Molecular communication between red blood cells of different phenotypes during blood storage in mice.

IF 2.5 3区医学 Q2 HEMATOLOGY

Transfusion Pub Date : 2024-08-02 DOI:10.1111/trf.17960

James C Zimring, Ariel M Hay, Monika Dzieciatkowska, Angelo D'Alessandro

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Abstract

Background: The cellular and molecular changes during red blood cell (RBC) storage that affect posttransfusion recovery (PTR) remain incompletely understood. We have previously reported that RBCs of different storage biology cross-regulate each other when stored together (co-storage cross-regulation [CSCR]). However, the mechanism of CSCR is unclear. In the current study, we tested the hypothesis that CSCR involves acquisition of molecular signatures associated with PTR.

Study design and methods: The whole blood compartment of either B6 or FVB mice was biotinylated in vivo prior to blood collection and storage. Bio-B6 or Bio.FVB were stored with RBCs from B6 mice transgenic for green florescent protein (GFP) (B6.GFP). After storage, avidin-magnetic beads were used to simultaneous purify Bio-RBCs (positive selection) and B6.GFPs (negative selection). Isolated populations were analyzed by transfusion to establish PTR, and subjected to metabolomic and proteomic analysis.

Results: B6 RBCs acquired molecular signatures associated with stored FVB RBCs at both the metabolomic and proteomic level including metabolites associated with energy metabolism, oxidative stress regulation, and oxidative damage. Mitochondrial signatures were also acquired by B6 RBCs. Protein signatures acquired by B6 RBCs include proteins associated with vesiculation.

Conclusion: The data presented herein demonstrate the appearance of multiple molecular changes from poor-storing RBCs in good-storing RBCs during co-storage. Whether this is a result of damage causing intrinsic molecular changes in B6 RBCs or if molecules of FVB RBC origin are transferred to B6 RBCs remains unclear. These studies broaden our mechanistic understanding of RBC storage (in particular) and potentially RBC biology (in general).

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小鼠血液储存过程中不同表型红细胞之间的分子交流。

背景：红细胞（RBC）储存过程中影响输血后恢复（PTR）的细胞和分子变化仍不完全清楚。我们以前曾报道过，不同储存生物学特性的红细胞储存在一起时会相互交叉调节（共储存交叉调节 [CSCR]）。然而，CSCR 的机制尚不清楚。在本研究中，我们检验了 CSCR 涉及获得与 PTR 相关的分子特征的假设：研究设计和方法：在血液采集和储存之前，在体内对 B6 或 FVB 小鼠的全血进行生物素化。将 Bio-B6 或 Bio.FVB 与转基因绿色荧光蛋白（GFP）（B6.GFP）的 B6 小鼠的红细胞一起储存。储存后，使用阿维丁磁珠同时纯化 Bio-RBC（阳性选择）和 B6.GFP（阴性选择）。通过输血分析分离群体以建立 PTR，并进行代谢组学和蛋白质组学分析：结果：B6红细胞在代谢组学和蛋白质组学水平上都获得了与储存的FVB红细胞相关的分子特征，包括与能量代谢、氧化应激调节和氧化损伤相关的代谢物。B6 RBC 还获得了线粒体特征。B6 RBC 获得的蛋白质特征包括与水泡化相关的蛋白质：本文提供的数据表明，在共同贮存过程中，贮存能力差的 RBC 在贮存能力好的 RBC 中出现了多种分子变化。这究竟是损伤导致 B6 红细胞发生内在分子变化，还是 FVB 红细胞的分子转移到了 B6 红细胞，目前仍不清楚。这些研究拓宽了我们对 RBC 储存（特别是）以及潜在的 RBC 生物学（一般）的机理认识。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Transfusion 医学-血液学

CiteScore

4.70

自引率

20.70%

发文量

426

审稿时长

1 months

期刊介绍： TRANSFUSION is the foremost publication in the world for new information regarding transfusion medicine. Written by and for members of AABB and other health-care workers, TRANSFUSION reports on the latest technical advances, discusses opposing viewpoints regarding controversial issues, and presents key conference proceedings. In addition to blood banking and transfusion medicine topics, TRANSFUSION presents submissions concerning patient blood management, tissue transplantation and hematopoietic, cellular, and gene therapies.

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