Illuminated night alters hippocampal gene expressions and induces depressive‐like responses in diurnal corvids

Taufique, S. K. Tahajjul; Prabhat, Abhilash; Kumar, Vinod

doi:10.1111/ejn.14157

Cited by 39 publications

(44 citation statements)

References 56 publications

(94 reference statements)

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“…In the HC, which is involved in the processing of spatial information [ 19 , 20 ], the significant increase in the number of new neurons that were recruited under ALAN is contrary to the decrease that was found in Indian house crows [ 3 ]. However, these crows were acclimated, after being caught from the wild, only for a single week, shorter than the recommended three weeks to ensure thermogenic [ 36 ] and physiological [ 37 ] acclimation in birds.…”

Section: Discussionmentioning

confidence: 99%

“…Despite a growing number of studies that demonstrate adverse effects of artificial light at night (ALAN) on the behaviour and physiology of many species (e.g., reviewed in [ 1 , 2 ]), still, in birds relatively little is known regarding its effects on brain plasticity. The few existing studies report a decrease in the numbers of newly formed neurons in the hippocampus (HC) of Indian house crows ( Corvus splendens ) [ 3 ], and a decrease in soma size of neurons in the HC and the lateral caudal nidopallium (NCL) in this species, suggesting reduced neuronal plasticity [ 4 ]. We have also studied the effect of ALAN on neuronal plasticity in another diurnal species, zebra finches ( Taeniopygia guttata ), which have excellent visual abilities [ 5 ] and their physiology, reproduction and survival are greatly affected by circadian and circannual rhythms [ 6 , 7 ].…”

Section: Introductionmentioning

confidence: 99%

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Artificial Light at Night Increases Recruitment of New Neurons and Differentially Affects Various Brain Regions in Female Zebra Finches

Moaraf

Heiblum

Vistoropsky

et al. 2020

IJMS

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Despite growing evidence that demonstrate adverse effects of artificial light at night (ALAN) on many species, relatively little is known regarding its effects on brain plasticity in birds. We recently showed that although ALAN increases cell proliferation in brains of birds, neuronal densities in two brain regions decreased, indicating neuronal death, which might be due to mortality of newly produced neurons or of existing ones. Therefore, in the present study we studied the effect of long-term ALAN on the recruitment of newborn neurons into their target regions in the brain. Accordingly, we exposed zebra finches (Taeniopygia guttata) to 5 lux ALAN, and analysed new neuronal recruitment and total neuronal densities in several brain regions. We found that ALAN increased neuronal recruitment, possibly as a compensatory response to ALAN-induced neuronal death, and/or due to increased nocturnal locomotor activity caused by sleep disruption. Moreover, ALAN also had a differential temporal effect on neuronal densities, because hippocampus was more sensitive to ALAN and its neuronal densities were more affected than in other brain regions. Nocturnal melatonin levels under ALAN were significantly lower compared to controls, indicating that very low ALAN intensities suppress melatonin not only in nocturnal, but also in diurnal species.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Artificial Light at Night Increases Recruitment of New Neurons and Differentially Affects Various Brain Regions in Female Zebra Finches

Moaraf

Heiblum

Vistoropsky

et al. 2020

IJMS

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“…The evidence, largely accumulated from nocturnal rodents, suggests that artificial light at night (LAN) impacts a wide range of biological functions including sleep [1][2][3]. Similar LAN-induced negative effects have been found on daily cycles of the activity-rest and melatonin secretion, and on metabolism, reproduction, depression and cognitive performance in several songbirds including Indian weaver birds, Ploceus phillipinus [4]; blackbirds, Turdus merula [5]; great tits, Parus major [6][7][8]; Indian house crows, Corvus splendens [9]; zebra finches, Taeniopygia guttata [10,11] and tree sparrows, Passer montanus [12]. In particular, female great tits were awake for a greater portion of the night inside the nest-box when it was dimly illuminated [6].…”

Section: Introductionmentioning

confidence: 88%

Sleep in unnatural times: illuminated night negatively affects sleep and associated hypothalamic gene expressions in diurnal zebra finches

et al. 2020

Self Cite

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We investigated the effects of exposure at ecologically relevant levels of dim light at night (dLAN) on sleep and the 24 h hypothalamic expression pattern of genes involved in the circadian timing ( per2, bmal1 , reverb-β , cry1 , ror-α , clock ) and sleep regulatory pathways (cytokines: tlr4 , tnf - α , il-1β , nos ; Ca 2+ -dependent pathway: camk2 , sik3 , nr3a ; cholinergic receptor, achm3 ) in diurnal female zebra finches. Birds were exposed to 12 h light (150 lux) coupled with 12 h of absolute darkness or of 5 lux dim light for three weeks. dLAN fragmented the nocturnal sleep in reduced bouts, and caused sleep loss as evidenced by reduced plasma oxalate levels. Under dLAN, the 24 h rhythm of per2 , but not bmal1 or reverb-β , showed a reduced amplitude and altered peak expression time; however, clock , ror-α and cry1 expressions showed an abolition of the 24 h rhythm. Decreased tlr4 , il-1β and nos , and the lack of diurnal difference in achm3 messenger RNA levels suggested an attenuated inhibition of the arousal system (hence, awake state promotion) under dLAN. Similarly, changes in camk2 , sik3 and nr3a expressions suggested dLAN-effects on Ca 2+ -dependent sleep-inducing pathways. These results demonstrate dLAN-induced negative effects on sleep and associated hypothalamic molecular pathways, and provide insights into health risks of illuminated night exposures to diurnal animals.

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“…Reaction to novel objects and novel food is known as one of the main factors determining the capacity of a species to thrive in an urban environment (41). The DCX gene is related to neuronal plasticity (56) and experimental approaches revealed that artificial light at night induces an overexpression of this gene linked to a change in behaviour and expression of depressive-like behaviour in crows (57). Finally, the CHRNA1 gene is associated with aggressive behaviour in chicken (58), and higher aggressiveness is commonly observed and hypothesized as adaptive in urban bird populations (59).…”

Section: Discussionmentioning

confidence: 99%

Testing for parallel genomic and epigenomic footprints of adaptation to urban life in a passerine bird

Grégoire

et al. 2021

Preprint

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Identifying the molecular mechanisms involved in rapid adaptation to novel environments and determining their predictability are central questions in Evolutionary Biology and pressing issues due to rapid global changes. Complementary to genetic responses to selection, faster epigenetic variations such as modifications of DNA methylation may play a substantial role in rapid adaptation. In the context of rampant urbanization, joint examinations of genomic and epigenomic mechanisms are still lacking. Here, we investigated genomic (SNP) and epigenomic (CpG methylation) responses to urban life in a passerine bird, the Great tit (Parus major). To test whether urban evolution is predictable (ie parallel) or involves mostly non-parallel molecular processes among cities, we analysed three distinct pairs of city and forest Great tit populations across Europe. Results reveal a polygenic response to urban life, with both many genes putatively under weak divergent selection and multiple differentially methylated regions (DMRs) between forest and city great tits. DMRs mainly overlapped transcription start sites and promotor regions, suggesting their importance in the modulation gene expression. Both genomic and epigenomic outliers were found in genomic regions enriched for genes with biological functions related to nervous system, immunity, behaviour, hormonal and stress responses. Interestingly, comparisons across the three pairs of city-forest populations suggested little parallelism in both genetic and epigenetic responses. Our results confirm, at both the genetic and epigenetic levels, hypotheses of polygenic and largely non-parallel mechanisms of rapid adaptation in new environments such as urbanized areas.

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Illuminated night alters hippocampal gene expressions and induces depressive‐like responses in diurnal corvids

Cited by 39 publications

References 56 publications

Artificial Light at Night Increases Recruitment of New Neurons and Differentially Affects Various Brain Regions in Female Zebra Finches

Artificial Light at Night Increases Recruitment of New Neurons and Differentially Affects Various Brain Regions in Female Zebra Finches

Sleep in unnatural times: illuminated night negatively affects sleep and associated hypothalamic gene expressions in diurnal zebra finches

Testing for parallel genomic and epigenomic footprints of adaptation to urban life in a passerine bird

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