Disulfide-linked antibody-maytansinoid conjugates: optimization of in vivo activity by varying the steric hindrance at carbon atoms adjacent to the disulfide linkage

In this report, we describe the synthesis of a panel of disulfide-linked huC242 (anti-CanAg) antibody maytansinoid conjugates (AMCs), which have varying levels of steric hindrance around the disulfide bond, in order to investigate the relationship between stability to reduction of the disulfide linker and antitumor activity of the conjugate in vivo. The conjugates were first tested for stability to reduction by dithiothreitol in vitro and for plasma stability in CD1 mice. It was found that the conjugates having the more sterically hindered disulfide linkages were more stable to reductive cleavage of the maytansinoid in both settings. When the panel of conjugates was tested for in vivo efficacy in two human colon cancer xenograft models in SCID mice, it was found that the conjugate with intermediate disulfide bond stability having two methyl groups on the maytansinoid side of the disulfide bond and no methyl groups on the linker side of the disulfide bond (huC242-SPDB-DM4) displayed the best efficacy. The ranking of in vivo efficacies of the conjugates was not predicted by their in vitro potencies, since all conjugates were highly active in vitro, including a huC242-SMCC-DM1 conjugate with a noncleavable linkage which showed only marginal activity in vivo. These data suggest that factors in addition to intrinsic conjugate potency and conjugate half-life in plasma influence the magnitude of antitumor activity observed for an AMC in vivo. We provide evidence that bystander killing of neighboring nontargeted tumor cells by diffusible cytotoxic metabolites produced from target cell processing of disulfide-linked antibody-maytansinoid conjugates may be one additional factor contributing to the activity of these conjugates in vivo.     

Selective disulfide bond cleavage in gold(I) cationized polypeptide ions formed via gas-phase ion/ion cation switching

Gaseous multiply protonated disulfide-linked peptides have been subjected to reactions with AuCl2(-) ions to explore the possibility of effecting cation switching of Au+ for two protons and to determine whether cationization by Au+ ions affords selective dissociation of disulfide linkages. The incorporation of Au+ into several model disulfide-linked peptides proved to be straightforward. The primary ion/ion reaction channels were proton transfer, which does not lead to Au+ incorporation, and attachment of AuCl2(-) ions to the polypeptide cation, which does incorporate Au+. Fragmentation of the attachment product, the extent of which varied with peptide and charge state, led to losses of one or more molecules of HCl and, to some extent, cleavage of polypeptides at the disulfide linkage into its two constituent chains. Collisional activation of the intact metal-ion-incorporated peptides showed cleavage of the disulfide linkage to be a major, and in some cases exclusive, process. Cations with protons as the only cationizing agents showed only small contributions from cleavage of the disulfide linkage. These results indicate that Au+ incorporation into a disulfide-linked polypeptide ion is a promising way to effect selective dissociation of disulfide bonds. Cation switching via ion/ion reactions is a convenient means for incorporating gold and is attractive because it avoids the requirement of adding metal salts to the analyte solution.     

The trypsin and chymotrypsin inhibitors in chick peas (Cicer arietinum L). Identification of the trypsin-reactive site, partial-amino-acid sequence and further physico-chemical properties of the major inhibitor.

The two principal isoinhibitors P-5 and P-6 isolated earlier from the seeds of chick peas (Cicer arietinum L.) by a procedure involving biospecific affinity chromatography on active, matrix-bound trypsin are shown to be the virgin and trypsin-modified forms of the same inhibitor. The virgin inhibitor P-5 consists of a single peptide chain of 66 amino acid residues cross-linked by seven disulfide bridges. Upon interaction with the matrix-bound trypsin under the conditions used the virgin inhibitor P-5 is about 50% converted to P-6 by cleavage of a single Lys-Ser linkage at position 14-15 in the molecule. The resulting tetradecapeptide remains bound to the rest of the molecule by two or four disulfide bridges, but the two fragments representing residues 1-14 and 15-66 separate readily by molecular-sieve chromatography following reductive or oxidative cleavage of the disulfide linkages. The sequence 1-25 was established by Edman degradation.     

Transcellular processing of disulfide- and thioether-linked peroxidase--polylysine conjugates in cultured MDCK epithelial cells

Horseradish peroxidase (HRP) was conjugated to nondegradable polycationic poly(D-lysine) (PDL) through either a thioether (HRP-S-PDL) or a disulfide (HRP-SS-PDL) linkage. The binding and transcytosis of these conjugates was studied in Madin-Darby canine kidney (MDCK) cell monolayers grown on 3-microns microporous polycarbonate filters. Conjugation of HRP to PDL with both linkages markedly increased the binding of this protein onto the cell monolayers. However, an enhancement of the transcellular transport of HRP in both apical-to-basal and basal-to-apical directions was observed only in HRP-SS-PDL, but not in HRP-S-PDL. HRP-SS-PDL transport was inhibited by colchicine and by 4 degrees C incubation. The transport of 14C-sucrose was not affected by the presence of conjugates. These results indicate that the transport of the conjugate across the cell monolayers was due to a transcellular process rather than to any leakage of the cell junction caused by polycations. The disulfide linkage between HRP and PDL was cleaved rapidly at the basal and, to a lesser extent, at the apical surface of the cell. Neuraminidase treatment decreased the binding of the conjugates onto the cell surface, but did not decrease the transcellular transport, suggesting that not all surface-bound conjugates were available for transcytosis. These results demonstrate that disulfide linkages can be cleaved during transcytosis in MDCK cells. The cleavage, however, occurs mostly at the binding site on the cell surface, which may prevent the cellular uptake of the intact conjugate.     

Selective bone targeting 5-fluorouracil prodrugs: synthesis and preliminary biological evaluation

Bone tumor is a notoriously difficult disease to manage, requiring frequent and heavy doses of systemically administered chemotherapy. Targeting anticancer drug to the bone after systemic administration may provide both greater efficacy of treatment and less frequent administration. In this paper, a series of bone targeting Asp oligopeptides 5-fluorouracil conjugates have been synthesized in a convergent approach and well characterized by NMR and MS techniques. Their hydroxyapatite (HAP) affinity, drug release and cytotoxicity characteristics were evaluated in in vitro conditions. All the prodrugs were water soluble and exhibited high affinity to HAP .The efficient release of the active drug moiety occurring by the cleavage of different linkage in physiological conditions significantly reduced the number of viable human cancer cells. From in vivo distribution, we get these compounds with high bone-selectivity and long halflife. These results provided an effective entry to the development of new bone targeting chemotherapeutic drugs.     

Recombinant expression of mouse osteocalcin protein in Escherichia coli

Osteocalcin is the most abundant non-collagenous protein of bone. Recombinant mouse osteocalcin protein (mOC) that includes the highly conserved central domain for binding to hydroxyapatite (HA), a mineral component of bone, was expressed in Escherichia coli. Purified mOC protein exhibited a significant increase in HA adhesion and differentiation in osteoblast cells as well as binding to HA with high affinity.     

Preparation of N-tBoc L-glutathione dimethyl and di-tert-butyl esters: versatile synthetic building blocks

The title l-glutathione derivatives, containing acid- and base-labile esters, respectively, were obtained in good overall yields. N-(t)Boc l-glutathione dimethyl ester was prepared via Fischer esterification of l-glutathione disulfide (GSSG) using HCl in dry methanol, protection of the amine with (t)Boc(2)O, and tributylphosphine cleavage of the disulfide in wet isopropanol. Alternatively, Fischer esterification and (t)Boc-protection of l-glutathione (GSH) also furnished N-(t)Boc glutathione dimethyl ester accompanied by a small amount of S-(t)Boc that was removed chromatographically. The di-tert-butyl ester was obtained by S-palmitoylation of GSH in TFA as solvent, N-(t)Boc-protection, esterification using (t)BuOH mediated by diisopropylcarbodiimide/copper(I) chloride, and saponification of the thioester. These l-glutathione derivatives are versatile synthetic building blocks for the preparation of S-glutathione adducts.     

Homo-oligomerization of the porcine reproductive and respiratory syndrome virus nucleocapsid protein and the role of disulfide linkages

As a step toward understanding the assembly pathway of the porcine reproductive and respiratory syndrome virus (PRRSV), the oligomeric properties of the nucleocapsid (N) protein were investigated. In this study, we have demonstrated that under nonreducing conditions the N protein forms disulfide-linked homodimers. However, inclusion of an alkylating agent (N-ethylmaleimide [NEM]) prevented disulfide bond formation, suggesting that these intermolecular disulfide linkages were formed as a result of spurious oxidation during cell lysis. In contrast, N protein homodimers isolated from extracellular virions were shown to have formed NEM-resistant intermolecular disulfide linkages, the function of which is probably to impart stability to the virion. Pulse-chase analysis revealed that N protein homodimers become specifically disulfide linked within the virus-infected cell, albeit at the later stages of infection, conceivably when the virus particle buds into the oxidizing environment of the endoplasmic reticulum. Moreover, NEM-resistant disulfide linkages were shown to occur only during productive PRRSV infection, since expression of recombinant N protein did not result in the formation of NEM-resistant disulfide-linked homodimers. Mutational analysis indicated that of the three conserved cysteine residues in the N protein, only the cysteine at position 23 was involved in the formation of disulfide linkages. The N protein dimer was shown to be stable both in the presence and absence of intermolecular disulfide linkages, indicating that noncovalent interactions also play a role in dimerization. Non-disulfide-mediated N protein interactions were subsequently demonstrated both in vitro by the glutathione S-transferase (GST) pull-down assay and in vivo by the mammalian two-hybrid assay. Using a series of N protein deletion mutants fused to GST, amino acids 30 to 37 were shown to be essential for N-N interactions. Furthermore, since RNase A treatment markedly decreased N protein-binding affinity, it appears that at least in vitro, RNA may be involved in bridging N-N interactions. In cross-linking experiments, the N protein was shown to assemble into higher-order structures, including dimers, trimers, tetramers, and pentamers. Together, these findings demonstrate that the N protein possesses self-associative properties, and these likely provide the basis for PRRSV nucleocapsid assembly.     

Localization of two interchain disulfide bridges in dimers of bovine alpha s2-casein. Parallel and antiparallel alignments of the polypeptide chains.

Carboxymethylation of bovine skimmed milk with 14C-labelled iodoacetic acid followed by purification of the alpha s2-casein dimer showed that all four cysteine residues in the protein are engaged in disulfide linkages. Mass spectrometry and sequence analysis of cystine-containing tryptic peptides revealed the presence of two interchain disulfide bridges in the protein. Sequence analysis of disulfide-linked peptides resulting from an enzymatic cleavage between the bridges demonstrated that the individual chains in the dimers are either aligned in an antiparallel or a parallel orientation. The identity of some of the disulfide-linked peptides was further verified by performic acid oxidation followed by sequence analysis of the resulting peptides.     

Interposition of different chemical linkages between antibody and 111In-DTPA to accelerate clearance from non-target organs and blood

Two chemically labile linkages, disulfide and diester, and two stable linkages, thioether and hydrocarbon, were introduced between antibody and ¹¹¹In-DTPA in order to modify their biodistributions. The biodistributions of the new linkages were evaluated in rats with target antigens localized in lungs. For a comparison purpose, the antibody-DTPA conjugate with a peptide linkage was used as a control conjugate. The antibody conjugates with the stable linkages produced the biodistributions similar to that of the peptide linked conjugate during a 48 h period. The disulfide and diester conjugates, however, cleared from blood much faster and are retained in normal organs much lower than the peptide conjugate. The disulfide and the diester conjugate amplified the lung (target) to blood ratio by 15 and 6 times, respectively at 48 h, as compared to the corresponding target to blood ratio of the control conjugate. Compared to the control conjugate, a 3 times higher target to liver ratio was also obtained by the disulfide conjugate and a 4 times higher target to kidney ratio was obtained by the diester conjugate at 48 h.     

Conjugates of a novel 7-substituted camptothecin with RGD-peptides as α(v)β₃ integrin ligands: An approach to tumor-targeted therapy

Eight conjugates of a novel camptothecin derivative (Namitecan, NMT) with RGD peptides have been synthesized and biologically evaluated. This study focused on factors that optimize the drug linkage to the transport vector. The different linkages investigated consist of heterofunctional glycol fragments and a lysosomally cleavable peptide. The linkage length and conformation were systematically modified with the purpose to understand their effect on receptor affinity, systemic stability, cytotoxicity, and solubility of the corresponding conjugates. Among the new conjugates prepared, C6 and C7 showed high receptor affinity and tumor cell adhesion, acceptable stability in murine blood, and high cytotoxic activity (IC?? = 8 nM). The rationale, synthetic strategy, and preliminary biological results will be presented.     

Disulfide bonding in influenza virus proteins as revealed by polyacrylamide gel electrophoresis.

Disulfide bonding in the major proteins of influenza virus A, WSN strain, was studied by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels under reducing and nonreducing conditions. The electrophoretic behavior of the proteins correlated with their localization in the virions and their chemical composition. The internal proteins of the viral particles, i.e. matrix and nucleoproteins, were shown to contain a relatively small number of cysteine residues. Electrophoresis under nonreducing conditions yielded multiple forms of the proteins which could be discriminated by small but readily observable, reproducible differences in their migration rates in the gel. the multiplicity of the protein forms was caused by the formation of intramolecular disulfide bonds in matrix and nucleoproteins that arose during or after solubilization in sodium dodecyl sulfate. On the other hand, we failed to detect native inter- and intramolecular linkages in matrix and nucleoproteins. External glycoproteins of the virions (HA and NA) had, in contrast to the internal ones, a higher number of cysteine residues and native disulfide bonds. At least three disulfide linkages were revealed in HA and NA in our experiments. In uncleaved HA all of the linkages were intramolecular. In NA at least one disulfide bond linked two identical polypeptides into a dimer. It was established that the reduction of the different disulfide linkages in HA and NA required different concentrations of the reducing agent.     

Covalent fixation of hemoglobin to dextran phosphates decreases its oxygen affinity.

The interactions between various dextran phosphates and Hb (hemoglobin) were studied by measuring the oxygen-binding parameters of the mixtures. The effector properties of polymers were found to depend on the concentration of monoalkylmonophosphate groups on the polymers and also on their molecular weights. The covalent fixation of dextran phosphates bearing aldehydic groups to oxyHb and deoxyHb was carried out. The oxygen-binding properties of the conjugates thus obtained depended upon the initial form of the protein. Thus, only the conjugates synthesized from deoxyHb exhibited a low oxygen affinity, which means that, in this case, the linkages between the dextran phosphate and the protein allow a permanent interaction of the phosphate groups with amines of the 2,3-diphosphoglycerate binding site. The Hill coefficient values of these conjugates were smaller than that of free Hb, corresponding to a loss of the cooperativity of the protein upon fixation of polymers. However, as these new conjugates are capable of unloading more O2 than blood when subjected to oxygen pressures corresponding to physiological conditions, they can be regarded as potential erythrocyte substitutes.     

Reduction of a disulfide bond of thrombospondin in the supernatant solution of activated platelets

Incubation of the material secreted by activated platelets leads to the formation of disulfide-linked dimers and multimers of one of the proteins, thrombospondin. To determine whether these complexes formed as a result of thiol-disulfide exchange (no change in the number of thiols) or of oxidation of thiols (a decrease in the number of thiols), the number of thiols in TSP was measured during formation of multimers. The number of thiols increased from about 3/mol to 4.8/mol. The half-time for the disappearance of monomers of thrombospondin was fourfold greater than the half-time for appearance of new thiols. The appearance of new thiols, as well as the formation of multimers, was inhibited by Ca2+. The appearance of new thiols was reversible; addition of Ca2+ reversed the process, and at pH 8, but not at pH 6 or 7, the appearance of new thiols spontaneously reversed. No new thiols formed during incubation of partially purified thrombospondin or after the supernatant solution had been treated with activated thiol-Sepharose to remove reactive thiol compounds. It is concluded that thrombospondin has a disulfide bond that is unstable in the absence of Ca2+. It can be attacked by a thiol of another molecule of thrombospondin to form disulfide-linked multimers, by a thiol of the same molecule of thrombospondin to generate isomerization of disulfide bonds or, as observed in this study, by another secreted thiol compound to give a mixed disulfide and a new thiol.     

Productive recognition of factor IX by factor XIa exosites requires disulfide linkage between heavy and light chains of factor XIa

In the intrinsic pathway of blood coagulation factor XIa (FXIa) activates factor IX (FIX) by cleaving the zymogen at Arg(145)-Ala(146) and Arg(180)-Val(181) bonds releasing an 11-kDa activation peptide. FXIa and its isolated light chain (FXIa-LC) cleave S-2366 at comparable rates, but FXIa-LC is a very poor activator of FIX, possibly because FIX undergoes allosteric modification on binding to an exosite on the heavy chain of FXIa (FXIa-HC) required for optimal cleavage rates of the two scissile bonds of FIX. However preincubation of FIX with a saturating concentration of isolated FXIa-HC did not result in any potentiation in the rate of FIX cleavage by FXIa-LC. Furthermore, if FIX binding via the heavy chain exosite of FXIa determines the affinity of the enzyme-substrate interaction, then the isolated FXIa-HC should inhibit the rate of FIX activation by depleting the substrate. However, whereas FXIa/S557A inhibited FIX activation of by FXIa, FXIa-HC did not. Therefore, we examined FIX binding to FXIa/S557A, FXIa-HC, FXIa-LC, FXIa/C362S/C482S, and FXIa/S557A/C362S/C482S. The heavy and light chains are disulfide-linked in FXIa/S557A but not in FXIa/C362S/C482S and FXIa/S557A/C362S/C482S. In an ELISA assay only FXI/S557A ligated FIX with high affinity. Partial reduction of FXIa/S557A to produce heavy and light chains resulted in decreased FIX binding, and this function was regained upon reformation of the disulfide linkage between the heavy and the light chains. We therefore conclude that substrate recognition by the FXIa exosite(s) requires disulfide-linked heavy and light chains.     

The N-terminal disulfide linkages of human insulin-like growth factor-binding protein-6 (hIGFBP-6) and hIGFBP-1 are different as determined by mass spectrometry.

The actions of insulin-like growth factors (IGFs) are modulated by a family of six high affinity binding proteins (IGFBPs 1-6). IGFBP-6 differs from other IGFBPs in having the highest affinity for IGF-II and in binding IGF-I with 20-100-fold lower affinity. IGFBPs 1-5 contain 18 conserved cysteines, but human IGFBP-6 lacks 2 of the 12 N-terminal cysteines. The complete disulfide linkages of IGFBP-6 were determined using electrospray ionization mass spectrometry of purified tryptic peptide complexes digested with combinations of chymotrypsin, thermolysin, and endoproteinase Glu-C. Numbering IGFBP-6 cysteines sequentially from the N terminus, the first three disulfide linkages are Cys1-Cys2, Cys3-Cys4, and Cys5-Cys6. The next two linkages are Cys7-Cys9 and Cys8-Cys10, which are analogous to those previously determined for IGFBP-3 and IGFBP-5. The C-terminal linkages are Cys11-Cys12, Cys13-Cys14, and Cys15-Cys16, analogous to those previously determined for IGFBP-2. Disulfide linkages of IGFBP-1 were partially determined and show that Cys1 is not linked to Cys2 and Cys3 is not linked to Cys4. Analogous with IGFBP-3, IGFBP-5, and IGFBP-6, Cys9-Cys11 and Cys10-Cys12 of IGFBP-1 are also disulfide-linked. The N-terminal linkages of IGFBP-6 differ significantly from those of IGFBP-1 (and, by implication, the other IGFBPs), which could contribute to the distinctive IGF binding properties of IGFBP-6.     

Biodegradable block copolymer micelles with thiol-responsive sheddable coronas

Novel sheddable micelles having hydrophilic coronas capable of being shed from biodegradable polylactide (PLA) cores by the cleavage of disulfide linkages in response to thiols were prepared by aqueous micellization of PLA-based amphiphilic block copolymers functionalized with disulfides at block junctions. These well-defined copolymers were synthesized by a combination of ring-opening polymerization and atom transfer radical polymerization in the presence of a new disulfide-functionalized double-head initiator having both terminal OH and Br groups. (1)H NMR and GPC results indicate that both polymerizations were well-controlled with molecular weight distribution as low as M(w)/M(n) < 1.2. Aqueous micellization to form core/shell micelles with disulfides at the interface of PLA cores and hydrophilic coronas and their thiol-responsive degradation were investigated. In the presence of water-soluble thiols, disulfide linkages in the micelles were cleaved and hydrophilic coronas were lost, causing PLA cores to precipitate due to the loss of colloidal stability. In a biomedical perspective, the new sheddable micelles were not cytotoxic and hence biocompatible.     

Cysteinylated protein as reactive disulfide: an alternative route to affinity labeling

Engineering the permanent formation of a receptor-ligand complex has a number of promising applications in chemistry, biology, and medicine. Antibodies and other proteins can be excellent receptors for synthetic ligands such as probes or drugs. Because proteins possess an array of nucleophilic sites, the placement of an electrophile on the synthetic ligand to react with a nucleophile on the macromolecule is a standard practice. Previously, we have used the site-directed incorporation of cysteine nucleophiles at the periphery of an antibody's binding site, paired with the chemical design of weakly electrophilic ligands, to produce receptor-ligand pairs that conjugate specifically and permanently (Corneillie et al. (2004) Bioconjugate Chem. 15, 1392-1402 and references therein). After protein expression in Drosophila S2 cells, we found, as is frequently observed, that the engineered cysteine was reversibly blocked by disulfide linkage to a cysteine monomer (cysteinylated). Removal of the cysteine monomer requires some care because of the need to preserve other disulfide linkages in the protein. Here, we report that cysteinylation can be used to advantage by treating the cysteine monomer as a leaving group and the protein disulfide as an electrophile with special affinity for thiols. Two ligands bearing thiol side chains were synthesized and incubated with the cysteinylated antibody Fab fragment 2D12.5 G54C, with the finding that both ligands become covalently attached within a few minutes under physiological conditions. The attachment is robust even in the presence of excess thiol reagents. This rapid, specific conjugation is particularly interesting for biomedical applications.     

Hyaluronic acid-paclitaxel conjugate micelles: synthesis, characterization, and antitumor activity

Chemical conjugates of paclitaxel and hyaluronic acid (HA) were synthesized by utilizing a novel HA solubilization method in a single organic phase. Hydrophilic HA was completely dissolved in anhydrous DMSO with addition of poly(ethylene glycol) (PEG) by forming nanocomplexes. Paclitaxel was then chemically conjugated to HA in the DMSO phase via an ester linkage without modifying extremely hydrophilic HA. A series of HA-paclitaxel conjugates with different conjugation percentages were synthesized and characterized. HA-paclitaxel conjugates self-assembled in aqueous solution to form nanosized micellar aggregates, as characterized by dynamic light scattering (DLS), atomic force microscopy (AFM), and transmission electron microscopy (TEM). An intact form of paclitaxel was regenerated from HA-paclitaxel conjugate micelles at acidic pH conditions. HA-paclitaxel conjugate micelles exhibited more pronounced cytotoxic effect for HA receptor overexpressing cancer cells than for HA receptor deficient cells, suggesting that they can be potentially utilized as tumor-specific nanoparticulate therapeutic agents.     

Determination of the disulfide structure of sillucin, a highly knotted, cysteine-rich peptide, by cyanylation/cleavage mass mapping

The disulfide structure of sillucin, a highly knotted, cysteine-rich, antimicrobial peptide, isolated from Rhizomucor pusillus, has been determined to be Cys2--Cys7, Cys12--Cys24, Cys13--Cys30, and Cys14--Cys21 by disulfide mass mapping based on partial reduction and CN-induced cleavage enabled by cyanylation. The denatured 30-residue peptide was subjected to partial reduction by tris(2-carboxyethyl)phosphine hydrochloride at pH 3 to produce a mixture of partially reduced sillucin species; the nascent sulfhydryl groups were immediately cyanylated by 1-cyano-4-(dimethylamino)pyridinium tetrafluoroborate. The cyanylated species, separated and collected during reversed phase high-performance liquid chromatography, were treated with aqueous ammonia, which cleaved the peptide chain on the N-terminal side of cyanylated cysteine residues. The CN-induced cleavage mixture was analyzed by matrix-assisted laser desorption ionization time-of-flight mass spectrometry before and after complete reduction of residual disulfide bonds in partially reduced and cyanylated species to mass map the truncated peptides to the sequence. Because the masses of the CN-induced cleavage fragments of both singly and doubly reduced and cyanylated sillucin are related to the linkages of the disulfide bonds in the original molecule, the presence of certain truncated peptide(s) can be used to positively identify the linkage of a specific disulfide bond or exclude the presence of other possible linkages.