Restricted accessResearch articleFirst published online 2025-5
Differential molecular mechanism of the neuroprotective activity of mulberries ( Morus Alba & Morus Nigra ) against glutamate induced-excitotoxicity on cortical neurons
Neurotoxicity induced by glutamate is used herein in his study for testing the neuroprotective effects of Tunisian mulberries fruits extracts from two different varieties, white and black mulberries (Morus alba and Morus nigra).The polyphenols content and composition between the two samples was determined using HPLC- LCMS mass spectrometry. Caffeoylquinic acid and chlorogenic acid isomers are the most abundant cinnamic acids in our extracts, while rutin, quercetin, and kaempferol are the predominant flavonols. Pre-incubation of cell with Morus alba extract (MAE) or Morus nigra extract (MNE) (2.5; 5 and 10 μg/mL) protect neurons against oxidative stress triggered by glutamate in both concentration and time-dependent manner. Remarquably, M.nigra, exhibititing the higher antioxidant activity and polyphenols contents, enhanced more efficiently neurons survival rate after glutamate insult. However, pretreatment with Chelerytrine, a PKC –inhibitor pathway, abolished the protective effect of both MAE and MNE on cell viability suggesting the involvement of PKC signaling pathway is in the neuro-protective activities of mulberries against Glutamate excitotoxicity. Protective effect of extracts may be due to both the inhibition of caspase-1, −8, and −9 activities via intrinsic mitochondrial pathways, as well as a decrease in reactive oxygen species (ROS) production. Moreover, glutamate treatment resulted in the induction of calpain inhibitors (PD150606 and calpeptin) protected neurons against the glutamate-induced neurons alteration in the brain and notably reduced the observed neuro-protective effects of MAE against Glutamate excitotoxicity. Our data suggest that mulberries protect against neuronal damage by inhibiting apoptosis and oxidative stress. The MAP kinase pathways play a crucial role in these neuroprotective effects.
BlandinFGreenamyreJTNappiG. The role of glutamate in the pathophysiology of Parkinson’s disease. Funct Neurol1996; 11: 3–15.
4.
DaiSMShanZZNakamuraH. Catabolic stress induces features of chondrocyte senescence through overexpression of caveolin 1: possible involvement of caveolin 1-induced down-regulation of articular chondrocytes in the pathogenesis of osteoarthritis. Arthritis Rheum2006; 54: 818–831.
5.
BroesSBrookesN. Transfer of glutamine between astrocytes and neurons. J Neurochem2001; 7: 705–719.
6.
KangTHOhHRJungSM, et al.Mulberry leaves (Morus alba L.) prepared by the anaerobic treatment against ischemic damage. Biol Pharm Bull2006; 29: 270–274.
7.
NiidomeTTakahashiKGotoY, et al.Mulberry leaf extract prevents amyloid beta-peptide fibril formation and neurotoxicity. Neuro Report2006; 18: 813–816.
8.
PawlowskaAMOleszekWBracaA. Quali-quantitative analyses of flavonoids of Morus nigra L. and Morus alba L. (Moraceae) fruits. J Agric Food Chem2008; 56: 3377–3380.
9.
ChenPChenNChuSC, et al.Mulberry anthocyanins cyanidin 3-rutinoside and cyanidin 3-glucoside exhibited an inhibitory effect on the migration and invasion of a human lung cancer cell line. Cancer Lett2006; 235: 248–259.
10.
FattouchSCaboniPCoreneoV, et al.Antimicrobial activity of Tunisian quince (Cydonia oblonga Miller) pulp and peel polyphenolic extracts. J Agric Food Chem2007; 55: 963–969.
11.
AtouiAKMansouriABoskouG,et al.Tea and herbal infusions: their antioxidant activity and phenolic profile. Food Chem2005; 89: 27–36.
12.
BravoLGoyaLLecumberriE. LC/MS characterization of phenolic constituents of mate (Ilex paraguariensis, St. Hil.) and its antioxidant activity compared to commonly consumed beverages. Food Res Int2007; 40: 393–405.
13.
dos SantosMDMartinsPRdos SantosPA, et al.Oxidative metabolism of 5-O-caffeoylquinic acid (chlorogenic acid), a bioactive natural product, by metalloporphyrin and rat liver mitochondria. Eur J Pharm Sci2005; 26: 62–70.
14.
OkelloEJMcDougallGJKumarS,et al.In vitro protective effects of colon-available extract of Camellia sinensis (tea) against hydrogen peroxide and beta-amyloid (Aβ (1-42) induced cytotoxicity in differentiated PC12 cells. Phytomedicine2011; 18: 691–696.
15.
DugoGCacciolaF. Phenolic compounds in foods: analysis and identification by liquid chromatography-mass spectrometry (LC-MS). Food Res Int2007; 40: 661–670.
16.
MarkisDPBoskouGAndrikP. Recovery of antioxidant phenolics from white vinification solid by products employing water-ethanol mixture. Bioresour Technol2007; 98: 2963–2967.
Campus-EsparzaRSanchez-GomezMVMatuteC. Molecular mechanisms of neu roprotection by two natural antioxidant polyphenols. Cell Calcium2009; 45: 358–368.
19.
RebaiOBelkhirMSanchez-GomezMV, et al.Differential molecular targets for neuroprotective effect of chlorogenic acid and its related compounds against glutamate induced excitotoxicity and oxidative stress in rat cortical neurons. Neurochem Res2017; 42: 3559–3572.
20.
WangKKPosmanturRNadimpalliR, et al.Caspase-mediated fragmentation ofcalpain inhibitor protein calpastatin during apoptosis. Arch Biochem Biophys1998; 356: 187–196.
21.
AebiH. Catalase in vitro. Methods Enzymol1984; 105: 121–126.
22.
MisraHPFridovichI. The role of superoxideanion in the autoxidation of epinephrine and a simpleassay for superoxide dismutase. J Biol Chem1972; 247: 3170–3175.
23.
OhnishiSTBarrJK. A simple method ofquantitating protein using the biuret and phenolreagent. Anal Biochem1978; 86: 193–200.
24.
HamdiYKaddourHVaudryD, et al.The octadecaneuropeptide ODN protects astrocytes against hydrogen peroxide-induced apoptosis via a PKA/MAPK-dependent mechanism. PLoS One2012; 7: e42498.
25.
DugoPDonatoPCacciolaF, et al.Characterization of the polyphenolic fraction of Morus alba leaves extracts by HPLC coupled to a hybrid IT-TOF MS system. J Sep Sci2009; 32: 3627–3634.
26.
ThabtiA. Identification and quantification of phenolic acids and flavonol glycosides in Tunisian Morus species by HPLC-DAD and HPLC-MS. J Funct Foods2012; 4: 367–374.
27.
Sánchez-SalcedoEMTassottiMDel RioD, et al.(Poly)phenolic fingerprint and chemometric analysis of white (Morus alba L.) and black (Morus nigra L.) mulberry leaves using a non-targeted UHPLC-MS approach. Food Chem2016; 212: 250–258.
28.
OnogiAOsawaKYasudaH, et al.Flavonol glycosides from the leaves of Morus alba. Shoyakuga Zasshi. 1993; 47: 423–425.
29.
MatsuokaTKimuraTMuraokaN. Research of the available constituents frommulberry tree. Tohoku Agric Res1994; 47: 361–362.
30.
KimGNJangHD. Favonol content in the water extract of the Mulberry leaf and their antioxidant capacities. J Food Sci2011; 76: 869–873.
31.
KatsubeTYamasakiMShiwakuK, et al.Effect of flavonol glycoside in mulberry (Morus alba L.) leaf on glucose metabolism and oxidative stress in liver in diet-induced obese mice. J Sci Food Agric2010; 90: 2386–2392.
FangNYuSPriorRL. LC/MS/MS characterization of phenolic constituents in dried plums. J Agric Food Chem2002; 50: 3579–3585.
34.
KimSYGaoJJLeeWC, et al.Antioxidative flavonoids from the leaves of Morus alba. Arch Pharm Res1999; 22: 81–85.
35.
MatsudaFMorinoKMiyashitaM,et al.Metabolic flux analysis of the phenylpropanoid pathway in woundhealing potato tuber tissue using stable isotope-labeled tracer and LC-MS spectroscopy. Plant Cell Physiol2003; 44: 510–517.
36.
MikamiYYamazawaT. Chlorogenic acid, a polyphenol in coffee, protects neurons against glutamate neurotoxicity. Life Sci2015; 15: 69–74.
37.
FattmanCLSchaeferLMOuryTD. Extracellular superoxide dismutase in biology and medicine. Free Radic Biol Med2003; 35: 236–256.
LevitesYAmitTYoudimMB,et al.Involvement of protein kinase C activation and cell survival/cell cycle genes in green tea polyphenol (-)-epigallocatechin 3-gallate neuroprotective action. J Biol Chem2002; 277: 30574–30580.
40.
AlkonDLSunMKNelsonTJ. PKC Signaling deficits: a mechanistic hypothesis for the origins of Alzheimer’s disease. Trends Pharmacol Sci2007; 28: 51–60.
41.
WeiXMiouZBaudryM. Neuroprotection by cell permeable TAT-mGluR1 peptide in ischemia: synergy between carrier and cargo sequences. Neuroscientist2008; 145: 409–414.
ChangYHYangX. Proteases for cell suicide: functions and regulation of caspases. Microbiol Mol Biol Rev2000; 64: 821–846.
44.
EarnshawWCMartinsLMKaufmannSH. Mammalian caspases: structure, activation, substrates, and functions during apoptosis. Annu Rev Biochem1999; 68: 383–424.
45.
ZhaoXNewcombJKPikeBR, et al.Novel characteristics of glutamate-induced cell death in primary septohippocampal cultures: relationship to calpain and caspase-3 protease activation. J Cereb Blood Flow Metab2000; 20: 550–562.
46.
YuanBYanknerA. Apoptosis in the nervous system. Nature2000; 407: 802–809.
