Mutualisme fourmis pucerons et guilde aphidiphage associée : le cas de la prédation furtive

Le mutualisme est une relation ubiquiste qui est étudiée sérieusement par les écologistes depuis les années 70. Les fourmis, de part leur rôle écologique au sein des écosystèmes, ont développé des relations de mutualisme avec de nombreux organismes et fournissent donc un modèle intéressant pour l'étude de cette interaction. La relation développée avec des herbivores de l'ordre des Homoptères et plus particulièrement les pucerons a été bien étudiée. Divers bénéfices pour les pucerons ont ainsi été mis en évidence, et il semble que la protection contre les ennemis naturels soit le bénéfice majeur retiré de cette association. Cependant, quelques ennemis naturels, surtout parmi les parasitoïdes, ont été identifiés comme étant capables d'exploiter les colonies de pucerons malgré la présence de fourmis par des mécanismes physiologiques, morphologiques ou comportementaux.\ud Cette étude se divise en trois sections. Le premier chapitre explore les facteurs qui influencent le nombre de fourmis que l'on retrouve au sein des colonies de pucerons. Le nombre de pucerons est alors le principal facteur déterminant le nombre de fourmis que l'on rencontre sur les colonies de pucerons. La date, souvent reliée au nombre de pucerons, influence également le nombre de fourmis. Ce chapitre montre aussi qu'il existe une hiérarchie dans l'entretien des différentes espèces de pucerons rencontrées. Le second chapitre étudie la composition de la guilde aphidiphage que l'on retrouve sur les colonies de pucerons en présence de fourmis. L'ensemble de ces ennemis naturels est divisé en trois guildes distinctes en fonction de leur comportement de prédation: les prédateurs actifs qui déclenchent des réactions défensives chez leurs proies et dont les mouvements sont rapides, les prédateurs furtifs qui ne déclenchent pas de réaction défensive chez leur proie et dont les mouvements sont réduits, et enfin les parasitoïdes qui pondent sur ou dans leur proie. Nous avons alors postulé que les prédateurs furtifs et les parasitoïdes seront dominants au sein des colonies entretenues. Les prédateurs actifs sont alors les plus affectés quels que soit le système plante-pucerons étudié. À l'inverse, les prédateurs furtifs sont dominants au sein de ces communautés sur le chardon et le pommier. Les parasitoïdes sont eux dominants sur asclépiade. L'exclusion des prédateurs actifs par les fourmis semble alors privilégier les ennemis naturels plus vulnérables comme les prédateurs furtifs ou les parasitoïdes. Le troisième chapitre étudie la capacité d'un prédateur furtif, Aphidoletes aphidimyza, à se maintenir au sein de colonies de pucerons entretenues par les fourmis, ainsi que l'impact du mouvement sur ce maintien. La présence de fourmis n'affecte pas le maintien du prédateur furtif contrairement au prédateur actif, Harmonia axyridis. La comparaison entre les larves mobiles et immobiles du prédateur actif montre alors que le mouvement semble affecter l'agressivité des fourmis envers les ennemis naturels.\ud Cette étude explore donc diverses facettes de la relation de mutualisme fourmis-pucerons, ainsi que l'impact de cette interaction sur les ennemis naturels associés aux pucerons. Plusieurs questions évolutives, qui nécessiteront des études complémentaires pour y répondre, sont alors soulevées par ces résultats. ______________________________________________________________________________ MOTS-CLÉS DE L’AUTEUR : Mutualisme, Trade off coûts-bénéfices, Comportement de prédation, Guilde aphidiphage, Prédation furtive, Mouvements, Zone libre d'ennemi

Toward understanding the predatory ant genus Myopias (Formicidae: Ponerinae), including a key to global species, male-based generic diagnosis, and new species description

The predatory ponerine genus Myopias has remained poorly-known despite considerable interest. To encourage future revisionary and natural history research on the genus, we provide the first global key to valid species, the first male-based diagnosis, a detailed description of a new species—M. darioi sp. nov.—based on all castes, a review of the natural history, and an update of biogeographic knowledge. The new species is distinguished from all valid Myopias species by the comparatively enlarged frontal lobes, subrectangular midclypeal lobe lacking denticles, strongly reduced eyes, and details of mandibular morphology.

Tracing the Rise of Ants - Out of the Ground

We thank S.G. Brady, T.R. Schultz, B.L. Fisher and P.S. Ward for making original data available for re-analysis. P.S. Ward, M. Borowiec and J.K. Lattke provided input regarding habitat strata of the ant genera. J. Hunt provided input regarding the natural history of outgroup taxa. We thank J. Breinholt for technical assistance with analyses and express our appreciation to B. O'Meara, B.M. Wiegmann, Editor C.S. Moreau and two excellent reviewers for their insightful suggestions that significantly improved the manuscript.Conceived and designed the experiments: AL MDT BG MDW RRD. Performed the experiments: AL MDT. Analyzed the data: AL MDT. Contributed reagents/materials/analysis tools: AL MDT BG MDW RRD. Wrote the paper: AL MDT RRD.The evolution of ants (Hymenoptera: Formicidae) is increasingly well-understood due to recent phylogenetic analyses, along with estimates of divergence times and diversification rates. Yet, leading hypotheses regarding the ancestral habitat of ants conflict with new findings that early ant lineages are cryptic and subterranean. Where the ants evolved, in respect to habitat, and how habitat shifts took place over time have not been formally tested. Here, we reconstruct the habitat transitions of crown-group ants through time, focusing on where they nest and forage (in the canopy, litter, or soil). Based on ancestral character reconstructions, we show that in contrast to the current consensus based on verbal arguments that ants evolved in tropical leaf litter, the soil is supported as the ancestral stratum of all ants. We also find subsequent movements up into the litter and, in some cases, into the canopy. Given the global importance of ants, because of their diversity, ecological influence and status as the most successful eusocial lineage on Earth, understanding the early evolution of this lineage provides insight into the factors that made this group so successful today.Yeshttp://www.plosone.org/static/editorial#pee

Macroecology and macroevolution of the latitudinal diversity gradient in ants.

The latitudinal diversity gradient-the tendency for more species to occur toward the equator-is the dominant pattern of life on Earth, yet the mechanisms responsible for it remain largely unexplained. Recently, the analysis of global data has led to advances in understanding, but these advances have been mostly limited to vertebrates and trees and have not provided consensus answers. Here we synthesize large-scale geographic, phylogenetic, and fossil data for an exemplar invertebrate group-ants-and investigate whether the latitudinal diversity gradient arose due to higher rates of net diversification in the tropics, or due to a longer time period to accumulate diversity due to Earth\u27s climatic history. We find that latitudinal affinity is highly conserved, temperate clades are young and clustered within tropical clades, and diversification rate shows no systematic variation with latitude. These results indicate that diversification time-and not rate-is the main driver of the diversity gradient in ants

Remarkable diversity in a little red dot: a comprehensive checklist of known ant species in Singapore (Hymenoptera: Formicidae) with notes on ecology and taxonomy

Despite a legacy of extensive deforestation, the 720 km2 city state of Singapore still harbours impressively diverse flora and fauna. Given increasing evidence of global insect declines, we urgently need to better document and protect local insect diversity. Numerous species of ants (Hymenoptera, Formicidae) have been recorded or described from Singapore since its founding in 1819. However, it has been over a century since Hugo Viehmeyer (1916) documented a total of 159 species found in the country. Here, we present an updated comprehensive checklist of all named species and subspecies of ants found in Singapore, with specimen collection data, and notes on taxonomy and ecology in the local context. We compiled the list based on museum collections material (the Zoological Reference Collection), primary literature sources, and verified records from known overseas repositories. We documented a total of 409 nominal species and subspecies, also a few notable morphospecies, from 10 subfamilies and 100 genera. These include new records for 121 species and 10 genera. Another 96 species and subspecies have types designated from Singapore; of these, 34 are currently considered as endemic. We also raised nine subspecies to species and synonymized two species, providing reasons justifying each status change: 1) Camponotus (Tanaemyrmex) carinifer stat. n., 2) Camponotus (Tanaemyrmex) tinctus nom rev., 3) Paraparatrechina malaccana stat. n., 4) Aphaenogaster simulans Forel, 1915 stat. n., 5) Myrmicaria adpressipilosa stat. n., 6) Vollenhovia minuta stat. n., 7) Vollenhovia brevicornis (Emery, 1893) = V. fridae Forel, 1913 syn. n., 8) Hypoponera javana stat. n., 9) Hypoponera singaporensis stat. n., 10) Mesoponera javana stat. n. Most species are considered native to Indomalaya, including 13 cosmopolitan tramps. Only 10 other species are presumed exotic to the region. At the time of writing, Singapore can be deemed the city with the highest recorded ant diversity in the world. Despite the sheer numbers, this list remains incomplete, with more species awaiting discovery or taxonomic resolution in future. The immense diversity of ants in Singapore is mainly threatened by continued decimation of remnant forest habitats and encroaching urban developments

Evolution of the latitudinal diversity gradient in the hyperdiverse ant genus Pheidole

AimThe latitudinal diversity gradient is the dominant geographic pattern of life on Earth, but a consensus understanding of its origins has remained elusive. The analysis of recently diverged, hyperâ rich invertebrate groups provides an opportunity to investigate latitudinal patterns with the statistical power of large trees while minimizing potentially confounding variation in ecology and history. Here, we synthesize global phylogenetic and macroecological data on a hyperdiverse (> 1,100 species) ant radiation, Pheidole and test predictions of three general explanations for the latitudinal gradient: variation in diversification rates, tropical conservatism and ecological regulation.LocationGlobal.Time periodThe past 35 million years.Major taxa studiedThe hyperdiverse ant genus Pheidole Westwood.MethodsWe assembled geographic data for 1,499 species and morphospecies, and inferred a dated phylogeny for 449 species of Pheidole, including 167 species newly sequenced for this study. We tested for correlations between diversification rate and latitude with Bayesian analysis of macroevolutionary mixtures (BAMM), hidden state speciation and extinction (HiSSE), geographic state speciation and extinction (GeoSSE), and a nonâ parametric method (FiSSE), evaluated evidence for richness steady state, and examined patterns of diversification as Pheidole spread around the globe.ResultsThere was no evidence of systematic variation of net diversification rates with latitude across any of the methods. We found that Pheidole diversification occurred in bursts when new continents were colonized, followed by a slowdown in each region, but there is no evidence richness has saturated at an equilibrium in any region. Additionally, we found latitudinal affinity is moderately conserved with a Neotropical ancestor and simulations show that phylogenetic inertia alone is sufficient to produce the gradient pattern.Main conclusionsOur results provide no evidence that diversification rates vary systematically with latitude. Richness is far from steady state in each region, contrary to the ecological regulation hypothesis, although there is evidence that ecological opportunity promotes diversification after colonization of new areas. The fact that niche conservatism is strong enough to produce the gradient pattern is in accord with the tropical conservatism hypothesis. Overall, these results shed light on the mechanisms underlying the emergence of the diversity gradient within the past 34 million years, complementing recent work on deeper timeâ scales, and more generally contribute toward muchâ needed invertebrate perspective on global biodiversity dynamics.Peer Reviewedhttps://deepblue.lib.umich.edu/bitstream/2027.42/148253/1/geb12867-sup-0001-AppendixS1-S2.pdfhttps://deepblue.lib.umich.edu/bitstream/2027.42/148253/2/geb12867-sup-0005-TableS3.pdfhttps://deepblue.lib.umich.edu/bitstream/2027.42/148253/3/geb12867-sup-0006-Supinfo.pdfhttps://deepblue.lib.umich.edu/bitstream/2027.42/148253/4/geb12867-sup-0002-FigS1.pdfhttps://deepblue.lib.umich.edu/bitstream/2027.42/148253/5/geb12867.pdfhttps://deepblue.lib.umich.edu/bitstream/2027.42/148253/6/geb12867_am.pd

A large‐scale assessment of ant diversity across the Brazilian Amazon Basin: integrating geographic, ecological and morphological drivers of sampling bias

Tropical ecosystems are often biodiversity hotspots, and invertebrates represent the main underrepresented component of diversity in large-scale analyses. This problem is partly related to the scarcity of data widely available to conduct these studies and the lack of systematic organization of knowledge about invertebrates\u27 distributions in biodiversity hotspots. Here, we introduce and analyze a comprehensive data compilation of Amazonian ant diversity. Using records from 1817 to 2020 from both published and unpublished sources, we describe the diversity and distribution of ant species in the Brazilian Amazon Basin. Further, using high-definition images and data from taxonomic publications, we build a comprehensive database of morphological traits for the ant species that occur in the region. In total, we recorded 1067 nominal species in the Brazilian Amazon Basin, with sampling locations strongly biased by access routes, urban centers, research institutions and major infrastructure projects. Large areas where ant sampling is non-existent represent about 52% of the basin and are concentrated mainly in the northern, southeastern and western Brazilian Amazon. We found that distance to roads is the main driver of ant sampling in the Amazon. Contrary to our expectations, morphological traits had lower predictive power in predicting sampling bias than purely geographic variables. However, when geographic predictors were controlled, habitat stratum and traits contribute to explain the remaining variance. More species were recorded in better-sampled areas, but species richness estimation models suggest that areas in southern Amazonian edge forests are associated with especially high species richness. Our results represent the first trait-based, large-scale study for insects in Amazonian forests and a starting point for macroecological studies focusing on insect diversity in the Amazon Basin

New records of ant species from Yunnan, China

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The impact of land use on non-native species incidence and number in local assemblages worldwide.

While the regional distribution of non-native species is increasingly well documented for some taxa, global analyses of non-native species in local assemblages are still missing. Here, we use a worldwide collection of assemblages from five taxa - ants, birds, mammals, spiders and vascular plants - to assess whether the incidence, frequency and proportions of naturalised non-native species depend on type and intensity of land use. In plants, assemblages of primary vegetation are least invaded. In the other taxa, primary vegetation is among the least invaded land-use types, but one or several other types have equally low levels of occurrence, frequency and proportions of non-native species. High land use intensity is associated with higher non-native incidence and frequency in primary vegetation, while intensity effects are inconsistent for other land-use types. These findings highlight the potential dual role of unused primary vegetation in preserving native biodiversity and in conferring resistance against biological invasions

Genomic Signature of Shifts in Selection in a Subalpine Ant and Its Physiological Adaptations

Understanding how organisms adapt to extreme environments is fundamental and can provide insightful case studies for both evolutionary biology and climate-change biology. Here, we take advantage of the vast diversity of lifestyles in ants to identify genomic signatures of adaptation to extreme habitats such as high altitude. We hypothesized two parallel patterns would occur in a genome adapting to an extreme habitat: 1) strong positive selection on genes related to adaptation and 2) a relaxation of previous purifying selection. We tested this hypothesis by sequencing the high-elevation specialist Tetramorium alpestre and four other phylogenetically related species. In support of our hypothesis, we recorded a strong shift of selective forces in T. alpestre, in particular a stronger magnitude of diversifying and relaxed selection when compared with all other ants. We further disentangled candidate molecular adaptations in both gene expression and protein-coding sequence that were identified by our genome-wide analyses. In particular, we demonstrate that T. alpestre has 1) a higher level of expression for stv and other heat-shock proteins in chill-shock tests and 2) enzymatic enhancement of Hex-T1, a rate-limiting regulatory enzyme that controls the entry of glucose into the glycolytic pathway. Together, our analyses highlight the adaptive molecular changes that support colonization of high-altitude environments