TREM-1抑制肽LR12对脓毒症小鼠心肌损伤的改善作用及其机制

doi:10.13481/j.1671-587X.20260208

Abstract

Abstract:

Objective To discuss the effect of triggering receptor expressed on myeloid cells-1 （TREM-1） inhibitory peptide LR12 on myocardial injury in the septic mice， and to clarify its possible mechanism. Methods The mouse model of sepsis was established by cecal ligation and puncture （CLP）. Forty male mice were randomly divided into sham operation group， model group， CLP+LR12 control peptide （LR12-scr） group， CLP+LR12 group， and CLP+DNase Ⅰ group， and there were 8 mice in each group. Except for sham operation group， the mice in the other groups underwent CLP to establish the sepsis models， and were intraperitoneally injected with LR12-scr， LR12， and DNase Ⅰ at 1 h after operation， respectively. At 24 h after operation， the status and behavior of the mice in various groups were observed. A small animal ultrasound system was used to detect the cardiac function of the mice in various groups； enzyme-linked immunosorbent assay （ELISA） method was used to detect the levels of creatine kinase isoenzyme-MB （CK-MB）， cardiac troponin I （cTnI）， and inflammatory indicators interleukin-1β （IL-1β）， interleukin-6 （IL-6）， and tumor necrosis factor-α （TNF-α） in serum， as well as the levels of myeloperoxidase （MPO）-DNA and neutrophil elastase （NE）-DNA in myocardium tissue of the mice in various groups； HE staining was used to observe the pathomorphology of myocardium tissue of the mice in various groups； immunofluorescence staining was used to detect the co-expression of lymphocyte antigen 6G （Ly6G） and citrullinated histone H3 （cit-H3） proteins in myocardium tissue of the mice in various groups； Western blotting method was used to detect the expression levels of TREM-1， MPO， NE， and cit-H3 proteins in myocardium tissue of the mice in various groups. Results Compared with sham operation group， the mice in model group were listless， with disordered arrangement of myocardium tissue， and atrophy and deformation of cardiomyocytes； compared with model group， the mental state and myocardium tissue injury of the mice in CLP+LR12 group and CLP+DNase Ⅰ group were significantly improved， while no significant change was observed in CLP+LR12-scr group. The cardiac function detection results showed that compared with sham operation group， the left ventricular ejection fraction （LVEF） and left ventricular fractional shortening （LVFS） of the mice in model group were significantly decreased （P<0.01）； compared with model group， the LVEF and LVFS of the mice in CLP+LR12 group and CLP+DNase Ⅰ group were significantly increased （P<0.01）. The ELISA results showed that compared with sham operation group， the levels of CK-MB， cTnI， IL-1β， IL-6， and TNF-α in serum and the levels of MPO-DNA and NE-DNA in myocardium tissue of the mice in model group were significantly increased （P<0.01）； compared with model group， the levels of CK-MB， cTnI， IL-1β， IL-6， and TNF-α in serum and the levels of MPO-DNA and NE-DNA in myocardium tissue of the mice in CLP+LR12 group and CLP+DNase Ⅰ group were significantly decreased （P<0.01）； no significant changes in the above indicators were observed in CLP+LR12-scr group （P>0.05）. The immunofluorescence staining results showed that compared with sham operation group， the co-expression of Ly6G and cit-H3 proteins in myocardium tissue of the mice in model group was increased； compared with model group， the co-expression of Ly6G and cit-H3 proteins in myocardium tissue of the mice in CLP+LR12 group and CLP+DNase Ⅰ group was decreased. The Western blotting method results showed that compared with sham operation group， the expression levels of TREM-1， MPO， NE， and cit-H3 proteins in myocardium tissue of the mice in model group were significantly increased （P<0.01）； compared with model group， the expression levels of TREM-1， MPO， NE， and cit-H3 proteins in myocardium tissue of the mice in CLP+LR12 group were significantly decreased （P<0.01）， while the expression levels of MPO， NE， and cit-H3 proteins in myocardium tissue of the mice in CLP+DNase Ⅰ group were significantly decreased （P<0.01）， and there was no significant difference in the expression level of TREM-1 protein （P>0.05）. Conclusion TREM-1 inhibitory peptide LR12 can improve the cardiac function and alleviate myocardial inflammation and injury in the septic mice， and its mechanism may be related to inhibiting the formation of neutrophil extracellular traps （NETs）.

Key words: Sepsis, Myocardial injury, Triggering receptor expressed on myeloid cells-1, Neutrophil extracellular trap, LR12

CLC Number:

R542.2

Jinyu LI,Zhonghui LI,Aibin CHENG,Xuan BU,Jing BAI,Jianjun WANG. Improvement effect of TREM-1 inhibitory peptide LR12 on myocardial injury in septic mice and its mechanism[J].Journal of Jilin University(Medicine Edition), 2026, 52(2): 366-374.

Figures/Tables 7

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References 29

[1]	BURN G L， FOTI A， MARSMAN G， et al. The neutrophil［J］. Immunity， 2021， 54（7）： 1377-1391.
[2]	ZHANG H， WANG Y， QU M D， et al. Neutrophil， neutrophil extracellular traps and endothelial cell dysfunction in sepsis［J］. Clin Transl Med， 2023， 13（1）： e1170.
[3]	PAPAYANNOPOULOS V. Neutrophil extracellular traps in immunity and disease［J］. Nat Rev Immunol， 2018， 18（2）： 134-147.
[4]	LIPINSKA-GEDIGA M. Neutrophils， NETs， NETosis-old or new factors in sepsis and septic shock？［J］. Anaesthesiol Intensive Ther， 2017， 49（3）： 235-240.
[5]	FENG J Y， SU W J， PAN S W， et al. Role of TREM-1 in pulmonary tuberculosis patients- analysis of serum soluble TREM-1 levels［J］. Sci Rep， 2018， 8（1）： 8223.
[6]	BOUFENZER A， CARRASCO K， JOLLY L， et al. Potentiation of NETs release is novel characteristic of TREM-1 activation and the pharmacological inhibition of TREM-1 could prevent from the deleterious consequences of NETs release in sepsis［J］. Cell Mol Immunol， 2021， 18（2）： 452-460.
[7]	SHI R L， ZHANG J C， PENG Z， et al. Expression level of 12-amino acid triggering receptor on myeloid cells-like transcript 1 derived peptide alleviates lipopolysaccharide-induced acute lung injury in mice［J］. Int J Mol Med， 2018， 41（4）： 2159-2168.
[8]	田勇，周颖，古雍翔，等. 二甲双胍诱导心肌细胞自噬对脓毒症小鼠心肌损伤的保护机制［J］. 安徽医科大学学报， 2024， 59（1）： 92-98.
[9]	JOLLY L， CARRASCO K， DERIVE M， et al. Targeted endothelial gene deletion of triggering receptor expressed on myeloid cells-1 protects mice during septic shock［J］. Cardiovasc Res， 2018， 114（6）： 907-918.
[10]	WILLEMSEN J F， WENSKUS J， LENZ M， et al. DNases improve effectiveness of antibiotic treatment in murine polymicrobial sepsis［J］. Front Immunol， 2024， 14： 1254838.
[11]	LI X Y， SUN H， ZHANG L Y， et al. GDF15 attenuates sepsis-induced myocardial dysfunction by inhibiting cardiomyocytes ferroptosis via the SOCS1/GPX4 signaling pathway［J］. Eur J Pharmacol， 2024， 982： 176894.
[12]	BI C F， LIU J， YANG L S， et al. Research progress on the mechanism of sepsis induced myocardial injury［J］. J Inflamm Res， 2022， 15： 4275-4290.
[13]	HUANG C J， XIAO S N， XIA Z， et al. The diagnostic value of plasma miRNA-497， cTnI， FABP3 and GPBB in pediatric sepsis complicated with myocardial injury［J］. Ther Clin Risk Manag， 2021， 17： 563-570.
[14]	ZHANG C Y， KAN X G， ZHANG B L， et al. The role of triggering receptor expressed on myeloid cells-1 （TREM-1） in central nervous system diseases［J］. Mol Brain， 2022， 15（1）： 84.
[15]	CAO C L， GU J X， ZHANG J Y. Soluble triggering receptor expressed on myeloid cell-1 （sTREM-1）： a potential biomarker for the diagnosis of infectious diseases［J］. Front Med， 2017， 11（2）： 169-177.
[16]	COLONNA M， FACCHETTI F. TREM-1 （triggering receptor expressed on myeloid cells）： a new player in acute inflammatory responses［J］. J Infect Dis， 2003， 187（）： S397-S401.
[17]	YANG Z L， PAN X Y， WU X X， et al. TREM-1 induces pyroptosis in cardiomyocytes by activating NLRP3 inflammasome through the SMC4/NEMO pathway［J］. FEBS J， 2023， 290（6）： 1549-1562.
[18]	谭子富，方孝俊，李家权，等. TREM1抑制肽LR12后处理对大鼠心肌缺血再灌注损伤的保护作用及机制［J］. 岭南心血管病杂志， 2024， 30（2）： 208-213.
[19]	WU J F， HAN B， FANELLI V， et al. Distinctive roles and mechanisms of human neutrophil peptides in experimental sepsis and acute respiratory distress syndrome［J］. Crit Care Med， 2018， 46（9）： e921-e927.
[20]	ZHAO Z Y， PAN Z R， ZHANG S， et al. Neutrophil extracellular traps： a novel target for the treatment of stroke［J］. Pharmacol Ther， 2023， 241： 108328.
[21]	ZHANG H， WU D， WANG Y， et al. Ferritin-mediated neutrophil extracellular traps formation and cytokine storm via macrophage scavenger receptor in sepsis-associated lung injury［J］. Cell Commun Signal， 2024， 22（1）： 97.
[22]	XIE X， PI M Y， ZHANG H， et al. Neutrophil-derived exosomes promote sepsis-related multiple organ dysfunction through the induction of neutrophil extracellular trap formation［J］. Int Immunopharmacol， 2025， 159： 114892.
[23]	DUAN Z H， XIE T， CHU C N， et al. De-escalation antibiotic therapy alleviates organ injury through modulation of NETs formation during sepsis［J］. Cell Death Discov， 2021， 7（1）： 345.
[24]	OKAMOTO M， MIZUNO R， KAWADA K， et al. Neutrophil extracellular traps promote metastases of colorectal cancers through activation of ERK signaling by releasing neutrophil elastase［J］. Int J Mol Sci， 2023， 24（2）： 1118.
[25]	古力加乃提·麦麦吐逊，麦路德木·麦麦吐逊，王静静，等. 脑脊液和血浆中性粒细胞外诱捕网标志物对结核性脑膜炎与化脓性脑膜炎的鉴别诊断价值［J］. 山东医药， 2024， 64（29）： 25-28.
[26]	MU Q C， YAO K， SYEDA M Z， et al. Neutrophil targeting platform reduces neutrophil extracellular traps for improved traumatic brain injury and stroke theranostics［J］. Adv Sci， 2024， 11（21）： 2308719.
[27]	GAO T W， LI J， SHI L， et al. Rosavin inhibits neutrophil extracellular traps formation to ameliorate sepsis-induced lung injury by regulating the MAPK pathway［J］. Allergol Immunopathol， 2023， 51（4）： 46-54.
[28]	SHEN B， SHEN Q K， ZENG Q Q， et al. Silenced-C5ar1 improved multiple organ injury in sepsis rats via inhibiting neutrophil extracellular trap［J］. J Mol Histol， 2024， 55（1）： 69-81.
[29]	ZHANG X， SONG H X， LIU D， et al. S100A12 triggers NETosis to aggravate myocardial infarction injury via the Annexin A5-calcium axis［J］. Nat Commun， 2025， 16（1）： 1746.

Group	LVEF	LVFS
Sham operation	66.85±3.17	37.28±3.06
Model	45.19±2.26^*	26.34±2.40^*
CLP+ LR12-scr	46.72±2.05	27.10±1.82
CLP+LR12	57.26±2.83^△	31.13±2.47^△
CLP+DNase Ⅰ	61.09±3.29^△	34.84±2.11^△

Group	CK-MB [λ_B/(U·L^-1)]	cTnI [ρ_B/(ng·L^-1)]
Sham operation	28.73±1.86	19.21±1.52
Model	57.65±4.18^*	53.37±4.83^*
CLP+LR12-scr	58.43±4.35	51.82±4.70
CLP+LR12	40.08±3.07^△	35.88±2.14^△
CLP+DNase Ⅰ	34.23±2.79^△	29.43±2.53^△

Group	IL-1β	IL-6	TNF-α
Sham operation	34.08±3.81	12.34±1.05	110.20±9.72
Model	83.05±6.24^*	33.18±2.16^*	188.62±12.65^*
CLP+LR12-scr	82.46±7.01	32.52±2.71	186.17±15.43
CLP+LR12	55.15±3.72^△	24.48±1.22^△	163.35±13.08^△
CLP+DNase Ⅰ	48.02±4.35^△	18.20±1.07^△	147.91±16.13^△

Group	MPO-DNA[w_B/（μg·g^-1）]	NE-DNA[w_B/（ng·g^-1）]
Sham operation	10.32±1.15	7.88±1.36
Model	31.89±4.04^*	27.53±2.28^*
CLP+LR12-scr	30.42±3.85	25.76±3.19
CLP+LR12	22.98±2.72^△	17.60±1.88^△
CLP+DNaseⅠ	19.36±2.24^△	15.87±1.45^△

Improvement effect of TREM-1 inhibitory peptide LR12 on myocardial injury in septic mice and its mechanism

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