Neuroprotection against apoptosis of SK-N-MC cells using RMP-7- and lactoferrin-grafted liposomes carrying quercetin
Authors Kuo Y, Tsao C
Received 16 January 2017
Accepted for publication 20 March 2017
Published 7 April 2017 Volume 2017:12 Pages 2857—2869
Checked for plagiarism Yes
Review by Single anonymous peer review
Peer reviewer comments 3
Editor who approved publication: Dr Lei Yang
Yung-Chih Kuo, Chien-Wei Tsao
Department of Chemical Engineering, National Chung Cheng University, Chia-Yi, Taiwan, Republic of China
Abstract: A drug delivery system of quercetin (QU)-encapsulated liposomes (LS) grafted with RMP-7, a bradykinin analog, and lactoferrin (Lf) was developed to permeate the blood–brain barrier (BBB) and rescue degenerated neurons, acting as an Alzheimer’s disease (AD) pharmacotherapy. This colloidal formulation of QU-encapsulated LS grafted with RMP-7 and Lf (RMP-7-Lf-QU-LS) was used to traverse human brain microvascular endothelial cells (HBMECs) regulated by human astrocytes (HAs) and to treat SK-N-MC cells after an insult with cytotoxic β-amyloid (Aβ) fibrils. We found that surface RMP-7 and Lf enhanced the ability of QU to cross the BBB without inducing strong toxicity and damaging the tight junction. In addition, RMP-7-Lf-QU-LS significantly reduced Aβ-induced neurotoxicity and improved the viability of SK-N-MC cells. Compared with free QU, RMP-7-Lf-QU-LS could also significantly inhibit the expression of phosphorylated c-Jun N terminal kinase, phosphorylated p38, and phosphorylated tau protein at serine 202 by SK-N-MC cells, indicating an important role of RMP-7, Lf, and LS in protecting neurons against apoptosis. RMP-7-Lf-QU-LS is a promising carrier targeting the BBB to prevent Aβ-insulted neurodegeneration and may have potential in managing AD in future clinical applications.
Keywords: Alzheimer’s disease, blood–brain barrier, β-amyloid, drug targeting, neurodegeneration, pharmacotherapy
Alzheimer’s disease (AD) is one of the most serious neurodegenerative disorders in the world today.1 The most common symptom of AD is irreversible dementia, including chronic memory loss, episodic confusion about time and/or place, cognitive impairment, and personality change.2 AD patients also exhibited an atrophic change in brain parenchyma, arteriosclerotic tissue, and entanglement of neurofibrils in cerebral neurons.3 Molecular biology has shown that two major anatomical components responsible for AD pathology are deposited β-amyloid (Aβ) of abnormal senile plaques and hyperphosphorylated tau protein of cholinergic neurons in the hippocampus.4,5 In light of the pathological features, an apoptotic cell model to assist in understanding neurodegeneration would be of practical use for AD therapy. For example, cholinergic SK-N-MC cells with active neurochemical traits could be an eligible culture for this purpose because their α7 nicotinic acetylcholine receptors can recognize and internalize Aβ.6,7 A neuroprotective analysis of Aβ-induced cytotoxicity also validated SK-N-MC cells as a useful system for AD-related study.8 In addition to the neuronal model, various drugs have been developed for pharmacotherapy in AD management. Quercetin (QU), for instance, had an antioxidative ability to eliminate free radicals and could ameliorate cognitive and memory dysfunction.9–12 However, problems, including low solubility in the blood, rapid metabolism in the intestine and liver, and low uptake in the brain, have considerably restrained clinical application of QU.13 Hence, a modification with bioactive molecules to mediate the brain distribution of QU can be a possible approach to alleviating AD progression.
RMP-7, a bradykinin analog with a molecular weight of 1,096 Da, has higher selectivity in binding to the blood–brain barrier (BBB) than bradykinin and can stimulate the expression of B2 bradykinin receptors in the neural tissue.14 In fact, RMP-7 could facilitate the infiltration of pharmaceuticals into the central nervous system and might also regulate the tight junction opening of the BBB.15 In addition, liposomes (LS) associated with RMP-7 could accelerate delivery of Evans blue across the BBB.16 Lactoferrin (Lf), a member of the transferrin family, is a vital biomolecule in the blood that regulates immunological response, inflammation, and cell differentiation.17 Lf receptor (LfR) on human brain microvascular endothelial cells (HBMECs) activates receptor-mediated transcytosis for BBB permeation and controls neuronal physiology in the AD brain.18,19 It was reported that Lf could benefit the transport of anticancer medicine-loaded polymeric nanoparticles to brain tumor.20 Thus, RMP-7 and Lf may qualify as ingredients in pharmaceutical formulations for AD medication. Furthermore, the combined use of RMP-7 with Lf in brain targeting has never been reported. In a drug carrier system, RMP-7 and transferrin were used to improve the permeability of macromolecular nerve growth factor across the BBB.21 It is intriguing that the brain uptake of Lf was higher than that of transferrin, implying a higher efficiency of the former in permeating the BBB.22
The aim of this study was to develop QU-encapsulated LS grafted with RMP-7 and Lf (RMP-7-Lf-QU-LS) for use in neuroprotection in AD management. Since the bioavailability of QU in the brain is a critical issue in treating neurodegeneration, the influence of dual targeting on BBB permeability using RMP-7-Lf-QU-LS was investigated. RMP-7-grafted LS has been investigated previously; however, this study highlights the combination of RMP-7 and Lf on LS containing complicated lipid components for carrying and releasing QU. In addition, RMP-7-Lf-QU-LS was used to inhibit apoptotic progress and rescue neurons after an insult with Aβ, because Aβ plaques attack neurons in the degenerated AD brain. We especially examined the effect of RMP-7-Lf-QU-LS on the viability of Aβ-insulted SK-N-MC cells and on the neuronal expression of phosphorylated c-Jun N terminal kinase (p-JNK), phosphorylated p38 (p-p38), and phosphorylated tau protein at serine 202 (p-S202).
Materials and methods
1,2-Dipalmitoyl-sn-glycero-3-phosphocholine (DPPC), 1′,3′-bis[1,2-dimyristoyl-sn-glycero-3-phospho]-sn-glycerol (cardiolipin [CL]), 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N-[carboxy(polyethylene glycol)-2000] (DSPE-PEG(2000)-CA), and polycarbonate membrane were purchased from Avanti Polar Lipids (Alabaster, AL, USA). Soybean phosphatidylcholine (SPC), stearylamine (SA), cholesterol, fluorescein isothiocyanate (FITC)-conjugated dextran 70000, Dulbecco’s phosphate-buffered saline (DPBS), 2-(N-morpholino)ethanesulfonic acid (MES), 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), Lf, QuantiPro bicinchoninic acid (BCA) assay kit, phosphotungstic acid (PTA), sodium azide, propidium iodide (PI), formalin, 4′,6-diamidino-2-phenylindole (DAPI), sodium dodecyl sulfate (SDS), and polyacrylamide gel (PAG) were obtained from Sigma-Aldrich (St Louis, MO, USA). HBMECs were purchased from Biocompare (South San Francisco, CA, USA). Human astrocytes (HAs), endothelial cell medium (ECM), and astrocyte medium were obtained from Sciencell (Carlsbad, CA, USA). SK-N-MC cells from human neuroblastoma were purchased from American Type Tissue Collection (Rockville, MD, USA). Anti-LfR monoclonal antibody, goat anti-mouse polyclonal secondary antibody immunoglobulin G (heavy and light) (IgG (H + L)) conjugated with rhodamine, lysis buffer, anti-JNK (phospho T183 and Y185) (anti-p-JNK), goat anti-rabbit IgG (H + L) (horseradish peroxidase [HRP]), and anti-Aβ monoclonal antibody were obtained from Abcam (Cambridge, MA, USA). Sephadex G-100, polyvinylidene fluoride (PVDF), enhanced chemiluminescence (ECL), and select ECL were purchased from GE Healthcare (Piscataway, NJ, USA). Anti-p38 (phospho Thr180 + Tyr185) (anti-p-p38), anti-tau (phospho serine 202) (anti-p-S202), and anti-glyceraldehyde 3-phosphate dehydrogenase (GAPDH) were obtained from Cell Signaling (Danvers, MA, USA). Chloroform was purchased from JT Baker (Phillipsburg, NJ, USA), QU from Santa Cruz Biotechnology (Santa Cruz, CA, USA), methanol from Mallinckrodt Baker (Phillipsburg, NJ, USA), ultrapure water from Barnstead (Dubuque, IA, USA), N-hydroxysuccinimide (NHS) from Alfa Aesar (Ward Hill, MA, USA), RMP-7 from Alkermes (Cambridge, MA, USA), tris(hydroxymethyl)aminomethane (Tris) from Riedel-de Haën (Seelze, Germany), regenerated cellulose (50 kDa) from Spectrum Laboratories (Rancho Dominguez, CA, USA), serum blocking solution from Zymed (South San Francisco, CA, USA), 2,3-bis-(2-methoxy-4-nitro-5-sulfophenyl)-2H-tetrazolium-5-carboxanilide (XTT) from Biological Industries (Beit Haemek, Israel), anti-B2 bradykinin receptor antibody from Alomone (Jerusalem, Israel), Triton-X-100 from Acros (Geel, Belgium), aqueous mounting medium from Bio SB (Santa Barbara, CA, USA), Aβ1–42 from Life Technologies (Carlsbad, CA, USA), Coomassie Blue Kit from Thermo Fisher Scientific (St Waltham, MA, USA), transfer buffer from Bio-Rad (Hercules, CA, USA), sample buffer from Millipore (Billerica, MA, USA), 96-well plate from Nalge Nunc (Rochester, NY, USA), 24-well flat-bottom tissue culture microtiter plate (polystyrene) from Midwest Scientific (St Louis, MO, USA), and microscope cover glass (gelatin coated) from Marienfeld GmbH (Lauda-Königshofen, Germany). Polyethylene terephthalate (PET) membrane (gelatin coated) and transwell were obtained from BD Falcon (Franklin Lakes, NJ, USA).
Preparation of RMP-7-Lf-QU-LS
Preparation of QU-encapsulated LS (QU-LS)
DPPC, SPC, CL, SA, cholesterol, and DSPE-PEG(2000)-CA were mixed in 1 mL of chloroform at 25°C. In the typical case, the mole percentages of DPPC, SPC, CL, SA, cholesterol, and DSPE-PEG(2000)-CA were 25%,17%, 10%, 5%, 40%, and 3%, respectively. When the mole percentage of SA varied, the content of DPPC, CL, cholesterol, and DSPE-PEG(2000)-CA remained constant and SPC balanced the variation at the level of SA. The weight percentage of QU was controlled at 4% in the lipids. Fluorescent LS were obtained with the addition of 0.1% (w/v) FITC-conjugated dextran 70000 to the lipid phase. Chloroform was evaporated in a 50 mL round bottom flask using a rotary evaporator (Panchum, Kaohsiung, Taiwan) and a vacuum pump (Panchum) at 75 rpm and 45°C for 15 min. QU was dissolved in methanol. To prepare QU-LS, QU was added to the concentrated lipid film and evaporated again. A total of 2 mg/mL of the concentrated lipid film was solvated in DPBS at 45°C, vibrated at 46 kHz and 45°C for 30 min, and compressed through a 100-nm polycarbonate membrane in an extruder set (Avanti Polar Lipids) 15 times. Unloaded QU and QU-LS were separated using an upright column of 1.5×50 cm packed with Sephadex G-100 at 25°C. In all, 3 mL of the QU-LS suspension and 150 mL of DPBS were added to the column. A total of 2 mL of every effluent was collected, treated with 2 mL of methanol, analyzed using a high-performance liquid chromatograph (HPLC; JASCO, Tokyo, Japan) with a reverse phase Hypersil BDS C18 column (Thermo Hypersil-Keystone, Bellefonte, PA, USA), and detected using an ultraviolet (UV) detector (UV-2075 Plus; JASCO) at 370 nm. The mobile phase was 50% (v/v) methanol in ultrapure water at a flow rate of 1 mL/min. The encapsulation efficiency of QU in QU-LS was defined as ([quantity of encapsulated QU in QU-LS]/[quantity of total QU in the preparation]) ×100%.
Grafting efficiency of Lf on QU-LS
QU-LS were suspended in MES. The carboxyl groups on QU-LS were activated with 1 mM of EDC and 1.5 mM of NHS at 80 rpm and 25°C for 1.5 h. The suspension was mixed with 5–20 μg/mL of Lf at 80 rpm and 25°C for 12 h, and 3 mL of the suspension containing QU-LS grafted with Lf (Lf-QU-LS) and 150 mL of DPBS were added to the Sephadex G-100 column at 25°C. Then, 2 mL of every effluent was collected. The quantity of unloaded Lf was evaluated with a QuantiPro BCA assay kit and determined using an enzyme-linked immunosorbent assay (ELISA) spectrophotometer (BioTek, Winooski, VT, USA) at 562 nm. The grafting efficiency of Lf on QU-LS, ELf, was defined as ELf (%) = ([quantity of total Lf in a preparation − quantity of unloaded Lf after gel chromatography]/[quantity of total Lf in a preparation]) ×100%.
Grafting efficiency of RMP-7 on Lf-QU-LS
Activated Lf-QU-LS were mixed with 5–20 μg/mL of RMP-7 at 80 rpm and 25°C for 12 h. The steps for grafting RMP-7 on Lf-QU-LS using EDC and NHS were analogous to those for grafting Lf on QU-LS, which is described in the “Grafting efficiency of Lf on QU-LS” section. A total of 3 mL of the suspension containing Lf-QU-LS grafted with RMP-7, defined as RMP-7-Lf-QU-LS, and 150 mL of DPBS were added to the Sephadex G-100 column at 25°C. The grafting efficiency of RMP-7 on Lf-QU-LS, ERMP-7, was defined as ERMP-7 (%) = ([quantity of total RMP-7 in a preparation − quantity of unloaded RMP-7 after gel chromatography]/[quantity of total RMP-7 in a preparation]) ×100%.
Characterization of RMP-7-Lf-QU-LS
Particle size and charge
The cumulant Z-averaged diameter, D, and zeta potential, ζ, of RMP-7-Lf-QU-LS were analyzed using a Zetasizer 3000 HSA with a photon correlation spectroscope and a laser Doppler velocimeter (Malvern, Worcestershire, UK) at 25°C. In all, 3 mL of 1 mg/mL of RMP-7-Lf-QU-LS in Tris buffer at pH 7.4 was used in every study.
Scanning electron microscope (SEM) and transmission electron microscope (TEM) morphology
The geometry of RMP-7-Lf-QU-LS was investigated using a field emission scanning electron microscope (FE-SEM; JSM-6330 TF; JEOL, Tokyo, Japan). In all, 10 μL of 2 mg/mL of RMP-7-Lf-QU-LS in Tris buffer was ultrasonically vibrated for 1 min, dropped on a cover slide, dried at 25°C for 24 h, vacuum dried, glued with carbon paint, and sputter coated with platinum. The structure of RMP-7-Lf-QU-LS was examined using a TEM (JEM-1400; JEOL). In all, 10 μL of 2 mg/mL of RMP-7-Lf-QU-LS in Tris buffer was loaded on a carbon-coated 200-mesh copper grid for 1 min and were treated with 10 μL of 2% (w/v) PTA solution for 2 min.
X-ray photoelectron spectroscope (XPS) spectra
Surface atoms on RMP-7-Lf-QU-LS were analyzed using an XPS (Kratos, Kanagawa, Japan) under a light beam area of 300×700 mm at 2×10−7 Pa and 300 W. A total of 2 mg/mL of RMP-7-Lf-QU-LS was dropped on a coverslip of 5×5 mm, dehydrated, and vacuum dried for 15 min.
Release kinetics of QU
In all, 1.5 mg/mL of RMP-7-Lf-QU-LS in DPBS containing 0.05% (w/v) sodium azide at pH 7.4 was used for the dissolution study. A dialysis tube of regenerated cellulose was trimmed to 3.3×20 cm. A total of 10 mL of the suspension was added to the dialysis tube in a 100 mL flask containing 50 mL of DPBS at pH 7.4 and was shaken in a bath reciprocal shaker at 50 rpm and 37°C for 48 h. In all, 100 μL of dialyzate was taken out from the flask at a specific time point and the quantity of QU was evaluated using an HPLC-UV at 370 nm. The dialyzate was compensated with 100 μL of fresh DPBS immediately after sampling. The cumulative percentage of QU released from RMP-7-Lf-QU-LS, PQU, was defined as ([quantity of cumulative QU in DPBS]/[quantity of encapsulated QU in RMP-7-Lf-QU-LS]) ×100%.
Transport across the BBB using RMP-7-Lf-QU-LS
Toxicity to HBMECs and HAs
The methods used to cultivate HBMECs and HAs have been described previously.23 HBMECs at a density of 7.5×103 cells/well in gelatin-pretreated 96-well plates were cultured with 150 μL of endothelial cell medium per well in a humidified CO2 incubator (NuAire, Plymouth, MN, USA) at 37°C for 8 h and incubated with 0.025% (w/v) RMP-7-Lf-QU-LS for 12 h. The viability of HBMECs was assayed with XTT and was evaluated using an ELISA spectrophotometer at 450 nm. Cultured HBMECs were reacted with 50 μL of XTT per well containing 2% (v/v) activation solution in a humidified CO2 incubator for 4 h. Analogous procedures were used to determine the viability of HAs cultured with the astrocyte medium. The viability of BBB cells (HBMECs and HAs), PV,BBB, was defined as PV,BBB (%) = ([optical density of HBMECs or HAs after treatment with RMP-7-Lf-QU-LS − optical density of XTT]/[optical density of HBMECs or HAs − optical density of XTT]) ×100%.
Transendothelial electrical resistance (TEER) of the BBB after treatment with RMP-7-Lf-QU-LS
The method used to establish HBMECs regulated by HAs (HBMEC/HA) on a PET membrane with a pore size of 0.4 μm and a surface area of 0.3 cm2 in a transwell was described in our previous study.24 In all, 0.025% (w/v) RMP-7-Lf-QU-LS was added to the upper donor chamber facing the HBMECs, cultured in ECM in a 24-well flat-bottom tissue culture microtiter plate, and placed in a humidified CO2 incubator for 5 h. The donor chamber and lower receiver chamber facing the HAs were filled with a fresh medium before determining the electrical resistance of the membrane using a Millicell electrical resistance system (Millipore). The TEER of HBMEC/HA was defined as TEER (Ω·cm2) = (electrical resistance of membrane with HBMEC/HA − electrical resistance of original membrane without cells) × surface area of the membrane.
Ability of PI to cross the BBB after treatment with RMP-7-Lf-QU-LS
After treatment with RMP-7-Lf-QU-LS, the medium of the donor chamber was replaced with a fresh medium containing 0.25 mg/mL of PI and cultured in a CO2 incubator for 5 h. The quantity of PI in the receiver chamber was determined using a microplate fluorescent reader (Synergy HT; BioTek) with excitation at 485 nm and emission at 590 nm. The ability of PI to cross the BBB, PBBB,PI, was defined as ([ability of PI to cross the membrane with HBMEC/HA]−1 − [ability of PI to cross the membrane without cells]−1)−1.
Ability of QU to cross the BBB using RMP-7-Lf-QU-LS
A total of 0.025% (w/v) RMP-7-Lf-QU-LS was added to the donor chamber and cultured in a humidified CO2 incubator for 5 h. In all, 20 μL of the liquid in the receiver chamber was sampled every 2.5 h, treated with methanol at 37°C for 30 min, and analyzed using the HPLC-UV system (at 370 nm) described in the “Preparation of QU-LS” section. A total of 20 μL of the fresh medium was added to the receiver chamber immediately. The ability of QU to cross the BBB, PBBB,QU, was defined as ([ability of QU to cross the membrane with HBMEC/HA]−1 − [ability of QU to cross the membrane without cells]−1)−1.
Immunochemical staining of LfR and B2 bradykinin receptor in HBMECs during interaction with RMP-7-Lf-QU-LS
HBMECs at a density of 1×105 cells/cm2 were seeded on a microscope cover glass in a 24-well plate, cultured in a humidified CO2 incubator for 8 h, treated with 0.025% (w/v) RMP-7-Lf-QU-LS, and cultured in a humidified CO2 incubator for 3 h. In preparing the staining sample, cultured HBMECs were fixed with 10% (v/v) formalin at 25°C for 10 min, treated with 0.5% (v/v) Triton-X-100 at 25°C for 10 min, and incubated with serum blocking solution at 25°C for 30 min. The sample was reacted with 1 μg/mL of anti-LfR monoclonal antibody and/or with anti-B2 bradykinin receptor antibody (1:1,000) at 4°C for 12 h, stained with goat anti-mouse polyclonal secondary antibody IgG (H + L) conjugated with rhodamine (1:100) at 25°C for 1 h in darkness, treated with 0.5% (w/v) DAPI in 0.1% (v/v) Triton-X-100 at 25°C for 3 min in darkness, and incubated in an aqueous mounting medium. RMP-7-Lf-QU-LS, LfR and/or B2 bradykinin receptor, and HBMECs were visualized using a confocal laser scanning microscope (LSM 510; Zeiss, Oberkochen, Germany) with excitation at 350 nm (nuclei, blue), 490 nm (RMP-7-Lf-QU-LS, green), and 555 nm (LfR and/or B2 bradykinin receptor, red) and emission at 475 nm, 520 nm, and 565 nm.
Rescue of degenerated SK-N-MC cells from apoptosis using RMP-7-Lf-QU-LS
Viability of SK-N-MC cells after treatment with RMP-7-Lf-QU-LS
The methods used to culture SK-N-MC cells and prepare fibrillar Aβ1–42 were described in our previous study.25 For the viability assay, the steps used to treat SK-N-MC cells were analogous to those for HBMECs and HAs described in the “Toxicity to HBMECs and HAs” section, except for the addition of 15 μM of fibrillar Aβ1–42 to the culture medium for SK-N-MC cells. The viability of SK-N-MC cells, PV,SK-N-MC, was defined as PV,SK-N-MC (%) = ([optical density of SK-N-MC cells after treatment with RMP-7-Lf-QU-LS − optical density of XTT]/[optical density of SK-N-MC cells − optical density of XTT]) ×100%.
Western blot of p-p38 and p-S202 after treatment with RMP-7-Lf-QU-LS
SK-N-MC cells at a density of 1×105 cells/well were seeded in a 12-well plate, treated with 15 μM of fibrillar Aβ1–42 and RMP-7-Lf-QU-LS, and lyzed with 200 μL of lysis buffer per well for 30 min. A total of 2 μL of decomposed protein solution from SK-N-MC cells was diluted with 198 μL of ultrapure water, and 150 μL of diluted solution was reacted with 150 μL of Coomassie Blue Kit in a 96-well plate. The protein content in the sample was determined using an ELISA spectrophotometer at 595 nm. The sample was heated to 95°C and added to a 25% (v/v) sample buffer containing 25 μg of protein per vial. In the SDS-PAG electrophoresis, proteins were segregated in separating gel at 60 V for 15 min and then at 120 V for 30 min; relocated to the PVDF membrane in transfer buffer at 400 mA and 4°C for 90 min; incubated with 5% (w/v) skim milk for 1 h; reacted with anti-p-JNK (1:1,000), anti-p-p38 (1:1,000), anti-p-S202 (1:1,000), and anti-GAPDH (1:1,000) at 4°C for 12 h; and stained with goat anti-rabbit IgG (H + L) (HRP; 1:2,000) at 25°C for 1.5 h. Anti-GAPDH was augmented with ECL, and anti-p-JNK, anti-p-p38, and anti-p-S202 were augmented with select ECL for 1 min. Protein bands in lanes were visualized using a Luminescence Image Analysis System (Fujifilm, Tokyo, Japan), and the relative quantity of protein was analyzed using the ImageJ software (version 1.50; National Institutes of Health, Bethesda, MD, USA).
Immunochemical staining of RMP-7-Lf-QU-LS adjacent to Aβ-insulted SK-N-MC cells
The steps taken to prepare the staining sample of SK-N-MC cells were analogous to those of HBMECs described in the “Immunochemical staining of LfR and B2 bradykinin receptor in HBMECs during interaction with RMP-7-Lf-QU-LS” section. Differences between the two systems were the addition of 15 μM of fibrillar Aβ1–42 with RMP-7-Lf-QU-LS and the replacement of anti-LfR and anti-B2 bradykinin receptor antibody with anti-Aβ monoclonal antibody (1:400). The procedure for fluorescent imaging of SK-N-MC cells was the same as that for HBMECs.
Data are presented as mean ± standard deviation. Statistical comparison between groups was performed using a one-way analysis of variance followed by Tukey’s honest significant difference test.
Results and discussion
Colloidal delivery system of RMP-7-Lf-QU-LS
Figure 1A shows the average diameter and zeta potential of RMP-7-Lf-QU-LS. The insets in this figure reveal the corresponding SEM morphology at mole percentage of SA in the lipid bilayer (rSA) =5%, 15%, and 25%. As seen in Figure 1A, an increase in the mole percentage of SA from 5% to 25% enlarged the particles and increased the zeta potential. This was because SA was positively charged in the bilayer and could increase repulsion between positively charged groups in the membrane, leading to a random liposomal structure and large particles. The particle size in the SEM image was consistent with the data. This SEM morphology was similar to that reported in the literature on LS comprising phospholipids and cholesterol.26 In this study, the encapsulation efficiency of QU in QU-LS was 52.61%±3.27% at rSA =5% (n=3). QU in methanol was added to and incorporated in a lipid thin film via hydrophobic affinity. It was reported that hydrophilic and hydrophobic drugs could be entrapped in LS.27 Figure 1B reveals the coated structure of RMP-7 and/or Lf on the particles. The bilayer structure of QU-LS is shown in Figure 1Ba. Figure 1Bb exhibits a dark contour of modified Lf. RMP-7-Lf-QU-LS reveals prominent negative stains in Figure 1Bc. Figure 1C shows the grafting efficiency of RMP-7 and Lf. As seen in this figure, an increase in the mole percentage of SA from 5% to 25% reduced the grafting efficiency of RMP-7 and Lf, in general. This was because positive charges on the particles repelled positively charged RMP-7 and Lf in the grafting medium.28 Figure 1D shows the signals of surface atoms on RMP-7-Lf-QU-LS. In this figure, an increase in the mole percentage of SA from 0% to 5% enhanced the quantity of surface nitrogen at 397 eV. This was because the atomic ratio of nitrogen to all atoms in SA was higher than that in QU-LS without SA. In addition, RMP-7 and Lf had abundant nitrogen atoms and significantly promoted the nitrogen content on QU-LS. Figure 1E shows the release kinetics of QU from RMP-7-Lf-QU-LS. The initial leakage of encapsulated QU from the current LS preparation was negligible. The release rate was in the order of RMP-7-Lf-QU-LS < Lf-QU-LS < QU-LS for 48 h, suggesting the sustained release characteristics of RMP-7-Lf-QU-LS. This was because surface RMP-7 and/or Lf shielded the particle surface, obstructed the diffusion path, increased the migration distance to the medium, and retarded the dissolution of QU from the bilayer. As a result, QU could migrate and diffuse to DPBS. Previous studies reported that the release kinetics of QU to aqueous medium could be biphasic, including burst and prolonged stages; this was also observed in our study.29–31
Delivery of QU across the BBB using RMP-7-Lf-QU-LS
Figure 2A shows the cytotoxicity of RMP-7-Lf-QU-LS to HBMECs and HAs. As seen in this figure, the viability of the BBB cells was high, suggesting that RMP-7-Lf-QU-LS could be appropriate drug delivery carriers for targeting without seriously imperiling the BBB, although LS might induce inflammatory responses.32 Figure 2A also indicates that the viability of HBMECs and HAs was comparable. Figure 2B shows the TEER of the BBB and the ability of PI to cross the BBB after treatment with RMP-7-Lf-QU-LS. A high TEER and a low ability of PI to permeate the BBB represent a compact tight junction. As indicated in Figure 2B, an increase in the concentration of RMP-7 and Lf slightly decreased the TEER and increased the ability of PI to cross the BBB. This suggested that RMP-7-Lf-QU-LS might slightly enhance paracellular drug delivery.33 It has been reported that LS could not severely damage the integrity of the BBB.34 Figure 2C shows the ability of QU to cross the BBB using RMP-7-Lf-QU-LS. This figure demonstrates the enhancement of the ability of QU to cross the BBB by increasing the level of surface RMP-7 and Lf. The ability of free QU to cross the BBB was 6.42±0.51 cm/s (n=3), which was greater than the ability of QU using Lf-QU-LS prepared at 5 μg/mL of Lf. This was because hydrophobic drugs such as QU with a molecular weight of 302.24 Da might be easier to transport across the BBB.35 However, QU loaded in nanocarriers such as RMP-7-Lf-QU-LS could have controlled release characteristics and targeting ability to rescue neurons in the brain. In addition, the ability of QU to cross the BBB using QU-encapsulated LS grafted with RMP-7 (RMP-7-QU-LS) that was prepared at 5 μg/mL of RMP-7 was 5.76±1.87 cm/s (n=3), which was lower than that for free QU. However, the ability of QU to cross the BBB using RMP-7-QU-LS prepared at 10 μg/mL of RMP-7 increased to 7.03±1.45 cm/s (n=3), which was comparable to that for free QU. Figure 2C shows that RMP-7-Lf-QU-LS prepared at 10 μg/mL of Lf and 10 μg/mL of RMP-7 could double the ability of free QU to cross the BBB and significantly increased the ability of QU when using Lf-QU-LS alone. A study on chemotherapy for brain cancer indicated that a modification of targeting molecules was a potent strategy to deliver daunorubicin across the BBB.36 Figure 2D shows immunocytochemical staining images unveiling the internalization of RMP-7-Lf-QU-LS by HBMECs through recognition of B2 bradykinin receptor and LfR. Ample LfRs on HBMECs appear in Figure 2Db, and ample B2 bradykinin receptors and LfRs on HBMECs are seen in Figure 2Da, c, and d. Moreover, the green intensity was in the order of QU-LS < Lf-QU-LS < RMP-7-Lf-QU-LS, and a high concentration of RMP-7 could promote the uptake of RMP-7-Lf-QU-LS. This suggested that surface RMP-7 and Lf could target HBMECs and favor the delivery of QU across the BBB and that the images in Figure 2D were consistent with the data in Figure 2C.
Rescue of degenerated SK-N-MC cells using RMP-7-Lf-QU-LS
Figure 3A shows the viability of Aβ-insulted SK-N-MC cells after salvage with RMP-7-Lf-QU-LS. As seen in this figure, Aβ induced strong neurotoxicity and RMP-7-Lf-QU-LS could protect SK-N-MC cells from significant neurodegeneration. QU-LS containing CL in bilayers could also reduce apoptosis of SK-N-MC cells. This was because of the affinity of CL to Aβ.37 A reduced toxicity to SK-N-MC cells has also been reported due to the high affinity of AA3E2 to Aβ.38 In addition, CL could form a complex for transporting electrons by conjugating a portion of MGST1 antibody.39 Figure 3A reveals that RMP-7-Lf-QU-LS could also enhance the viability of SK-N-MC cells via a targeting effect of Lf. Figure 3B shows the expression of p-JNK, p-p38, and p-S202 in Aβ-insulted SK-N-MC cells after salvage with RMP-7-Lf-QU-LS. This figure indicates that Aβ induced substantial expressions of p-JNK, p-p38, and p-S202 in SK-N-MC cells. QU-LS could significantly retard the expressions of p-JNK, p-p38, and p-S202, and free QU led only to minor inhibition of their expressions. After treating with RMP-7-Lf-QU-LS, the levels of p-JNK, p-p38, and p-S202 in Aβ-insulted SK-N-MC cells were comparable to those of the control group. JNK belongs to the mitogen-activated protein kinase (MAPK) family.40 It was reported that JNK could be activated by Aβ, leading to tau protein phosphorylation.41 p38 also belongs to the MAPK family and is regarded as one of the key kinases in tau phosphorylation.42 Moreover, tau hyperphosphorylation induced by p-JNK and p-p38 is located at S202 in the early stage.43 It is well known that hyperphosphorylated tau can sequestrate soluble tau in the dysfunction of axonal transport in neurons and contributes to AD. Figure 3C shows the staining images of RMP-7-Lf-QU-LS adjacent to Aβ-insulted SK-N-MC cells. As seen in this figure, fluorescent red Aβ surrounded SK-N-MC cells and attracted green RMP-7-Lf-QU-LS. Figure 3Ca and b shows that QU-LS and RMP-7-QU-LS appeared in the neighborhood of SK-N-MC cells due to recognition of Aβ. Compared with Figure 3Cb, c, and d shows that surface Lf increased the quantity of green particles around SK-N-MC cells. Furthermore, an increase in the concentration of Lf enhanced the quantity of RMP-7-Lf-QU-LS near SK-N-MC cells. This was because RMP-7-Lf-QU-LS had an effect on targeting LfR and low-density lipoprotein receptor-related protein-1 (LRP1) on SK-N-MC cells.44 It has also been reported that LRP1 and its ligands exist in the Aβ plaque of AD patients and could form a complex to eliminate Aβ.45,46 Thus, RMP-7-Lf-QU-LS could conjugate Aβ and be internalized by SK-N-MC cells, leading to a high uptake of QU and high likelihood of inhibiting neuronal apoptosis. Figure 3C is also consistent with Figure 3A and B.
RMP-7-Lf-QU-LS was fabricated for targeting of the BBB and for delivering QU to SK-N-MC cells. Experimental evidence revealed that an increase in the mole percentage of SA increased the particle size and zeta potential but decreased the grafting efficiency of RMP-7 and Lf, in general. In addition, incorporated RMP-7 and Lf on the particles increased the level of surface nitrogen. RMP-7 and Lf also slightly enhanced the ability of PI to cross the BBB and reduced the TEER, indicating a minor tight junction opening after treatment with RMP-7-Lf-QU-LS. With regard to sustained release, dissolution of QU was in the order of QU-LS > Lf-QU-LS > RMP-7-Lf-QU-LS. Moreover, RMP-7-Lf-QU-LS had low cytotoxicity to HBMECs and HAs and could be recognized by HBMECs for enhancing the transport of QU across the BBB. In terms of protein expression, p-JNK, p-p38, and p-S202 in SK-N-MC cells were in the order of free QU > QU-LS > RMP-7-Lf-QU-LS, suggesting that RMP-7-Lf-QU-LS could reduce neurotoxicity and improve neuronal survival. Hence, RMP-7-Lf-QU-LS can act as a potential neuroprotective system for inhibiting Aβ-induced apoptosis in AD management.
This work was supported by the Ministry of Science and Technology of the Republic of China (Taiwan) under grant number MOST 103-2221-E-194-043-MY3.
The authors report no conflicts of interest in this work.
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