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1. Flexural rigidity of hawkmoth antennae depends on the bending direction

   https://doi.org/10.1016/j.actbio.2024.06.036  

   Puchalski, Adam; McCarthy, Zoë; Palaoro, Alexandre Varaschin; Salamatin, Arthur A; Nagy-Mehesz, Agnes; Korneva, Guzeliya; Beard, Charles E; Owens, Jeffery; Adler, Peter H; Kornev, Konstantin G (August 2024, Acta Biomaterialia)

   Wagner, William R (Ed.)

   To probe its environment, the flying insect controllably flexes, twists, and maneuvers its antennae by coupling mechanical deformations with the sensory output. We question how the materials properties of insect antennae could influence their performance. A comparative study was conducted on four hawkmoth species: Manduca sexta, Ceratomia catalpae, Manduca quinquemaculata, and Xylophanes tersa. The morphology of the antennae of three hawkmoths that hover while feeding and one putatively non-nectar-feeding hawkmoth (Ceratomia catalpa) do not fundamentally differ, and all the antennae are comb-like (i.e., pectinate), markedly in males but weakly in females. Applying different weights to the free end of extracted cantilevered antennae, we discovered anisotropy in flexural rigidity when the antenna is forced to bend dorsally versus ventrally. The flexural rigidity of male antennae was less than that of females. Compared with the hawkmoths that hover while feeding, Ceratomia catalpae has almost two orders of magnitude lower flexural rigidity. Tensile tests showed that the stiffness of male and female antennae is almost the same. Therefore, the differences in flexural rigidity are explained by the distinct shapes of the antennal pectination. Like bristles in a comb, the pectinations provide extra rigidity to the antenna. We discuss the biological implications of these discoveries in relation to the flight habits of hawkmoths. Flexural anisotropy of antennae is expected in other groups of insects, but the targeted outcome may differ. Our work offers promising new applications of shaped fibers as mechanical sensors. 

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2. Challenges in Modeling Pheromone Capture by Pectinate Antennae

   https://doi.org/10.1093/icb/icaa057  

   Jaffar-Bandjee, Mourad; Krijnen, Gijs; Casas, Jérôme (June 2020, Integrative and Comparative Biology)

   null (Ed.)

   Synopsis Insect pectinate antennae are very complex objects and studying how they capture pheromone is a challenging mass transfer problem. A few works have already been dedicated to this issue and we review their strengths and weaknesses. In all cases, a common approach is used: the antenna is split between its macro- and microstructure. Fluid dynamics aspects are solved at the highest level of the whole antenna first, that is, the macrostructure. Then, mass transfer is estimated at the scale of a single sensillum, that is, the microstructure. Another common characteristic is the modeling of sensilla by cylinders positioned transversal to the flow. Increasing efforts in faithfully modeling the geometry of the pectinate antenna and their orientation to the air flow are required to understand the major advantageous capture properties of these complex organs. Such a model would compare pectinate antennae to cylindrical ones and may help to understand why such forms of antennae evolved so many times among Lepidoptera and other insect orders. 

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3. Systematic morphological andmorphometricanalysisofidentified olfactory receptor neurons in Drosophila melanogaster

   https://doi.org/10.1101/2021.04.28.441861  

   Gonzales, Cesar Nava; McKaughan, Quintyn; Bushong, Eric A; Cauwenberghs, Kalyani; Ng, Renny; Madany, Matthew; Ellisman, Mark H; Su, Chih-Ying (April 2021, bioRxiv)

   null (Ed.)

   The biophysical properties of sensory neurons are influenced by their morphometric and morphological features, whose precise measurements require high-quality volume electron microscopy (EM). However, systematic surveys of these nanoscale characteristics for identified neurons are scarce. Here, we characterize the morphology of Drosophila olfactory receptor neurons (ORNs) across the majority of genetically identified sensory hairs.By analyzing serial block-face electron microscopy (SBEM) images of cryo fixed antennal tissues, we compile an extensive morphometric dataset based on 122reconstructed 3D models of 33 identifiedORN types.In addition, we observe multiple novel features—including extracellular vacuoles within sensillum lumen, intricate dendritic branching,mitochondria enrichment in select ORNs, novel sensillum types, and empty sensilla containing no neurons—which raise new questions pertinent to cell biology and sensory neurobiology.Our systematic survey is critical for future investigations into how the size and shape of sensory neurons influence their responses, sensitivity and circuit function. 

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4. Identification of a Female-Produced Sex Attractant Pheromone of the Winter Firefly, Photinus corruscus Linnaeus (Coleoptera: Lampyridae)

   https://doi.org/10.1007/s10886-023-01417-2  

   Lower, Sarah E.; Pask, Gregory M.; Arriola, Kyle; Halloran, Sean; Holmes, Hannah; Halley, Daphné C.; Zheng, Yiyu; Collins, Douglas B.; Millar, Jocelyn G. (April 2023, Journal of Chemical Ecology)

   Abstract Firefly flashes are well-known visual signals used by these insects to find, identify, and choose mates. However, many firefly species have lost the ability to produce light as adults. These “unlighted” species generally lack developed adult light organs, are diurnal rather than nocturnal, and are believed to use volatile pheromones acting over a distance to locate mates. While cuticular hydrocarbons, which may function in mate recognition at close range, have been examined for a handful of the over 2000 extant firefly species, no volatile pheromone has ever been identified. In this study, using coupled gas chromatography - electroantennographic detection, we detected a single female-emitted compound that elicited antennal responses from wild-caught male winter fireflies,Photinus corruscus. The compound was identified as (1S)-exo-3-hydroxycamphor (hydroxycamphor). In field trials at two sites across the species’ eastern North American range, large numbers of maleP. corruscuswere attracted to synthesized hydroxycamphor, verifying its function as a volatile sex attractant pheromone. Males spent more time in contact with lures treated with synthesized hydroxycamphor than those treated with solvent only in laboratory two-choice assays. Further, using single sensillum recordings, we characterized a pheromone-sensitive odorant receptor neuron in a specific olfactory sensillum on maleP. corruscusantennae and demonstrated its sensitivity to hydroxycamphor. Thus, this study has identified the first volatile pheromone and its corresponding sensory neuron for any firefly species,and provides a tool for monitoringP. corruscuspopulations for conservation and further inquiry into the chemical and cellular bases for sexual communication among fireflies. 

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5. Wing–antenna interaction reduces odour fatigue in butterfly odour-tracking flight

   https://doi.org/10.1017/jfm.2024.644  

   Lou, Zhipeng; Lei, Menglong; Dong, Haibo; Li, Chengyu (November 2024, Journal of Fluid Mechanics)

   Flying insects exhibit remarkable capabilities in coordinating their olfactory sensory system and flapping wings during odour plume-tracking flights. While observations have indicated that their flapping wing motion can ‘sniff’ up the incoming plumes for better odour sampling range, how flapping motion impacts the odour concentration field around the antennae is unknown. Here, we reconstruct the body and wing kinematics of a forwards-flying butterfly based on high-speed images. Using an in-house computational fluid dynamics solver, we simulate the unsteady flow field and odourant transport process by solving the Navier–Stokes and odourant advection-diffusion equations. Our results show that, during flapping flight, the interaction between wing leading-edge vortices and antenna vortices strengthens the circulation of antenna vortices by over two-fold compared with cases without flapping motion, leading to a significant increase in odour intensity fluctuation along the antennae. Specifically, the interaction between the wings and antennae amplifies odour intensity fluctuations on the antennae by up to 8.4 fold. This enhancement is critical in preventing odour fatigue during odour-tracking flights. Further analysis reveals that this interaction is influenced by the inter-antennal angle. Adjusting this angle allows insects to balance between resistance to odour fatigue and the breadth of odour sampling. Narrower inter-antennal angles enhance fatigue resistance, while wider angles extend the sampling range but reduce resistance. Additionally, our findings suggest that while the flexibility of the wings and the thorax's pitching motion in butterflies do influence odour fluctuation, their impact is relatively secondary to that of the wing–antenna interaction. 

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