RESUMEN
Winter geometrid moths show striking sexual dimorphism by having female-specific flightless morphs. The evolutionary grades of wing reduction in winter geometrid moths vary and range from having short wings, vestigial wings, to being wingless. Although the ontogenetic processes underlying the development of the wingless or short-wing morphs in Lepidoptera has been well studied, the mechanisms underlying the development of vestigial wing morphs in winter geometrid moths during metamorphosis are poorly understood. In the winter geometrid moth Sebastosema bubonaria Warren, 1896, the males have functional wings, but the females have vestigial wings. Here, we studied the ontogenetic processes affecting wing reduction in the winter geometrid moth S. bubonaria using light microscopy and transmission electron microscopy, and compared the ontogenetic process of wing reduction in this species with that in another species of the wingless-female winter moth that we investigated previously. Our results showed that, in the vestigial-wing morphs, the loss of pupal wing epithelium was terminated in the middle of the wing degeneration process, whereas in the wingless morph, the pupal wing epithelium disappeared almost completely and the final appearance of the wings differed slightly among flightless morphs. We propose that the extent and location of cell death in the pupal wing play an important role in the various patterns of reduced wings that are observed in flightless moths.
Asunto(s)
Mariposas Nocturnas , Masculino , Femenino , Animales , Metamorfosis Biológica , Muerte Celular , Evolución Biológica , Alas de AnimalesRESUMEN
Unlike faster-acting conventional insecticides, some botanical insecticides exhibit growth inhibitory activity against some insect pests. One of the distinguishing features of growth inhibitory activity appears to be in malformed moths with vestigial wings. However, the molecular mechanism underlying vestigial wings of insect pests induced by plant natural products or their derivatives is still elusive. In this work, based upon the phenotype of the vestigial wings of Mythimna separata Walker (as a model pest) induced by a podophyllotoxin derivative 2a (as a model compound), we found that compound 2a not only resulted in 22.1% of malformed moths with vestigial wings but also significantly decreased the fecundity of vestigial-winged female moths in the P generation; the trait of vestigial wings caused by 2a in the P generation can be inherited by the F1 generation; compound 2a may target insulin receptor 1 (InR1), suppress the InR1 mRNA level, and block InR1-pY1229 and InR1-pY1233/1234 phosphorylation levels in a tissue-specific manner "head/thorax/wing tissues". Notably, compound 2a can also induce the vestigial wings of Spodoptera frugiperda (another seriously harmful migratory lepidoptera pest). It is noteworthy that this insect insulin receptor can be used as a new kind of target receptors for the design of novel green insecticides.