Two insulin receptors determine alternative wing morphs in planthoppers

Xu, Haijun; Xue, Jian; Lü, Bo; Zhang, Xue-Chao; Zhuo, Ji-Chong; He, Shuqing; Ma, Xiaofang; Jiang, Yonglei; Fan, Hai-Wei; Xu, Jiyu; Ye, Yuxuan; Pan, Peng-Lu; Qiao, Li; Bao, Yan-Yuan; Nijhout, H. Frederik; Zhang, Chuan-Xi

doi:10.1038/nature14286

Cited by 379 publications

(468 citation statements)

References 36 publications

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“…IIS may also be responsible for the reduction in eye size and wing size observed in small D. melanogaster individuals (Tang et al, 2011). More extreme variation in tissue growth has been observed in other insects, where it is associated with IIS, but also JH, ecdysone and even the hedgehog signaling pathway (Lobbia et al, 2003;Emlen et al, 2012;Gotoh et al, 2014;Niitsu et al, 2014;Kijimoto and Moczek, 2016;Xu et al, 2015; see also the excellent discussion in Zinna et al, 2016). Any or all of these factors (and others yet to be discovered) are candidate caste differentiation factors in ants.…”

Section: Caste Differentiationmentioning

confidence: 99%

“…Here, we attempt to unify the literature on ant caste development and evolution with a single theoretical framework, drawing on recent advances in evolutionary developmental biology (Carroll et al, 2001;West-Eberhard, 2003;Hartfelder and Emlen, 2012;Bopp et al, 2014;Wagner, 2014;Londe et al, 2015;Xu et al, 2015). We propose that ants possess a developmental spectrum of phenotypes, with increasing body size associated with increasingly queen-like traits (Fig.…”

Section: Introductionmentioning

confidence: 99%

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Caste development and evolution in ants: it's all about size

Trible

Kronauer

2017

Journal of Experimental Biology

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Female ants display a wide variety of morphological castes, including workers, soldiers, ergatoid (worker-like) queens and queens. Alternative caste development within a species arises from a variable array of genetic and environmental factors. Castes themselves are also variable across species and have been repeatedly gained and lost throughout the evolutionary history of ants. Here, we propose a simple theory of caste development and evolution. We propose that female morphology varies as a function of size, such that larger individuals possess more queen-like traits. Thus, the diverse mechanisms that influence caste development are simply mechanisms that affect size in ants. Each caste-associated trait has a unique relationship with size, producing a phenotypic space that permits some combinations of worker-and queen-like traits, but not others. We propose that castes are gained and lost by modifying the regions of this phenotypic space that are realized within a species. These modifications can result from changing the sizefrequency distribution of individuals within a species, or by changing the association of tissue growth and size. We hope this synthesis will help unify the literature on caste in ants, and facilitate the discovery of molecular mechanisms underlying caste development and evolution.

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Section: Caste Differentiationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Caste development and evolution in ants: it's all about size

Trible

Kronauer

2017

Journal of Experimental Biology

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“…NlInR1 and NlInR2 closely resemble each other as well as their Drosophila counterpart with respect to amino acid identity and domain architecture [50]. Surprisingly, NlInR1 and NlInR2 play fully opposite roles in wing-morph determination in the BPH.…”

Section: Environmental Factors Influencing Wing Dimorphism In the Bromentioning

confidence: 84%

“…These breakthrough findings suggest that the BPH employs the same suit of genes to generate different wing morphs in different environments by alternating their expressional levels. Further, functional studies on insulin receptors from additional two planthopper species, L. striatellus and S. furcifera, indicated that the planthopper family might share a common regulatory mechanism underlying wing dimorphism [50]. Thus, we refer to the wing-morph plasticity in planthoppers as wing polyphenism instead of wing polymorphism, as alternative wing morphs are caused by redeployment of the existing developmental pathways, but are not genetically determined.…”

Section: Environmental Factors Influencing Wing Dimorphism In the Bromentioning

confidence: 99%

“…Although the data are limited, we speculate that more insects encoding two or more InRs will be revealed as more genomic sequences become available. By examining the structural difference between NlInR1 and NlInR2 in the BPH, we found that the second InR (NlInR2) lacks four cysteine residues adjacent to the amino-terminal part of the furin-like cysteine-rich region (Fu) domain [50] that plays an important functional role in the interaction of the receptor with insulin [51,52]. Especially, only one cysteine at position 550 (C 550 ), numbered after the Drosophila counterpart, is found within the amino-terminal portion of the Fu domain in the NlInR2, whereas concatenate residues of two cysteines (C 549 C 550 ) are present in the corresponding position in NlInR1 (figure 2).…”

Section: (B) Conservation Of the Second Insulin Receptor Across Insectsmentioning

confidence: 99%

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Insulin receptors and wing dimorphism in rice planthoppers

Xu¹,

Zhang²

2017

Phil. Trans. R. Soc. B

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Wing polymorphism contributes significantly to the success of a wide variety of insects. However, its underlying molecular mechanism is less well understood. The migratory planthopper (BPH), Nilaparvata lugens , is one of the most extensively studied insects for wing polymorphism, due to its natural features of short- and long-winged morphs. Using the BPH as an example, we first surveyed the environmental cues that possibly influence wing developmental plasticity. Second, we explained the molecular basis by which two insulin receptors (InR1 and InR2) act as switches to determine alternative wing morphs in the BPH. This finding provides an additional layer of regulatory mechanism underlying wing polymorphism in insects in addition to juvenile hormones. Further, based on a discrete domain structure between InR1 and InR2 across insect species, we discussed the potential roles by which they might contribute to insect polymorphism. Last, we concluded with future directions of disentangling the insulin signalling pathway in the BPH, which serves as an ideal model for studying wing developmental plasticity in insects. This article is part of the themed issue ‘Evo-devo in the genomics era, and the origins of morphological diversity’.

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