Glycaemic control boosts glucosylated nanocarrier crossing the BBB into the brain

Anraku, Yasutaka; Kuwahara, Hiroya; Fukusato, Yu; Mizoguchi, Asao; Ishii, Takumi; Nitta, Keiko; Matsumoto, Yu; Toh, Kazuko; Miyata, Kanjiro; Uchida, Satoshi; Nishina, Kazutaka; Osada, Kensuke; Itaka, Keiji; Nishiyama, Nobuhiro; Mizusawa, Hidehiro; Yamasoba, Tatsuya; Yokota, Takanori; Kataoka, Kazunori

doi:10.1038/s41467-017-00952-3

Cited by 204 publications

(216 citation statements)

References 35 publications

(35 reference statements)

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“…To this extent, the use of super-resolution imaging in combination with molecular dynamics simulation presents a critical role of the cargo in templating the tubular formation and dynamics (Fig.7). In conclusion, we shed light on BEC transcytosis using LRP1 as the main actor, but considering that "Goldilocks" avidity effect was also reported for transferrin receptor [49,50,51] and GLUT1 [52], our findings might suggest similar mechanisms. Nevertheless, ultimately, we report here a clear path to the brain, which once optimised it allows high delivery efficiency.…”

Section: Discussionsupporting

confidence: 61%

“…Both methods show that while all angiopep-2 formulations enter the brain and can be found at relatively high concentrations across the BBB, the formulation with the most effective crossing is again A 22 -P, in agreement with the in vitro data. Such a non-linear dependence of the ligand binding energy on BBB crossing rate was also reported for the targeting of the transferrin receptor [49,50,51] and glucose transporter-1 (GLUT1) [52].…”

Section: Figurementioning

confidence: 54%

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On the shuttling across the blood-brain barrier via tubules formation: mechanism and cargo avidity bias

Tian

Leite

Scarpa

et al. 2020

Preprint

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The blood-brain barrier is made of polarised brain endothelial cells (BECs) phenotypically conditioned by the central nervous system (CNS). Transport across BECs is of paramount importance for nutrient uptake as well as to rid the brain of waste products. Nevertheless,currently we do not understand how large macromolecular cargo shuttles across and how BECs discriminate between the brain-bound and own nutrients. Here, we study the low-density lipoprotein receptor-related protein 1 (LRP1) an essential regulator of BEC transport, and show that it is associated with endocytic effectors, endo-lysosomal compartments as well as syndapin-2, a member of the Bin/Amphiphysin/Rvs (BAR) domain superfamily known to stabilise tubular carriers. We employed synthetic self-assembled vesicles, polymersomes, as a multivalent system with tunable avidity as a tool to investigate the mechanism of transport across BECs. We used a combination of conventional and super-resolution microscopy, both in vivo and in vitro, accompanied with biophysical modelling of transport kinetics and membrane-bound interactions. Our results demonstrate that the avidity of the ligand-receptor interaction (the overall cargo binding energy) determines the mechanism of sorting during the early stages of endocytosis and consequent trafficking. We show that high avidity cargo biases the LRP1 towards internalisation and fast degradation in BECs, while mid avidity augments the formation of syndapin-2 stabilised tubular carriers and promotes fast shuttling across BECs. Thus, we map out a very detailed mechanism where clathrin, actin, syndapin-2, dynamin and SNARE act synergistically to enable fast shuttling across BECs.

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Section: Discussionsupporting

confidence: 61%

Section: Figurementioning

confidence: 54%

On the shuttling across the blood-brain barrier via tubules formation: mechanism and cargo avidity bias

Tian

Leite

Scarpa

et al. 2020

Preprint

View full text Add to dashboard Cite

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“…Hopefully, nanoparticle by intracephalic administration may be a method to resolve the problem. [16][17][18][19][20] It is a new idea for GBM treatment in future to lucubrate new intracephalic delivery carriers including nanoparticle and utilize their unique surface properties, good biocompatibility and biodegradation. In that way, we can achieve the goals to carry antitumor medicine through BBB or BTB to reach the target region of neoplasm and release drug continuously, eventually attaining drug concentration needed to inhibit or kill tumor cells and reducing the drug's toxicity to normal cells.…”

Section: Introductionmentioning

confidence: 99%

<p>Delivery luteolin with folacin-modified nanoparticle for glioma therapy</p>

Chen

et al. 2019

IJN

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Background: Glioblastoma mutliforme is the most common and has the poorest prognosis of any malignant tumor of the central nervous system. Luteolin, the most abundant xanthone extracted from vegetables and medicinal plants, has been shown to have treatment effects in various cancer cell types. Luteolin is however, hydrophobic and has poor biocompatibility, which leads to low bioavailability. Patients and methods: In this study, folic acid modifiedpoly(ethylene glycol)-poly(ecaprolactone) (Fa-PEG-PCL) nano-micelles was used to encapsulate the luteolin, creating luteolin loaded PEG-PCL (Lut/Fa-PEG-PCL) micelles to treat glioma both in vitro and in vivo. Results: When compared with the free luteolin and Lut/MPEG-PCL, Lut/Fa-PEG-PCL induced a significant cell growth inhibition and more apoptosis of GL261 cells both in vitro and in vivo. The safety assessment also showed no obvious side effects were observed in mice which were administrated with free luteolin or Lut/MPEG-PCL and Lut/Fa-PEG-PCL. Conclusion: These results suggested Lut/Fa-PEG-PCL may be used as an excellent intravenously injectable formulation for the treatment and chemoprevention.

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“…An in vivo study showed this drug delivery system could accumulate in brain tumors and substantially slow tumor growth. Glucose is another targeting ligand that could cross the brain capillary endothelial cells via glucose transporter-1 99 . Anraku et al 99 showed that glucose-modified nanocarriers could cross the BBB and accumulate in brain parenchyma, which has huge potential for the treatment of CNS diseases.…”

Section: Non-viral Gene Delivery To the Cns And Brain Tumorsmentioning

confidence: 99%

Non‐viral nucleic acid delivery to the central nervous system and brain tumors

Wang

Huang

2019

The Journal of Gene Medicine

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Gene therapy is a rapidly emerging remedial route for many serious incurable diseases, such as central nervous system (CNS) diseases. Currently, nucleic acid medicines, including DNAs encoding therapeutic or destructive proteins, small interfering RNAs or microRNAs, have been successfully delivered to the CNS with gene delivery vectors using various routes of administration and have subsequently exhibited remarkable therapeutic efficiency. Among these vectors, non‐viral vectors are favorable for delivering genes into the CNS as a result of their many special characteristics, such as low toxicity and pre‐existing immunogenicity, high gene loading efficiency and easy surface modification. In this review, we highlight the main types of therapeutic genes that have been applied in the therapy of CNS diseases and then outline non‐viral gene delivery vectors.

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Glycaemic control boosts glucosylated nanocarrier crossing the BBB into the brain

Cited by 204 publications

References 35 publications

On the shuttling across the blood-brain barrier via tubules formation: mechanism and cargo avidity bias

On the shuttling across the blood-brain barrier via tubules formation: mechanism and cargo avidity bias

<p>Delivery luteolin with folacin-modified nanoparticle for glioma therapy</p>

Non‐viral nucleic acid delivery to the central nervous system and brain tumors

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