Origin and transformation of the in‐flight wing‐coupling structure in Psocodea (Insecta: Paraneoptera)

Many four‐winged insects have mechanisms that unite the forewings and hindwings in a single plane. Such an in‐flight wing coupling apparatus may improve flight performance in four‐winged insects, but its structure is variable among different insect groups. The wings of bark lice (Insecta: Psocodea: “Psocoptera”) also have an in‐flight wing coupling apparatus, but to date, its morphology has not been studied in detail. In this study, we examined the wing‐coupling structure in representative species of the three suborders of bark lice (Trogiomorpha, Troctomorpha, and Psocomorpha) and inferred its origin and transformation. We conclude that the main component of the psocodean wing coupling apparatus evolved once in the common ancestor via modification of cuticular structures at the apex of the forewing CuP vein. Morphological differences in components of the coupling structures are phylogenetically informative at the intraorder level and include an autapomorphy that characterizes Troctomorpha and a synapomorphy that supports a sister relationship between Troctomorpha and Psocomorpha.     

Gastric mill structure and its phylogenetic significance in larval Hydropsychidae (Trichoptera)

Gastric mills of final instar larval Hydropsychidae (21 genera: 59 species) observed by scanning electron microscopy, revealed dramatic structural variation. There was no dental development in Diplectrona (S. F. Diplectroninae ), minute spines in Aphropsyche, Austropsyche, Homoplectra (S. F. Diplectroninae ), Arctopsyche and Parapsyche (S. F. Arclopsychinae ), and well-developed sclerotized teeth in most genera of Hydropsychinae and Macronematinae. Hydropsyche and Ceratopsyche were characterized by 30–50 triangular tooth-plates. Only two genera in the Hydropsychinae possessed a constant number of teeth in the proventriculus - Synaptopsyche with 36 and Potamyia with 18. Gastric mills of Cheumatopsyche contained larger numbers of smaller, spine-covered teeth whereas in Smicridea teeth were absent. Within the Macronematinae, species of Macrostemum, Blepharopus, Protomacronema, Amphipsyche and Aethaloptera invariably had 18 tooth-plates while Polymorphanisus possessed 12 smaller, sharply triangular teeth. Leptonema, Macronema and Plectromacronema all had spinate proventriculi. In general the degree of dental development within subfamilies supports currently held views on hydropsychid phylogeny. I suggest that the development of large tooth-plates for food processing has contributed significantly to the adaptive radiation of the more highly evolved Hydropsychinae and Macronematinae. Examination of gut contents from Amphipsyche meridiana indicated differential crushing efficiency of diatoms and dinoflagellates. Further studies are required to determine the functional role of the dentition in each type of mill.     

Central projections of the wing afferents in the hawkmoth, Agrius convolvuli

Flight behaviors in various insect species are closely correlated with their mechanical and neuronal properties. Compared to locusts and flies which have been intensively studied, moths have “intermediate” properties in terms of the neurogenic muscle activations, power generation by indirect muscles, and two-winged-insect-like flapping behavior. Despite these unique characteristics, little is known about the neuronal mechanisms of flight control in moths. We investigated projections of the wing mechanosensory afferents in the central nervous system (CNS) of the hawkmoth, Agrius convolvuli, because the mechanosensory proprioceptive feedback has an essential role for flight control and would be presumably optimized for insect species. We conducted anterograde staining of nine afferent nerves from the fore- and hindwings. All of these afferents projected into the prothoracic, mesothoracic and metathoracic ganglia (TG1, 2 and 3) and had ascending fibers to the head ganglia. Prominent projection areas in the TG1–3 and suboesophageal ganglion (SOG) were common between the forewing, hindwing and contralateral forewing afferents, suggesting that information from different wings are converged at multiple levels presumably for coordinating wing flapping. On the other hand, differences of projections between the fore- and hindwing afferents were observed especially in projection areas of the tegulae in the TG1 and contralateral projections of the anterior forewing nerve in the TGs and SOG, which would reflect functional differences between corresponding mechanoreceptors on each wing. Afferents comprising groups of the campaniform sensilla at the wing bases had prominent ascending pathways to the SOG, resembling the head–neck motor system for gaze control in flies. Double staining of the wing afferents and flight or neck motoneurons also indicated potential connectivity between them. Our results suggest multiple roles of the wing proprioceptive feedback for flight and provide the anatomical basis for further understanding of neuronal mechanisms of the flight system in moths.     

Hox基因与昆虫翅的特化

自从1978年E.B. Lewis描述了著名的果蝇双胸突变体（bithorax）以来,大量的比较发育遗传学研究为我们揭示了形态进化的遗传基础,从而使形态进化研究进入了一个新的时代。同时,Hox基因的研究也成为这一领域的焦点。本文综述了昆虫翅的起源及其特化类群翅的发育遗传学研究的最新进展。一般认为,原始的有翅昆虫胸腹部多附肢（包括翅）; 之后不同的体节受到了不同Hox的抑制,形成两对翅以及前后翅的分化; Ubx的不同表达导致了前后翅的分化,并且Ubx负责识别后翅。我们选择翅特化最为显著的3个类群——鞘翅目（T2鞘翅）、双翅目（T3平衡棒）和捻翅目（T2平衡棒）,结合Hox的表达情况讨论了翅的特化机理。目前已知双翅目和鞘翅目的翅的控制模式存在巨大差异,两种模式的比较研究对于理解翅的形态进化具有重要的意义。但是对捻翅目昆虫的研究则很少。     

Functional forewing morphology and stridulation in crickets (Orthoptera, Grylloidea)

Forewing morphology and infrastructure are analysed in three cricket species ( Gryllus campestris, Oecanthus pellucens and Lerneca fuscipennis ) and checked in 20 other genera. A strong dorsoventral asymmetry is demonstrated for the first time. The upper side of the tegmina is covered with hexagonal, more or less high crests forming reliefs. On the lower side, annulate, flat and thick veins exist. The distribution of the hexagons and that of the different vein types is uneven on the forewing surfaces. Their significance in forewing functional morphology is discussed in relation to stridulation and to current knowledge on cricket sound production mechanisms. Their extent and distribution, together with the number and strength of the veins and the surface of wing cells, could account for the vibrational characteristics of the cricket forewing and explain the diverse results obtained by several authors on Gryllus and Oecanthus .     

Apoptotic wing degeneration and formation of an altruism-regulating glandular appendage (gemma) in the ponerine ant <Emphasis Type="Italic">Diacamma</Emphasis> sp. from Japan (Hymenoptera,Formicidae, Ponerinae)

We here show an example of morphological novelties, which have evolved from insect wings into the specific structures controlling social behaviour in an ant species. Most ant colonies consist of winged queen(s) and wingless workers. In the queenless ponerine ant Diacamma sp. from Japan, however, all female workers have a pair of small thoracic appendages, called gemmae, which are homologous to the forewings and acts as an organ regulating altruism expression. Most workers, whose gemmae are clipped off by other colony members, become nonreproductive helpers, while only a single individual with complete gemmae becomes functionally reproductive. We examined histologically the development of gemmae, and compared it with that of functional wings in males. Female larvae had well-developed wing discs for both fore- and hindwings. At pupation, however, the wing discs started to evaginate and later degenerate. The hindwing discs completely degenerated, while the degeneration of forewing discs was incomplete, leading to the formation of gemmae. The degeneration process involved apoptotic cell death as confirmed by TUNEL assay. In addition, glandular cells differentiated from the epithelial cells of the forewing buds after completion of pupation. The mechanism of developmental transition from wing to gemma can be regarded as an evolutionary gain of new function, which can be seen in insect appendages and vertebrate limbs.Edited by P. Simpson     

On the sex-specific mechanisms of butterfly flight: flight performance relative to flight morphology, wing kinematics, and sex in Pararge aegeria

Many evolutionary ecological studies have documented sexual dimorphism in morphology or behaviour. However, to what extent a sex-specific morphology is used differently to realize a certain level of behavioural performance is only rarely tested. We experimentally quantified flight performance and wing kinematics (wing beat frequency and wing stroke amplitude) and flight morphology (thorax mass, body mass, forewing aspect ratio, and distance to centre of forewing area) in the butterfly Pararge aegeria (L.) using a tethered tarsal reflex induced flight set-up under laboratory conditions. On average, females showed higher flight performance than males, but frequency and amplitude did not differ. In both sexes, higher flight performance was partly determined by wing beat frequency but not by wing stroke amplitude. Dry body mass, thorax mass, and distance to centre of forewing area were negatively related to wing beat frequency. The relationship between aspect ratio and wing stroke amplitude was sex-specific: females with narrower wings produced higher amplitude whereas males show the opposite pattern. The results are discussed in relation to sexual differences in flight behaviour.  © 2006 The Linnean Society of London, Biological Journal of the Linnean Society , 2006, 89 , 675–687.     

The comparative morphology of the wings and axillae of selected Heteroptera

The wings of selected species are here treated as functional deformable aerofoils and their morphology described with this in mind. A novel type of non-tubular vein structure in the forewing and hindwing membranes, a 'channel vein', is described. The presence of small, cuticular membrane thickenings in the hindwing is recorded and their possible functions are discussed.
A comparative account of the structure and musculature of the axillae is presented with a view in particular to clarifying some of the associated terminology.
A mechanism for wing folding is described and previously unrecorded adaptations for this purpose seen in Notonecta are described and discussed.     

Structure and evolution of the stigmapophysis—A unique repose wing-coupling structure in Psocodea

The gain of foldable wings is regarded as one of the key innovations enabling the present-day diversity of neopteran insects. Wing folding allows compact housing of the wings and shields the insect body from damage. Wing-fixing systems have evolved in some insects, probably to increase the durability of the shielding function by the wings. Bark lice (Psocodea) are known to possess a unique wing-to-wing repose coupling system, but a detailed morphological and evolutionary study of this system is lacking. In this study, we examined this repose coupling structure by SEM in 32 species including representatives of all three suborders of bark lice (Trogiomorpha, Troctomorpha and Psocomorpha). We concluded that the repose wing-coupling apparatus independently evolved twice within Psocodea. In Trogiomorpha, the apparatus is located on the subcostal vein of the forewing and is composed of elongated rib-like structures. In Troctomorpha and Psocomorpha, in contrast, the repose coupling structure is located on the radius vein of the forewing and is formed by a swollen vein. These morphological and developmental differences in the repose coupling structures also provide phylogenetic information at different systematic levels.     

Evolutionary pattern of the forewing shape in the Neotropical genus of jumping plant-lice (Hemiptera: Psylloidea: <Emphasis Type="Italic">Russelliana</Emphasis>)

Geometric morphometric and phylogenetic analyses, applied to 43 species of Russelliana, shed light on the evolution of insect wing shape. Unconstrained and constrained ordination techniques are introduced to detect patterns of the forewing shape variation within genus. Results show a high congruence between forewing shape variation and host-plant preference supporting monophyly of most phylogenetic groups in Russelliana. Reconstruction of the ancestral forewing state shows its similarity to a forewing shape of Solanaceae feeding species defined as ancestors by the phylogenetic study supporting a hypothesis as to a primary association of Russelliana with Solanaceae. In contrast to some other comparative studies on insect wing shape, results of the present study reveal a strong correlation between variation of forewing shape in Russelliana and its phylogeny. Potential influence of vicariant events and host shifts on the evolution of forewing shape is discussed.     

Resilin in dragonfly and damselfly wings and its implications for wing flexibility

Although there is mounting evidence that passive mechanical dynamics of insect wings play an integral role in insect flight, our understanding of the structural details underlying insect wing flexibility remains incomplete. Here, we use comparative morphological and mechanical techniques to illuminate the function and diversity of two mechanisms within Odonata wings presumed to affect dynamic wing deformations: flexible resilin vein‐joints and cuticular spikes. Mechanical tests show that joints with more resilin have lower rotational stiffness and deform more in response to a load applied to an intact wing. Morphological studies of 12 species of Odonata reveal that resilin joints and cuticular spikes are widespread taxonomically, yet both traits display a striking degree of morphological and functional diversity that follows taxonomically distinct patterns. Interestingly, damselfly wings (suborder Zygoptera) are mainly characterized by vein‐joints that are double‐sided (containing resilin both dorsally and ventrally), whereas dragonfly wings (suborder Epiprocta) are largely characterized by single‐sided vein‐joints (containing resilin either ventrally or dorsally, but not both). The functional significance and diversity of resilin joints and cuticular spikes could yield insight into the evolutionary relationship between form and function of wings, as well as revealing basic principles of insect wing mechanical design. J. Morphol., 2011. © 2011 Wiley‐Liss, Inc.     

Sexual dimorphism and intraspecific variation in wing size and shape of Tongeia fischeri (Lepidoptera: Lycaenidae)

Wing morphological variations are described here for the lycaenid butterfly Tongeia fischeri. A landmark‐based geometric morphometric approach based on wing venation of 197 male and 187 female butterflies collected in Japan was used to quantify wing size and shape variations between sexes and among populations. Sexual dimorphism in wing size and shape was detected. Females had significantly larger wings than males, while males showed a relatively elongated forewing with a longer apex and narrower wing tornus in comparison to females. Intraspecific variations in wing morphology among populations were revealed for the wing shape, but not wing size. Distinct wing shape differences were found in the vein intersections area around the distal part of the discal cell where median veins originated in the forewing and around the origin of the CU1 vein in the hindwing. In addition, phenotypic relationships inferred from wing shape variations grouped T. fischeri populations into three groups, reflecting the subspecies classification of the species. The spatial variability and phenotypic relationships between conspecific populations of T. fischeri detected here are generally in agreement with the previous molecular study based on mitochondrial and nuclear sequences, suggesting the presence of a phylogenetic signal in the wing shape of T. fischeri, and thus having taxonomic implications.     

The wing vestiture of the non-ditrysian Lepidoptera (Insecta). Comparative morphology and phylogenetic implications

The ultrastructure of the dorsal forewing vestiture in exemplars of all family group taxa of non‐ditrysian Lepidoptera is examined, and the evolutionary implications at family level and above are discussed. Wing‐scale terminology is reviewed. Three different types of bilayer wing‐scale covering are recognized; only a few groups have a single‐layer wing‐scale covering. The general scale arrangement is random, but a few taxa have clustered scale arrangements and scattered heteroneurans have scales arranged in transverse rows. Cross ribs are present in all taxa, but only as vestiges in eriocraniid cover scales. Ridge dimorphism is widespread in Neolepidoptera. Surprisingly, ridges and cross ribs on the adwing scale surface are of general occurrence in Neopseustidae and Hepialidae, and are even found on parts of the ground scales of many other Neolepidoptera. Morphological evidence strongly indicates that the fused wing‐scale types found in non‐Coelolepidan Lepidoptera and Neolepidoptera are independently evolved, as evidenced from the presence of vestigial perforations. Absence of perforations is not infallible evidence that a scale is solid. Microtrichia are independently reduced in a number of taxa and probably re‐evolved in at least higher nepticulids. Wing vestiture and scale characters indicate that Tischerioidea may be the sister group of Ditrysia.     

Phylogenesis of spermatogenesis in Annulipalpia caddisflies: An ultrastructural analysis on philopotamidae spermiogenesis

Characters currently used in phylogenetic analyses are insufficient for determining the status of several families of the order Trichoptera (caddisflies). Comparative spermatology can contribute to solving this problem. In the suborder Integripalpia, the sperm axoneme displays the pattern of 9 + 2 pairs of parallel microtubules found in many animal species. In the suborder Annulipalpia, however, axonemes bear remarkable aberrations. Consistently, in Chimarra florida (Philopotamidae, Annulipalpia) we found that the number of central microtubules varies from zero to four in axonemes of the spermatids and that spermatozoa lack axonemes. We propose that, similarly, the axoneme pattern became unstable in the Annulipalpia ancestor, from which branched two phylogenetic lines having different kinds of axoneme aberrations: (a) families in which the number of central microtubules of the axoneme exceeds two (e.g., Philopotamidae, Polycentropodidae) and (b) families in which the number of central microtubules of the axoneme does not exceed two (e.g., Hydropsychidae).     

Evidence for Carboniferous origin of the order Mantodea (Insecta: Dictyoptera) gained from forewing morphology

Homologies of the forewing venation pattern of the order Mantodea (Insecta: Dictyoptera) consistent with the accepted insect wing venation groundplan are proposed. A comparative morphological analysis was carried out based on a broad taxonomic sample of extant taxa. Besides macromorphological aspects, focus is given to the pattern of the tracheal system as a basis for establishing primary homologies. All extant praying mantids exhibit a composite stem composed of the posterior radius (RP) and the media (M) and most praying mantids exhibit a fusion of the anterior branch of RP + M with the anterior radius (RA). The wing venation of the species ?Mesoptilus dolloi, previously assigned to the polyphyletic fossil assemblage ‘Protorthoptera’, is re‐interpreted in the light of the new homology statement. Our interpretation suggests that it is a putative stem‐Mantodea, as are some other ‘protorthopterous’ taxa. This hypothesis implies that the total‐group Mantodea arose as soon as the Late Carboniferous, i.e. about 175 million years earlier than previously estimated. This analysis contributes to the view that most of the Late Carboniferous ‘Protorthoptera’ are stem‐representatives of the major polyneopteran clades (e.g. cockroaches, grasshoppers and crickets, rock‐crawlers), suggesting a survivorship of several main Pterygota lineages at the end‐Permian extinction event higher than previously expected. © 2009 The Linnean Society of London, Zoological Journal of the Linnean Society, 2009, 156 , 79–113.     

Three‐dimensional geometry of a pterosaur wing skeleton,and its implications for aerial and terrestrial locomotion

This study reports on the three‐dimensional spatial arrangement and movements of the skeleton of Anhanguera santanae (Pterodactyloidea: Ornithocheiridae), determined using exceptionally well‐preserved uncrushed fossil material, and a rigid‐body method for analysing the joints of extinct animals. The geometric results of this analysis suggest that the ornithocheirids were inherently unstable in pitch and yaw. As a result, pitch control would probably have been brought about by direct adjustment of the angle of attack of the wing, by raising or lowering the trailing edge from the root using the legs if, as is indicated in soft‐tissue specimens of a number of unrelated pterosaur species, the legs were attached to the main wing membrane, or by using long‐axis rotations at the shoulder or wrist to raise and lower the trailing edge from the wingtip. An analysis of the three‐dimensional morphology of the wrist lends support to the idea that the pteroid – a long, slender wrist bone unique to pterosaurs that supported a membranous forewing – was directed forwards in flight, not towards the body. As a result, the forewing could have fulfilled the function of an air‐brake and high‐lift device, and may also have had an important role in pitch, yaw, and roll control. The joint analysis is consistent with a semi‐erect quadrupedal model of terrestrial locomotion in the ornithocheirids. © 2008 The Linnean Society of London, Zoological Journal of the Linnean Society, 2008, 154 , 27–69.     

Phylogenetic position of rhyacophiloid caddisflies (Insecta, Trichoptera): a spermatological analysis of Rhyacophilidae and Glossosomatidae

Most caddisflies (Insecta, Trichoptera) are classified into two suborders, Annulipalpia and Integripalpia. However, the use of the derived characters that are regularly applied in systematic and phylogenetic analyses of Trichoptera is insufficient to determine with certainty the position of the families belonging to Rhyacophiloidea, which are considered by different authors to be either Annulipalpia, or Integripalpia, or even a separate suborder. Rhyacophiloidea comprise four overall similar families: free-living Rhyacophilidae and Hydrobiosidae, saddle-case making Glossosomatidae, and purse-case making Hydroptilidae. It was previously found that Annulipalpia spermatozoa have aberrant axonemes while Integripalpia spermatozoa display the plesiomorph 9 + 2 axoneme. The present spermatological analysis of the families Rhyacophilidae and Glossosomatidae shows that both have spermatozoa with aberrant axonemes lacking the two central microtubules found in the typical axoneme of insect spermatozoa. This is an apomorphic character shared with the superfamily Hydropsychoidea, indicating that from this point of view, Rhyacophiloidae are more closely related to Annulipalpia than to Integripalpia.     

Support and deformability in insect wings

Coupled investigations of insect wing movements and detailed wing morphology are in progress, and some functional principles underlying wing design are emerging. High speed cine and still photography and stroboscopy indicate that most wings undergo orderly deformation in flight. Common patterns are described and their significance discussed in the light of recent aerodynamic studies.
Many aspects of wing morphology–venational features, relief, thickened areas, flexionlines and vein fractures–may be related to the control of three-dimensional shape while beating. It is usually possible to distinguish areas specialized for deformability, and for support and the limiting of deformation. Some structural adaptations for these roles are described and illustrated.     

Mate-locating strategies are related to relative body length and wing colour in the speckled wood butterfly Pararge aegeria

1. The mate-locating strategies of Pararge aegeria (L.) males were studied in relation to adult morphology (dorsal wing colour, forewing length, body length and forewing length : body length ratio) and generation.
2. Males locate females either by perching and defending territories, or by patrolling. Individuals were more consistent in their mating strategies than expected by chance.
3. Forewing length : body length ratio was positively correlated with thorax mass : body mass; relatively short-bodied males had relatively heavy thoraxes. Therefore, forewing length : body length ratio was an index of mass allocation.
4. Perching males had higher forewing length : body length ratios and were paler than patrolling males.
5. The higher forewing length : body length ratio was due to the differences in body length and not wing length. Perchers had shorter bodies than patrollers.