Parasite-host specificity: a cross-infection study of the parasite Ophryocystis elektroscirrha. Journal of Invertebrate Pathology,170,107328.

[12]	Gao, K.,Wijk, M.v.,Clement, Z.,Egas, M. and Groot, A.T. (2020b) A life-history perspective on sexual selection in a polygamous species. BMC Evolutionary Biology,20,1–10.

[13]	Gao, K.,Wijk, M.V.,Dang, Q.T.D.,Heckel, D.G.,Zalucki, M.P. and Groot, A.T. (2021) How healthy is your mate? Sex-specific consequences of parasite infections in the moth Helicoverpa armigera. Animal Behaviour,178,105–113.

[14]	Gilbert, R.,Karp, R.D. and Uetz, G.W. (2016) Effects of juvenile infection on adult immunity and secondary sexual characters in a wolf spider. Behavioral Ecology,27,946–954.

[15]	Gonzalez-Tokman, D.M.,Munguía-Steyer, R.,Gonzalez-Santoyo, I.,Baena-Díaz, F.S. and Cordoba-Aguilar, A. (2012) Support for the immunocompetence handicap hypothesis in the wild: hormonal manipulation decreases survival in sick damselflies. Evolution,66,3294–3301.

[16]	Gould, F.,Estock, M.,Hillier, N.K.,Powell, B.,Groot, A.T.,Ward, C.M. et al. (2010) Sexual isolation of male moths explained by a single pheromone response QTL containing four receptor genes. Proceedings of the National Academy of Sciences USA,107,8660–8665.

[17]	Grafen, A. (1990) Biological signals as handicaps. Journal of Theoretical Biology,144,517–546.

[18]	Groot, A.T.,Claßen, A.,Staudacher, H.,Schal, C. and Heckel, D.G. (2010) Phenotypic plasticity in sexual communication signal of a noctuid moth. Journal of Evolutionary Biology,23,2731–2738.

[19]	Groot, A.T.,Horovitz, J.L.,Hamilton, J.,Santangelo, R.G.,Schal, C. and Gould, F. (2006) Experimental evidence for interspecific directional selection on moth pheromone communication. Proceedings of the National Academy of Sciences USA,103,5858–5863.

[20]	Groot, A.T.,Schöfl, G.,Inglis, O.,Donnerhacke, S.,Classen, A.,Schmalz, A. et al. (2014) Within-population variability in a moth sex pheromone blend: genetic basis and behavioural consequences. Proceedings of the Royal Society B: Biological Sciences,281,20133054.

[21]	Groot, A.T.,Wijk, M.v.,Villacis-Perez, E.,Kuperus, P.,Schöfl, G.,Veldhuizen, D.v. et al. (2019) Within-population variability in a moth sex pheromone blend, part 2: selection towards fixation. Royal Society Open Science,6,182050.

[22]	Harari, A.R.,Zahavi, T. and Thiéry, D. (2011) Fitness cost of pheromone production in signaling female moths. Evolution,65,1572–1582.

[23]	Hare, R.M. and Simmons, L.W. (2019) Sexual selection and its evolutionary consequences in female animals. Biological Reviews,94,929–956.

[24]	Hasselquist, D.,Marsh, J.A.,Sherman, P.W. and Wingfield, J.C. (1999) Is avian humoral immunocompetence suppressed by testosterone? Behavioral Ecology and Sociobiology,45,167–175.

[25]	Hedrick, P.W. (1982) Genetic hitchhiking: a new factor in evolution? Bioscience,32,845–853.

[26]	Henry, M.A.,Gasco, L.,Chatzifotis, S. and Piccolo, G. (2018) Does dietary insect meal affect the fish immune system? The case of mealworm,Tenebrio molitor on European sea bass,Dicentrarchus labrax. Developmental & Comparative Immunology,81,204–209.

[27]	Jacot, A.,Scheuber, H. and Brinkhof, M.W.G. (2004) Costs of an induced immune response on sexual display and longevity in field crickets. Evolution,58,2280–2286.

[28]	Johnstone, R.A. (1995) Sexual selection, honest advertisement and the handicap principle: reviewing the evidence. Biological Reviews,70,1–65.

[29]	Lawniczak, M.K.N.,Barnes, A.I.,Linklater, J.R.,Boone, J.M.,Wigby, S. and Chapman, T. (2007) Mating and immunity in invertebrates. Trends in Ecology and Evolution,22,48–55.

[30]	McKean, K.A. and Nunney, L. (2008) Sexual selection and immune function in Drosophila melanogaster. Evolution,62,386–400.

[31]	McLaughlin, R.E. and Myers . (1970) Ophryocystis elektroscirrha sp. n., a neogregarine pathogen of the monarch butterfly Danaus plexippus (L.) and the Florida queen butterfly D. gilippus berenice Cramer. The Journal of Protozoology,17,300–305.

[32]	Olson, V.A. and Owens, I.P.F. (1998) Costly sexual signals: are carotenoids rare, risky or required? Trends in Ecology & Evolution,13,510–514.

[33]	Penn, D.J. and Számadó S. (2020) The Handicap Principle: how an erroneous hypothesis became a scientific principle. Biological Reviews,95,267–290.

[34]	Ponton, F.,Tan, Y.X.,Forster, C.C.,Austin, A.J.,English, S.,Cotter, S.C. et al. (2023) The complex interactions between nutrition, immunity and infection in insects. Journal of Experimental Biology,226,jeb245714.

[35]	Rantala, M.J.,Kortet, R.,Kotiaho, J.S.,Vainikka, A. and Suhonen, J. (2003a) Condition dependence of pheromones and immune function in the grain beetle Tenebrio molitor. Functional Ecology,17,534–540.

[36]	Rantala, M.J.,Moore, F.R.,Skrinda, I.,Krama, T.,Kivleniece, I.,Kecko, S. et al. (2012) Evidence for the stress-linked immunocompetence handicap hypothesis in humans. Nature Communications,3,694.

[37]	Rantala, M.J.,Vainikka, A. and Kortet, R. (2003b) The role of juvenile hormone in immune function and pheromone production trade-offs: a test of the immunocompetence handicap principle. Proceedings of the Royal Society of London. Series B: Biological Sciences,270,2257–2261.

[38]	Roberts, M.L.,Buchanan, K.L. and Evans, M.R. (2004) Testing the immunocompetence handicap hypothesis: a review of the evidence. Animal Behaviour,68,227–239.

[39]	Roulin, A. (2016) Condition-dependence, pleiotropy and the handicap principle of sexual selection in melanin-based colouration. Biological Reviews,91,328–348.

[40]	Ryder, J.J. and Siva-Jothy, M.T. (2000) Male calling song provides a reliable signal of immune function in a cricket. Proceedings of the Royal Society of London. Series B: Biological Sciences,267,1171–1175.

[41]	Scharf, I.,Peter, F. and Martin, O.Y. (2013) Reproductive trade-offs and direct costs for males in arthropods. Evolutionary Biology,40,169–184.

[42]	Schmid-Hempel, P. (2005) Evolutionary ecology of insect immune defenses. Annual Review of Entomology,50,529–551.

[43]	Shangguan, X.,Zhang, J.,Liu, B.,Zhao, Y.,Wang, H.,Wang, Z. et al. (2018) A mucin-like protein of planthopper is required for feeding and induces immunity response in plants. Plant Physiology,176,552–565.

[44]	Singer, M.S.,Mason, P.A. and Smilanich, A.M. (2014) Ecological immunology mediated by diet in herbivorous insects. Integrative and Comparative Biology,54,913–921.

[45]	Stearns, S.C. (1989) Trade-offs in life-history evolution. Functional Ecology,3,259–268.

[46]	Syed, Z.A.,Härd, T.,Uv, A. and Dijk-Härd, I.F.v. (2008) A potential role for Drosophila mucins in development and physiology. PLoS ONE,3,e3041.

[47]	Unckless, R.L.,Rottschaefer, S.M. and Lazzaro, B.P. (2015) The complex contributions of genetics and nutrition to immunity in Drosophila melanogaster. PLoS Genetics,11,e1005030.

[48]	Wijk, M.v.,Heath, J.,Lievers, R.,Schal, C. and Groot, A.T. (2017) Proximity of signallers can maintain sexual signal variation under stabilizing selection. Scientific Reports,7,18101.

[49]	Willson, M.F. (1990) Sexual selection in plants and animals. Trends in Ecology & Evolution,5,210–214.

[50]	Zahavi, A. (1975) Mate selection-a selection for a handicap. Journal of Theoretical Biology,53,205–214.

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2024 The Authors. Insect Science published by John Wiley & Sons Australia, Ltd on behalf of Institute of Zoology, Chinese Academy of Sciences.

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