RBC Adherence of Immune Complexes Containing Botulinum Toxin Improves Neutralization and Macrophage Uptake.

In the paralytic disease botulism, the botulinum neurotoxin (BoNT) passes through the bloodstream to reach and inactivate neuromuscular junctions. Monoclonal antibodies (mAbs) may be useful BoNT countermeasures, as mAb combinations can rapidly clear BoNT from the blood circulation. We have previously shown that the BoNT-neutralizing potency of mAbs can be improved through red blood cell (RBC) immunoadherence. For example, a fusion protein (FP) that adheres biotinylated mAbs to the RBC surface enabled a pair of mAbs to neutralize 5000 LD50 BoNT/A in the mouse protection assay. Here, we added two mAbs to that combination, creating a 4-mAb:FP complex that neutralized 40,000 LD50 BoNT/A in vivo, and analyzed functional correlates of neutralization. The FP enhanced potency of BoNT/A immune complexes, providing the greatest magnitude of benefit to the 4-mAb combination. RBC binding of a BoNT/A complexed with 4-mAb:FP exhibited a bi-phasic clearance process in vivo. Most of the complexes were cleared within five minutes; the rest were cleared gradually over many hours. Peritoneal macrophages showed better uptake of the 4-mAb complex than the 3-mAb complex, and this was not affected by the presence of the FP. However, the addition of RBCs to the 4-mAb:FP BoNT/A doubled macrophage uptake of the complexes. Lastly, the 4-mAb:FP BoNT/A complex synergistically induced M2 macrophage polarization, as indicated by IL-10 expression, whether or not RBCs were present. RBC-targeted immunoadherence through the FP is a potent enhancer of mAb-mediated BoNT/A neutralization in vivo, and can have positive effects on BoNT/A sequestration, immune complex uptake, and macrophage activation.

Enhanced neutralization potency of botulinum neurotoxin antibodies using a red blood cell-targeting fusion protein.

Botulinum neurotoxin (BoNT) potently inhibits cholinergic signaling at the neuromuscular junction. The ideal countermeasures for BoNT exposure are monoclonal antibodies or BoNT antisera, which form BoNT-containing immune complexes that are rapidly cleared from the general circulation. Clearance of opsonized toxins may involve complement receptor-mediated immunoadherence to red blood cells (RBC) in primates or to platelets in rodents. Methods of enhancing immunoadherence of BoNT-specific antibodies may increase their potency in vivo. We designed a novel fusion protein (FP) to link biotinylated molecules to glycophorin A (GPA) on the RBC surface. The FP consists of an scFv specific for murine GPA fused to streptavidin. FP:mAb:BoNT complexes bound specifically to the RBC surface in vitro. In a mouse model of BoNT neutralization, the FP increased the potency of single and double antibody combinations in BoNT neutralization. A combination of two antibodies with the FP gave complete neutralization of 5,000 LD50 BoNT in mice. Neutralization in vivo was dependent on biotinylation of both antibodies and correlated with a reduction of plasma BoNT levels. In a post-exposure model of intoxication, FP:mAb complexes gave complete protection from a lethal BoNT/A1 dose when administered within 2 hours of toxin exposure. In a pre-exposure prophylaxis model, mice were fully protected for 72 hours following administration of the FP:mAb complex. These results demonstrate that RBC-targeted immunoadherence through the FP is a potent enhancer of BoNT neutralization by antibodies in vivo.

Prodrug of proline analogue reduces hypoxic pulmonary hypertension in rats.

A polymeric prodrug of the proline analogue cis-4-hydroxy-l-proline (CHOP), poly(ethylene glycol)-lysine-CHOP or CHOP-PEG, prevents hypoxic pulmonary hypertension in rats by inhibiting collagen accumulation. A more potent prodrug was synthesized by increasing the loading of CHOP on the carrier from 14 to 100%. Pulmonary antihypertensive efficacy and pharmacokinetics are described in the rat hypoxia model. The antihypertensive effect of CHOP-PEG in rats exposed to 10% O2 for 7d showed approximately 2 x 10(2)-fold greater potency than monomeric CHOP. Routes of administration were compared to determine the lowest dose of CHOP-PEG that reduced right ventricular pressure approximately 50% vs. untreated hypoxic controls at 7d. Total doses required were: continuous s.c. via an osmotic minipump, 0.8 mg; single s.c., 10mg; single i.v., 40 mg; and single intratracheal 90 mg. Efficacy for at least 7d postdosing in pre-established pulmonary hypertension was shown. Using an ELISA-based assay, biphasic i.v. and stable s.c. pharmacokinetic profiles were observed 72 h after single injections and 7d after continuous s.c. infusion. Thus, this CHOP-PEG formulation prevents and reverses chronic hypoxic pulmonary hypertension in rats, is most effective when given by continuous s.c. infusion, and has favorable pharmacokinetic properties. Potent inhibitors of fibrosis appear to be promising agents in treating pulmonary hypertension and possibly other fibrosing diseases.