Temporal and geographic variations in the morphology and chemical composition of the frontal gland in imagoes of Prorhinotermes species (Isoptera: Rhinotermitidae)

Although the frontal gland has long been known as a prominent defensive device for termite soldiers in many Rhinotermitidae and Termitidae, almost nothing is known about its function in imagoes. In the present study, we show that the frontal gland of imagoes in Prorhinotermes species is well developed at the time of the nuptial flight, and is filled with a complex mixture of sesquiterpene hydrocarbons and nitroalkenes. The sesquiterpene composition varies between Prorhinotermes simplex and Prorhinotermes canalifrons , between geographically distant colonies of P. simplex (Cuba versus Florida), and even between different flights of closely-related subcolonies. The ratio between ( E )-1-nitropentadec-1-ene and sesquiterpenes is sex-specific. The volume of secretory cells decreases in functional kings and queens after colony foundation, and the subcellular organization changes into a form resembling unmodified epidermal cells. Dealate reproductives lose the ability for biosynthesis, and their frontal gland is devoid of volatile compounds found in swarming imagoes. The results obtained in the present study clearly show that the frontal gland is only temporarily active at the time of the dispersal flight. The most likely function of this gland is defence by the toxic nitroalkenes.  © 2009 The Linnean Society of London, Biological Journal of the Linnean Society , 2009, 98 , 384–392.     

Anatomy of the coracoid and diversity of the Procellariiformes (Aves) in the Oligocene of Europe

Abstract: Two European species of the Diomedeoididae, an extinct family of procellariiform (tube‐nose) birds, have hitherto been distinguished primarily by size of their limb bones. Here, we describe an Early Oligocene (Rupelian) procellariifom coracoid that in all probability represents the larger species, Diomedeoides lipsiensis, and compare it to the coracoids of smaller diomedeoidids and extant procellariiforms. Using multivariate (Principal Component Analysis) and univariate analyses, we demonstrate that nearly all measurements are heavily size dependent, which makes the proportions and some other shape characters of little use as phylogenetic markers. Among eight measurements, the coracoid corpus width shows the highest correlation (higher than corpus depth) with body mass, permitting a precise calculation of over twofold difference in body mass between D. lipsiensis and smaller species. Among 16 qualitative characters analysed, the majority proved too variable to be used as markers of interfamily relationships and only 2–3, the ventral intermuscular line, sternocoracoid articulation (divided vs. undivided), and, with reservations, epimarginal crest vary consistently between the families. By far the most variable is the acrocoracoid process that tends to be deeper (more elongate dorsoventrally) in larger petrels but not in the albatrosses. However, the detailed shapes of the acrocoracoid heads are highly genus specific and suggest a genus‐level diversity among the Diomedeoididae from the Oligocene of Europe. The common features of the diomedeoidid coracoids are best interpreted as plesiomorphies, which accounts for some similarities to the Oceanitinae (that are probably basal among the crown‐group procellariiforms). The evidence from the coracoid is consistent with a stem‐group position of the Diomedeoididae as previously proposed by others. We emphasize the need of a group‐specific character analysis, primarily of allometries and levels of character variation, prior to a phylogenetic reconstruction.     

Cuticular hydrocarbon profiles of codling moth larvae,Cydia pomonella (Lepidoptera: Tortricidae), reflect those of their host plant species

The cuticular hydrocarbons (CHCs) of codling moth larvae collected in the field from their host plant species, apple and walnut, were analyzed and compared with the CHCs of fruits from these two phylogenetically distant hosts. The CHC profiles of the larvae consisted solely of n‐alkanes (C₂₃–C₃₁) and differed quantitatively between host populations. Amounts of the CHCs from the walnut‐collected larvae were shifted towards longer‐chain alkanes compared to those from apple‐collected larvae. A similar shift was observed for the CHC profiles of walnut and apple fruits. Analysis of the CHCs of larvae reared on artificial diet, in comparison with hydrocarbons from the diet, confirmed that larval CHCs scarcely reflect hydrocarbons from the food source. This finding indicates that the larval hydrocarbons must be biosynthesized to a large degree by the insect, rather than being gained directly from its diet. Hence, codling moth populations from apple and walnut each synthesize their own CHC profiles, which largely resemble those of their respective host plant, yielding a potential tool of chemical camouflage from certain natural antagonists of the larvae. The findings of the present study, together with recent molecular population analyses, provides evidence for a process that might ultimately lead to sympatric speciation of this herbivore species. © 2010 The Linnean Society of London, Biological Journal of the Linnean Society, 2010, 101 , 376–384.