Supramolecular Probe for Monitoring Lysosomal Ferritinophagy to Facilitate the Early Diagnosis of Parkinson's Disease

Shiqin Zhou , Bo Xiao , Jiamin Chen , Jinming Zhu , Xia Ran , Zuoji Liu , Chaozhong Li , Li Wang , Xinai Cui , Rong Li , Guangwei Feng , Jian Feng

Aggregate ›› 2025, Vol. 6 ›› Issue (9) : e70120

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Aggregate ›› 2025, Vol. 6 ›› Issue (9) : e70120 DOI: 10.1002/agt2.70120
RESEARCH ARTICLE

Supramolecular Probe for Monitoring Lysosomal Ferritinophagy to Facilitate the Early Diagnosis of Parkinson's Disease

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Abstract

Lysosomal iron overload, resulting from dysregulated ferritinophagy, is a significant early event in the progression of Parkinson's disease (PD). This condition causes iron accumulation within cells, triggering oxidative stress and ferroptosis, along with mitochondrial dysfunction and α-synuclein (α-syn) aggregation, ultimately damaging dopaminergic neurons irreversibly. However, tools for real-time monitoring of Fe3+ dynamics in vivo are limited. In this study, we introduce TPE-4B/4Q[7], a supramolecular fluorescent probe designed for selective and stable tracking of Fe3+ changes within lysosomes. This probe exhibits excellent photostability, low cytotoxicity, and a detection limit of 1.23 × 10⁻⁶ M. In cellular models of PD, TPE-4B/4Q[7] effectively monitors lysosomal ferritinophagy-induced Fe3+ overload, allowing for the assessment of oxidative stress, mitochondrial function, and the levels of key biomarkers such as α-syn and tyrosine hydroxylase. Additionally, this probe can track iron accumulation linked to neurodegenerative lesions in Caenorhabditis elegans and MPTP-induced PD mouse models, with signal changes correlating closely with neurodegenerative phenotypes and molecular pathology. Notably, TPE-4B/4Q[7] enables non-invasive brain imaging via nasal delivery. TPE-4B/4Q[7] is a sensitive molecular indicator for early risk assessment and monitoring of PD progression. It is anticipated to be an effective instrument for the early diagnosis of PD.

Keywords

ferritinophagy / iron metabolism / lysosomal targeting / Parkinson's disease / supramolecular probe

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Shiqin Zhou, Bo Xiao, Jiamin Chen, Jinming Zhu, Xia Ran, Zuoji Liu, Chaozhong Li, Li Wang, Xinai Cui, Rong Li, Guangwei Feng, Jian Feng. Supramolecular Probe for Monitoring Lysosomal Ferritinophagy to Facilitate the Early Diagnosis of Parkinson's Disease. Aggregate, 2025, 6(9): e70120 DOI:10.1002/agt2.70120

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Y. Ben-Shlomo, S. Darweesh, J. Llibre-Guerra, C. Marras, M. San Luciano, and C. Tanner, “The Epidemiology of Parkinson's Disease,” The Lancet 403 (2024): 283-292.
[2]

I. C. Lampropoulos, F. Malli, O. Sinani, K. I. Gourgoulianis, and G. Xiromerisiou, “Worldwide Trends in Mortality Related to Parkinson's Disease in the Period of 1994-2019: Analysis of Vital Registration Data From the WHO Mortality Database,” Frontiers in Neurology 13 (2022): 956440.
[3]

L. V. Kalia and A. E. Lang, “Parkinson's Disease,” The Lancet 386 (2015): 896-912.
[4]

P. Calabresi, G. Di Lazzaro, G. Marino, F. Campanelli, and V. Ghiglieri, “Advances in Understanding the Function of Alpha-synuclein: Implications for Parkinson's Disease,” Brain 146 (2023): 3587-3597.
[5]

H. Ye, L. A. Robak, M. Yu, M. Cykowski, and J. M. Shulman, “Genetics and Pathogenesis of Parkinson's Syndrome,” Annual Review of Pathology: Mechanisms of Disease 18 (2023): 95-121.
[6]

G. E. C. Thomas, A. Zarkali, M. Ryten, et al., “Regional Brain Iron and Gene Expression Provide Insights Into Neurodegeneration in Parkinson's disease,” Brain 144 (2021): 1787-1798.
[7]

F. A. Zucca, J. Segura-Aguilar, E. Ferrari, et al., “Interactions of Iron, Dopamine and Neuromelanin Pathways in Brain Aging and Parkinson's Disease,” Progress in Neurobiology 155 (2017): 96-119.
[8]

F. Yu, Q. Zhang, H. Liu, et al., “Dynamic O-GlcNAcylation Coordinates Ferritinophagy and Mitophagy to Activate Ferroptosis,” Cell Discovery 8 (2022): 40.
[9]

A. D. Read, R. Et. Bentley, S. L. Archer, and K. J. Dunham-Snary, “Mitochondrial Iron-Sulfur Clusters: Structure, Function, and an Emerging Role in Vascular Biology,” Redox Biology 47 (2021): 102164.
[10]

B. Galy, M. Conrad, and M. Muckenthaler, “Mechanisms Controlling Cellular and Systemic Iron Homeostasis,” Nature Reviews Molecular Cell Biology 25 (2024): 133-155.
[11]

Q. Ru, Y. Li, L. Chen, Y. Wu, J. Min, and F. Wang, “Iron Homeostasis and Ferroptosis in Human Diseases: Mechanisms and Therapeutic Prospects,” Signal Transduction and Targeted Therapy 9 (2024): 271.
[12]

S. Masaldan, A. I. Bush, D. Devos, A. S. Rolland, and C. Moreau, “Striking While the Iron Is Hot: Iron Metabolism and Ferroptosis in Neurodegeneration,” Free Radical Biology and Medicine 133 (2019): 221-233.
[13]

S. Levi, M. Ripamonti, A. S. Moro, and A. Cozzi, “Iron Imbalance in Neurodegeneration,” Molecular Psychiatry 29 (2024): 1139-1152.
[14]

J. D. Mancias, X. Wang, S. P. Gygi, J. W. Harper, and A. C. Kimmelman, “Quantitative Proteomics Identifies NCOA4 as the Cargo Receptor Mediating Ferritinophagy,” Nature 509 (2014): 105-109.
[15]

X. Ding, L. Gao, Z. Han, et al., “Ferroptosis in Parkinson's Disease: Molecular Mechanisms and Therapeutic Potential,” Ageing Research Reviews 91 (2023): 102077.
[16]

I. Costa, D. J. Barbosa, S. Benfeito, et al., “Molecular Mechanisms of Ferroptosis and Their Involvement in Brain Diseases,” Pharmacology & Therapeutics 244 (2023): 108373.
[17]

Z. D. Zhou and E.-K. Tan, “Iron Regulatory Protein (IRP)-iron Responsive Element (IRE) Signaling Pathway in human Neurodegenerative Diseases,” Molecular Neurodegeneration 12 (2017): 75.
[18]

L. Mahoney-Sánchez, H. Bouchaoui, S. Ayton, D. Devos, J. A. Duce, and J.-C. Devedjian, “Ferroptosis and Its Potential Role in the Physiopathology of Parkinson's Disease,” Progress in Neurobiology 196 (2021): 101890.
[19]

N. He, H. Ling, B. Ding, et al., “Region-specific Disturbed Iron Distribution in Early Idiopathic Parkinson's Disease Measured by Quantitative Susceptibility Mapping,” Human Brain Mapping 36 (2015): 4407-4420.
[20]

Q. Shen, X. Jv, X. Ma, et al., “Cell Senescence Induced by Toxic Interaction Between α-synuclein and Iron Precedes Nigral Dopaminergic Neuron Loss in a Mouse Model of Parkinson's Disease,” Acta Pharmacologica Sinica 45 (2024): 268-281.
[21]

J.-J. Guo, F. Yue, D.-Y. Song, et al., “Intranasal Administration of α-synuclein Preformed Fibrils Triggers Microglial Iron Deposition in the Substantia nigra of Macaca fascicularis,” Cell Death & Disease 12 (2021): 81.
[22]

L. Xie and L. Hu, “Research Progress in the Early Diagnosis of Parkinson's Disease,” Neurological Sciences 43 (2022): 6225-6231.
[23]

J. Gujral, “PET, SPECT, and MRI Imaging for Evaluation of Parkinson's Disease,” American Journal of Nuclear Medicine and Molecular Imaging 14 (2024): 371-390.
[24]

N. Pyatigorskaya, C. B. Sanz-Morère, R. Gaurav, et al., “Iron Imaging as a Diagnostic Tool for Parkinson's Disease: A Systematic Review and Meta-Analysis,” Frontiers in Neurology 11 (2020): 366.
[25]

L. Gao, W. Wang, X. Wang, et al., “Fluorescent Probes for Bioimaging of Potential Biomarkers in Parkinson's Disease,” Chemical Society Reviews 50 (2021): 1219-1250.
[26]

W. Chi, R. Liu, W. Zhou, W. Li, and Y. Yu, “The Mechanisms of Interaction Between Biomaterials and Cells/Cellular Microenvironment and the Applications in Neural Injuries,” Chinese Chemical Letters 36 (2025): 110587.
[27]

J. Liu, X. Wang, X. Zhu, Y. Zhao, and Y. Ye, “Advances in Dual-function Bioprobes for Simultaneous Detection of Transition Metal Ions (Fe, Cu, Zn) and Bioactive Species,” Coordination Chemistry Reviews 526 (2025): 216352.
[28]

A. T. Aron, K. M. Ramos-Torres, J. A. Cotruvo, and C. J. Chang, “Recognition- and Reactivity-Based Fluorescent Probes for Studying Transition Metal Signaling in Living Systems,” Accounts of Chemical Research 48 (2015): 2434-2442.
[29]

K. Grover, A. Koblova, A. T. Pezacki, C. J. Chang, and E. J. New, “Small-Molecule Fluorescent Probes for Binding- and Activity-Based Sensing of Redox-Active Biological Metals,” Chemical Reviews 124 (2024): 5846-5929.
[30]

Y. Wang, Y. Hou, F. Huo, and X. Hou, “Fe3+ Ion Quantification With Reusable Bioinspired Nanopores,” Chinese Chemical Letters 36 (2025): 110428.
[31]

J. Yin, L. Huang, L. Wu, J. Li, T. D. James, and W. Lin, “Small Molecule Based Fluorescent Chemosensors for Imaging the Microenvironment Within Specific Cellular Regions,” Chemical Society Reviews 50 (2021): 12098-12150.
[32]

W. Xu, Z. Zeng, J. Jiang, Y. Chang, and L. Yuan, “Discerning the Chemistry in Individual Organelles With Small-Molecule Fluorescent Probes,” Angewandte Chemie International Edition 55 (2016): 13658-13699.
[33]

Y. Wang, F. Liu, C. Pu, Z. Tong, M. Wang, and J. Wang, “Galactose-imidazole Mediated Dual-targeting Fluorescent Probe for Detecting Fe3+ in the Lysosomes of Hepatocytes: Design, Synthesis and Evaluation,” Biosensors & Bioelectronics 204 (2022): 114083.
[34]

Y. Wang, F. Liu, Q. Yi, M. Wang, and J. Wang, “Design, Synthesis and Biological Evaluation of Novel Dual-targeting Fluorescent Probes for Detection of Fe3+ in the Lysosomes of Hepatocytes Mediated by Galactose-morpholine Moieties,” Talanta 243 (2022): 123362.
[35]

Z. Cheng, X. Liu, D. Chen, Y. Liu, L. Zheng, and H. He, “A Lysosome-targeting Probe for Dynamic Fe3+ Tracking and the Probe-Fe3+ Imaging Applications in Living Cells,” Journal of Molecular Structure 1290 (2023): 135927.
[36]

F. Rizzollo, S. More, P. Vangheluwe, and P. Agostinis, “The Lysosome as a Master Regulator of Iron Metabolism,” Trends in Biochemical Sciences 46 (2021): 960-975.
[37]

Z. Li, J.-T. Hou, S. Wang, L. Zhu, X. He, and J. Shen, “Recent Advances of Luminescent Sensors for Iron and Copper: Platforms, Mechanisms, and Bio-applications,” Coordination Chemistry Reviews 469 (2022): 214695.
[38]

Y.-L. Qi, H.-R. Wang, L.-L. Chen, Y.-T. Duan, S.-Y. Yang, and H.-L. Zhu, “Recent Advances in Small-molecule Fluorescent Probes for Studying Ferroptosis,” Chemical Society Reviews 51 (2022): 7752-7778.
[39]

Y. Duo, G. Luo, W. Zhang, et al., “Noncancerous Disease-targeting AIEgens,” Chemical Society Reviews 52 (2023): 1024-1067.
[40]

W. Guo, T. Peng, W. Zhu, et al., “Visualization of Supramolecular Assembly by Aggregation-induced Emission,” Aggregate 4 (2023): e297.
[41]

J. Tan, C. Wang, Z. Hu, and X. Zhang, “Wash-free Fluorescent Tools Based on Organic Molecules: Design Principles and Biomedical Applications,” Exploration 5 (2025): 20230094.
[42]

W. He, T. Zhang, H. Bai, R. T. K. Kwok, J. W. Y. Lam, and B. Z. Tang, “Recent Advances in Aggregation-Induced Emission Materials and Their Biomedical and Healthcare Applications,” Advanced Healthcare Materials 10 (2021): 2101055.
[43]

X. Cai and B. Liu, “Aggregation-Induced Emission: Recent Advances in Materials and Biomedical Applications,” Angewandte Chemie International Edition 59 (2020): 9868-9886.
[44]

X. Nie, W. Huang, D. Zhou, et al., “Kinetic and Thermodynamic Control of Tetraphenylethene Aggregation-induced Emission Behaviors: Nanoscience: Special Issue Dedicated to Professor Paul S. Weiss,” Aggregate 3 (2022): e165.
[45]

Y. Wang, Y. Zhang, J. Wang, and X.-J. Liang, “Aggregation-induced Emission (AIE) Fluorophores as Imaging Tools to Trace the Biological Fate of Nano-based Drug Delivery Systems,” Advanced Drug Delivery Reviews 143 (2019): 161-176.
[46]

Z. Zhu, S. Liu, X. Wu, et al., “An Azo Substituted Quinoline-malononitrile Enzyme-activable Aggregation-induced Emission Nanoprobe for Hypoxia Imaging,” Smart Molecules 3 (2025): e20240028.
[47]

Y. Zhang, R. Cai, Y. Ding, et al., “Synthesis and Evaluation of Smart Drugs With Integrated Functions for Identifying and Treating Oxidative Microenvironments Associated With Cellular Ferroptosis,” Smart Molecules 3 (2025): e20240048.
[48]

J. Qian and B. Z. Tang, “AIE Luminogens for Bioimaging and Theranostics: From Organelles to Animals,” Chemistry 3 (2017): 56-91.
[49]

G. Niu, R. Zhang, X. Shi, et al., “AIE Luminogens as Fluorescent Bioprobes,” TrAC Trends in Analytical Chemistry 123 (2020): 115769.
[50]

J. Li, J. Wang, H. Li, N. Song, D. Wang, and B. Z. Tang, “Supramolecular Materials Based on AIE Luminogens (AIEgens): Construction and Applications,” Chemical Society Reviews 49 (2020): 1144-1172.
[51]

H. Nie, Z. Wei, X.-L. Ni, and Y. Liu, “Assembly and Applications of Macrocyclic-Confinement-Derived Supramolecular Organic Luminescent Emissions From Cucurbiturils,” Chemical Reviews 122 (2022): 9032-9077.
[52]

Y. Luo, S. Gan, W. Zhang, et al., “A New Cucurbit[10]Uril-based AIE Fluorescent Supramolecular Polymer for Cellular Imaging,” Materials Chemistry Frontiers 6 (2022): 1021-1025.
[53]

W. Zhang, Y. Luo, J. Zhao, et al., “tQ[14]-based AIE Supramolecular Network Polymers as Potential Bioimaging Agents for the Detection of Fe3+ in Live HeLa Cells,” Sensors & Actuators, B: Chemical 354 (2022): 131189.
[54]

S. Behzadi, V. Serpooshan, W. Tao, et al., “Cellular Uptake of Nanoparticles: Journey inside the Cell,” Chemical Society Reviews 46 (2017): 4218-4244.
[55]

M. Yan, S. Wu, Y. Wang, et al., “Recent Progress of Supramolecular Chemotherapy Based on Host-Guest Interactions,” Advanced Materials 36 (2024): 2304249.
[56]

G. Cheng, J. Luo, Y. Liu, X. Chen, Z. Wu, and T. Chen, “Cucurbituril-Oriented Nanoplatforms in Biomedical Applications,” ACS Applied Bio Materials 3 (2020): 8211-8240.
[57]

Z. Wang, C. Sun, K. Yang, X. Chen, and R. Wang, “Cucurbituril-Based Supramolecular Polymers for Biomedical Applications,” Angewandte Chemie International Edition 134 (2022): e202206763.
[58]

R. H. Gao, L. X. Chen, K. Chen, Z. Tao, and X. Xiao, “Development of Hydroxylated Cucurbit[n]Urils, Their Derivatives and Potential Applications,” Coordination Chemistry Reviews 348 (2017): 1-24.
[59]

Q. Wang, K.-N. Wei, S.-Z. Huang, Q. Tang, Z. Tao, and Y. Huang, “Turn-Off' Supramolecular Fluorescence Array Sensor for Heavy Metal Ion Identification,” ACS Omega 6 (2021): 31229-31235.
[60]

S. Zhang, L. Grimm, Z. Miskolczy, L. Biczók, F. Biedermann, and W. M. Nau, “Binding Affinities of Cucurbit[n]Urils With Cations,” Chemical Communications 55 (2019): 14131-14134.
[61]

H. N. Kim, B.-R. Seo, H. Kim, and J.-Y. Koh, “Cilostazol Restores Autophagy Flux in Bafilomycin A1-treated, Cultured Cortical Astrocytes Through Lysosomal Reacidification: Roles of PKA, Zinc and Metallothionein 3,” Scientific Reports 10 (2020): 9175.
[62]

M. H. Keuters, V. Keksa-Goldsteine, H. Dhungana, et al., “An Arylthiazyne Derivative Is a Potent Inhibitor of Lipid Peroxidation and Ferroptosis Providing Neuroprotection in Vitro and in Vivo,” Scientific Reports 11 (2021): 3518.
[63]

K. Cheng, G. Yang, M. Huang, Y. Huang, and C. Wang, “Exogenous 1,25(OH)2D3/VD3 Counteracts RSL3-Induced Ferroptosis by Enhancing Antioxidant Capacity and Regulating Iron Ion Transport: Using Zebrafish as a Model,” Chemico-Biological Interactions 387 (2024): 110828.
[64]

M. Xu, Y. Li, D. Meng, et al., “6-Hydroxydopamine Induces Abnormal Iron Sequestration in BV2 Microglia by Activating Iron Regulatory Protein 1 and Inhibiting Hepcidin Release,” Biomolecules 12 (2022): 266.
[65]

Z. Yao, F. Jia, S. Wang, et al., “The Involvement of IRP2-induced Ferroptosis Through the p53-SLC7A11-ALOX12 Pathway in Parkinson's Disease,” Free Radical Biology and Medicine 222 (2024): 386-396.
[66]

M. T. Ibarra-Gutiérrez, N. Serrano-García, and M. Orozco-Ibarra, “Rotenone-Induced Model of Parkinson's Disease: Beyond Mitochondrial Complex I Inhibition,” Molecular Neurobiology 60 (2023): 1929-1948.
[67]

L. Hu, Q. Lan, C. Tang, et al., “Abnormalities of Serum Lipid Metabolism in Patients With Acute Paraquat Poisoning Caused by Ferroptosis,” Ecotoxicology and Environmental Safety 266 (2023): 115543.
[68]

Z. Chen, N. Zheng, F. Wang, et al., “The Role of Ferritinophagy and Ferroptosis in Alzheimer's Disease,” Brain Research 1850 (2025): 149340.
[69]

M. Tang, Z. Chen, D. Wu, and L. Chen, “Ferritinophagy/Ferroptosis: Iron-related Newcomers in human Diseases,” Journal of Cellular Physiology 233 (2018): 9179-9190.
[70]

L. Ma, Y. Zhao, Y. Chen, B. Cheng, A. Peng, and K. Huang, “Caenorhabditis elegans as a Model System for Target Identification and Drug Screening Against Neurodegenerative Diseases,” European Journal of Pharmacology 819 (2018): 169-180.
[71]

T. Herraiz, “N-methyltetrahydropyridines and Pyridinium Cations as Toxins and Comparison With Naturally-occurring Alkaloids,” Food and Chemical Toxicology 97 (2016): 23-39.
[72]

H. Cong, J. Hu, J. Wang, et al., “Bromocriptine Mesylate-loaded Nanoparticles co-modified With Low Molecular Weight Protamine and Lactoferrin for Enhanced Nose-to-brain Delivery in Parkinson's disease Treatment,” International Journal of Pharmaceutics 669 (2025): 125054.
[73]

Q. Huang, Y. Chen, W. Zhang, et al., “Nanotechnology for Enhanced Nose-to-brain Drug Delivery in Treating Neurological Diseases,” Journal of Controlled Release 366 (2024): 519-534.

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