Teotonio et al. (2012) Derivation of the ancestral A0 population and adaptation of replicate populations varying in mating system to the lab environment for 100 generations.
Chelo et al. (2013) Testing of frequency-dependent allelic extinction probabilities using two inbred lines derived from A6140, one after introgression of an integrated GFP reporter under the myo-3 promoter.
Chelo & Teotonio (2013) Individual-level genotyping from dioecious and androdioecious populations derived from A0 to study the mode of selection underlying maintenance of genetic diversity during adaptation.
Goussen et al. (2013) The veolution of resistance to Uranium, using A0.
Chelo et al. (2013) The evolution of inbreeding and outbreeding depression under androdioecy and dioecy, using populations derived from A0.
Masri et al. (2013) The role, and differential sensitivity, of males in evolution of resistance to Bacillus thuringiensis, using A0.
Carvalho et al. (2014) Evolution of population fitness and hermaphrodite fitness components in inbred populations derived from A0 and adapted to the lab for 100 generations.
Carvalho et al. (2014) Evolution of sex allocation in hermaphrodites, using replicates of dioecious and androdioecious populations derived from A0 and adapted to the lab for 100 generations.
Theologidis et al. (2014) Testing of hermaphrodite reproductive assurance during adaptation to a novel environment. Mono-, di- and trioecious populations were derived from A6140 and adapted to lab conditions, or to gradual or sudden increases in NaCl (including CA[1-3]50, GA[1,2,4]50, GT[1,2]50, GM[1,3]50).
Masri et al. (2015) Experimental co-evolution of Bacillus thuringiensis and A0.
Poullet et al. (2016) Life-history responses to experimental evolution in hermaphrodites, using A0 and derived androdioecious populations (A[4-6]100).
Dey et al. (2016) Experimental evolution of maternal effects, using a salt-adapted population GA250.
Parrish et al. (2016) Experimental evolution using A0 testing the effects of outcrossing and genetic variation on adaptation to the parasite Serratia marcescens.
Noble et al. (2017) Description of the CeMEE v1 RIL panel (RILs sampled from A6140 and derived populations), and QTL mapping of fertility and worm area on NGM.
Guzella et al. (2018) Evolution under gradual and rapid environmental change, using monoecious populations derived from A6140 adapting to salt (including GM[1-7]50).
Chelo et al. (2019) The effects of mating system on genetic load, using populations derived from A6140 and adapted to salt (including GM[1,3]50, GA[1,2,4]50, GT[1,2]50).
Noble et al. (2019) Expansion of the CeMEE RIL panel, with new populations (CA[1-3]100), updated SNV genotypes, haplotype reconstructions, de novo mutation, and candidate loci under selection.
Papkou et al. (2019) Coevolution of Bacillus thuringiensis and CeMEE populations.
Mallard, Noble, et al. (2019) Analysis of phenotypic evolution in populations under a constant environment (CA[1-3]50 and CA[1-3]100, derived from A6140).
Archer et al. (2019) Application of the Starvation Arena to study adult starvation resistance in 72 CeMEE RILs.
Noble et al. (2020) Interaction between a col-182 mutation in N2 and standing genetic variation in CeMEE RILs modifies worm locomotion and shape.
Pelizzola et al. (2020) Development of a method (R:haploSep) for inferring haplotypes and their frequencies from time-series allele frequency data.
Archer, Heather, Stephen Banse, Ben Blue, and Patrick C Phillips. 2019. “A Naturally Segregating Polymorphism Balancing Semelparous Reproduction Versus Reproductive Diapause Revealed via Microfluidic Assessment of Starvation Stress in Caenorhabditis Elegans.”
Carvalho, S, I M Chelo, C Goy, and H Teotónio. 2014. “The Role of Hermaphrodites in the Experimental Evolution of Increased Outcrossing Rates in Caenorhabditis Elegans.” BMC Evol. Biol. 14: 116.
Carvalho, S, P C Phillips, and H Teotónio. 2014. “Hermaphrodite Life History and the Maintenance of Partial Selfing in Experimental Populations of Caenorhabditis Elegans.” BMC Evol. Biol. 14: 117.
Chelo, I M, B Afonso, S Carvalho, I Theologidis, C Goy, A Pino-Querido, S Proulx, and H Teotónio. 2019. “Partial Selfing Can Reduce Genetic Loads While Maintaining Diversity During Evolution.” G3 9: 2811–21.
Chelo, I M, S Carvalho, D Manoel, S Proulx, and H Teotónio. 2013. “The Genetic Basis and Experimental Evolution of Inbreeding Depression in Caenorhabiditis Elegans.” Heredity 112: 248–54.
Chelo, Ivo M, Judit Nédli, Isabel Gordo, and Henrique Teotónio. 2013. “An Experimental Test on the Probability of Extinction of New Genetic Variants.” Nat. Commun. 4: 10.1038/ncomms3417.
Chelo, Ivo M, and Henrique Teotónio. 2013. “The Opportunity for Balancing Selection in Experimental Populations of Caenorhabditis Elegans.” Evolution 67 (1): 142–56.
Dey, Snigdhadip, Stephen R Proulx, and Henrique Teotónio. 2016. “Adaptation to Temporally Fluctuating Environments by the Evolution of Maternal Effects.” PLoS Biol. 14 (2): e1002388.
Goussen, Benoit, Florian Parisot, Rémy Beaudouin, Morgan Dutilleul, Adeline Buisset-Goussen, Alexandre R R Péry, and Jean-Marc Bonzom. 2013. “Consequences of a Multi-Generation Exposure to Uranium on Caenorhabditis Elegans Life Parameters and Sensitivity.” Ecotoxicology 22 (5): 869–78.
Guzella, T, S Dey, I M Chelo, A Pino-Querido, V Pereira, S Proulx, and H Teotónio. 2018. “Slower Environmental Change Hinders Adaptation from Standing Genetic Variation.” PLoS Genet. 14: e1007731.
Mallard, François, Luke Noble, Thiago Guzella, Bruno Afonso, Charles F Baer, and Henrique Teotónio. 2019. “Selection and Drift Determine Phenotypic Stasis Despite Genetic Divergence.” bioRxiv, September, 778282.
Masri, Leila, Antoine Branca, Anna E Sheppard, Andrei Papkou, David Laehnemann, Patrick S Guenther, Swantje Prahl, et al. 2015. “Host-Pathogen Coevolution: The Selective Advantage of Bacillus Thuringiensis Virulence and Its Cry Toxin Genes.” PLoS Biol. 13 (6): e1002169.
Masri, Leila, Rebecca D Schulte, Nadine Timmermeyer, Stefanie Thanisch, Lena Luise Crummenerl, Gunther Jansen, Nico K Michiels, and Hinrich Schulenburg. 2013. “Sex Differences in Host Defence Interfere with Parasite-Mediated Selection for Outcrossing During Host-Parasite Coevolution.” Ecol. Lett. 16 (4): 461–68.
Noble, Luke M, Ivo Chelo, Thiago Guzella, Bruno Afonso, David D Riccardi, Patrick Ammerman, Adel Dayarian, et al. 2017. “Polygenicity and Epistasis Underlie Fitness-Proximal Traits in the Caenorhabditis Elegans Multiparental Experimental Evolution (CeMEE) Panel.” Genetics 207 (4): genetics–300406.
Noble, Luke M, Asif Miah, Taniya Kaur, and Matthew V Rockman. 2020. “The Ancestral Caenorhabditis Elegans Cuticle Suppresses Rol-1.” G3 10 (7): 2385–95.
Noble, Luke M, Matthew V Rockman, and Henrique Teotónio. 2019. “Gene-Level Quantitative Trait Mapping in an Expanded C. Elegans Multiparent Experimental Evolution Panel.” bioRxiv, March, 589432.
Papkou, Andrei, Thiago Guzella, Wentao Yang, Svenja Koepper, Barbara Pees, Rebecca Schalkowski, Mike-Christoph Barg, Philip C Rosenstiel, Henrique Teotónio, and Hinrich Schulenburg. 2019. “The Genomic Basis of Red Queen Dynamics During Rapid Reciprocal Host-Pathogen Coevolution.” Proc. Natl. Acad. Sci. U. S. A. 116 (3): 923–28.
Parrish, Raymond C, 2nd, Mckenna J Penley, and Levi T Morran. 2016. “The Integral Role of Genetic Variation in the Evolution of Outcrossing in the Caenorhabditis Elegans-Serratia Marcescens Host-Parasite System.” PLoS One 11 (4): e0154463.
Pelizzola, Marta, Merle Behr, Housen Li, Axel Munk, and Andreas Futschik. 2020. “Multiple Haplotype Reconstruction from Allele Frequency Data.”
Poullet, Nausicaa, Anne Vielle, Clotilde Gimond, Sara Carvalho, Henrique Teotónio, and Christian Braendle. 2016. “Complex Heterochrony Underlies the Evolution of Caenorhabditis Elegans Hermaphrodite Sex Allocation.” Evolution 70 (10): 2357–69.
Teotonio, Henrique, Sara Carvalho, Diogo Manoel, Miguel Roque, and Ivo M Chelo. 2012. “Evolution of Outcrossing in Experimental Populations of Caenorhabditis Elegans.” PLoS One 7 (4): e35811.
Theologidis, Ioannis, Ivo M Chelo, Christine Goy, and Henrique Teotónio. 2014. “Reproductive Assurance Drives Transitions to Self-Fertilization in Experimental Caenorhabditis Elegans.” BMC Biol. 12 (1): 1–21.