Your search keyword '"Dave Lutgen"' showing total 5 results

1. An annotated chromosome-scale reference genome for Eastern black-eared wheatear (Oenanthe melanoleuca)

Author

Valentina Peona, Octavio Manuel Palacios-Gimenez, Dave Lutgen, Remi André Olsen, Niloofar Alaei Kakhki, Pavlos Andriopoulos, Vasileios Bontzorlos, Manuel Schweizer, Alexander Suh, and Reto Burri

Subjects

Genetics, QH426-470

Abstract

AbstractPervasive convergent evolution and in part high incidences of hybridization distinguish wheatears (songbirds of the genus OenantheOenanthe melanoleucaOenanthe hispanica

Published

2023

2. Comparative transcriptomics reveals divergent paths of chitinase evolution underlying dietary convergence in ant-eating mammals

Author

Rémi Allio, Sophie Teullet, Dave Lutgen, Amandine Magdeleine, Rachid Koual, Marie-Ka Tilak, Benoit de Thoisy, Christopher A. Emerling, Tristan Lefébure, and Frédéric Delsuc

Abstract

Ant-eating mammals represent a textbook example of convergent evolution. Among them, anteaters and pangolins exhibit the most extreme convergent phenotypes with complete tooth loss, elongated skulls, protruding tongues, hypertrophied salivary glands producing large amounts of saliva, and powerful claws for ripping open ant and termite nests. However, comparative genomic analyses have shown that anteaters and pangolins differ in their chitinase gene (CHIA) repertoires, which potentially degrade the chitinous exoskeletons of ingested ants and termites. While the southern tamandua (Tamandua tetradactyla) harbors four functionalCHIAparalogs (CHIA1-4), Asian pangolins (Manisspp.) have only one functional paralog (CHIA5). Here, we performed a comparative transcriptomic analysis of salivary glands in 33 placental species, including 16 novel transcriptomes from ant-eating species and close relatives. Our results suggest that salivary glands play an important role in adaptation to an insect-based diet, as expression of differentCHIAparalogs is observed in insectivorous species. Furthermore, convergently-evolved pangolins and anteaters express different chitinases in their digestive tracts. In the Malayan pangolin,CHIA5is overexpressed in all major digestive organs, whereas in the southern tamandua, all four functional paralogs are expressed, at very high levels forCHIA1andCHIA2in the pancreas, and forCHIA3andCHIA4in the salivary glands, stomach, liver, and pancreas. Overall, our results demonstrate that divergent molecular mechanisms underlie convergent adaptation to the ant-eating diet in pangolins and anteaters. This study highlights the role of historical contingency and molecular tinkering of the chitin-digestive enzyme toolkit in this classic example of convergent evolution.

Published

2022

3. A Phylogenomic Assessment of Processes Underpinning Convergent Evolution in Open-Habitat Chats

Author

Niloofar Alaei Kakhki, Manuel Schweizer, Dave Lutgen, Rauri C K Bowie, Hadoram Shirihai, Alexander Suh, Holger Schielzeth, and Reto Burri

Subjects

Genetics, 570 Life sciences, biology, Molecular Biology, Ecology, Evolution, Behavior and Systematics

Abstract

Insights into the processes underpinning convergent evolution advance our understanding of the contributions of ancestral, introgressed, and novel genetic variation to phenotypic evolution. Phylogenomic analyses characterizing genome-wide gene tree heterogeneity can provide first clues about the extent of ILS and of introgression and thereby into the potential of these processes or (in their absence) the need to invoke novel mutations to underpin convergent evolution. Here, we were interested in understanding the processes involved in convergent evolution in open-habitat chats (wheatears of the genusOenantheand their relatives). To this end, based on whole-genome resequencing data from 50 taxa of 44 species, we established the species tree, characterized gene tree heterogeneity, and investigated the footprints of ILS and introgression within the latter. The species tree corroborates the pattern of abundant convergent evolution, especially in wheatears. The high levels of gene tree heterogeneity in wheatears are explained by ILS alone only for 30% of internal branches. For multiple branches with high gene tree heterogeneity, D-statistics and phylogenetic networks identified footprints of introgression. Finally, long branches without extensive ILS between clades sporting similar phenotypes provide suggestive evidence for a role of novel mutations in the evolution of these phenotypes. Together, our results suggest that convergent evolution in open-habitat chats involved diverse processes and highlight that phenotypic diversification is often complex and best depicted as a network of interacting lineages.

Published

2022

4. DNA extraction protocol for historical toe pad samples from birds v1

Author

Dave Lutgen

Abstract

Museums hold collections of specimens from vast taxonomic and geographic ranges that constitute rich resources for research into the origins, evolution, and maintenance of biodiversity on earth. However, specimens are often not prepared for specific research purposes. Especially the isolation of adequate quantities of DNA for genomic research can be challenging. Here, we report a modified protocol of a commercially available kit optimized to reliably extract adequate quantities of DNA from bird toepads and dried skin from sutures of museum specimens for whole-genome resequencing.

Published

2020

5. Linked‐read sequencing enables haplotype‐resolved resequencing at population scale

Author

Hadoram Shirihai, Dave Lutgen, Manuel Schweizer, Raphael Ritter, Remi-Andre Olsen, Holger Schielzeth, Reto Burri, Alexander Suh, Philip Ewels, Jesús T. García, Joel Gruselius, and German Research Foundation

Subjects

0106 biological sciences, 0301 basic medicine, Sequencing data, Population, Introgression, Sequence assembly, Biology, 010603 evolutionary biology, 01 natural sciences, Genome, Songbirds, Population genomics, 03 medical and health sciences, Genetics, Animals, Genus Oenanthe, education, Ecology, Evolution, Behavior and Systematics, education.field_of_study, Haplotype, High-Throughput Nucleotide Sequencing, Genomics, Sequence Analysis, DNA, Genetics, Population, 030104 developmental biology, Haplotypes, Evolutionary biology, Scale (map), Biotechnology

Abstract

The feasibility to sequence entire genomes of virtually any organism provides unprecedented insights into the evolutionary history of populations and species. Nevertheless, many population genomic inferences – including the quantification and dating of admixture, introgression and demographic events, and inference of selective sweeps – are still limited by the lack of high‐quality haplotype information. The newest generation of sequencing technology now promises significant progress. To establish the feasibility of haplotype‐resolved genome resequencing at population scale, we investigated properties of linked‐read sequencing data of songbirds of the genus Oenanthe across a range of sequencing depths. Our results based on the comparison of downsampled (25×, 20×, 15×, 10×, 7×, and 5×) with high‐coverage data (46–68×) of seven bird genomes mapped to a reference suggest that phasing contiguities and accuracies adequate for most population genomic analyses can be reached already with moderate sequencing effort. At 15× coverage, phased haplotypes span about 90% of the genome assembly, with 50% and 90% of phased sequences located in phase blocks longer than 1.25–4.6 Mb (N50) and 0.27–0.72 Mb (N90). Phasing accuracy reaches beyond 99% starting from 15× coverage. Higher coverages yielded higher contiguities (up to about 7 Mb/1 Mb [N50/N90] at 25× coverage), but only marginally improved phasing accuracy. Phase block contiguity improved with input DNA molecule length; thus, higher‐quality DNA may help keeping sequencing costs at bay. In conclusion, even for organisms with gigabase‐sized genomes like birds, linked‐read sequencing at moderate depth opens an affordable avenue towards haplotype‐resolved genome resequencing at population scale., This research was supported by a Science for Life Laboratory Swedish Biodiversity Programme grant (2015‐R14) to AS and by a German Research Foundation (DFG) research grant (BU3456/3‐1) to RB.

Published

2020