Abstract
Endoreduplication or nuclear genome replication without cell division is widely observed in the metabolically active tissues of plants and animals. The fat body cells of adult female insects produce abundant yolk proteins and become polyploid, which is assumed to accelerate egg production. Recently, it was reported that in termites, endopolyploidy in the fat body occurs only in queens but not in the other females; however, the relationship between the fecundity and ploidy level in the fat body remains unclear. Termite queens exhibit a huge variation in their egg‐producing capacity among different species; queens in the species with a foraging lifestyle, in which workers leave the nest to forage outside, are much more fecund than those in the species living in a single piece of wood. In this study, we conducted ploidy analyses on three foragings and three wood‐dwelling termites via flow cytometry. In all the species, the fat body of queens contained significantly more polyploid cells than that of other nonreproductive females, considering their body size effect. However, the male fat body, which is not involved in yolk production, did not show consistency in polyploid cell numbers among the species studied. Moreover, highly fecund queens in foraging termites exhibit higher levels of endopolyploidy in their fat body than those with less fecundity in wood‐dwelling termites. These results suggest that endopolyploidy in the fat body of termite queens can boost their egg production, and the level of endopolyploidy in their fat body is linked to their fecundity. Our study provides a novel insight into the evolutionary relationship between endoreduplication and caste specialization in social insects.
Highlights
Social insects are defined by the reproductive division of labor, wherein a small number of individuals monopolize reproduction while others conduct nonreproductive tasks such as foraging, brood care, defense, and maintenance of the colony (Wilson, 1971).Extreme reproductive specializations are exhibited in social insects under such a system
In I. schwartzi, we found significant effects of both castes and body weight on the proportions of polyploid cells in the fat body (GLMM with a Wald chi‐square test, castes: χ2 = 263.827, df = 3, p < .001, body weight: χ2 = 60.772, df = 1, p < .001)
In Z. nevadensis, while body weight had a significant effect on the proportion of poly‐ ploid cells in their fat body (GLMM with a Wald chi‐square test, χ2 = 15.551, df = 1, p < .001), castes had a significant effect (χ2 = 216.074, df = 2, p < .001)
Summary
Social insects are defined by the reproductive division of labor, wherein a small number of individuals monopolize reproduction while others conduct nonreproductive tasks such as foraging, brood care, defense, and maintenance of the colony (Wilson, 1971). Determining the ploidy levels in fat body cells of both the sexes of various termite species would provide further implica‐ tions for the functional significance of endopolyploidy in caste specialization and queen fecundity in social insects. We investigated the relationship between repro‐ duction and fat body polyploidization using three foraging species with highly fecund queens (Termitidae: Nasutitermes takasagoensis Shiraki; Rhinotermitidae: Coptotermes formosanus Shiraki and Reticulitermes speratus Kolbe; Figure 2a) and three wood‐dwelling species with less fecund queens (Kalotermitidae: and Neotermes sugioi Yashiro and Incisitermes schwarzi Banks; Termopsidae: Zootermopsis nevadensis Hagen; Figure 2b) These species roughly cover the termite phylogenetic diversity and exhibit considerable. Others Nymph ♀: 12.5–15.1 (5) Nymph ♂: 10.8–12.9 (5) NA NA NA Alate ♀: 9.9–12.9 (3) Alate ♂: 8.0–11.4 (3) NA
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