Inhibition of DAMP Actions in the Tumoral Microenvironment Using Lactoferrin-Glycyrrhizin Nanoconjugate for Glioblastoma Therapy

doi:10.21203/rs.3.rs-2527406/v1

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Research Article

Inhibition of DAMP Actions in the Tumoral Microenvironment Using Lactoferrin-Glycyrrhizin Nanoconjugate for Glioblastoma Therapy

https://doi.org/10.21203/rs.3.rs-2527406/v1

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Journal Publication

published 20 May, 2023

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Background

High-mobility group box-1 (HMGB1) released from the tumor microenvironment plays a pivotal role in the tumor progression. HMGB1 serves as a damaged-associated molecular pattern (DAMP) that induces tumor angiogenesis and its development. Glycyrrhizin (GL) is an effective intracellular antagonist of tumor released HMGB1, but its pharmacokinetics (PK) and delivery to tumor site is deficient. To address this shortcoming, we developed lactoferrin-glycyrrhizin (Lf-GL) conjugate.

Methods

Biomolecular interaction between Lf-GL and HMGB1 was evaluated by surface plasmon resonance (SPR) binding affinity assay. Inhibition of tumor angiogenesis and development by Lf-GL attenuating HMGB1 action in the tumor microenvironment was comprehensively evaluated through in vitro, ex vivo, and in vivo. Pharmacokinetic study and anti-tumor effects of Lf-GL were investigated in orthotopic glioblastoma mice model.

Results

Lf-GL interacts with lactoferrin receptor (LfR) expressed on BBB and GBM, therefore, efficiently inhibits HMGB1 in both the cytoplasmic and extracellular regions of tumors. Regarding the tumor microenvironment, Lf-GL inhibits angiogenesis and tumor growth by blocking HMGB1 released from necrotic tumors and preventing recruitment of vascular endothelial cells. In addition, Lf-GL improved the PK properties of GL approximately 10-fold in the GBM mouse model and reduced tumor growth by 32%. Concurrently, various biomarkers for tumor were radically diminished.

Conclusion

Collectively, our study demonstrates a close association between HMGB1 and tumor progression, suggesting Lf-GL as a potential strategy for coping with DAMP-related tumor microenvironment.

damaged-associated molecular patterns

glioblastoma multiforme

tumor-microenvironment

glycyrrhizin

lactoferrin

Glioblastoma multiforme (GBM) is the most common primary malignant brain tumor, and the median survival is less than a year after diagnosis [1]. Current standards of care include surgical resection followed by radiation therapy and chemotherapy, but only 3 to 5% of GBM patient survive beyond 5 years [2]. In general, GBM tissues are characterized by high expression levels of microvascular proliferation due to upregulation of pro-angiogenesis cytokines [3]. Therefore, anti-angiogenesis has been a priority strategy of drug development for GBM over the last decade. Angiogenesis is intricately linked with tumor progression due to a lack of nutrients and oxygen. In the tumor microenvironment, abnormal and functionally immature blood vessels are generated due to dysregulated factors such as angiogenesis inhibitors, angiogenic growth factors, and other molecules that may act as angiogenesis mediators [4]. Vascular endothelial growth factor (VEGF) is the most representative and well-known angiogenesis regulator in tumors that induces angiogenic intracellular signaling through the mediation of receptor kinases that stimulate pro-angiogenic activity and endothelial cell migration [5]. Bevacizumab, a recombinant monoclonal antibody targeting VEGF ligand A, had received accelerated approval for recurrent GBM in United States, but has not shown any survival benefit in newly diagnosed GBM patients in multiple large-scale phase 3 clinical trials [6]. Therefore, the search for novel angiogenesis modulators and the pursuit of alternative GBM anti-angiogenic therapies have been demanded to date.

High-mobility group box-1 (HMGB1) is a ubiquitous non-histone nuclear protein that acts as an architectural chromatin binding factor [7]. However, once transported into cytoplasm or extracellular space, it participates as a damage-associated molecular patterns (DAMP) that binds to the receptor for advanced glycation end products (RAGE) [8]. Subsequently, it activates AKT and ERK signaling pathways and promotes tumor cell invasion [9, 10]. Recent clinical studies have shown that overexpressed HMGB1 is involved in GBM development, and its expression levels are closely related to the advanced stage of GBM and poor prognosis [11]. HMGB1 released from necrotic tumor cells, a natural phenomenon in tumor development, is expected to be highly involved in angiogenesis and tumor cell progression. Consistent with that expectation, either actively secreted or passively released HMGB1 has been reported to regulate angiogenesis, including promoting endothelial progenitor cells, homing them to tumor tissues, and inducing endothelial cell sprouting and migration [12]. Given the tumor microenvironment, blockade therapy of HMGB1 binding to RAGE is considered a potent strategy to concurrently inhibit angiogenesis and tumor progression. Therefore, delivery of HMGB1-specific antagonists to the tumor microenvironment can efficiently inhibit tumorigenic, angiogenesis and GBM development.

Glycyrrhizin (GL), the active compound of licorice, is a direct antagonist of HMGB1. The inhibitory effect of GL on HMGB1 is manifested in two aspects [13]. GL blocks the release of HMGB1 into the extracellular space by interacting with the two shallow concave surfaces formed by the two arms of the HMG boxes. Also, it inhibits HMGB1 phosphorylation inside the cell, thereby reducing the secretion of HMGB1 and decreasing its overall expression. In addition, GL is found to suppress angiogenic activities of endothelial cells by downregulating ERK angiogenic signaling pathway [14], and also elicits anti-tumor effects by downregulating the NF-κB signaling [15]. Therefore, considering the tumor microenvironment in which tumors deteriorate through HMGB1, GL, which has both antitumor and HMGB1 inhibitory effects, could play a pivotal role in GBM treatment. However, GL has poor bioavailability due to short biological half-life and lacks the GBM targeting ability, which hinders its clinical application. Therefore, the drug delivery system is required for its therapeutic application to GBM.

Our previous studies demonstrated that the modification of drugs via lactoferrin (Lf) can target GBM by penetrating the blood-brain barrier (BBB) and increasing their stability and half-life of blood circulation [16, 17] This was also possible because the lactoferrin receptor (LfR) is highly expressed in the blood-brain barrier (BBB) and GBM cells and on brain endothelial cells [18–21]. Moreover, Lf, a product of exocrine glands that found in many parts of the human body, prevents the partial first-pass effects of hepatic metabolism and allow it to persist longer [22]. Therefore, to overcome the limitations of GL for GBM targeting, here we introduced lactoferrin (Lf) as a targeting ligand for GL delivery. Collectively, Lf-GL conjugate was delivered to GBM, and it effectively regulated the tumorigenic activity of HMGB1 in the tumor microenvironment (Fig. 1a).

Materials

Glycyrrhizin (ammonium salt, purity 95%), sodium periodate (NaIO₄), lactoferrin human (Lf), sodium carbonate (Na₂CO₃), sodium bicarbonate (NaHCO₃), sodium cyanoborohydride (NaBH₃CN), fluorescein isothiocyanate isomer 1 (FITC), 2-mercaptoethanol and tetramethylethylenediamine (TEMED), and water (HPLC grade) were purchased from Sigma-Aldrich (St. Louis, MO, USA). 4′,6-diamidino-2-phenylindole (DAPI) was purchased from Vector Laboratories (Burlingame, CA, USA). NP40, cell extraction buffer, and Lysotracker® were purchased from Invitrogen (Waltham, MA, USA). Phenylmethylsulfonyl fluoride (PMSF), acetonitrile, and methanol (HPLC grade) were purchased from Thermo Fisher Scientific (Waltham, MA, USA). Paraformaldehyde (4%) was purchased by Wako (Kanto, Saitama, Japan). Protease inhibitor and Calcein AM (Cat #: BMD00064) were purchased from Abbkine (Wuhan, China). Sodium dodecyl sulfate was purchased from Affymetrix (Waltham, MA, USA). Acrylamide solution (30%) and ammonium persulfate (APS) were purchased by BIO-RAD (Hercules, CA, USA). Coomassie blue solution was purchased from Abcam (Cambridge, UK).

Experimental Cell Lines And Animals

In vitro experiments were performed using the U87MG human glioma cell line (Korean Cell Line Bank, Seoul, Korea), human umbilical vein endothelial cell line (HUVEC; LONZA, NJ, USA), and the human epithelial colorectal cell line (Caco-2; Korean Cell Line Bank, Seoul, Korea). U87MG (passage numbers 2 to 5) and Caco-2 cells were cultured using Dulbecco’s modified Eagle’s medium (DMEM; GenDEPOT, TX, USA) containing 10% fetal bovine serum (FBS; GenDEPOT), 1% penicillin-streptomycin (Thermo Fisher Scientific) in standard culture conditions at 37°C and 5% CO₂. HUVECs (passage numbers 2 to 4) were cultured using endothelial growth medium (EGM-2 bullet kit; LONZA, NJ, USA) in standard culture conditions at 37°C and 5% CO₂. In vivo experiments were carried out using seven-week-old male Balb/c nude mice and Balb/c mice (Nara-Bio Company, Seoul, Korea). All animals were housed in specific pathogen-free conditions and maintained under the Institutional Animal Care and Use Committee (IACUC: 2021-0108A) at Hanyang University.

Preparation Of Lactoferrin-glycyrrhizin Conjugate (Lf-gl)

GL (50 × 10^− 3 M) was dissolved in distilled water and pH was adjusted using sodium carbonate (1.0 M) until the GL was fully dissolved into the solution. Next, sodium periodate (50 × 10^− 3 M) was dissolved in distilled water and the solution was kept in the dark. Then, the GL solution was slowly dropped into a SP solution to oxidize GL by stirring in the dark for 2 h at RT. Lf (0.0625 × 10^− 3 M) was dissolved in carbonate-bicarbonate buffer (CBS) (pH 10.5) at 4℃. The same volume of the Lf solution was added to the oxidized-GL solution in a drop-wise manner. The solution was reacted at 4℃ for 6 h. Finally, sodium cyanoborohydride solution (5 M, 10 µL) was added per milliliter. The reaction was allowed to proceed overnight at 4℃. The resulting solution was dialyzed with MWCO 50 kDa Centricon^™ (Millipore, MA, USA) to remove unreacted substances. Then, it was lyophilized for 2 days to obtain the Lf-GL conjugate.

Characterization Of Lf-gl

Fourier transform infrared spectroscopy measurements (FT-IR, NICOLET IS50, Thermo Fisher Scientific) were conducted to identify the functional group of Lf-GL. The molecular weight of Lf-GL was determined by SDS-PAGE (12%-gel) and matrix-assisted laser desorption/ionization time-of-flight (MALDI TOF). MALDI-TOF was conducted at Seoul National University (Korea) using a MALDI-TOF Voyager DE-STR (Applied Biosystems, MA, USA). A sinapinic acid (Sigma-Aldrich) aqueous solution containing about 30% acetonitrile in 0.15% trifluoroacetic acid (Millipore) was used as a matrix. High performance liquid chromatography (Alliance HPLC e2695, Waters, MA, UK) using a gel permeation chromatography (GPC) column was performed to verify GL content in the Lf-GL conjugate. The mobile phase was composed of methanol, acetonitrile, water, and acetic acid in a ratio of 55:23.69:19.63:0.68. GL was dissolved in the mobile phase in different concentrations (2.5 to 200 × 10^− 6 M), and Lf-GL (25 × 10^− 6 M) was also dissolved in the mobile phase. Ultrahydrogel 120 Column (Waters) was used as a column, and the flow rate was 1 mL min^− 1. Then, absorbance was measured at 254 nm, and the results were calibrated with Empower software (Waters).

Binding Affinity Against Hmgb1

To confirm the binding affinity of Lf-GL to HMGB1, Surface Plasmon Resonance (SPR) was conducted at WoojungBSC (Korea). The Reichert SR7500DC system (Reichert technologies, NA, USA) and Scrubber2 software (Biologic software, FRA) were used, and a CMDH chip (Cat #: 13206066, Reichert technologies) was used for immobilization of the human recombinant HMGB1 protein (Abcam). HMGB1 protein was used as a ligand, and the analytes were HMGB1 antibody (Abcam), GL, Lf and Lf-GL conjugate. The immobilization buffer was S.A. (10 × 10^− 3 M, pH 4.5), and the running buffer was PBS (pH 7.4). The flow rate of the analyte was 30 µL min^− 1. The association and dissociation time were 3 min each, and measurements were conducted at room temperature. Results are expressed in response units (RU) over time.

Cell Viability Test

Cell viability was determined using a cell counting kit-8 (CCK-8). U87MG and HUVECs (seeding density: 0.75 × 10⁴ cells per well) in 96-well culture plates were treated with GL, Lf, or Lf-GL (25 to 200 × 10^− 6 M of GL equivalent concentration) and were incubated for different periods of time (24, 48, and 72 h). After washing with PBS, they were treated with a cell culture medium containing a CCK-8 assay kit (Abbkine) and were incubated at 37°C and 5% CO₂ for 2 h. Then, absorbance was measured at 450 nm in a micro-plate reader (VLBL00D0, Thermo Fisher Scientific). Results were quantified using Sigma Plot (Systat Software, USA). To determine the effect of extracellular HMGB1 in GBM and endothelial cell proliferation, U87MG and HUVECs were seeded in 96-well culture plates (seeding density: 0.75 × 10⁴ cells per well) and GL, Lf, or Lf-GL (50 × 10^− 6 M GL equivalent concentration) were added to cells with or without HMGB1 protein (U87MG: 0.1 µg mL^− 1, and HUVEC: 1 µg mL^− 1). Cells were incubated for different periods of time (24, 48, and 72 h).

Cell Migration Assay

A wound-healing scratch assay was performed in U87MG to evaluate the effect of GL, Lf and Lf-GL treatment on the cancer cell migration. Cells were seeded in 100 mm-cell culture dishes, 2.0 × 10⁶ cells per dish. After the cells were grown to 80% confluence, a scratch was made through the cell monolayer with a 200 µL pipet tip, and it was washed with PBS. Photographs (4×) were taken in each of three different scratch areas, and their location on the dish was marked. GL (50 × 10^− 6 M), Lf (5 × 10^− 6 M) or Lf-GL (1 × 10^− 6 M) dissolved in serum-free medium were added to cells with or without HMGB1 protein (0.1 µg mL^− 1). Then, cells were incubated for 24 h, and the same areas were re-photographed. Migration distances were examined using the scale bar.

In Vitro Gbm Cell Uptakes Of Lf-gl

To verify cellular uptake of Lf-GL, U87MG cells (seeding density: 2.5 × 10⁴ cells per well) in an 8 well Nunc™ Lab-Tek II chambered coverglass (Thermo Scientific) were treated with FITC-tagged Lf-GL (1 × 10^− 6 M) for different time periods (0 to 18 h). After washing with PBS, cells were treated with lysotracker (75 × 10^− 9 M) and incubated for 2 h. Then, cells were fixed with 4% paraformaldehyde followed by DAPI mounting. Confocal laser scanning microscopy (SP8 X, Leica, Germany) was used to observe intracellular fluorescence, and images were processed using LAS X software (Leica).

HMGB1 ELISA

U87MG cells were seeded in 100 mm-cell culture dishes (2.2 × 10⁶ cells per dish) and treated with GL, Lf, or Lf-GL (50 × 10^− 6 M GL equivalent concentration) for 48 h. After incubating, cells were collected using a cell scrapper and were centrifuged for 3 min at 150 × g. Supernatant was collected as cell culture medium, and pellets were washed with cold PBS twice and transferred into a microcentrifuge tube. Tubes were centrifuged, and then pellets were resuspended in 500 µL 1X hypotonic buffer and incubated on ice. Then, 25 µL of NP40 was added and the mixture was agitated using a vortex mixer at the highest setting. Homogenates were centrifuged for 10 min at 842 × g at 4℃. Supernatant was collected as the cytoplasmic fraction, and pellets were resuspended in cell extraction buffer (50 µL) and were incubated for 30 min on ice with vortexing at 10 min intervals. Then, homogenates were centrifuged for 30 min at 14,000 × g at 4℃. Supernatant was collected as the nuclear fraction. The amount of HMGB1 in the samples was measured using a HMGB1 ELISA kit (Abbkine), and absorbance was measured at 450 nm in a micro-plate reader. A DNA assay (Quant-iT™ dsDNA Assay Kit, Invitrogen) was also conducted to express HMGB1 concentrations in equivalent amounts of DNA.

Tube Formation Assay

A 24-well plate was coated with of Matrigel® (200 µL, Corning, NY, USA) and was incubated for 30 min in 37℃ incubators. HUVECs were seeded upon a coated Matrigel® 24-well plate (seeding density: 5.0 × 10⁴ cells per well). Subsequently, cells were treated with GL (50 × 10^− 6 M), Lf (5 × 10^− 6 M) or Lf-GL (1 × 10^− 6 M) and incubated for 24 h. Then, Calcein AM was added to each well, and the formation of tubes was observed using fluorescence microscopy. These tubes were quantified using Image J.

Aorta Ring Assay

An aorta ring assay was conducted to confirm the anti-angiogenesis effect of Lf-GL ex vivo. A 48-well plate was coated with of Matrigel® (100 µL) and was incubated for 30 min or more in 37℃ incubators. In the meantime, thoracic aortas of 7-week old male SD rats were excised. Then, the fat layer and outer membrane were removed, and rings approximately 1 mm in length were prepared. The prepared aortic rings were seeded on a coated Matrigel® of 48-well plate and were covered with Matrigel®. (100 µL) Subsequently, the aortic ring was treated with a control (with or without 25 ng mL^− 1 of VEGF) or different concentrations of Lf-GL complex. Medium was changed once every two days. Fourteen days after treatment, optical images of sprouting microvessels were obtained using microscopy magnification (×40 or ×100). Sprouting microvessel area was quantified using Image J and Sigma Plot.

Western Blot

Total cellular protein concentration was determined using a BCA Protein Assay Kit (Pierce, Rockford, IL, USA). Equal amounts of protein from cell lysates were loaded onto a 12% sodium dodecyl sulfate-polyacrylamide gel. After electrophoresis, proteins were transferred to polyvinylidene fluoride membranes blocked with 5% bovine serum albumin for 1 h at room temperature and were diluted 1:500 with the indicated primary antibodies (rabbit anti-ERK1/2, anti-phospho-ERK1 and β-actin antibodies [Cell Signaling Technology, INC.]). Then, the membrane was washed 3 times for 15 minutes with tris-buffered saline containing Tween 20 and was incubated with HRP-conjugated secondary antibody for 1 hour at room temperature. After washing three times for another 15 min with Tris-buffered saline with Tween 20, immune complexes were detected with an enriched chemiluminescent reagent (EZ-Western Lumi Femto, DoGen, South Korea) and staining was quantified by densitometry analysis using an Alpha Imager 2200.

Huvec Co-cultured With U87mg

To evaluate the inhibitory effect of Lf-GL on neovascularization in the tumor microenvironment in vitro, U87MG cells were seeded in the Transwell® insert chambers that were 6.5 mm in diameter and had 0.4 µm pore sizes (seeding density: 2.5 × 10⁴ cells per well, Corning). HUVECs were seeded in the Transwell basal chamber (seeding density: 5.0 × 10⁴ cells per well). GL, Lf, or Lf-GL (100 × 10^− 6 M of GL equivalent concentration) were added to the insert chamber, and cells were incubated for 24 h. CCK-8 assay and HMGB1 ELISA were conducted at the basal chamber.

In Vivo Pharmacokinetics Study Of Lf-gl

Balb/c mice were used for pharmacokinetics studies of GL and Lf-GL. Mice were administrated with GL equivalent concentration doses of 50 mg kg^− 1 body weight through tail vein injection. After the GL and Lf-GL injection, blood samples (500 µL) were collected by intra-cardiac puncture at time points of: 1 min, 3 min, 5 min, 10 min, 30 min, 1 h, 2 h, 2.5 h, 6 h, 12 h, 18 h, and 24 h. Blood samples were collected in ethylene-diamine-tetraacetic acid (EDTA) tubes (Microcollect, GSMEDITECH, Korea), and then centrifuged for 30 min at 842 × g in 4℃. Then, supernatants (50 µL) were mixed with methanol (100 µL). After vortexing for 10 min, extracts were centrifuged for 10 min at 10,000 × g. Thereafter, supernatants (100 µL) were mixed with the mobile phase solution (900 µL), which were then filtered with a syringe filter (0.22 µm). Samples were collected in 2 mL HPLC vials (Screw top vial, Waters) and analyzed with HPLC. The GL standard samples for calibration were also conducted using the same process. The absorbance of the samples was measured at 254 nm, and concentrations were calibrated through a GL standard curve.

In Vivo Fluorescence Tracer Image Of Lf-gl

For the fluorescence tracer images, Balb/c mice were administered either FITC-tagged GL or FITC-tagged Lf-GL at a GL equivalent concentration of 50 mg kg^− 1 body weight via tail vein injection. After 1, 10, 30, and 60 min, the experimental mice were sacrificed, and the organs were extracted. The fluorescence signals of FITC-tagged GL or FITC-tagged Lf-GL in organs were imaged using an in vivo imaging system (FOBI, CELLGENTEK, South Korea). The exposure time was fixed to 200 sec for analyzing fluorescent signals from tissues. The quantified fluorescence signal of the brain at each time point was measured in terms of intensity units (IU, Intensity Min^− 1 Gain^− 1).

In Vivo Analysis Of Gbm Targeted-gl By Hplc In Orthotopic Gbm Modeled Mice Brain

Orthotopic GBM mice model mice were used for quantification of GBM targeting efficacy. The brain tissue was homogenized in deionized water at a 33.3 w/v (%) using a FastPrep-24 5G (MP biomedical, South Korea). The GL were added to pooled brain homogenate to obtain seven-point calibration curves with a range of 10-1000 ng mL^− 1. Then, homogenate (50 µL) was mixed with methanol (100 µL). After vortexing for 10 min, extracts were centrifuged for 10 min at 10,000 × g. Thereafter, supernatants (100 µL) were mixed with mobile phase solution (900 µL), then filtered with a 0.22 µm syringe filter. Samples were collected in a 2 mL HPLC vial (Screw top vial, Waters, USA) and analyzed by HPLC at 254 nm. For the comparative study of GBM targeting, mice were administered GL and Lf-GL at a GL equivalent concentration dose of 50 mg kg^− 1 body weight through tail vein injection. Mice were sacrificed and brain tissues were collected 10 min after the GL and Lf-GL injection. The samples for quantification were also conducted using the same process as GL standard preparation. The absorbance of the samples was measured at 254 nm, and concentrations were calibrated suing the GL standard curve.

In Vivo Systemic Toxicity Evaluation In Gbm Mouse Model

To establish the orthotopic GBM mice model, GBM cells (U87MG, inoculation density: 1.0 × 10⁶ cells per 10 µL) were stereotactically injected into the right striatum of Balb/c nude mice. Then, mice were randomly divided into four groups (n = 5): control, GL, Lf, and Lf-GL treated group. From the day after tumor transplantation, the mice were administrated the drugs with GL equivalent concentration doses of 50 mg kg^− 1 body weight through tail vein injection every other day. Mice were observed for four weeks, and body weights and survival rates were recorded. After four weeks, mice were sacrificed, and organs were harvested and fixed with 4% paraformaldehyde for further analysis.

In Vivo Histological Study For Lf-gl Efficacy On Gbm Mouse Model

GBM mice were prepared and grouped as in previous experiments, but drugs were administrated every day (GL equivalent concentration dose of 50 mg kg^− 1 body weight through tail vein injection). After two weeks, mice were sacrificed, and the brains were harvested and fixed with paraformaldehyde (4%). Then, tissue processing was automatically conducted using a Leica TP1020 semi-enclosed Benchtop Tissue Processor (Leica Biosystems, Wetzlar, Hesse, Germany), followed by embedding in paraffin blocks. Paraffin blocks were sliced into 5 µm thick slices using a Leica RM2145 Microtome (Leica Biosystems). Nissl staining was used to stain brain tissue slides with pre-warmed 0.1% Cresyl Violet Stain Solution (Abcam). TUNEL assays were conducted following the manufacturer’s instructions. For immunofluorescence staining; anti-HMGB1 antibody (Abcam), anti-Ki67 antibody (Abcam), anti-CD31 antibody (Abcam), and anti-VEGF antibody (Abcam) were used as primary antibodies, and goat anti-rabbit IgG-H&L Alexa Fluor 488 and goat anti-rabbit IgG H&L Alexa Fluor 647 were used as secondary antibodies, followed by DAPI mounting.

Statistics

All data are presented as the mean ± standard error of the mean (S.E.M). Statistical analysis was evaluated by Student’s t-tests or one-way analysis of variance (ANOVA) (Sigma Plot). P-values less than 0.05 are considered to be statistically significant.

Synthesis and characterization of Lf-GL conjugate

To construct Lf-GL conjugate, we first oxidized GL using sodium periodate, a strong oxidant that is also used for opening glucose rings between vicinal diols [23], therefore aldehyde residues were exposed. Afterward, the aldehyde of oxidized-GL and amine of Lf undergo a Schiff-Base reaction to form a secondary amide bond. In this procedure, cyanoborohydride works as a reductant to reducing unstable secondary amide bonds to stable primary amide bond (Fig. 1b). The conjugation between GL and Lf was confirmed by FT-IR analysis, it exhibited amide I and amide II vibrations in both Lf and Lf-GL at 1,520 cm^− 1 and 1,630 cm^− 1 (Fig. S1) [24]. The observed peak at 1,035 cm^− 1 in both GL and Lf-GL indicates the primary alcohol stretch of GL. Therefore, the observation of the characteristic peaks of each Lf and GL in the Lf-GL conjugate suggests that the Lf-GL conjugation proceeded as intended. In the SDS-PAGE result, the band of Lf-GL shifted upward compared to native Lf due to the increased molecular weight by conjugation (Fig. S2). Moreover, in HPLC analysis, GL was detected at 17 min, while Lf-GL was detected at 3.5 min (Fig. S3). The faster elution time of Lf-GL compared to GL indicates that Lf-GL has a higher molecular weight than GL while maintaining sufficient GL content. MALDI-TOF was conducted to quantify the molecular weight of Lf-GL (Fig. S4). Average molecular weights of Lf and Lf-GL were 78,497.9 and 86,727.3 Da, respectively. Considering that the molecular weight of GL was 822.9 Da, the binding ratio between Lf and GL was 1:10.

Lf-gl As A Potent Hmgb1 Antagonist Due To Its High Binding Affinity To Hmgb1

GL is one of the most potent inhibitors of HMGB1 and is known to block the nucleocytoplasmic translocation of HMGB1, thereby inhibiting its extracellular secretion and function as a DAMP in the tumor microenvironment [25, 26]. Therefore, we evaluated the respective binding affinities of different concentrations of GL, Lf, and Lf-GL to HMGB1 (Table 1 and Fig. S5). The K_D value of GL was 540.0 ± 20 µM for the HMGB1, whereas the values of Lf, Lf-GL (1:4), Lf-GL (1:10) and Lf-GL (1:15) were 165.0 ± 3, 595 ± 5, 23.1 ± 0.1 and 32.3 ± 0.2 nM, respectively. It is noteworthy that Lf and Lf-GL showed higher affinity for HMGB1 compared to the HMGB1 antibody (K_D value of 1.0 ± 3.0 µM) as well as GL, which is known as an antagonist to HMGB1 [13]. Among analytes, Lf-GL (1:10) showed the highest affinity with a K_D value of 23.1 ± 0.1 nM, whereas that of Lf-GL (1:15) containing more GL was 32.3 ± 0.2 nM. In general, the structural mechanism by which GL binds to HMGB1 is known as an extended hydrophobic interaction due to the formation of a concave surface formed by the two arms of HMG box A [27]. More specifically, the proximal glucuronic acid residue (attached to the terpenoid unit) of GL is key for the HMG interaction, in which hydrogen bonds and hydrophobic interactions stabilize the HMGB1-GL complexes. The bond stability is then further increased through intramolecular cysteine disulfide bonds. However, in our results, excessive amounts of GL (Lf-GL (1:15)) are shown to interfere with binding to HMGB1 by inducing intermolecular pi-pi stacking, hydrophobic interactions and hydrogen bonding [28]. Taken together, Lf-GL (1:10) contains an adequate amount of GL without physical interference for HMGB1 binding, and the contribution of Lf to HMGB1 binding leads to improved affinity. Therefore, Lf-GL (1:10) was determined to exert optimal pharmacological properties and was subjected to further experiments.

Table 1

Binding affinity for HMGB1 according to the respective dissociation constants
Ligand	Analyte	K_a [M^− 1s^− 1]^a)	K_d [M^− 1s^− 1]^b)	K_D [M]^c)
HMGB1	Glycyrrhizin	5.3 ± 0.1	0.00283 ± 0.00003	540 ± 20 µM
	Lactoferrin	(8.1 ± 0.1)∙10⁴	0.01336 ± 0.00005	165 ± 3 nM
	Lf:GL (1:4)	(2.66 ± 0.02)∙10³	0.001584 ± 0.000008	596 ± 5 nM
	Lf:GL (1:10)	(2.6 ± 0.01)∙10⁴	(3.11 ± 0.02)∙10^− 4	23.1 ± 0.1 nM
	Lf:GL (1:15)	(2.99 ± 0.02)∙10⁴	(9.65 ± 0.04)∙10^− 4	32.3 ± 0.2 nM
	HMGB1 Ab	(1 ± 3)∙10²	(1.60 ± 0.01)∙10^− 4	1 ± 3 µM
^a) Association rate constant. ^b) Dissociation rate constant. ^C) Equilibrium dissociation constant (K_D = K_d K_a⁻¹)

Table 2. Pharmacokinetics parameters of intravenously administered glycyrrhizin and Lf-GL

Parameters	C_max (µg mL^− 1)	AUC_last (µg mL^− 1)	T_max (min)	T_1/2 (min)	MRT (min)
Glycyrrhizin	253.7 ± 116.8	6109.5 ± 3695.5	1	3.8 ± 0.2	4.6 ± 0.3
Lf-GL	271.0 ± 130.9	71255.2 ± 45319.4	1	5.3 ± 0.4	3.4 ± 0.8
C_max: maximum plasma concentration; AUC_last: area under plasma concentration-time curve from zero to last time; T_max: time to reach C_max; T_1/2: elimination half-life; MRT: mean retention time.

In Vitro, Attenuation Of Gbm Proliferation By Lf-gl Treatment

A cell viability assay showed that Lf-GL more significantly reduced the number of GBM cells (U87MG) compared to Lf- and GL-treated groups at all GL equivalent concentrations of 25 µM to 200 µM (Fig. 2a and Fig. S6). Since the non-toxic concentration of Caco-2 cells considered normal cell was less than 100 µM while sufficient anti-tumor effect achieved above 25 µM (Fig. S7), further experiments were set at 50 µM. The inhibitory effects of GL, Lf and Lf-GL on cell growth were measured for 72 h (Fig. 2b). After 48 h treatment, GL, Lf and Lf-GL reduced the number of cells to 93.4 ± 4.8, 69.6 ± 5.7 and 44.1 ± 6.3% of the original count, respectively. Thereafter, cell number of the GL- and Lf-treated groups increased sharply over the next 24 h. In contrast, the Lf-GL-treated group efficiently attenuated the growth rate to 68.7 ± 15.9%. Considering the U87MG doubling time of 30.8 ± 2.5 h [29], it is anticipated that Lf-GL inhibits proliferation through cell division.

A major problem of chemotherapy is that high pressure in solid tumors reduces drug diffusion from blood vessels to tumor cells, resulting in poor penetration [30]. Therefore, anti-proliferative effect of Lf-GL on the three-dimensional (3D) structure of solid tumor-like glioma spheroids was investigated for 6 days (Fig. S8a). Morphological changes of spheroids including surface collapse or 3D structure destruction were not observed in the Lf-GL treatment. However, it sufficiently impeded the growth of tumor spheroids. The average volume of the control group increased gradually, which was 294% at day 6 compared to day 0 (Fig. S8b). In Lf-GL (1:4) and Lf-GL (1:15), spheroids increased in volume at day 6 by 185% and 179%, respectively, and moderate confinement effect was observed. Intriguingly, spheroids treated with the Lf-GL (1:10) increased by 156% at day 6, which was the slowest growth rate among other treatment groups. Furthermore, live/dead assay was conducted to determine the mechanism of Lf-GL in its tumor suppressive effect (Fig. S9). As a result, the growth of tumor spheroids was inhibited by anti-proliferation rather than by cell death such as apoptosis or necrosis. Consistently, the ratio of annexin V (+)/PI (+) cell population in the Lf-GL treatment group was 0.28%, which was lower than 1.40% in the control group. (Fig. S10). In addition, we observed that Lf-GL inhibits phosphorylation and activation of ERK1/2 signaling, a crucial factor involved in tumor cell proliferation and invasion (Fig. S11). In this regards, it has been reported that Lf exerts an antitumor effect through downregulation of pERK1/2, pPI3K, and pAkt [29]. This demonstrates that Lf-GL could more effectively downregulate the fast-growing nature of GBM due to the additional attribution of Lf in regulating the phosphorylation of kinases such as pERK1/2.

HMGB1-mediated GBM cell proliferation and its inhibitory effect of Lf-GL were investigated for 3 days. HMGB1 upregulated tumor growth by 110.7 ± 8.2, 133.4 ± 1.3 and 140.7 ± 5.2% on days 1, 2 and 3, respectively, compared to controls not treated with HMGB1. In this system, Lf-GL resulted the most robust inhibitory effect over 3 days (Fig. 2c). In the wound healing scratch assay, the HMGB1-treated cell (noted as HMGB1 (+)) migrated 121.3 ± 42.8 µm more than the HMGB1-nontreated cell (noted as HMGB1 (-)) at 24 h (Fig. 2d). Similar to the above results, Lf-GL inhibited cell migration in the absence of HMGB1, but its effect was more dominant in the presence of HMGB1 (Fig. 2e). This could be the direct evidence that HMGB1 induces rapid tumor growth and metastasis, but Lf-GL can refrain HMGB1-mediated tumor progression with high affinity.

Downregulation Of Cytoplasmic-hmgb1 Level By Lfr-mediated Endocytosis Of Lf-gl

The cellular uptake of Lf-GL was investigated to determine the cause of the lethal inhibitory effect on the proliferation of tumor cells. As a result, Lf-GL gradually internalized into U87MG cells up to 84.5% over 18 h (Fig. S12). To examine the endocytic mechanism of Lf-GL, the cellular uptake of FITC-tagged Lf-GL was monitored through flow cytometry in the presence of the Lf or Pitstop®, which is an inhibitor of clathrin-mediated endocytosis. After 2 h incubation, the cellular internalization of Lf-GL-FITC decreased about 17% in the presence of Lf, whereas it was not affected in the Pitstop® treatment. This result indicates that Lf-GL internalizes cells via the Lf receptor (LfR), but its endocytic pathway does not follow the clathrin-mediated pathway. Colocalization of Lysotracker and FITC-tagged Lf-GL indicated the receptor mediated endocytosis through LfR overexpressed in U87MG cellular membranes, suggesting that it increases cellular uptake compared to GL (Fig. 2f) [31]. Moreover, after 18 h of incubation, Lf-GL was located in the cytoplasm, which is interpreted as a result of stable escape from lysosomes. The level of HMGB1 in the culture medium, nucleus, and cytoplasm was investigated. In the culture medium, the level of HMGB1 in the control group was 131.8 ± 11.4 ng mL^− 1. In contrast, the level of HMGB1 decreased to 104.7 ± 1.0, 79.8 ± 1.7 and 74.0 ± 0.9 ng mL^− 1 in the GL-, Lf- and Lf-GL-treated groups, respectively (Fig. 2g, the HMGB1 level in medium fraction). Therefore, secreted extracellular HMGB1 was effectively inhibited by GL, Lf and Lf-GL, and the extent was most pronounced in Lf-GL due to its highest binding affinity for HMGB1. Furthermore, the level of HMGB1 in the cytoplasmic fraction was the lowest in the Lf-GL-treated cells among the drug treated groups (GL-, Lf- and Lf-GL-treated cell) (Fig. 2g, the HMGB1 in cytoplasm fraction). This suggests that the enhanced cellular uptake of Lf-GL raise more opportunity to arrest cytoplasmic-HMGB1, which plays a critical role as a DAMP.

Anti-angiogenic Effect Of Lf-gl

Angiogenesis is a fundamental event in solid tumor progression, where inhibition of neovascularization is considered a beneficial therapeutic approach. Therefore, we investigated the anti-angiogenic effects of Lf-GL on the neovascularization activities of endothelial cells. Cell viability assays showed that Lf-GL reduced the number of HUVEC the most (Fig. 3a, Fig. S13). Contrary to the mechanism in GBM cells, Lf-GL severely induced apoptosis and necrosis of endothelial cells (Fig. S14). Furthermore, the inhibitory effect of Lf-GL on endothelial cell proliferation, which is essential for angiogenesis, was monitored for 3 days. As a result, Lf-GL significantly inhibited endothelial cell growth compared to either the GL- treated or the Lf- treated groups for the entire time (Fig. 3b). To further investigate the contribution of extracellular HMGB1 to tumor angiogenesis, HMGB1 protein were treated to HUVEC to mimic the activity of HMGB1 in tumor microenvironment. HMGB1 indeed increased angiogenic potential of HUVEC by 108.2 ± 7.9, 137.9 ± 12.3 and 169.8 ± 18.1% on day 1, 2 and 3, respectively (Fig. 3c, viability comparison between control and HMGB1 (+) control groups). Due to the high binding affinity of Lf-GL against HMGB1, it successfully attenuated the angiogenic effect triggered by HMGB1. It is known that HMGB1 triggers an angiogenic gene expression in endothelial cells and is involved in autocrine and paracrine cycle mechanisms resulting in positive enforcement of HMGB1 expression and that of its receptors like toll-like receptor 4 (TLR4) and RAGE [10, 32]. To this respect, Lf-GL may break this vicious cycle leading to endothelial cell sprouting and migration.

In the study of capillary tube formation, newly generated micro-vessels were increased by 21.0 ± 2.1% upon exposure to HMGB1 (Fig. 3d and 3e, comparison of angiogenic tube number between HMGB1 (-) control and HMGB1 (+) control groups). In this regard, Lf-GL significantly decreased the tube formation in both absence and presence of HMGB1 treatment, respectively. The ERK and phosphorylated-ERK (p-ERK) signaling molecules, which are critically involved in endothelial cell proliferation, were investigated to gain further insight into the relationship between HMGB1 and HUVEC proliferation (Fig. 3f). After 24 h of treatment with HMGB1, the p-ERK level was significantly increased by 2.3 times compared to non-treatment of HMGB1 (Fig. 3g). However, Lf-GL reversed the ratio of p-ERK to ERK induced by HMGB1, inhibited most ERK phosphorylation, and showed substantial anti-angiogenic ability of Lf-GL.

Aortic rings obtained from rats were treated with GL, Lf and Lf-GL for 14 days to examine the anti-angiogenic effect under conditions where endothelial cells, progenitor cells, and other angiogenic factors are interacting (Fig. 3h) [33]. Vascular endothelial growth factor (VEGF) was used as a positive control group, and the outgrowth of endothelial tubules increased by 51.1 ± 105.2%. Furthermore, the vascular development from the intima/subintima of the aorta, sprouting from the initial vessels, and new micro-vessels formation was found in control (Fig. S15) On the other hand, Lf-GL decreased the sprouted area of the micro-vessel by 80.2 ± 4.5%, degenerated pre-existed blood vessels and suppressed new micro vascularization (Fig. 3i).

Inhibition Of Tumor Progression By Lf-gl In The Tumor Microenvironment

To clarify the influence of tumor released-HMGB1 on endothelial cell proliferation, we mimicked the tumor microenvironment with a co-culture system using 0.4 µm pore size trans-well plates. In this model, HUVECs were seeded in the basal chamber and U87MG cells were seeded in the apical compartment (Fig. 4a). As a result, the proliferation and viability of endothelial cells, which are essential for angiogenesis and microvascular sprouts, were increased by 31.6 ± 1.8% in the co-culture system (Fig. 4c). Accordingly, the HMGB1 concentration in the medium increased from 165.6 ± 16.6 to 217.8 ± 5.9 ng mL^− 1 in the co-culture condition (Fig. 4d, comparison between HUVEC only and control of HUVEC/U87MG co-cultured). This suggests that HMGB1 secreted from tumor is a key regulator for angiogenesis and that glioma and endothelial cells may have reciprocal effects through HMGB1. By arresting tumor secreted-HMGB1, GL, Lf and Lf-GL reduced endothelial cell proliferation by 10.7 ± 2.9, 8.2 ± 2.9 and 13.0 ± 0.7%, respectively (Fig. 4c), and HMGB1 level decreased to 190.7 ± 19.0, 177.3 ± 3.6 and 176.1 ± 4.9 ng mL^− 1, respectively (Fig. 4d).

Extension Of Survival Rate With Minimal Systemic Toxicity Through Lf-gl Treatment

Survival and systemic toxicity studies were performed by intravenous administration of daily doses (equivalent GL concentration dose of 50 mg kg^− 1 and Lf concentration dose of 5 mg kg^− 1) to GBM-mice model for 28 days (Fig. 5e). As a result, PBS vehicle-administered (Control) began to die on day 21 and none survived until day 25. The GL had a modest effect on long-term survival in that survived 4 more days. Interestingly, the Lf or Lf-GL-treated mice had an additional 5 days in the overall survival rate. Moreover, 20% and 80% of the mice in the Lf-and Lf-GL-treated groups survived up to 28 days, respectively. (Fig. 5f). Weight loss an important parameter in repeated-dose toxicology studies [36], were measured throughout the experiment to investigate the systemic toxicity of Lf-GL upon long-term repeated dosing (daily administered for 28 days) (Fig. 5g). There was no difference in body weight in all experimental groups until day 21, the time of death due to tumor development. The spleen weight/body weight ratio was evaluated to investigate whether spleen enlargement occurred due to unwanted immune stimulation after repeated administration. As expected, there was no significant difference between groups (Fig. 5h). Histopathological analyses of the heart, liver, lung, spleen, and kidneys were conducted and there was no detection of immune responses leading to histological lesions composed of inflammatory cells such as neutrophils, macrophages, and B lymphocytes in all groups (Fig. S17). Therefore, we inferred that repeated administration of Lf-GL itself does not cause an unnecessary immune response to the reticuloendothelial system (RES) and has no systemic toxicity. Moreover, due to the improved PK properties of Lf-GL (Table 2), we expected it to be an excellent conjugate formulation that can improve tumor targeting by reducing RES clearance and increasing bioavailability.

Reduction Of Biomarkers Related To Tumor Development By Inhibition Of Hmgb1 Activity

The restriction effect of Lf-GL on tumor development was assessed with intravenous administration of daily doses (equivalent GL concentration dose of 50 mg kg^− 1 and Lf concentration dose of 5 mg kg^− 1) up to 14 days after GBM modeling (Fig. 6a). The mean fluorescence intensity (MFI) of HMGB1 was highest in the PBS vehicle-administered (control) group, with a value of 15.3 ± 1.7. In contrast, the GL-, Lf-, and Lf-GL- administration group reduced the MFI of HMGB1 to 6.2 ± 0.8, 7.9 ± 1.4, and 1.7 ± 1.0, respectively, and the distribution area was relatively narrow (HMGB1 immunofluorescence staining in Fig. 6b and 6c). This could be interpreted as Lf-GL arrests the tumor-released HMGB1 at an early stage and prevents aggressively worsening tumor growth. Furthermore, HMGB1 promotes vascular endothelial growth factor (VEGF) secretion in a RAGE-dependent manner and is also known to stimulate endothelial progenitor cells homing to tumor tissue [37]. Therefore, the control group, which had a high MFI value of HMGB1, also showed the highest MFI value of VEGF among the experimental groups but it gradually decreased by the treatments (VEGF immunofluorescence staining in Fig. 6b and 6d). GBM is a tumor in which angiogenesis actively occurs, although a marked imbalance between angiogenesis-promoting factors and anti-angiogenic factors in the tumor microenvironment results in abnormal blood vessels. To this end, tumor vascularization of CD31, an endothelial cell marker, was investigated. Expression of CD31 associated with abnormal blood vessels was detected high in the control group with an MFI value of 14.7 ± 1.4. Moreover, its CD31-positive blood vessels dispersed throughout the GBM lesions. In contrast, the MFIs of CD31 in the GL-, Lf-, and Lf-GL- administered group decreased by approximately 4-, 2-, and 7-fold, respectively (CD31 immunofluorescence staining in Fig. 6b and Fig. 6e). Consistent with the CD31 staining results, tumor cell proliferation marker Ki67 was also expressed abundantly in the control group, but treatments decreased similarly to CD31(Ki67 immunofluorescence staining in Fig. 6b and 6f).

Significant Gbm Therapeutic Effect By Lf-gl Treatment In Orthotopic Gbm Mouse Model

The GBM/normal brain ratio was determined through Nissl staining. GL-, Lf-, and Lf-GL-administered group reduced the ratio to 26.4 ± 5.7, 29.7 ± 3.3, and 8.9 ± 3.2, respectively. On the other hand, the PBS vehicle-administered group (Control) showed the highest ratio of 37.5 ± 2.3 (Fig. 6g and 6i, Nissl staining). In the H&E results, the tumor tissue had a dense structure and consisted of polymorphic cells with oval nuclei 10 to 20 µm in diameter. A large number of necrotic areas were observed in the GBM region of the control groups, whereas it significantly decreased in the GL-, Lf-, and Lf-GL-administered groups (Fig. 6g and 6j, H&E staining). It was noteworthy that hemorrhage and thrombosis were observed in the GBM region of the Lf-GL-administered group (Fig. 6g, green dashed line in Lf-GL group). This is because Lf-GL limits tumor vascularization through apoptosis in endothelial cells, leading to oxygen and nutrient deprivation.

TUNEL assays are widely used for the detection of apoptotic events by terminal deoxynucleotidyl transferase (TdT), which labels blunt ends of double-stranded DNA fragments. Therefore, a TUNEL-positive signal should not be found in the GBM region because the anti-apoptotic mechanism is abnormally upregulated in tumors, which enables cancer cells to avoid apoptosis [38]. However, over the past decade, numerous shortcomings have been pointed out in the evaluation of apoptosis through the TUNEL assay [39]. Many reports claim that TUNEL staining is non-specific in that it labels all free 3'-hydroxyl ends, irrespective of the molecular mechanism designed as planned. For this reason, it also labels non-apoptotic cells such as necrotic degenerative cells [40]. Therefore, the morphology should be assessed concurrently when performing the TUNEL assay to differentiate between apoptotic cells and necrotic cells. Consistent to recent claims, TUNEL-positive cells were predominant in the innermost GBM region where a large number of necrotic cells were observed in the H&E results. On the other hands, the TUNEL signal was not detected in the normal brain regions (Fig. 6h). In this respect, TUNEL-positive cells can be considered as necrotic tumor cells that play a catalytic role in tumor progression and aggressiveness. As results, the PBS-vehicle administered group (control) had the most TUNEL-positive cells among the experimental groups with an MFI value of 28.5 ± 4.8. Moreover, those TUNEL-positive cells invaded normal areas and metastasized to surrounding tissues. Meanwhile, the MFI of GL-, Lf-, and Lf-GL- administration group decreased to 16.3 ± 2.8, 9.4 ± 1.6, and 9.1 ± 0.9, respectively, (Fig. 6h and 6k) and most of them were confined to the tumor site without migration to the normal region (Fig. 6h, images of tumors and normal areas separated by red dashed line).

In this study, we demonstrated that the extracellular HMGB1 protein, recognized as a DAMP in the tumor microenvironment, plays a critical role in tumor angiogenesis and development. The HMGB1 released from the necrotic tumor executes alarmin functions, activating tumor growth signaling via binding to a variety of receptors including TLR2/4, RAGE, and C-X-C motif chemokine receptor 4 (CXCR-4) [41, 42]. Moreover, it is known that tumor cells secrete HMGB1 to recruit endothelial cells and facilitate a tumor vascular system by the crosstalk [43, 44]. To this respect, a few small molecules such as GL, acetylcholine, and GTS-21 (also known as DMBX-A) have been characterized as HMGB1 inhibitors, binding directly to inactivate its function or expression. GL is known to be a potent inhibitor of HMGB1, which of the equilibrium dissociation constant (K_D) value was previously reported to be 170 ± 3 µM for box A and 140 ± 3 µM for box B [13]. However, a small molecule, GL, suffers from poor pharmacokinetics (PK) and pharmacodynamic (PD) properties, resulting in deficient delivery to the site-of-action.

To address this unmet clinical application, we established a novel Lf-GL conjugate with a ligation ratio of 1:10 (Fig. 1b). Notably, we found for the first time that Lf has high affinity for HMGB1 with a K_D value of 165.0 ± 3 nM, which is approximately ~ 10 folds higher than that of HMGB1 antibody (K_D value of 1.0 ± 3.0 µM) (Table 1). In the case of protein-protein interactions (PPIs), the combination of hydrophobic interactions, van der Waals forces, and metal or ion bridges at specific binding domains on each protein are all significant factors. These domains can be small binding clefts or large surfaces of the protein. In this context, Lf is an iron-binding protein consisting of two connected lobes, each with a binding site located in a cleft. Assuming the binding of Lf to the HMGB1 protein, it is expected that Lf, a globular glycoprotein with a molecular mass of about 80 kDa, would participate in many non-covalent interactions with HMGB1. Thereafter, the two arm-structure of HMGB1 and each lobe of Lf undergo a conformation change to become a stable complex. It is a valuable finding that Lf exhibits significant affinity for HMGB1, but more structural information of this complex must be further investigated by specific analysis such as NMR spectroscopy and thermodynamic characterization. Taken together, the exceptional contribution of Lf to HMGB1 binding resulted in a significant affinity with a K_D value of 23.1 ± 0.1 nM when conjugated between Lf and GL at a ratio of 1:10.

Behalf of the high binding affinity to HMGB1, Lf-GL (1:10) exerted dominant antitumor activity in both 2D and 3D tumor cell spheroid culture system (Fig. 2d and 2e). Tumor cell migration and invasion, a critical factor in tumor progression and metastasis, were effectively attenuated in the presence of HMGB1 (Fig. 2). It is important to arrest HMGB1 in terms of tumor malignancy because extracellular HMGB1 is known to bind RAGE, which is overexpressed in high grade tumors [45]. Once RAGE is engaged by HMGB1, several signaling pathways such as MAPK and NF-_KB become activated, thereby reprogramming cellular properties and progress to tumor migration and proliferation. In our study, Lf-GL arrested HMGB1 not only in the extracellular but also in the cytoplasmic fraction (Fig. 2g). This was attributed to the interaction between Lf and LfR that expressed on GBM cells, and we further explored the endocytosis mechanisms. As results, Lf-GL sufficiently internalized GBM cells (84.5%) via Lf receptor (LfR), but its endocytic pathway was not dependent on the clathrin-mediated pathway (Fig. 2f). The mechanism of internalization of Lf through GBM cell remains controversial. There is evidence that internalization of nanoparticles functionalized with Lf is partially (40%) decreased by inhibitors of clathrin-mediated endocytosis of mannitol (200 mM) [20], which is not consistent with our result. However, the endocytic pathway also depends on the physical, chemical, and geometrical properties of the molecules. Therefore, it is assumed that those distinct properties of Lf-GL do not follow a high dependence on the clathrin-mediated endocytic pathway. Due to the independence of clathrin-mediated endocytic pathway which can circumvent lysosomal protein degradation [46], Lf-GL was capable to arrest HMGB1 in the cytoplasm of GBM cell. Arresting HMGB1 in the cytoplasmic fraction is regarded as significant because the function of HMGB1 is dominated by its subcellular location. In general, HMGB1 is localized in the nucleus, which regulates DNA stability and repair. However, the translocated HMGB1 from the nucleus governs the tumor cell proliferation, invasion, and metastasis [47]. It has been reported that the translocation of HMGB1 from the nucleus to the cytoplasm actively promotes autocrine, which is governed by post-translational modification such as phosphorylation [48]. Then, phosphorylated HMGB1 is transported to the cytoplasm and subsequently secreted out of the cells, where it plays a pivotal role in tumor progression [49] [50]. Therefore, we hypothesized that enhanced cellular uptake of Lf-GL provided more benefit in arresting nuclear-to-cytoplasmic translocated-HMGB1 as an important factor in the disturbance of tumor cell proliferation compared with other treatment groups.

In the tumor angiogenic environment, HMGB1 is known to act as a proinflammatory cytokine that stimulates the expression of vascular endothelial growth factor (VEGF) and triggers migration and sprouting of endothelial cells [51]. Multiple sources of HMGB1 exist in the tumor microenvironment; 1) necrotic tumor cells passively release HMGB1 into the peripheral space; 2) tumor-associated macrophages (TAMs) actively secrete HMGB1 and other vascularization growth factor [52]; 3) it also has been shown that endothelial cells secrete HMGB1 after activation and re-activate themselves upon exposure to that of previously secreted HMGB1 [51]. To this end, we constructed tumor microenvironment-mimic model to investigate the restriction effect of Lf-GL on HMGB1, which plays a critical role in crosstalk between tumor and endothelial cells (Fig. 4). As results, Lf-GL arrested HMGB1 secreted by GBM cells, attenuating angiogenic functions and inhibiting migration to endothelial cells. Therefore, the proliferation and motility of endothelial cells were efficiently inhibited in the tumor microenvironment (Fig. 4b). Taken together, Lf-GL efficiently targeted the GBM through interactions with LfR, inhibited GBM cell proliferation and growth, and arrested HMGB1, which is considered as a key factor for tumor growth and angiogenesis. Therefore, in the tumor microenvironment, Lf-GL appears to be a potent anti-tumor and anti-angiogenesis therapeutic agent.

GL, a small molecule used for anticancer treatment, often suffers from poor pharmacokinetics (PK) and pharmacodynamic (PD) properties due to its small size. Small molecules typically exhibit short half-lives and broad distributions, making them difficult to target at the site of action for long periods of time [53]. In addition, the small size of the pharmacophore often results in non-specific binding, resulting in narrow therapeutic indices. In this regard, protein conjugates are generally reported as a strategy for improving the PK-PD properties of small molecules, which may significantly increase their therapeutic potential. Targeted protein conjugates, developed primarily from antibodies, antibody derivatives, or endogenous proteins, are designed to improve delivery to the site of action and thereby enhance the therapeutic index of the agent [54]. Our results suggest that the conjugation of Lf, an autocrine endogenous protein, to GL significantly improved the PK properties of the molecules and increased its delivery to GBM (Table 2 and Fig. 5a-5d). The enhanced PK properties of Lf-GL enabled targeting of LfR expressed in BBB and GBM cells, and the accumulated amount was 2-fold higher than GL without Lf conjugation (Fig. 5b-5d)

Clinically, the development of necrotic cores in cancer patients is correlated with high-grade disease, increased tumor size, and poor prognosis [55]. More specifically, tumor necrosis, a common occurrence in malignant brain tumors, begins with cell swelling and releases cytoplasmic contents such as HMGB1 into the extracellular space through plasma membrane rupture. These released molecules promote tumor progression by recruiting immune cells that can trigger an inflammatory response, increasing the possibility of epigenetic changes or proto-oncogenic mutations, and inducing angiogenesis, cancer cell proliferation and invasion. In this respect, the released HMGB1 plays a critical role in regulating the epithelial mesenchymal transition (EMT), which initiates tumor invasion and metastasis [56]. Consistent to clinical view, in our study, necrotic tumor cells sustainedly secreted HMGB1 and triggered cascade response, leading to persistent necrosis of the lesion. Moreover, HMGB1 released into the extracellular environment infiltrates into the surrounding brain tissue to proliferate the surrounding tumor cells, causing the regeneration of small blood vessels to promote spreading and tumor growth [57]. At this point, Lf-GL, which has a high binding affinity for HMGB1, eliminate the activity involved in tumor development and metastasis by arresting HMGB1. Thus, it prevents infiltration of tumor cells into surrounding tissues, which occurs through tumor necrosis.

In this study, we developed Lf-GL with a high binding affinity for HMGB1 that acts as a tumor-promoting cytokine and is involved in angiogenesis and tumor progression in the tumor microenvironment. The binding affinity of Lf-GL to HMGB1 was 45-fold higher than that of the HMGB1 antibody. Lf of the Lf-GL improved targeting to GBM through interaction with LfR, allowing Lf-GL to arrest released HMGB1 present in the extracellular space as well as in the cytoplasmic fraction. Therefore, Lf-GL effectively inhibited the cascade (tumor angiogenesis, tumor progression, infiltration into surrounding tissues, etc.) induced by HMGB1 secreted from necrotic tumor. Furthermore, Lf addressed the unfavorable PK property of GL, delivering it to the site of action. Thus, in the orthotopic GBM mice model, Lf-GL significantly prolonged the survival period and reduced the tumor volume by 32% compared to the untreated group. Consequently, our findings suggest a new HMGB1 inhibition approach to comprehensive GBM treatment and may offer a novel platform for the treatment of HMGB1-related disorder.

HMGB1	High-mobility group box-1
DAMP	Damaged-associated molecular pattern
GL	Glycyrrhizin
PK	Pharmacokinetics
PD	Pharmacodynamics
Lf-GL	Lactoferrin-glycyrrhizin conjugate
SPR	Surface plasmon resonance
LfR	Lactoferrin receptor
GBM	Glioblastoma multiforme
VEGF	Vascular endothelial growth factor
RAGE	Receptor for advanced glycation end products
BBB	Blood-brain barrier
MALDI TOF	Matrix-assisted laser desorption/ionization time-of-flight
CCK-8	Cell counting kit-8
p-ERK	Phosphorylated-ERK
I.U.	Intensity units
RES	Reticuloendothelial system
MFI	Mean fluorescence intensity
CXCR-4	C-X-C motif chemokine receptor 4
K_D	Equilibrium dissociation constant
PPI	Protein-protein interactions
TAMs	Tumor-associated macrophages
EMT	Epithelial mesenchymal transition

Acknowledgements

Not applicable

Authors’ contribution
H.S.K, S.C.P, H.J.K and D.Y.L conceived the research design. H.S.K, S.C.P and H.J.K performed the experiments. H.S.K, S.C.P and D.Y.L conducted data processing. H.S.K, S.C.P and D.Y.L contributed to analysis and interpretation of data. H.S.K., and D.Y.L. grafted the manuscript. H.S.K., and D.Y.L. edited the manuscript.

Funding

This research was supported by the National Research Foundation of Korea (NRF) grant funded by the Korea government (MSIT) (NRF-2020R1A2C3005834, NRF-2022R1A4A1030421).

Availability of data and materials

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.

Ethics approval and consent to participate

All animals were housed in specific pathogen-free conditions and maintained under the Institutional Animal Care and Use Committee (IACUC: 2020–0081) at Hanyang University.

Consent for Publication

Not applicable

Competing interest
The authors declare no conflict of interest.

Appendix A. Supplementary data

Supplementary data to this article can be found online

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Inhibition of DAMP Actions in the Tumoral Microenvironment Using Lactoferrin-Glycyrrhizin Nanoconjugate for Glioblastoma Therapy

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Abstract

Background

Methods

Results

Conclusion

Figures

Background

Materials And Methods

Materials

Experimental Cell Lines And Animals

Preparation Of Lactoferrin-glycyrrhizin Conjugate (Lf-gl)

Characterization Of Lf-gl

Binding Affinity Against Hmgb1

Cell Viability Test

Cell Migration Assay

In Vitro Gbm Cell Uptakes Of Lf-gl

HMGB1 ELISA

Tube Formation Assay

Aorta Ring Assay

Western Blot

Huvec Co-cultured With U87mg

In Vivo Pharmacokinetics Study Of Lf-gl

In Vivo Fluorescence Tracer Image Of Lf-gl

In Vivo Analysis Of Gbm Targeted-gl By Hplc In Orthotopic Gbm Modeled Mice Brain

In Vivo Systemic Toxicity Evaluation In Gbm Mouse Model

In Vivo Histological Study For Lf-gl Efficacy On Gbm Mouse Model

Statistics

Results

Synthesis and characterization of Lf-GL conjugate

Lf-gl As A Potent Hmgb1 Antagonist Due To Its High Binding Affinity To Hmgb1

In Vitro, Attenuation Of Gbm Proliferation By Lf-gl Treatment

Downregulation Of Cytoplasmic-hmgb1 Level By Lfr-mediated Endocytosis Of Lf-gl

Anti-angiogenic Effect Of Lf-gl

Inhibition Of Tumor Progression By Lf-gl In The Tumor Microenvironment

Extension Of Survival Rate With Minimal Systemic Toxicity Through Lf-gl Treatment

Reduction Of Biomarkers Related To Tumor Development By Inhibition Of Hmgb1 Activity

Significant Gbm Therapeutic Effect By Lf-gl Treatment In Orthotopic Gbm Mouse Model

Discussion

Conclusion

Abbreviations

Declarations

References

Supplementary Files

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