Nanoscopic Insights of Amphiphilic Peptide against the Oligomer Assembly Process to Treat Huntington's Disease

Ruei-Yu He; Xiang-Me Lai; Chia-Sui Sun; Te-Shien Kung; Jhu-Ying Hong; Yu-Song Jheng; Wei-Neng Liao; Jen-Kun Chen; Yung-Feng Liao; Pang-Hsien Tu; Joseph Jen-Tse Huang

doi:10.1002/advs.201901165

Nanoscopic Insights of Amphiphilic Peptide against the Oligomer Assembly Process to Treat Huntington's Disease

Adv Sci (Weinh). 2019 Dec 9;7(2):1901165. doi: 10.1002/advs.201901165. eCollection 2020 Jan.

Authors

Ruei-Yu He¹, Xiang-Me Lai^{2

3}, Chia-Sui Sun¹, Te-Shien Kung^{1

4}, Jhu-Ying Hong¹, Yu-Song Jheng², Wei-Neng Liao⁵, Jen-Kun Chen^{3

5}, Yung-Feng Liao⁶, Pang-Hsien Tu^{2

3}, Joseph Jen-Tse Huang¹

Affiliations

¹ Institute of Chemistry Academia Sinica Taipei 11529 Taiwan.
² Institute of Biomedical Sciences Academia Sinica Taipei 11529 Taiwan.
³ Division of Urology Department of Surgery Tri-Service General Hospital National Defense Medical Center Taipei 11490 Taiwan.
⁴ Department of Chemical Engineering National Taiwan University of Science and Technology Taipei 10607 Taiwan.
⁵ Institute of Biomedical Engineering and Nanomedicine National Health Research Institutes Miaoli 35053 Taiwan.
⁶ Institute of Cellular and Organismic Biology Academia Sinica Taipei 11529 Taiwan.

Abstract

Finding an effective therapeutic regimen is an urgent demand for various neurodegenerative disorders including Huntington's disease (HD). For the difficulties in observing the dynamic aggregation and oligomerization process of mutant Huntingtin (mHtt) in vivo, the evaluation of potential drugs at the molecular protein level is usually restricted. By combing lifetime-based fluorescence microscopies and biophysical tools, it is showcased that a designed amphiphilic peptide, which targets the mHtt at an early stage, can perturb the oligomer assembly process nanoscopically, suppress the amyloid property of mHtt, conformationally transform the oligomers and/or aggregates of mHtt, and ameliorate mHtt-induced neurological damage and aggregation in cell and HD mouse models. It is also found that this amphiphilic peptide is able to transport to the brain and rescue the memory deficit through intranasal administration, indicating its targeting specificity in vivo. In summary, a biophotonic platform is provided to investigate the oligomerization/aggregation process in detail that offers insight into the design and effect of a targeted therapeutic agent for Huntington's disease.

Keywords: Huntington's disease; amphiphilic peptides; fluorescence lifetime imaging; intranasal administration; oligomer assembly.