|
Defect-Buffering Cellular Plasticity Increases Robustness of Metazoan Embryogenesis
Long Xiao, Duchangjiang Fan, Huan Qi, Yulin Cong, Zhuo Du
Cell Systems
Abstract
Developmental processes are intrinsically robust so as to preserve a normal-like state in response to genetic and environmental fluctuations. However, the robustness and potential phenotypic plasticity of individual developing cells under genetic perturbations remain to be systematically evaluated. Using large-scale gene perturbation, live imaging, lineage tracing, and single-cell phenomics, we quantified the phenotypic landscape of C. elegans embryogenesis in >2,000 embryos following individual knockdown of over 750 conserved genes. We observed that cellular genetic systems are not sufficiently robust to single-gene perturbations across all cells; rather, gene knockdowns frequently induced cellular defects. Dynamic phenotypic analyses revealed many cellular defects to be transient, with cells exhibiting phenotypic plasticity that serves to alleviate, correct, and accommodate the defects. Moreover, potential developmentally related cell modules may buffer the phenotypic effects of individual cell position changes. Our findings reveal non-negligible contributions of cellular plasticity and multicellularity as compensatory strategies to increase developmental robustness.
|
论文编号: |
DOI:10.1016/j.cels.2022.07.001 |
论文题目: |
Defect-Buffering Cellular Plasticity Increases Robustness of Metazoan Embryogenesis |
英文论文题目: |
Defect-Buffering Cellular Plasticity Increases Robustness of Metazoan Embryogenesis |
第一作者: |
Long Xiao, Duchangjiang Fan, Huan Qi, Yulin Cong, Zhuo Du |
英文第一作者: |
Long Xiao, Duchangjiang Fan, Huan Qi, Yulin Cong, Zhuo Du |
联系作者: |
|
英文联系作者: |
|
外单位作者单位: |
|
英文外单位作者单位: |
|
发表年度: |
2022-07-26 |
卷: |
|
期: |
|
页码: |
|
摘要: |
Developmental processes are intrinsically robust so as to preserve a normal-like state in response to genetic and environmental fluctuations. However, the robustness and potential phenotypic plasticity of individual developing cells under genetic perturbations remain to be systematically evaluated. Using large-scale gene perturbation, live imaging, lineage tracing, and single-cell phenomics, we quantified the phenotypic landscape of C. elegans embryogenesis in >2,000 embryos following individual knockdown of over 750 conserved genes. We observed that cellular genetic systems are not sufficiently robust to single-gene perturbations across all cells; rather, gene knockdowns frequently induced cellular defects. Dynamic phenotypic analyses revealed many cellular defects to be transient, with cells exhibiting phenotypic plasticity that serves to alleviate, correct, and accommodate the defects. Moreover, potential developmentally related cell modules may buffer the phenotypic effects of individual cell position changes. Our findings reveal non-negligible contributions of cellular plasticity and multicellularity as compensatory strategies to increase developmental robustness. |
英文摘要: |
Developmental processes are intrinsically robust so as to preserve a normal-like state in response to genetic and environmental fluctuations. However, the robustness and potential phenotypic plasticity of individual developing cells under genetic perturbations remain to be systematically evaluated. Using large-scale gene perturbation, live imaging, lineage tracing, and single-cell phenomics, we quantified the phenotypic landscape of C. elegans embryogenesis in >2,000 embryos following individual knockdown of over 750 conserved genes. We observed that cellular genetic systems are not sufficiently robust to single-gene perturbations across all cells; rather, gene knockdowns frequently induced cellular defects. Dynamic phenotypic analyses revealed many cellular defects to be transient, with cells exhibiting phenotypic plasticity that serves to alleviate, correct, and accommodate the defects. Moreover, potential developmentally related cell modules may buffer the phenotypic effects of individual cell position changes. Our findings reveal non-negligible contributions of cellular plasticity and multicellularity as compensatory strategies to increase developmental robustness. |
刊物名称: |
Cell Systems |
英文刊物名称: |
Cell Systems |
论文全文: |
|
英文论文全文: |
|
全文链接: |
|
其它备注: |
Long Xiao, Duchangjiang Fan, Huan Qi, Yulin Cong, Zhuo Du. Defect-Buffering Cellular Plasticity Increases Robustness of Metazoan Embryogenesis. Cell Systems. DOI:10.1016/j.cels.2022.07.001 |
英文其它备注: |
|
学科: |
|
英文学科: |
|
影响因子: |
|
第一作者所在部门: |
|
英文第一作者所在部门: |
|
论文出处: |
|
英文论文出处: |
|
论文类别: |
|
英文论文类别: |
|
参与作者: |
|
英文参与作者: |
|
|