Your search keyword '"Maria Wilson"' showing total 7 results

1. Induced quiescence in eggs of the tropical calanoid copepod Acartia tropica : Effect of different storage conditions

Author

Jess Maria Wilson, Bhaskaran Pillai Santhosh, Boby Ignatius, Paramita Banerjee Sawant, and Narinder Kumar Chadha

Subjects

biology, Cryoprotectant, Zoology, Cold storage, Aquatic Science, biology.organism_classification, Acartia, Copepod

Published

2021

2. Effect of adult density on egg production, egg hatching success, adult mortality, nauplii cannibalism and population growth of the tropical calanoid copepod Acartia tropica

Author

Paramita Banerjee Sawant, Boby Ignatius, Jess Maria Wilson, S. Anju Soma, and B Santhosh

Subjects

Animal science, Hatching, embryonic structures, Significant difference, Cannibalism, Population growth, Aquatic Science, Biology, biology.organism_classification, Acartia, Copepod

Abstract

Present study evaluated the impacts of adult density on key biological parameters of a tropical estuarine calanoid copepod A. tropica. Egg production, egg hatching success (EHS), adult mortality (%), nauplii cannibalism (% hour−1), population growth and intrinsic rate of population increase in response to five different adult densities viz. 125, 250, 500, 1000 and 2000 adults/L were assessed. The highest individual egg production (IEP, eggs/female/day) was recorded at 125 adults/L treatment while relative egg production (REP, eggs/L/day) was highest at 1000 adults/L. EHS (24 h and 48 h) showed significant difference (p

Published

2022

3. Behavioural responses to infrasonic particle acceleration in cuttlefish

Author

Jens Ådne Rekkedal Haga, Hans Erik Karlsen, and Maria Wilson

Subjects

030110 physiology, 0106 biological sciences, 0301 basic medicine, Cuttlefish, Physiology, Infrasound, Decapodiformes/physiology, Acceleration, Zoology, Escape response, Aquatic Science, Stimulus (physiology), Biology, Sepia officinalis, 010603 evolutionary biology, 01 natural sciences, Particulate Matter/analysis, Predation, 03 medical and health sciences, Suction feeding, Hearing, Escape Reaction, medicine, Animals, Inner ear, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Predator-prey interaction, Striking predator, Decapodiformes, Particle acceleration, medicine.anatomical_structure, Insect Science, Predatory Behavior, Darkness, Hydrodynamics, Particulate Matter, Animal Science and Zoology

Abstract

Attacks by aquatic predators generate frontal water disturbances characterised by low-frequency gradients in pressure and particle motion. Low-frequency hearing is highly developed in cephalopods. Thus, we examined behavioural responses in juvenile cuttlefish to infrasonic accelerations mimicking main aspects of the hydrodynamic signals created by predators. In the experimental set-up, animals and their surrounding water moved as a unit to minimise lateral line activation and to allow examination of the contribution by the inner ear. Behavioural responses were tested in light versus darkness and after food deprivation following a ‘simulated’ hunting opportunity. At low acceleration levels, colour change threshold at 3, 5 and 9 Hz was 0.028, 0.038 and 0.035 m s−2, respectively. At higher stimulus levels, jet-propulsed escape responses thresholds in daylight were 0.043, 0.065 and 0.069 m s−2 at 3, 5 and 9 Hz, respectively, and not significantly different from the corresponding darkness thresholds of 0.043, 0.071 and 0.064 m s−2. In a simulated hunting mode, escape thresholds were significantly higher at 3 Hz (0.118 m s−2) but not at 9 Hz (0.134 m s−2). Escape responses were directional, and overall followed the direction of the initial particle acceleration, with mean escape angles from 313 to 33 deg for all three experiments. Thus, in the wild, particle acceleration might cause escape responses directed away from striking predators but towards suction-feeding predators. We suggest that cuttlefish jet-propulsed escape behaviour has evolved to be elicited by the early hydrodynamic disturbances generated during predator encounters, and that the inner ear plays an essential role in the acoustic escape responses.

Published

2018

4. Changes of loggerhead turtle (Caretta caretta) dive behavior associated with tropical storm passage during the inter-nesting period

Author

Kristian Beedholm, David A. Mann, Maria Wilson, and Anton D. Tucker

Subjects

0106 biological sciences, Turtles/physiology, Activity level, Conservation of Natural Resources, Physiology, Diving, Climate change, GREEN SEA TURTLES, DIVING BEHAVIOR, Aquatic Science, ACCELERATION, 010603 evolutionary biology, 01 natural sciences, law.invention, Nesting Behavior, Nest, law, CHELONIA-MYDAS, Animal motion tags, Animals, Turtle (robot), Nesting season, Molecular Biology, TEMPERATURE, Ecology, Evolution, Behavior and Systematics, Tropical storm, Ecology, Cyclonic Storms, 010604 marine biology & hydrobiology, Energetics, Storm, Feeding Behavior, Fishery, Loggerhead turtle, ASCENSION ISLAND, Satellite tags, Insect Science, Threatened species, Florida, SATELLITE TRACKING, PATTERNS, Environmental science, INTERNESTING INTERVALS, Animal Science and Zoology, BUOYANCY CONTROL, Tropical cyclone

Abstract

To improve conservation strategies for threatened sea turtles, more knowledge on their ecology, behavior, and how they cope with severe and changing weather conditions is needed. Satellite and animal motion datalogging tags were used to study the inter-nesting behavior of two female loggerhead turtles in the Gulf of Mexico, which regularly has hurricanes and tropical storms during nesting season. We contrast the behavioral patterns and swimming energetics of these two turtles, the first tracked in calm weather and the second tracked before, during and after a tropical storm. Turtle 1 was highly active and swam at the surface or submerged 95% of the time during the entire inter-nesting period, with a high estimated specific oxygen consumption rate (0.95 ml min-1 kg-0.83). Turtle 2 was inactive for most of the first 9 days of the inter-nesting period, during which she rested at the bottom (80% of the time) with low estimated oxygen consumption (0.62 ml min-1 kg-0.83). Midway through the internesting period, turtle 2 encountered a tropical storm and became highly active (swimming 88% of the time during and 95% after the storm). Her oxygen consumption increased significantly to 0.97 ml min-1 kg-0.83 during and 0.98 ml min-1 kg-0.83 after the storm. However, despite the tropical storm, turtle 2 returned to the nesting beach, where she successfully re-nested 75 m from her previous nest. Thus, the tropical storm had a minor effect on this female's individual nesting success, even though the storm caused 90% loss nests at Casey Key.

Published

2017

5. Directional escape behavior in allis shad (Alosa alosa) exposed to ultrasonic clicks mimicking an approaching toothed whale

Author

Magnus Wahlberg, Peter T. Madsen, Henriette B. Schack, Maria Wilson, and Annemarie Surlykke

Subjects

Sound Spectrography, food.ingredient, Physiology, Toothed whale, Acoustics, Zoology, Aquatic Science, Predation, food, Escape Reaction, Animals, Ultrasonics, Allis shad, Sound pressure, Molecular Biology, Swimming, Ecology, Evolution, Behavior and Systematics, Alosa, biology, Fishes, Whales, biology.organism_classification, Acoustic Stimulation, Echolocation, Predatory Behavior, Insect Science, %22">Fish , Animal Science and Zoology, Ultrasonic sensor

Abstract

SUMMARYToothed whales emit high-powered ultrasonic clicks to echolocate a wide range of prey. It may be hypothesized that some of their prey species have evolved capabilities to detect and respond to such ultrasonic pulses in a way that reduces predation, akin to the situation for many nocturnal insects and echolocating bats. Using high-speed film recordings and controlled exposures, we obtained behavioural evidence that simulated toothed whale biosonar clicks elicit highly directional anti-predator responses in an ultrasound-sensitive allis shad (Alosa alosa). Ten shad were exposed to 192 dB re. 1 μPa (pp) clicks centred at 40 kHz at repetition rates of 1, 20, 50 and 250 clicks s–1 with summed energy flux density levels of 148, 161, 165 and 172 dB re. 1 μPa2 s. The exposures mimicked the acoustic exposure from a delphinid toothed whale in different phases of prey search and capture. The response times of allis shad were faster for higher repetition rates of clicks with the same sound pressure level. None of the fish responded to a single click, but had median response times of 182, 93 and 57 ms when exposed to click rates of 20, 50 and 250 clicks s–1, respectively. This suggests that the ultrasound detector of allis shad is an energy detector and that shad respond faster when exposed to a nearby fast-clicking toothed whale than to a slow-clicking toothed whale far away. The findings are thus consistent with the hypothesis that shad ultrasound detection is used for reducing predation from echolocating toothed whales.

Published

2011

6. Ultrasound detection in the Gulf menhaden requires gas-filled bullae and an intact lateral line

Author

Maria Wilson, Eric W. Montie, Kenneth A. Mann, and David A. Mann

Subjects

Physiology, Oceans and Seas, Fish species, Aquatic Science, TheoryofComputation_ANALYSISOFALGORITHMSANDPROBLEMCOMPLEXITY, Utricle, medicine, Animals, Inner ear, Ultrasonics, Bulla (seal), Molecular Biology, Gulf menhaden, Ecology, Evolution, Behavior and Systematics, Ultrasonic detection, biology, business.industry, Ultrasound, Fishes, Anatomy, X-Ray Microtomography, biology.organism_classification, Lateral Line System, Lateral recess, Animal Communication, medicine.anatomical_structure, Insect Science, Auditory Perception, Evoked Potentials, Auditory, Animal Science and Zoology, business, Mechanoreceptors

Abstract

Clupeiform fish species, including the Gulf menhaden (Brevoortia patronus) that belong to the subfamily Alosinae, can detect ultrasound. Clupeiform fishes are unique in that they have specialized gas-filled bullae in the head associated with the ear via the bulla membrane and with the lateral line via the lateral recess membrane. It has been hypothesized that the utricle of the inner ear is responsible for ultrasound detection through a specialized connection to the gas-filled bullae complex. Here, we show that the lateral line and its connection to the gas-filled bullae complex via the lateral recess are involved in ultrasound detection in Gulf menhaden. Removal of a small portion of the lateral line overlying the lateral recess membrane eliminates the ability of Gulf menhaden to detect ultrasound. We further show that the gas-filled bullae vibrates in response to ultrasound, that the gas-filled bullae are necessary for detecting ultrasound, and that the bullae connections to the lateral line via the lateral recess membrane play an important role in ultrasound detection. These results add a new dimension to the role of the lateral line and bullae as part of the ultrasonic detection system in Gulf menhaden

Published

2009

7. Clicking for calamari: toothed whales can echolocate squid Loligo pealeii

Author

N. Aguilar de Soto, Roger T. Hanlon, Maria Wilson, Peter L. Tyack, Alessandro Bocconcelli, Peter T. Madsen, and Mark Johnson

Subjects

0106 biological sciences, Loligo, Ecology, biology, Toothed whale, 010604 marine biology & hydrobiology, Zoology, Pelagic zone, Human echolocation, Aquatic Science, Oceanography, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Sonar, Fishery, Beak, Crypsis, 14. Life underwater, Target strength, Ecology, Evolution, Behavior and Systematics

Abstract

Squid play an important role in bio- mass turnover in marine ecosystems and constitute a food source for ~90% of all echolocating toothed whale species. Nonetheless, it has been hypo- thesized that the soft bodies of squid provide echoes too weak to be detected by toothed whale biosonars, and that only the few hard parts of the squid body may generate significant backscatter. We measured the acoustic backscatter from the common squid Loligo pealeii for signals similar to toothed whale echolocation clicks using an energy detector to mimic the mammalian auditory system. We show that the dorsal target strengths of L. pealeii with mantle lengths between 23 and 26 cm fall in the range from -38 to -44 dB, and that the pen, beak and lenses do not contribute significantly to the backscatter. Thus, the muscular mantle and fins of L. pealeii constitute a sufficient sonar target for individual biosonar detection by toothed whales at ranges between 25 and 325 m, depending on squid size, noise levels, click source levels, and orientation of the ensonified squid. While epipelagic squid must be fast and muscular to catch prey and avoid visual predators, it is hypothesized that some deep-water squid may have adopted passive acoustic crypsis, with a body of low muscle mass and low metabolism that will render them less con- spicuous to echolocating predators.

Published

2007