Biogeography of time partitioning in mammals

Bennie, Jonathan; Duffy, James P.; Inger, Richard; Gaston, Kevin J.

doi:10.1073/pnas.1216063110

Cited by 225 publications

(213 citation statements)

References 56 publications

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“…They have driven the development of biological phenomena from the molecule to the ecosystem, including metabolic and physiological pathways, the behaviour of individuals, geographical patterns of adaptation and species richness, and ecosystem cycles (e.g. [1][2][3][4]). Indeed, biological systems are arguably organized foremost by light [5][6][7].…”

Section: The Challengementioning

confidence: 99%

The biological impacts of artificial light at night: the research challenge

Gaston

Visser

Hölker

2015

Phil. Trans. R. Soc. B

Self Cite

383

275

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Section: The Challengementioning

confidence: 99%

The biological impacts of artificial light at night: the research challenge

Gaston

Visser

Hölker

2015

Phil. Trans. R. Soc. B

Self Cite

383

275

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“…[27,[65][66][67][68]). Comparative studies have discussed transitions between nocturnality and diurnality, and have suggested that mammals have undergone a 'nocturnal bottleneck' during evolution to escape predation [69,70].…”

Section: (B) Ecologymentioning

confidence: 99%

Two sides of a coin: ecological and chronobiological perspectives of timing in the wild

Helm

Visser

Schwartz

et al. 2017

Phil. Trans. R. Soc. B

132

193

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Most processes within organisms, and most interactions between organisms and their environment, have distinct time profiles. The temporal coordination of such processes is crucial across levels of biological organization, but disciplines differ widely in their approaches to study timing. Such differences are accentuated between ecologists, who are centrally concerned with a holistic view of an organism in relation to its external environment, and chronobiologists, who emphasize internal timekeeping within an organism and the mechanisms of its adjustment to the environment. We argue that ecological and chronobiological perspectives are complementary, and that studies at the intersection will enable both fields to jointly overcome obstacles that currently hinder progress. However, to achieve this integration, we first have to cross some conceptual barriers, clarifying prohibitively inaccessible terminologies. We critically assess main assumptions and concepts in either field, as well as their common interests. Both approaches intersect in their need to understand the extent and regulation of temporal plasticity, and in the concept of 'chronotype', i.e. the characteristic temporal properties of individuals which are the targets of natural and sexual selection. We then highlight promising developments, point out open questions, acknowledge difficulties and propose directions for further integration of ecological and chronobiological perspectives through Wild Clock research.

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“…Depending on the constraints of physiological thermal limit and light availability, animals evolved few basic patterns of diel activity: diurnal, nocturnal, crepuscular or cathemeral (Bennie et al 2014). In mammals, a given animal can stably and predictably switch back and forth between different patterns in context-dependent ways (Kas and Edgar 1999;Mrosovsky 2003).…”

Section: Network Architecture Under Ld Cyclesmentioning

confidence: 99%

Control of Sleep-Wake Cycles in Drosophila

Chatterjee

Rouyer

2016

Research and Perspectives in Endocrine Interactions

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Inter-oscillator communication modulates and sustains the circadian locomotor rhythms in flies and rodent animal models. In Drosophila, the multioscillator network that controls sleep-wake cycles includes about 150 clock neurons. A subset of lateral neurons (LNs) expressing the Pigment-dispersing factor (PDF) appears to act as a master clock in constant darkness (DD). In light-dark (LD) cycles, flies show a bimodal distribution of their activity, and the PDF-expressing LNs play a major role in the control of the morning bout of activity. In contrast, a subset of PDF-negative LNs can generate evening activity in the absence of other functional oscillators. How these oscillators interact in a fully functional network to shape the sleep-wake cycle remains debated. The PDF neurons strongly influence the PDF-negative ones in DD and, to a lesser extent, in LD. The extent of hierarchy depends on environmental conditions and the way the dominance of PDF neurons is exerted on the different types of PDF-negative neurons is unclear. The recent discovery of light-and temperature-dependent oscillators in the dorsal neurons (DNs) sheds new light on the circuits that control the Drosophila diurnal behavior and its adaptation to environmental changes.

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Biogeography of time partitioning in mammals

Cited by 225 publications

References 56 publications

The biological impacts of artificial light at night: the research challenge

The biological impacts of artificial light at night: the research challenge

Two sides of a coin: ecological and chronobiological perspectives of timing in the wild

Control of Sleep-Wake Cycles in Drosophila

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