Neural Representation of Object Approach in a Decision-Making Motor Circuit

Preuss, Thomas; Osei-Bonsu, Princess E.; Weiss, Shennan A.; Wang, C.; Faber, Donald S.

doi:10.1523/jneurosci.5259-05.2006

Cited by 153 publications

(209 citation statements)

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“…It makes sense that locusts would ignore very slow approaches (high l/͉v͉) and might fail to generate an appropriate escape motor program in response to very fast approaching stimuli (low l/͉v͉). Decreased escape probabilities for small and fast stimuli have been reported in goldfish as well (Preuss et al, 2006). Thus, we believe that l/͉v͉ ϭ 40 -120 ms covers the range leading to the most relevant and robust escape jumps in the present context.…”

Section: Stimulus Parameter Selectionsupporting

confidence: 62%

“…However, it does not rule out the involvement of other neurons in the generation of this motor program. Preuss et al (2006) have described recently looming-evoked escape responses in goldfish triggered by visual inputs to the Mauthner cell. Approaching objects elicit a compound EPSP (cEPSP) that has a similar, although not identical, time course to the DCMD firing rate: the cEPSP amplitude increases, peaks, and then decays toward the end of approach.…”

Section: A Model For the Role Of The Dcmd Activity In Escape Jumpsmentioning

confidence: 99%

“…Some animals have evolved fast motor circuits devoted to the generation of such behaviors, such as the giant fiber system in flies, the Mauthner cell in fish, or the lateral giant neurons of crayfish (Wyman et al, 1984;Edwards et al, 1999;Korn and Faber, 2005). Although much is known in these and in other systems about how escape behaviors are generated in response to abrupt stimuli such as mechanical disturbances, air puffs, or light flashes (Levi and Camhi, 2000;Fayyazuddin et al, 2006;Bhatt et al, 2007), we still know very little about how escape behaviors are generated in response to objects approaching on a collision course, as may be expected from potential predators (Yamamoto et al, 2003;Preuss et al, 2006;Santer et al, 2006;Oliva et al, 2007;Hammond and O'Shea, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Relationship between the Phases of Sensory and Motor Activity during a Looming-Evoked Multistage Escape Behavior

Fotowat¹,

Gabbiani²

2007

J. Neurosci.

105

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The firing patterns of visual neurons tracking approaching objects need to be translated into appropriate motor activation sequences to generate escape behaviors. Locusts possess an identified neuron highly sensitive to approaching objects (looming stimuli), thought to play an important role in collision avoidance through its motor projections. To study how the activity of this neuron relates to escape behaviors, we monitored jumps evoked by looming stimuli in freely behaving animals. By comparing electrophysiological and highspeed video recordings, we found that the initial preparatory phase of jumps occurs on average during the rising phase of the firing rate of the looming-sensitive neuron. The coactivation period of leg flexors and extensors, which is used to store the energy required for the jump, coincides with the timing of the peak firing rate of the neuron. The final preparatory phase occurs after the peak and takeoff happens when the firing rate of the looming-sensitive neuron has decayed to Ͻ10% of its peak. Both the initial and the final preparatory phases and takeoff are triggered when the approaching object crosses successive threshold angular sizes on the animal's retina. Our results therefore suggest that distinct phases of the firing patterns of individual sensory neurons may actively contribute to distinct phases of complex, multistage motor behaviors.

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Section: Stimulus Parameter Selectionsupporting

confidence: 62%

Section: A Model For the Role Of The Dcmd Activity In Escape Jumpsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Relationship between the Phases of Sensory and Motor Activity during a Looming-Evoked Multistage Escape Behavior

Fotowat¹,

Gabbiani²

2007

J. Neurosci.

105

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show abstract

“…Although this neural circuit enables ultrafast reactions to stimuli (≈4 ms), the limited number of neurons and synapses involved constrains the flexibility of the response (60). Mauthner command cells, activated by close-range acoustic, lateral line, tactile, and looming visual stimuli (59) in proportion to the speed of looming (61), are only present in vertebrates up through amphibians, including frogs (62,63).…”

Section: Implications Of Long-range Vision For Reactive Neural Circuimentioning

confidence: 99%

Massive increase in visual range preceded the origin of terrestrial vertebrates

MacIver

Schmitz

Mugan

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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The evolution of terrestrial vertebrates, starting around 385 million years ago, is an iconic moment in evolution that brings to mind images of fish transforming into four-legged animals. Here, we show that this radical change in body shape was preceded by an equally dramatic change in sensory abilities akin to transitioning from seeing over short distances in a dense fog to seeing over long distances on a clear day. Measurements of eye sockets and simulations of their evolution show that eyes nearly tripled in size just before vertebrates began living on land. Computational simulations of these animal's visual ecology show that for viewing objects through water, the increase in eye size provided a negligible increase in performance. However, when viewing objects through air, the increase in eye size provided a large increase in performance. The jump in eye size was, therefore, unlikely to have arisen for seeing through water and instead points to an unexpected hybrid of seeing through air while still primarily inhabiting water. Our results and several anatomical innovations arising at the same time suggest lifestyle similarity to crocodiles. The consequent combination of the increase in eye size and vision through air would have conferred a 1 million-fold increase in the amount of space within which objects could be seen. The "buena vista" hypothesis that our data suggest is that seeing opportunities from afar played a role in the subsequent evolution of fully terrestrial limbs as well as the emergence of elaborated action sequences through planning circuits in the nervous system. fish-tetrapod transition | vision | visual ecology | terrestriality | prospective cognition B efore terrestrial vertebrates arose, their ancestors inhabited underwater environments, where vision is highly compromised compared with vision above water. The visual difference between life in water and life above it is comparable with driving fast on a foggy road, where our responses must be rapid and simple, vs. driving in clear daylight conditions, where deliberation over more complex choices is enabled by the vast increase in sensory range. Nonetheless, although an immense quantity of work has been done on the emergence of limbs during the evolution of land vertebrates, how visual capability changed during the transition from water to land has not been explored. In part, this lack of exploration is because computational visual ecology-necessary to interpret the fossil data-has not been combined with early tetrapod paleontology. Through combining these disciplines, here we probe the evolutionary history of the switch in our visual sensory ecology from water to air. Surprisingly, our results show that eyes tripled in size just before full-time life on land evolved. Convergent lines of evidence, including our own, strongly support the hypothesis that a crocodilian ecotype-using the greatly enhanced visual capabilities conferred by vision through air to prey on the bounty of unexploited invertebrates that long preceded the vertebrates onto ...

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“…The peak firing rate always occurs a fixed delay after the time at which the looming stimulus reaches an angular threshold on the retina, independent of the stimulus' specific characteristics, such as the simulated object's size, speed, texture, or approach direction (Gabbiani et al, 1999;. Neurons with nearly identical response profiles have been identified in a variety of vertebrate and invertebrate species (Sun and Frost, 1998;Wu et al, 2005;Preuss et al, 2006;Fotowat et al, 2009;Nakagawa and Hongjian, 2010;Liu et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Logarithmic Compression of Sensory Signals within the Dendritic Tree of a Collision-Sensitive Neuron

Jones

Gabbiani²

2012

J. Neurosci.

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Neurons in a variety of species, both vertebrate and invertebrate, encode the kinematics of objects approaching on a collision course through a time-varying firing rate profile that initially increases, then peaks, and eventually decays as collision becomes imminent. In this temporal profile, the peak firing rate signals when the approaching object's subtended size reaches an angular threshold, an event which has been related to the timing of escape behaviors. In a locust neuron called the lobula giant motion detector (LGMD), the biophysical basis of this angular threshold computation relies on a multiplicative combination of the object's angular size and speed, achieved through a logarithmic-exponential transform. To understand how this transform is implemented, we modeled the encoding of angular velocity along the pathway leading to the LGMD based on the experimentally determined activation pattern of its presynaptic neurons. These simulations show that the logarithmic transform of angular speed occurs between the synaptic conductances activated by the approaching object onto the LGMD's dendritic tree and its membrane potential at the spike initiation zone. Thus, we demonstrate an example of how a single neuron's dendritic tree implements a mathematical step in a neural computation important for natural behavior.

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Neural Representation of Object Approach in a Decision-Making Motor Circuit

Cited by 153 publications

References 50 publications

Relationship between the Phases of Sensory and Motor Activity during a Looming-Evoked Multistage Escape Behavior

Relationship between the Phases of Sensory and Motor Activity during a Looming-Evoked Multistage Escape Behavior

Massive increase in visual range preceded the origin of terrestrial vertebrates

Logarithmic Compression of Sensory Signals within the Dendritic Tree of a Collision-Sensitive Neuron

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