Developmental deconvolution of complex organs and tissues at the level of
individual cells remains challenging. Non-invasive genetic fate mapping1 has been widely used, but the low number
of distinct fluorescent marker proteins limits its resolution. Much higher
numbers of cell markers have been generated using viral integration sites2, viral barcodes3, and strategies based on transposons4 and CRISPR/Cas9 genome editing5; however, temporal and tissue-specific induction of
barcodes in situ has not been achieved. Here we report the development of an
artificial DNA recombination locus (termed Polylox) that
enables broadly applicable endogenous barcoding based on the
Cre-loxP recombination system6,7. Polylox
recombination in situ reaches a practical diversity of several hundred thousand
barcodes, allowing tagging of single cells. We have used this experimental
system, combined with fate mapping, to assess haematopoietic stem cell (HSC)
fates in vivo. Classical models of haematopoietic lineage specification assume a
tree with few major branches. More recently, driven in part by the development
of more efficient single-cell assays and improved transplantation efficiencies,
different models have been proposed, in which unilineage priming may occur in
mice and humans at the level of HSCs8–10. We have
introduced barcodes into HSC progenitors in embryonic mice, and found that the
adult HSC compartment is a mosaic of embryo-derived HSC clones, some of which
are unexpectedly large. Most HSC clones gave rise to multilineage or
oligolineage fates, arguing against unilineage priming, and suggesting coherent
usage of the potential of cells in a clone. The spreading of barcodes, both
after induction in embryos and in adult mice, revealed a basic split between
common myeloid-erythroid development and common lymphocyte development,
supporting the long-held but contested view of a tree-like haematopoietic
structure.
Lineage tracing reveals hematopoietic stem cell (HSC) fates, while single-cell RNA sequencing identifies snapshots of HSC transcriptomes. To obtain information on fate plus transcriptome in the same cell, we developed the PolyloxExpress allele, enabling Cre-recombinase-dependent RNA barcoding in situ. Linking fates to single HSC transcriptomes provided the information required to identify transcriptional signatures of HSC fates, which were not apparent in single-HSC transcriptomes alone. We find that differentiation-inactive, multilineage, and lineage-restricted HSC clones reside in distinct regions of the transcriptional landscape of hematopoiesis. Differentiation-inactive HSC clones are closer to the origin of the transcriptional trajectory, yet they are not characterized by a quiescent gene signature. Fate-specific gene signatures imply coherence of clonal HSC fates, and HSC output toward short-lived lineage progenitors indicates stability of HSC fates over time. These combined analyses of fate and transcriptome under physiological conditions may pave the way toward identifying molecular determinants of HSC fates.
Pollen tube tip growth is an extreme form of polarized cell growth, which requires polarized exocytosis based on a dynamic actin cytoskeleton. However, the molecular basis for the connection between actin filaments and exocytic vesicles is unclear. Here, we identified a Lilium longiflorum pollen-specific formin (LlFH1) and found that it localized at the apical vesicles and plasma membrane (PM). Overexpression of LlFH1 induced excessive actin cables in the tube tip region, and downregulation of LlFH1 eliminated the actin fringe. Fluorescence recovery after photobleaching (FRAP) analysis revealed that LlFH1-labeled exocytic vesicles exhibited an initial accumulation at the shoulder of the apex and coincided with the leading edge of the actin fringe. Time-lapse analysis suggested that nascent actin filaments followed the emergence of the apical vesicles, implying that LlFH1 at apical vesicles could initiate actin polymerization. Biochemical assays showed that LlFH1 FH1FH2 could nucleate actin polymerization, but then capped the actin filament at the barbed end and inhibited its elongation. However, in the presence of lily profilins, LlFH1 FH1FH2 could accelerate barbed-end actin elongation. In addition, LlFH1 FH1FH2 was able to bundle actin filaments. Thus, we propose that LlFH1 and profilin coordinate the interaction between the actin fringe and exocytic vesicle trafficking during pollen tube growth of lily.
Adult bone marrow harbors a mosaic of hematopoietic stem cell (HSC) clones of embryonic origin, and recent work suggests that such clones may have coherent lineage fates. To probe under physiological conditions whether HSC clones with different fates are transcriptionally distinct, we developed PolyloxExpress -a Cre recombinase-dependent DNA substrate for in situ barcoding that allows parallel readout of barcodes and transcriptomes in single cells. We describe differentiation-inactive, multilineage and lineage-restricted HSC clones, find that they reside in distinct regions of the transcriptional landscape of hematopoiesis, and identify corresponding gene signatures. All clone types contain proliferating HSCs, indicating that differentiationinactive HSCs can undergo symmetric self-renewal. Our work establishes an approach for studying determinants of stem cell fate in vivo and provides molecular evidence for fate coherence of HSC clones.
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