Pharmacokinetic, biodistribution, and biophysical profiles of TNF nanobodies conjugated to linear or branched poly(ethylene glycol)

Covalent attachment of poly(ethylene glycol) (PEG) to therapeutic proteins has been used to prolong in vivo exposure of therapeutic proteins. We have examined pharmacokinetic, biodistribution, and biophysical profiles of three different tumor necrosis factor alpha (TNF) Nanobody-40 kDa PEG conjugates: linear 1 × 40 KDa, branched 2 × 20 kDa, and 4 × 10 kDa conjugates. In accord with earlier reports, the superior PK profile was observed for the branched versus linear PEG conjugates, while all three conjugates had similar potency in a cell-based assay. Our results also indicate that (i) a superior PK profile of branched versus linear PEGs is likely to hold across species, (ii) for a given PEG size, the extent of PEG branching affects the PK profile, and (iii) tissue penetration may differ between linear and branched PEG conjugates in a tissue-specific manner. Biophysical analysis (R(g)/R(h) ratio) demonstrated that among the three protein-PEG conjugates the linear PEG conjugate had the most extended time-average conformation and the most exposed surface charges. We hypothesized that these biophysical characteristics of the linear PEG conjugate accounts for relatively less optimal masking of sites involved in elimination of the PEGylated Nanobodies (e.g., intracellular uptake and proteolysis), leading to lower in vivo exposure compared to the branched PEG conjugates. However, additional studies are needed to test this hypothesis.     

PEGylation enhances the therapeutic potential of peptide antagonists of the neonatal Fc receptor, FcRn

Peptides targeting the human neonatal Fc receptor (FcRn) were conjugated to poly(ethylene glycol) (PEG) polymers to study their effect on inhibition of the IgG:FcRn protein-protein interaction both in vitro and in mice. Both linear (5-40kDa) and branched (20, 40kDa) PEG aldehydes were conjugated to an amine-containing linker of a homodimeric anti-FcRn peptide using reductive alkylation chemistry. It was found that conjugation of PEG to the peptide compromised the in vitro activity, with larger and branched PEGs causing the most dramatic losses in activity. The conjugates were evaluated in transgenic mice for their ability to accelerate the catabolism of human IgG. Optimal pharmacodynamic properties were observed with PEG-peptide conjugates that contained 20-40kDa linear PEGs and a 20kDa branched PEG. The optimal PEG-peptide conjugates were more effective in vivo than the unconjugated peptide control on a mole:mole and mg/kg basis, and represent potential new longer-acting peptide therapeutics for the treatment of humorally-mediated autoimmune disease.     

Size comparison between proteins PEGylated with branched and linear poly(ethylene glycol) molecules

Therapeutic proteins conjugated with branched poly(ethylene glycol) (PEG) have extended in vivo circulation half-lives compared to linear PEG-proteins, thought to be due partly to a greater hydrodynamic volume of branched PEG-proteins, which reduces the glomerular sieving coefficient. In this paper, viscosity radii of PEGylated alpha-lactalbumin (M(r) = 14.2 kDa) and bovine serum albumin (M(r) = 67 kDa) prepared with linear and branched PEGs (with nominal molecular weights 5, 10, 20 and 40 kDa) were compared experimentally using size exclusion chromatography (SEC). PEG adduct:protein molecular weight ratios of the PEGylated proteins covered the range 1:12 to 6:1. Direct comparisons of experimentally measured viscosity radii were found to be misleading due to differences between actual and nominal molecular weights of the PEG reagents used. Comparison with predicted viscosity radii shows that there is no significant difference between the viscosity radii of branched and linear PEG-proteins having the same total molecular weight of PEG adducts. Therefore, longer in vivo circulation half-lives of branched PEG-proteins compared to linear PEG-proteins are not explained by size difference. It is also calculated that the molecular size cut-off for glomerular filtration, 60 A for a 30 kDa PEG, matches the 30-50 A size range for the pores of the glomerular basement membrane. Finally, it is confirmed that prediction of PEG-protein viscosity radii should be based upon conservation of the total PEG adduct surface area to volume ratio for both linear and branched PEG-proteins regardless of PEGylation extent.     

Preparation and characterization of active site protected poly(ethylene glycol)–avidin bioconjugates

Avidin was modified with poly(ethylene glycol) in the presence of a biotin binding site protective agent synthesised by imminobiotin conjugation to branched 20 kDa PEG. Avidin was incubated with imminobiotin–PEG and reacted with high amounts of 5, 10 or 20 kDa PEG to modify the protein amino groups. Circular dichroism demonstrated that the extensive PEGylation does not alter the protein conformational structure. The affinity of avidin–PEG conjugates for biotin and biotinylated antibodies depended on the PEG size or the use of a protective agent. Avidin–PEG 10 and 20 kDa prepared in the presence of imminobiotin–PEG maintained 100% of the native affinity for biotin. The 5 kDa PEG derivative and the ones obtained without biotin site protection maintained 79–85% of the native affinity. The affinity for biotinylated antibodies decreased to 35% when the conjugation was performed without imminobiotin–PEG, while the conjugates obtained with high-molecular-weight PEGs in the presence of protective agent displayed high residual affinity. All conjugates possessed negligible antigenicity and immunogenicity. PEGylation greatly prolonged the avidin permanence in the circulation, reduced its disposition in the liver and kidneys and promoted accumulation into solid tumors. PEGylation was found to prevent the protein cell uptake, either by phagocytosis or pinocytosis.     

Protein precipitation by polyethylene glycol: a generalized model based on hydrodynamic radius

PEGs for protein precipitation are usually classified by molecular weight. The higher molecular weight precipitants are more efficient but result in higher viscosity. Following empirical evidence that the precipitation efficiency is more comprehensively characterized by PEG hydrodynamic radius (r_h,PEG) than molecular weight, this paper proposes a model to explicate the significance of r_h,PEG. A general expression was formulated to characterize the PEG effect exclusively by r_h,PEG. The coefficients of a linearized form were then fitted using empirical solubility data. The result is a simple numerical relation that models the efficiency of general-shaped PEG precipitants as a function of r_h,PEG and protein hydrodynamic radius (r_h,prot). This equation also explains the effects of environmental conditions and PEG branching. While predictions by the proposed correlation agree reasonably well with independent solubility data, its simplicity gives rise to potential quantitative deviations when involving small proteins, large proteins and protein mixtures. Nonetheless, the model offers a new insight into the precipitation mechanism by clarifying the significance of r_h,PEG. This in turn helps to refine the selection criterion for PEG precipitants.     

Enzymatic activity and thermal stability of PEG-α-chymotrypsin conjugates

α-Chymotrypsin was chemically modified with methoxypoly(ethylene glycol) (PEG) of different molecular weights (700, 2,000, and 5,000 Da) and the amount of polymer attached to the enzyme was varied systematically from 1 to 9 PEG molecules per enzyme molecule. Upon PEG conjugation, enzyme catalytic turnover (k _cat) decreased by 50% and substrate affinity was lowered as evidenced by an increase in the K _M from 0.05 to 0.19 mM. These effects were dependent on the amount of PEG bound to the enzyme but were independent of the PEG size. In contrast, stabilization toward thermal inactivation depended on the PEG molecular weight with conjugates with the larger PEGs being more stable.     

Branched polyethylene glycol for protein precipitation

The use of linear PEGs for protein precipitation raises the issues of high viscosity and limited selectivity. This paper explores PEG branching as a way to alleviate the first problem, by using 3-arm star as the model branched structure. 3-arm star PEGs of 4,000 to 9,000 Da were synthesized and characterized. The effects of PEG branching were then elucidated by comparing the branched PEG precipitants to linear versions of equivalent molecular weights, in terms of IgG recovery from CHO cell culture supernatant, precipitation selectivity, solubility of different purified proteins, and precipitation kinetics. Two distinct effects were observed: PEG branching reduced dynamic viscosity; secondly, the branched PEGs precipitated less proteins and did so more slowly. Precipitation selectivity was largely unaffected. When the branched PEGs were used at concentrations higher than their linear counterparts to give similar precipitation yields, the dynamic viscosity of the branched PEGs were noticeably lower. Interestingly, the precipitation outcome was found to be a strong function of PEG hydrodynamic radius, regardless of PEG shape and molecular weight. These observations are consistent with steric mechanisms such as volume exclusion and attractive depletion.     

Electrophoretic mobility of human red blood cells coated with poly(ethylene glycol)

Poly(ethylene glycol), abbreviated as PEG, was covalently attached to the surface of human red blood cells (RBC) and the effects of such coating on the regions near the cell's glycocalyx were explored by means of cell electrophoresis. RBC electrophoretic mobilities were measured, in polymer-free buffers of various ionic strengths, as functions of PEG molecular mass (3.35, 18.5, 35.0, 35.9 kDa), geometry, (linear or 8-arm branched) and polymer/RBC ratio during attachment. The results indicate marked decreases of the mobility (up to 85%) which were affected by polymer molecular mass and geometry. Since PEG is neutral and its covalent attachment only removes positively-charged amino groups on the cell membrane, such decreases of mobility likely reflect structural changes near and within the RBC glycocalyx. Experimental results were analyzed using an extended "hairy sphere" model to consider friction and thickness of the polymer layer. Calculated polymer layer thickness increased with molecular mass for linear PEGs and was less extended for a branched PEG of similar molecular mass. Friction within the polymer layer increased with polymer/RBC ratio and for the linear PEGs was inversely related to molecular mass; friction was greatest for the branched PEG. Our results are consistent with the effects of attached PEGs on RBC aggregation and surface antigenic site masking, and suggest the usefulness of electrophoretic mobility techniques for studies of bound neutral polymers.     

Facile purification of mono-PEGylated interleukin-1 receptor antagonist and its characterization with multi-angle laser light scattering

Recombinant human interleukin-1 receptor antagonist (rhIL-1ra) was chemically conjugated with succinimidyl carbonate monomethoxyl polyethylene glycols of 5 kDa (SC-PEG_5k) and 10 kDa (SC-PEG_10k) molecular weight. A facile purification of the conjugates was achieved by one-step cationic exchange chromatography. The purity of mono-PEGylated protein was greater than 95%. The purified conjugate was characterized by multi-angle laser light scattering (MALLS) for determining the apparent gyration radius (r_g) and hydrodynamic radius (r_h). MALLS results showed that the conjugation of PEG markedly enhanced r_g and r_h of parent protein (r_g: from 15.7 to 48.2 nm for the PEG_5k and 81.9 nm for the PEG_10k; r_h: from 4.2 to 58.4 nm for the PEG_5k and 102.3 nm for the PEG_10k). The PEGylated rhIL-1ra retained 44.6% of binding activities to the cell receptor for PEG_5k and 40.2% for PEG_10k, compared to the original protein.     

Characterization of a Photosystem II core and its three-dimensional crystals

A photosystem II core from spinach containing the chlorophyll-binding proteins 47 kDa, 43 kDa, the reaction center proteins D1, D2 and cytochromeb ₅₅₉ and three low molecular weight polypeptides (MW < 10 kDa) was isolated, its three-dimensional crystals were prepared, and both core and crystals were studied by spectroscopic techniques and electron microscopy. The absorption spectra of the crystallized form of the core indicate a specific orientation of the various pigments within the crystal.     

Association of hydrophobically-modified poly(ethylene glycol) with fusogenic liposomes

We present results on using cooperative interactions to shield liposomes by incorporating multiple hydrophobic anchoring sites on polyethylene glycol (PEG) polymers. The hydrophobically-modified PEGs (HMPEGs) are comb-graft polymers with strictly alternating monodisperse PEG blocks (M_w=6, 12, or 35 kDa) bonded to C18 stearylamide hydrophobes. Cooperativity is varied by changing the degree of oligomerization at a constant ratio of PEG to stearylamide. Fusogenic liposomes prepared from N-C12-DOPE:DOPC 7:3 (mol:mol) were equilibrated with HMPEGs. Affinity for polymer association to liposomes increases with the degree of oligomerization; equilibrium constants (given as surface coverage per equilibrium concentration of free polymer) for 6 kDa PEG increased from 6.1±0.8 (mg/m²)/(mg/ml) for 2.5 loops to 78.1±12.2 (mg/m²)/(mg/ml) for 13 loops. In contrast, the equilibrium constant for distearoylphosphatidylethanolamine-poly(ethylene glycol) (DSPE-PEG5k) was 0.4±0.1 (mg/m²)/(mg/ml).The multi-loop HMPEGs demonstrate higher levels of protection from complement binding than DSPE-PEG5k. Greater protection does not correlate with binding strength alone. The best shielding was by HMPEG6k-DP3 (with three 6 kDa PEG loops), suggesting that PEG chains with adequate surface mobility provide optimal protection from complement opsonization. Complement binding at 30 min and 12 h demonstrates that protection by multi-looped PEGs is constant whereas DSPE-PEG5k initially protects but presumably partitions off of the surface at longer times.     

Polymeric micelles of PEG-PE as carriers of all-trans retinoic acid for stability improvement

The topical application of all-trans retinoic acid (ATRA) is an effective treatment for several skin disorders, including photo-aging. Unfortunately, ATRA is susceptible to light, heat, and oxidizing agents. Thus, this study aimed to investigate the ability of polymeric micelles prepared from polyethylene glycol conjugated phosphatidylethanolamine (PEG-PE) to stabilize ATRA under various storage conditions. ATRA entrapped in polymeric micelles with various PEG and PE structures was prepared. The critical micelle concentrations were 97–243 μM, depending on the structures of the PEG and PE molecules. All of the micelles had particle diameters of 6–20 nm and neutral charges. The highest entrapment efficiency (82.7%) of the tested micelles was exhibited by ATRA in PEG with a molecular weight of 750 Da conjugated to dipalmitoyl phosphatidylethanolamine (PEG₇₅₀-DPPE) micelles. The PEG₇₅₀-DPPE micelle could significantly retard ATRA oxidation compared to ATRA in 75% methanol/HBS solution. Up to 87% of ATRA remained in the PEG₇₅₀-DPPE micelle solution after storage in ambient air for 28 days. This result suggests that PEG₇₅₀-DPPE micelle can improve ATRA stability. Therefore, ATRA in PEG₇₅₀-DPPE micelle is an interesting alternative structure for the development of cosmeceutical formulations.     

Shielding effect of a PEG molecule of a mono-PEGylated peptide varies with PEG chain length

Abstract

‘Shielding’ effect of a conjugated PEG molecule could cause a change in the electrostatic interaction characteristics of a PEGylate. We investigated how PEG chain length (or molecular weight) alters the electrostatic interaction potential of exenatide variants using their mono-PEGylates in a branched and linear form as model PEGylates. First, we performed the experiments to demonstrate the elution time changes of the mono-PEGylates conjugated with various MW PEGs (5, 10, 20, and 40 kD) using cation exchange chromatography (HiTrap^® SP) at various pHs (2.5, 3.0, 3.5, and 4.0). Then, we calculated the net surface charge of each mono-PEGylate to propose the PEG molecule’s shielding range in terms of the number of amino acids adjacent to the conjugation residue, assuming that a PEG molecule in solution sweeps out a spherical space and an exenatide molecule have a secondary structure. The net charge calculation result was well-correlated with the experimental elution time data, where 5, 10, 20, and 40 kD PEG hindered the electrostatic potential of 5, 8, 12, and 17 amino acid residues in maximum, respectively, on each side of the conjugation point.     

CO2 bioconversion using carbonic anhydrase (CA): Effects of PEG rigidity on the structure of bio-mineralized crystal composites

The combined effect of both carbonic anhydrase (CA) and the rigidity of polyethylene glycol (PEG) were found to assist the bio-mineralized crystallization behavior of CO₂ differentially. In this study, different forms of magnetically responsive calcium carbonate (CaCO₃) crystal composites were successfully formed from gaseous CO₂ by using the different forms of polyethylene glycols (PEGs) in a constant CO₂ pressure controlled chamber. Polygonal particles were produced with more rigid polymer chains (branched PEG), whereas less rigid polymer chains (PEG) induced the formation of ellipsoidal particles. However, no morphological changes occurred without the presence of CA.     

Purification of Pseudomonas sp. proteases through aqueous biphasic systems as an alternative source to obtain bioactive protein hydrolysates

Aqueous biphasic systems (ABSs) are an interesting alternative for separating industrial enzymes due to easy scale-up and low operational cost. The proteases of Pseudomonas sp. M211 were purified through ABS platforms formed by polyethylene glycol (PEG) and citrate buffer salt. Two experimental designs 2³ + 4 were performed to evaluate the following parameters: molar mass of PEG (M_PEG), concentration of PEG (C_PEG), concentration of citrate buffer (C_Cit), and pH. The partition coefficient (K), activity yield (Y), and purification factor (PF) were the responses analyzed. The best purification performance was obtained with the system composed of M_PEG = 10,000 g/mol, C_PEG = 22 wt%, C_Cit = 12 wt%, pH = 8.0; the responses obtained were K = 4.9, Y = 84.5%, PF = 15.1, and tie-line length = 52.74%. The purified proteases of Pseudomonas sp. (PPP) were used to obtain hydrolysates of Lupinus mutabilis (Peruvian lupin cultivar) seed protein in comparison with the commercial protease Alcalase® 2.4L. A strong correlation between hydrolysis degree and radical scavenging activity was observed, and the highest antioxidant activity was obtained with Alcalase® (1.40 and 3.47 μmol Trolox equivalent/mg protein, for 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulphonic acid) and oxygen radical absorbance capacity, respectively) compared with PPP (0.55 and 1.03 μmol Trolox/mg protein). Nevertheless, the IC₅₀ values were lower than those often observed for antioxidant hydrolysates from plant proteins. PEG/citrate buffer system is valuable to purify Pseudomonas proteases from the fermented broth, and the purified protease could be promising to produce antioxidant protein hydrolysates.     

Quantitatively investigating monomethoxypolyethylene glycol modification of protein by capillary electrophoresis

Capillary electrophoresis (CE) was applied to study quantitatively protein modification with succinimidyl succinate-activated monomethoxypolyethylene glycol (MPEG-SS). The heterogeneous distribution of modified proteins and the average modification degree were determined by CE, and the latter met with the results from 2,4,6-trinitrobenzenesulfonic acid (TNBS) spectrometric assay. It was found that the optimal buffer pH for the modification was between pH 7.4 and 8.4, and the modification degree decreased when the modified sample was preserved in high pH solutions. The protein fractions attached with different number of polyethylene glycols (PEGs) were monitored along the process of protein modification. CE was proved to be efficient to evaluate quantitatively several factors of the protein modification, including the modifier/protein molar ratio, the stability of conjugates in different pH environments, and the time course of modification process.     

Analytical partitioning of poly(ethylene glycol)-modified proteins

Covalently grafting proteins with varying numbers (n) of poly(ethylene glycol) molecules (PEGs) often enhances their biomedical and industrial usefulness. Partition between the phases in aqueous polymer two-phase systems can be used to rapidly characterize polymer-protein conjugates in a manner related to various enhancements. The logarithm of the partition coefficient (K) approximates linearity over the range 0<n<x. However, x varies with the nature of the conjugate (e.g., protein molecular mass) and such data analysis does not facilitate the comparison of varied conjugates. The known behavior of surface localized PEGs suggests a better correlation should exist between log K and the weight fraction of polymer in PEG-protein conjugates. Data from four independent studies involving three proteins (granulocyte-macrophage colony stimulation factor, bovine serum albumin and immunoglobulin G) has been found to support this hypothesis. Although somewhat simplistic, ‘weight fraction’ based analysis of partition data appears robust enough to accommodate laboratory to laboratory variation in protein, polymer and phase system type. It also facilitates comparisons between partition data involving disparate polymer-protein conjugates.     

Application of aqueous biphasic systems as strategy to purify tannase from Aspergillus tamarii URM 7115

The aims of the current study are to assess the influence of polyethylene glycol (PEG) concentration, molar mass, pH, and citrate concentrations on aqueous biphasic systems based on 2⁴ factorial designs, as well as to check their capacity to purify tannase secreted by Aspergillus tamarii URM 7115. Tannase was produced through submerged fermentation at 26°C for 67?h in Czapeck-Dox modified broth and added with yeast extract and tannic acid. The factorial design was followed to assess the influence of PEG molar mass (M_PEG 600; 4,000 and 8,000?g/?mol), and PEG (C_PEG 20.0; 22.0 and 24.0% w/w) and citrate concentrations (C_CIT 15.0, 17.5, and 20.0%, w/w), as well as of pH (6.0, 7.0, and 8.0) on the response variables; moreover, partition coefficient (K), yield (Y), and purification factor (PF) were analyzed. The most suitable parameters to purify tannase secreted by A. tamarii URM 7115 through a biphasic system were 600 (g/mol) M_PEG, 24% (w/w) C_PEG, 15% (w/w) C_CIT at pH 6.0 and they resulted in 6.33 enzyme partition, 131.25% yield, 19.80 purification factor and 195.08 selectivity. Tannase secreted by A. tamarii URM 7115 purified through aqueous biphasic systems composed of PEG/citrate can be used for industrial purposes, since it presents suitable purification factor and yield.     

Production,extraction, and thermodynamics protease partitioning from Aspergillus tamarii Kita UCP1279 using PEG/sodium citrate aqueous two-phase systems

Abstract

The protease from Aspergillus tamarii Kita UCP1279 extraction by aqueous two-phase PEG-Citrate (ATPS) systems, using a factorial design 2⁴, was investigated. Then, the variables studied were polyethylene glycol (PEG) molar mass (M_PEG), concentrations of PEG (C_PEG) and citrate (C_CIT), and pH. The responses analyzed were the partition coefficient (K), activity yield (Y) and purification factor (PF). The thermodynamic parameters of the ATPS partition were estimated as a function of temperature. ATPS was able to pre-purify the protease (PF = 1.6) and obtained 84% activity yield. The thermodynamic parameters ΔG°_m (?10.89?kJ mol^?1), ΔH_m (?5.0?kJ?mol^?1) and partition ΔS_m (19.74?J mol^?1 K^?1) showed that the preferential migration of almost all protein contaminants of the crude extract to the salt-rich phase, while the preferred protease was the PEG rich phase. The extracted enzyme presents optimum temperature and pH at range of 40–50?°C and 9.0–11.0, respectively. Moreover, the enzyme was identified as serine protease based on inhibition profile. ATPS showed the satisfactory performance as the first step for Aspergillus tamarii Kita UCP1279 protease pre-purification.     

Effects of linear and branched polyethylene glycol on PEGylation of recombinant hirudin: Reaction kinetics and in vitro and in vivo bioactivities

To improve the therapy efficacy of recombinant hirudin variant-2 (HV2), its PEGylation was investigated using linear mPEG-succinimidyl carbonate (mPEG-SC) and branched mPEG₂-N-hydroxysuccinimide (mPEG₂-NHS). The reaction mixtures of PEGylation were analyzed by RP-HPLC and the mono-PEG-HV2 products were purified by anion exchange chromatography (IEC). Effects of linear and branched PEG on the hydrolysis kinetics of the PEG reagent, the PEGylation kinetics of HV2 and the in vitro and in vivo bioactivity of mono-PEG-HV2 were investigated. The RP-HPLC and IEC analyses showed that linear and branched PEG-HV2 with identical molecular weight had different chromatographic behaviors. The reaction kinetics showed that branched mPEG₂-NHS displayed higher hydrolysis rate but lower PEGylation rates than linear mPEG-SC. Consequently, HV2 conjugated with mPEG₂-NHS required a greater molar ratio of PEG to HV2 than that of mPEG-SC to achieve the identically desired yield of mono-PEG-HV2. The in vitro and in vivo bioactivities of mono-PEG-HV2 showed that branched PEG-HV2 had higher therapeutic efficacy than linear PEG-HV2 with identical molecular weight. The in vivo bioactivity of mono-B-PEG40k-HV2 (mono-PEG-HV2 derived from 40 kDa branched mPEG₂-NHS) had a markedly longer duration in rabbits than did unmodified HV2, which showed its potential to be developed as a candidate antithrombotic drug.