Your search keyword '"Herberstein, Marie E."' showing total 6 results

1. Asymmetric arms races between predators and prey: a tug of war between the life–dinner principle and the rare-enemy principle.

Author

McLean, Donald James, Herberstein, Marie E., and Kokko, Hanna

Subjects

*ARMS race, *COEVOLUTION, *PREDATORY animals, *METAPHOR, *SPECIES, *PREDATION

Abstract

Antagonistic co-evolution can be asymmetric, where one species lags behind another. Asymmetry in a predator–prey context is expressed by the 'life–dinner principle', a classic informal model predicting that prey should be in some sense ahead in this arms race, since prey are running for their lives, while predators lag as they only run for their dinner. The model has undergone surprisingly little theoretical scrutiny. We derive analytical models that show coevolutionary outcomes do not always align with the life–dinner principle. Our results show that other important asymmetries can easily reverse the outcome, especially the rare-enemy principle: predators are usually outnumbered by their prey, sometimes substantially (trophic asymmetry), which can make selection on prey relatively weak. We additionally show that the antagonists typically exhibit different evolutionary responses to a situation where both predator and prey start out as equally fast runners. Although predators sometimes become so efficient that attacks always succeed, attack success often reaches a stable intermediate value. We conclude that the life–dinner principle has some validity as a metaphor, but its effect is of an 'all else being equal' type, which is surprisingly easily overridden by other features of the evolutionary dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

2. Current evidence of climate‐driven colour change in insects and its impact on sexual signals.

Author

Haque, Md Tangigul, Khan, Md Kawsar, and Herberstein, Marie E.

Subjects

INSECT physiology, SEXUAL selection, PHENOTYPIC plasticity, CLIMATE change, COLOR

Abstract

The colours of insects function in intraspecific communication such as sexual signalling, interspecific communication such as protection from predators, and in physiological processes, such as thermoregulation. The expression of melanin‐based colours is temperature‐dependent and thus likely to be impacted by a changing climate. However, it is unclear how climate change drives changes in body and wing colour may impact insect physiology and their interactions with conspecifics (e.g. mates) or heterospecific (e.g. predators or prey). The aim of this review is to synthesise the current knowledge of the consequences of climate‐driven colour change on insects. Here, we discuss the environmental factors that affect insect colours, and then we outline the adaptive mechanisms in terms of phenotypic plasticity and microevolutionary response. Throughout we discuss the impact of climate‐related colour change on insect physiology, and interactions with con‐and‐heterospecifics. [ABSTRACT FROM AUTHOR]

Published

2024

3. Morphological ant mimics: constrained to imperfection?

Author

McLean, Donald James, primary, Cassis, Gerasimos, additional, and Herberstein, Marie E., additional

Published

2024

4. Cooler and drier conditions increase parasitism in a subtropical damselfly population

Author

Paul, Shatabdi, primary, Rayhan, Mostakim, additional, Herberstein, Marie E., additional, and Khan, Md Kawsar, additional

Published

2024

5. Predator selection on multicomponent warning signals in an aposematic moth.

Author

Hämäläinen, Liisa, Binns, Georgina E, Hart, Nathan S, Mappes, Johanna, McDonald, Paul G, O'Neill, Louis G, Rowland, Hannah M, Umbers, Kate D L, and Herberstein, Marie E

Subjects

PREDATORY animals, WARNINGS, MOTHS, STRIPES

Abstract

Aposematic prey advertise their unprofitability with conspicuous warning signals that are often composed of multiple color patterns. Many species show intraspecific variation in these patterns even though selection is expected to favor invariable warning signals that enhance predator learning. However, if predators acquire avoidance to specific signal components, this might relax selection on other aposematic traits and explain variability. Here, we investigated this idea in the aposematic moth Amata nigriceps that has conspicuous black and orange coloration. The size of the orange spots in the wings is highly variable between individuals, whereas the number and width of orange abdominal stripes remains consistent. We produced artificial moths that varied in the proportion of orange in the wings or the presence of abdominal stripes. We presented these to a natural avian predator, the noisy miner (Manorina melanocephala) , and recorded how different warning signal components influenced their attack decisions. When moth models had orange stripes on the abdomen, birds did not discriminate between different wing signals. However, when the stripes on the abdomen were removed, birds chose the model with smaller wing spots. In addition, we found that birds were more likely to attack moths with a smaller number of abdominal stripes. Together, our results suggest that bird predators primarily pay attention to the abdominal stripes of A. nigriceps, and this could relax selection on wing coloration. Our study highlights the importance of considering individual warning signal components if we are to understand how predation shapes selection on prey warning coloration. [ABSTRACT FROM AUTHOR]

Published

2024

6. Small Brains: Body Shape Constrains Tissue Allocation to the Central Nervous System in Ant-Mimicking Spiders.

Author

Kelly MBJ, Penna-Gonçalves V, Willmott NJ, McLean DJ, Black JR, Wolff JO, and Herberstein ME

Subjects

Animals, Biological Mimicry physiology, X-Ray Microtomography, Central Nervous System anatomy & histology, Central Nervous System physiology, Central Nervous System diagnostic imaging, Spiders anatomy & histology, Spiders physiology, Brain anatomy & histology, Brain diagnostic imaging, Brain physiology, Ants anatomy & histology, Ants physiology

Abstract

In Batesian mimicry, mimetic traits are not always as convincing as predicted by theory-in fact, inaccurate mimicry with only a superficial model resemblance is common and taxonomically widespread. The "selection trade-offs hypothesis" proposes a life-history trade-off between accurate mimetic traits and one or more vital biological functions. Here, using an accurate myrmecomorphic (ant-mimicking) jumping spider species, Myrmarachne smaragdina, we investigate how myrmecomorphic modifications to the body shape impact the internal anatomy in a way that could be functionally limiting. Specifically, via x-ray micro-computed tomography (microCT), we quantify how the spider's constricted prosoma, which emulates the head and thorax of ants, impacts the size of the central nervous system (CNS) and the venom glands. Although, relative to their whole-body mass, we found no significant difference in venom gland volume, the CNS of the ant-mimicking jumping spider was significantly smaller when compared with a relatively closely related non-mimic jumping spider, indicating that some trade-off between mimic accuracy and size of neural anatomy, as articulated by the "selection trade-offs hypothesis," is a possibility. Our explorative evidence enables and encourages broader investigation of how variable mimic accuracy impacts the neuroanatomy in ant mimics as a direct test of the "selection trade-offs hypothesis.", (© 2024 The Author(s). The Journal of Comparative Neurology published by Wiley Periodicals LLC.)

Published

2024