Circadian rhythms in insect disease vectors

Meireles-Filho, Antonio C. A.; Kyriacou, Charalambos P.

doi:10.1590/0074-0276130438

Cited by 67 publications

(70 citation statements)

References 133 publications

(156 reference statements)

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“…Thus, the adaptation of the daily activity patterns to different environmental conditions can be easily observed in flies, although individual animals are relatively short‐lived and do usually not experience several seasons (only the individuals that overwinter experience autumn, winter, and spring). The great advantage of studying flies is that the molecular and neuronal mechanisms of the circadian clock are well‐understood in D. melanogaster (see King & Sehgal, this issue) and start to emerge also in other Diptera (Bazalova & Dolezel, ; Bertolini et al., ; Codd et al., ; Gentile, Rivas, Meireles‐Filho, Lima, & Peixoto, ; Gesto et al., ; Kaiser et al., ; Kyriacou, ; Meireles‐Filho & Kyriacou, ; Meuti, Stone, Ikeno, & Denlinger, ; Noreen, Pegoraro, Nouroz, Tauber, & Kyriacou, ; Rivas et al., ; Rund, Hou, Ward, Collins, & Duffield, ). In D. melanogaster , recent studies have shown that M and E activity bouts are reflected by Ca 2+ rhythms in the relevant clock neurons controlling M and E activity, respectively (Liang, Holy, & Taghert, , ).…”

Section: Introductionmentioning

confidence: 99%

Flies as models for circadian clock adaptation to environmental challenges

Helfrich‐Förster

Bertolini

Menegazzi

2018

Eur J of Neuroscience

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Life on earth is assumed to have developed in tropical regions that are characterized by regular 24 hr cycles in irradiance and temperature that remain the same throughout the seasons. All organisms developed circadian clocks that predict these environmental cycles and prepare the organisms in advance for them. A central question in chronobiology is how endogenous clocks changed in order to anticipate very different cyclical environmental conditions such as extremely short and long photoperiods existing close to the poles. Flies of the family Drosophilidae can be found all over the world—from the tropics to subarctic regions—making them unprecedented models for studying the evolutionary processes that underlie the adaptation of circadian clocks to different latitudes. This review summarizes our current understanding of these processes. We discuss evolutionary changes in the clock genes and in the clock network in the brain of different Drosophilids that may have caused behavioural adaptations to high latitudes.

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Section: Introductionmentioning

confidence: 99%

Flies as models for circadian clock adaptation to environmental challenges

Helfrich‐Förster

Bertolini

Menegazzi

2018

Eur J of Neuroscience

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“…In conjunction with the conservation of core clock genes, our data suggest that D. pulex maintain a molecular clock with similar architecture to those studied in other eukaryotic organisms (Partch, Green, & Takahashi, ; Tilden et al., ). Of note, the expression levels of per and clk in our control population closely resemble the expression of these genes in mosquitoes ( Anopheles gambiae ), relevant as the circadian rhythm of D. pulex is thought to be more like that of butterflies and mosquitos than that of Drosophila (Bernatowicz et al., ; Meireles‐Filho & Kyriacou, ; Rund et al., ; Tilden et al., ).…”

Section: Discussionmentioning

confidence: 64%

“…Of note, the expression levels of per and clk in our control population closely resemble the expression of these genes in mosquitoes (Anopheles gambiae), relevant as the circadian rhythm of D. pulex is thought to be more like that of butterflies and mosquitos than that of Drosophila (Bernatowicz et al, 2016;Meireles-Filho & Kyriacou, 2013;Rund et al, 2016;Tilden et al, 2011).…”

Section: Discussionmentioning

confidence: 73%

Evolution to environmental contamination ablates the circadian clock of an aquatic sentinel species

Coldsnow

Relyea

Hurley

2017

Ecology and Evolution

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Environmental contamination is a common cause of rapid evolution. Recent work has shown that Daphnia pulex, an important freshwater species, can rapidly evolve increased tolerance to a common contaminant, sodium chloride (NaCl) road salt. While such rapid evolution can benefit organisms, allowing them to adapt to new environmental conditions, it can also be associated with unforeseen tradeoffs. Given that exposure to environmental contaminants can cause circadian disruption, we investigated whether the circadian clock was affected by evolving a tolerance to high levels of road salt. By tracking the oscillations of a putative clock gene, period, we demonstrated that D. pulex express per mRNA with approximately 20‐hr oscillations under control conditions. This putative circadian rhythm was ablated in response to high levels of salinity; populations adapted to high NaCl concentrations exhibited an ablation of period oscillation. Moreover, we showed that while gene expression is increased in several other genes, including clock, actin, and Na + /K + ‐ATPase, upon the adaptation to high levels of salinity, per expression is unique among the genes we tracked in that it is the only gene repressed in response to salt adaptation. These results suggest that rapid evolution of salt tolerance occurs with the tradeoff of suppressed circadian function. The resultant circadian disruption may have profound consequences to individuals, populations, and aquatic food webs by affecting species interactions. In addition, our research suggests that circadian clocks may also be disrupted by the adaptation to other environmental contaminants.

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“…activity change due to changes in their circadian rhythms by external factors such as light. 25 The number of Aedes spp. increased in the dormitory at night as students spend time at the dormitory at night, and electrical lighting attracts the mosquito.…”

Section: Discussionmentioning

confidence: 99%

Mosquito Survey in the Campus Area of Universitas Padjadjaran Jatinangor in September to November 2016

Faridah

Baizura

Yusnita

2017

GMHC

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Sumedang regency reported being one of dengue endemic areas in West Java. The number of dengue fever patients in Sumedang District General Hospital increased in the last quarter of 2015. Universitas Padjadjaran (Unpad) is one of most significant areas in Jatinangor Sumedang where many people are doing their activity day and night. The purpose of the study was to identify what types of mosquito genera exist in Unpad campus according to the time and location. A field survey was conducted at 22 locations in Unpad campus using modified electric light trap placed indoor and outdoor at each site from September to November 2016. The modified electrical trap was turned on for 24 hours and samples collected every 12 hours. Mosquitoes trapped were put into the plastic cup, labeled according to time collected, and brought to Parasitology Laboratory of Unpad for identification. The study result identified four types of mosquito genera which were Culex spp. (405), Armigeres spp. (70), Aedes spp. (33), and Anopheles spp. (10). Prevention toward potential breeding sites and protection using window net should be considered to reduce the risk of vector-borne diseases. In conclusion, Aedes spp. is the most active mosquito during the day while Culex spp. and Armigeres spp. are the most active mosquito during the night.

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Circadian rhythms in insect disease vectors

Cited by 67 publications

References 133 publications

Flies as models for circadian clock adaptation to environmental challenges

Flies as models for circadian clock adaptation to environmental challenges

Evolution to environmental contamination ablates the circadian clock of an aquatic sentinel species

Mosquito Survey in the Campus Area of Universitas Padjadjaran Jatinangor in September to November 2016

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