Your search keyword '"Lohmann KJ"' showing total 10 results

1. Odors from marine plastic debris elicit foraging behavior in sea turtles.

Author

Pfaller JB, Goforth KM, Gil MA, Savoca MS, and Lohmann KJ

Subjects

Animals, Waste Products adverse effects, Feeding Behavior drug effects, Odorants, Plastics adverse effects, Turtles physiology, Water Pollutants adverse effects

Abstract

Pfaller et al. report that sea turtles respond to odors from biofouled plastic debris with the same behavior that is elicited by food odors, providing a possible unifying explanation for why sea turtles interact with marine plastic., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

2. Animal migration research takes wing.

Author

Lohmann KJ

Subjects

Animals, Animal Migration physiology, Invertebrates anatomy & histology, Invertebrates genetics, Invertebrates physiology, Vertebrates anatomy & histology, Vertebrates genetics, Vertebrates physiology

Abstract

In the beginning there was great confusion about animal migration. Aristotle, noting that the types of birds around him changed with the seasons, concluded that summer redstarts turned into robins at the onset of winter, and that garden warblers became blackcaps [1]. Others thought that birds disappear in winter because they hibernate submerged in mud. In a case of art decidedly not imitating life, a 16th century illustration accompanying the writings of Swedish Archbishop Olaus Magnus showed a fishing net filled with hibernating swallows being pulled from a lake [1]. Gradually, over centuries, these fanciful early explanations gave way to an understanding that migration is a widespread phenomenon and that Earth is alive with itinerant animals traversing continents, seas, and skies (Figure 1)., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

3. Evidence that Magnetic Navigation and Geomagnetic Imprinting Shape Spatial Genetic Variation in Sea Turtles.

Author

Brothers JR and Lohmann KJ

Subjects

Animals, Genetic Variation genetics, Genetics, Population methods, Geography, Imprinting, Psychological physiology, Magnetic Fields, Reproduction physiology, Animal Migration physiology, Homing Behavior physiology, Turtles physiology

Abstract

The canonical drivers of population genetic structure, or spatial genetic variation, are isolation by distance and isolation by environment. Isolation by distance predicts that neighboring populations will be genetically similar and geographically distant populations will be genetically distinct [1]. Numerous examples also exist of isolation by environment, a phenomenon in which populations that inhabit similar environments (e.g., same elevation, temperature, or vegetation) are genetically similar even if they are distant, whereas populations that inhabit different environments are genetically distinct even when geographically close [2-4]. These dual models provide a widely accepted conceptual framework for understanding population structure [5-8]. Here, we present evidence for an additional, novel process that we call isolation by navigation, in which the navigational mechanism used by a long-distance migrant influences population structure independently of isolation by either distance or environment. Specifically, we investigated the population structure of loggerhead sea turtles (Caretta caretta) [9], which return to nest on their natal beaches by seeking out unique magnetic signatures along the coast-a behavior known as geomagnetic imprinting [10-12]. Results reveal that spatial variation in Earth's magnetic field strongly predicts genetic differentiation between nesting beaches, even when environmental similarities and geographic proximity are taken into account. The findings provide genetic corroboration of geomagnetic imprinting [10, 13]. Moreover, they provide strong evidence that geomagnetic imprinting and magnetic navigation help shape the population structure of sea turtles and perhaps numerous other long-distance migrants that return to their natal areas to reproduce [13-17]., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

4. Evidence for geomagnetic imprinting and magnetic navigation in the natal homing of sea turtles.

Author

Brothers JR and Lohmann KJ

Subjects

Animals, Florida, Geography, Linear Models, Oceans and Seas, Homing Behavior physiology, Magnetic Phenomena, Spatial Navigation physiology, Turtles physiology

Abstract

Natal homing is a pattern of behavior in which animals migrate away from their geographic area of origin and then return to reproduce in the same location where they began life [1-3]. Although diverse long-distance migrants accomplish natal homing [1-8], little is known about how they do so. The enigma is epitomized by loggerhead sea turtles (Caretta caretta), which leave their home beaches as hatchlings and migrate across entire ocean basins before returning to nest in the same coastal area where they originated [9, 10]. One hypothesis is that turtles imprint on the unique geomagnetic signature of their natal area and use this information to return [1]. Because Earth's field changes over time, geomagnetic imprinting should cause turtles to change their nesting locations as magnetic signatures drift slightly along coastlines. To investigate, we analyzed a 19-year database of loggerhead nesting sites in the largest sea turtle rookery in North America. Here we report a strong association between the spatial distribution of turtle nests and subtle changes in Earth's magnetic field. Nesting density increased significantly in coastal areas where magnetic signatures of adjacent beach locations converged over time, whereas nesting density decreased in places where magnetic signatures diverged. These findings confirm central predictions of the geomagnetic imprinting hypothesis and provide strong evidence that such imprinting plays an important role in natal homing in sea turtles. The results give credence to initial reports of geomagnetic imprinting in salmon [11, 12] and suggest that similar mechanisms might underlie long-distance natal homing in diverse animals., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

5. An inherited magnetic map guides ocean navigation in juvenile Pacific salmon.

Author

Putman NF, Scanlan MM, Billman EJ, O'Neil JP, Couture RB, Quinn TP, Lohmann KJ, and Noakes DL

Subjects

Aging, Animals, Pacific Ocean, Animal Migration, Magnetic Phenomena, Salmon physiology

Abstract

Migratory marine animals exploit resources in different oceanic regions at different life stages, but how they navigate to specific oceanic areas is poorly understood. A particular challenge is explaining how juvenile animals with no prior migratory experience are able to locate specific oceanic feeding habitats that are hundreds or thousands of kilometers from their natal sites. Although adults reproducing in the vicinity of favorable ocean currents can facilitate transport of their offspring to these habitats, variation in ocean circulation makes passive transport unreliable, and young animals probably take an active role in controlling their migratory trajectories. Here we experimentally demonstrate that juvenile Chinook salmon (Oncorhynchus tshawytscha) respond to magnetic fields like those at the latitudinal extremes of their ocean range by orienting in directions that would, in each case, lead toward their marine feeding grounds. We further show that fish use the combination of magnetic intensity and inclination angle to assess their geographic location. The "magnetic map" of salmon appears to be inherited, as the fish had no prior migratory experience. These results, paired with findings in sea turtles, imply that magnetic maps are phylogenetically widespread and likely explain the extraordinary navigational abilities evident in many long-distance underwater migrants., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

6. Evidence for geomagnetic imprinting as a homing mechanism in Pacific salmon.

Author

Putman NF, Lohmann KJ, Putman EM, Quinn TP, Klimley AP, and Noakes DL

Subjects

Animals, Breeding, Feeding Behavior, Oceans and Seas, Reproduction, Rivers, Animal Migration physiology, Imprinting, Psychological, Magnetic Fields, Salmon physiology

Abstract

In the final phase of their spawning migration, Pacific salmon use chemical cues to identify their home river, but how they navigate from the open ocean to the correct coastal area has remained enigmatic. To test the hypothesis that salmon imprint on the magnetic field that exists where they first enter the sea and later seek the same field upon return, we analyzed a 56-year fisheries data set on Fraser River sockeye salmon, which must detour around Vancouver Island to approach the river through either a northern or southern passageway. We found that the proportion of salmon using each route was predicted by geomagnetic field drift: the more the field at a passage entrance diverged from the field at the river mouth, the fewer fish used the passage. We also found that more fish used the northern passage in years with warmer sea surface temperature (presumably because fish were constrained to more northern latitudes). Field drift accounted for 16% of the variation in migratory route used, temperature 22%, and the interaction between these variables 28%. These results provide the first empirical evidence of geomagnetic imprinting in any species and imply that forecasting salmon movements is possible using geomagnetic models., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

7. Longitude perception and bicoordinate magnetic maps in sea turtles.

Author

Putman NF, Endres CS, Lohmann CM, and Lohmann KJ

Subjects

Animals, Atlantic Ocean, Florida, Animal Migration, Geography, Magnetics, Orientation physiology, Turtles physiology

Abstract

Long-distance animal migrants often navigate in ways that imply an awareness of both latitude and longitude. Although several species are known to use magnetic cues as a surrogate for latitude, it is not known how any animal perceives longitude. Magnetic parameters appear to be unpromising as longitudinal markers because they typically vary more in a north-south rather than an east-west direction. Here we report, however, that hatchling loggerhead sea turtles (Caretta caretta) from Florida, USA, when exposed to magnetic fields that exist at two locations with the same latitude but on opposite sides of the Atlantic Ocean, responded by swimming in different directions that would, in each case, help them advance along their circular migratory route. The results demonstrate for the first time that longitude can be encoded into the magnetic positioning system of a migratory animal. Because turtles also assess north-south position magnetically, the findings imply that loggerheads have a navigational system that exploits the Earth's magnetic field as a kind of bicoordinate magnetic map from which both longitudinal and latitudinal information can be extracted., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

8. Compatibility of magnetic imprinting and secular variation.

Author

Putman NF and Lohmann KJ

Subjects

Animals, Locomotion physiology, Marine Biology, Models, Biological, Turtles physiology, Behavior, Animal physiology, Magnetics

Published

2008

9. Sea turtles: navigating with magnetism.

Author

Lohmann KJ

Subjects

Animals, Female, Homing Behavior physiology, Magnetoencephalography, Oceans and Seas, Satellite Communications, Animal Migration physiology, Magnetics, Turtles physiology

Abstract

Young sea turtles use the Earth's magnetic field as a source of navigational information during their epic transoceanic migrations and while homing. A new study using satellite telemetry has now demonstrated for the first time that adult turtles also navigate using the Earth's magnetic field.

Published

2007

10. Sea turtles.

Author

Lohmann CM and Lohmann KJ

Subjects

Animal Migration, Animals, Homing Behavior, Turtles anatomy & histology, Turtles classification, Turtles physiology

Published

2006