Project description:<p>Hematopoietic stem cell (HSC) mutations can result in clonal hematopoiesis (CH) with heterogeneous clinical outcomes. Here, we investigated how the cell state preceding <em>Tet2</em> mutation impacts the pre-malignant phenotype. Using an inducible system for clonal analysis of myeloid progenitors, we found that the epigenetic features of clones at similar differentiation status were highly heterogeneous and functionally responded differently to <em>Tet2</em> mutation. Cell differentiation stage also influenced <em>Tet2</em> mutation response indicating that the cell of origin's epigenome modulates clone-specific behaviors in CH. Molecular features associated with higher risk outcomes include <em>Sox4</em> that sensitized cells to <em>Tet2</em> inactivation, inducing dedifferentiation, altered metabolism and increasing the <em>in vivo</em> clonal output of mutant cells, as confirmed in primary GMP and HSC models. Our findings validate the hypothesis that epigenetic features can predispose specific clones for dominance, explaining why identical genetic mutations can result in different phenotypes.</p>

Project description:T cells activated by chronic antigen exposure in the setting of viral infections or cancer can adopt an exhausted T cell (TEx) state, characterized by reduced effector function and proliferative capacity, and the upregulation of inhibitory receptors. Here, we generate a single-cell multi-omic atlas of T cell exhaustion in chronic viral infection that redefines the phenotypic diversity and molecular regulation of TEx states. Longitudinal analysis of the T cell response identifies an early effector phenotype that is epigenetically primed for TEx differentiation. However, clonal T cell trajectories defined using paired single-cell RNA and T cell receptor (scRNA/TCR-seq) sequencing reveal divergent differentiation trajectories among clones that recognize shared antigens, resulting in TEx- or effector memory-biased clone behaviors. Multi-organ clonal analysis reveals that T cell clone behaviors are sensitive to the tissue environment, and the liver niche preclude the development of effector memory phenotypes and induce exaggerated exhaustion. Finally, we show that divergent clonal trajectories are driven by differences in TCR affinity, and that high-affinity T cell clones preferentially adopt the divergent fate, while low-affinity clones adopt effector memory fates that are deleted in high antigen niches. These findings reveal heterogeneity in clonal T cell responses to chronic antigen and link TCR signal strength and epigenetic programming to TEx cell fates and persistence, which may be manipulated for cancer immunotherapy.

Project description:Human induced pluripotent stem cells (hiPSCs) generate multiple clones with inherent heterogeneity, leading to variations in their differentiation capacity. Previous studies have primarily addressed line-to-line variations in differentiation capacity, leaving a gap in the comprehensive understanding of clonal heterogeneity. Here, we aimed to identify predictive biomarkers for cardiomyocyte differentiation capacity by integrating transcriptomic, epigenomic, endogenous retroelement, and protein kinase phosphorylation profiles. We generated multiple clones from a single donor and validated that these clones exhibited comparable levels of pluripotent markers. These clones were then classified into two groups based on their differentiation capacity: productive clone (PC) and non-productive clone (NPC). We performed RNA sequencing and assay for transposase-accessible chromatin with sequencing (ATAC-seq). NPC was enriched in vasculogenesis and cell adhesion, accompanied by elevated ERK1/2 signaling pathway phosphorylation. Conversely, PC exhibited enrichment in embryonic organ development and transcription factor activation, accompanied by increased chromatin accessibility. Integrative analysis of RNA sequencing and ATAC-seq revealed 14 candidate genes correlated with cardiac differentiation propensity. Notably, TEK and SDR42E1 were upregulated in NPC. Our integrative profiles enhance the understanding of clonal heterogeneity and highlight two novel biomarkers associated with cardiomyocytes differentiation. This insight may facilitate the identification of suboptimal hiPSC clones, thereby mitigating adverse outcomes in clinical applications.

Project description:Human induced pluripotent stem cells (hiPSCs) generate multiple clones with inherent heterogeneity, leading to variations in their differentiation capacity. Previous studies have primarily addressed line-to-line variations in differentiation capacity, leaving a gap in the comprehensive understanding of clonal heterogeneity. Here, we aimed to identify predictive biomarkers for cardiomyocyte differentiation capacity by integrating transcriptomic, epigenomic, endogenous retroelement, and protein kinase phosphorylation profiles. We generated multiple clones from a single donor and validated that these clones exhibited comparable levels of pluripotent markers. These clones were then classified into two groups based on their differentiation capacity: productive clone (PC) and non-productive clone (NPC). We performed RNA sequencing and assay for transposase-accessible chromatin with sequencing (ATAC-seq). NPC was enriched in vasculogenesis and cell adhesion, accompanied by elevated ERK1/2 signaling pathway phosphorylation. Conversely, PC exhibited enrichment in embryonic organ development and transcription factor activation, accompanied by increased chromatin accessibility. Integrative analysis of RNA sequencing and ATAC-seq revealed 14 candidate genes correlated with cardiac differentiation propensity. Notably, TEK and SDR42E1 were upregulated in NPC. Our integrative profiles enhance the understanding of clonal heterogeneity and highlight two novel biomarkers associated with cardiomyocytes differentiation. This insight may facilitate the identification of suboptimal hiPSC clones, thereby mitigating adverse outcomes in clinical applications.

Project description:Hematopoietic stem cell (HSC) differentiation into mature lineages has been studied under physiological conditions in vivo by genetic barcoding-driven lineage tracing. HSC clones differ in output (differentiation-inactive versus differentiation-active), and in fates (multilineage versus lineage-restricted). Single-cell sequencing data revealed transcriptome diversity of HSC and progenitors, and suggested differentiation pathways. However, molecular hallmarks of functionally distinct HSC clones have not been resolved because existing lineage tracing experiments did not provide transcriptomes, and single cell RNA sequencing lacked information on precursor-product relationships, and hence fate. To close this gap, here we introduce PolyloxExpress, a Cre recombinase-dependent DNA substrate for in situ barcoding in mice that is expressed as mRNA. PolyloxExpress barcoding allows parallel readout of clonal HSC fates (via comparison of barcodes in HSC and mature lineages), and transcriptomes (via single-cell RNA sequencing and barcode matching). Analysing a total of 91 individual HSC clones, we show that differentiation-inactive versus differentiation-active HSC clones reside in different regions of the transcriptional landscape. Inactive HSC clones are closer to the origin of the transcriptional trajectory, yet are proliferatively not more quiescent than active clones. Multilineage versus myelo-erythroid fate-restricted HSC clones show very few transcriptional differences at the HSC stage, yet pronounced fate-specific profiles at the multipotent progenitor stage. Projecting HSC clones with defined fates onto transcriptional landscapes provides a basis for future studies into the molecular determinants for stem cell fate.

Project description:Hematopoietic stem cell (HSC) differentiation into mature lineages has been studied under physiological conditions in vivo by genetic barcoding-driven lineage tracing. HSC clones differ in output (differentiation-inactive versus differentiation-active), and in fates (multilineage versus lineage-restricted). Single-cell sequencing data revealed transcriptome diversity of HSC and progenitors, and suggested differentiation pathways. However, molecular hallmarks of functionally distinct HSC clones have not been resolved because existing lineage tracing experiments did not provide transcriptomes, and single cell RNA sequencing lacked information on precursor-product relationships, and hence fate. To close this gap, here we introduce PolyloxExpress, a Cre recombinase-dependent DNA substrate for in situ barcoding in mice that is expressed as mRNA. PolyloxExpress barcoding allows parallel readout of clonal HSC fates (via comparison of barcodes in HSC and mature lineages), and transcriptomes (via single-cell RNA sequencing and barcode matching). Analysing a total of 91 individual HSC clones, we show that differentiation-inactive versus differentiation-active HSC clones reside in different regions of the transcriptional landscape. Inactive HSC clones are closer to the origin of the transcriptional trajectory, yet are proliferatively not more quiescent than active clones. Multilineage versus myelo-erythroid fate-restricted HSC clones show very few transcriptional differences at the HSC stage, yet pronounced fate-specific profiles at the multipotent progenitor stage. Projecting HSC clones with defined fates onto transcriptional landscapes provides a basis for future studies into the molecular determinants for stem cell fate.

Project description:Clonal hematopoiesis (CH) results from enhanced fitness of a mutant hematopoietic stem and progenitor cell (HSPC), but how such clones expand is unclear. Here, we developed a technique that combines mosaic mutagenesis with color labeling of HSPCs to study how acquired mutations affect clonal fitness in a native environment. Mutations in CH-associated genes, like asxl1, promoted clonal dominance. Single-cell transcriptional analysis revealed that mutations stimulated expression of proinflammatory genes in mature myeloid cells and anti-inflammatory genes in progenitor cells of the mutant clone. Biallelic loss of one such immunomodulator, nr4a1, abrogated the ability of asxl1-mutant clones to establish clonal dominance. These results support a model where clonal fitness of mutant clones is driven by enhanced resistance to inflammatory signals from their mutant mature cell progeny.

Project description:Clonal hematopoiesis (CH) results from enhanced fitness of a mutant hematopoietic stem and progenitor cell (HSPC), but how such clones expand is unclear. Here, we developed a technique that combines mosaic mutagenesis with color labeling of HSPCs to study how acquired mutations affect clonal fitness in a native environment. Mutations in CH-associated genes, like asxl1, promoted clonal dominance. Single-cell transcriptional analysis revealed that mutations stimulated expression of proinflammatory genes in mature myeloid cells and anti-inflammatory genes in progenitor cells of the mutant clone. Biallelic loss of one such immunomodulator, nr4a1, abrogated the ability of asxl1-mutant clones to establish clonal dominance. These results support a model where clonal fitness of mutant clones is driven by enhanced resistance to inflammatory signals from their mutant mature cell progeny.

Project description:Glioblastoma progression remains elusive, especially in its first stages. Here, by simultaneous transfer of PDGFB and genetic barcode in mouse brain, we triggered gliomagenesis in univocally labelled cells in vivo, hence enabling direct tracing of glioblastoma evolution from the earliest possible stage. We observed an unexpectedly high incidence of clonal extinction events and progressive clonal size divergence, even after the acquisition of a malignant phenotype. Computational modelling suggests these dynamics as the consequence of a clonal-based cell-cell competition. Bulk and single-cell transcriptome analyses, coupled to lineage tracing, revealed that the strongest correlation with clonal size unbalancing is shown by Myc transcriptional targets. Additionally, higher levels of Myc signalling discriminate "winner" from "loser" clones in early gliomagenesis. These results agree with recent understanding of the Myc-mediated induction of supercompetitive phenotype in mammalian embryo. Our findings shed light on aspects of glioblastoma evolution inaccessible by conventional retrospective approaches and highlight the potential of the combined use of clonal tracing and transcriptomic analyses in this field.

Project description:Glioblastoma progression remains elusive, especially in its first stages. Here, by simultaneous transfer of PDGFB and genetic barcode in mouse brain, we triggered gliomagenesis in univocally labelled cells in vivo, hence enabling direct tracing of glioblastoma evolution from the earliest possible stage. We observed an unexpectedly high incidence of clonal extinction events and progressive clonal size divergence, even after the acquisition of a malignant phenotype. Computational modelling suggests these dynamics as the consequence of a clonal-based cell-cell competition. Bulk and single-cell transcriptome analyses, coupled to lineage tracing, revealed that the strongest correlation with clonal size unbalancing is shown by Myc transcriptional targets. Additionally, higher levels of Myc signalling discriminate "winner" from "loser" clones in early gliomagenesis. These results agree with recent understanding of the Myc-mediated induction of supercompetitive phenotype in mammalian embryo. Our findings shed light on aspects of glioblastoma evolution inaccessible by conventional retrospective approaches and highlight the potential of the combined use of clonal tracing and transcriptomic analyses in this field.