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Journal of Biomolecular Structure and Dynamics Volume 25, 2007 - Issue 2
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Original Articles

Molecular Dynamics Simulations of Human Cystatin C and Its L68Q Varient to Investigate the Domain Swapping Mechanism

Hsuan-Liang Liu Department of Chemical Engineering and Biotechnology; Graduate Institute of Biotechnology National Taipei University of Technology, 1 Sec. 3 ZhongXiao E. Rd., Taipei, Taiwan, 10608
,
Yuan-Min Lin Department of Chemical Engineering and Biotechnology
,
Jian-Hua Zhao Department of Chemical Engineering and Biotechnology
,
Man-Ching Hsieh Graduate Institute of Biotechnology National Taipei University of Technology, 1 Sec. 3 ZhongXiao E. Rd., Taipei, Taiwan, 10608
,
Hsin-Yi Lin Graduate Institute of Biotechnology National Taipei University of Technology, 1 Sec. 3 ZhongXiao E. Rd., Taipei, Taiwan, 10608
,
Chih-Hung Huang Graduate Institute of Biotechnology National Taipei University of Technology, 1 Sec. 3 ZhongXiao E. Rd., Taipei, Taiwan, 10608
,
Hsu-Wei Fang Graduate Institute of Biotechnology National Taipei University of Technology, 1 Sec. 3 ZhongXiao E. Rd., Taipei, Taiwan, 10608
,
Yih Ho School of Pharmacy Taipei Medical University, 250 Wu-Hsing St., Taipei, Taiwan, 110
&
Wen-Yih Chen Department of Chemical and Materials Engineering, National Central University, 300 Jhongda Rd., Jhongli City, Taoyuan County, Taiwan, 32001
 show all
Pages 135-144 | Received 23 May 2007, Published online: 15 May 2012
 
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Abstract

Human cystatin C variant (L68Q), one of the amyloidgenic proteins, has been shown to form dimeric structure spontaneously via domain swapping and easily cause amyloid deposits in the brains of patients suffering from Alzheimer's disease or hereditary cystatin C amyloid angiopathy. The monomeric L68Q and wild-type (wt) HCCs share similar structural feature consisting of a core with a five-stranded anti-parallel β-sheet (β-region) wrapped around a central helix. In this study, various molecular dynamics simulations were conducted to investigate the conformational fluctuations of the monomeric L68Q and wt HCCs at various combinations of temperature (300 and 500K) and pH (2 and 7) to gain insights into the domain swapping mechanism. The results show that elevated temperature accelerates the disruption of the hydrophobic core and acidic condition promotes the destruction of three salt bridges between β2 and β3 in both HCCs. The results also indicate that the interior hydrophobic core of the L68Q variant is relatively unstable, leading to domain swapping more readily comparing to wt HCC under conditions favoring this process. However, these two monomeric HCCs adopt the same mechanism of domain swapping as follows: (i) first, the interior hydrophobic core is disrupted; (ii) subsequently, the central helix departs from the β-region; (iii) then, the β2-L1-β3 hairpin structure unfolds following the so-called “zip-up” mechanism; and (iv) finally, the open form HCC is generated.

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