Your search keyword '"D. E. Canale"' showing total 2 results

1. First evidence of underwater sounds emitted by the living fossils Lepidurus lubbocki and Triops cancriformis (Branchiopoda: Notostraca)

Author

Elena Papale, F. Marrone, Maria Ceraulo, D. E. Canale, Giuseppa Buscaino, Buscaino G., Ceraulo M., Canale D.E., Papale E., and Marrone F.

Subjects

0106 biological sciences, Passive acoustic monitoring, QH301-705.5, Settore BIO/05 - Zoologia, Branchiopoda, Zoology, Aquatic Science, Oceanography, 010603 evolutionary biology, 01 natural sciences, Microbiology, Notostraca, Biology (General), Ecology, Evolution, Behavior and Systematics, Lepidurus, Sounds, Ecology, biology, 010604 marine biology & hydrobiology, biology.organism_classification, Temporal pattern, QR1-502, Triops cancriformis, Living fossil

Abstract

Sound is the most effective means of communication in marine and freshwater ecosystems. However, no data about acoustic emissions from non-malacostracan crustaceans are currently available, so their ability to produce sounds is unknown. For the first time, this study investigated the sound produced by 2 tadpole shrimp species,Triops cancriformisandLepidurus lubbocki.L. lubbockiindividuals were collected from a natural temporary pond in Sicily (Italy), whereasT. cancriformisindividuals were obtained from eggs contained in sediment from a rock pool in Sardinia (Italy). In the laboratory, experimental tanks with the animals (one species at a time) were acoustically monitored. Both species produced high-frequency, wideband pulses distinguishable by their sound pressure level, which was higher inL. lubbocki(146 dB) than inT. cancriformis(130 dB), and by their first and second peak frequencies, which were higher inL. lubbocki(65 and 86 kHz) than inT. cancriformis(63 and 71 kHz). The energy distributions in the power density spectra showed different shapes, as revealed by the 3 dB bandwidth and centre frequency. The pulse durations were 88 and 97 µs inL. lubbockiandT. cancriformis, respectively.L. lubbockipresented a higher emission rate thanT. cancriformisand a marked circadian pattern, with a higher abundance of sounds during the night. This study reports the first evidence of sound emissions from non-malacostracan crustaceans and reveals the high potential of passive acoustic monitoring to detect the presence, abundance, and life cycle of these elusive keystone species of temporary water bodies.

Published

2021

2. Spatio-temporal distribution and acoustic characterization of haddock (Melanogrammus aeglefinus, Gadidae) calls in the Arctic fjord Kongsfjorden (Svalbard Islands)

Author

D. E. Canale, Marta Picciulin, Salvatore Mazzola, Giuseppa Buscaino, Rosario Grammauta, Maria Ceraulo, and Elena Papale

Subjects

0106 biological sciences, Male, Conservation of Natural Resources, Periodicity, Behavioural ecology, Population, Population Dynamics, Settore BIO/05 - Zoologia, lcsh:Medicine, Fjord, 010603 evolutionary biology, 01 natural sciences, Article, Svalbard, Spatio-Temporal Analysis, Animals, education, lcsh:Science, Diel vertical migration, Atlantic Ocean, education.field_of_study, geography, Multidisciplinary, geography.geographical_feature_category, biology, Arctic Regions, 010604 marine biology & hydrobiology, lcsh:R, Haddock, Acoustics, Gadidae, biology.organism_classification, The arctic, Gadiformes, Oceanography, Arctic, Echolocation, Sound analysis, Female, lcsh:Q, Seasons, Vocalization, Animal, Geology

Abstract

In this study we analysed the acoustic properties and presence of haddock calls in the Arctic fjord Kongsfjorden (79° N–12° E, Svalbard Islands, Norway) in one year. Data were collected with three autonomous acoustic recorders located in the inner, middle, and outer parts of the fjord. The fjord is characterized by a gradient of oceanographic conditions from the inner to the outer part, reflecting changes from Arctic to Atlantic waters. Haddock sounds were more abundant in the outer fjord than in the middle fjord, whereas they were absent at the inner site. Mainly at the open-water site, the call abundance exhibited strong periodicity and a correlation with the cycles of neap tide (15 days) in August, with a clear diel cycle (24 h) in September and October. This result suggests that in this extreme environment with 24 h of light during summer, haddock regulate their acoustic activity according to the main available oscillating external physical driver, such as tide during the polar summer, while when the alternation of light/dark starts, they shift the periodicity of their calls to a diel cycle. Calls were recorded outside the spawning period (from July to October), and their characteristics indicated non-reproductive communicative contests. By using a detailed sound analysis based on previous laboratory studies for the first time, we suggest that the monitored population contains mainly juveniles (44% compared to 41% females and only approximately 15% mature males), showing the predominance of females in the middle fjord and juveniles at the open-water site.

Published

2020