Electroreception, electrogenesis and electric signal evolution

Crampton, William G. R.

doi:10.1111/jfb.13922

Cited by 109 publications

(119 citation statements)

References 367 publications

(826 reference statements)

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“…The freshwater sensitivity is commensurate with that of the obligate freshwater P. motoro , which can detect voltages as weak as 5 μV cm −1 (Harris et al, ). This suggests that a reduced sensitivity and detection range of electrical stimuli in freshwater species (Crampton, ) occurs due to the lower conductivity and higher resistivity of fresh water compared with seawater and not the morphological adaptations of thicker skin and shorter ampullary canals seen in obligate freshwater elasmobranchs (Harris et al, ).…”

Section: Behaviourmentioning

confidence: 92%

“…These aspects are fundamental to understanding how electrosensitive species might respond to electrical changes in the marine environment. The review complements that of electroreception in freshwater fishes by Crampton (2019), which provides a comprehensive state of knowledge regarding the evolution of electroreception, particularly active electroreception and electric signal generation in electric fishes. For further specific reviews on chondrichthyan electroreception, readers are referred to Collin and Whitehead (2004), Gardiner et al (2012), Kajiura et al (2010), Tricas and Sisneros (2004) and Wilkens and Hofmann (2005).…”

mentioning

confidence: 98%

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Electroreception in marine fishes: chondrichthyans

Newton

Gill

Kajiura

2019

Journal of Fish Biology

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Electroreception in marine fishes occurs across a variety of taxa and is best understood in the chondrichthyans (sharks, skates, rays, and chimaeras). Here, we present an up‐to‐date review of what is known about the biology of passive electroreception and we consider how electroreceptive fishes might respond to electric and magnetic stimuli in a changing marine environment. We briefly describe the history and discovery of electroreception in marine Chondrichthyes, the current understanding of the passive mode, the morphological adaptations of receptors across phylogeny and habitat, the physiological function of the peripheral and central nervous system components, and the behaviours mediated by electroreception. Additionally, whole genome sequencing, genetic screening and molecular studies promise to yield new insights into the evolution, distribution, and function of electroreceptors across different environments. This review complements that of electroreception in freshwater fishes in this special issue, which provides a comprehensive state of knowledge regarding the evolution of electroreception. We conclude that despite our improved understanding of passive electroreception, several outstanding gaps remain which limits our full comprehension of this sensory modality. Of particular concern is how electroreceptive fishes will respond and adapt to a marine environment that is being increasingly altered by anthropogenic electric and magnetic fields.

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Section: Behaviourmentioning

confidence: 92%

mentioning

confidence: 98%

Electroreception in marine fishes: chondrichthyans

Newton

Gill

Kajiura

2019

Journal of Fish Biology

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“…Another source of natural electric fields is living organisms. Organisms constantly generate electric fields during their life processes for example during cell membrane transport, muscle contractions and nerve cell communication (Crampton 2019). The characteristics of the generated electric fields depend on the taxa, position and activity of the animal, and typically range from 2 000 -100 000 nV/cm at a very close distance (Haine et al 2001).…”

Section: Electric Fieldsmentioning

confidence: 99%

Electric and magnetic senses in marine animals, and potential behavioral effects of electromagnetic surveys

Nyqvist

Durif

Johnsen

et al. 2020

Marine Environmental Research

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This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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“…In pulse‐type fish, in contrast, the interval between EODs is much larger than its duration and the electric discharge consists of a series of discrete, rhythmic and stereotyped beats. The functional division of gymnotiform into pulse and wave types is likely associated with ancient divergences in niche occupancy that shaped the evolution of signal diversity among this group (Crampton, ). However, phylogenetic analysis of morphological and molecular data indicate that pulse‐ and wave‐type families can be more closely related than families of pulse‐type fish (Crampton, ).…”

Section: The Electromotor Central Pattern Generator In Gymnotiformesmentioning

confidence: 99%

Hormone‐mediated modulation of the electromotor CPG in pulse‐type weakly electric fish. Commonalities and differences across species

Borde

Quintana

Comas

et al. 2020

Developmental Neurobiology

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Like stomatogastric activity in crustaceans, vocalization in teleosts and frogs, and locomotion in mammals, the electric organ discharge (EOD) of weakly electric fish is a rhythmic and stereotyped electromotor pattern. The EOD, which functions in both perception and communication, is controlled by a two‐layered central pattern generator (CPG), the electromotor CPG, which modifies its basal output in response to environmental and social challenges. Despite major anatomo‐functional commonalities in the electromotor CPG across electric fish species, we show that Gymnotus omarorum and Brachyhypopomus gauderio have evolved divergent neural processes to transiently modify the CPG outputs through descending fast neurotransmitter inputs to generate communication signals. We also present two examples of electric behavioral displays in which it is possible to separately analyze the effects of neuropeptides (mid‐term modulation) and gonadal steroid hormones (long‐term modulation) upon the CPG. First, the nonbreeding territorial aggression of G. omarorum has been an advantageous model to analyze the status‐dependent modulation of the excitability of CPG neuronal components by vasotocin. Second, the seasonal and sexually dimorphic courtship signals of B. gauderio have been useful to understand the effects of sex steroids on the responses to glutamatergic inputs in the CPG. Overall, the electromotor CPG functions in a regime that safeguards the EOD waveform. However, prepacemaker influences and hormonal modulation enable an enormous versatility and allows the EOD to adapt its functional state in a species‐, sex‐, and social context‐specific manners.

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Electroreception, electrogenesis and electric signal evolution

Cited by 109 publications

References 367 publications

Electroreception in marine fishes: chondrichthyans

Electroreception in marine fishes: chondrichthyans

Electric and magnetic senses in marine animals, and potential behavioral effects of electromagnetic surveys

Hormone‐mediated modulation of the electromotor CPG in pulse‐type weakly electric fish. Commonalities and differences across species

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