In vivo single-cell lineage tracing in zebrafish using high-resolution infrared laser-mediated gene induction microscopy
Autor: | Jianan Y. Qu, Sicong He, Xuesong Li, Yi Wu, Kani Chen, Yingzhu He, Jin Xu, Zilong Wen, Qiqi Sun, Xinwei Shen, Shachuan Feng, Ye Tian |
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Rok vydání: | 2020 |
Předmět: |
0301 basic medicine
Cell type QH301-705.5 Science Cell Population Biology General Biochemistry Genetics and Molecular Biology 03 medical and health sciences lineage tracing 0302 clinical medicine medicine Animals Cell Lineage Blood islands Biology (General) education Zebrafish Hemogenic endothelium education.field_of_study Microscopy Confocal General Immunology and Microbiology General Neuroscience General Medicine biology.organism_classification Stem Cells and Regenerative Medicine heat shock hematopoiesis Tools and Resources Cell biology 030104 developmental biology medicine.anatomical_structure Medicine Single-Cell Analysis Stem cell Developmental biology single-cell labeling 030217 neurology & neurosurgery Developmental Biology |
Zdroj: | eLife eLife, Vol 9 (2020) |
ISSN: | 2050-084X |
Popis: | Heterogeneity broadly exists in various cell types both during development and at homeostasis. Investigating heterogeneity is crucial for comprehensively understanding the complexity of ontogeny, dynamics, and function of specific cell types. Traditional bulk-labeling techniques are incompetent to dissect heterogeneity within cell population, while the new single-cell lineage tracing methodologies invented in the last decade can hardly achieve high-fidelity single-cell labeling and long-term in-vivo observation simultaneously. In this work, we developed a high-precision infrared laser-evoked gene operator heat-shock system, which uses laser-induced CreERT2 combined with loxP-DsRedx-loxP-GFP reporter to achieve precise single-cell labeling and tracing. In vivo study indicated that this system can precisely label single cell in brain, muscle and hematopoietic system in zebrafish embryo. Using this system, we traced the hematopoietic potential of hemogenic endothelium (HE) in the posterior blood island (PBI) of zebrafish embryo and found that HEs in the PBI are heterogeneous, which contains at least myeloid unipotent and myeloid-lymphoid bipotent subtypes. eLife digest Animals begin life as a single cell that then divides to become a complex organism with many different types of cells. Every time a cell divides, each of its two daughter cells can either stay the same type as their parent or adopt a different identity. Once a cell acquires an identity, it usually cannot ‘go back’ and choose another. Eventually, this process will produce daughter cells with the identity of a specific tissue or organ and that cannot divide further. Multipotent cells are cells that can produce daughter cells with different identities, including other multipotent cells. These cells can usually give rise to different cell types in a specific organ, and generate more cells to replace any cells that die in that organ. Tracking the cells descended from a multipotent cell in a specific tissue can provide information about how the tissue develops. Hemogenic endothelium cells produce the multipotent cells that give rise to two types of white blood cells: myeloid cells and lymphoid cells. Myeloid cells include innate immune cells that protect the body from infection non-specifically; while lymphoid cells include T cells and B cells with receptors that detect specific bacteria or viruses. It remains unclear whether each of these two cell types originate from a single population of hemogenic endothelium cells or from two distinct subpopulations. He et al. have now developed a new optical technique to label a single hemogenic endothelium cell in a zebrafish and track the cell and its descendants. This method revealed that there are at least two distinct populations of hemogenic endothelium cells. One of them can give rise to both lymphoid and myeloid cells, while the other can only give rise to myeloid cells. These findings shed light on the mechanisms of blood formation, and potentially could provide useful tools to study the development of diseases such as leukemia. Additionally, the single-cell labeling technology He et al. have developed could be applied to study the development of other tissues and organs. |
Databáze: | OpenAIRE |
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