TY - JOUR
T1 - Synthetic high-density lipoprotein nanodisks for targeted withalongolide delivery to adrenocortical carcinoma
AU - Kuai, Rui
AU - Subramanian, Chitra
AU - White, Peter T.
AU - Timmermann, Barbara N.
AU - Moon, James J.
AU - Cohen, Mark S.
AU - Schwendeman, Anna
N1 - Funding Information:
The authors acknowledge the following funding sources for support of this work: University of Michigan, Michigan Translational Research and Commercialization (MTRAC) grant (MSC and AS), University of Michigan Comprehensive Cancer Center support grant F030221 (MSC), and University of Michigan Department of Surgery, Research Advisory Committee (RAC) grant (CS and MSC). This work was partly funded by NIH T32 CA009672, R01 CA173292, R01-AI127070, R01-EB022563, R01-CA210273, U01-CA-120458, and R21 NS091555. Rui Kuai was supported in part by American Heart Association (AHA) predoctoral fellowship 15PRE25090050. The authors also acknowledge Grace Wang (University of Michigan) for help with histological analyses.
Publisher Copyright:
© 2017 Kuai et al.
PY - 2017/9/6
Y1 - 2017/9/6
N2 - Adrenocortical carcinoma (ACC) is a rare endocrine malignancy and has a 5-year survival rate of <35%. ACC cells require cholesterol for steroid hormone production, and this requirement is met via expression on the cell surface of a high level of SRB1, responsible for the uptake of high-density lipoproteins (HDLs), which carry and transport cholesterol in vivo. Here, we describe how this natural lipid carrier function of SRB1 can be utilized to improve the tumor-targeted delivery of a novel natural product derivative - with along olide A 4,19,27-triacetate (WGA-TA) - which has shown potent antitumor efficacy, but poor aqueous solubility. Our strategy was to use synthetic HDL (sHDL) nanodisks, which are effective in tumor-targeted delivery due to their smallness, long circulation half-life, documented safety, and ability to bind to SRB1. In this study, we prepared sHDL nanodisks using an optimized phospholipid composition combined with ApoA1 mimetic peptide (22A), which has previously been tested in clinical trials, to load WGA-TA. Following optimization, WGA-TA nanodisks showed drug encapsulation efficiency of 78%, a narrow particle size distribution (9.81±0.41 nm), discoid shape, and sustained drug release in phosphate buffered saline. WGA-TA-sHDL nanodisks exhibited higher cytotoxicity in the ACC cell line H295R half maximal inhibitory concentration ([IC50] 0.26±0.045 μM) than free WGA-TA (IC50 0.492±0.115 μM, P,0.05). Fluorescent dye-loaded sHDL nanodisks efficiently accumulated in H295R adrenal carcinoma xenografts 24 hours following dosing. Moreover, daily intraperitoneal administration of 7 mg/kg WGA-TA-loaded sHDL nanodisks significantly inhibited tumor growth during 21-day administration to H295R xenograft-bearing mice compared to placebo (P,0.01). Collectively, these results suggest that WGA-TA-loaded nanodisks may represent a novel and beneficial therapeutic strategy for the treatment of ACC.
AB - Adrenocortical carcinoma (ACC) is a rare endocrine malignancy and has a 5-year survival rate of <35%. ACC cells require cholesterol for steroid hormone production, and this requirement is met via expression on the cell surface of a high level of SRB1, responsible for the uptake of high-density lipoproteins (HDLs), which carry and transport cholesterol in vivo. Here, we describe how this natural lipid carrier function of SRB1 can be utilized to improve the tumor-targeted delivery of a novel natural product derivative - with along olide A 4,19,27-triacetate (WGA-TA) - which has shown potent antitumor efficacy, but poor aqueous solubility. Our strategy was to use synthetic HDL (sHDL) nanodisks, which are effective in tumor-targeted delivery due to their smallness, long circulation half-life, documented safety, and ability to bind to SRB1. In this study, we prepared sHDL nanodisks using an optimized phospholipid composition combined with ApoA1 mimetic peptide (22A), which has previously been tested in clinical trials, to load WGA-TA. Following optimization, WGA-TA nanodisks showed drug encapsulation efficiency of 78%, a narrow particle size distribution (9.81±0.41 nm), discoid shape, and sustained drug release in phosphate buffered saline. WGA-TA-sHDL nanodisks exhibited higher cytotoxicity in the ACC cell line H295R half maximal inhibitory concentration ([IC50] 0.26±0.045 μM) than free WGA-TA (IC50 0.492±0.115 μM, P,0.05). Fluorescent dye-loaded sHDL nanodisks efficiently accumulated in H295R adrenal carcinoma xenografts 24 hours following dosing. Moreover, daily intraperitoneal administration of 7 mg/kg WGA-TA-loaded sHDL nanodisks significantly inhibited tumor growth during 21-day administration to H295R xenograft-bearing mice compared to placebo (P,0.01). Collectively, these results suggest that WGA-TA-loaded nanodisks may represent a novel and beneficial therapeutic strategy for the treatment of ACC.
KW - Adrenocortical carcinomas
KW - Nanodisks
KW - Scavenger receptor class B
KW - Synthetic high-density lipoproteins
KW - Targeted delivery
KW - Withalongolides
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U2 - 10.2147/IJN.S140591
DO - 10.2147/IJN.S140591
M3 - Article
C2 - 28919755
AN - SCOPUS:85029169281
SN - 1176-9114
VL - 12
SP - 6581
EP - 6594
JO - International journal of nanomedicine
JF - International journal of nanomedicine
ER -