Echo feedback mediates noise-induced vocal modifications in flying bats

Call production and wingbeat coupling is flexible and species-specific in echolocating bats

Echolocation and flight are two key behavioral innovations that contribute to the evolutionary success and diversification of bats, which are classified phylogenetically into two suborders: Yinpterochiroptera and Yangochiroptera. Considerable research has identified a coupling between call production and wingbeat in flying bats, although only a few have quantified the relationship and all were restricted to bats from the suborder Yangochiroptera. Here, we quantitatively compared the coupling between call production and wingbeat in two representative species of bats, Hipposideros pratti of the suborder Yinpterochiroptera and Myotis pilosus of the suborder Yangochiroptera, under identical experimental settings. We found that (1) both species exhibited the temporal coupling of call production and wingbeat; (2) the degree of coupling is species-specific, with M. pilosus showing a tighter coupling between call timing and wingbeat cycle than H. pratti; (3) the coupling is a plastic trait, as evidenced by the effect of environmental clutter in H. pratti; and (4) there is no evidence that the coupling of call production and wingbeat limits the source level control in either species. We suggest that the coupling between call production and wingbeat is flexible and species-specific, which may not compromise precise echolocation control in bats.

From mechanoecology to sensory physiology to olfactory navigation: the Editors' and Readers' Choice Awards 2025

In celebration of the excellence of articles published in the Journal of Comparative Physiology A, Editors' and Readers' Choice Awards are annually conferred to the top papers in the categories Original Research Paper and Review/Review-History Article. The recipients of the 2025 Editors' Choice Awards were selected based on votes cast by the Editorial Board on articles published in 2024. In the category Original Research Paper, this distinction goes to 'Tonotopic Ca2+ dynamics and sound processing in auditory interneurons of the bush-cricket Mecopoda elongata' by Timothy Bayley and Berthold Hedwig (J Comp Physiol A 210:353-369, 2024). In the category Review/Review-History Article, this distinction goes to 'Mechanoecology: biomechanical aspects of insect-plant interactions' by Gianandrea Salerno, Manuela Rebora, Elena Gorb, and Stanislav Gorb (J Comp Physiol A 210:249-265, 2024). The winners of the 2025 Readers' Choice Awards were determined by the number of online accesses of articles published in 2023. In the category Original Research Paper, the winner is 'Coleoptera claws and trichome interlocking' by Gianandrea Salerno, Manuela Rebora, Silvana Piersanti, Valerio Saitta, Elena Gorb, and Stanislav Gorb (J Comp Physiol A 209:299-312, 2023). In the category Review/Review-History Article, the winner is 'Olfactory navigation in arthropods' by Theresa J. Steele, Aaron J. Lanz, and Katherine I. Nagel (J Comp Physiol A 209:467-488, 2023), which already won the Editors' Choice Award in 2024.

Prevalent Harmonic Interaction in the Bat Inferior Colliculus

Animal vocalizations and human speech are typically characterized by a complex spectrotemporal structure, composed of multiple harmonics, and patterned as temporally organized sequences. However, auditory research often employed simple artificial acoustic stimuli or their combinations. Here we addressed the question of whether the neuronal responses to natural echolocation call sequences can be predicted by manipulated sequences of incomplete constituents at the midbrain inferior colliculus (IC). We characterized the extracellular single-unit activity of IC neurons in the great roundleaf bat, Hipposideros armiger (both sexes), using natural call sequences, various manipulated sequences of incomplete vocalizations, and pure tones. We report that approximately two-thirds of IC neurons exhibited a harmonic interaction. Neurons with high harmonic interactions exhibited greater selectivity to natural call sequences, and the degree of harmonic interaction was robust to the natural amplitude variations between call harmonics. For 81% of the IC neurons, the responses to the natural echolocation call sequence could not be predicted by altered sequences of missing call components. Surprisingly, nearly 70% of the neurons that showed a harmonic interaction were characterized by a single excitatory response peak as revealed by pure tones. Our results suggest that prevalent harmonic processing has already emerged in the auditory midbrain IC in the echolocating bat.

Superfast Lombard response in free-flying, echolocating bats

Acoustic cues are crucial to communication, navigation, and foraging in many animals, which hence face the problem of detecting and discriminating these cues in fluctuating noise levels from natural or anthropogenic sources. Such auditory dynamics are perhaps most extreme for echolocating bats that navigate and hunt prey on the wing in darkness by listening for weak echo returns from their powerful calls in complex, self-generated umwelts.1,2 Due to high absorption of ultrasound in air and fast flight speeds, bats operate with short prey detection ranges and dynamic sensory volumes,3 leading us to hypothesize that bats employ superfast vocal-motor adjustments to rapidly changing sensory scenes. To test this hypothesis, we investigated the onset and offset times and magnitude of the Lombard response in free-flying echolocating greater mouse-eared bats exposed to onsets of intense constant or duty-cycled masking noise during a landing task. We found that the bats invoked a bandwidth-dependent Lombard response of 0.1-0.2 dB per dB increase in noise, with very short delay and relapse times of 20 ms in response to onsets and termination of duty-cycled noise. In concert with the absence call time-locking to noise-free periods, these results show that free-flying bats exhibit a superfast, but hard-wired, vocal-motor response to increased noise levels. We posit that this reflex is mediated by simple closed-loop audio-motor feedback circuits that operate independently of wingbeat and respiration cycles to allow for rapid adjustments to the highly dynamic auditory scenes encountered by these small predators.

Daubenton's bats maintain stereotypical echolocation behaviour and a lombard response during target interception in light

Most bats hunt insects on the wing at night using echolocation as their primary sensory modality, but nevertheless maintain complex eye anatomy and functional vision. This raises the question of how and when insectivorous bats use vision during their largely nocturnal lifestyle. Here, we test the hypothesis that the small insectivorous bat, Myotis daubentonii, relies less on echolocation, or dispenses with it entirely, as visual cues become available during challenging acoustic noise conditions. We trained five wild-caught bats to land on a spherical target in both silence and when exposed to broad-band noise to decrease echo detectability, while light conditions were manipulated in both spectrum and intensity. We show that during noise exposure, the bats were almost three times more likely to use multiple attempts to solve the task compared to in silent controls. Furthermore, the bats exhibited a Lombard response of 0.18 dB/dBnoise and decreased call intervals earlier in their flight during masking noise exposures compared to in silent controls. Importantly, however, these adjustments in movement and echolocation behaviour did not differ between light and dark control treatments showing that small insectivorous bats maintain the same echolocation behaviour when provided with visual cues under challenging conditions for echolocation. We therefore conclude that bat echolocation is a hard-wired sensory system with stereotyped compensation strategies to both target range and masking noise (i.e. Lombard response) irrespective of light conditions. In contrast, the adjustments of call intervals and movement strategies during noise exposure varied substantially between individuals indicating a degree of flexibility that likely requires higher order processing and perhaps vocal learning.

Effects of insect pursuit on the Doppler shift compensation in a hipposiderid bat

Doppler shift compensation (DSC) is a unique feature observed in certain species of echolocating bats and is hypothesized to be an adaptation to detecting fluttering insects. However, current research on DSC has primarily focused on bats that are not engaged in foraging activities. In this study, we investigated the DSC performance of Pratt's roundleaf bat, Hipposideros pratti, which was trained to pursue insects in various motion states within a laboratory setting. Our study yielded three main results. First, H. pratti demonstrated highly precise DSC during insect pursuit, aligning with previous findings of other flutter-detecting foragers during orientation or landing tasks. Second, we found that the motion state of the insect prey had little effect on the DSC performance of H. pratti. Third, we observed variations in the DSC performance of H. pratti throughout the course of insect pursuit. The bats exhibited the highest DSC performance during the phase of maximum flight speed but decreased performance during the phase of insect capture. These findings of high precision overall and the time-dependent performance of DSC during insect pursuit support the hypothesis that DSC is an adaptation to detecting fluttering insects.

Neuroethology of auditory systems: contributions in memory of Albert S. Feng

Albert (Al) S. Feng (1944 - 1921) was a pioneer in the area of neuroethology of auditory systems. This special issue of the Journal of Comparative Physiology A commemorates his life and work by presenting 15 articles written by friends, students, and colleagues, many of whom have become leading experts themselves in this field. Their contributions not only provide a comprehensive overview of bioacoustics in amphibians and mammals (including bats), but also are intended to inspire a new generation of scientists to advance our understanding of brain mechanisms of acoustic perception.