A novel one-pot de-blocking and conjugation reaction step leads to process intensification in the manufacture of PEGylated insulin IN-105

Bio-catalytic in vitro multistep reactions can be combined in a single step in one pot by optimizing multistep reactions under identical reaction condition. Using this analogy, the process of making PEGylated insulin, IN-105, was simplified. Instead of taking the purified active insulin bulk powder as the starting material for the conjugation step, an insulin process intermediate, partially purified insulin ester, was taken as starting material. Process intensification (PI) was established by performing a novel de-blocking (de-esterification) of the partially purified insulin ester and conjugation at B-29 Lys residue of B chain with a short-chain methoxy polyethylene glycol (mPEG) in a single-pot reactor. The chromatographic profile at the end of the reaction was found similar irrespective of whether both the reactions were performed sequentially or simultaneously. The conjugated product of interest, IN-105 (conjugation at LysB(29)), was purified from the heterogeneous mixture of conjugated products. The new manufacturing process was deduced to be more simplified and economical in making the insulin conjugates as several downstream purification steps could be circumvented. The physicochemical characteristics of IN-105 manufactured through this economic process was found to be indifferent from the product formed through the traditional process where the conjugation starting material was purified from bulk insulin.     

Induction of in vivo helper activity for murine antibody responses by macrophages pulsed with ovalbumin-monomethoxypolyethylene glycol (OA-mPEG) conjugates

Conjugates of protein antigens with an optimal number of monomethoxypolyethylene glycol (mPEG) chains of an appropriate molecular weight had been shown to suppress murine IgE responses to the unmodified antigen. To investigate the possibility that the tolerogenic capacity of these mPEG conjugates is attributable to a defect in macrophage (M phi) presentation of their antigenic determinants, the activity of ovalbumin (OA)-mPEG conjugates when pulsed onto mouse peritoneal adherent cells (M phi) was compared in this study with their activity in solution. Surprisingly, in contrast to the suppressogenic capacity of mPEG conjugates in solution, the OA-mPEG pulsed M phi appeared to exert a helper effect when injected intraperitoneally (ip), i.e., after subsequent immunization with dinitrophenylated OA (DNP3-OA) in Al(OH)3, the mice showed accelerated IgE and IgG1 antibody responses to OA and DNP. However, when M phi were exposed to limiting concentrations of OA or OA-mPEG, markedly higher concentrations of OA-mPEG were required to yield pulsed M phi, exerting a significant helper effect. It was concluded that although M phi were capable of presenting the OA determinants of OA-mPEG conjugates to helper T (Th) cells, the preparations of modified antigen were presented less effectively than native OA.     

B-Domain deleted recombinant coagulation factor VIII modified with monomethoxy polyethylene glycol

Recombinant coagulation factor VIII (r-VIII SQ) was chemically modified with monomethoxy poly(ethylene glycol) (mPEG). Three mPEG derivatives were used for coupling to the r-VIII SQ lysines, a mixed anhydride of monomethoxy poly(ethylene glycol) succinic acid (mPEG-SAH), monomethoxy poly(ethylene glycol) succinimidyl succinate (mPEG-SS), and monomethoxy poly(ethylene glycol) tresylate (mPEG-TRES). A consequence of the modification with all derivatives was a substantial reduction in coagulant activity, even at very low degrees of modification. A method was developed with the purpose of avoiding conjugation at certain important biological sites on the factor VIII and thereby producing conjugates with better retained activity. This was achieved by immobilizing the protein onto a solid matrix during the modification reaction. Characterization of conjugates by SDS-PAGE, western blots, interaction with von Willebrand factor (vWf), and thrombin activation/inactivation analyses was undertaken. The SDS-PAGE and western blots revealed coupling heterogeneity regarding degree of modification. The amount of factor VIII able to bind to vWf decreased with the conjugation. Thrombin activated the modified factor VIII to essentially the same extent as the reference preparation of r-VIII SQ. Inactivation of the modified factor VIII was, however, slower than inactivation of the unmodified protein. Finally, an in vitro study was performed to evaluate the influence of the mPEG modification on the protein stability in extract of porcine tissue. Despite that conjugates with low degrees of modification were included in the study, the coagulant activity was preserved to a significantly higher extent in all incubation mixtures containing conjugates compared to that with unmodified protein.     

Synthesis and characterization of poly(ethylene glycol)-insulin conjugates

Human insulin was modified by covalent attachment of short-chain (750 and 2000 Da) methoxypoly (ethylene glycol) (mPEG) to the amino groups of either residue PheB1 or LysB29, resulting in four distinct conjugates: mPEG(750)-PheB1-insulin, mPEG(2000)-PheB1-insulin, mPEG(750)-LysB29-insulin, and mPEG(2000)-LysB29-insulin. Characterization of the conjugates by MALDI-TOF mass spectrometry and N-terminal protein sequence analyses verified that only a single polymer chain (750 or 2000 Da) was attached to the selected residue of interest (PheB1 or LysB29). Equilibrium sedimentation experiments were performed using analytical ultracentrifugation to quantitatively determine the association state(s) of insulin derivatives. In the concentration range studied, all four of the conjugates and Zn-free insulin exist as stable dimers while Zn(2+)-insulin was exclusively hexameric and Lispro was monomeric. In addition, insulin (conjugate) self-association was evaluated by circular dichroism in the near-ultraviolet wavelength range (320-250 nm). This independent method qualitatively suggests that mPEG-insulin conjugates behave similarly to Zn-free insulin in the concentration range studied and complements results from ultracentrifugation studies. The physical stability/resistance to fibrillation of mPEG-insulin conjugates in aqueous solution were assessed. The data proves that mPEG(750 and 2000)-PheB1-insulin conjugates are substantially more stable than controls but the mPEG(750 and 2000)-LysB29-insulin conjugates were only slightly more stable than commercially available preparations. Circular dichroism studies done in the far ultraviolet region confirm insulin's tertiary structure in aqueous solution is essentially conserved after mPEG conjugation. In vivo pharmacodynamic assays reveal that there is no loss in biological activity after conjugation of mPEG(750) to either position on the insulin B-chain. However, attachment of mPEG(2000) decreased the bioactivity of the conjugates to about 85% of Lilly's HumulinR formulation. The characterization presented in this paper provides strong testimony to the fact that attachment of mPEG to specific amino acid residues of insulin's B-chain improves the conjugates' physical stability without appreciable perturbations to its tertiary structure, self-association behavior, or in vivo biological activity.     

Development of a process to manufacture PEGylated orally bioavailable insulin

To make insulin orally bioavailable, insulin was modified by covalent attachment (conjugation) of a short-chain methoxy polyethylene glycol (mPEG) derivative to the ε-amino group of a specific amino acid residue (LysB(29)). During the conjugation process, activated PEG can react with any of the free amino groups, the N-terminal of the B chain (PheB(1)), the N-terminal of the A chain (GlyA(1)), and the ε-amino group of amino acid (LysB(29)), resulting in a heterogeneous mixture of conjugated products. The abundance of the desired product (Methoxy-PEG(3)-propionyl--insulin at LysB(29):IN-105) in the conjugation reaction can be controlled by changing the conjugation reaction conditions. Reaction conditions were optimized for maximal yield by varying the proportions of protein to mPEG molecule at various values of pH and different salt and solvent concentrations. The desired conjugated molecule (IN-105) was purified to homogeneity using RP-HPLC. The purified product, IN-105, was crystallized and lyophilized into powder form. The purified product was characterized using multiple analytical methods including ESI-TOF and peptide mapping to verify its chemical structure. In this work, we report the process development of new modified insulin prepared by covalent conjugation of short chain mPEG to the insulin molecule. The attachment of PEG to insulin resulted in a conjugated insulin derivative that was biologically active, orally bioavailable and that showed a dose-dependent glucose lowering effect in Type 2 diabetes patients.     

Chemical camouflage of nanospheres with a poorly reactive surface: towards development of stealth and target-specific nanocarriers

A two-step approach is described to chemically camouflage the inert surface of model polystyrene nanospheres of 60 nm in diameter against recognition by the body's defenses. The first step was based on the strong protein adsorbing potency of polystyrene, and the second step utilized the chemical reactivity of the adsorbed proteins for conjugation with cyanuric chloride-activated methoxypoly(ethyleneglycol)5000, mPEG5000. Bovine serum albumin (BSA) and rat IgG were used as models of non-immune and immune proteins, respectively. The maximum adsorbance values for both proteins were near expectation for a close-packed monolayer. Adsorption isotherms studies and analysis of the hydrodynamic thickness of the adsorbed protein layer confirmed the close-packed side-on mode of adsorption for BSA and the end-on mode of adsorption for IgG, respectively. Nucleophiles on the adsorbed proteins were then reacted with cyanuric chloride activated mPEG5000. The average poly(ethyleneglycol) (PEG) content for a 60-nm nanospheres was found to be 13.7+/-0.4 micromol PEG/micromol BSA and 3.6+/-0.3 micromol PEG/micromol IgG. The interaction of both PEG-bearing nanospheres with the hydrophobic column material octyl-agarose indicated surface heterogeneity among the nanospheres. Only nanospheres with the most hydrophilic phenotype (approximately 70% of the total population) exhibited stealth properties after intravenous injection to rats. In contrast to the described approach, incubation of uncoated nanospheres with preformed BSA-mPEG5000 conjugates failed to produce long circulating entities. For design of splenotropic particles cyanuric chloride-activated mPEG5000 was conjugated to BSA-coated polystyrene beads of 225 nm in diameter. Despite their stealth property to hepatic Kupffer cell recognition, these nanospheres were cleared by the splenic red pulp macrophages.     

Metallo-phthalocyanine near-IR fluorophores: oligonucleotide conjugates and their applications in PCR assays

Water soluble, metallo-pthalocyanine (MPc) near-IR fluorophores were designed, synthesized, and evaluated as highly stable and sensitive reporters for fluorescence assays. Their conjugation to oligonucleotides was achieved via succinimidyl ester-amino coupling chemistry with the conditions for conjugation extensively examined and optimized. In addition, various conjugate purification and isolation techniques were evaluated as well. Results showed that under proper conditions and following purification using reverse-phase ion-pair chromatography, labeling efficiencies near 80% could be achieved using ZnPc (Zn phthalocyanine) as the labeling fluorophore. Absorption and fluorescence spectra accumulated for the conjugates indicated that the intrinsic fluorescence properties of the MPc's were not significantly altered by covalent attachment to oligonucleotides. As an example of the utility of MPc reporters, we used the MPc-oligonucleotide conjugates as primers for PCR (polymerase chain reaction) amplifications with the products sorted via electrophoresis and detected using near-IR fluorescence (lambda ex = 680 nm). The MPc dyes were found to be more chemically stable under typical thermal cycling conditions used for PCR compared to the carbocyanine-based near-IR reporter systems typically used and produced single and narrow bands in the electrophoretic traces, indicative of producing a single PCR product during amplification.     

Thiolytically cleavable dithiobenzyl urethane-linked polymer-protein conjugates as macromolecular prodrugs: reversible PEGylation of proteins

New thiolytically cleavable dithiobenzyl (DTB) urethane-linked conjugates of methoxypoly(ethylene glycol) (mPEG) and a model protein, lysozyme, were prepared and thoroughly characterized. In contrast to our earlier communication [Zalipsky, et al. (1999) Bioconjugate Chem. 10, 703], in the current study we used a more sterically hindered form of para-DTB urethane linkage containing a methyl group on the alpha-carbon to the disulfide moiety. The new reagent for covalent attachment of mPEG-DTB to amino groups of proteins was synthesized via a seven-step process. As a result of PEG conjugation, the lysozyme was shown to completely lose its bacterial cell wall-lysing activity. However, activity was almost fully restored upon cysteine-mediated cleavage of the PEG component. The conjugate decomposition process was monitored by RP-HPLC and by ion spray LC-MS, which showed the formation of the p-mercaptobenzyl urethane-lysozyme intermediate, and ultimately its conversion to the unmodified lysozyme as the sole protein component. Pharmacokinetic evaluation of (125)I-labeled cleavable and noncleavable PEG-lysozyme given intravenously in rats revealed similar clearance patterns; both cleared in a significantly slower manner compared to that of the native protein. However, subcutaneous administration of the same conjugates showed a significantly larger AUC of the cleavable conjugate, indicating that some cleavage of the DTB urethane may have occurred. Although the DTB-linked PEG-lysozyme exhibited almost the same plasma clearance as the noncleavable counterpart, hinting that methyl-DTB linkage might be stable in the bloodstream, SDS-PAGE examination of the conjugate incubated in plasma showed decomposition at least partially mediated by albumin. These results suggest the potential of PEG-DTB-proteins as macromolecular prodrugs capable of generating fully active native proteins under in vivo conditions.     

Preparation of bioconjugates by solid-phase conjugation to ion exchange matrix-adsorbed carrier proteins

A solid-phase conjugation method utilizing carrier protein bound to an ion exchange matrix was developed. Ovalbumin was adsorbed to an anion exchange matrix using a batch procedure, and the immobilized protein was then derivatized with iodoacetic acid N-hydroxysuccinimid ester. The activated protein was conjugated with glutathione, the conjugation ratio determined by acid hydrolysis, and amino acid analysis performed with quantification of carboxymethyl cysteine. Elution of conjugates from the resin by a salt gradient revealed considerable heterogeneity in the degree of derivatization, and immunization experiments with the eluted conjugates showed that the more substituted conjugates gave rise to the highest titers of glutathione antibodies. Direct immunization with the conjugates adsorbed to the ion exchange matrix was possible and gave rise to high titers of glutathione antibodies. Conjugates of ovalbumin and various peptides were prepared in a similar manner and used for production of peptide antisera by direct immunization with the conjugates bound to the ion exchanger. Advantages of the method are its solid-phase nature, allowing fast and efficient reactions and intermediate washings, and the ability to release conjugates from the solid phase under mild conditions.     

Preparation and characterization of paramagnetic polychelates and their protein conjugates

The gadolinium complexes of poly-L-lysine-poly(diethylenetriamine-N,N,N',N",N"-pentaacetic acid) (Gd-PL-DTPA) and poly-L-lysine-poly(1,4,7,10-tetraazacyclododecane-N,N',N",N"'-tetr aacetic acid) (Gd-PL-DOTA) and their conjugates with human serum albumin (HSA) have been prepared and characterized. Poly-L-lysine (PL, degree of polymerization approximately 100) was N-acylated with a mixed anhydride of the chelating ligand (DTPA or DOTA). Sixty to ninety chelating groups per molecule of PL could be attached in this way. Following purification of the polychelate by size-exclusion chromatography, the gadolinium complexes were prepared by standard methods and conjugated to HSA with heterobifunctional cross-linking reagents. The molar relaxities of these macromolecular species were 2-3-fold higher than those of the corresponding monomeric metal complexes [( Gd(DTPA)] and [Gd(DOTA)]). The conjugation conditions were optimized to produce conjugates containing 60-90 metal centers per molecule of HSA (ca. one polychelate per protein).     

Role of the methoxy group in immune responses to mPEG-protein conjugates

Anti-PEG antibodies have been reported to mediate the accelerated clearance of PEG-conjugated proteins and liposomes, all of which contain methoxyPEG (mPEG). The goal of this research was to assess the role of the methoxy group in the immune responses to mPEG conjugates and the potential advantages of replacing mPEG with hydroxyPEG (HO-PEG). Rabbits were immunized with mPEG, HO-PEG, or t-butoxyPEG (t-BuO-PEG) conjugates of human serum albumin, human interferon-α, or porcine uricase as adjuvant emulsions. Assay plates for enzyme-linked immunosorbent assays (ELISAs) were coated with mPEG, HO-PEG, or t-BuO-PEG conjugates of the non-cross-reacting protein, porcine superoxide dismutase (SOD). In sera from rabbits immunized with HO-PEG conjugates of interferon-α or uricase, the ratio of titers of anti-PEG antibodies detected on mPEG-SOD over HO-PEG-SOD ("relative titer") had a median of 1.1 (range 0.9-1.5). In contrast, sera from rabbits immunized with mPEG conjugates of three proteins had relative titers with a median of 3.0 (range 1.1-20). Analyses of sera from rabbits immunized with t-BuO-PEG-albumin showed that t-butoxy groups are more immunogenic than methoxy groups. Adding Tween 20 or Tween 80 to buffers used to wash the assay plates, as is often done in ELISAs, greatly reduced the sensitivity of detection of anti-PEG antibodies. Competitive ELISAs revealed that the affinities of antibodies raised against mPEG-uricase were c. 70 times higher for 10 kDa mPEG than for 10 kDa PEG diol and that anti-PEG antibodies raised against mPEG conjugates of three proteins had >1000 times higher affinities for albumin conjugates with c. 20 mPEGs than for analogous HO-PEG-albumin conjugates. Overall, these results are consistent with the hypothesis that antibodies with high affinity for methoxy groups contribute to the loss of efficacy of mPEG conjugates, especially if multiply-PEGylated. Using monofunctionally activated HO-PEG instead of mPEG in preparing conjugates for clinical use might decrease this undesirable effect.     

Solid-phase PEGylation of recombinant interferon alpha-2a for site-specific modification: process performance, characterization, and in vitro bioactivity

'Solid-phase' PEGylation, in which a conjugation reaction attaches proteins to a solid matrix, has distinct advantages over the conventional, solution-phase process. We report a case study in which recombinant interferon (rhIFN) alpha-2a was adsorbed to a cation-exchange resin and PEGylated at the N-terminus by 5, 10, and 20 kDa mPEG aldehydes through reductive alkylation. After PEGylation, a salt gradient elution efficiently purified the mono-PEGylate of unwanted species such as unmodified IFN and unreacted PEG. Mono-PEGylation and purification were integrated into a single, chromatographic step. Depending on the molecular weight of the mPEG aldehyde, the mono-PEGylation yield ranged from 50 to 65%. Major problems associated with the solution-phase process such as random or uncontrollable multi-PEGylation and post-PEGylation purification difficulties were overcome. N-terminus sequencing and MALDI-TOF mass spectrophometry confirmed that the PEG molecule was conjugated only to the N-terminus. A cell proliferation study indicated reduced antiviral activity of the mono-PEGylate compared to that of the unmodified IFN. As higher molecular weight PEG was conjugated, in vitro bioactivity and antibody binding activity, as measured by a surface plasmon resonance biosensor, decreased. Nevertheless, trypsin resistance and thermal stability were considerably improved .     

Immunochemical cross reactivity of the antibody elicited against L-histidine decarboxylase purified from the whole bodies of fetal rats with the enzyme from rat brain

Rat cytosolic glutathione S-transferases catalyzed the conjugation of phenethyl chloride and phenethyl bromide with glutathione. The reaction proceeded with a high degree of stereoselectivity. The glutathione conjugate possessing the (R,S,S)- absolute configuration was formed in major quantities from the racemic substrates. The use of the enantiomers of the phenethyl chloride substrates indicated that the (S)-phenethyl chloride was conjugated in preference to the (R)-enantiomer. The conjugation proceeded with inversion of configuration at the benzylic carbon consistent with an SN₂-type mechanism. The stereoselectivity was greater for phenethyl chloride than for phenethyl bromide. Varying the substrate or enzyme concentration had no effect upon the observed stereoselectivity. The diastereomeric glutathione conjugates were separated by high performance liquid chromatography. These findings represent the first demonstration of the substrate stereoselectivity of the glutathione S-transferases.     

Simple, direct conjugation of bacterial O-SP-core antigens to proteins: development of cholera conjugate vaccines

Bacterial O-SP-core antigens can be conjugated to proteins in the same, simple way as synthetic, linker-equipped carbohydrates by applying squaric acid chemistry. Introduction of spacers (linkers) to either O-SP-core antigens or protein carriers, which is involved in commonly applied protocols, is not required. The newly developed method described here consists of preparation of a squaric acid monoester derivative of O-SP-core antigen, utilizing the amino group inherent in the core, and reaction of the monoester with the carrier protein. The intermediate monoester can be easily purified; its conjugation can be monitored by SELDI-TOF mass spectrometry and, thus, readily controlled, since the conjugation can be terminated when the desired carbohydrate-protein ratio is reached. Here, we describe production of conjugates containing the O-SP-core antigen of Vibrio cholerae O1, the major cause of cholera, a severe dehydrating diarrheal disease of humans. The resultant products are recognized by convalescent phase sera from patients recovering from cholera in Bangladesh, and anti-O-SP-core-protein responses correlate with plasma antilipopolysaccharide and vibriocidal responses, which are the primary markers of protection from cholera. The results suggest that such conjugates have potential as vaccines for cholera and other bacterial diseases.     

Distribution of cell surface saccharides on pancreatic cells

We describe here a simple, general procedure for the purification of a variety of lectins, and for the preparation of lectin-ferritin conjugates of defined molar composition and binding properties to be used as probes for cell surface saccharides. The technique uses a “universal” affinity column for lectins and their conjugates, which consists of hog sulfated gastric mucin glycopeptides covalently coupled to agarose. The procedure involes: (a) purification of lectins by chromatography of aqueous extracts of seeds or other lectin-containing fluids over the affinity column, followed by desorption of the desired lectin with its hapten suge; (b) iodination of the lectin to serve as a marker during subsequent steps; (c) conjugation of lectin to ferritin with glutaraldehyde; (d) collection of active lectin-ferritin conjugates by affinity chromatography; and (e) separation of monomeric lectin-ferritin conjugates from larger aggregates and unconjugated lectin by gel chromatography. Based on radioactivity and absorbancy at 310 nm for lectin and ferritin, respectively, the conjugates consist of one to two molecules of lectin per ferrritin molecule. Binding studies of native lectins and their ferritin conjugates to dispersed pancreatic acinar cells showed that the conjugation procedure does not significantly alter either the affinity constant of the lectin for its receptor on the cell surface or the number of sites detected.     

Effects of quaternization and PEGylation on the biocompatibility, enzymatic degradability and antioxidant activity of chitosan derivatives

Chitosan-N-trimethylaminoethylmethacrylate chloride (CS-TM) copolymers with different quaternization degrees (DQ, 30 and 50%) were synthesized and further modified with methoxypoly(ethylene glycol) (mPEG) of different molecular weights (MW, 2 and 5 kDa). The hydrophilicity of the resulting copolymers was significantly increased as evidenced by decreased contact angles. PEGylation with higher mPEG MW could significantly reduce the hemolytic potential, protein adsorption, cytotoxicity and intestinal mucosal damage of CS-TM (DQ of 50%, CS-TM50). PEGylation resulted in a considerable increase in the release of reducing sugars following 84-day lysozyme-catalyzed degradation, and an increase in mPEG MW led to a faster degradation of CS-TM50. The antioxidant activity of CS-TM50 was superior to that of PEGylated CS-TM50, exhibiting dose-dependent reducing power and lipid peroxidation inhibition effect. In conclusion, quaternization and subsequent PEGylation of CS with rational modification degree of its free amino group will be a potential strategy for the development of biocompatible and biodegradable CS derivatives.     

Separation and purification of methoxypoly(ethylene glycol) grafted red blood cells via two-phase partitioning

Alloimmunization to donor blood group antigens remains a significant problem in transfusion medicine. To attenuate the risk of alloimmunization, we have pioneered the membrane grafting of methoxypoly(ethylene glycol) (mPEG) to produce immunocamouflaged red blood cells (RBC). Grafting of the mPEG was accomplished using cyanuric chloride activated mPEG (CmPEG; M(r) = 5000), benzotriazole carbonate methoxyPEG (BTCmPEG; M(r) = 2000, 5000 or 20000); or N-hydroxysuccinimidyl ester of mPEG propionic acid (SPAmPEG; M(r) = 5000, or 20000). Because of the heterogeneity of grafting, a crucial tool in developing the stealth RBC is an ability to purify the modified RBC from unmodified (immunogenic) donor cells. As demonstrated, a (5, 4) dextran:PEG aqueous two-phase polymer partitioning system cleanly separated the immunologically silent mPEG-grafted human RBC from control or lightly modified cells. Cell mixing experiments employing varying ratios of mPEG-modified and control RBC confirmed the purification efficacy of the phase partitioning system. Proportional changes in PEG-rich phase partitioning were achieved by increasing either the quantity of surface mPEG or the mPEG molecular weight. The biological viability of purified mPEG-RBC (BTCmPEG; [M(r) = 20000) was demonstrated by their normal in vivo survival at immunoprotective grafting concentrations (相似文献   

Characterization of morphine-glucose-6-phosphate dehydrogenase conjugates by mass spectrometry

A key characteristic of the analyte-reporter enzyme conjugate used in the enzyme-multiplied immunoassay technique (EMIT) is the inhibition of the conjugate enzyme upon anti-analyte antibody binding. To improve our understanding of the antibody-induced inhibition mechanism, we characterized morphine-glucose-6-phosphate dehydrogenase (G6PDH) conjugates as model EMIT analyte-reporter enzyme conjugates. Morphine-G6PDH conjugates were prepared by acylating predominantly the primary amines on G6PDH with morphine 3-glucuronide NHS ester molecules. In this study, morphine-G6PDH conjugates were characterized using a combination of methods, including tryptic digestion, immunoprecipitation, matrix-assisted laser desorption ionization mass spectrometry, and electrospray ionization tandem mass spectrometry. Twenty-six conjugation sites were identified. The identified sites all were found to be primary amines. The degree of conjugation was determined to be less than the number of conjugation sites, suggesting heterogeneity within the morphine-G6PDH conjugate population. Two catalytically important residues in the active site (K22 and K183) were among the identified conjugation sites, explaining at least partially the cause of loss of activity due to the coupling reaction.     

The utilization of alanine, glutamic acid, and serine as amino acid substrates for glycine N-acyltransferase

The conjugation of benzoyl-CoA with the aliphatic and acidic amino acids by glycine N-acyltransferase, as well as the amides of the latter group, was investigated. Bovine and human liver benzoyl-amino acid conjugation were investigated using electrospray ionization tandem mass spectrometry (ESI-MS-MS). Bovine glycine N-acyltransferase catalyzed conjugation of benzoyl-CoA with Gly (Km(Gly) = 6.2 mM), Asn (Km(Asn) = 129 mM), Gln (Km(Gln) = 353 mM), Ala (Km(Ala) = 1573 mM), Glu (Km(Glu) = 1148 mM) as well as Ser in a sequential mechanism. In the case of the human form, conjugation with Gly (Km(Gly) = 6.4 mM), Ala (Km(Ala) = 997 mM), and Glu was detected. The presence of these alternative conjugates did not inhibit bovine glycine N-acyltransferase activity significantly. Considering the relatively low levels at which these conjugates are formed, it is unlikely that they will have a significant contribution to acyl-amino acid conjugation under normal conditions in vivo. However, their cumulative contribution to acyl-amino acid conjugation under metabolic disease states may prove to have a useful contribution to detoxification of elevated acyl-CoAs.     

Novel poly(ethylene glycol) derivatives for preparation of ribosome-inactivating protein conjugates

This study describes the synthesis, characterization, and reactivity of new methoxypoly(ethylene glycol) (mPEG) derivatives containing a thioimidoester reactive group. These activated polymers are able to react with the lysyl epsilon-amino groups of suitable proteins, generating an amidinated linkage and thereby preserving the protein's positive charge. mPEG derivatives of molecular weight 2000 and 5000 Da were used, and two spacer arms were prepared, introducing chains of different lengths between the hydroxyl group of the polymer and the thioimidate group. These mPEG derivatives were used to modify gelonin, a cytotoxic single-chain glycoprotein widely used in preparation of antitumoral conjugates, whose biological activity is strongly influenced by charge modification. The reactivity of mPEG thioimidates toward lysil epsilon-amino groups of gelonin was evaluated, and the results showed an increased degree of derivatization in proportion to the molar excesses of the polymer used and to the length of the alkyl spacer. Further studies showed that the thioimidate reactive is able to maintain gelonin's significant biological activity and immunogenicity. On the contrary, modification of the protein with N-hydroxysuccinimide derivative of mPEG strongly reduces the protein's cytotoxic activity. Evaluation of the pharmacokinetic behavior of native and PEG-grafted gelonin showed a marked increase in plasma half-life after protein PEGylation; in particular, the circulating life of the conjugates increased with increased molecular weight of the polymer used. The biodistribution test showed lower organ uptake after PEGylation, in particular by the liver and spleen.