Experimental evolution reveals habitat‐specific fitness dynamics among <i><scp>W</scp>olbachia</i> clades in <i><scp>D</scp>rosophila melanogaster</i>

Versace, Elisabetta; Nolte, Viola; Pandey, Ram Vinay; Tobler, Raymond; Schlötterer, Christian

doi:10.1111/mec.12643

Cited by 43 publications

(37 citation statements)

References 61 publications

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“…Wolbachia’ s ability to provide anti‐viral protection to their hosts has emerged as the most promising approach to combatting insect‐vector borne pathogens that pose serious health risks to humans, such as dengue fever and Zika (Moreira et al ., ; Iturbe‐Ormaetxe et al ., ; Dutra et al ., ). However, because the strength of anti‐viral protection is associated with higher Wolbachia densities (Chrostek et al ., ; Martinez et al ., ) and bacterial titres are a temperature sensitive trait (Hoffmann et al ., ; Reynolds et al ., ; Mouton et al ., ; ; Bordenstein and Bordenstein, ; Correa and Ballard, ; Chrostek et al ., ; Strunov et al ., ; Murdock et al ., ; Versace et al ., ), it is feasible that under certain thermal conditions such as lower environmental temperatures, Wolbachia‐ induced virus protection could be attenuated or absent (Chrostek, ). Furthermore, our findings, as demonstrated in a highly inbred lab strain of D. melanogaster , need to be tested first in different host backgrounds, which are naturally or artificially infected with the endosymbiont.…”

Section: Discussionmentioning

confidence: 99%

Wolbachia modifies thermal preference in Drosophila melanogaster

Truitt

Kapun

Kaur

et al. 2018

Environmental Microbiology

100

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Environmental variation can have profound and direct effects on fitness, fecundity, and host-symbiont interactions. Replication rates of microbes within arthropod hosts, for example, are correlated with incubation temperature but less is known about the influence of host-symbiont dynamics on environmental preference. Hence, we conducted thermal preference (T ) assays and tested if infection status and genetic variation in endosymbiont bacterium Wolbachia affected temperature choice of Drosophila melanogaster. We demonstrate that isogenic flies infected with Wolbachia preferred lower temperatures compared with uninfected Drosophila. Moreover, T varied with respect to three investigated Wolbachia variants (wMel, wMelCS, and wMelPop). While uninfected individuals preferred 24.4°C, we found significant shifts of -1.2°C in wMel- and -4°C in flies infected either with wMelCS or wMelPop. We, therefore, postulate that Wolbachia-associated T variation within a host species might represent a behavioural accommodation to host-symbiont interactions and trigger behavioural self-medication and bacterial titre regulation by the host.

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Section: Discussionmentioning

confidence: 99%

Wolbachia modifies thermal preference in Drosophila melanogaster

Truitt

Kapun

Kaur

et al. 2018

Environmental Microbiology

100

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“…Kazancioglu & Arnqvist, ). There is also evidence that the presence of Wolbachia may affect life history in Drosophila (Fry et al ., ), and that the frequency of different Wolbachia strains may respond to selection imposed by thermal stress (Versace et al ., ), suggesting that genetic variation in Wolbachia may affect host stress tolerance. Our selected and control populations all carry Wolbachia (B. Erkosar, unpublished data).…”

Section: Discussionmentioning

confidence: 99%

Idiosyncratic evolution of maternal effects in response to juvenile malnutrition in Drosophila

Vijendravarma

Kawecki

2015

J of Evolutionary Biology

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Maternal effects often affect fitness traits, but there is little experimental evidence pertaining to their contribution to response to selection imposed by novel environments. We studied the evolution of maternal effects in Drosophila populations selected for tolerance to chronic larval malnutrition. To this end, we performed pairwise reciprocal F 1 crosses between six selected (malnutrition tolerant) populations and six unselected control populations and assessed the effect of cross direction on larval growth and developmental rate, adult weight and egg-to-adult viability expressed under the malnutrition regime. Each pair of reciprocal crosses revealed large maternal effects (possibly including cytoplasmic genetic effects) on at least one trait, but the magnitude, sign and which traits were affected varied among populations. Thus, maternal effects contributed significantly to the response to selection imposed by the malnutrition regime, but these changes were idiosyncratic, suggesting a rugged adaptive landscape. Furthermore, although the selected populations evolved both faster growth and higher viability, the maternal effects on growth rate and viability were negatively correlated across populations. Thus, genes mediating maternal effects can evolve to partially counteract the response to selection mediated by the effects of alleles on their own carriers' phenotype, and maternal effects may contribute to evolutionary trade-offs between components of offspring fitness.

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“…At its most powerful, this may involve varying thermal environment within laboratory or caged populations over a number of generations and examining its impact on symbiont dynamics. For instance, Versace et al (2014) noted that the Wolbachia strain that spread in passage through Drosophila melanogaster population cages depended upon the temperature at which the population was maintained (Versace et al, 2014). However, studies such as this are logistically complex for many species.…”

Section: The Interaction Between Thermal Environment and Facultative mentioning

confidence: 99%

Heritable symbionts in a world of varying temperature

et al. 2016

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Heritable microbes represent an important component of the biology, ecology and evolution of many plants, animals and fungi, acting as both parasites and partners. In this review, we examine how heritable symbiont-host interactions may alter host thermal tolerance, and how the dynamics of these interactions may more generally be altered by thermal environment. Obligate symbionts, those required by their host, are considered to represent a thermally sensitive weak point for their host, associated with accumulation of deleterious mutations. As such, these symbionts may represent an important determinant of host thermal envelope and spatial distribution. We then examine the varied relationship between thermal environment and the frequency of facultative symbionts that provide ecologically contingent benefits or act as parasites. We note that some facultative symbionts directly alter host thermotolerance. We outline how thermal environment will alter the benefits/costs of infection more widely, and additionally modulate vertical transmission efficiency. Multiple patterns are observed, with symbionts being cold sensitive in some species and heat sensitive in others, with varying and non-coincident thresholds at which phenotype and transmission are ablated. Nevertheless, it is clear that studies aiming to predict ecological and evolutionary dynamics of symbiont-host interactions need to examine the interaction across a range of thermal environments. Finally, we discuss the importance of thermal sensitivity in predicting the success/failure of symbionts to spread into novel species following natural/engineered introduction.

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Experimental evolution reveals habitat‐specific fitness dynamics among Wolbachia clades in Drosophila melanogaster

Cited by 43 publications

References 61 publications

Wolbachia modifies thermal preference in Drosophila melanogaster

Wolbachia modifies thermal preference in Drosophila melanogaster

Idiosyncratic evolution of maternal effects in response to juvenile malnutrition in Drosophila

Heritable symbionts in a world of varying temperature

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