Sensory cues underlying competitive growth in the clown anemonefish (Amphiprion percula)

Desrochers, Leah

20 January 2021

In some animal societies, access to breeding depends on the individual’s position in a hierarchy, which often depends on an individual’s size. In such societies, individuals may engage in competitive growth, trying to outgrow one another to attain a higher rank. This suggests that members of the hierarchy can track changes in the growth and size of potential competitors and respond accordingly. The clown anemonefish, Amphiprion percula, is one species known to exhibit competitive growth at the initiation of size hierarchies. Here, we use 5 combinations of sensory cues to determine which cues must be available to initiate competitive growth between size-matched individuals. Our results show that mechanosensory (pressure and/or touch) cues are used to assess size and initiate competitive growth. This study provides an understanding into the relationship between environment and phenotypic response in a social context.

Biology

Amphiprion percula

Competitive growth

Mechanosensory cues

Phenotypic plasticity

Sensory cues

Développement embryonnaire, détermination du sexe sensible à la température et phénologie des pontes sous contrainte du changement climatique : le cas de la tortue Caouanne (Caretta caretta) / Embryonic development, temperature-dependent sex determination and nesting phenology under climate change constraints : the case of the loggerhead turtle (Caretta caretta)

Monsinjon, Jonathan

20 December 2017

Le climat affecte entre autre la phénologie, l’aire de distribution, le comportement et la physiologie des espèces. Le changement climatique a donc des répercussions sur chacun de ces facteurs. L’augmentation globale des températures prévue d’ici 2100 pourrait profondément modifier la biodiversité de l’échelle des espèces jusqu’à celle des écosystèmes. Les ectothermes, et en particulier les reptiles ovipares à détermination du sexe sensible à la température, font partie des organismes susceptibles d’être les plus vulnérables au réchauffement du climat puisque quasiment tous leurs traits d’histoire de vie dépendent de la température. L’origine et le maintien de ce mécanisme de détermination du sexe, pouvant conduire à un sex ratio fortement biaisé à l’échelle d’une population, reste une énigme pour les écologues. Parmi les nombreuses questions soulevées par la présence de ce mécanisme de détermination du sexe, la signification adaptative, s’il y en a une, de ce mécanisme est cruciale.Ce mécanisme de détermination du sexe rend-il les espèces plus vulnérables dans le contexte actuel du changement du climat ? Plusieurs hypothèses évolutives ont été proposées et des modèles de dynamique des populations sont disponibles pour répondre à ces questions. Cependant, prédire le sex ratio primaire en conditions naturelles, c’est-à-dire le sex ratio des nouveaux nés, reste un défi majeur à l’heure actuel. Ce manuscrit vise à apporter de nouveaux outils méthodologiques afin de correctement prédire le sex ratio d’une ponte en fonction de la température ressentie par les embryons au cours de l’incubation. Les tortues marines,quasiment toutes menacées, sont des espèces migratrices présentant toute ce mécanisme de détermination du sexe.Chez ces espèces, la phénologie des pontes est aussi sensible à la température du milieu. Ce type de plasticité phénotypique est probablement la stratégie la plus efficace pour pallier à un changement rapide du climat. Ce manuscrit apporte quelques éléments de réponse quant au potentiel adaptatif des tortues marines face au réchauffement climatique avec l’exemple de plusieurs populations de tortues Caouanne (Caretta caretta). / Climate affects, among other things, species’phenology, distribution range, behavior and physiology.Climate change thus impacts each of these factors. Global warming expected by 2100 might profoundly modify biodiversity from species to ecosystems. Ectotherms, and in particular oviparous reptiles with temperature dependent sex determination, are thought to be among the most vulnerable in the face of global warming because virtually all their life history traits depend on temperature.The origin and the persistence of temperature-dependent sex determination, which could lead to heavily biased population sex ratios, is still an enigma for ecologists. Among numerous issues related to this sex determining mechanism, understanding its adaptive significance, if there is one, is crucial. At another level, does this sex determining mechanism make species more vulnerable in the context of contemporary climate change ? Several evolutionary hypotheses have been proposed and population dynamic models are available to address these issues. However, predicting primary sex ratio, i.e., the sex ratio of hatchlings, in natural conditions currently remainsa challenge. This manuscript aims to bring new methodological tools to properly predict sex ratio of aclutch depending on temperature experienced by embryosthroughout incubation. Marine turtles, almost all being threatened, are migratory species that all exhibit this sex determining mechanism. For those species, nesting phenology is also sensitive to environmental temperature.This type of phenotypic plasticity is probably the most efficient strategy to keep up with rapid climate change.This manuscript provides some elements for understanding the adaptive potential of sea turtles in the face of global warming with the example of several).

Tortue marine

Reptile

Incubation

Plasticité phénotypique

Norme de réaction

Sea turtle

Reptile

Incubation

Phenotypic plasticity

Reaction norm

Contrôle génétique de l'établissement et de la plasticité de la pigmentation abdominale chez Drosophila melanogaster / Genetic control of the establishment and the plasticity of abdominal pigmentation in Drosophila melanogaster

Silva de Castro, Sandra

29 November 2018

La plasticité phénotypique est la capacité d’un génotype donné à produire différents phénotypes en réponse à différents environnements tels que la température, la nutrition ou encore la présence de prédateurs. Ce phénomène permet aux individus de s’adapter à des environnements fluctuants. Il peut également faciliter l’évolution en élargissant la gamme de phénotypes produits par un génotype. Comme modèle de plasticité phénotypique, nous étudions la pigmentation abdominale chez les femelles Drosophila melanogaster. En effet, ce caractère est sensible à la température : les femelles drosophiles sont plus pigmentées lorsqu’elles se développent à basse température, particulièrement dans les segments abdominaux postérieurs. Les études précédentes du laboratoire ont montré que le gène tan (t), codant une enzyme de pigmentation, est beaucoup plus fortement exprimé à 18°C qu'à 29°C. Par ailleurs, ce gène joue un rôle essentiel dans la plasticité phénotypique de la pigmentation abdominale des femelles Drosophila melanogaster. Au cours de ma thèse, je me suis intéressée à la caractérisation du réseau de gènes impliqué dans la régulation de l’expression de t dans l’épiderme abdominal des femelles Drosophila melanogaster. J'ai également cherché à identifier, dans ce réseau, les acteurs pouvant médier l'effet de la température sur l'expression de t. A l'aide d'une approche gène candidat, j'ai montré que les facteurs de transcription Bric-à-Brac (Bab) et Abdominal-B (Abd-B) intervenaient dans la plasticité phénotypique de la pigmentation abdominale en régulant notamment t. De plus, j'ai réalisé un crible génétique ciblant 573 gènes codant des facteurs de transcription et des régulateurs de la chromatine afin d'identifier de nouveaux régulateurs de t. A l'issue de ce crible, j'ai obtenu une liste de 27 gènes impliqués dans cette régulation. J'ai ensuite commencé la caractérisation fonctionnelle de deux de ces candidats : forkhead box subgroup O (foxo) codant un facteur de transcription impliqué dans la voie de réponse à l'insuline et little imaginal discs (lid) codant une histone déméthylase. / Phenotypic plasticity is the ability of a given genotype to produce different phenotypes in response to different environmental factors such as temperature, nutrition or presence of predators. This phenomenon allows the adaptation of individuals to their fluctuating environments. It can also facilitate evolution, as it broadens the range of phenotypes produced by a given genotype. As a model of phenotypic plasticity, we study the abdominal pigmentation in Drosophila melanogaster females. Indeed, this trait is temperature-sensitive: drosophila females are darker when they develop at lower temperatures particularly in the posterior segments. In the laboratory, it has been previously shown, that tan (t), a gene encoding a pigmentation enzyme, is more expressed at 18°C than at 29°C. Moreover, this gene plays an essential role in the phenotypic plasticity of abdominal pigmentation in Drosophila melanogaster females. During my thesis, I aimed to characterize the gene regulatory network involved in t regulation in the abdominal epidermis of Drosophila melanogaster females. I also tried to identify, in this network, the actors mediating the effect of temperature on t expression. Using a candidate gene approach, I showed that the transcription factors Bric-à-brac (Bab) and Abdominal-B (Abd-B) are involved in the phenotypic plasticity of abdominal pigmentation by regulating t. Furthermore, I performed a genetic screen targeting 573 genes encoding transcription factors and chromatin regulators to identify new regulators of t. At the end of this screen, I obtained a list of 27 genes involved in this regulation. I then started the functional characterization of two of these candidates: forkhead box subgroup O (foxo) encoding a transcription factor involved in the insulin response pathway and little imaginal discs (lid) encoding a histone demethylase.

Drosophile

Plasticité phénotypique

Pigmentation abdominale

Tan

Bab

Foxo

Lid

Drosophila

Phenotypic plasticity

Abdominal pigmentation

571.85

Plasticité phénotypique chez le Cnidaire symbiotique Anemonia viridis : analyse de la réponse au stress à différents niveaux de complexité structurale / Phenotypic plasticity in the symbiotic cnidarian Anemonia viridis : stress response at multiple levels of structural complexity

Ventura, Patrícia Nobre Montenegro

12 December 2016

Durant leur cycle de vie, les organismes sont exposés à des variations environnementales capables d'induire des changements physiologiques, morphologiques et comportementaux, résultant d’une plasticité phénotypique. La plasticité phénotypique est la capacité d'un génotype à générer un nouveau phénotype suite à un stress. Ici, nous avons étudié la plasticité phénotypique d’un Cnidaire symbiotique et non-calcifiant, l’anémone de mer Anemonia viridis, à de multiples niveaux de complexité structurale, in vivo et in vitro. In vivo, nous avons identifié les mécanismes sous-jacents de la plasticité phénotypique potentiellement induits par les futurs changements climatiques (acidification et réchauffement des océans). Nos résultats montrent des modifications dans l'utilisation du carbone inorganique par A. viridis exposée à une forte pCO2 lors d’un stress chronique in natura ou lors d’un stress court en conditions contrôlées. Nous avons ainsi observé une diminution des activités anhydrase carbonique, une enzyme clé des mécanismes de concentration du carbone chez les Cnidaires. Nous avons aussi démontré que l'augmentation concomittante de la température modifie la réponse observée lors d'une élévation seule de la pCO2. In vitro, nous avons établi une culture de cellules primaires viables issue de tentacules d’A. viridis en régénération. Nous avons déterminé l'origine gastrodermale des cellules cultivées et validé l'utilisation de ce nouvel outil pour l'étude de la réponse au stress au niveau cellulaire. Ce nouvel outil ouvre une multitude de perspectives pour l'étude des réponses cellulaires aux stress exogènes (changement climatique) et endogènes (contraintes dues à la symbiose) / During the course of their life cycle organisms are exposed to natural environment variations capable of inducing physiological, morphological and behaviour changes, thus a phenotypic plasticity. Phenotypic plasticity is the ability of a genotype to generate a new phenotype following exogeneous or endogeneous stress. Here, we investigated the phenotypic plasticity of the non-calcifying symbiotic cnidarian Anemonia viridis at multiple levels of structural complexity, in vivo and in vitro. In vivo, we determined the mechanisms behind the phenotypic plasticity under expected future climate change (i.e. ocean acidification and ocean warming). Our results show physiological changes in the inorganic carbon use of the sea anemone A. viridis exposed to high pCO2 during a long-term stress in natura or a short-term stress in controlled conditions. We then observed an equivalent decrease in carbonic anhydrase activity, a key enzyme of cnidarian carbon concentrating mechanisms. Also, we demonstrated that an increase in seawater temperature modified the response observed during a high pCO2 scenario. In vitro, we established a viable primary cell culture from regenerating tentacles of A. viridis. We determined the gastrodermal tissue origin of the cultivated cells and validated the use of this new tool to the in vitro study of stress response at the cellular level. The set-up of this powerful in vitro tool will open a multitude of perspectives for the study of cellular responses to exogeneous stress (as global change perturbations) and to endogeneous stress (as the symbiosis constraints experienced by symbiotic cnidarians)

Cnidaire symbiotique

Plasticité phénotypique

Acidification

Culture des cellules

Symbiotic Cnidarian

Phenotypic plasticity

Acidification

Culture cells

Fenotypová variabilita a evoluční vztahy populací Primula elatior podél výškového gradientu / Phenotypic variability and evolutionary relationships among populations of Primula elatior along an altitudinal gradient

Konečná, Veronika

January 2017

Primula elatior represents a promising model for addressing the role of phenotypic plasticity vs. genetic basis of traits in populations differentiated along altitudinal gradients. Phenotypic plasticity is mainly exhibited by the extensive variability of the leaves. Genetic structure of P. elatior populations has been poorly studied so far, the first insights suggested potentially large intraspecific genetic variation. Therefore, the first aim of this study was to reveal the genetic structure as well as morphological and cytological variation of P. elatior populations in the central Europe and compare those to another two intraspecific taxa from the southeastern Europe. Further, I selected three target mountain regions to address the role of altitudinal differentiation for structuring genetic diversity. Finally, I evaluated the status of the putative endemic species Primula elatior subsp. corcontica from the Krkonoše Mts. Microsatellite analyses, multivariate morphometrics and flow cytometry were employed to evaluate variation of P. elatior populations. I identified six major genetic groups by genotyping 12 nuclear microsatellite loci in the study area of central and southeastern Europe with the clear separation of subp. intricata. Focused on the central Europe, three well-defined genetic groups...

Fenotypová plasticita perloočky Daphnia cucullata ve dvou polabských tůních / Phenotypic plasticity of Daphnia cucullata in two lowland ponds

Volemanová, Eva

January 2010

4 ABSTRACT Characteristic high helmets in Daphnia cucullata, which increase resistance of Daphnia against various invertebrate predators, can be induced by chemical cues released by these invertebrates but also by small-scale turbulence. I evaluated the response of D. cucullata to both factors in several clones originating from two riverine pools differing in their predator regime. In a large pool, the dominant invertebrate predator is the cladoceran Leptodora kindtii, and the Daphnia population there shows a typical cyclomorphosis. In the second (small) pool, Daphnia do not produce helmets, despite the presence of the phantom midge larvae Chaoborus flavicans. I compared phenotypic changes of Daphnia cucullata clones from these pools to Chaoborus kairomones and to a small-scale turbulence in laboratory experiments. Kairomones induced significantly longer helmets in clones from both pools; however, only clones form the large pool reacted also to turbulence. As all daphnids in the experiments responded to chemical cues from Chaoborus, I assume that either the kairomone dose under natural conditions in the small pool is too low to induce helmets or the phenotypic response of the local population is mediated by other factors. On the other hand, the variation of response to small-scale turbulence suggests that...

Adaptive Phenotypic Plasticity and Local Adaptation for Temperature Tolerance in Freshwater Zooplankton

Yampolsky, Lev Y., Schaer, Tobias M.M., Ebert, Dieter

18 December 2013

Many organisms have geographical distributions extending from the tropics to near polar regions or can experience up to 30°C temperature variation within the lifespan of an individual. Two forms of evolutionary adaptation to such wide ranges in ambient temperatures are frequently discussed: local adaptation and phenotypic plasticity. The freshwater planktonic crustaceanDaphnia magna, whose range extends from South Africa to near arctic sites, shows strong phenotypic and genotypic variation in response to temperature. In this study, we use D. magna clones from 22 populations (one clone per population) ranging from latitude 0° (Kenya) to 66° North (White Sea) to explore the contributions of phenotypic plasticity and local adaptation to high temperature tolerance. Temperature tolerance was studied as knockout time (time until immobilization, Timm) at 37°C in clones acclimatized to either 20°C or 28°C. Acclimatization to 28°C strongly increased Timm, testifying to adaptive phenotypic plasticity. At the same time, Timm significantly correlated with average high temperature at the clones' sites of origin, suggesting local adaptation. As earlier studies have found that haemoglobin expression contributes to temperature tolerance, we also quantified haemoglobin concentration in experimental animals and found that both acclimatization temperature (AccT) and temperature at the site of origin are positively correlated with haemoglobin concentration. Furthermore, Daphnia from warmer climates upregulate haemoglobin much more strongly in response to AccT, suggesting local adaptation for plasticity in haemoglobin expression. Our results show that both local adaptation and phenotypic plasticity contribute to temperature tolerance, and elucidate a possible role of haemoglobin in mediating these effects that differs along a cold-warm gradient.

daphnia

haemoglobin

heat tolerance

local adaptation

phenotypic plasticity

temperature

Biological Sciences

Adaptive Phenotypic Plasticity and Local Adaptation for Temperature Tolerance in Freshwater Zooplankton

Yampolsky, Lev Y., Schaer, Tobias M.M., Ebert, Dieter

18 December 2013

Many organisms have geographical distributions extending from the tropics to near polar regions or can experience up to 30°C temperature variation within the lifespan of an individual. Two forms of evolutionary adaptation to such wide ranges in ambient temperatures are frequently discussed: local adaptation and phenotypic plasticity. The freshwater planktonic crustaceanDaphnia magna, whose range extends from South Africa to near arctic sites, shows strong phenotypic and genotypic variation in response to temperature. In this study, we use D. magna clones from 22 populations (one clone per population) ranging from latitude 0° (Kenya) to 66° North (White Sea) to explore the contributions of phenotypic plasticity and local adaptation to high temperature tolerance. Temperature tolerance was studied as knockout time (time until immobilization, Timm) at 37°C in clones acclimatized to either 20°C or 28°C. Acclimatization to 28°C strongly increased Timm, testifying to adaptive phenotypic plasticity. At the same time, Timm significantly correlated with average high temperature at the clones' sites of origin, suggesting local adaptation. As earlier studies have found that haemoglobin expression contributes to temperature tolerance, we also quantified haemoglobin concentration in experimental animals and found that both acclimatization temperature (AccT) and temperature at the site of origin are positively correlated with haemoglobin concentration. Furthermore, Daphnia from warmer climates upregulate haemoglobin much more strongly in response to AccT, suggesting local adaptation for plasticity in haemoglobin expression. Our results show that both local adaptation and phenotypic plasticity contribute to temperature tolerance, and elucidate a possible role of haemoglobin in mediating these effects that differs along a cold-warm gradient.

daphnia

haemoglobin

heat tolerance

local adaptation

phenotypic plasticity

temperature

Biological Sciences

Social dominance and personality in male fowl (Gallus gallus domesticus)

Favati, Anna

January 2013

Individuals in social species commonly form dominance relationships among each other, and are often observed to differ in behaviour depending on their social status. However, whether such behavioural differences are a consequence of dominance position, or also a cause to it, remains unclear. In this thesis I therefore investigated two perspectives of the relationship between social dominance and personality in the domestic fowl (Gallus gallus domesticus), a social species that forms relatively stable dominance hierarchies. In paper I I investigated the influence of social status on the expression and consistency of behaviours by experimentally changing status between repeated personality assays. The level of vigilance, activity and exploration changed with social status, while boldness and territorial crows appeared as stable individual properties, independent of status. These results showed that social status contribute to both variation and consistency in behavioural responses. Social status should therefore be taken into account when investigating and interpreting variation in personality. In paper II I showed that behaviour in a novel arena test and during encounter with an opponent can predict social status, more specifically that fast exploration and aggressiveness predicted a dominant social position. Together, these results highlight the dynamics of the two-way relationship between social position and individual behaviour and indicate that individual behaviour can both be a cause and a consequence of social status.

Behavioral Sciences Biology

Etologi

Plastic and Genetic Determination of Population, Community, and Ecosystem Properties in Freshwater Environments

Latta, IV, Leigh C.

01 May 2010

The hierarchy of biological organization, from molecules to ecosystems, describes the relationships among various biological systems. Of particular interest is assessing how the factors that primarily determine the nature of one hierarchical level also have transcendent qualities that affect the ecology and evolution of higher hierarchical levels. The goal of this dissertation was to use a bottom-up approach to examine the transcendent effects of two factors that strongly determine the nature of their associated level of biological organization. The first, phenotypic plasticity, is a primary factor that determines the phenotype of an individual. The second factor, genetic diversity, largely determines the phenotypic distributions associated with populations. Controlled laboratory experiments on taxa from a freshwater tri-trophic food web were employed to examine the transcendent effects of phenotypic plasticity and genetic diversity on the biological hierarchy because relationships between individuals and populations from different trophic levels are well documented for numerous freshwater species. The results show that phenotypic plasticity can induce changes in population means and variances that promote population persistence and evolvability, and that plasticity provides a mechanistic explanation of community stability in response to changing environments. Similarly, genetic diversity may act as a signal that induces phenotypic plasticity in individuals, modulates community richness and ecosystem properties, and suggests a potential mechanism for the changes in biodiversity. Thus, results from this dissertation show that plasticity and genetic variation can shape the attributes of other biological groups higher in the biological hierarchy, and, in some cases, may also provide a mechanistic explanation for variability observed in higher levels of the biological hierarchy. These results highlight the importance of integrating traditionally disparate biological disciplines and may help to unify biology as a field.

Community

Daphnia

Ecosystem

Genetic Variation

Phenotypic Plasticity

Ecology and Evolutionary Biology

Genetics