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4. Genome-wide selection signatures reveal widespread synergistic effects of two different stressors in Drosophila melanogaster.

Author

Burny, Claire, Nolte, Viola, Dolezal, Marlies, and Schlötterer, Christian

Subjects
*DROSOPHILA melanogaster, *BODY temperature regulation, *TEMPERATURE effect, *GENETIC variation, *EXTREME environments, *DROSOPHILIDAE, *DROSOPHILA
Abstract

Experimental evolution combined with whole-genome sequencing (evolve and resequence (E&R)) is a powerful approach to study the adaptive architecture of selected traits. Nevertheless, so far the focus has been on the selective response triggered by a single stressor. Building on the highly parallel selection response of founder populations with reduced variation, we evaluated how the presence of a second stressor affects the genomic selection response. After 20 generations of adaptation to laboratory conditions at either 18°C or 29°C, strong genome-wide selection signatures were observed. Only 38% of the selection signatures can be attributed to laboratory adaptation (no difference between temperature regimes). The remaining selection responses are either caused by temperature-specific effects, or reflect the joint effects of temperature and laboratory adaptation (same direction, but the magnitude differs between temperatures). The allele frequency changes resulting from the combined effects of temperature and laboratory adaptation were more extreme in the hot environment for 83% of the affected genomic regions—indicating widespread synergistic effects of the two stressors. We conclude that E&R with reduced genetic variation is a powerful approach to study genome-wide fitness consequences driven by the combined effects of multiple environmental factors. [ABSTRACT FROM AUTHOR]

Published
2022
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5. Highly Parallel Genomic Selection Response in Replicated Drosophila melanogaster Populations with Reduced Genetic Variation.

Author

Burny, Claire, Nolte, Viola, Dolezal, Marlies, and Schlötterer, Christian

Subjects
*GENETIC variation, *DROSOPHILA melanogaster, *X chromosome, *LOCUS (Genetics), *CHROMOSOMES, *PHENOTYPES
Abstract

Many adaptive traits are polygenic and frequently more loci contributing to the phenotype are segregating than needed to express the phenotypic optimum. Experimental evolution with replicated populations adapting to a new controlled environment provides a powerful approach to study polygenic adaptation. Because genetic redundancy often results in nonparallel selection responses among replicates, we propose a modified evolve and resequence (E&R) design that maximizes the similarity among replicates. Rather than starting from many founders, we only use two inbred Drosophila melanogaster strains and expose them to a very extreme, hot temperature environment (29 °C). After 20 generations, we detect many genomic regions with a strong, highly parallel selection response in 10 evolved replicates. The X chromosome has a more pronounced selection response than the autosomes, which may be attributed to dominance effects. Furthermore, we find that the median selection coefficient for all chromosomes is higher in our two-genotype experiment than in classic E&R studies. Because two random genomes harbor sufficient variation for adaptive responses, we propose that this approach is particularly well-suited for the analysis of polygenic adaptation. [ABSTRACT FROM AUTHOR]

Published
2021
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6. Secondary Evolve and Resequencing: An Experimental Confirmation of Putative Selection Targets without Phenotyping.

Author

Burny, Claire, Nolte, Viola, Nouhaud, Pierre, Dolezal, Marlies, and Schlötterer, Christian

Subjects
*FUNCTIONAL analysis, *STATISTICAL significance, *DROSOPHILA, *GENE frequency
Abstract

Evolve and resequencing (E&R) studies investigate the genomic responses of adaptation during experimental evolution. Because replicate populations evolve in the same controlled environment, consistent responses to selection across replicates are frequently used to identify reliable candidate regions that underlie adaptation to a new environment. However, recent work demonstrated that selection signatures can be restricted to one or a few replicate(s) only. These selection signatures frequently have weak statistical support, and given the difficulties of functional validation, additional evidence is needed before considering them as candidates for functional analysis. Here, we introduce an experimental procedure to validate candidate loci with weak or replicate-specific selection signature(s). Crossing an evolved population from a primary E&R experiment to the ancestral founder population reduces the frequency of candidate alleles that have reached a high frequency. We hypothesize that genuine selection targets will experience a repeatable frequency increase after the mixing with the ancestral founders if they are exposed to the same environment (secondary E&R experiment). Using this approach, we successfully validate two overlapping selection targets, which showed a mutually exclusive selection signature in a primary E&R experiment of Drosophila simulans adapting to a novel temperature regime. We conclude that secondary E&R experiments provide a reliable confirmation of selection signatures that either are not replicated or show only a low statistical significance in a primary E&R experiment unless epistatic interactions predominate. Such experiments are particularly helpful to prioritize candidate loci for time-consuming functional follow-up investigations. [ABSTRACT FROM AUTHOR]

Published
2020
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8. Exploiting Single-Cell Quantitative Data to Map Genetic Variants Having Probabilistic Effects.

Author

Chuffart, Florent, Richard, Magali, Jost, Daniel, Burny, Claire, Duplus-Bottin, Hélène, Ohya, Yoshikazu, and Yvert, Gaël

Subjects
HUMAN genetic variation, GENETIC polymorphisms, GENE mapping, PROBABILITY theory, PHENOTYPES, SIMULATION methods & models
Abstract

Despite the recent progress in sequencing technologies, genome-wide association studies (GWAS) remain limited by a statistical-power issue: many polymorphisms contribute little to common trait variation and therefore escape detection. The small contribution sometimes corresponds to incomplete penetrance, which may result from probabilistic effects on molecular regulations. In such cases, genetic mapping may benefit from the wealth of data produced by single-cell technologies. We present here the development of a novel genetic mapping method that allows to scan genomes for single-cell Probabilistic Trait Loci that modify the statistical properties of cellular-level quantitative traits. Phenotypic values are acquired on thousands of individual cells, and genetic association is obtained from a multivariate analysis of a matrix of Kantorovich distances. No prior assumption is required on the mode of action of the genetic loci involved and, by exploiting all single-cell values, the method can reveal non-deterministic effects. Using both simulations and yeast experimental datasets, we show that it can detect linkages that are missed by classical genetic mapping. A probabilistic effect of a single SNP on cell shape was detected and validated. The method also detected a novel locus associated with elevated gene expression noise of the yeast galactose regulon. Our results illustrate how single-cell technologies can be exploited to improve the genetic dissection of certain common traits. The method is available as an open source R package called ptlmapper. [ABSTRACT FROM AUTHOR]

Published
2016
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9. Early diagnosis of gestational trophoblastic neoplasia based on trajectory classification with compartment modeling.

Author

Burny, Claire, Rabilloud, Muriel, Golfier, François, Massardier, Jérôme, Hajri, Touria, Schott, Anne-Marie, and Subtil, Fabien

Subjects
*ALGORITHMS, *BIOLOGICAL models, *CHORIONIC gonadotropins, *DYNAMICS, *HEALTH outcome assessment, *MOLAR pregnancy, *PREGNANCY complications, *TIME, *TROPHOBLASTIC tumors, *EARLY diagnosis, *UTERINE tumors, *DIAGNOSIS, RESEARCH evaluation
Abstract

Background: In randomized clinical trials or observational studies, it is common to collect biomarker values longitudinally on a cohort of individuals. The investigators may be interested in grouping individuals that share similar changes of biomarker values and use these groups for diagnosis or therapeutic purposes. However, most classical model-based classification methods rely mainly on empirical models such as splines or polynomials and do not reflect the physiological processes.Methods: A model-based classification method was developed for longitudinal biomarker measurements through a pharmacokinetic model that describes biomarker changes over time. The method is illustrated using data on human Chorionic Gonadotrophic Hormone measurements after curettage of hydatidiform moles.Results: The resulting classification was linked to the evolution toward gestational trophoblastic neoplasia and may be used as a tool for early diagnosis. The diagnostic accuracy of the pharmacokinetic model was more reproducible than the one of a purely mathematical model that did not take into account the biological processes.Conclusion: The use of pharmacokinetic models in model-based classification approaches can lead to clinically useful classifications. [ABSTRACT FROM AUTHOR]

Published
2016
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10. Host cell surfaces induce a Type IV pili-dependent alteration of bacterial swimming.

Author

Golovkine, Guillaume, Lemelle, Laurence, Burny, Claire, Vaillant, Cedric, Palierne, Jean-Francois, Place, Christophe, and Huber, Philippe

Abstract

For most pathogenic bacteria, flagellar motility is recognized as a virulence factor. Here, we analysed the swimming behaviour of bacteria close to eukaryotic cellular surfaces, using the major opportunistic pathogen Pseudomonas aeruginosa as a model. We delineated three classes of swimming trajectories on both cellular surfaces and glass that could be differentiated by their speeds and local curvatures, resulting from different levels of hydrodynamic interactions with the surface. Segmentation of the trajectories into linear and curved sections or pause allowed us to precisely describe the corresponding swimming patterns near the two surfaces. We concluded that (i) the trajectory classes were of same nature on cells and glass, however the trajectory distribution was strikingly different between surface types, (ii) on cell monolayers, a larger fraction of bacteria adopted a swimming mode with stronger bacteria-surface interaction mostly dependent upon Type IV pili. Thus, bacteria swim near boundaries with diverse patterns and importantly, Type IV pili differentially influence swimming near cellular and abiotic surfaces. [ABSTRACT FROM AUTHOR]

Published
2016
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11. Back pain exercise therapy remodels human epigenetic profiles in buccal and human peripheral blood mononuclear cells: an exploratory study in young male participants.

Author

Burny C, Potočnjak M, Hestermann A, Gartemann S, Hollmann M, Schifferdecker-Hoch F, Markanovic N, Di Sanzo S, Günsel M, Solis-Mezarino V, and Voelker-Albert M

Abstract

Background: With its high and increasing lifetime prevalence, back pain represents a contemporary challenge for patients and healthcare providers. Monitored exercise therapy is a commonly prescribed treatment to relieve pain and functional limitations. However, the benefits of exercise are often gradual, subtle, and evaluated by subjective self-reported scores. Back pain pathogenesis is interlinked with epigenetically mediated processes that modify gene expression without altering the DNA sequence. Therefore, we hypothesize that therapy effects can be objectively evaluated by measurable epigenetic histone posttranslational modifications and proteome expression. Because epigenetic modifications are dynamic and responsive to environmental exposure, lifestyle choices-such as physical activity-can alter epigenetic profiles, subsequent gene expression, and health traits. Instead of invasive sampling (e.g., muscle biopsy), we collect easily accessible buccal swabs and plasma. The plasma proteome provides a systemic understanding of a person's current health state and is an ideal snapshot of downstream, epigenetically regulated, changes upon therapy. This study investigates how molecular profiles evolve in response to standardized sport therapy and non-controlled lifestyle choices., Results: We report that the therapy improves agility, attenuates back pain, and triggers healthier habits. We find that a subset of participants' histone methylation and acetylation profiles cluster samples according to their therapy status, before or after therapy. Integrating epigenetic reprogramming of both buccal cells and peripheral blood mononuclear cells (PBMCs) reveals that these concomitant changes are concordant with higher levels of self-rated back pain improvement and agility gain. Additionally, epigenetic changes correlate with changes in immune response plasma factors, reflecting their comparable ability to rate therapy effects at the molecular level. We also performed an exploratory analysis to confirm the usability of molecular profiles in (1) mapping lifestyle choices and (2) evaluating the distance of a given participant to an optimal health state., Conclusion: This pre-post cohort study highlights the potential of integrated molecular profiles to score therapy efficiency. Our findings reflect the complex interplay of an individual's background and lifestyle upon therapeutic exposure. Future studies are needed to provide mechanistic insights into back pain pathogenesis and lifestyle-based epigenetic reprogramming upon sport therapy intervention to maintain therapeutic effects in the long run., Competing Interests: CB, MP, NM, SS, MG, VS-M, and MV-A were employees of EpiQMAx GmbH. MP, SS, and MV-A are employees of MOLEQLAR Analytics GmbH. AH, SG, MH, and FS are employees of FPZ GmbH., (© 2024 Burny, Potočnjak, Hestermann, Gartemann, Hollmann, Schifferdecker-Hoch, Markanovic, Di Sanzo, Günsel, Solis-Mezarino and Voelker-Albert.)

Published
2024
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12. Acute multi-level response to defective de novo chromatin assembly in S-phase.

Author

Dreyer J, Ricci G, van den Berg J, Bhardwaj V, Funk J, Armstrong C, van Batenburg V, Sine C, VanInsberghe MA, Marsman R, Mandemaker IK, di Sanzo S, Costantini J, Manzo SG, Biran A, Burny C, Völker-Albert M, Groth A, Spencer SL, van Oudenaarden A, and Mattiroli F

Abstract

Long-term perturbation of de novo chromatin assembly during DNA replication has profound effects on epigenome maintenance and cell fate. The early mechanistic origin of these defects is unknown. Here, we combine acute degradation of Chromatin Assembly Factor 1 (CAF-1), a key player in de novo chromatin assembly, with single-cell genomics, quantitative proteomics, and live-microscopy to uncover these initiating mechanisms in human cells. CAF-1 loss immediately slows down DNA replication speed and renders nascent DNA hyperaccessible. A rapid cellular response, distinct from canonical DNA damage signaling, is triggered and lowers histone mRNAs. As a result, histone variants usage and their modifications are altered, limiting transcriptional fidelity and delaying chromatin maturation within a single S-phase. This multi-level response induces a cell-cycle arrest after mitosis. Our work reveals the immediate consequences of defective de novo chromatin assembly during DNA replication, explaining how at later times the epigenome and cell fate can be altered.

Published
2024
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13. Condensin controls cellular RNA levels through the accurate segregation of chromosomes instead of directly regulating transcription.

Author

Hocquet C, Robellet X, Modolo L, Sun XM, Burny C, Cuylen-Haering S, Toselli E, Clauder-Münster S, Steinmetz L, Haering CH, Marguerat S, and Bernard P

Subjects
Adenosine Triphosphatases metabolism, DNA-Binding Proteins metabolism, G2 Phase genetics, Gene Expression Profiling, Genomic Instability genetics, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Microscopy, Confocal, Multiprotein Complexes metabolism, Mutation, RNA, Fungal metabolism, S Phase genetics, Schizosaccharomyces genetics, Schizosaccharomyces metabolism, Adenosine Triphosphatases genetics, Chromosome Segregation genetics, DNA-Binding Proteins genetics, Gene Expression Regulation, Fungal, Multiprotein Complexes genetics, RNA, Fungal genetics
Abstract

Condensins are genome organisers that shape chromosomes and promote their accurate transmission. Several studies have also implicated condensins in gene expression, although any mechanisms have remained enigmatic. Here, we report on the role of condensin in gene expression in fission and budding yeasts. In contrast to previous studies, we provide compelling evidence that condensin plays no direct role in the maintenance of the transcriptome, neither during interphase nor during mitosis. We further show that the changes in gene expression in post-mitotic fission yeast cells that result from condensin inactivation are largely a consequence of chromosome missegregation during anaphase, which notably depletes the RNA-exosome from daughter cells. Crucially, preventing karyotype abnormalities in daughter cells restores a normal transcriptome despite condensin inactivation. Thus, chromosome instability, rather than a direct role of condensin in the transcription process, changes gene expression. This knowledge challenges the concept of gene regulation by canonical condensin complexes., Competing Interests: CH, XR, LM, XS, CB, SC, ET, SC, LS, CH, SM, PB No competing interests declared, (© 2018, Hocquet et al.)

Published
2018
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