Origin and diversification of wings: Insights from a neopteran insect

Victor Medved; James H. Marden; Howard W. Fescemyer; Joshua P. Der; Jin Liu; Najmus Mahfooz; Aleksandar Popadić

doi:10.1073/pnas.1509517112

Edited by Sean B. Carroll, Howard Hughes Medical Institute and University of Wisconsin-Madison, Madison, WI, and approved November 3, 2015 (received for review May 18, 2015)

Significance

De-repressing appendage growth induces development of ectopic wings on the dorsal prothorax (T1) of the neopteran insect Oncopeltus. These T1 wings, albeit fully developed, are small and of primarily dorsal origin. Transcriptome data indicate that incorporation of ventrally originating tissue was a key evolutionary innovation for generating large and useful T2 and T3 wings. Complimentary functional experiments reveal that wings and an adjacent thoracic plate are not developmentally distinct structures, and are coregulated to create tight wing folding that arose during the transition from paleopteran to neopteran insects. Finally, Ultrabithorax regulates the divergence of fore- and hindwing morphology, a culminating but also ancient feature of insect wing diversity. These innovations account for major features of insect wing origin and diversification.

Abstract

Winged insects underwent an unparalleled evolutionary radiation, but mechanisms underlying the origin and diversification of wings in basal insects are sparsely known compared with more derived holometabolous insects. In the neopteran species Oncopeltus fasciatus, we manipulated wing specification genes and used RNA-seq to obtain both functional and genomic perspectives. Combined with previous studies, our results suggest the following key steps in wing origin and diversification. First, a set of dorsally derived outgrowths evolved along a number of body segments including the first thoracic segment (T1). Homeotic genes were subsequently co-opted to suppress growth of some dorsal flaps in the thorax and abdomen. In T1 this suppression was accomplished by Sex combs reduced, that when experimentally removed, results in an ectopic T1 flap similar to prothoracic winglets present in fossil hemipteroids and other early insects. Global gene-expression differences in ectopic T1 vs. T2/T3 wings suggest that the transition from flaps to wings required ventrally originating cells, homologous with those in ancestral arthropod gill flaps/epipods, to migrate dorsally and fuse with the dorsal flap tissue thereby bringing new functional gene networks; these presumably enabled the T2/T3 wing’s increased size and functionality. Third, “fused” wings became both the wing blade and surrounding regions of the dorsal thorax cuticle, providing tissue for subsequent modifications including wing folding and the fit of folded wings. Finally, Ultrabithorax was co-opted to uncouple the morphology of T2 and T3 wings and to act as a general modifier of hindwings, which in turn governed the subsequent diversification of lineage-specific wing forms.

Footnotes

↵¹V.M. and J.H.M. contributed equally to this work.
↵²To whom correspondence should be addressed. Email: apopadic{at}biology.biosci.wayne.edu.

Author contributions: V.M., J.H.M., and A.P. designed research; V.M., H.W.F., J.P.D., and N.M. performed research; H.W.F., J.P.D., and J.L. contributed new reagents/analytic tools; V.M., J.H.M., and A.P. analyzed data; and V.M., J.H.M., and A.P. wrote the paper.
The authors declare no conflict of interest.
This article is a PNAS Direct Submission.
Data deposition: The sequences reported in this paper have been deposited in the National Center for Biotechnology Information Sequence Read Archive (NCBI SRA), www.ncbi.nlm.nih.gov/sra (accession no. SRP066252).
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1509517112/-/DCSupplemental.