Retracing the <i>in vivo</i> haematopoietic tree using single‐cell methods

Perié, Leïla; Duffy, Ken R.

doi:10.1002/1873-3468.12299

Cited by 15 publications

(16 citation statements)

References 75 publications

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“…The generation of a diversity of cell types is presently assumed to result from a diversification within a family, and methods for inferring differentiation trajectories using single cell RNA sequencing data from snapshot data assume that cells all behave independently [41,42]. Consistent with previous observations of early lineages decisions [22,43,44], our findings establish that familial dependencies that are currently unmeasured exist within the population, and call for a revision of that assumption and subsequent analysis. Ancestral cell surface expression of markers used for phenotyping serve as correlates that partially predict some of these familial properties, but, in particular, a correlate that explains the highly heritable division progression of ST-HSC and MPP families is not contained within them.…”

Section: Discussionsupporting

confidence: 80%

“…Those data suggest that HSCs are a heterogeneous population, where each one of them may be committed to the production of only a few lineages, possibly through lineage priming or externally through instruction from a niche. Similarly, transplanted barcoded MPPs have been reported to produce heterogeneous patterns of restricted cell types [21], suggesting that lineage restriction may occur early in the hematopoietic tree, in the pool of HSCs and MPPs [22].…”

Section: Introductionmentioning

confidence: 99%

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Simultaneous tracking of division and differentiation from individual hematopoietic stem and progenitor cells reveals within-family homogeneity despite population heterogeneity

Tak

Prevedello

Simon

et al. 2019

Preprint

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The advent of high throughput single cell methods such as scRNA-seq has uncovered substantial heterogeneity in the pool of hematopoietic stem and progenitor cells (HSPCs). A significant issue is how to reconcile those findings with the standard model of hematopoietic development, and a fundamental question is how much instruction is inherited by offspring from their ancestors. To address this, we further developed a high-throughput method that enables simultaneously determination of common ancestor, generation, and differentiation status of a large collection of single cells. Data from it revealed that while there is substantial population-level heterogeneity, cells that derived from a common ancestor were highly concordant in their division progression and share similar differentiation outcomes, revealing significant familial effects on both division and differentiation. Although each family diversifies to some extent, the overall collection of cell types observed in a population is largely composed of homogeneous families from heterogeneous ancestors. Heterogeneity between families could be explained, in part, by differences in ancestral expression of cellsurface markers that are used for phenotypic HSPC identification: CD48, SCA-1, c-kit and Flt3. These data call for a revision of the fundamental model of haematopoiesis from a single tree to an ensemble of trees from distinct ancestors where common ancestor effect must be considered. As HSPCs are cultured in the clinic before bone marrow transplantation, our results suggest that the broad range of engraftment and proliferation capacities of HSPCs could be consequences of the heterogeneity in their engrafted families, and altered culture conditions might reduce heterogeneity between families, possibly improving transplantation outcomes.

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Section: Discussionsupporting

confidence: 80%

Section: Introductionmentioning

confidence: 99%

Simultaneous tracking of division and differentiation from individual hematopoietic stem and progenitor cells reveals within-family homogeneity despite population heterogeneity

Tak

Prevedello

Simon

et al. 2019

Preprint

Self Cite

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“…Various alternative approaches have been developed (Kretzschmar and Watt, 2012). In mice, cells can be genetically marked with different colors (Barker et al, 2007) or DNA barcodes (Lu et al, 2011;Naik et al, 2013;Perie and Duffy, 2016), and their offspring traced during development. Recent work has used iterative CRISPR-based genome editing to generate random genetic scars in the fetal genome and use them to reconstruct lineages in the adult animal (McKenna et al, 2016).…”

Section: Multiplex In Situ Analysis and Other Spatial Techniques Aim mentioning

confidence: 99%

The Human Cell Atlas

Regev

Teichmann

Lander

et al. 2017

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The recent advent of methods for high-throughput single-cell molecular profiling has catalyzed a growing sense in the scientific community that the time is ripe to complete the 150-year-old effort to identify all cell types in the human body, by undertaking a Human Cell Atlas Project as an international collaborative effort. The aim would be to define all human cell types in terms of distinctive molecular profiles (e.g., gene expression) and connect this information with classical cellular descriptions (e.g., location and morphology). A comprehensive reference map of the molecular state of cells in healthy human tissues would propel the systematic study of physiological states, developmental trajectories, regulatory circuitry and interactions of cells, as well as provide a framework for understanding cellular dysregulation in human disease. Here we describe the idea, its potential utility, early proofs-of-concept, and some design considerations for the Human Cell Atlas.

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“…The protein abundances were saved at 100 uniformly placed time points from t=0 to t=150. 1 Here we mean cutting in the sense used regarding hierarchical clustering, and not in the sense previously used for trees.…”

Section: Generation Of Hierarchically Branching Synthetic Datamentioning

confidence: 99%

Tree-ensemble analysis tests for presence of multifurcations in single cell data

Macnair

Roditi

Ganscha

et al. 2017

Preprint

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We introduce TreeTop, an algorithm for single-cell data analysis to identify and assess statistical significance of branch points in biological processes with possibly multi-level branching hierarchies. We demonstrate branch point identification for processes with varying topologies, including T cell maturation, B cell differentiation and hematopoiesis. Our analyses are consistent with recent experimental studies suggesting a shallow hierarchy of differentiation events in hematopoiesis, rather than the classical multi-level hierarchy. MainMany important biological processes, such as differentiation in developmental and immune biology, and clonal evolution in cancer, can be conceived of as bi-or multi-furcated cellular state trajectories. Hematopoiesis is such a process, where hematopoietic stem cells (HSCs) give rise to multiple distinct mature blood cell types via a sequence of lineage commitments. The exact sequence is still debated 1 , either assuming a hierarchical architecture of multiple fate decisions via distinct oligopotent progenitor cell states 2-4 , or a flat hierarchy of hematopoiesis, which does not include oligopotent progenitors, and where HSCs differentiate directly into committed lineages 5-7 .High dimensional single-cell technologies, such as single-cell RNA sequencing 8 and mass cytometry 9 , constitute increasingly widely used tools to investigate such opposing models of differentiation, and other branching processes. These technologies allow the evaluation of the state of single cells, i.e. the transcriptional or proteomic abundance profile in the case of single cell RNA sequencing or mass cytometry, respectively. Biological processes can be conceived of as trajectories through state space: temporal sequences of cellular states that can either be derived from time series or reconstructed from non-time series single-cell data 10 . We define a branch point as the location in state space where three or more distinct . CC-BY-NC-ND 4.0 International license not peer-reviewed) is the author/funder. It is made available under a The copyright holder for this preprint (which was . http://dx.doi.org/10.1101/200923 doi: bioRxiv preprint first posted online Oct. 10, 2017; cellular state trajectories meet. Branch points dissect these trajectories into distinct state trajectory branches.Identifying branch points is challenging because for each single cell measurement, both branch membership and ordering within each branch must be learned simultaneously. Existing approaches include pseudotime ordering, which learns a latent time variable along a mean trajectory through state space is limited to non-branching processes [11][12] . SPADE overcomes this limitation by fitting a single minimum spanning tree to non-deterministically clustered data 13 . Monocle 11,14 fits smoothed trees to a low dimensional representation of single cell data, where branch points in the tree are assumed to correspond to branch points in the data. Both Monocle and SPADE by definition impose a tree topology, regardless ...

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Retracing the in vivo haematopoietic tree using single‐cell methods

Cited by 15 publications

References 75 publications

Simultaneous tracking of division and differentiation from individual hematopoietic stem and progenitor cells reveals within-family homogeneity despite population heterogeneity

Simultaneous tracking of division and differentiation from individual hematopoietic stem and progenitor cells reveals within-family homogeneity despite population heterogeneity

The Human Cell Atlas

Tree-ensemble analysis tests for presence of multifurcations in single cell data

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