Artificial light at night amplifies seasonal relapse of haemosporidian parasites in a widespread songbird

Becker, Daniel J.; Singh, Devraj; Pan, Qiuyun; Montoure, Jesse D.; Talbott, Katherine; Wanamaker, Sarah; Ketterson, Ellen D.

doi:10.1101/2020.06.22.163998

Cited by 6 publications

(6 citation statements)

References 67 publications

(91 reference statements)

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“…At the individual level, ALAN can disrupt biological rhythm, behavior, and physiology for both migratory and resident species. Examples include adverse effects on body mass and reproductive success (Malek & Haim, 2019), disease tolerance (Kernbach et al, 2021; Malek & Haim, 2019), immunity and parasitism (Becker et al, 2020), intestinal microbiota (Jiang et al, 2020), breeding phenology (Dominoni et al, 2020; Kempenaers et al, 2010), migration phenology (Smith et al, 2021), foraging activity (Amichai & Kronfeld‐Schor, 2019), and sleeping behavior (Aulsebrook et al, 2020; Sun et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Seasonal associations with light pollution trends for nocturnally migrating bird populations

et al. 2022

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Artificial light at night (ALAN) is adversely affecting natural systems worldwide, including the disorienting influence of ALAN on nocturnally migrating birds. Understanding how ALAN trends are developing across species' seasonal distributions will inform mitigation efforts, such as Lights Out programs. Here, we intersect ALAN annual trend estimates with weekly estimates of relative abundance for 42 nocturnally migrating passerine bird species that breed in North America using observations from the eBird community science database for the combined period 2005-2020. We use a cluster analysis to identify species with similar weekly associations with ALAN trends. Our results identified three prominent clusters. Two contained species that occurred in northeastern and western North America during the breeding season. These species were associated with moderate ALAN levels and weak negative ALAN trends during the breeding season, and low ALAN levels and strong positive ALAN trends during the nonbreeding season. The difference between the breeding and nonbreeding seasons was lower for species that occurred in northern South America and greater for species that occurred in Central America during the nonbreeding season. For species that occurred in South America during the nonbreeding season, positive ALAN trends increased in strength as species migrated through Central America, especially in the spring. The third cluster contained species whose associations with positive ALAN trends remained high across the annual cycle, peaking during migration, especially in the spring. These species occurred in southeastern North America during the breeding season where they were associated with high ALAN levels, and in northern South America during the nonbreeding season where they were associated with low ALAN levels. Our findings suggest reversing ALAN trends in Central America during migration, especially in the spring, would benefit the most individuals of the greatest number of species. Reversing ALAN trends in southeastern North America during the breeding season and Central America during the nonbreeding season would generate the greatest benefits outside of migration.

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Section: Introductionmentioning

confidence: 99%

Seasonal associations with light pollution trends for nocturnally migrating bird populations

et al. 2022

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“…infection risk increases with elevation; however, most of these infections were submicroscopic in high elevation in breeding season (April-May). This contrasts with studies on the ecology of haemosporidia in temperate regions where birds with latent infections return to the breeding grounds and experience a relapse, with increase in parasites visible in the blood stages (Applegate, 1970;Becker et al, 2020). In general, We used climate models to interrogate how changing temperature from 2021 to 2040 could potentially lead to an expansion of the temperature range conducive for malaria transmission in highelevation zones.…”

Section: Discussionmentioning

confidence: 99%

Exploring the thermal limits of malaria transmission in the western Himalaya

Mozaffer

Menon

Ishtiaq

2022

Ecology and Evolution

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Environmental temperature is a key driver of malaria transmission dynamics. Using detailed temperature records from four sites: low elevation (1800), mid elevation (2200 m), and high elevation (2600–3200 m) in the western Himalaya, we model how temperature regulates parasite development rate (the inverse of the extrinsic incubation period, EIP) in the wild. Using a Briére parametrization of the EIP, combined with Bayesian parameter inference, we study the thermal limits of transmission for avian ( Plasmodium relictum ) and human Plasmodium parasites ( P. vivax and P. falciparum ) as well as for two malaria‐like avian parasites, Haemoproteus and Leucocytozoon . We demonstrate that temperature conditions can substantially alter the incubation period of parasites at high elevation sites (2600–3200 m) leading to restricted parasite development or long transmission windows. The thermal limits (optimal temperature) for Plasmodium parasites were 15.62–34.92°C (30.04°C) for P. falciparum , 13.51–34.08°C (29.02°C) for P. vivax , 12.56–34.46°C (29.16°C) for P. relictum and for two malaria‐like parasites, 12.01–29.48°C (25.16°C) for Haemoproteus spp. and 11.92–29.95°C (25.51°C) for Leucocytozoon spp. We then compare estimates of EIP based on measures of mean temperature versus hourly temperatures to show that EIP days vary in cold versus warm environments. We found that human Plasmodium parasites experience a limited transmission window at 2600 m. In contrast, for avian Plasmodium transmission was not possible between September and March at 2600 m. In addition, temperature conditions suitable for both Haemoproteus and Leucocytozoon transmission were obtained from June to August and in April, at 2600 m. Finally, we use temperature projections from a suite of climate models to predict that by 2040, high elevation sites (~2600 m) will have a temperature range conducive for malaria transmission, albeit with a limited transmission window. Our study highlights the importance of accounting for fine‐scale thermal effects in the expansion of the range of the malaria parasite with global climate change.

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“…Such resources could dampen or amplify pathogen relapse at spring departure depending on their nutritional quality or effects on host density and crowding [75]. Other stressors in urban habitats, such as artificial light at night, could further amplify the likelihood of relapse [76]. These consequences of urban habituation could be especially relevant for human health in the context of wildlife reservoirs of relapsing zoonoses, such as flying foxes and henipaviruses [77].…”

Section: Discussionmentioning

confidence: 99%

Reactivation of latent infections with migration shapes population-level disease dynamics

2020

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Annual migration is common across animal taxa and can dramatically shape the spatial and temporal patterns of infectious disease. Although migration can decrease infection prevalence in some contexts, these energetically costly long-distance movements can also have immunosuppressive effects that may interact with transmission processes in complex ways. Here, we develop a mechanistic model for the reactivation of latent infections driven by physiological changes or energetic costs associated with migration (i.e. ‘migratory relapse’) and its effects on disease dynamics. We determine conditions under which migratory relapse can amplify or reduce infection prevalence across pathogen and host traits (e.g. infectious periods, virulence, overwinter survival, timing of relapse) and transmission phenologies. We show that relapse at either the start or end of migration can dramatically increase prevalence across the annual cycle and may be crucial for maintaining pathogens with low transmissibility and short infectious periods in migratory populations. Conversely, relapse at the start of migration can reduce the prevalence of highly virulent pathogens by amplifying culling of infected hosts during costly migration, especially for highly transmissible pathogens and those transmitted during migration or the breeding season. Our study provides a mechanistic foundation for understanding the spatio-temporal patterns of relapsing infections in migratory hosts, with implications for zoonotic surveillance and understanding how infection patterns will respond to shifts in migratory propensity associated with environmental change. Further, our work suggests incorporating within-host processes into population-level models of pathogen transmission may be crucial for reconciling the range of migration–infection relationships observed across migratory species.

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Artificial light at night amplifies seasonal relapse of haemosporidian parasites in a widespread songbird

Cited by 6 publications

References 67 publications

Seasonal associations with light pollution trends for nocturnally migrating bird populations

Seasonal associations with light pollution trends for nocturnally migrating bird populations

Exploring the thermal limits of malaria transmission in the western Himalaya

Reactivation of latent infections with migration shapes population-level disease dynamics

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