基于转录组测序的蓖麻毒素诱导巨噬细胞焦亡中氧化应激相关基因及环状RNA表达谱分析

doi:10.13481/j.1671-587X.20250417

Abstract

Abstract:

Objective To analyze and identify the expression profiles of oxidative stress-related genes and circular RNAs （circRNAs） in ricin toxin （RT）-induced pyroptosis of mouse mononuclear macrophages （RAW264.7） using transcriptome sequencing and bioinformatics technology， and to preliminarily analyze their potential functions. Methods The macrophages （RAW264.7 cells） were treated with RT to establish a cell pyroptosis model and divided into control group， 40 μg·L^-1 RT group， and 80 ng/mL RT group. Transmission electron microscope （TEM） was used to observe the morphology of the RAW264.7 cells in various groups； Western blotting method was used to detect the expression levels of the pyroptosis pathway-related proteins in the cells in various groups； 80 μg·L^-1 RT was selected for subsequent experiments. Transcriptome sequencing （RNA-Seq） was performed to obtain the circRNA and mRNA expression profiles in the RAW264.7 cells in control group and RT-treated group， followed by bioinformatics analysis. Results Compared with control group， the cells in 40 and 80 μg·L^-1 RT groups underwent morphological changes； the cells in RT groups showed obvious pyroptosis-like morphological changes， characterized by significant swelling of dying cells and the appearance of characteristic large bubbles on the plasma membrane. Compared with control group， the expression level of gasdermin DN-terminal fragment （GSDMD-N） protein in 40 and 80 μg·L^-1 RT groups was increased （P<0.05）； compared with 40 μg·L^-1 RT group， the expression level of GSDMD-N protein in the cells in 80 μg·L^-1 RT group was increased （P<0.05）； therefore， the subsequent experiments used the RT concentration of 80 μg·L^-1. A total of 2930 differentially expressed messenger RNAs （mRNAs） and 24 differentially expressed circRNAs were identified. The constructed circRNA-microRNA （miRNA）-mRNA competing endogenous RNA （ceRNA） regulatory network consisted of 7 circRNAs， 12 miRNAs and 13 mRNAs. Gene Ontology （GO） functional enrichment analysis showed that in biological process （BP）， the functions regulated by differentially expressed genes mainly included immune response and oxidative stress response； in cellular component （CC）， differentially expressed genes were mainly localized to the external side of plasma membrane and cell leading edge； in molecular function （MF）， they were mainly involved in transporter transmembrane activity and hormone receptor binding. Kyoto Encyclopedia of Genes and Genomes （KEGG） pathway enrichment analysis showed that differentially expressed genes were mainly enriched in Toll-like receptor signaling pathway， Forkhead box O（FoxO） signaling pathway and nuclear factor kappa-light-chain-enhancer of activated B cells （NF-κB） signaling pathway. In the protein-protein interaction （PPI） network， the top 10 hub genes with the highest connectivity were screened by CytoHubba， including matrix metalloproteinase 9 （MMP9）， superoxide dismutase 2 （SOD2）， and v-src sarcoma viral oncogene homolog （Src）. Conclusion The expression profiles of oxidative stress-related genes and circRNAs in RAW264.7 cells are altered after RT treatment. The screened differentially expressed circRNAs and mRNAs may serve as potential targets to regulate RT-induced pyroptosis in RAW264.7 cells through oxidative stress pathways.

Key words: Ricin toxin, Pyroptosis, Oxidative stress, Circular RNA, Competing endogenous RNA

CLC Number:

R392.1

Nan LU,Mingxin DONG,Lei YU,Chengbiao SUN,Yan WANG,Na XU,Wensen LIU,Shumin GE. Transcriptome sequencing-based expression profiling of oxidative stress-related genes and circRNAs in ricin toxin-induced macrophage pyroptosis[J].Journal of Jilin University(Medicine Edition), 2025, 51(4): 1007-1018.

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References 32

[1]	徐义峰，柯诗文，李可可，等. 氧化应激和免疫浸润在特发性肺纤维化中的作用及中药防治研究［J］. 中国免疫学杂志， 2024， 40（10）： 2108-2115.
[2]	于馨雅，申元英，郭乐. Nrf2/HO-1通路在氧化应激和炎性反应中的作用［J］. 医学研究杂志， 2023， 52（7）： 19-22.
[3]	ZHANG T， WU D M， LUO P W， et al. CircNEIL3 mediates pyroptosis to influence lung adenocarcinoma radiotherapy by upregulating PIF1 through miR-1184 inhibition［J］. Cell Death Dis， 2022， 13（2）： 167.
[4]	LI M Z， HUA Q H， SHAO Y T， et al. Circular RNA circBbs9 promotes PM_2.5-induced lung inflammation in mice via NLRP3 inflammasome activation［J］. Environ Int， 2020， 143： 105976.
[5]	王俊虹，吴绘，魏茂提. BALB/c小鼠免疫重组蓖麻毒素B链蛋白的免疫机制研究［J］. 中国免疫学杂志， 2016， 32（12）： 1758-1760.
[6]	TESH V L. The induction of apoptosis by Shiga toxins and ricin［J］. Curr Top Microbiol Immunol， 2012， 357： 137-178.
[7]	IORDANOV M S， PRIBNOW D， MAGUN J L， et al. Ribotoxic stress response： activation of the stress-activated protein kinase JNK1 by inhibitors of the peptidyl transferase reaction and by sequence-specific RNA damage to the alpha-sarcin/ricin loop in the 28S rRNA［J］. Mol Cell Biol， 1997， 17（6）： 3373-3381.
[8]	XU Y X， DONG M X， SUN C B， et al. Caspase-3/Gasdermin E-mediated pyroptosis contributes to Ricin toxin-induced inflammation［J］. Toxicol Lett， 2024， 396： 19-27.
[9]	JOMOVA K， RAPTOVA R， ALOMAR S Y， et al. Reactive oxygen species， toxicity， oxidative stress， and antioxidants： chronic diseases and aging［J］. Arch Toxicol， 2023， 97（10）： 2499-2574.
[10]	WEN S， LI S L， LI L L， et al. circACTR2： a novel mechanism regulating high glucose-induced fibrosis in renal tubular cells via pyroptosis［J］. Biol Pharm Bull， 2020， 43（3）： 558-564.
[11]	POLISENO L， SALMENA L， ZHANG J W， et al. A coding-independent function of gene and pseudogene mRNAs regulates tumour biology［J］. Nature， 2010， 465（7301）： 1033-1038.
[12]	LATZ E， XIAO T S， STUTZ A. Activation and regulation of the inflammasomes［J］. Nat Rev Immunol， 2013， 13（6）： 397-411.
[13]	KLOTZ L O. Redox regulation of FoxO activity： impact on micronutrient homeostasis［J］. Free Radic Biol Med， 2015， 86： S13.
[14]	LIANG D， WANG Q L， ZHANG W B， et al. JAK/STAT in leukemia： a clinical update［J］. Mol Cancer， 2024， 23（1）： 25.
[15]	WANG J J， FU D D， SENOUTHAI S， et al. Critical roles of PI3K/Akt/NF-κB survival axis in angiotensin II-induced podocyte injury［J］. Mol Med Rep， 2019， 20（6）： 5134-5144.
[16]	LOU W Y， DING B S， WANG J N， et al. The involvement of the hsa_circ_0088494-miR-876-3p-CTNNB1/CCND1 axis in carcinogenesis and progression of papillary thyroid carcinoma［J］. Front Cell Dev Biol， 2020， 8： 605940.
[17]	ZHU L N， YANG T， LI L J， et al. TSC1 controls macrophage polarization to prevent inflammatory disease［J］. Nat Commun， 2014， 5： 4696.
[18]	CHEN F J， XING Y F， CHEN Z J， et al. Competitive adsorption of microRNA-532-3p by circular RNA SOD2 activates Thioredoxin Interacting Protein/NLR family pyrin domain containing 3 pathway and promotes pyroptosis of non-alcoholic fatty hepatocytes［J］. Eur J Med Res， 2024， 29（1）： 250.
[19]	SLACK S， BATTAGLIA A， CIBERT-GOTON V， et al. EphrinB2 induces tyrosine phosphorylation of NR2B via Src-family kinases during inflammatory hyperalgesia［J］. Neuroscience， 2008， 156（1）： 175-183.
[20]	TANG J， XIAO Y Z， LIN G X， et al. Tyrosine phosphorylation of NLRP3 by the Src family kinase Lyn suppresses the activity of the NLRP3 inflammasome［J］. Sci Signal， 2021， 14（706）： eabe3410.
[21]	张晓文，张婵，张迪，等. 川楝素通过MMP9抑制肾癌细胞的增殖、迁移和侵袭［J］. 中国免疫学杂志， 2023， 39（4）： 793-798， 803.
[22]	胡佳，张海霞，苏婉露，等. 间充质干细胞对2型糖尿病小鼠糖尿病肾病进展的影响及其机制［J］. 解放军医学杂志， 2023， 48（4）： 383-393.
[23]	LI M X， LIN Y F， PALCHIK G A， et al. The catalytic subunit of DNA-dependent protein kinase is required for cellular resistance to oxidative stress independent of DNA double-strand break repair［J］. Free Radic Biol Med， 2014， 76： 278-285.
[24]	ERTTMANN S F， HÄRTLOVA A， SLONIECKA M， et al. Loss of the DNA damage repair kinase ATM impairs inflammasome-dependent anti-bacterial innate immunity［J］. Immunity， 2016， 45（1）： 106-118.
[25]	WILLIAMSON M R， SHUTTLEWORTH A， CANFIELD A E， et al. The role of endothelial cell attachment to elastic fibre molecules in the enhancement of monolayer formation and retention， and the inhibition of smooth muscle cell recruitment［J］. Biomaterials， 2007， 28（35）： 5307-5318.
[26]	NGUYEN A D， ITOH S， JENEY V， et al. Fibulin-5 is a novel binding protein for extracellular superoxide dismutase［J］. Circ Res， 2004， 95（11）： 1067-1074.
[27]	SCHLUTERMAN M K， CHAPMAN S L， KORPANTY G， et al. Loss of fibulin-5 binding to beta1 integrins inhibits tumor growth by increasing the level of ROS［J］. Dis Model Mech， 2010， 3（5/6）： 333-342.
[28]	MAJMUNDAR A J， WONG W J， SIMON M C. Hypoxia-inducible factors and the response to hypoxic stress［J］. Mol Cell， 2010， 40（2）： 294-309.
[29]	SEMENZA G L. Hypoxia-inducible factors in physiology and medicine［J］. Cell， 2012， 148（3）： 399-408.
[30]	XUE X， RAMAKRISHNAN S， ANDERSON E， et al. Endothelial PAS domain protein 1 activates the inflammatory response in the intestinal epithelium to promote colitis in mice［J］. Gastroenterology， 2013， 145（4）： 831-841.
[31]	STRANG K H， GOLDE T E， GIASSON B I. MAPT mutations， tauopathy， and mechanisms of neurodegeneration［J］. Lab Investig， 2019， 99（7）： 912-928.
[32]	BRADFORD X， FERNANDES H J R， SNOWDEN S G. Changes in oxidised phospholipids in response to oxidative stress in Microtubule-associated protein tau （MAPT） mutant dopamine neurons［J］. Antioxidants （Basel）， 2024， 13（5）： 508.

Gene	Correlation description	Score
Mmp9	Matrix metallopeptidase 9	10
Src	Sarcoma	8
Atm	Ataxia telangiectasia mutated	8
Sod2	Superoxide-dimutase-2	8
Mapt	Microtubule-associated protein	4
Epas1	Endothelial PAS domain protein 1	4
Tsc1	Tuberous sclerosis	2
Fbln5	Fibulin-5	2

Transcriptome sequencing-based expression profiling of oxidative stress-related genes and circRNAs in ricin toxin-induced macrophage pyroptosis

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