Corrigendum: Lineage Tracing and Fate Mapping in Xenopus Embryos

Abstract Kupffer cells (KCs) originate from yolk sac progenitors before birth, but the origin of repopulating KCs in adult remains unclear. In current study, we firstly traced the fate of preexisting KCs and that of monocytic cells with tissue-resident macrophage-specific and monocytic cell-specific fate mapping mouse models, respectively, and found no evidences that repopulating KCs originate from preexisting KCs or MOs. Secondly, we performed genetic lineage tracing to determine the type of progenitor cells involved in response to KC depletion in mice, and found that in response to KC depletion, hematopoietic stem cells (HSCs) proliferated in the bone marrow, mobilized into the blood, adoptively transferred into the liver and differentiated into KCs. Finally, we traced the fate of HSCs in a HSC-specific fate-mapping mouse model, in context of chronic liver inflammation induced by repeated carbon tetrachloride treatment, and confirmed that repopulating KCs originated directly from HSCs. Taken together, these findings provided in vivo fate-mapping evidences that repopulating KCs originate directly from hematopoietic stem cells, which present a completely novel understanding of the cellular origin of repopulating Kupffer Cells and shedding light on the divergent roles of KCs in liver homeostasis and diseases.

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Regional cell movement and tissue patterning in the zebrafish embryo revealed by fate mapping with caged fluorescein

Biochemistry and Cell Biology ◽

10.1139/o97-090 ◽

1997 ◽

Vol 75 (5) ◽

pp. 551-562 ◽

Cited By ~ 115

Author(s):

David J Kozlowski ◽

Tohru Murakami ◽

Robert K Ho ◽

Eric S Weinberg

Keyword(s):

Zebrafish Embryo ◽

Fluorescent Dyes ◽

Cell Lineage ◽

Cell Movement ◽

Ventral Side ◽

Lineage Tracing ◽

Otic Vesicle ◽

Fate Mapping ◽

Fate Map ◽

Animal Pole

Determination of fate maps and cell lineage tracing have previously been carried out in the zebrafish embryo by following the progeny of individual cells injected with fluorescent dyes. We review the information obtained from these experiments and then present an approach to fate mapping and cell movement tracing utilizing the activation of caged fluorescein-dextran. This method has several advantages over single-cell injections in that it is rapid, allows cells at all depths in the embryo to be marked, can be used to follow cells starting at any time during development, and allows an appreciation of the movements of cells located in a coherent group at the time of uncaging. We demonstrate that the approach is effective in providing additional and complementary information on prospective mesoderm and brain tissues studied previously. We also present, for the first time, a fate map of placodal tissues including the otic vesicle, lateral line, cranial ganglia, lens, and olfactory epithelium. The prospective placodal cells are oriented at the 50% epiboly stage on the ventral side of the embryo with anterior structures close to the animal pole, and posterior structures nearer to the germ ring.

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T cell fate mapping and lineage tracing technologies probing clonal aspects underlying the generation of CD8 T cell subsets

Scandinavian Journal of Immunology ◽

10.1111/sji.12983 ◽

2020 ◽

Vol 92 (6) ◽

Author(s):

Shaima Al Khabouri ◽

Carmen Gerlach

Keyword(s):

T Cell ◽

Cell Fate ◽

Cd8 T Cell ◽

Lineage Tracing ◽

T Cell Subsets ◽

Fate Mapping

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Specific modulation of ectodermal cell fates in Xenopus embryos by glycogen synthase kinase

Development ◽

10.1242/dev.121.12.3979 ◽

1995 ◽

Vol 121 (12) ◽

pp. 3979-3988 ◽

Cited By ~ 15

Author(s):

K. Itoh ◽

T.L. Tang ◽

B.G. Neel ◽

S.Y. Sokol

Keyword(s):

Signaling Pathways ◽

Glycogen Synthase ◽

Neural Tissue ◽

Lineage Tracing ◽

Glycogen Synthase Kinase ◽

Cell Fates ◽

Cell Stage ◽

Xenopus Embryos ◽

Mammalian Homologue ◽

Molecular Marker Analysis

Shaggy is a downstream component of the wingless and Notch signaling pathways which operate during Drosophila development. To address the role of glycogen synthase kinase 3 beta (GSK3 beta), a mammalian homologue of Shaggy, in vertebrate embryogenesis, it was overexpressed in Xenopus embryos. Microinjection of rat GSK3 beta mRNA into animal ventral blastomeres of 8-cell-stage embryos triggered development of ectopic cement glands with an adjacent anterior neural tissue as evidenced by in situ hybridization with Xotx2, a fore/midbrain marker, and NCAM, a pan-neural marker. In contrast, animal dorsal injection of the same dose of GSK3 beta mRNA caused eye deficiencies, whereas vegetal injections had no pronounced effects on normal development. Using several mutated forms of rat GSK3 beta, we demonstrate that the observed phenotypes are dose-dependent and tightly correlate with GSK3 beta enzymatic activity. Lineage tracing experiments showed that the effects of GSK3 beta are cell autonomous and that ectopic cement glands and eye deficiencies arose directly from cells containing GSK3 beta mRNA. Molecular marker analysis of ectodermal explants overexpressing GSK3 beta has revealed activation of Xotx2 and of cement gland marker XAG-1, but expression of NCAM and XIF-3 was not detected. Phenotypic effects of mRNA encoding a Xenopus homologue of GSK3 beta were identical to those of rat GSK3 beta mRNA. We hypothesize that GSK3 beta mediates the initial steps of neural tissue specification and modulates anteroposterior ectodermal patterning via activation of Otx2 transcription. Our observations implicate GSK3 beta in signaling pathways operating during neural tissue development and during specification of anterior ectodermal cell fates.

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Repopulating Kupffer Cells Originate Directly from Hematopoietic Stem Cells

10.1101/2020.07.31.230649 ◽

2020 ◽

Author(s):

Xu Fan ◽

Pei Lu ◽

Xianghua Cui ◽

Peng Wu ◽

Weiran Lin ◽

...

Keyword(s):

Stem Cells ◽

Hematopoietic Stem Cells ◽

Kupffer Cells ◽

Lineage Tracing ◽

Genetic Lineage ◽

Fate Mapping ◽

Monocytic Cell ◽

Hematopoietic Stem ◽

Cellular Origin

AbstractKupffer cells (KCs) originate from yolk sac progenitors before birth. Throughout adulthood, they self-maintain independently from the input of circulating monocytes (MOs) at stead state, and are replenished within 2 weeks after having been depleted, but the origin of repopulating KCs in adult remains unclear. The current paradigm dictates that repopulating KCs originate from preexisting KCs or monocytes, but there remains a lack of fate-mapping evidence. In current study, we firstly traced the fate of preexisting KCs and that of monocytic cells with tissue-resident macrophage-specific and monocytic cell-specific fate mapping mouse models, respectively, and found no evidences that repopulating KCs originate from preexisting KCs or MOs. Secondly, we performed genetic lineage tracing to determine the type of progenitor cells involved in response to KC depletion in mice, and found that in response to KC depletion, hematopoietic stem cells (HSCs) proliferated in the bone marrow, mobilized into the blood, adoptively transferred into the liver and differentiated into KCs. Finally, we traced the fate of HSCs in a HSC-specific fate-mapping mouse model, in context of chronic liver inflammation induced by repeated carbon tetrachloride treatment, and confirmed that repopulating KCs originated directly from HSCs. Taken together, these findings provided strong in vivo fate-mapping evidences that repopulating KCs originate directly from Hematopoietic stem cells not from preexisting KCs or from MOs.SignificanceThere is a standing controversy in the field regarding the cellular origin of repopulating macrophages. This paper provides strong in vivo fate-mapping evidences that repopulating KCs originate directly from hematopoietic stem cells not from preexisting KCs or from MOs, which presenting a completely novel understanding of the cellular origin of repopulating Kupffer Cells and shedding light on the divergent roles of KCs in liver homeostasis and diseases.

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Genetic tool for fate mapping of Oct4 (Pou5f1)-expressing cells and their progeny past the pluripotency stage

Stem Cell Research & Therapy ◽

10.1186/s13287-019-1520-6 ◽

2019 ◽

Vol 10 (1) ◽

Cited By ~ 1

Author(s):

Andrey A. Kuzmin ◽

Veronika V. Ermakova ◽

Sergey A. Sinenko ◽

Sergey V. Ponomartsev ◽

Tatiana Y. Starkova ◽

...

Keyword(s):

Stem Cells ◽

Cell Fate ◽

Embryonic Stem ◽

Stop Signal ◽

Lineage Tracing ◽

Fate Mapping ◽

Stage Of Development ◽

Time Point

Abstract Background Methods based on site-specific recombinases are widely used in studying gene activities in vivo and in vitro. In these studies, constitutively active or inducible variants of these recombinases are expressed under the control of either lineage-specific or ubiquitous promoters. However, there is a need for more advanced schemes that combine these features with possibilities to choose a time point from which lineage tracing starts in an autonomous fashion. For example, the key mammalian germline gatekeeper gene Oct4 (Pou5f1) is expressed in the peri-implantation epiblast which gives rise to all cells within embryos. Thus the above techniques are hardly applicable to Oct4 tracing past the epiblast stage, and the establishment of genetic tools addressing such a limitation is a highly relevant pursuit. Methods The CRISPR/Cas9 tool was used to manipulate the genome of mouse embryonic stem cells (ESCs), and various cell culture technics—to maintain and differentiate ESCs to neural cell, lentivirus-based reprogramming technique—to generate induced pluripotent stem cells (iPSCs). Results In this paper, we have developed a two-component genetic system (referred to as O4S) that allows tracing Oct4 gene activity past the epiblast stage of development. The first component represents a knock-in of an ubiquitous promoter-driven inducible Cre, serving as a stop signal for downstream tdTomato. Upon activation of Cre activity with 4-hydroxytamoxifen (4-OHT) at any given time point, the recombinase excises a stop signal and poses the second component of the system—the FlpO recombinase, knocked into 3’UTR of Oct4, to be expressed upon activation of the latter gene. Oct4-driven expression of FlpO, in turn, triggers the tdTomato expression and thus, permanently marks Oct4+ cells and their progeny. We have validated the O4S system in cultured ESCs and shown that it is capable, for example, to timely capture an activation of Oct4 gene during the reprogramming of somatic cells into iPSCs. Conclusions The developed O4S system can be used to detect Oct4 activation event, both permanent and transient, in somatic cell types outside the germline. The approach can be equally adjusted to other genes, provided the first component of the system is placed under transcriptional control of these genes, thus, making it a valuable tool for cell fate mapping in mice.

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Genetic lineage tracing with multiple DNA recombinases: A user's guide for conducting more precise cell fate mapping studies

Journal of Biological Chemistry ◽

10.1074/jbc.rev120.011631 ◽

2020 ◽

Vol 295 (19) ◽

pp. 6413-6424 ◽

Cited By ~ 6

Author(s):

Kuo Liu ◽

Hengwei Jin ◽

Bin Zhou

Keyword(s):

Cell Fate ◽

Cell Biology ◽

Lineage Tracing ◽

Cell Labeling ◽

Genetic Lineage ◽

Fate Mapping ◽

Technical Limitation ◽

Biological Phenomena ◽

Recombination System ◽

Genetic Lineage Tracing

Site-specific recombinases, such as Cre, are a widely used tool for genetic lineage tracing in the fields of developmental biology, neural science, stem cell biology, and regenerative medicine. However, nonspecific cell labeling by some genetic Cre tools remains a technical limitation of this recombination system, which has resulted in data misinterpretation and led to many controversies in the scientific community. In the past decade, to enhance the specificity and precision of genetic targeting, researchers have used two or more orthogonal recombinases simultaneously for labeling cell lineages. Here, we review the history of cell-tracing strategies and then elaborate on the working principle and application of a recently developed dual genetic lineage-tracing approach for cell fate studies. We place an emphasis on discussing the technical strengths and caveats of different methods, with the goal to develop more specific and efficient tracing technologies for cell fate mapping. Our review also provides several examples for how to use different types of DNA recombinase–mediated lineage-tracing strategies to improve the resolution of the cell fate mapping in order to probe and explore cell fate–related biological phenomena in the life sciences.

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