Project description:Adaptive evolution in response to cellular stress is a critical process implicated in a wide range of core biological and clinical phenomena. Two major routes of adaptation have been identified: non-genetic cellular plasticity, which allows expression of different phenotypes in novel environments, and genetic variation achieved by selection of fitter phenotypes. While these processes are now broadly accepted, their temporal and epistatic features in the context of cellular evolution and emerging drug resistance are contentious. In this project, we generated hypomorphic alleles of the essential nuclear pore complex (NPC) gene NUP58. By dissecting both early and long-term mechanisms of adaptation in independent clones, we observed that early physiological adaptation correlated with transcriptome rewiring and upregulation of genes known to interact with the NPC. In contrast, long-term adaptation and fitness recovery occurred via focal amplification of NUP58 and restoration of mutant protein expression. These data support the concept that plasticity-mediated and genetic routes can co-exist to enable cellular evolution, with early flexibility of phenotype allowing later acquisition of genetic adaptations to a specific impairment. We propose this approach as a genetic model to mimic targeted drug therapy in human cells and to dissect early and late mechanisms of adaptation. Targeting both mechanisms in parallel may reduce the emergence of drug resistance.

Project description:The discovery of white-opaque switching in natural MTLa/alpha isolates of Candida albicans sheds new light on the evolution of phenotypic plasticity and host adaptation. Comparing gene expression of white and opaque cells of a MTL a/alpha strain

Project description:The discovery of white-opaque switching in natural MTLa/alpha isolates of Candida albicans sheds new light on the evolution of phenotypic plasticity and host adaptation.

Project description:Long-term laboratory evolution experiments provide a controlled record of evolutionary dynamics and metabolic change in microorganisms. Nevertheless, the correspondence between genetic mutation and phenotypic adaptation remains elusive, partly because of the overwhelming number of genetic changes that accrue after tens-of-thousands of generations. Using a coarse-grained characterization of bacterial physiology applied to Lenski's laboratory-evolved strains of Escherichia coli, we identify an intermediate measure between genotype and phenotype that provides insight into the dynamics of adaptation.

Project description:Many organisms can acclimate to new environments through phenotypic plasticity, a complex trait that can be heritable, subject to selection, and evolve. However, the rate and genetic basis of plasticity evolution remain largely unknown. We experimentally evolved outbred populations of the nematode Caenorhabditis remanei under an acute heat shock during early larval development. When raised in a non-stressful environment, ancestral populations were highly sensitive to a 36.8°C heat shock and exhibited high mortality. However, initial exposure to a non-lethal high temperature environment resulted in significantly reduced mortality during heat shock (hormesis). Lines selected for heat shock resistance rapidly evolved the capacity to withstand heat shock in the native environment without any initial exposure to high temperatures, and early exposure to high temperatures did not lead to further increases in heat resistance. This loss of plasticity would appear to have resulted from the genetic assimilation of the heat induction response in the non-inducing environment. However, analyses of transcriptional variation via RNA-sequencing from the selected populations revealed no global changes in gene regulation correlated with the observed changes in heat stress resistance. Instead, assays of the phenotypic response across a broader range of temperatures revealed that the induced plasticity was not fixed across environments, but rather the threshold for the response was shifted to higher temperatures over evolutionary time. These results demonstrate that apparent genetic assimilation can result from shifting thresholds of induction across environments and that analysis of the broader environmental context is critically important for understanding the evolution of phenotypic plasticity. mRNA profiles of ancestral and two experimentally evolved populations of C. remanei at 20°C or 30°C, 6 replicates/temperature for each population

Project description:The interplay between phenotypic plasticity and adaptive evolution has long been an important topic of evolutionary biology. This process is critical to our understanding of a species evolutionary potential in light of rapid climate changes. Despite recent theoretical work, empirical studies of natural populations, especially in marine invertebrates, are scarce. In this study, we investigated the relationship between adaptive divergence and plasticity by integrating genetic and phenotypic variation in Pacific oysters from its natural range in China. Genome resequencing of 371 oysters revealed unexpected fine-scale genetic structure that is largely consistent with phenotypic divergence in growth, physiology, thermal tolerance and gene expression across environmental gradient. These findings suggest that selection and local adaptation are pervasive and together with limited gene flow shape adaptive divergence. Plasticity in gene expression is positively correlated with evolved divergence, indicating that plasticity is adaptive and likely favored by selection in organisms facing dynamic environments such as oysters. Divergence in heat response and tolerance implies that the evolutionary potential to a warming climate differs among oyster populations. We suggest that trade-offs in energy allocation are important to adaptive divergence with acetylation playing a role in energy depression under thermal stress.

Project description:Genome-wide transcriptional plasticity underlies cellular adaptation to novel challenge

Project description:The prevailing model of therapeutic resistance in cancer posits that malignant cells acquire genetic mutations in the context of therapeutic pressure that negate the efficacy of the drug. This mutation centric view of therapeutic resistance has recently been challenged by emerging evidence that shows a paucity of genetic diversity in malignant cells that evade therapeutic challenge emphasizing the role of epigenetic evolution in drug resistance. We have previously established that therapeutic resistance emerges in the absence of genetic adaptation from leukemia stem cells and whilst the clinical relevance of these findings has been established, what remains unanswered is whether transcriptional programs that confer resistance to therapies are pre-existing or acquired. It is also unclear how stable this adaptive transcriptional response is and whether it can be reversed. Here, we utilize a unique leukaemia model to highlight the key principles of epigenetic resistance. Using single cell RNA-seq with indexed flow sorting, we demonstrate that a form of Lamarckian evolution, namely transcriptional plasticity, drives epigenetic resistance. With a CRISPR-Cas9 screen we identify reciprocal regulators of the enhancer modification H3K4me1/2, LSD1 and MLL4, as important modulators of the resistant cell state. Knockdown or catalytic inhibition of LSD1 causes reversion to a drug sensitive state that is dependent on the lineage determining pioneer transcription factor Pu.1. Mechanistically, we establish that inhibition of LSD1 results in newly formed enhancers marked by H3K4me1/2, H3K27ac and Pu.1 binding, which facilitates the recruitment of transcriptional co-activators and activation of a differentiation gene expression program. We show that this enhancer-remodeling does not result in a simple linear reversion to the original chromatin state of drug naive cells, rather it reinstates the cells dependence on transcriptional co-activators including Med1 and Brd4 due to the formation of new enhancers with enhancer-promoter loops to canonical Brd4 target genes. Together these findings provide new insights into the molecular mechanisms that facilitate epigenetic resistance to cancer therapies and highlight new opportunities for therapeutic intervention to overcome transcriptional plasticity.

Project description:The prevailing model of therapeutic resistance in cancer posits that malignant cells acquire genetic mutations in the context of therapeutic pressure that negate the efficacy of the drug. This mutation centric view of therapeutic resistance has recently been challenged by emerging evidence that shows a paucity of genetic diversity in malignant cells that evade therapeutic challenge emphasizing the role of epigenetic evolution in drug resistance. We have previously established that therapeutic resistance emerges in the absence of genetic adaptation from leukemia stem cells and whilst the clinical relevance of these findings has been established, what remains unanswered is whether transcriptional programs that confer resistance to therapies are pre-existing or acquired. It is also unclear how stable this adaptive transcriptional response is and whether it can be reversed. Here, we utilize a unique leukaemia model to highlight the key principles of epigenetic resistance. Using single cell RNA-seq with indexed flow sorting, we demonstrate that a form of Lamarckian evolution, namely transcriptional plasticity, drives epigenetic resistance. With a CRISPR-Cas9 screen we identify reciprocal regulators of the enhancer modification H3K4me1/2, LSD1 and MLL4, as important modulators of the resistant cell state. Knockdown or catalytic inhibition of LSD1 causes reversion to a drug sensitive state that is dependent on the lineage determining pioneer transcription factor Pu.1. Mechanistically, we establish that inhibition of LSD1 results in newly formed enhancers marked by H3K4me1/2, H3K27ac and Pu.1 binding, which facilitates the recruitment of transcriptional co-activators and activation of a differentiation gene expression program. We show that this enhancer-remodeling does not result in a simple linear reversion to the original chromatin state of drug naive cells, rather it reinstates the cells dependence on transcriptional co-activators including Med1 and Brd4 due to the formation of new enhancers with enhancer-promoter loops to canonical Brd4 target genes. Together these findings provide new insights into the molecular mechanisms that facilitate epigenetic resistance to cancer therapies and highlight new opportunities for therapeutic intervention to overcome transcriptional plasticity.

Project description:The prevailing model of therapeutic resistance in cancer posits that malignant cells acquire genetic mutations in the context of therapeutic pressure that negate the efficacy of the drug. This mutation centric view of therapeutic resistance has recently been challenged by emerging evidence that shows a paucity of genetic diversity in malignant cells that evade therapeutic challenge emphasizing the role of epigenetic evolution in drug resistance. We have previously established that therapeutic resistance emerges in the absence of genetic adaptation from leukemia stem cells and whilst the clinical relevance of these findings has been established, what remains unanswered is whether transcriptional programs that confer resistance to therapies are pre-existing or acquired. It is also unclear how stable this adaptive transcriptional response is and whether it can be reversed. Here, we utilize a unique leukaemia model to highlight the key principles of epigenetic resistance. Using single cell RNA-seq with indexed flow sorting, we demonstrate that a form of Lamarckian evolution, namely transcriptional plasticity, drives epigenetic resistance. With a CRISPR-Cas9 screen we identify reciprocal regulators of the enhancer modification H3K4me1/2, LSD1 and MLL4, as important modulators of the resistant cell state. Knockdown or catalytic inhibition of LSD1 causes reversion to a drug sensitive state that is dependent on the lineage determining pioneer transcription factor Pu.1. Mechanistically, we establish that inhibition of LSD1 results in newly formed enhancers marked by H3K4me1/2, H3K27ac and Pu.1 binding, which facilitates the recruitment of transcriptional co-activators and activation of a differentiation gene expression program. We show that this enhancer-remodeling does not result in a simple linear reversion to the original chromatin state of drug naive cells, rather it reinstates the cells dependence on transcriptional co-activators including Med1 and Brd4 due to the formation of new enhancers with enhancer-promoter loops to canonical Brd4 target genes. Together these findings provide new insights into the molecular mechanisms that facilitate epigenetic resistance to cancer therapies and highlight new opportunities for therapeutic intervention to overcome transcriptional plasticity.