木犀草素抑制ROS/TXNIP/NLRP3信号通路激活对小鼠急性呼吸窘迫综合征的改善作用

doi:10.13481/j.1671-587X.20220316

Abstract

Abstract: Objective

To investigate the improvement effect of luteolin in the mice with acute respiratory distress syndrome （ARDS） by regulating the activation of reactive oxygen species （ROS）/thioredoxin binding protein （TXNIP）/NOD like receptor associated protein 3 （NLRP3） signaling pathway.

Methods

A total of 60 SD mice were randomly divided into control group， model group， luteolin （20 mg·kg^－1） group， pyrogallol（PG）（75 mg·kg^－1） group， luteolin （20 mg·kg^－1） + PG（75 mg·kg^－1） group， and there were 12 mice in each group.Besides control group， the mice in the other groups were instilled with lipopolysaccharide（LPS） solution through the trachea to establish the ARDS models， and the mice in control group were instilled with the same amount of normal saline through the trachea. The wet weights and dry weights of right lung tissue of the mice in various groups were weighed， and ratios of the wet weight/dry weight （W/D） of the mice in various were caculated； the arterial blood oxygen pressure （PaO₂） was measured； the pathomorphology of lung tissue of the mice in various groups was observed by HE staining； the inspiratory resistance （Ri）， minute ventilation （MV） and peak expiratory flow rate （PEF） of the mice in various groups were detected； the levels of ROS， glutathione peroxidase （GSH-Px）， catalase （CAT） in lung tissue and levels of serum interleukin-18 （IL-18），interleukin-1β（IL-1β） and tumor necrosis factor α（TNF-α） of the mice in various groups were determined； the expression levels of TXNIP， caspase-1， caspase-4 and NLRP3 proteins in lung tissue of the mice in various groups were detected by Western blotting method.

Results

Compared with control group， the alveolar walls of the mice in model group became thicker， the alveoli collapsed and deformed， the pulmonary interstitial edema was accompanied by a large number of inflammatory cell infiltration， and the lung tissue had the severe pathological damage； the W/D ratio， Ri， serum IL-18， IL-1β and TNF-α levels， the level of ROS and the expression levels of TXNIP， caspase-1， caspase-4， and NLRP3 proteins in lung tissue were increased （P<0.05），and the MV， PEF， PaO₂， levels of GSH-Px and CAT in lung tissue were decreased （P<0.05）. Compared with model group， the pathological damage of lung tissue of the mice in luteolin group was improved， the W/D ratio， Ri， serum IL-18， IL-1β and TNF-α levels， ROS level and the expression levels of TXNIP， caspase-1， caspase-4 and NLRP3 proteins in lung tissue were significantly decreased （P<0.05）， and the MV， PEF， PaO₂， and GSH-Px and CAT levels in lung tissue were increased （P<0.05）； the pathological damage of lung tissue of the mice in PG group was increased， the W/D ratio， Ri， serum levels of IL-18， IL-1β， and TNF-α，the ROS level and the expression levels of TXNIP， caspase-1， caspase-4，and NLRP3 proteins in lung tissue were increased （P<0.05），and the MV， PEF， PaO₂，GSH-Px， and CAT levels in lung tissue were decreased （P<0.05）.

Conclusion

Luteolin can reduce the lung inflammation and oxidative stress， improve the lung injury in the ARDS mice， and repair their lung functions by inhibiting the ROS/TXNIP/NLRP3 signaling pathway activation.

Key words: Luteolin, Reactive oxygen species, Thioredoxin-binding protein, NOD-like receptor pyrin domain containing 3, Acute respiratory distress syndrome

CLC Number:

R563.8

Haixin QU,Erwei YUAN,Weiping GUO,Yajing ZHANG,Wenxia MA,Dan WU. Improvement effect of luteolin on acute respiratory distress syndrome by inhibiting ROS/TXNIP/NLRP3 signaling pathway activation in mice[J].Journal of Jilin University(Medicine Edition), 2022, 48(3): 676-683.

Figures/Tables 7

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Fig. 2

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References 22

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Group	MV（V/mL）	PEF（mL·s^－1）	Ri（kPa.s·L^－1）
Control	7.71±0.68	62.45±6.56	25.05±2.52
Model	2.82±0.35^*	39.38±3.43^*	60.13±6.68^*
PG	1.15±0.13^△	20.84±2.12^△	79.85±7.18^△
Luteolin	7.66±0.74^△	62.17±6.26^△	25.21±2.63^△
Luteolin+PG	2.85±0.42^#○	39.42±3.78^#○	59.98±7.04^#○

Group	W/D	PaO₂（P/mmHg）
Control	4.42±0.39	98.79±9.67
Model	6.78±0.56^*	55.86±4.18^*
PG	8.65±0.61^△	37.08±3.27^△
Luteolin	4.55±0.33^△	98.57±10.23^△
Luteolin+PG	6.74±0.70^#○	56.01±6.24^#○

Group	GSH-Px	CAT
Control	20.09±3.45	5.13±0.32
Model	9.86±1.06^*	2.61±0.15^*
PG	6.12±1.39^△	1.02±0.23^△
Luteolin	19.97±3.27^△	5.09±0.51^△
Luteolin+PG	9.90±1.25^#○	2.64±0.18^#○

Group	IL-18 [ρ_B/（μg·L^－1）]	IL-1β [ρ_B/（ng·L^－1）]	TNF-α [ρ_B/（μg·L^－1）]
Control	0.32±0.07	21.93±4.81	0.42±0.10
Model	1.15±0.18^*	67.41±9.32^*	1.47±0.28^*
PG	1.90±0.23^△	98.72±11.48^△	2.30±0.32^△
Luteolin	0.33±0.08^△	22.01±5.84^△	0.44±0.11^△
Luteolin+PG	1.13±0.24^#○	67.37±10.56^#○	1.45±0.23^#○

Group	ROS[（U·kg^－1）]	TXNIP/GAPDH	caspase-1/GAPDH	NLRP3/GAPDH	caspase-4/GAPDH
Control	1.65±0.21	0.39±0.07	0.51±0.12	0.43±0.08	0.60±0.13
Model	5.06±0.35^*	1.15±0.29^*	1.49±0.28^*	1.32±0.23^*	1.34±0.25^*
PG	7.61±0.64^△	1.86±0.35^△	2.31±0.35^△	2.01±0.37^△	2.12±0.31^△
Luteolin	1.69±0.24^△	0.41±0.09^△	0.53±0.19^△	0.45±0.11^△	0.64±0.18^△
Luteolin+PG	5.01±0.32^#○	1.14±0.21^#○	1.47±0.24^#○	1.30±0.22^#○	1.31±0.20^#○

Improvement effect of luteolin on acute respiratory distress syndrome by inhibiting ROS/TXNIP/NLRP3 signaling pathway activation in mice

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