多肽功能化亲和微球的制备与线粒体高选择性分离分析

doi:10.3724/SP.J.1123.2024.01013

摘要/Abstract

摘要：

线粒体作为细胞物质和能量代谢的主要细胞器,在维持细胞生理稳态中发挥关键作用,进而与诸多疾病的发生发展密切相关。从高度复杂的细胞组分中特异性分离分析线粒体,对于其功能解析、分子机制研究和化学干预具有重要意义,但仍存在困难与挑战。本研究以靶向多肽为识别元件,开展了线粒体亲和分离新材料的设计、合成和分析应用研究。以与线粒体膜具有特异性相互作用的线粒体穿透肽(mitochondrial penetrating peptide, MPP)为识别元件,通过引入空间手臂分子,设计合成了多肽亲和配基。以表面富含醛基的聚合物基质微球(matrix beads, MB)为亲和基质,建立了基于胺甲基化反应的多肽功能化亲和微球制备方法,该方法具有修饰反应条件温和、配基修饰效率高的特点。将所构建的亲和微球MB@MPP用于细胞破碎液中线粒体的直接分离,实现了完整线粒体的快速、高选择性和无损捕获。与商品化分离试剂盒相比,MB@MPP捕获的线粒体中标志蛋白富集效率更高,纯度更好。基于多肽功能化微球对线粒体高选择性分离能力,以线粒体代谢所需关键辅酶的前体小分子色氨酸和核黄素为目标,进一步建立了基于液相色谱-串联质谱的线粒体中活性小分子的分析检测方法,实现了激酶激动剂刺激前后线粒体中活性小分子含量及其动态变化分析,为线粒体功能解析和相关疾病分子机制研究提供了方法基础。

关键词: 多肽, 亲和识别, 分离材料, 线粒体, 复杂体系, 液相色谱-串联质谱

Abstract:

Mitochondria perform various metabolic processes that significantly affect cell differentiation, proliferation, signal transduction, and programmed cell death. The disruption of mitochondrial bioenergetic and metabolic functions is closely related to many disorders. The specific isolation and purification of intact, high-purity, and functional mitochondria are central to the understanding of their mechanism of action but remain challenging tasks.

In this study, a mitochondrial penetrating peptide (MPP) with the sequence FrFKFrFK(Ac) was used as a mitochondrial recognition motif to construct a peptide-guided affinity separation material. The multiple aromatic phenylalanine (F) residues in this amphiphilic peptide can confer lipophilicity to the mitochondrial membrane, whereas the basic residues (D-arginine and lysine) render the MPP surface positively charged, thereby promoting the binding of negatively charged mitochondria. After the derivatization of the N terminal of MPP with an oligoglycine spacer, the peptide ligands were conjugated to matrix beads (MB) with surface aldehyde functional groups. Peptide functionalization was performed via a condensation reaction between the amino group in the peptide ligand and the aldehyde group on the beads. The generated Schiff bases were reduced, affording stable covalent bonds. The dense and stable functionalization of the beads with the mitochondria-targeting peptides was demonstrated using high performance liquid chromatography (HPLC), zeta potential assay, and scanning electron microscopy (SEM). The immobilization efficiency of the peptide ligands was 1.47 μmol/g, and the surface potential of MB@MPP was 11 mV. MB@MPP was used for the direct isolation of mitochondria after cell homogenization. As observed by SEM, mitochondria with a cross-sectional diameter of 500 nm were efficiently captured on the MB@MPP surface. Because the mitochondrial membrane potential is an important marker of mitochondrial function and the driving force behind the staining of mitochondria with Mito Tracker dyes, the specific binding and separation of fluorescent mitochondria from the cell samples revealed that the proposed MB@MPP-based isolation approach can keep mitochondria intact and retain their functions. Western blot assays were employed to characterize the protein markers of the mitochondria (citrate synthase (CS) and voltage-dependent anion channel protein (VDAC)) and cytoplasmic protein (vinculin), and examine the integrity and purity of the captured mitochondria. The results showed that the lysates released from MB@MPP had high CS and VDAC contents. By contrast, vinculin, which is highly abundant in whole-cell lysates, was barely detected in the lysates from MB@MPP. These results suggest that MB@MPP isolates mitochondria with high affinity, specificity, and antifouling ability by using the targeting peptide as the capture handle. A comparison with a commercial mitochondrial isolation kit demonstrated that MB@MPP can separate mitochondria with higher CS and VDAC abundance and purity. Given the superior separation performance of MB@MPP, the molecular profiles of the isolated mitochondria under stress were subjected to further analysis of their molecular profiles under stress.

A liquid chromatography-tandem mass spectrometry (LC-MS/MS) method was established to detect tryptophan (Trp) and riboflavin in the mitochondria. Quantification was performed in multiple-reaction monitoring (MRM) mode. Owing to the high purity of the mitochondria, the Trp and riboflavin contents were determined to be 265 and 0.67 nmol/mg, respectively. The metabolic response of mitochondria to external stimuli was further examined using acadesine, an adenosine 5'-monophosphate (AMP)-activated protein kinase activator with a wide range of metabolic effects, to treat cells. After cell homogenization, MB@MPP was used to separate the mitochondria from the cell samples with and without acadesine treatment, followed by LC-MS/MS analysis. The quantification results demonstrated that acadesine induced a 14% upregulation of Trp content in the mitochondria. By contrast, the riboflavin content decreased to 0.48 nmol/mg, which is 72% of that in untreated mitochondria. The changes in Trp and riboflavin contents could influence their metabolic pathways and, thus, the levels of their metabolites, such as nicotinamide adenine dinucleotide, flavin mononucleotide, and flavin adenine dinucleotide, which are essential coenzymes in mitochondria. Peptide-functionalized affinity microbeads with high affinity and specificity for mitochondria are promising for the efficient isolation of high-quality mitochondria, and offer a useful tool for understanding the complicated functions and dynamics of this unique organelle.

Key words: peptide, affinity recognition, separation materials, mitochondria, complicated systems, liquid chromatography-tandem mass spectrometry (LC-MS/MS)

中图分类号:

O658

陈建, 徐坤, 高涵, 赵睿, 黄嫣嫣. 多肽功能化亲和微球的制备与线粒体高选择性分离分析[J]. 色谱, 2024, 42(6): 555-563.

CHEN Jian, XU Kun, GAO Han, ZHAO Rui, HUANG Yanyan. Preparation of peptide-functionalized affinity materials for the highly specific capture and analysis of mitochondria[J]. Chinese Journal of Chromatography, 2024, 42(6): 555-563.

图/表 6

表 1 Trp和核黄素的保留时间和质谱参数

Table 1 Retention times and MS parameters of tryptophan and riboflavin

Compound	Retention time/min	Precursor ion (m/z)	Product ion (m/z)	CE/eV
Tryptophan	2.74	205.0	188.1^*	10
			146.1	19
			118.1	26
Riboflavin	2.79	377.0	243.0^*	24
			198.1	40
			172.7	40

图 1 (a)多肽功能化亲和微球的构建示意图及其(b)用于线粒体靶向分离分析流程图

Fig. 1 (a) Schematic illustration of the synthetic process of peptide-functionalized affinity beads and (b) their application to the specific separation of mitochondria from complex cell samples

图 2 寡聚甘氨酸手臂衍生后的线粒体靶向多肽MPP的(a)HPLC图和(b)二级质谱图

Fig. 2 (a) HPLC chromatogram and (b) MS/MS characterization of oligoglycine-derived MPP after purification

图 3 (a)RP-HPLC表征线粒体靶向多肽配基在MB微球上的修饰量,线粒体靶向多肽修饰前后微球的(b)SEM表征和(c)表面电荷表征(n=3)

Fig. 3 (a) RP-HPLC analysis of the modification efficie- ncy of the mitochondria-targeting peptide on MB, (b) SEM and (c) zeta potential characterization of MB and MB@MPP (n=3)

图 4 (a)SEM和(b)共聚焦激光扫描显微镜表征MB@MPP 对线粒体的特异性捕获能力,(c)免疫印迹法表征细胞破碎液、商品化试剂盒提取线粒体和MB@MPP捕获线粒体中的蛋白,(d)根据图 4c中的免疫印迹结果,计算细胞破碎液、商品化试剂盒提取线粒体和MB@MPP捕获线粒体中线粒体标志蛋白的相对含量

Fig. 4 (a) SEM and (b) confocal laser scanning micros- copic observation of mitochondria captured by MB@MPP, (c) Western blot analysis of vinculin, citrate synthase (CS), and voltage-dependent anion channel protein (VDAC) in various samples, (d) comparison of the relative contents of mitochondria marker proteins with and without isolation based on the Western blot results in (c) In (c), vinculin is used as the reference. Statistical analysis was performed using Student’s t-test, * P<0.05 (n=4).

图 5 (a)Trp和核黄素的MRM色谱图,(b)药物分子阿卡地辛处理前后,HepG2细胞的线粒体中Trp和核黄素含量变化

Fig. 5 (a) MRM chromatograms of Trp and riboflavin, (b) Trp and riboflavin contents in the mitochondria of HepG2 cells with and without acadesine treatment Statistical analysis was performed using Student’s t-test, ** P<0.01, * P<0.05 (n=3).

参考文献

[1]	Shen K, Pender C L, Bar-Ziv R, et al. Annu Rev Cell Dev Biol, 2022, 38: 179
[2]	Harrington J S, Ryter S W, Plataki M, et al. Physiol Rev, 2023, 103(4): 2349
[3]	Bock F J, Tait S W G. Nat Rev Mol Cell Biol, 2020, 21(2): 85
[4]	Bonora M, Wieckowski M R, Sinclair D A, et al. Nat Rev Cardiol, 2019, 16(1): 33
[5]	Huang Y Y, Zhang G X, Zhao R, et al. ChemMedChem, 2020, 15(23): 2220
[6]	Gorman G S, Chinnery P F, DiMauro S, et al. Nat Rev Dis Primers, 2016, 2: 16080
[7]	Sainero-Alcolado L, Liaño-Pons J, Ruiz-Pérez M V, et al. Cell Death Differ, 2022, 29(7): 1304
[8]	Melin F, Hellwig P. Chem Rev, 2020, 120(18): 10244
[9]	Huang Y Y, You X, Wang L N, et al. Angew Chem Int Ed, 2020, 59(25): 10042
[10]	Reinders J, Zahedi R P, Pfanner N, et al. J Proteome Res, 2006, 5(7): 1543
[11]	Wieckowski M R, Giorgi C, Lebiedzinska M, et al. Nat Protoc, 2009, 4(11): 1582
[12]	Eubel H, Lee C P, Kuo J, et al. Plant J, 2007, 52(3): 583
[13]	Yang J S, Lee J Y, Moon M H, et al. Anal Chem, 2015, 87(12): 6342
[14]	de Mello N P, Fecher C, Pastor A M, et al. Nat Protoc, 2023, 18(7): 2181
[15]	Chen W W, Freinkman E, Wang T, et al. Cell, 2016, 166(5): 1324
[16]	Doerr A. Nat Methods, 2016, 13: 899
[17]	Chang M M, Wang Q Q, Liu X Y, et al. Anal Chem, 2021, 93(32): 11099
[18]	Ahier A, Dai C Y, Tweedie A, et al. Nat Cell Biol, 2018, 20(3): 352
[19]	Saw P E, Xu X D, Kim S H, et al. Acc Chem Res, 2021, 54(18): 3576
[20]	Wang L, Wang N X, Zhang W P, et al. Signal Transduct Target Ther, 2022, 7(1): 48
[21]	Huang Y Y, Jin Y L, Zhao R. Sci China Chem, 2016, 59: 1250
[22]	Zhong H F, Huang Y Y, Jin Y L, et al. Chinese Journal of Chromatography, 2021, 39(1): 26
[22]	钟卉菲, 黄嫣嫣, 金钰龙, 等. 色谱, 2021, 39(1): 26
[23]	Li Y M, Gao H, Jin Y L, et al. Anal Bioanal Chem, 2023, 415(18): 4079
[24]	Wang W Z, Wang Z H, Bu X L, et al. Adv Healthc Mater, 2015, 4(18): 2802
[25]	Shi Z Q, Zhang X C, Yang X J, et al. Adv Mater, 2023, 35(33): e2302560
[26]	Zhong H F, Yuan C W, He J Y, et al. Anal Chem, 2021, 93: 9778
[27]	Suwatthanarak T, Thiodorus I A, Tanaka M, et al. Lab Chip, 2021, 21: 597
[28]	Xu K, Jin Y L, Huang Y Y, et al. Chinese Journal of Chromatography, 2020, 38(3): 324
[28]	徐坤, 金钰龙, 黄嫣嫣, 等. 色谱, 2020, 38(3): 324
[29]	Hoye A T, Davoren J E, Wipf P, et al. Acc Chem Res, 2008, 41(1): 87
[30]	Schumacher M, Habibović P, van Rijt S. ACS Appl Mater Interfaces, 2022, 14(4): 4959
[31]	Brambilla D, Sola L, Ferretti A M, et al. Anal Chem, 2021, 93(13): 5476
[32]	Pérez J, Dulay S, Mir M, et al. Biosens Bioelectron, 2018, 121: 54
[33]	Minhas P S, Liu L, Moon P K, et al. Nat Immunol, 2019, 20(1): 50
[34]	You J, Pan X, Yang C, et al. Metab Eng, 2021, 68: 46
[35]	Martínez Reyes I, Cardona L R, Kong H, et al. Nature, 2020, 585(7824): 288
[36]	Jäger S, Handschin C, St-Pierre J, et al. Proc Natl Acad Sci U S A, 2007, 104(29): 12017
[37]	Komen J C, Thorburn D R. Br J Pharmacol, 2014, 171(8): 1818