Landler Lukas, Painter Michael S, Youmans Paul W, Hopkins William A, Phillips John B
Department of Biological Sciences, Virginia Tech, Blacksburg, Virginia, United States of America.
Department of Fish and Wildlife Conservation, Virginia Tech, Blacksburg, Virginia, United States of America.
PLoS One. 2015 May 15;10(5):e0124728. doi: 10.1371/journal.pone.0124728. eCollection 2015.
We investigated spontaneous magnetic alignment (SMA) by juvenile snapping turtles using exposure to low-level radio frequency (RF) fields at the Larmor frequency to help characterize the underlying sensory mechanism. Turtles, first introduced to the testing environment without the presence of RF aligned consistently towards magnetic north when subsequent magnetic testing conditions were also free of RF ('RF off → RF off'), but were disoriented when subsequently exposed to RF ('RF off → RF on'). In contrast, animals initially introduced to the testing environment with RF present were disoriented when tested without RF ('RF on → RF off'), but aligned towards magnetic south when tested with RF ('RF on → RF on'). Sensitivity of the SMA response of yearling turtles to RF is consistent with the involvement of a radical pair mechanism. Furthermore, the effect of RF appears to result from a change in the pattern of magnetic input, rather than elimination of magnetic input altogether, as proposed to explain similar effects in other systems/organisms. The findings show that turtles first exposed to a novel environment form a lasting association between the pattern of magnetic input and their surroundings. However, under natural conditions turtles would never experience a change in the pattern of magnetic input. Therefore, if turtles form a similar association of magnetic cues with the surroundings each time they encounter unfamiliar habitat, as seems likely, the same pattern of magnetic input would be associated with multiple sites/localities. This would be expected from a sensory input that functions as a global reference frame, helping to place multiple locales (i.e., multiple local landmark arrays) into register to form a global map of familiar space.
我们通过让稚鳄龟暴露于拉莫尔频率的低水平射频(RF)场来研究其自发磁定向(SMA),以帮助确定潜在的感觉机制。当首次将龟引入不存在RF的测试环境中时,随后在无RF的磁测试条件下(“RF关→RF关”),它们始终一致地朝着磁北方向定向,但随后暴露于RF时(“RF关→RF开”)就会迷失方向。相比之下,最初在有RF的情况下引入测试环境的动物,在无RF测试时(“RF开→RF关”)会迷失方向,但在有RF测试时(“RF开→RF开”)会朝着磁南方向定向。一岁龟的SMA反应对RF的敏感性与自由基对机制的参与一致。此外,RF的影响似乎是由磁输入模式的变化引起的,而不是像在其他系统/生物体中解释类似效应时所提出的那样完全消除磁输入。研究结果表明,首次暴露于新环境的龟会在磁输入模式与其周围环境之间形成持久的关联。然而,在自然条件下,龟永远不会经历磁输入模式的变化。因此,如果龟每次遇到不熟悉的栖息地时都与周围环境形成类似的磁线索关联,这似乎是很有可能的,那么相同的磁输入模式将与多个地点/位置相关联。这是预期从作为全局参考框架的感觉输入中得到的结果,有助于将多个地点(即多个局部地标阵列)对齐以形成熟悉空间的全局地图。
