Pick-up Single-cell Proteomic Analysis for Quantifying Up to 3000 Proteins in a Mammalian Cell

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Feb 10

PMID 38341466

Authors

Yu Wang

Zhi-Ying Guan

Shao-Wen Shi

Yi-Rong Jiang

Jie Zhang

Yi Yang

Qiong Wu

Jie Wu

Jian-Bo Chen

Wei-Xin Ying

Qin-Qin Xu

Qian-Xi Fan

Hui-Feng Wang

Li Zhou

Ling Wang

Jin Fang

Jian-Zhang Pan

Qun Fang

Affiliations

Soon will be listed here.

Abstract

The shotgun proteomic analysis is currently the most promising single-cell protein sequencing technology, however its identification level of ~1000 proteins per cell is still insufficient for practical applications. Here, we develop a pick-up single-cell proteomic analysis (PiSPA) workflow to achieve a deep identification capable of quantifying up to 3000 protein groups in a mammalian cell using the label-free quantitative method. The PiSPA workflow is specially established for single-cell samples mainly based on a nanoliter-scale microfluidic liquid handling robot, capable of achieving single-cell capture, pretreatment and injection under the pick-up operation strategy. Using this customized workflow with remarkable improvement in protein identification, 2449-3500, 2278-3257 and 1621-2904 protein groups are quantified in single A549 cells (n = 37), HeLa cells (n = 44) and U2OS cells (n = 27) under the DIA (MBR) mode, respectively. Benefiting from the flexible cell picking-up ability, we study HeLa cell migration at the single cell proteome level, demonstrating the potential in practical biological research from single-cell insight.

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