拉曼光谱技术在单细胞表型检测与分选中的应用进展

王喜先; 孙晴; 刁志钿; 徐健; 马波

doi:10.12211/2096-8280.2022-043

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拉曼光谱技术在单细胞表型检测与分选中的应用进展

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- 拉曼光谱技术在单细胞表型检测与分选中的应用进展
- Advances with applications of Raman spectroscopy in single-cell phenotype sorting and analysis
- 合成生物学 2023年4卷第1期页码：204-224
- 作者机构：
  
  中国科学院青岛生物能源与过程研究所单细胞中心，山东青岛 266101
- 作者简介：
  
  [ "王喜先（1988—），男，博士，副研究员，硕士生导师。研究方向为微流控、高通量拉曼流式分选技术等。E-mail：wangxx@qibebt.ac.cn" ]
  [ "马波（1976—），男，博士，研究员，博士生导师。研究方向为单细胞关键技术与仪器、微流控技术等。E-mail：mabo@qibebt.ac.cn" ]
- 基金信息：
  
  国家重点研发计划“合成生物学”重点专项(2018YFA090290);天津市合成生物技术创新能力提升行动项目(TSBICIP-PTJS-003-05)
- DOI：10.12211/2096-8280.2022-043
  中图分类号： Q939.97
- 收稿：2022-08-03，
  
  修回：2022-09-12，
  
  纸质出版：2023-02-28
- 稿件说明：
移动端阅览
王喜先，孙晴，刁志钿，徐健，马波. 拉曼光谱技术在单细胞表型检测与分选中的应用进展［J］. 合成生物学， 2023， 4（1）： 204-224

WANG Xixian， SUN Qing， DIAO Zhidian， XU Jian， MA Bo. Advances with applications of Raman spectroscopy in single-cell phenotype sorting and analysis［J］. Synthetic Biology Journal， 2023， 4（1）： 204-224
王喜先，孙晴，刁志钿，徐健，马波. 拉曼光谱技术在单细胞表型检测与分选中的应用进展［J］. 合成生物学， 2023， 4（1）： 204-224 DOI： 10.12211/2096-8280.2022-043.

WANG Xixian， SUN Qing， DIAO Zhidian， XU Jian， MA Bo. Advances with applications of Raman spectroscopy in single-cell phenotype sorting and analysis［J］. Synthetic Biology Journal， 2023， 4（1）： 204-224 DOI： 10.12211/2096-8280.2022-043.

摘要

基因组测序、编辑与合成技术日新月异，推动了基因型“设计”和“合成”能力的突飞猛进，同时也使人工细胞的表型检测成为合成生物学发展的瓶颈之一。对于细胞功能的快速测试与评价，单细胞分析技术具有重要意义与前景，但理想的解决方案需要具备活体无损、非标记式、提供全景式表型、能分辨复杂功能、快速高通量且低成本、能与组学分析联动等特征。拉曼光谱技术具备上述所有特征，能够提供单细胞的化学成分组成及分子结构等信息，是一种高效的单细胞表型识别技术。本文首先概述了拉曼组概念和基于拉曼组的细胞功能表型识别，包括代谢产物定性和定量、底物代谢和互作表征、细胞种类和状态鉴定以及环境应激检测等；其次，根据拉曼信号的分类、拉曼信号检测模式和目标细胞分选策略，对现有的拉曼分选平台及其在细胞表型分选中的应用进行分析总结；最后，对单细胞拉曼光谱技术在合成细胞表型检测与分选面临的问题、潜在解决策略进行了探讨和展望。单细胞拉曼光谱技术不仅为细胞工厂的高通量、全景式表型检测与筛选提供了全新的解决方案，还将推动“单细胞精度的表型组-功能基因组”作为一种新的生物大数据类型，服务于“数据科学”驱动下的合成生物技术。

Abstract

In synthetic biology

methodological innovations in sequencing

editing and synthesis of genes and whole genomes have resulted in unprecedented development in "design and manufacturing of genotypes". On the other hand

"testing of cellular phenotypes and functions" has increasingly become one of major bottlenecks. Single-cell technologies have tremendous impacts and potentials in rapid testing of cellular phenotypes and functions. However

such single-cell methods should allow non-invasive live-cell probing

be label-free

provide landscape-like phenotype sorting

distinguish complex functions

operate with high speed

sufficient throughput and low-cost

and finally

be able to integrate with downstream omics analysis. Raman spectroscopy has all the above features

and can provide information on the chemical composition and molecular structure of single cells

making it an efficient single-cell phenotyping technology. In this review

we first introduce the concept of Ramanome and Ramanome-based phenotyping technologies

including detecting and quantifying products

measuring profiles of substrates and metabolites

discriminating cell types or states

and characterizing stress response and modeling environmental changes. We then summarize the development of existing Raman-activated cell sorting (RACS) platforms in phenotyping and sorting of cell factories such as including spontaneous Raman

resonance Raman

and coherent Raman

the modes for acquiring Raman signals including static modes on dry slice and in liquid as well

flow modes by trap-free and trap-and-release manners

and principles for target cells sorting including Ejection by pulsed laser

dragging by optical tweezer

and sorting by microfluidics operation and droplets. We also highlight the applications of different RACS platforms

including the sorting of carotenoid-producing yeast and cyanobacteria cells

astaxanthin (AXT)-hyperproducing microalgae cells

triacylglycerol (TAG)-producing yeast cells

etc. Finally

challenges with single cell Raman spectroscopy (SCRS) in the phenotyping and sorting of synthetic cells and their perspectives are outlined and discussed. We propose that SCRS will bridge phenotypes and genotypes in science and technologies through coupling with downstream high-throughput cell sorting and omics profiling. This bridge will lead to novel and creative solutions to high-throughput

landscape-like testing and screening of synthetic cells. Moreover

it will fulfill the promise of Raman spectroscopy-enabled single-cell "phenome-genome" as a new type of biological big-data

and accelerate the pace of "data-driven" synthetic biology.

关键词

Keywords

references

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