SubsidieMeestersExpanding our understanding of human evolution through pleiotropy
This project leverages dental pleiotropy through genetic analysis, historical datasets, and fossil records to enhance understanding of human evolution beyond dentition.
Projectdetails
Introduction
Teeth dominate the fossil and bioarchaeological records because they consist mostly of inorganic material. Consequently, dental anthropology has long been essential in our investigation of the human past. Variation in the anatomy of teeth is instrumental for differentiating species, identifying biological affinities between populations, making inferences about dietary adaptations, and timing key developmental life stages.
Advances in Genetics
However, recent advances in genetics, genomics, and developmental biology undermine many assumptions built into anthropologists' study of the dentition by revealing extensive pleiotropy when one gene influences more than one anatomical structure simultaneously. This is not a setback but rather an advantage. In this project, we will use the pleiotropies that involve teeth to open windows to the evolution of human anatomies far beyond the dentition.
Methodological Approaches
I will employ three methodological approaches that utilize pleiotropy to probe different aspects of human paleobiology:
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Quantitative Genetic Analyses: The first approach will use quantitative genetic analyses to calibrate the extent to which cranial evolution is genetically correlated with dental evolution.
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Morphological Datasets and GWAS: In the second approach, we will employ large historical morphological datasets combined with the modern insight from genome-wide association studies (GWAS) to explore how the evolution of soft-tissue anatomy may have driven changes in the dentition.
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Fossil Record Analysis: Finally, we will turn to the fossil record. Using traits that were defined using a pleiotropic approach, we will test the hypothesis that environmental selection influenced dental variation during two key time periods within the evolution of genus Homo.
Conclusion
This project modernizes the study of the human past by incorporating the phenomenon of dental pleiotropy. By combining these three different approaches and a range of time scales, we turn the conundrum of pleiotropy into a powerful tool for studying human evolution.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.252.167 |
| Totale projectbegroting | € 2.252.167 |
Tijdlijn
| Startdatum | 1-11-2022 |
| Einddatum | 31-10-2027 |
| Subsidiejaar | 2022 |
Partners & Locaties
Projectpartners
- CENTRO NACIONAL DE INVESTIGACION SOBRE LA EVOLUCION HUMANApenvoerder
Land(en)
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Evaluating how pleiotropy influences genetic and developmental evolution by using rodent teeth
This project investigates how pleiotropy influences the rapid evolution of developmental gene expression and regulatory regions in rodent molars, focusing on compensatory mutations across species.
Exploring the origin and diversification of mammalian tooth classes
This project aims to understand the origin and diversification of mammalian tooth classes using bat teeth as a model, integrating morphological, genomic, and developmental approaches.
Studying the cis-regulatory changes that have shaped human evolution
This project aims to uncover the genetic basis of human adaptation by using hybrid cells and MPRAs to map cis-regulatory changes and their impact on gene expression and phenotypes.
Inferring hominin population history through space and time using introgressed haplotypes
This project aims to develop advanced bioinformatic methods to analyze ancient DNA, revealing the history of human interbreeding and genetic factors influencing modern human survival.
Reconstructing Paleolithic Population Dynamics Using Microstratified Paleogenomic Analysis
This project aims to enhance archaeogenetic research by using microstratigraphic frameworks to analyze ancient DNA from sediments and speleothems, reconstructing human interactions in Upper Paleolithic Georgia.