Bioluminescence Imaging with Functional Amyloid Reservoirs in Alzheimer’s Disease Models

Bioluminescence Imaging with Functional Amyloid Reservoirs in Alzheimer’s Disease Models

Bioluminescence imaging has changed the daily practice of preclinical research on cancer and other diseases over the last few decades; however, it has rarely been applied in preclinical research on Alzheimer’s disease (AD). In this Article, we demonstrated that bioluminescence imaging could be used...

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Veröffentlicht in:Analytical chemistry (Washington) 2023-09, Vol.95 (38), p.14261-14270
Hauptverfasser: Yang, Jing, Ding, Weihua, Zhu, Biyue, Zhen, Sherri, Kuang, Shi, Yang, Jun, Zhang, Can, Wang, Peng, Yang, Fan, Yang, Liuyue, Yin, Wei, Tanzi, Rudolph E., Shen, Shiqian, Ran, Chongzhao
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Alzheimer's disease
amyloid
Analytical chemistry
Bioluminescence
brain
Chemistry
Fibrils
genetically modified organisms
In vivo methods and tests
Infrared windows
luciferase
Medical imaging
Neurodegenerative diseases
Neuroimaging
Plaques
Secretase
Sequestering
Substrates
therapeutics
Transgenic mice
β-Amyloid
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container_end_page 14270
container_issue 38
container_start_page 14261
container_title Analytical chemistry (Washington)
container_volume 95
creator Yang, Jing
Ding, Weihua
Zhu, Biyue
Zhen, Sherri
Kuang, Shi
Yang, Jun
Zhang, Can
Wang, Peng
Yang, Fan
Yang, Liuyue
Yin, Wei
Tanzi, Rudolph E.
Shen, Shiqian
Ran, Chongzhao
description Bioluminescence imaging has changed the daily practice of preclinical research on cancer and other diseases over the last few decades; however, it has rarely been applied in preclinical research on Alzheimer’s disease (AD). In this Article, we demonstrated that bioluminescence imaging could be used to report the levels of amyloid beta (Aβ) species in vivo. We hypothesized that AkaLumine, a newly discovered substrate for luciferase, could bind to Aβ aggregates and plaques. We further speculated that the Aβ aggregates/fibrils/plaques could be considered as “functional amyloids”, which have a reservoir function to sequester and release AkaLumine to control the bioluminescence intensity, which could be used to report the levels of Aβs. Our hypotheses have been validated via in vitro solution tests, mimic studies with brain tissues and mice, two-photon imaging with AD mice, and in vivo bioluminescence imaging using transgenic AD mice that were virally transduced with AkaLuciferase (AkaLuc), a new luciferase that generates bioluminescence in the near-infrared window. As expected, compared to the control group, we observed that the Aβ group showed lower bioluminescence intensity due to AkaLumine sequestering at early time points, while higher intensity was due to AkaLumine releasing at later time points. Lastly, we demonstrated that this method could be used to monitor AD progression and the therapeutic effectiveness of avagacestat, a well-studied gamma-secretase inhibitor. Importantly, a good correlation (R 2 = 0.81) was established between in vivo bioluminescence signals and Aβ burdens of the tested AD mice. We believe that our approach can be easily implemented into daily imaging experiments and has tremendous potential to change the daily practice of preclinical AD research.
doi_str_mv 10.1021/acs.analchem.3c02358
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Chem</addtitle><description>Bioluminescence imaging has changed the daily practice of preclinical research on cancer and other diseases over the last few decades; however, it has rarely been applied in preclinical research on Alzheimer’s disease (AD). In this Article, we demonstrated that bioluminescence imaging could be used to report the levels of amyloid beta (Aβ) species in vivo. We hypothesized that AkaLumine, a newly discovered substrate for luciferase, could bind to Aβ aggregates and plaques. We further speculated that the Aβ aggregates/fibrils/plaques could be considered as “functional amyloids”, which have a reservoir function to sequester and release AkaLumine to control the bioluminescence intensity, which could be used to report the levels of Aβs. 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Chem</addtitle><date>2023-09-26</date><risdate>2023</risdate><volume>95</volume><issue>38</issue><spage>14261</spage><epage>14270</epage><pages>14261-14270</pages><issn>0003-2700</issn><issn>1520-6882</issn><eissn>1520-6882</eissn><abstract>Bioluminescence imaging has changed the daily practice of preclinical research on cancer and other diseases over the last few decades; however, it has rarely been applied in preclinical research on Alzheimer’s disease (AD). In this Article, we demonstrated that bioluminescence imaging could be used to report the levels of amyloid beta (Aβ) species in vivo. We hypothesized that AkaLumine, a newly discovered substrate for luciferase, could bind to Aβ aggregates and plaques. We further speculated that the Aβ aggregates/fibrils/plaques could be considered as “functional amyloids”, which have a reservoir function to sequester and release AkaLumine to control the bioluminescence intensity, which could be used to report the levels of Aβs. Our hypotheses have been validated via in vitro solution tests, mimic studies with brain tissues and mice, two-photon imaging with AD mice, and in vivo bioluminescence imaging using transgenic AD mice that were virally transduced with AkaLuciferase (AkaLuc), a new luciferase that generates bioluminescence in the near-infrared window. As expected, compared to the control group, we observed that the Aβ group showed lower bioluminescence intensity due to AkaLumine sequestering at early time points, while higher intensity was due to AkaLumine releasing at later time points. Lastly, we demonstrated that this method could be used to monitor AD progression and the therapeutic effectiveness of avagacestat, a well-studied gamma-secretase inhibitor. Importantly, a good correlation (R 2 = 0.81) was established between in vivo bioluminescence signals and Aβ burdens of the tested AD mice. 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source American Chemical Society Journals
subjects Aggregates
Alzheimer's disease
amyloid
Analytical chemistry
Bioluminescence
brain
Chemistry
Fibrils
genetically modified organisms
In vivo methods and tests
Infrared windows
luciferase
Medical imaging
Neurodegenerative diseases
Neuroimaging
Plaques
Secretase
Sequestering
Substrates
therapeutics
Transgenic mice
β-Amyloid
title Bioluminescence Imaging with Functional Amyloid Reservoirs in Alzheimer’s Disease Models
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