Twinkle Light-Inspired Aggregation-Induced Emission “Lighting-Up” Bacteriophages to Enhance Immunoassays via Spontaneous Amino-Yne Click Reaction

Xiaoyi Lv , Xirui Chen , Qi Chen , Qing Liu , Mingjian Yao , Weipeng Tong , Hao Fang , Yiping Chen , Yonghua Xiong , Ben Zhong Tang , Xiaolin Huang

Aggregate ›› 2025, Vol. 6 ›› Issue (9) : e70097

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Aggregate ›› 2025, Vol. 6 ›› Issue (9) : e70097 DOI: 10.1002/agt2.70097
RESEARCH ARTICLE

Twinkle Light-Inspired Aggregation-Induced Emission “Lighting-Up” Bacteriophages to Enhance Immunoassays via Spontaneous Amino-Yne Click Reaction

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Abstract

Traditional fluorescence immunoassays are often hindered by false negatives or quantification inaccuracies, especially at high target concentrations, due to the aggregation-caused quenching effect of fluorescent indicators. This study introduces a novel fluorescence immunoassay strategy that leverages the spontaneous amino-yne click reaction to covalently assemble activated alkyne-based luminogens with aggregation-induced emission characteristics (AIEgens) onto the surface of bifunctional M13 bacteriophages, thereby facilitating efficient “lighting-up” fluorescence signal output in conjunction with magnetic-mediated immunorecognition. To further enhance the load of activated alkyne-based AIEgens and improve the fluorescence “lighting-up” efficiency, M13 bacteriophages were engineered to display varying numbers of surface-exposed lysine residues. This was achieved by inserting different quantities of lysines between the signal peptide and the amino acid sequence of the pVIII protein via a point mutation strategy. Benefiting from the synergy of AIEgen stacking-enhanced fluorescence output and M13 bacteriophage-driven signal amplification, the developed “lighting-up” immunoassay enabled highly sensitive and rapid detection of targets, from small molecules to pathogenic microorganisms. This work provides valuable insights into the design of “lighting-up” AIEgens for enhancing fluorescence immunoassays. Moreover, the proposed strategy offers great versatility, allowing it to be readily adapted to detect other targets simply by pairing the target with the M13 bacteriophages.

Keywords

aggregation-induced emission / amino-yne click reaction / fluorescence immunoassay / M13 bacteriophage

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Xiaoyi Lv, Xirui Chen, Qi Chen, Qing Liu, Mingjian Yao, Weipeng Tong, Hao Fang, Yiping Chen, Yonghua Xiong, Ben Zhong Tang, Xiaolin Huang. Twinkle Light-Inspired Aggregation-Induced Emission “Lighting-Up” Bacteriophages to Enhance Immunoassays via Spontaneous Amino-Yne Click Reaction. Aggregate, 2025, 6(9): e70097 DOI:10.1002/agt2.70097

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References

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

G. Zhang, T. T. Liu, H. D. Cai, et al., “Molecular Engineering and Confinement Effect Powered Ultrabright Nanoparticles for Improving Sensitivity of Lateral Flow Immunoassay,” ACS Nano 18 (2024): 2346-2354.
[2]

J. J. Zhang, Y. Li, F. L. Chai, et al., “Ultrasensitive Point-Of-Care Biochemical Sensor Based on Metal-AIEgen Frameworks,” Science Advances 8 (2022): eabo1874.
[3]

J. Shu, Y. J. Li, H. Cai, et al., “Ultrabright NIR AIEgen Nanoparticles-Enhanced Lateral Flow Immunoassay Platform for Accurate Diagnostics of Complex Samples,” Aggregate 5 (2024): e551.
[4]

J. Y. Qiao, X. Y. Liu, L. R. Zhang, J. F. Eubank, X. Liu, and Y. L. Liu, “Unique Fluorescence Turn-On and Turn-Off-On Responses to Acids by a Carbazole-Based Metal-Organic Framework and Theoretical Studies,” Journal of the American Chemical Society 144 (2022): 17054-17063.
[5]

J. J. Pang, Z. Q. Yao, K. Zhang, et al., “Real-Time In Situ Volatile Organic Compound Sensing by a Dual-Emissive Polynuclear Ln-MOF With Pronounced Ln III Luminescence Response,” Angewandte Chemie International Edition 62 (2023): e202217456.
[6]

K. P. Lin, A. A. Liu, W. Zhao, et al., “Multihierarchical Regulation To Achieve Quantum Dot Nanospheres With a Photoluminescence Quantum Yield Close to 100%,” Journal of the American Chemical Society 146 (2024): 21348-21356.
[7]

C. M. Song, J. X. Liu, J. W. Li, and Q. Liu, “Dual FITC Lateral Flow Immunoassay for Sensitive Detection of Escherichia coli O157:H7 in Food Samples,” Biosensors & Bioelectronics 85 (2016): 734-739.
[8]

L. Huang, T. Liao, J. Wang, L. J. Ao, W. Su, and J. Hu, “Brilliant Pitaya-Type Silica Colloids With Central-Radial and High-Density Quantum Dots Incorporation for Ultrasensitive Fluorescence Immunoassays,” Advanced Functional Materials 28 (2018): 1705380.
[9]

Y. H. Wu, J. Y. Sun, X. L. Wang, et al., “Ultra-stable and Broadband Absorption Fe3O4-Gold/Polydopamine Nanohybrid Enabling Ultrasensitive Fluorescence Quenching Mediated Immunochromatography Assay,” Chemical Engineering Journal 503 (2025): 118353.
[10]

M. Asad, M. I. Anwar, A. Abbas, et al., “AIE Based Luminescent Porous Materials as Cutting-Edge Tool for Environmental Monitoring: State of the Art Advances and Perspectives,” Coordination Chemistry Reviews 463 (2022): 214539.
[11]

X. L. Huang, Q. Guo, R. Y. Zhang, et al., “AIEgens: An Emerging Fluorescent Sensing Tool to Aid Food Safety and Quality Control,” Comprehensive Reviews in Food Science and Food Safety 19 (2020): 2297-2329.
[12]

Y. N. Hong, W. Y. L. Jacky, and B. Z. Tang, “Aggregation-Induced Emission,” Chemical Society Reviews 40 (2011): 5361-5388.
[13]

Z. Y. Ye, W. He, Z. C. Zhang, Z. J. Qiu, Z. Zhao, and B. Z. Tang, “AIEgens for Microorganism-Related Visualization and Therapy,” Interdisciplinary Medicine 1 (2023): e20220011.
[14]

Y. N. Liao, Z. Peng, X. L. Liu, Y. B. Hu, and J. Zhang, “Theranostic Applications of Biomolecule-Responsive Aggregation-Induced Emission Luminogens,” Interdisciplinary Medicine 1 (2023): e20230024.
[15]

Y. Yu, W. W. Ni, Q. Hu, et al., “A Dual Fluorescence Turn-On Sensor Array Formed by Poly(Para-Aryleneethynylene) and Aggregation-Induced Emission Fluorophores for Sensitive Multiplexed Bacterial Recognition,” Angewandte Chemie International Edition 63 (2024): e202318483.
[16]

Y. Q. Guo, Y. F. Zhou, H. Duan, et al., “CRISPR/Cas-Mediated “One to More” Lighting-Up Nucleic Acid Detection Using Aggregation-Induced Emission Luminogens,” Nature Communications 15 (2024): 8560.
[17]

X. R. Chen, Q. M. Yang, X. Y. Lv, Y. H. Xiong, B. Z. Tang, and X. L. Huang, “Rational Design of Ratiometric Aggregation-Induced Emission Luminogens for Biosensing and Bioimaging,” Coordination Chemistry Reviews 516 (2024): 215970.
[18]

X. R. Chen, W. C. Zhan, H. Duan, et al., “Crescent-Shaped Janus Nanoassemblies of Gold Nanoparticles and AIEgens: Enhancing Plasmonic and Fluorescent Activities for Colorimetric and Ratiometric Fluorescence Lateral Flow Immunoassay,” Nano Today 58 (2024): 102452.
[19]

Y. Su, X. R. Chen, H. Huang, et al., “Rearranging Fluorescence-Magneto Spatiality for “Win-Win” Dual Functions to Enhance Point-Of-Care Diagnosis,” Aggregate 5 (2024): e459.
[20]

R. Chen, C. P. Ren, M. Liu, et al., “Early Detection of SARS-CoV-2 Seroconversion in Humans With Aggregation-Induced Near-Infrared Emission Nanoparticle-Labeled Lateral Flow Immunoassay,” ACS Nano 18 (2024): 2346-2354.
[21]

X. R. Chen, Z. W. Li, H. Duan, et al., “A Ligand-Directed Spatial Regulation to Structural and Functional Tunability in Aggregation-Induced Emission Luminogen-Functionalized Organic-Inorganic Nanoassemblies,” Advanced Materials 36 (2024): 2313381.
[22]

G. Zhang, S. Yu, J. Peng, Y. H. Xiong, L. M. Hu, and W. H. Lai, “Novel Reporter Based on Aggregation-Induced Emission Luminogens for Lateral Flow Immunoassay: A Mini Review,” Trends in Analytical Chemistry 183 (2025): 118098.
[23]

X. W. He, Y. J. Yang, Y. C. Guo, et al., “Phage-Guided Targeting, Discriminative Imaging, and Synergistic Killing of Bacteria by AIE Bioconjugates,” Journal of the American Chemical Society 142 (2020): 3959-3969.
[24]

S. Manivannan, S. Park, J. Jeong, and K. Kim, “Aggregation-Free Optical and Colorimetric Detection of Hg(II) With M13 Bacteriophage-Templated Au Nanowires,” Biosensors & Bioelectronics 161 (2020): 112237.
[25]

H. Peng and I. A. Chen, “Rapid Colorimetric Detection of Bacterial Species Through the Capture of Gold Nanoparticles by Chimeric Phages,” ACS Nano 13 (2019): 1244-1252.
[26]

M. Alarcon-Correa, J. P. Günther, J. Troll, et al., “Self-Assembled Phage-Based Colloids for High Localized Enzymatic Activity,” ACS Nano 13 (2019): 5810-5815.
[27]

H. Fang, Y. F. Zhou, Y. B. Ma, et al., “M13 Bacteriophage-Assisted Recognition and Signal Spatiotemporal Separation Enabling Ultrasensitive Light Scattering Immunoassay,” ACS Nano 17 (2023): 18596-18607.
[28]

S. Wu, L. N. Sheng, G. C. Kou, et al., “Double Phage Displayed Peptides Co-Targeting-Based Biosensor With Signal Enhancement Activity for Colorimetric Detection of Staphylococcus aureus,” Biosensors & Bioelectronics 249 (2024): 116005.
[29]

J. H. Lee, F. Xu, D. W. Domaille, C. Choi, S. Jin, and J. N. Cha, “M13 Bacteriophage as Materials for Amplified Surface Enhanced Raman Scattering Protein Sensing,” Advanced Functional Materials 24 (2014): 2079-2084.
[30]

C. X. Huang, J. P. Zhao, R. S. Lu, et al., “A Phage-Based Magnetic Relaxation Switching Biosensor Using Bioorthogonal Reaction Signal Amplification for Salmonella Detection in Foods,” Food Chemistry 400 (2023): 134035.
[31]

S. N. Zhan, H. Fang, Q. Chen, et al., “M13 Bacteriophage as Biometric Component for Orderly Assembly of Dynamic Light Scattering Immunosensor,” Biosensors & Bioelectronics 217 (2022): 114693.
[32]

J. H. Lee and J. N. Cha, “Amplified Protein Detection Through Visible Plasmon Shifts in Gold Nanocrystal Solutions From Bacteriophage Platforms,” Analytical Chemistry 83 (2011): 3516-3519.
[33]

J. H. Lee, D. W. Domaille, and J. N. Cha, “Amplified Protein Detection and Identification Through DNA-Conjugated M13 Bacteriophage,” ACS Nano 6 (2012): 5621-5626.
[34]

J. H. Lee, D. W. Domaille, and J. N. Cha, “Collagen Mimetic Peptide Engineered M13 bacteriophage for Collagen Targeting and Imaging in Cancer,” Biomaterials 35 (2014): 9236-9245.
[35]

C. C. Liu, H. T. Bai, B. Z. He, et al., “Functionalization of Silk by AIEgens Through Facile Bioconjugation: Full-Color Fluorescence and Long-Term Bioimaging,” Angewandte Chemie International Edition 60 (2021): 12424-12430.
[36]

X. R. Guo, F. Gao, F. B. Chen, et al., “Dynamic Enamine-One Bond Based Vitrimer Via Amino-Yne Click Reaction,” ACS Macro Letters 10 (2021): 1186-1190.
[37]

S. Y. Lv, C. Wang, K. Xue, et al., “Activated Alkyne-Enabled Turn-On Click Bioconjugation With Cascade Signal Amplification for Ultrafast and High-Throughput Antibiotic Screening,” Proceedings of the National Academy of Sciences of the United States of America 120 (2023): e2302367120.
[38]

B. Z. He, S. J. Zhen, Y. W. Wu, et al., “Cu(i)-Catalyzed Amino-Yne Click Polymerization,” Polymer Chemistry 7 (2016): 7375-7382.
[39]

M. J. Chao, S. M. Tai, X. X. Mao, et al., “Versatile and Efficient Fabrication of Signal “Turn-on” Lateral Flow Assay for Ultrasensitive Naked Eye Detection of Small Molecules Based on Self-assembled Fluorescent Gold Nanoclusters-Antigen Aggregates,” Aggregate 6 (2025): e644.
[40]

Q. L. Wei, C. X. Huang, P. Lu, X. Y. Zhang, and Y. P. Chen, “Combining Magnetic MOFs as a Highly Adsorbent With Homogeneous Chemiluminescent Immunosensor for Rapid and Ultrasensitive Determination of Ochratoxin A,” Journal of Hazardous Materials 441 (2023): 129960.
[41]

X. Q. Zou, C. C. Chen, X. L. Huang, X. L. Chen, L. Wang, and Y. H. Xiong, “Phage-Free Peptide ELISA for Ochratoxin A Detection Based on Biotinylated Mimotope as a Competing Antigen,” Talanta 146 (2016): 394-400.
[42]

Y. Zhang, X. R. Liao, G. G. Yu, et al., “Phage-Displayed Nanobody as a Sensitive Nanoprobe to Enhance Chemiluminescent Immunoassay for Cronobacter sakazakii Detection in Dairy Products,” Analytical Chemistry 95 (2023): 13698-13707.
[43]

G. Zhang, Z. Huang, L. W. Hu, et al., “Molecular Engineering Powered Dual-Readout Point-Of-Care Testing for Sensitive Detection of Escherichia coli O157:H7,” ACS Nano 17 (2023): 23723-23731.
[44]

X. L. Huang, Z. D. Xu, Y. Map, et al., “Gold Nanoparticle-Based Dynamic Light Scattering Immunoassay for Ultrasensitive Detection of Listeria monocytogenes in Lettuces,” Biosensors & Bioelectronics 66 (2015): 184-190.
[45]

M. J. McIvor, N. Karoonuthaisiri, R. Charlermroj, L. D. Stewart, C. T. Elliott, and I. R. Grant, “Phage Display-Derived Binders Able to Distinguish Listeria monocytogenes From Other Listeria Species,” PLoS ONE 8 (2013): e74312.

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2025 The Author(s). Aggregate published by SCUT, AIEI, and John Wiley & Sons Australia, Ltd.

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