Abstract
Strategies to overcome toxicity and drug resistance caused by chemotherapeutic drugs for targeted therapy against hepatocellular carcinoma (HCC) are urgently needed. Previous studies revealed that high oxidored-nitro domain-containing protein 1(NOR1) expression in HCC was associated with cisplatin (DDP) resistance. Herein, a novel dual-targeting nanocarrier system AR-NADR was generated for the treatment of DDP resistance in HCC. The core of the nanocarrier system is the metal–organic frameworks (MOF) modified with nuclear location sequence (NLS), which loading with DDP and NOR1 shRNA (R). The shell is an A54 peptide inserted into the erythrocyte membrane (AR). Our results show that AR-NADR efficiently internalized by tumor cells due to its specific binding to the A54 receptors that are abundantly expressed on the surface of HCC cells and NLS peptide-mediated nuclear entry. Additionally, DDP is more likely to be released due to the degradation of Ag-MOF in the acidic tumor microenvironment. Moreover, by acting as a vector for gene delivery, AR-NADR effectively inhibits tumor drug resistance by suppressing the expression of NOR1, which induces intracellular DDP accumulation and makes cells sensitive to DDP. Finally, the anti-HCC efficacy and mechanisms of AR-NADR were systematically elucidated by a HepG2/DDP cell model as well as a tumor model. Therefore, AR-NADR constitutes a key strategy to achieve excellent gene silencing and antitumor efficacy, which provides effective gene therapy and precise treatment strategies for cisplatin resistance in HCC.
Graphical Abstract
Similar content being viewed by others
Introduction
Hepatocellular carcinoma (HCC) is a common malignant tumor characterized by aggressiveness and rapid progression, with high morbidity and mortality [1]. Patients with early HCC are mainly treated by surgery, such as liver resection and liver transplantation. However, 70–80% of patients with HCC are diagnosed at an advanced stage because of tumor progression and unsatisfactory surgical treatments for metastatic lesions. Regional or systemic chemotherapy is a commonly implemented treatment for patients with advanced HCC [2,3,4]. Cisplatin (DDP) is a classic chemotherapeutic drug for HCC. Unfortunately, the use of DDP in clinical practice is largely limited because severe off-target effects tend to cause a number of treatment-related side effects and serious systemic toxicity [5]. More importantly, multidrug resistance (MDR) causes HCC patients to exhibit a poor drug response, which is the key factor limiting its success [6, 7]. Hence, it is extremely important to develop a valid therapeutic approach to enhance DDP targeting and reverse DDP resistance for HCC therapy.
The oxidored-nitro domain-containing protein 1 (NOR1) gene (also called organic solute carrier partner 1, OSCP1), first isolated from nasopharyngeal carcinoma (NPC) [8], and located on chromosome 1P33.4, is specifically expressed in normal tissues such as the testis, placenta, trachea and brain [9, 10]. Previous studies have revealed that NOR1 displays moderate to strong expression in HCC [11] and promotes HCC cell proliferation and migration by modulating the Notch signaling pathway [12, 13]. Elevated expression of NOR1 is related to advanced clinical stage and predicts poor prognosis of HCC [14]. NOR1 also could activate hepatic stellate cells (HSCs), contributing to liver fibrosis in vitro through the Wnt/β‑catenin signaling pathway [15]. Moreover, NOR1, as a specific organic solute carrier protein, is also widely expressed in the blood-placental barrier, where promotes drug clearances and prevents drugs from entering the fetus through the placenta [16]. It has been reported that methylation of the NOR1 gene is associated with resistance to imatinib [17]. However, there is little information available regarding its role in the DDP resistance of HCC. Our work revealed that DDP-resistant HCC cells overexpressed NOR1. Knocking down NOR1 expression effectively sensitized DDP-resistant HCC cells to DDP by reducing drug pumping and increasing the accumulation of DDP. Therefore, the NOR1 gene seems to have emerged as a crucial target for sensitizing HCC cells to chemotherapeutics.
The RNA interference (RNAi) technique is considered a promising therapeutic method for cancer treatment because of its ability to effectively silence genes connected with overexpressed cancer markers and to subsequently resensitize cancer cells [18]. However, gene therapy vectors mainly utilize adenovirus and lentivirus vectors, their potential immunogenicity, carcinogenicity, poor repeatability and high cost hinder widespread clinical application [19,20,21,22]. Currently, remarkable progress has been made in the development and application of engineered nanoparticles to treat cancer more effectively [23,24,25,26]. Due to their chemical versatility, easy modification, controlled release properties and biosafety, nanocarriers have been widely used to deliver small interfering RNA/short hairpin RNA (siRNA/shRNA) for gene therapy [27,28,29,30]. Metal–organic frameworks (MOF) are a class of organic–inorganic hybrid materials consisting of metal ions/clusters and organic ligands, with the advantages of a high specific surface area, porous architecture, and tailorable structure [31]. Recently, biomedical applications of MOF for drug or siRNA/shRNA delivery have attracted close attention [32, 33]. MOF nanocarriers can effectively load drugs and negatively charged genetic materials, which not only protects them from degradation but also accelerates their cellular uptake through the enhanced permeability and retention effect (EPR) effect [34, 35]. In this study, silver ions (Ag+) and L-histidine were used to synthesize a porous Ag-MOF that can effectively load chemotherapeutic drugs (DDP) and NOR1 shRNA (R). To enter the nucleus from outside a cell, nanocarriers require special modifications [36]. The surface serialized nuclear localization signal (NLS, amino acid sequence: PKKKRKVG) is considered to be the most classic mediator of nuclear entry [37]. NLS-modified nanoparticles exhibit nuclear targeting by participating in specific intraendosomal processing pathways for endosomal escape without cytotoxicity [36, 38, 39]. Therefore, Ag-MOF modified with NLS will be a feasible method for the efficient delivery of DDP and NOR1 shRNA to the nucleus.
As an exogenous substance, nanomaterials are easily identified and cleared by the mononuclear phagocytic system, resulting in lower blood circulation times [40]. To solve these issues, we propose a novel approach to embellish nanomaterials [41]. Red blood cells (RBCs) are extensively applied in the construction of biomimetic nanomaterials that have a long circulation half-life, incomparable biocompatibility and are easily obtained [42, 43]. In this study, RBC membranes (RBCms) were selected to disguise nanomaterials to help them escape recognition by the immune system and enhance their blood circulation and action time [44]. Ideal nanodelivery systems not only protect the loaded drug from degradation but also possess components that assist the targeting moiety in delivering the drug at the target position [45,46,47]. The A54 peptide (sequence AGKGTPSLETTP) is an HCC-specific combining peptide containing twelve amino acids selected from a phage display peptide library and effectively localizes to the receptor on the surface of HCC cells [48]. A few studies have revealed that nanomaterials modified with the A54 peptide could specifically target HCC cells, increasing cellular internalization of drug by achieving effective aggregation [49,50,51,52]. Conclusively, by inserting the A54 peptide on the surface of RBCms, RBCms are able to bind specifically to the A54 peptide receptor on the surface of HCC cells for increased uptake of nanomaterials.
Consequently, we propose to structure a tumor-targeting, pH-stimulated drug/shRNA codelivery system (AR-NADR) (Fig. 2) that comprises two functional modules, including the core of the nanocarrier system, that is, NLS-modified Ag-MOF (NA) loaded with DDP (D) and NOR1 shRNA (R). The shell is the A54 peptide inserted into RBCm (AR); In particular, AR-NADR can induce a trio of synergetic effects: (i) the dual-targeting effects of the NLS and A54 peptide guide the AR-NADR to the HCC cell nucleus; (ii) the camouflage provided by the RBCms imparts good immune escape ability as well as biocompatibility; and (iii) the downregulation of NOR1 can reverse cisplatin resistance by reducing drug elimination. Thus, this tumor-targeting nanodelivery system is a prospective vector for anticancer drugs and therapeutic RNAi for overcoming drug resistance.
Materials and methods
Materials
Silver nitrate (S116266) was purchased from Aladdin (China). Cisplatin (IC0440) and dialysis membrane (2 kDa) (YA1036) were obtained from Solarbio (China). L-histidine (A604351), succinic anhydride (A607835), the MuLV First Strand cDNA Synthesis Kit (B532435) and SYBR Green PCR Mix (B110031) were obtained from Sangon Biotech (China). NLS peptide and A54 peptide were designed by QYAOBIO (China). The shRNA plasmid used to interfere with the NOR1 gene was designed by GeneChem (China). Polycarbonate porous membrane syringe filters (200 nm) (BS-PES-22) were obtained from Biosharp (China). Penicillin and streptomycin cocktail (PB180120), fetal bovine serum (FBS) (164210-50) and medium (Dulbecco's Modified Eagle Medium (DMEM)) (PM150210) were obtained from Procell (China). TRIzol reagent (15596018) was purchased from Thermo Fisher Scientific (USA). The Cell Counting Kit-8 (CCK-8) (C6005) was manufactured by NCM Biotech (China). Calcein/PI Cell Viability Assay Kit (C2015S), Annexin V-FITC/PI Apoptosis Assay Kit (C1062M), ATP Detection Kit (S0026) and Lipo8000™ Transfection Reagent (C0533) were purchased from Beyotime Biotechnology (China). The Reactive Oxygen Species (ROS) Assay Kit (AKCE002) and Mitochondrial Membrane Potential (MMP) Assay Kit (AKOP013) were purchased from Boxbio (China). The antibody against NOR1 (HPA028436) was manufactured by Sigma-Aldrich (USA). Goat anti-rabbit IgG H&L (HRP) (511203) was purchased from ZENBIO (China).
Cell culture and selection of mice
HepG2 cells and HepG2/DDP cells were obtained from the Institute for Advanced Study, Central South University (China). The cells were cultured in DMEM containing 10% FBS and 1% penicillin–streptomycin at 37 °C and 5% CO2. We chose six-week-old female nude mice and bought the mice from Hunan SJA Laboratory Animal Co., Ltd. (China).
Transcriptomic analysis
To measure the expression of NOR1 in DDP-resistant HCC, the total RNA in HepG2 cells and HepG2/DDP cells was extracted using TRIzol reagent. A NanoDrop 2000 (Thermo Fisher Scientific, USA) was applied to measure the concentration and purity of the extracted RNA. Sequencing libraries were generated with a Hieff NGS Ultima Dual-mode mRNA Library Prep Kit for Illumina (12308ES08, Yeasen Biotechnology, China) following the manufacturer’s recommendations. The library quality was assessed on the Agilent Bioanalyzer 2100 system. Subsequently, the samples were sequenced by an Illumina NovaSeq6000. Finally, the raw reads were further processed with a bioinformatics pipeline, namely, the BMKCloud (www.biocloud.net) online platform. Differential expression analysis of the two conditions/groups was performed using DESeq2. Genes with differences in expression levels that exhibited adjusted P values of < 0.05 along with |log2FC|≥ 1.5 were identified as significantly differentially expressed genes. The CCK-8 assay was used to calculate the half-inhibitory concentration (IC50) of HepG2 cells and HepG2/DDP cells before/after transfection with NOR1 shRNA.
Preparation of AR-NADR
Construction of Ag-MOF (AM)
L-histidine (0.4 g) and silver nitrate (AgNO3, 0.1 g) were added to 5 mL of double distilled water (ddH2O). Next, silver nitrate solution was added dropwise to the L-histidine solution. Before the solution changed to milky-white to form Ag-MOF (AM), the solution was placed in a reaction pot at 37 °C and magnetically stirred. Then, the solution was centrifuged at 12,000 rpm for 5 min and washed 3 times with ddH2O. The AM powder was dried in a vacuum freeze dryer for storage.
Construction of NLS-Ag-MOF (NA)
Ag-MOF (1 mg) was dissolved in 5 mL of ddH2O, and succinic anhydride (0.2 mg) was added. The carboxylated Ag-MOF was obtained by centrifugation (12,000 rpm) after magnetic stirring overnight. Carboxylated Ag-MOF (1 mg) was dissolved in 5 mL of ddH2O, and then 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride (EDC, 5.3 mg), N-hydroxysuccinimide (NHS, 5.6 mg) and NLS peptide (molecular weight: 940.21, 2 mg) were added and the solution was stirred overnight at 37 °C. Unincorporated EDC, NHS and NLS were filtered by dialysis to obtain NA.
Synthesis of NADR (NA/DDP/shRNA)
NA (1 mg) was dissolved in 1 ml of ddH2O, PEI (0.1 g) was added to generate positively charge NA, and 50 µg of shRNA plasmid, which was used to interfere with NOR1 gene expression, was added to react for 2 h with NA/shRNA (NAR). Then, 1 mg of DDP was added, the solution was magnetically stirred at 37 °C in the dark overnight, and NADR was obtained by centrifugation. The absorbances of different concentration gradients of DDP at 301 nm were determined, and the unbound DDP in the supernatant was calculated using standard curves. The calculation formulas for EE and LE were as follows: EE (%) = amounts of DDP loaded on nanocomposite/amounts of DDP added initially × 100. LE (%) = quantity of DDP loaded on the nanocomposite/total quantity of this nanocomposite × 100.
Preparation of A54 peptide-inserted RBC membranes (AR)
As mentioned above, the whole blood samples obtained from mice were centrifuged at 3000 rpm for 5 min, and then the supernatant was removed. Finally, the membrane precipitate was washed repeatedly with PBS (3 times) [53]. After washing repeatedly with PBS (0.25X) to release the hemoglobin, the pink erythrocyte membrane precipitate was collected through centrifugation. Finally, nanoscale erythrocyte membrane vesicles were obtained after ultrasound (42 kHz, 100 W) for 5 min and extraction with porous membrane syringe filters (200 nm). In brief, A54 peptide (6.25 mg), DSPE-PEG2000-NH2 (5 mg), EDC (2.8 mg), and NHS (1.7 mg) were dissolved in PBS (5 ml) and the solution was magnetically stirred at 37 °C for 24 h. The unbound EDC, NHS and A54 peptide were removed using a dialysis bag. Later, DSPE-PEG2000-NH2-A54 (0.1 ml) and the RBC membrane (0.9 ml) were mixed and stirred for 2 h at 37 °C. Eventually, the A54 peptide inserted into the RBC membrane (AR) was synthesized.
Construction of A54-RBCm@NLS-Ag-MOF/DDP/shRNA (AR-NADR)
AR was added to an equal volume (0.5 ml) of NADR by ultrasound (5 min, 42 kHz, 100 W). The mixture was then extracted repeatedly 20 times using a porous membrane syringe filter (200 nm). The excess AR in the supernatant was removed through centrifugation (10,000 rpm, 10 min), and the precipitate obtained was the AR-NADR.
Characterization of AR-NADR
Transmission electron microscopy (TEM; FEI Tecnai F20) was used to confirm the size and morphology of Ag-MOF, NLS-Ag-MOF, NADR, AR, and AR-NADR. The zeta potentials of various nanocomposites were detected using a Zetasizer Nano ZS (Malvern, UK). The X-ray diffraction patterns of Ag-MOF sample are obtained through X-ray diffraction instrument (XRD, Rigaku Ultima IV, Japan). Fourier-transform infrared spectroscopy (FTIR) was used to study the molecular functional groups of Ag-MOF (Thermo Scientific iN10, USA). UV−vis spectrometry (ScanDrop, Analytik Jena, Germany) was used to confirm the construction of AR-NADR. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS‒PAGE) was performed to identify erythrocyte membrane proteins. The gel was stained with Coomassie Blue staining solution (P1300) (SolarBio, China). Finally, the gel imaging system was used for analysis after decolorization.
Release characteristics of DDP in AR-NADR
To determine whether DDP could be more easily released from AR-NADR once it reached the acidic tumor microenvironment (TME), drug release tests were performed. In short, 1 ml of AR-NADR (the DDP concentration was 1 mg/mL) was placed into a dialysis bag (molecular weight cutoff of 2 kDa) and which was immersed in PBS (20 ml) at pH 7.4 and pH 6.5 separately with magnetic stirring at 37 °C. A 1 mL sample of the dialysate was collected from the incubation medium at specific time points (6, 12, 24, 48, and 72 h), and equal volumes of fresh PBS were placed into the incubation medium. The absorbance of the dialysate was detected at 301 nm (DDP characteristic peak) to measure the concentration of DDP released from the AR-NADR using standard curves.
Biocompatibility of AR-NADR in vitro
Immune escape assay
The immune evasion of AR-NADR was assessed in a RAW264.7 cell uptake assay. RAW264.7 cells were incubated with Cy5.5-labeled NADR, R-NADR and AR-NADR (20 µL) for 6 h and later stained with DAPI. Finally, an inverted fluorescence microscope (Zen2, Zeiss, Germany) was used for imaging.
Cytotoxicity assay
The cytotoxicity of AR-NADR was determined using a CCK-8 in Human Umbilical Vein Endothelial Cells(HUVECs). In short, the cells were seeded in 96-well plates (5 × 103 cells/well) for 24 h. Various concentrations of NADR, R-NADR and AR-NADR (0–100 µg/mL) were added and incubated for 24 h. Then, 10 µL of CCK-8 solution was added to each well and incubated for 2 h, and the absorbance was measured at 450 nm.
Hemocompatibility
Hemocompatibility was detected with a hemolysis assay. Various concentrations of AR-NADR (0–100 µg/mL) were incubated with 5% red blood cells at 37 °C for 2 h. The supernatant was collected after centrifugation (1500 rpm, 10 min), and a microwell plate detector (EnSpire 2300, PerkinElmer, USA) was applied to detect the absorbance at 545 nm. The positive and negative controls were ddH2O and normal saline, respectively. The ratio of hemolysis (%) = (absorbance of experimental sample−absorbance of negative control)/(absorbance of positive control−absorbance of negative control) × 100.
Double target binding ability of AR-NADR
The targeting effect of the A54 peptide on different tumor cells was detected. First, HepG2 cells (A54 + cells) were treated with 20 μL of RBCm@NLS-Ag-MOFs (RBC-NA) or A54-RBCm@NLS-Ag-MOFs (AR-NA) for 12 h. In addition, the A54 peptide competition test was used for further verification. In brief, the A54 peptide (20 μg) was pretreated for 2 h to block the HepG2 cell surface receptors, and then the cells were treated with 20 μL of AR-NA for 12 h [54]. Additionally, 4T1, A549 and HeLa cells (A54- cells) were treated with 20 μL of AR-NA to confirm the specific targeting of the A54 peptide to HCC cells. The Ag-MOFs were labeled with FITC. The fluorescence of AR-NA in the cells was observed with a fluorescence microscope (Zen2, Zeiss, Germany). Moreover, to detect the effect of the nuclear targeting of the NLS peptide, after 2, 6, and 24 h of incubation, HepG2 cells were exposed to 20 μL of AR@Ag-MOFs (AR-AM) and AR@NLS-Ag-MOFs (AR-NA) for 2 h, 6 h, and 24 h. The Ag-MOFs were labeled with Cy5.5. The cells were then washed with PBS, fixed with 4% paraformaldehyde, and stained with DAPI. The fluorescence was observed by a fluorescence microscope (Zen2, Zeiss, Germany).
NOR1 gene silencing/knockdown efficiency, IC50 and cell efflux assessments
Agarose gel electrophoresis was carried out to estimate NOR1 shRNA loading in NA. Different NA/shRNA weight ratios (w/w) (the weight of shRNA was 5 µg) were applied to an agarose gel (3%, 100 V) in TAE buffer containing YeaRed Nucleic Acid Gel Stain (10202ES76, Yeasen, China). A UV transilluminator and a digital imaging system (Life Science Technologies, USA) were applied to obtain images. The NOR1 gene silencing efficiency was sequentially evaluated. HepG2 cells and HepG2/DDP cells were cultured in 6-well plates (5 × 105 cells/well) for 24 h. Later, HepG2/DDP cells were treated for 48 h with PBS, free shRNA, Lipo8000-NC (Lipo8000-negative control plasmid), Lipo8000-shRNA and AR-NAR (AR-NA/shRNA), in which the polyplexes contained the NOR1 shRNA plasmid at a shRNA concentration of 2.5 µg well−1. The GFP of the plasmid could emit green fluorescence, which was used to evaluate transfection efficiency by an inverted fluorescence microscope (Zen2, Zeiss, Germany). In addition, total RNA was extracted from cultured cells with TRIzol reagent and reverse transcribed into cDNA with a MuLV First Strand cDNA Synthesis Kit. Then, real-time quantitative PCR (RT‒qPCR) was implemented with a SYBR Green PCR Kit, and the fluorescence was measured using a LightCycler 96 (Roche, USA). All samples were analyzed in triplicate and normalized to GAPDH levels. The relative fold variation in mRNA expression (normalized) was tested on the basis of the 2−ΔΔCt method. The sequences are provided as follows. For HS-GAPDH, the forward primer was CAGGAGGCATTGCTGATGAT; the reverse primer was: GAAGGCTGGGGCTCATTT; For NOR1, the forward primer was: CACTCCTCATCTTCTTCCAA; the reverse primer was: CCTCTTCTTCTTCTTCACCTT. In addition, the mRNA obtained from cells was evaluated by agarose gel electrophoresis (3% agarose gel, 100 V, 20 min). Furthermore, the protein obtained from cells was extracted with RIPA buffer and ultrasound, and the protein concentration was measured with a BCA protein assay kit. Following the Western blotting steps, we detected the expression of NOR1 in the cells with the corresponding antibody. ImageJ software was used for semiquantitative analysis of the agarose gel electrophoresis bands and Western blot bands. To demonstrate that reducing NOR1 expression could sensitize HepG2/DDP cells to DDP, the IC50 was calculated by the CCK-8 assay carried out using samples subjected to the above treatments. Furthermore, the cell efflux of DDP at 4, 6, 12, and 24 h was detected. HepG2 cells, HepG2/DDP cells and HepG2/DDP cells (treated with Lipo8000-shRNA) were seeded in 12-well plates (5 × 104 cells/well) for 24 h. Then, DDP (15 μg/mL) was added. After culturing for 4, 6, 12, and 24 h, the medium supernatant was collected at the indicated time points, and the absorbance was measured. The rate of cell efflux of DDP was calculated with a standard curve.
Antitumor action of AR-NADR in vitro
First, the toxicity of AR-NADR was determined by the CCK-8 test. HepG2 cells and HepG2/DDP cells were cultured in 96-well plates (5 × 103 cells/well) for 24 h. Then, the cells were exposed to AR-NA, AR-NAR, DDP, AR-NAD, or AR-NADR (the concentration of DDP was 0–40 μg/mL) for 24 h; subsequently, CCK-8 solution (10 µL) was added to each well for incubation at 37 °C for 2 h. The relative cell viability was calculated according to the absorbance at 450 nm. Additionally, the IC50 was calculated in cells treated with DDP, AR-NAD and AR-NADR. Moreover, live/dead cell staining was performed to estimate the antitumor effects of AR-NADR in vitro. HepG2 cells and HepG2/DDP cells were cultured in 6-well plates (5 × 105 cells/well). Next, the cells were exposed to PBS, AR-NA, AR-NAR, DDP, AR-NAD, or AR-NADR (the concentration of DDP was 15 μg/mL) for 6 h. After the medium was removed, calcein-AM and PI were used for live/dead staining, and the cells were observed with an inverted fluorescence microscope (Zen2, Zeiss, Germany).
Detection of MMP, ATP, ROS, and apoptosis in vitro
To investigate the mechanism by which AR-NADR overcomes drug resistance, HepG2/DDP cells were inoculated in 6-well plates (5 × 105 cells/well) for 24 h and later exposed to PBS, AR-NA, AR-NAR, DDP, AR-NAD and AR-NADR (the concentration of DDP was 15 μg/mL) for 12 h. Subsequently, the cells were collected. The JC-1 Assay Kit was used to measure the mitochondrial membrane potential (MMP) of cells detected by flow cytometry (Cytek Athena, USA). The intracellular adenosine triphosphate (ATP) and reactive oxygen species (ROS) level were detected with ATP quantification kit and ROS assay kit respectively. An Annexin V-FITC apoptosis detection kit was used to evaluate cell apoptosis by flow cytometry to comprehensively reveal the antitumor effect of AR-NADR in vitro.
Xenograft tumor models and assay of AR-NADR biodistribution
Six-week-old female nude mice were obtained from Hunan SJA Laboratory Animal Co., Ltd. (China). All the protocols for the proposed in vivo experiments were approved by the Animal Use and Care Committee of Central South University. HepG2/DDP cells (5 × 106 cells/100 μL) were subcutaneously used to inoculate nude mice to prepare a DDP-resistant hepatocellular carcinoma model. The tumor volume was measured using the following formula: volume = length × width2/2. The mice were deemed ready for further therapeutic study after the tumor volume reached 100 mm3. To evaluate the target of AR-NADR in vivo, 100 μL each of Cy5.5-NADR, Cy5.5-R-NADR and Cy5.5-AR-NADR (DDP, 2 mg/ml) was injected into HepG2/DDP tumor-bearing mice via the tail vein. The fluorescence signals of Cy5.5 from the mice, extracted organs and tumors were further detected with an In Vivo Imaging System (PerkinElmer, USA) at 6, 24, and 48 h after administration.
Antitumor action of AR-NADR in vivo
HepG2/DDP tumor-bearing mice were randomly divided into six groups (n = 5 per group) and intravenously injected with PBS, AR-NA, AR-NAR, DDP, AR-NAD, or AR-NADR in the tail vein 5 times (2 mg/ml DDP, every 2 days). The tumor size and body weight of the mice were recorded every second day. At 14 days, all the animals were euthanized, and the major organs (heart, liver, spleen, lung, and kidney), tumors and blood samples were collected for histological analysis (hematoxylin–eosin (H&E) staining) and blood tests. Western blotting and immunohistochemical analyses (IHC) were also performed to measure NOR1 expression in tumor tissues. Apoptosis in tumor tissues was detected via terminal deoxynucleotidyl transferase dUTP nick-end labeling (TUNEL) assays based on the standard protocol.
Statistical analysis
Data are expressed as the mean ± standard deviation (SD) after at least three independent experiments and were assessed by GraphPad Prism software. Intergroup differences were assessed with one-way analysis of variance (ANOVA) and Tukey’s post hoc test. (*p < 0.05, **p < 0.01, ***p < 0.001 and ****p < 0.0001).
Results and discussion
Transcriptomic study to explore the effect of NOR1 on cisplatin-resistant HCC cells
To evaluate the expression of NOR1 under conditions of DDP resistance, we conducted transcriptomic analysis on both HepG2 cells (n = 3) and HepG2/DDP cells (n = 3). As shown in Fig. 1A and B, among the differentially expressed genes (DEGs), the expression of the NOR1 (OSCP1) gene was significantly increased in the HepG2/DDP groups. After transfection with NOR1 shRNA, the IC50 in HepG2/DDP cells was significantly lower than that in HepG2 cells, indicating that the overexpression of the NOR1 gene was probably related to DDP resistance in HepG2/DDP cells (Fig. 1C). Based on the above findings, overexpressed NOR1 may affect DDP resistance and could serve as a new target for reversing DDP resistance in HCC.
Fabrication and characterization of AR-NADR
As indicated in Fig. 2, the fabrication of AR-NADR primarily included two processes: I) the construction of an NLS-modified Ag-MOF (NA) synthesized by Ag+ and L-histidine loaded with DDP (D) and NOR1 shRNA (R) to constitute a NADR nanocore, and II) the shell, in which the A54 peptide is inserted into a red blood cell membrane vesicle (AR) and is wrapped around the NADR to construct the whole core–shell structure of AR-NADR.
The morphology and size of different nanocomponents were visualized with TEM. As shown in Fig. 3A and B, the size and shape of Ag-MOF change little after modified with NLS. NADR exhibited a uniform spherical morphology with a size of ~ 113 nm (analyzed by the TEM). After decoration with AR, the average particle size of AR-NADR was 124.6 ± 4.04 nm. There was an 11-nm increase in the nanoparticle size, probably due to the membrane coatings, because the average thickness of RBC bilayers is 7–12 nm [55]. In Fig. 3C, the zeta potential of Ag-MOF, NLS- Ag-MOF and NADR were − 12.6 ± 1.7, − 9.2 ± 1.7 and − 7.2 ± 0.9 mV respectively; after fusion with AR, the zeta potential of AR-NADR decreased to − 10.4 ± 1.5 mV. This change might have resulted in AR encapsulation causing a charge shielding effect, which further confirmed the successful encapsulation of AR-NADR. As shown in Fig. 3D, the Ag-MOF were characterized by XRD, the phase detected of Ag-MOF was correspond to Ag (CHN), in which the 2θ of Ag (CHN) was 16.2, 20.02, 22.359, 28.699, and 37.283. Meanwhile, the FTIR spectra results (Fig. 3E) showed the absorption peaks of Ag-MOF all shifted to different degrees. C = O stretching vibration in the histidine was shifted from 1635 cm−1 to 1611 cm−1, and C–N stretching vibration was shifted from 1148 cm−1 to 1183 cm−1 and 1144 cm−1. This indicated that Ag+ in AgNO3 reacted with C–N in imidazole ring of histidine to form Ag–N chemical bond, which changed the infrared spectrum absorption peak of histidine. In the UV‒vis spectrum (Fig. 3F), AR-NADR had absorption peaks at 260, 301, and 410 nm, corresponding to the characteristic absorption peaks of NOR1 shRNA, DDP, and AR vesicles, respectively. Moreover, the SDS-PAGE results shown in Fig. 3G indicate that nearly all erythrocyte membrane protein profiles were retained in AR-NADR. All of the above findings further verified the successful preparation of AR-NADR.
Drug loading and release rate of DDP in AR-NADR
As a metal–organic material, NA synthesized with Ag+ and L-histidine served as an ideal carrier for drug/shRNA due to its high specific surface area and porosity. As shown in Fig. 4A, the drug encapsulation efficiency (EE%) and loading efficiency (LE%) of DDP in AR-NADR were 66.5 ± 3.09% and 49.8 ± 2.3%, respectively. Furthermore, the DDP release profiles of AR-NADR were evaluated at pH 7.4 and pH 6.5, which simulated a neutral circulation environment and an acidic tumor microenvironment, respectively (Fig. 4B). Increased cumulative amounts of the released DDP were obtained at pH 6.5 because of accelerated degradation of Ag-MOF in acidic conditions [56]. The release characteristic of the pH response of AR-NADR was especially helpful for drug delivery in a weakly acidic tumor environment and beneficial for enhancing antitumor effects and reducing toxic side effects.
Immune evasion and biocompatibility of AR-NADR in vitro
The antiphagocytic effect of AR-NADR in RAW264.7 macrophages was examined to determine the immune escape capacity. As observed in Fig. 5A and B, unlike the R-NADR and AR-NADR treated groups, a mass of red fluorescence accumulated in the RAW264.7 macrophages in the NADR treated group, indicating that after being camouflaged with RBCm vesicles, the immunogenicity of R-NADR and AR-NADR decreased and phagocytosis was significantly inhibited. Consequently, the above characteristics allowed AR-NADR to possess a prolonged circulatory half-life by avoiding recognition and eradication by the reticuloendothelial system in vivo. The results of toxicity assay (Fig. 5C) showed that even at a high dose (100 µg/mL), all preparations had little effect on the cell activity of HUVECs. The results demonstrated that the nanomaterial was nontoxic to normal cells and had good biocompatibility. Additionally, a hemolysis test was performed to confirm that AR-NADR was blood compatible. As indicated in Fig. 5D, R-NADR and AR-NADR hardly caused obvious hemolysis at 2 h (less than 5%). The above findings revealed that AR-NADR possessing good blood compatibility and biocompatibility could be applied for intravenous administration.
Double target binding ability of AR-NADR
As a targeted drug delivery system (DDS), AR-NADR specifically combines with the A54 peptide receptor expressed in HCC cells. The cellular uptake behavior was analyzed to determine its specific binding capability in various tumor cells. The RBCm@NLS-Ag-MOFs (RBCm-NA) and A54-RBCm@NLS-Ag-MOFs (AR-NA) were labeled with FITC expressing green fluorescence. As shown in Fig. 6A, unlike the RBCm-NA treated group, HepG2 cells that highly expressed the A54 peptide receptor on the cell surface (A54 + cells) accumulated abundant green fluorescence in the AR-NA-treated group. Another competition study of the A54 receptor was carried out. The results showed that cells pretreated with free A54 peptide exhibited little intracellular fluorescence even in HepG2 cells. Because the free A54 peptide saturated the A54 receptor on the cell membrane and inhibited the endocytosis of AR-NA mediated by the A54 receptor. The above observations indicated the effect of AR-NA on cell uptake mediated by the A54 receptor. Importantly, minimal green fluorescence was observed in 4T1, A549 or HeLa cells (A54− cells) treated with AR-NA, strongly suggesting that the A54 peptide of AR-NA had the ability to specifically target HCC cells.
To detect the effect of NLS nuclear targeting, the cellular uptake behavior of AR@Ag-MOFs (AR-AM) and AR@NLS-Ag-MOFs (AR-NA) was investigated in HepG2 cells. Cy5.5 was used to label AR-AM and AR-NA so that they displayed red fluorescence. As revealed in Fig. 6B, the level of red fluorescence increased over time in both groups. Notably, the cellular uptake capacity of AR-NA was slightly higher than that of AR-AM. Particularly at 24 h, the AR-NA group expressed a mass of red fluorescence in the cell nucleus, which verified the feasibility of the nuclear targeting of AR-NA after functionalization with the NLS peptide. The cells exhibited enhanced uptake of AR-NA, so the AR-NADR we later constructed could precisely deliver DDP and shRNA to the cell nucleus. The dual-targeting strategy of AR-NADR could specifically target HCC cells while enhancing the cell internalization of nanoparticles, which could effectively transport drugs and shRNA into the cells and improve the antitumor effect.
Efficient codelivery by AR-NADR of shRNA to suppress NOR1 expression in vitro
To investigate the binding capability of NA for NOR1 shRNA, an agarose gel electrophoresis assay was adopted. Different NA/shRNA weight ratios (w/w) were used to prepare NAR, and the movement of shRNA was observed with agarose gel electrophoresis. As shown in Fig. 7A, shRNA binding with NA was gradually impeded when the weight ratio increased from 0:1 to 30:1. When the weight ratios reached or exceeded 20:1, the migration of shRNA was entirely blocked, demonstrating the effective loading of shRNA in NA. An NA/shRNA weight ratio of 20:1 was used to generate AR-NADR to ensure stable and efficient delivery of shRNA.
Furthermore, the in vitro gene transfection efficiency of AR-NADR was evaluated. GFP in the plasmid emitted green fluorescence, which was used to evaluate the transfection efficiency. As shown in Fig. 7B, the level of green fluorescence in the AR-NAR group was analogous to that in the Lipo8000 transfection reagent-treated group (a commercial transfection reagent used as a positive control), indicating successful transfection. Subsequently, the mRNA and protein levels of NOR1 in HepG2 cells and HepG2/DDP cells were measured. As shown in Fig. 7C and D, the agarose gel electrophoresis and Western blot results suggested that compared with HepG2 cells, HepG2/DDP cells overexpressed NOR1. After treatment with Lipo8000-shRNA and AR-NAR, the expression of NOR1 was significantly decreased at both the mRNA and protein levels. As shown in Fig. 7E, HepG2/DDP cells highly expressed NOR1 with a higher IC50 value (25.5 ± 0.5 µg/mL) than in HepG2 cells (IC50 = 16.04 ± 1.18 µg/mL). NOR1 expression in cells was associated with sensitivity to DDP, and inhibition of NOR1 expression reversed drug resistance in HepG2/DDP cells. The IC50 values in the Lipo8000-shRNA and AR-NAR treated groups were 13 ± 0.98 µg/mL and 12.8 ± 1.2 µg/mL, respectively, which were dramatically lower than those in HepG2/DDP cells in the nontreated group. Furthermore, as shown in Fig. 7F, the cell efflux of DDP in HepG2/DDP cells was higher than that in HepG2 cells at 12 and 24 h. When NOR1 expression was inhibited, the cellular efflux of DDP was reduced; as a result, the ingestion of DDP was comparable to that in HepG2 cells. The above results indicated that AR-NAR efficiently delivered NOR1 shRNA. Downregulation of NOR1 reduced the IC50 of DDP in HepG2/DDP cells and decreased the efflux of DDP. Thus, AR-NADR presumably reverses chemoresistance by suppressing NOR1expression.
In vitro antitumor effects of AR-NADR
CCK-8 assays and live/dead cell staining were performed to investigate the cytotoxicity of AR-NADR against HCC cells. Compared with the PBS group, the DDP, AR-NAD and AR-NADR groups had significantly inhibited proliferation of HepG2 cells (Fig. 8A) and HepG2/DDP cells (Fig. 8B) in a dose-dependent manner. As shown in Fig. 8C, the IC50 value of DDP in HepG2 cells was observably lower than that in HepG2/DDP cells (IC50 = 16.04 ± 1.18 µg/mL on HepG2 cells versus IC50 = 25.5 ± 0.5 µg/mL on HepG2/DDP cells, denoting > 1.58-fold drug resistance). Moreover, AR-NAD had a stronger HepG2 cell killing effect than DDP alone, with an IC50 value of 13.17 ± 0.46 µg/mL. Because of the EPR effect as well as the target function of the nanocarrier, the internalization of DDP drugs by cells was higher [57]. Moreover, the anticancer effect of AR-NADR on HepG2/DDP cells was further improved (IC50 = 12.8 ± 1.2 µg/mL), and was almost twofold higher than that of DDP alone. This result further revealed that the effective reduction in the IC50 value in the AR-NADR-treated group in HepG2/DDP cells was mainly due to the downregulation of NOR1. Similar to other results (Fig. 5C), the drug-free nanocomposites AR-NA and AR-NAR showed little impact on the viability of HCC cells, indicating the safety of the nanosystem. As shown in Fig. 8D, the staining results of live/dead HepG2 cells and HepG2/DDP cells were in accordance with the results of the CCK-8 assay. The AR-NADR group exhibited apparent red fluorescence (dead cells) in both HepG2 cells and HepG2/DDP cells, indicating that AR-NADR had the most effective antitumor effects in vitro. Most importantly, the AR-NADR we constructed could potentially be an effective gene delivery vector for reversing drug resistance with powerful antitumor effects in HCC.
Mechanisms of AR-NADR against drug-resistant HCC cells
To thoroughly investigate the mechanism of the anticancer efficacy of AR-NADR against DDP-resistant cells, we sequentially investigated the MMP, ATP, ROS and apoptosis of HepG2/DDP cells. Mitochondrial injury characterized by decreased MMP is one of the hallmark events that occurs during the early stage of apoptosis. The change in MMP after apoptosis induction in cells allows the membrane permeability to be altered [58]. As shown in Fig. 9A, the cells were divided into upper quadrants (aggregates) and lower quadrants (monomers), indicating normal or damaged mitochondria of cells, respectively. The proportion of cells in the lower quadrant treated with AR-NADR was 33.4 ± 1.9%, which was higher than that treated with DDP (13.4 ± 3.5%) (Fig. 9D). Intracellular ATP production is affected if mitochondrial functionality is impaired [59]. Hence, compared with the DDP-treated group, the AR-NADR treated group showed significantly lower ATP content (Fig. 9E). The above results suggested that the AR-NADR-treated group exhibited more severe damage to mitochondrial function. Furthermore, overproduction of ROS is involved in damaging cellular components such as DNA, proteins and lipids, leading to apoptosis [60]. AR-NADR caused an obvious rightward shift of the peak, explaining it could induce more ROS production than other groups (Fig. 9B and F). In addition, as shown in Fig. 9C and G, the apoptotic rate of the AR-NADR-treated group was 59 ± 5.5%, which was higher than the group treated with DDP alone (35.3 ± 3.5%), revealing that AR-NADR induced more cell apoptosis. The AR-NA and AR-NAR treatments had little effect on the apoptotic rates. In conclusion, AR-NADR could accelerate mitochondrial injury and cell apoptosis and promote high ROS and ATP levels, which caused more cell death.
Biodistribution of AR-NADR in vivo
The efficiency of drug accumulation in tumors is a significant element that needs to be considered in drug delivery systems. To investigate the tumor targeting capability of AR-NADR in vivo, its biodistribution in a tumor-bearing mouse model was evaluated. As indicated in Fig. 10A, little fluorescence signal reached the tumor site in the NADR-treated group. Due to the EPR effect and immune escape, the R-NADR-treated group showed limited of fluorescence signal in the tumor site at 24 h post-injection. More importantly, the fluorescence signal increased obviously at 24 h in the tumor site of the AR-NADR group due to the targeting effect of the A54 peptide. Ex vivo images of major organs (heart, liver, spleen, lung, and kidney) and tumor tissues isolated from the sacrificed mice at 48 h post-injection were obtained (Fig. 10B and C). The results showed that, the fluorescence accumulated strongly at the tumor site in the AR-NADR-treated group and rarely accumulated in other organs. These outcomes confirmed that the immune escape of AR-NADR prolonged its time in the blood circulation and achieved efficient aggregation at the tumor site in response to the EPR effect and A54 peptide targeting [61].
In vivo antitumor effects of AR-NADR
The therapeutic efficacy of AR-NADR in vivo was examined in subcutaneous HepG2/DDP cell tumor-bearing nude mice (Fig. 11A). The tumor-bearing mice were randomly divided into six groups (n = 5 per group) and then intravenously injected with PBS, AR-NA, AR-NAR, DDP, AR-NAD, or AR-NADR 5 times (2 mg/ml DDP, every 2 days). The tumor size and body weight of the mice were measured every second day. As shown in Fig. 11Β, the mouse body weight displayed little change in each group except in the DDP-treated group, which exhibited certain side effects (weight loss of 20 ± 3.3%). However, the AR-NADR group showed markedly inhibited tumor growth (the inhibition rate was 75 ± 5%) on the 14th day compared with the other treatment groups (Fig. 11C and D). This finding demonstrated that the anticancer activity of AR-NADR could be markedly enhanced because of the long half-life, targeting effects and inhibition of NOR1 expression. At 14 days, all the mice were euthanized, and H&E staining, TUNEL assays and IHC of tumor tissues were performed. The results showed that the tumor tissues of the AR-NADR-treated group displayed obvious nuclear condensation and fragmentation, while the apoptotic fluorescence intensity was notably enhanced, unlike the staining results of samples from the other groups (Fig. 11E). Moreover, to verify the transfection efficiency of AR-NADR in vivo, IHC and Western blotting were also performed to analyze NOR1 expression in tumor tissues. As shown in Fig. 11E, the results of IHC staining revealed that the number of NOR1-positive cells (brownish yellow) was the lowest in the AR-NAR and AR-NADR groups, indicating that the nanosystem we constructed could effectively reduce NOR1 expression. Western blotting outcomes further proved the expression level of NOR1 protein in tumor tissues (Fig. 11F). Based on the above results, it was firmly believed that the Ag-MOF-assisted assembly strategy to accomplish effective coencapsulation of drugs and shRNA was feasible. Taken together, these results show that AR-NADR can improve anticancer activity, which provides a multiple-strategy treatment model with the potential for clinical translation.
Biocompatibility of AR-NADR in vivo
The biocompatibility of nanomaterials is attracting increasing attention for addressing medical and biological problems [62]. In this study, the safety profiles of AR-NADR in vivo were investigated. As shown in Fig. 12A, H&E staining of the major organs (heart, liver, spleen, lung, and kidney) displayed negligible histomorphological changes. In addition, similar to the PBS treatment group, there were no distinct alterations in hematological indices (RBC, WBC, PLT, and Hb) after injections of AR-NA, AR-NAR, DDP, AR-NAD, or AR-NADR (Fig. 12B). The body weight of mice also showed no obvious change (Fig. 12B). The above findings demonstrated that AR-NADR possessed lower toxicity, fewer side effects and good biocompatibility.
Conclusion
In this research, we revealed the potential relationship between NOR1 and DDP-resistant HCC. We successfully constructed a novel nanosystem, namely, AR-NADR, which contained A54-modified RBC membrane vesicles as the shell and an NLS modified Ag-MOF loaded with DDP and NOR1 shRNA as the core for the treatment of cisplatin resistance in HCC. This drug delivery system possesses many advantages, such as double targeting, satisfactory biocompatibility, and release properties in response to weak acidic environmental stimuli, effective gene transfection and synergistic antitumor effects. Consequently, AR-NADR is regarded as a reversal agent providing extraordinary potential for overcoming cisplatin resistance in tumors via multiple mechanisms. AR-NADR not only offers an effective strategy for the clinical application of gene therapy but also unveils a novel approach with applications in the biomedical field.
Availability of data and materials
All data generated or analyzed during this study are included in this published article.
References
Sung H, Ferlay J, Siegel RL, et al. Global cancer statistics 2020: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J Clin. 2021;71(3):209–49.
Wörns MA, Weinmann A, Schuchmann M, et al. Systemic therapies in hepatocellular carcinoma. Dig Dis. 2009;27(2):175–88.
Llovet JM, Kelley RK, Villanueva A, et al. Hepatocellular carcinoma. Nat Rev Dis Primers. 2021;7(1):7.
Sun Y, Zhang W, Bi X, et al. Systemic therapy for hepatocellular carcinoma: Chinese consensus-based interdisciplinary expert statements. Liver Cancer. 2022;11(3):192–208.
Hou G, Qian J, Guo M, et al. Hydrazided hyaluronan/cisplatin/indocyanine green coordination nanoprodrug for photodynamic chemotherapy in liver cancer. Carbohydr Polym. 2022;276: 118810.
Galluzzi L, Senovilla L, Vitale I, et al. Molecular mechanisms of cisplatin resistance. Oncogene. 2012;31(15):1869–83.
Zhang L, Zhou L, Zhang H, et al. Development of a DNA aptamer against multidrug-resistant hepatocellular carcinoma for in vivo imaging. ACS Appl Mater Interfaces. 2021;13(46):54656–64.
Nie X, Zhang B, Li X, et al. Cloning, expression, and mutation analysis of NOR1, a novel human gene down-regulated in HNE1 nasopharyngeal carcinoma cell line. J Cancer Res Clin Oncol. 2003;129(7):410–4.
Hiratsuka K, Yin SA, Ohtomo T, et al. Intratesticular localization of the organic solute carrier protein, OSCP1, in spermatogenic cells in mice. Mol Reprod Dev. 2008;75(10):1495–504.
Yi M, Yang J, Li W, et al. The NOR1/OSCP1 proteins in cancer: from epigenetic silencing to functional characterization of a novel tumor suppressor. J Cancer. 2017;8(4):626–35.
Xiang B, Wang W, Li W, et al. Differential expression of oxidored nitro domain containing protein 1 (NOR1), in mouse tissues and in normal and cancerous human tissues. Gene. 2012;493(1):18–26.
You K, Sun P, Yue Z, et al. NOR1 promotes hepatocellular carcinoma cell proliferation and migration through modulating the Notch signaling pathway. Exp Cell Res. 2017;352(2):375–81.
Li DQ, Qiu M, Nie XM, et al. Oxidored-nitro domain-containing protein 1 expression is associated with the progression of hepatocellular carcinoma. Oncol Lett. 2016;11(5):3003–8.
Chen S, Zheng P, Wang W, et al. Abberent expression of NOR1 protein in tumor associated macrophages contributes to the development of DEN-induced hepatocellular carcinoma. J Cell Physiol. 2018;233(6):5002–13.
Xiang T, Zhang S, Cheng N, et al. Oxidored-nitro domain-containing protein 1 promotes liver fibrosis by activating the Wnt/β-catenin signaling pathway in vitro. Mol Med Rep. 2017;16(4):5050–4.
Kobayashi Y, Shibusawa A, Saito H, et al. Isolation and functional characterization of a novel organic solute carrier protein, hOSCP1. J Biol Chem. 2005;280(37):32332–9.
Jelinek J, Gharibyan V, Estecio MR, et al. Aberrant DNA methylation is associated with disease progression, resistance to imatinib and shortened survival in chronic myelogenous leukemia. PLoS ONE. 2011;6(7): e22110.
Zhang Y, Zhang Z, Li S, et al. A siRNA-assisted assembly strategy to simultaneously suppress “self” and upregulate “eat-me” signals for nanoenabled chemo-immunotherapy. ACS Nano. 2021;15(10):16030–42.
JäSCHKE N, BüNING H. Adeno-associated virus vector design-moving the adeno-associated virus to a bioengineered therapeutic nanoparticle. Hematol Oncol Clin North Am. 2022;36(4):667–85.
Tariq I, Pinnapireddy SR, Duse L, et al. Lipodendriplexes: a promising nanocarrier for enhanced gene delivery with minimal cytotoxicity. Eur J Pharm Biopharm. 2019;135:72–82.
Asmamaw Mengstie M. Viral vectors for the in vivo delivery of crispr components: advances and challenges. Front Bioeng Biotechnol. 2022;10:895713.
Collins LT, Curiel DT. Synthetic biology approaches for engineering next-generation adenoviral gene therapies. ACS Nano. 2021;15(9):13970–9.
Wang Q, Zhang P, Li Z, et al. Evaluation of polymer nanoformulations in hepatoma therapy by established rodent models. Theranostics. 2019;9(5):1426–52.
Zheng P, Ding J. Calcium ion nanomodulators for mitochondria-targeted multimodal cancer therapy. Asian J Pharm Sci. 2022;17(1):1–3.
Chen J, Jiang Z, Xu W, et al. Spatiotemporally targeted nanomedicine overcomes hypoxia-induced drug resistance of tumor cells after disrupting neovasculature. Nano Lett. 2020;20(8):6191–8.
Chen J, Jiang Z, Zhang YS, et al. Smart transformable nanoparticles for enhanced tumor theranostics. Appl Phys Rev. 2021;8(4): 041321.
Hopkins C, Javius-jones K, Wang Y, et al. Combinations of chemo-, immuno-, and gene therapies using nanocarriers as a multifunctional drug platform. Expert Opin Drug Deliv. 2022;19(10):1337–1349.
Hassan EM, Zou S. Novel nanocarriers for silencing anti-phagocytosis CD47 marker in acute myeloid leukemia cells. Colloids Surf B Biointerfaces. 2022;217: 112609.
Kim H, Yuk SA, Dieterly AM, et al. Nanosac, a noncationic and soft polyphenol nanocapsule, enables systemic delivery of sirna to solid tumors. ACS Nano. 2021;15(3):4576–93.
Hajebi S, Yousefiasl S, Rahimmanesh I, et al. Genetically engineered viral vectors and organic-based non-viral nanocarriers for drug delivery applications. Adv Healthc Mater. 2022;11:e2201583.
Ge X, Wong R, Anisa A, et al. Recent development of metal-organic framework nanocomposites for biomedical applications. Biomaterials. 2022;281: 121322.
Poddar A, Conesa JJ, Liang K, et al. Encapsulation, visualization and expression of genes with biomimetically mineralized zeolitic imidazolate framework-8 (ZIF-8). Small. 2019;15(36): e1902268.
Ma Y, Su Z, Zhou L, et al. Biodegradable metal-organic-framework-gated organosilica for tumor-microenvironment-unlocked glutathione-depletion-enhanced synergistic therapy. Adv Mater. 2022;34(12): e2107560.
Sun Y, Zheng L, Yang Y, et al. Metal-organic framework nanocarriers for drug delivery in biomedical applications. Nanomicro Lett. 2020;12(1):103.
Liu X, Liang T, Zhang R, et al. Iron-based metal-organic frameworks in drug delivery and biomedicine. ACS Appl Mater Interfaces. 2021;13(8):9643–55.
Drescher D, Büchner T, Schrade P, et al. Influence of nuclear localization sequences on the intracellular fate of gold nanoparticles. ACS Nano. 2021;15(9):14838–49.
Tkachenko AG, Xie H, Coleman D, et al. Multifunctional gold nanoparticle-peptide complexes for nuclear targeting. J Am Chem Soc. 2003;125(16):4700–1.
Tan G, Liu D, Zhu R, et al. A core-shell nanoplatform as a nonviral vector for targeted delivery of genes to the retina. Acta Biomater. 2021;134:605–20.
Wang C, Wang B, Zou S, et al. Cyclo-γ-polyglutamic acid-coated dual-responsive nanomicelles loaded with doxorubicin for synergistic chemo-photodynamic therapy. Biomater Sci. 2021;9(17):5977–87.
Lopes J, Lopes D, Pereira-Silva M, et al. Macrophage cell membrane-cloaked nanoplatforms for biomedical applications. Small Methods. 2022;6(8): e2200289.
Li R, He Y, Zhang S, et al. Cell membrane-based nanoparticles: a new biomimetic platform for tumor diagnosis and treatment. Acta Pharm Sin B. 2018;8(1):14–22.
Xia Q, Zhang Y, Li Z, et al. Red blood cell membrane-camouflaged nanoparticles: a novel drug delivery system for antitumor application. Acta Pharm Sin B. 2019;9(4):675–89.
Rani NN, Alzubaidi ZM, Azhari H, et al. Novel engineering: Biomimicking erythrocyte as a revolutionary platform for drugs and vaccines delivery. Eur J Pharmacol. 2021;900: 174009.
Han X, Wang C, Liu Z. Red blood cells as smart delivery systems. Bioconjug Chem. 2018;29(4):852–60.
Taghipour YD, Zarebkohan A, Salehi R, et al. An update on dual targeting strategy for cancer treatment. J Control Release. 2022;349:67–96.
Bertrand N, Wu J, Xu X, et al. Cancer nanotechnology: the impact of passive and active targeting in the era of modern cancer biology. Adv Drug Deliv Rev. 2014;66:2–25.
Zhang L, Yang J, Tang D, et al. Tumor evolution-targeted nanomedicine<sup>EVT</sup>. Sci Sin Chimica. 2022;52(12):2121–55.
Du B, Han H, Wang Z, et al. targeted drug delivery to hepatocarcinoma in vivo by phage-displayed specific binding peptide. Mol Cancer Res. 2010;8(2):135–44.
Zhang J, Jiang Y, Li Y, et al. Micelles modified with a chitosan-derived homing peptide for targeted intracellular delivery of ginsenoside compound K to liver cancer cells. Carbohydr Polym. 2020;230: 115576.
Du YZ, Cai LL, Liu P, et al. Tumor cells-specific targeting delivery achieved by A54 peptide functionalized polymeric micelles. Biomaterials. 2012;33(34):8858–67.
Jianghong L, Tingting M, Yingping Z, et al. Aptamer and peptide-modified lipid-based drug delivery systems in application of combined sequential therapy of hepatocellular carcinoma. ACS Biomater Sci Eng. 2021;7(6):2558–68.
Liu N, Tan Y, Hu Y, et al. A54 peptide modified and redox-responsive glucolipid conjugate micelles for intracellular delivery of doxorubicin in hepatocarcinoma therapy. ACS Appl Mater Interfaces. 2016;8(48):33148–56.
Zhao Q, Li J, Wu B, et al. Smart biomimetic nanocomposites mediate mitochondrial outcome through aerobic glycolysis reprogramming: a promising treatment for lymphoma. ACS Appl Mater Interfaces. 2020;12(20):22687–701.
Lu CY, Ji JS, Zhu XL, et al. T2-weighted magnetic resonance imaging of hepatic tumor guided by SPIO-loaded nanostructured lipid carriers and ferritin reporter genes. ACS Appl Mater Interfaces. 2017;9(41):35548–61.
Wu X, Zhang X, Feng W, et al. A Targeted erythrocyte membrane-encapsulated drug-delivery system with anti-osteosarcoma and anti-osteolytic effects. ACS Appl Mater Interfaces. 2021;13(24):27920–33.
Huang R, Cai GQ, Li J, et al. Platelet membrane-camouflaged silver metal-organic framework drug system against infections caused by methicillin-resistant Staphylococcus aureus. J Nanobiotechnology. 2021;19(1):229.
Bjornmalm M, Thurecht KJ, Michael M, et al. Bridging bio-nano science and cancer nanomedicine. ACS Nano. 2017;11(10):9594–613.
Tang Y, Wang L, Qin J, et al. Targeting mitophagy to promote apoptosis is a potential therapeutic strategy for cancer. Autophagy. 2022;19(3):1031–1033.
Du Z, Mao Y, Zhang P, et al. TPGS-galactose-modified polydopamine co-delivery nanoparticles of nitric oxide donor and doxorubicin for targeted chemo-photothermal therapy against drug-resistant hepatocellular carcinoma. ACS Appl Mater Interfaces. 2021;13(30):35518–32.
Zhao Q, Sun X, Wu B, et al. Construction of homologous cancer cell membrane camouflage in a nano-drug delivery system for the treatment of lymphoma. J Nanobiotechnology. 2021;19(1):8.
Xu X, Li T, Jin K. Bioinspired and Biomimetic nanomedicines for targeted cancer therapy. Pharmaceutics. 2022;14(5):1109.
Singh R, Sharma A, Saji J, et al. Smart nanomaterials for cancer diagnosis and treatment. Nano Converg. 2022;9(1):21.
Acknowledgements
The authors appreciate https://biorender.com/ provide material for drawing scheme.
Funding
This work was supported by the National Natural Science Foundation of China (Grant No. 81971748 and 82001165), Hunan Provincial Natural Science Foundation of China (Grant No. 2020JJ4131, 2021JJ40926, 2021JJ31002 and 2021JJ40923), the key research and development program of Hunan Province (Grant No. 2022SK2004 and 2020SK2111), the Graduate Self Exploration and Innovation Project of Central South University of China under (Grant No. 2021ZZTS1084 and 2022ZZTS0890), Science and Technology Program of Changsha (Grant No. kh2201057) and the Wisdom Accumulation and Talent Cultivation Project of the Third xiangya hospital of Central South University (Grant No. BJ202101 and YX202206).
Author information
Authors and Affiliations
Contributions
Conceived and designed the experiments: XMN and JL. YFH carried out the experiment and contributed to analyze the experimental results. YFH wrote the manuscript. All authors read and approved the final manuscript.
Corresponding authors
Ethics declarations
Ethics approval and consent to participate
The authors obtained authorization to perform the tests on animal from the committee of the Experimental Animal Welfare Ethics Committee of Central South University.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data.
About this article
Cite this article
Huang, Y., Kou, Q., Su, Y. et al. Combination therapy based on dual-target biomimetic nano-delivery system for overcoming cisplatin resistance in hepatocellular carcinoma. J Nanobiotechnol 21, 89 (2023). https://doi.org/10.1186/s12951-023-01840-3
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s12951-023-01840-3