Abstract
In order to use a Hemoglobin Based Oxygen Carrier as an oxygen therapeutic or blood substitute, it is necessary to increase the size of the hemoglobin molecule to prevent rapid renal clearance. A common method uses maleimide PEGylation of sulfhydryls created by the reaction of 2-iminothiolane at surface lysines. However, this creates highly heterogenous mixtures of molecules. We recently engineered a hemoglobin with a single novel, reactive cysteine residue on the surface of the alpha subunit creating a single PEGylation site (βCys93Ala/αAla19Cys). This enabled homogenous PEGylation by maleimide-PEG with >80% efficiency and no discernible effect on protein function. However, maleimide-PEG adducts are subject to deconjugation via retro-Michael reactions and cross-conjugation to endogenous thiol species in vivo. We therefore compared our maleimide-PEG adduct with one created using a mono-sulfone-PEG less susceptible to deconjugation. Mono-sulfone-PEG underwent reaction at αAla19Cys hemoglobin with > 80% efficiency, although some side reactions were observed at higher PEG:hemoglobin ratios; the adduct bound oxygen with similar affinity and cooperativity as wild type hemoglobin. When directly compared to maleimide-PEG, the mono-sulfone-PEG adduct was significantly more stable when incubated at 37°C for seven days in the presence of 1 mM reduced glutathione. Hemoglobin treated with mono-sulfone-PEG retained > 90% of its conjugation, whereas for maleimide-PEG < 70% of the maleimide-PEG conjugate remained intact. Although maleimide-PEGylation is certainly stable enough for acute therapeutic use as an oxygen therapeutic, for pharmaceuticals intended for longer vascular retention (weeks-months), reagents such as mono-sulfone-PEG may be more appropriate.
Highlights
The red blood cell provides both volume support and oxygen transport
20 kDa mono-sulfone-poly(ethylene glycol) (PEG) was prepared according to a published synthetic route (Badescu et al, 2014) and 20 kDa maleimide-PEG was purchased from Iris Biotech
A small fraction of A12 runs as a covalently bonded dimer, presumably either due to oxidative deamination and intramolecular cross-linking during expression in E. coli (Levine et al, 1998) or a new disulfide bridge between the αAla19Cys residues in the two dimers (Cooper et al, 2020) Following PEGylation with 20 kDa mono-sulfone PEG, a significant new band is observed at 56 kDa and smaller bands at ca. 70 and 100 kDa, and - at high PEG:Hb ratios - bands >150 kDa
Summary
Blood loss during trauma and/or pathology can have serious consequences for the mammalian vasculature, dropping blood pressure and compromising oxygen delivery to tissue. More recently there has been interest in the development of “oxygen therapeutics”, Hb solutions designed not to replace blood, but to act in synergy with erythrocytes to deliver oxygen to tissues difficult for red blood cells Hb to access (Bettati and Mozzarelli, 2011). Such oxygen therapeutics have been suggested to play a critical role in new therapeutic interventions in, for example, stroke, trauma and sickle cell disease (Kawaguchi, 2017)
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