Erythrocytes as carriers of immunoglobulin-based therapeutics

The global and economic success of immunoglobulin-based therapeutics in treating a wide range of diseases has heightened the need to further enhance their efficacy and lifetime while diminishing deleterious side effects. The three most ubiquitous challenges of therapeutic immunoglobulin delivery are...

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Bibliographic Details
Published in:Acta biomaterialia 2020-01, Vol.101, p.422-435
Main Authors: Ji, Weihang, Smith, Paige N., Koepsel, Richard R., Andersen, Jill D., Baker, Stefanie L., Zhang, Libin, Carmali, Sheiliza, Myerson, Jacob W., Muzykantov, Vladimir, Russell, Alan J.
Format: Article
Language:English
Subjects:
Alkynes
Antibodies
Antibodies - metabolism
Antibody
Antigens
Antigens - metabolism
Bioconjugation
Buffers (chemistry)
Chemical engineering
Chemical synthesis
Click Chemistry
Control stability
Drug Carriers - chemistry
Erythrocyte Membrane - metabolism
Erythrocytes
Erythrocytes - metabolism
Fc receptors
Humans
Immunoglobulins
Immunoglobulins - therapeutic use
In vivo methods and tests
Masking
Mechanical properties
Membranes
Organic chemistry
Polyethylene glycol
Polyethylene Glycols - chemical synthesis
Polyethylene Glycols - chemistry
Protein A
Protein Binding
Proteins
Side effects
Staphylococcal Protein A - metabolism
TNFα
Tumor Necrosis Factor-alpha - metabolism
Tumor necrosis factor-α
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Summary:The global and economic success of immunoglobulin-based therapeutics in treating a wide range of diseases has heightened the need to further enhance their efficacy and lifetime while diminishing deleterious side effects. The three most ubiquitous challenges of therapeutic immunoglobulin delivery are their relatively short lifetimes in vivo, the immunologic consequences of soluble antibody-antigen complexes, and the emergence of anti-drug antibodies. We describe the rapid, cell-tolerated chemical engineering of the erythrocyte membrane in order to display any antibody, our model system being the display of anti-Tumor Necrosis Factor (anti-TNFα), on the surface of long-lived red blood cells (RBCs) while masking the antibody's Fc region. We developed four synthetic approaches to generate RBC-Staphylococcal protein A (RBC-SpA) complexes: amino group targeting through N-hydrosuccinidyl ester-functionalized homobifunctional poly(ethylene glycol) (NHS-PEG-NHS), direct thiol group targeting using heterobifunctional NHS-PEG-maleimide (NHS-PEG-MAL), converted thiol targeting using heterobifunctional NHS-PEG-MAL, and click chemistry using heterobifunctional NHS-PEG-azido (NHS-PEG-N3) and NHS-PEG-alkyne (NHS-PEG-alk). The RBC-PEG-SpA complexes were formed within minutes, followed by the attachment of over 105 antibodies per RBC to the accessible RBC-bound SpA via Fc-Protein A coupling. The RBC-PEG-SpA-antibody arrays were shown to be stable for more than 60 days in PBS and for more than 42 days in serum containing buffer. RBC-PEG-SpA-antibody complexes were shown to remove TNFα from physiological buffer and had similar mechanical properties to unmodified RBCs. Out of the four approaches, the converted thiol method provided the most controlled chemistry and construct stability. We are now ideally positioned to determine the long-term in vivo efficacy of chemically membrane-engineered RBCs to remove antigens, like TNFα, from serum. The global and economic success of immunoglobulin-based therapeutics in treating a wide range of diseases has heightened the need to further enhance their efficacy and lifetime while diminishing deleterious side effects. The three most ubiquitous challenges of therapeutic immunoglobulin delivery are their relatively short lifetimes in vivo, the immunologic consequences of soluble antibody-antigen complexes, and the emergence of anti-drug antibodies. We describe the rapid, cell-tolerated chemical engineering of the erythrocyte membrane to disp
ISSN:1742-7061
1878-7568
DOI:10.1016/j.actbio.2019.10.027