Energy limitation as a selective pressure on the evolution of sensory systems

Niven, Jeremy E.; Laughlin, Simon B.

doi:10.1242/jeb.017574

Cited by 915 publications

(826 citation statements)

References 144 publications

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“…These performance gains may explain the evolutionary increase of eye size, despite the high metabolic cost of sensory acquisition (30,(36)(37)(38)(39), but additional insights can be gained by combining the metabolic cost of sensing with the analysis of the energetics of movement (30). This synthesis suggests that reducing the metabolic cost of predation is spread across the motor and sensory systems involved.…”

Section: Discussionmentioning

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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Section: Discussionmentioning

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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“…1) and chemical ( Fig. 2) events across different activity levels suggests that there are physiological factors that limit the energy associated with cortical signaling (42) and that, within the normal physiological range of neuronal signaling, the electrical and chemical events are complimentary (3). Assuming a constant energetic cost of Na + and K + pumping, there is a direct relationship between synaptic strength (i.e., average current induced by a signaling event at a synapse, which can be increased through either induced conductivity or higher probability of presynaptic glutamate release) and energy consumption at the synapse.…”

Section: Glial Energy Demand and Excitatory Vs Inhibitory Neuronal Ementioning

confidence: 99%

Cortical energy demands of signaling and nonsignaling components in brain are conserved across mammalian species and activity levels

Hyder

Rothman

Bennett

2013

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

220

219

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The continuous need for ion gradient restoration across the cell membrane, a prerequisite for synaptic transmission and conduction, is believed to be a major factor for brain's high oxidative demand. However, do energy requirements of signaling and nonsignaling components of cortical neurons and astrocytes vary with activity levels and across species? We derived oxidative ATP demand associated with signaling (P s ) and nonsignaling (P ns ) components in the cerebral cortex using species-specific physiologic and anatomic data. In rat, we calculated glucose oxidation rates from layer-specific neuronal activity measured across different states, spanning from isoelectricity to awake and sensory stimulation. We then compared these calculated glucose oxidation rates with measured glucose metabolic data for the same states as reported by 2-deoxy-glucose autoradiography. Fixed values for P s and P ns were able to predict the entire range of states in the rat. We then calculated glucose oxidation rates from human EEG data acquired under various conditions using fixed P s and P ns values derived for the rat. These calculated metabolic data in human cerebral cortex compared well with glucose metabolism measured by PET. Independent of species, linear relationship was established between neuronal activity and neuronal oxidative demand beyond isoelectricity. Cortical signaling requirements dominated energy demand in the awake state, whereas nonsignaling requirements were ∼20% of awake value. These predictions are supported by 13 C magnetic resonance spectroscopy results. We conclude that mitochondrial energy support for signaling and nonsignaling components in cerebral cortex are conserved across activity levels in mammalian species.T he brain is one of the most energy demanding tissues in the body (1). 13 C magnetic resonance spectroscopy (MRS) in the rat has shown that, in the resting awake state, ∼80% of cortical energy consumption is used to support signaling as reflected by the rate of glutamate neurotransmitter release and astroglial uptake (2, 3). Cerebral energy demand is also positively correlated with the rate of pyramidal neuron firing in rat cortex (4, 5). 13 C MRS findings in the human cortex have been generally consistent with the rat results (6). However, there remain questions as to how well the energy costs of specific subcellular processes needed to support synaptic transmission and conduction are conserved over different activity levels and/or across species.Recent bottom-up energy budgets for gray matter in the mammalian brain have attempted to understand the energetic costs of neuronal and glial electrical and neurotransmission events occurring in the neuropil (7,8) by calculating the ATP used per neuron for signaling (P s ) and nonsignaling (P ns ) events. In the awake cortex, the total ATP used per unit cortical volume per unit time (E tot ; in units of ATP/s per centimeter 3 ) was determined by multiplying the P s (in units of ATP/neuron per spike) and P ns (in units of ATP/neuron per second) parameter...

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“…Over evolutionary time, selection has presumably favoured enhancements of sensory systems that provide the greatest benefits to individuals, while also favouring low costs [1]. The often observed match between the capacities of an animal's sensory systems and the animal's apparent needs is a testament to such selection [2,3].…”

Section: Introductionmentioning

confidence: 99%

Nocturnal foraging enhanced by enlarged secondary eyes in a net-casting spider

Stafstrom¹,

Hebets²

2016

Biol. Lett.

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Animals that possess extreme sensory structures are predicted to have a related extreme behavioural function. This study focuses on one such extreme sensory structure-the posterior median eyes of the net-casting spider Deinopis spinosa. Although past research has implicated the importance of vision in the nocturnal foraging habits of Deinopis, no direct link between vision in the enlarged eyes and nocturnal foraging has yet been made. To directly test the hypothesis that the enlarged posterior median eyes facilitate visually based nocturnal prey capture, we conducted repeated-measures, visual occlusion trials in both natural and laboratory settings. Our results indicate that D. spinosa relies heavily on visual cues detected by the posterior median eyes to capture cursorial prey items. We suggest that the enlarged posterior median eyes benefit D. spinosa not only through increased diet breadth, but also by allowing spiders to remain active solely at night, thus evading predation by diurnal animals.

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Energy limitation as a selective pressure on the evolution of sensory systems

Cited by 915 publications

References 144 publications

Massive increase in visual range preceded the origin of terrestrial vertebrates

Massive increase in visual range preceded the origin of terrestrial vertebrates

Cortical energy demands of signaling and nonsignaling components in brain are conserved across mammalian species and activity levels

Nocturnal foraging enhanced by enlarged secondary eyes in a net-casting spider

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