Lactobacillus plantarum alleviates lead exposure-induced learning and memory impairment in mice by regulating bile acid metabolism and inhibiting hippocampal NLRP3 expression

doi:10.12122/j.issn.1673-4254.2026.02.04

Abstract

Abstract:

Objective To explore the mechanism of Lactobacillus plantarum (L. plantarum) for alleviating learning and memory impairments caused by lead exposure. Methods Twenty-four C57BL/6J mice were randomized equally into control group, lead exposure (100 mg/L) group, and L.plantarum treatment group with daily gavage of L.plantarum (10⁹ CFU) for 10 weeks. Learning and memory abilities of the mice were evaluated using Morris water maze test, and blood lead level and bile acid levels were determined using inductively coupled plasma mass spectrometry (ICP-MS) and liquid chromatography-mass spectrometry (LC-MS), respectively. Hippocampal pathologies of the mice were examined with HE staining, and immunohistochemistry was used to observe morphological changes and microglia activation in the hippocampus. Serum levels of TNF‑α and IL-1β of the mice were determined with ELISA, and hippocampal expression levels of NLRP3 and TGR5 proteins were detected using Western blotting. Results Compared with those in lead exposure group, the mice receiving L.plantarum intervention showed significantly increased exploration time, swimming distance, and target platform crossings with reduced latency period to find the hidden platforms in Morris water maze test. L.plantarum intervention partially reversed lead exposure induced reduction of serum levels of deoxycholic acid, 3-hydroxydeoxycholic acid, 3-hydroxyursodeoxycholic acid, 3-thiodeoxycholic acid, and 3-thio‑α‑methylcholic acid. The treatment also significantly reduced hippocampus pathologies in mice with lead exposure, and reduced their serum levels of IL-1β and TNF‑α and hippocampal NLRP3 protein expression levels. Conclusion L.plantarum can alleviate learning and memory impairments caused by lead exposure in mice possibly by regulating bile acid metabolism and inhibiting hippocampal expression of NLRP3 protein.

Key words: lead exposure, learning and memory, Lactobacillus plantarum, targeted metabolomics, NLRP3

Lifan LI, Weijian YU, Meitao TAN, Yunting LI, Anfei LIU, Xiaojing MENG. Lactobacillus plantarum alleviates lead exposure-induced learning and memory impairment in mice by regulating bile acid metabolism and inhibiting hippocampal NLRP3 expression[J]. Journal of Southern Medical University, 2026, 46(2): 271-277.

Figures/Tables 4

Fig.1 L.plantarum supplementation alleviates lead-induced learning and memory impairments in mice as shown by performance in Morris water maze test. A: Swimming speed. B: Escape latency on day 4. C: Percentage of swimming distance in the target quadrant. D: Percentage of swimming time in the target quadrant. E: Number of crossings over the target platform. n=8, *P<0.05, ***P<0.001, ****P<0.0001.

Fig.2 ICP-MS detection of blood lead concentration in mice (n=6). ****P<0.0001.

Fig.3 L.plantarum treatment partially restores lead-induced disorders in bile acid metabolism. A: Principal component analysis of serum bile acid targeted metabolic profiles in different groups. B: Quantitative comparison of serum bile acid levels among the 3 groups. *P<0.05, **P<0.01, ***P<0.001.

Fig.4 L.plantarum supplementation alleviates lead-induced neuroinflammation by inhibiting NLRP3 inflammasome. A: HE staining and immunohistochemistry for IBA1 expression in the hippocampal DG region. The red arrow in the upper panel indicates hippocampal pathology, and the arrows in the lower panel indicate activated microglia. B: Levels of IL-1β and TNF-α in the hippocampal tissue and serum of the mice detected using ELISA (n=5). C: Western blotting for detecting TGR5 and NLRP3 expression levels in the hippocampus (n=3). *P<0.05, **P<0.01, ***P<0.001.

References 35

[1]	Tong S, von Schirnding YE, Prapamontol T. Environmental lead exposure: a public health problem of global dimensions[J]. Bull World Health Organ, 2000, 78(9): 1068-77.
[2]	国家统计局https://data.stats.gov.cn/easyquery.htm?cn=A01&zb=A02091F&sj=202504 [Z]. 2024
[3]	Gottesfeld P, Cherry CR. Lead emissions from solar photovoltaic energy systems in China and India[J]. Energy Policy, 2011, 39(9): 4939-46. doi：10.1016/j.enpol.2011.06.021
[4]	Wei BG, Yang LS. A review of heavy metal contaminations in urban soils, urban road dusts and agricultural soils from China[J]. Microchem J, 2010, 94(2): 99-107. doi：10.1016/j.microc.2009.09.014
[5]	Patrick L. Lead toxicity part II: the role of free radical damage and the use of antioxidants in the pathology and treatment of lead toxicity[J]. Altern Med Rev, 2006, 11(2): 114-27.
[6]	Virgolini MB, Aschner M. Molecular mechanisms of lead neurotoxicity[J]. Adv Neurotoxicol, 2021, 5: 159-213. doi：10.1016/bs.ant.2020.11.002
[7]	Shvachiy L, Geraldes V, Amaro-Leal Â, et al. Intermittent low-level lead exposure provokes anxiety, hypertension, autonomic dysfunction and neuroinflammation[J]. NeuroToxicology, 2018, 69: 307-19. doi：10.1016/j.neuro.2018.08.001
[8]	Xie J, Xie L, Wei H, et al. Dynamic regulation of DNA methylation and brain functions[J]. Biology: Basel, 2023, 12(2): 152. doi：10.3390/biology12020152
[9]	Kim M, Delgado E, Ko S. DNA methylation in cell plasticity and malignant transformation in liver diseases[J]. Pharmacol Ther, 2023, 241: 108334. doi：10.1016/j.pharmthera.2022.108334
[10]	Huang DB, Chen LX, Ji QY, et al. Lead aggravates Alzheimer's disease pathology via mitochondrial copper accumulation regulated by COX17[J]. Redox Biol, 2024, 69: 102990. doi：10.1016/j.redox.2023.102990
[11]	Pikor D, Hurła M, Słowikowski B, et al. Calcium ions in the physiology and pathology of the central nervous system[J]. Int J Mol Sci, 2024, 25(23): 13133. doi：10.3390/ijms252313133
[12]	Liu AF, Li YT, Li LF, et al. Bile acid metabolism is altered in learning and memory impairment induced by chronic lead exposure[J]. J Hazard Mater, 2024, 471: 134360. doi：10.1016/j.jhazmat.2024.134360
[13]	Shannon M, Graef J, Lovejoy FH. Efficacy and toxicity of d-penicillamine in low-level lead poisoning[J]. J Pediatr, 1988, 112(5): 799-804. doi：10.1016/s0022-3476(88)83212-8
[14]	Tizabi Y, Bennani S, El Kouhen N, et al. Interaction of heavy metal lead with gut microbiota: implications for autism spectrum disorder[J]. Biomolecules, 2023, 13(10): 1549. doi：10.3390/biom13101549
[15]	Yu XM, Wei M, Yang D, et al. Lactiplantibacillus plantarum strain FLPL05 promotes longevity in mice by improving intestinal barrier[J]. Probiotics Antimicrob Proteins, 2023, 15(5): 1193-205. doi：10.1007/s12602-022-09933-5
[16]	Liu YW, Liong MT, Tsai YC. New perspectives of Lactobacillus plantarum as a probiotic: the gut-heart-brain axis[J]. J Microbiol, 2018, 56(9): 601-13. doi：10.1007/s12275-018-8079-2
[17]	Nordström EA, Teixeira C, Montelius C, et al. Lactiplantibacillus plantarum 299v (LP299V^®): three decades of research[J]. Benef Microbes, 2021, 12(5): 441-65. doi：10.3920/bm2020.0191
[18]	Lu CS, Chang HC, Weng YH, et al. The add-on effect of Lactobacillus plantarum PS128 in patients with Parkinson's disease: a pilot study[J]. Front Nutr, 2021, 8: 650053. doi：10.3389/fnut.2021.650053
[19]	Liao JF, Cheng YF, You ST, et al. Lactobacillus plantarum PS128 alleviates neurodegenerative progression in 1-methyl-4-phenyl-1, 2, 3, 6-tetrahydropyridine-induced mouse models of Parkinson's disease[J]. Brain Behav Immun, 2020, 90: 26-46. doi：10.1016/j.bbi.2020.07.036
[20]	Beltrán-Velasco AI, Reiriz M, Uceda S, et al. Lactiplantibacillus (Lactobacillus) plantarum as a complementary treatment to improve symptomatology in neurodegenerative disease: a systematic review of open access literature[J]. Int J Mol Sci, 2024, 25(5): 3010. doi：10.3390/ijms25053010
[21]	Wang L, Li SY, Jiang Y, et al. Neuroprotective effect of Lactobacillus plantarum DP189 on MPTP-induced Parkinson's disease model mice[J]. J Funct Foods, 2021, 85: 104635. doi：10.1016/j.jff.2021.104635
[22]	Xu Z, Zhang J, Wu J, et al. Lactobacillus plantarum ST-III culture supernatant ameliorates alcohol-induced cognitive dysfunction by reducing endoplasmic reticulum stress and oxidative stress[J]. Front Neurosci, 2022, 16: 976358. doi：10.3389/fnins.2022.976358
[23]	Zhai Q, Liu Y, Wang C, et al. Lactobacillus plantarum CCFM8661 modulates bile acid enterohepatic circulation and increases lead excretion in mice[J]. Food Funct, 2019, 10(3): 1455-64. doi：10.1039/c8fo02554a
[24]	Li YT, Liu AF, Chen LX, et al. Lactobacillus plantarum WSJ-06 alleviates neurobehavioral injury induced by lead in mice through the gut microbiota[J]. Food Chem Toxicol, 2022, 167: 113308. doi：10.1016/j.fct.2022.113308
[25]	Gadaleta RM, Cariello M, Crudele L, et al. Bile salt hydrolase-competent probiotics in the management of IBD: unlocking the “bile acid code”[J]. Nutrients, 2022, 14(15): 3212. doi：10.3390/nu14153212
[26]	Zhu J, Zhou F, Zhou Q, et al. NLRP3 activation in microglia contributes to learning and memory impairment induced by chronic lead exposure in mice[J]. Toxicol Sci, 2023, 191(1): 179-91. doi：10.1093/toxsci/kfac115
[27]	Su P, Wang D, Cao Z, et al. The role of NLRP3 in lead-induced neuroinflammation and possible underlying mechanism[J]. Environ Pollut, 2021, 287: 117520. doi：10.1016/j.envpol.2021.117520
[28]	Nagpal AG, Brodie SE. Supranormal electroretinogram in a 10-year-old girl with lead toxicity[J]. Documenta Ophthalmol, 2009, 118(2): 163-6. doi：10.1007/s10633-008-9144-7
[29]	Lidsky TI, Schneider JS. Lead neurotoxicity in children: basic mechanisms and clinical correlates[J]. Brain, 2003, 126(pt 1): 5-19. doi：10.1093/brain/awg014
[30]	Xiao J, Wang T, Xu Y, et al. Long-term probiotic intervention mitigates memory dysfunction through a novel H3K27me3-based mechanism in lead-exposed rats[J]. Transl Psychiatry, 2020, 10(1): 25. doi：10.1038/s41398-020-0719-8
[31]	Tian FW, Zhai QX, Zhao JX, et al. Lactobacillus plantarum CCFM8661 alleviates lead toxicity in mice[J]. Biol Trace Elem Res, 2012, 150(1): 264-71. doi：10.1007/s12011-012-9462-1
[32]	Hu SP, Tang B, Lu C, et al. Lactobacillus rhamnosus GG ameliorates triptolide-induced liver injury through modulation of the bile acid-FXR axis[J]. Pharmacol Res, 2024, 206: 107275. doi：10.1016/j.phrs.2024.107275
[33]	McMillin M, Frampton G, Tobin R, et al. TGR5 signaling reduces neuroinflammation during hepatic encephalopathy[J]. J Neurochem, 2015, 135(3): 565-76. doi：10.1111/jnc.13243
[34]	Yanguas-Casás N, Barreda-Manso MA, Nieto-Sampedro M, et al. TUDCA: an agonist of the bile acid receptor GPBAR1/TGR5 with anti-inflammatory effects in microglial cells[J]. J Cell Physiol, 2017, 232(8): 2231-45. doi：10.1002/jcp.25742
[35]	Jena PK, Sheng L, Di Lucente J, et al. Dysregulated bile acid synthesis and dysbiosis are implicated in Western diet-induced systemic inflammation, microglial activation, and reduced neuroplasticity[J]. FASEB J, 2018, 32(5): 2866-77. doi：10.1096/fj.201700984rr