SubsidieMeestersSexual adaptation across evolution: the neural basis of female sexual motivation
This project aims to unravel the molecular mechanisms behind female sexual behavior variation in nematodes by comparing C. elegans and C. afra, revealing neural circuits and evolutionary adaptations.
Projectdetails
Introduction
What are the molecular mechanisms that determine intra- and inter-species behavioral variation? We propose to address this key outstanding question in evolutionary neuroscience by exploring a striking example of adaptive evolution of female sexual behavior.
Comparative Analysis
Comparing two closely related nematode species that use different mating strategies, we discovered that while androdioecious (hermaphrodite-male) C. elegans hermaphrodites are indifferent to males, dioecious (female-male) C. afra females exhibit a pronounced sex drive, actively engaging in and initiating mating.
Behavioral Insights
Importantly, we found that under induced reproductive pressure, the passive hermaphrodites switch to female-like behavior, suggesting the existence of a suppressed neuronal circuit.
Research Objectives
In this proposal, we will employ an evolutionary comparative approach to deconstruct the neural basis of female sexual motivation, by addressing three objectives:
- Explore and quantify the extent and molecular basis of female sexual motivation in C. afra.
- Characterize the neuronal underpinnings of sexual attraction, by mapping gene expression, connectivity, and network dynamics in females.
- Investigate how mating pressure promotes sexual adaptation in C. elegans hermaphrodites, by monitoring the evolving changes in genetics, epigenetics, and the neuromodulatory network in transition states from passive to active sexual behaviors.
Significance of the Study
Our suggested program challenges long-held assumptions about the role of female sexual motivation, which despite its complexity remains understudied compared to male mating behaviors.
Unique Approach
Our unique approach, utilizing the power of C. elegans alongside tool building for investigating C. afra, will not only unveil the molecular mechanisms governing the emergence of novel female sexual behaviors but also create a blueprint for understanding their evolution.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.000.000 |
| Totale projectbegroting | € 2.000.000 |
Tijdlijn
| Startdatum | 1-1-2025 |
| Einddatum | 31-12-2029 |
| Subsidiejaar | 2025 |
Partners & Locaties
Projectpartners
- WEIZMANN INSTITUTE OF SCIENCEpenvoerder
Land(en)
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Mechanisms and Functions of Brain- Body- Environment Interactions in C. elegans
This project aims to investigate how widespread neuronal activity patterns in C. elegans encode movement parameters, enhancing our understanding of sensory-motor transformations in the brain.
Brainstem circuits supporting adaptive instinctive behaviours
This project aims to understand the flexible mechanisms of instinctive behaviors in vertebrates by analyzing the periaqueductal gray's neural circuits and their modulation during various internal states.
Understanding diversity in decision strategy: from neural circuits to behavior
This project aims to uncover the neural mechanisms behind the brain's flexibility in decision-making strategies during foraging, using advanced computational and electrophysiological methods in mice.
The evolution of new organs during insects’ conquest of the sky
This project aims to investigate the evolutionary origins and impacts of wings and turbanate eyes in insects, using mayflies as a model to enhance understanding of morphological novelties.
Environmental control of physiology through the brain-gut axis
This project aims to investigate how environmental factors influence the brain-gut axis in Drosophila, revealing mechanisms of metabolic adaptation and potential implications for understanding related pathophysiology.