Publications by authors named "Marylaure de La Harpe"
Article Synopsis
- The subgenus Tillandsia is part of a rapidly evolving group of plants known for their unique water-saving adaptation called Crassulacean acid metabolism (CAM), which has independently evolved in various plant families.
- Researchers analyzed the genomes of two Tillandsia species with different photosynthetic traits to understand how CAM evolved, discovering that significant genomic rearrangements and a dynamic landscape of transposable elements influenced their genomes.
- The study found that changes in how photosynthesis is regulated played a key role in CAM evolution, with certain significant gene families expanding in the species that use CAM, although the actual DNA sequences of these genes weren't under strong selection pressure.
Species are seen as the fundamental unit of biotic diversity, and thus their delimitation is crucial for defining measures for diversity assessments and studying evolution. Differences between species have traditionally been associated with variation in morphology. And yet, the discovery of cryptic diversity suggests that the evolution of distinct lineages does not necessarily involve morphological differences.
View Article and Find Full Text PDFTo defend themselves against pathogenic microorganisms, honey bees resort to social immunity mechanisms, such as the secretion of antibiotic compounds in the jelly they feed to their larvae. Whereas the bactericidal activity of jelly fed to queen larvae is well studied, little is known about the bioactivity of compositionally different jelly fed to worker larvae. However, the numerous worker larvae are likely to drive the spread of the microorganism and influence its virulence and pathogenesis.
View Article and Find Full Text PDFTarget capture has emerged as an important tool for phylogenetics and population genetics in nonmodel taxa. Whereas developing taxon-specific capture probes requires sustained efforts, available universal kits may have a lower power to reconstruct relationships at shallow phylogenetic scales and within rapidly radiating clades. We present here a newly developed target capture set for Bromeliaceae, a large and ecologically diverse plant family with highly variable diversification rates.
View Article and Find Full Text PDFArticle Synopsis
- - The Bromeliaceae family, particularly the genus Tillandsia, has undergone significant diversification due to key innovations like the shift from C to CAM photosynthesis, which helps adaptations to dry environments.
- - Researchers used phylogenomic techniques and RNA sequencing to explore how these photosynthetic changes are linked to other adaptations for surviving in xeric conditions, including genetic and metabolic shifts.
- - Findings indicate that the evolution of CAM involved the expansion of certain genes related to growth regulation and the reprogramming of stress response genes, providing insight into how these adaptive traits are repeatedly developed in this diverse plant group.
The tribe Geonomateae is a widely distributed group of 103 species of Neotropical palms which contains six ecologically important understory or subcanopy genera. Although it has been the focus of many studies, our understanding of the evolutionary history of this group, and in particular of the taxonomically complex genus , is far from complete due to a lack of molecular data. Specifically, the previous Sanger sequencing-based studies used a few informative characters and partial sampling.
View Article and Find Full Text PDFArticle Synopsis
- This research focuses on understanding genetic diversification in palms, an important plant family, using advanced whole genome sequencing to create molecular markers for better studies at various evolutionary levels.
- The study developed a comprehensive set of genomic markers covering 4,184 regions, including genes and neutral areas, designed to avoid issues like copy number variation, enabling analysis of evolutionary rates.
- The newly created markers were tested across different palm sub-families, achieving high specificity and efficiency, which will enhance the analysis of genomic diversity and facilitate future research combining new and existing datasets.
Article Synopsis
- Understanding the drivers and limits of species radiations is key in evolutionary genetics, but connecting micro- and macroevolutionary methods has been challenging, leading to research gaps.
- Current studies show a focus on certain taxa, with many species-rich groups like arthropods, plants, and fungi being understudied, mainly due to limitations in sample size and nuclear genome data.
- The authors advocate for using whole-genome sequencing (WGS) and targeted resequencing to improve population and species sampling, making it possible to explore the genetic basis of species radiations more effectively.
Premise Of The Study: After decades of interest, the contribution of hybridization to ecological diversification remains unclear. Hybridization is a potent source of novelty, but nascent hybrid lineages must overcome reproductive and ecological competition from their parental species. Here, we assess whether hybrid speciation is advantageous over alternative modes of speciation, by comparing the geographical and ecological ranges and climatic niche evolutionary rates of stabilized allopolyploid vs.
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