Modulating the antibody density changes the uptake and transport at the blood‐brain barrier of both transferrin receptor‐targeted gold nanoparticles and liposomal cargo

Abstract Transport of the majority of therapeutic molecules to the brain is precluded by the presence of the blood‐brain barrier (BBB) rendering efficient treatment of many neurological disorders impossible. This BBB, nonetheless, may be circumvented by targeting receptors and transport proteins expressed on the luminal surface of the brain capillary endothelial cells (BCECs). The transferrin receptor (TfR) has remained a popular target since its original description for this purpose, although clinical progression of TfR‐targeted drug constructs or nanomedicines remains unsuccessful. One proposed issue pertaining to the use of TfR‐targeting in nanomedicines is the efficient tuning of the ligand density on the nanoparticle surface. We studied the impact of TfR antibody density on the uptake and transport of nanoparticles into the brain, taking a parallel approach to investigate the impact on both antibody‐functionalized gold nanoparticles (AuNPs) and cargo‐loaded liposomes. We report that among three different low‐range mean ligand densities (0.15, 0.3, and 0.6 * 103 antibodies/&mgr;m2), the highest density yielded the highest ability towards both targeting of the BCECs and subsequent transport across the BBB in vivo, and in vitro using primary cultures of the murine BBB. We also find that TfR‐targeting on liposomes in the mouse may induce severe adverse effects after intravenous administration. Graphical abstract Figure. No Caption available. HighlightsLigand density impacts brain transport of TfR‐targeted nanoparticles.Very low antibody densities do not improve brain transport of AuNPs and liposomes.TfR‐targeting may increase off‐target accumulation in the spleen.Liposome‐associated anti‐TfR antibodies induce adverse effects after administration.

[1]  L. B. Thomsen,et al.  Expression of Iron-Related Proteins at the Neurovascular Unit Supports Reduction and Reoxidation of Iron for Transport Through the Blood-Brain Barrier , 2016, Molecular Neurobiology.

[2]  L. B. Thomsen,et al.  Macromolecular drug transport into the brain using targeted therapy , 2010, Journal of neurochemistry.

[3]  R. Schulte,et al.  Inhibition of cell growth by monoclonal anti-transferrin receptor antibodies , 1985, Molecular and cellular biology.

[4]  J. Levy,et al.  Photofrin increases murine spleen cell transferrin receptor expression and responsiveness to recombinant myeloid and erythroid growth factors. , 1998, Immunopharmacology.

[5]  T. Andresen,et al.  Targeting transferrin receptors at the blood-brain barrier improves the uptake of immunoliposomes and subsequent cargo transport into the brain parenchyma , 2017, Scientific Reports.

[6]  Mark E. Davis,et al.  Transcytosis and brain uptake of transferrin-containing nanoparticles by tuning avidity to transferrin receptor , 2013, Proceedings of the National Academy of Sciences.

[7]  A. Camins,et al.  Trafficking of Gold Nanoparticles Coated with the 8D3 Anti-Transferrin Receptor Antibody at the Mouse Blood-Brain Barrier. , 2015, Molecular pharmaceutics.

[8]  K. B. Johnsen On the use of the transferrin receptor as a target for brain drug delivery , 2017 .

[9]  K. Nilsson,et al.  Labeling nanoparticles: Dye leakage and altered cellular uptake , 2017, Cytometry. Part A : the journal of the International Society for Analytical Cytology.

[10]  T. Andresen,et al.  Dissociation of fluorescently labeled lipids from liposomes in biological environments challenges the interpretation of uptake studies. , 2018, Nanoscale.

[11]  B. Zlokovic The Blood-Brain Barrier in Health and Chronic Neurodegenerative Disorders , 2008, Neuron.

[12]  Serena Mazzucchelli,et al.  Tumour homing and therapeutic effect of colloidal nanoparticles depend on the number of attached antibodies , 2016, Nature Communications.

[13]  Mauro Ferrari,et al.  Principles of nanoparticle design for overcoming biological barriers to drug delivery , 2015, Nature Biotechnology.

[14]  K. Scearce-Levie,et al.  Addressing Safety Liabilities of TfR Bispecific Antibodies That Cross the Blood-Brain Barrier , 2013, Science Translational Medicine.

[15]  Y. Beguin,et al.  Reticulocyte transferrin receptor (TfR) expression and contribution to soluble TfR levels. , 2001, Haematologica.

[16]  T. Singer,et al.  First Infusion Reactions are Mediated by FcγRIIIb and Neutrophils , 2018, Pharmaceutical Research.

[17]  C. Betsholtz,et al.  Trafficking of Endogenous Immunoglobulins by Endothelial Cells at the Blood-Brain Barrier , 2016, Scientific Reports.

[18]  P. Hass,et al.  Balancing Efficacy and Safety of an Anti-DLL4 Antibody through Pharmacokinetic Modulation , 2015, Clinical Cancer Research.

[19]  S H White,et al.  Leakage of membrane vesicle contents: determination of mechanism using fluorescence requenching. , 1995, Biophysical journal.

[20]  R. Schulte,et al.  Modulation of transferrin receptor expression and function by anti-transferrin receptor antibodies and antibody fragments. , 1989, Experimental cell research.

[21]  Anirvan Ghosh,et al.  Increased Brain Penetration and Potency of a Therapeutic Antibody Using a Monovalent Molecular Shuttle , 2014, Neuron.

[22]  M. Masserini,et al.  Liposomes functionalized to overcome the blood–brain barrier and to target amyloid-β peptide: the chemical design affects the permeability across an in vitro model , 2013, International journal of nanomedicine.

[23]  G. Ramadori,et al.  Ferroportin-1 is a ‘nuclear’-negative acute-phase protein in rat liver: a comparison with other iron-transport proteins , 2012, Laboratory Investigation.

[24]  P. Freskgård,et al.  Antibody therapies in CNS diseases , 2017, Neuropharmacology.

[25]  W. Luk,et al.  Boosting Brain Uptake of a Therapeutic Antibody by Reducing Its Affinity for a Transcytosis Target , 2011, Science Translational Medicine.

[26]  T. Suhara,et al.  Factors governing the in vivo tissue uptake of transferrin-coupled polyethylene glycol liposomes in vivo. , 2004, International journal of pharmaceutics.

[27]  Mark E. Davis,et al.  Increased brain uptake of targeted nanoparticles by adding an acid-cleavable linkage between transferrin and the nanoparticle core , 2015, Proceedings of the National Academy of Sciences.

[28]  T. Moos,et al.  Divalent metal transporter 1 (DMT1) in the brain: implications for a role in iron transport at the blood-brain barrier, and neuronal and glial pathology , 2015, Front. Mol. Neurosci..

[29]  T. Andresen,et al.  Antibody affinity and valency impact brain uptake of transferrin receptor-targeted gold nanoparticles , 2018 .

[30]  M. Salmona,et al.  Mono and Dually Decorated Nanoliposomes for Brain Targeting, In Vitro and In Vivo Studies , 2013, Pharmaceutical Research.

[31]  M. Awai,et al.  Transferrin Receptor Expression in Normal, Iron‐deficient and Iron‐overloaded Rats , 1989, Acta pathologica japonica.

[32]  G. Storm,et al.  Targeting Anti—Transferrin Receptor Antibody (OX26) and OX26-Conjugated Liposomes to Brain Capillary Endothelial Cells Using In Situ Perfusion , 2004, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[33]  D. B. Vieira,et al.  Getting into the brain: liposome-based strategies for effective drug delivery across the blood–brain barrier , 2016, International journal of nanomedicine.

[34]  B. Engelhardt,et al.  Targeting rat anti-mouse transferrin receptor monoclonal antibodies through blood-brain barrier in mouse. , 2000, The Journal of pharmacology and experimental therapeutics.

[35]  David J. Begley,et al.  Structure and function of the blood–brain barrier , 2010, Neurobiology of Disease.

[36]  R. Schulte,et al.  Expression of transferrin receptor on murine hematopoietic progenitors. , 1984, Cellular immunology.

[37]  F. Calon,et al.  In Vivo Labeling of Brain Capillary Endothelial Cells after Intravenous Injection of Monoclonal Antibodies Targeting the Transferrin Receptor , 2011, Molecular Pharmacology.

[38]  Johannes E. Schindelin,et al.  Fiji: an open-source platform for biological-image analysis , 2012, Nature Methods.

[39]  F. Calon,et al.  Brain uptake of a fluorescent vector targeting the transferrin receptor: a novel application of in situ brain perfusion. , 2014, Molecular pharmaceutics.

[40]  W. Jefferies,et al.  Transferrin receptor on endothelium of brain capillaries , 1984, Nature.

[41]  W. Pardridge,et al.  Capillary Depletion Method for Quantification of Blood–Brain Barrier Transport of Circulating Peptides and Plasma Proteins , 1990, Journal of neurochemistry.

[42]  E. Morgan,et al.  Restricted transport of anti‐transferrin receptor antibody (OX26) through the blood–brain barrier in the rat , 2001, Journal of neurochemistry.

[43]  Chengwen Sun,et al.  Grafting of cell-penetrating peptide to receptor-targeted liposomes improves their transfection efficiency and transport across blood-brain barrier model. , 2012, Journal of pharmaceutical sciences.

[44]  Diwei Ho,et al.  Dose-Dependent Therapeutic Distinction between Active and Passive Targeting Revealed Using Transferrin-Coated PGMA Nanoparticles. , 2016, Small.

[45]  N. Abbott Blood–brain barrier structure and function and the challenges for CNS drug delivery , 2013, Journal of Inherited Metabolic Disease.

[46]  T. Moos,et al.  Revisiting nanoparticle technology for blood-brain barrier transport: Unfolding at the endothelial gate improves the fate of transferrin receptor-targeted liposomes. , 2016, Journal of controlled release : official journal of the Controlled Release Society.

[47]  J. Huwyler,et al.  Brain drug delivery of small molecules using immunoliposomes. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[48]  A. Stensballe,et al.  Synthesis and deposition of basement membrane proteins by primary brain capillary endothelial cells in a murine model of the blood–brain barrier , 2017, Journal of neurochemistry.

[49]  E. Brunette,et al.  Enhanced Delivery of Galanin Conjugates to the Brain through Bioengineering of the Anti-Transferrin Receptor Antibody OX26. , 2018, Molecular pharmaceutics.

[50]  W. Hennink,et al.  Comparison of five different targeting ligands to enhance accumulation of liposomes into the brain. , 2011, Journal of controlled release : official journal of the Controlled Release Society.

[51]  G. Ramadori,et al.  Comparison of changes in gene expression of transferrin receptor-1 and other iron-regulatory proteins in rat liver and brain during acute-phase response , 2011, Cell and Tissue Research.

[52]  R. Andreesen,et al.  Expression of transferrin receptors and intracellular ferritin during terminal differentiation of human monocytes , 1984, Blut.

[53]  M. Parent,et al.  Internalization of targeted quantum dots by brain capillary endothelial cells in vivo , 2015, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[54]  J. Connor,et al.  Iron uptake and transport across physiological barriers , 2016, BioMetals.

[55]  Amit Modgil,et al.  Cell penetrating peptide tethered bi-ligand liposomes for delivery to brain in vivo: Biodistribution and transfection. , 2013, Journal of controlled release : official journal of the Controlled Release Society.

[56]  Amit Modgil,et al.  Influence of Short-Chain Cell-Penetrating Peptides on Transport of Doxorubicin Encapsulating Receptor-Targeted Liposomes Across Brain Endothelial Barrier , 2014, Pharmaceutical Research.

[57]  T. Andresen,et al.  Antibody affinity and valency impact brain uptake of transferrin receptor-targeted gold nanoparticles , 2018, Theranostics.

[58]  E. Brunette,et al.  Intracellular sorting and transcytosis of the rat transferrin receptor antibody OX26 across the blood–brain barrier in vitro is dependent on its binding affinity , 2018, Journal of neurochemistry.