Abstract

Apolipoprotein A-I (apoAI) is a 243-residue exchangeable apolipoprotein that plays a key role in clearing the """"""""bad cholesterol"""""""" from the human blood stream. Depending on the extent of lipidation, apoAI may adopt one of four distinct conformations, including: (1). Lipid-free apoAI conformation (Specific phospholipid-binding). (2). ApoAI on pre-beta-HDL (Specific cholesterol binding). (3). ApoAI on discoidal HDL (Specific LCAT activation). (4). ApoAI on spherical HDL (Specific SR-BI, the HDL-receptor, binding). The conformational plasticity indeed enables apoAI to perform multiple functions which regulate/direct HDL formation, maturation, transport and metabolism. Currently we do not have a clear understanding of how the apoAI structural domains allow for this structural plasticity. This proposal concentrates on determining the NMR structures/dynamics of the lipid-free and pre-beta-HDL-bound apoAl. Based on preliminary data and published results by other laboratories, the following hypotheses are proposed: (1). Lipid-free apoAI mainly adopts a helix-bundle structure. (2). Phospholipid-binding induces a dramatic conformational change of apoAI that exposes the hydrophobic sites for cholesterol binding. (3). ApoAI/DPC mimics the structure and functions of apoAI/pre-beta-HDL, thus may have therapeutical implications to atherosclerosis. In order to verify these hypotheses, we propose to solve the NMR structures of apoAI in three different states: (1). Lipid-free state, (2). ApoAI/DPC state, (3). ApoAI/pre-beta-HDL state. Functional characterizations of apoAI/DPC and apoAI/pre-beta-HDL will also be performed, in terms of cholesterol-binding activity. In addition, NMR techniques will be utilized to study structural dynamic of apoAI in these three states. These studies together may allow us to address the structural switching mechanism, which converts apoAl's conformation from one to another. It is anticipated that the structures of lipid-free and pre-beta-HDL bound apoAI will help in the understanding of how apoAI recruits lipid to initiate the HDL formation, and how apoAI promotes pre-beta-HDL to recruit more neutral lipids for the maturation of HDL. Since a low level of plasma HDL and a compromised HDL function are the common thread of metabolic disorders/diseases including: atherosclerosis, diabetes, obesity, stroke, and Alzheimer's disease, the results obtained from this proposal should have significant implications for the intervention of new medicine to treat these metabolic disorders/diseases.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
3R01HL076620-04S2
Application #
7850356
Study Section
Metabolism Study Section (MET)
Program Officer
Srinivas, Pothur R
Project Start
2004-04-01
Project End
2010-03-31
Budget Start
2009-06-01
Budget End
2010-03-31
Support Year
4
Fiscal Year
2009
Total Cost
$22,800
Indirect Cost

  Institution

Name
Wayne State University
Department
Biochemistry
Type
Schools of Medicine
DUNS #
001962224
City
Detroit
State
MI
Country
United States
Zip Code
48202

  Publications

Murray, Victoria; Huang, Yuefei; Chen, Jianglei et al. (2012) A novel bacterial expression method with optimized parameters for very high yield production of triple-labeled proteins. Methods Mol Biol 831:1-18
Chen, Jianglei; Liu, Chia-Chen; Li, Qianqian et al. (2011) Two structural and functional domains of MESD required for proper folding and trafficking of LRP5/6. Structure 19:313-23
Chen, Jianglei; Li, Qianqian; Liu, Chia-Chen et al. (2010) NMR structure note: solution structure of the core domain of MESD that is essential for proper folding of LRP5/6. J Biomol NMR 47:283-8
Sivashanmugam, Arun; Murray, Victoria; Cui, Chunxian et al. (2009) Practical protocols for production of very high yields of recombinant proteins using Escherichia coli. Protein Sci 18:936-48
Chen, Bin; Ren, Xuefeng; Neville, Tracey et al. (2009) Apolipoprotein AI tertiary structures determine stability and phospholipid-binding activity of discoidal high-density lipoprotein particles of different sizes. Protein Sci 18:921-35
Sivashanmugam, Arun; Yang, Yunhuang; Murray, Victoria et al. (2008) Structural basis of human high-density lipoprotein formation and assembly at sub nanometer resolution. Methods Cell Biol 90:327-64
Carnemolla, Ronald; Ren, Xuefeng; Biswas, Tapan K et al. (2008) The specific amino acid sequence between helices 7 and 8 influences the binding specificity of human apolipoprotein A-I for high density lipoprotein (HDL) subclasses: a potential for HDL preferential generation. J Biol Chem 283:15779-88
Chen, Jianglei; Bu, Guojun; Wang, Jianjun (2007) A complete NMR spectral assignment of the conserved region of the MESD protein, MESD(12-155). Biomol NMR Assign 1:3-5
Ren, Xuefeng; Yang, Yunhuang; Neville, Tracey et al. (2007) A complete backbone spectral assignment of human apolipoprotein AI on a 38 kDa prebetaHDL (Lp1-AI) particle. Biomol NMR Assign 1:69-71
Yang, Yunhuang; Hoyt, David; Wang, Jianjun (2007) A complete NMR spectral assignment of the lipid-free mouse apolipoprotein A-I (apoAI) C-terminal truncation mutant, apoAI(1-216). Biomol NMR Assign 1:109-11

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