Search for the autoantibody immunodominant region on thyroid peroxidase: epitopic footprinting with a human monoclonal autoantibody locates a facet on the native antigen containing a highly conformational epitope

Autoantibodies to thyroid peroxidase (TPO) are the hallmark of the humoral autoimmune response in human autoimmune thyroiditis (Hashimoto's thyroiditis). The majority of TPO autoantibodies in individual patients' sera interact with a restricted immunodominant region on TPO. Although this region can be mapped, previous studies have failed to localize its position on the TPO molecule. We, therefore, used a footprinting approach that can localize a highly conformational, discontinuous epitope on a very large molecule. Extensive biotinylation ( approximately 15 biotins/molecule protein) of lysine residues on the surface of purified, native TPO resulted in loss of multiple tryptic cleavage sites, as determined by analysis of tryptic polypeptide fragments on reverse-phase HPLC. TPO was then complexed with a monoclonal human autoantibody Fab (TR1.9) before biotinylation. After dissociation from TR1.9, TPO was recovered by gel filtration. A trypsin site, previously observed to be lost after TPO biotinylation, was restored when biotinylation was performed on the TPO-TR1.9 complex. The epitope-protected lysine (K) was present in a 30-aa TPO fragment that, by N-terminal sequencing, was found to be K713. Altered recognition by TR1.9 of a TPO-myeloperoxidase chimeric molecule involving this region supported the epitope protection data. In conclusion, we provide the first identification of an amino acid residue (K713) comprising part of an epitope within the TPO immunodominant region. This focal residue localizes the facet on the large, highly complex TPO molecule that contains the immunodominant region and provides the basis for rational guided mutagenesis studies to more fully characterize this region.     

Trifunctional conjugation reagents. Reagents that contain a biotin and a radiometal chelation moiety for application to extracorporeal affinity adsorption of radiolabeled antibodies

A method of removing radiolabeled monoclonal antibodies (mAbs) from blood using a device external to the body, termed extracorporeal affinity-adsorption (EAA), is being evaluated as a means of decreasing irradiation of noncancerous tissues in therapy protocols. The EAA device uses an avidin column to capture biotinylated-radiolabeled mAbs from circulated blood. In this investigation, three trifunctional reagents have been developed to minimize the potential deleterious effect on antigen binding brought about by the combination of radiolabeling and biotinylation of mAbs required in the EAA approach. The studies focused on radiolabeling with (111)In and (90)Y, so the chelates CHX-A' '-DTPA and DOTA, which form stable attachments to these radionuclides, were incorporated in the trifunctional reagents. The first trifunctional reagent prepared did not incorporate a group to block the biotin cleaving enzyme biotinidase, but the two subsequent reagents coupled aspartic acid to the biotin carboxylate for that purpose. All three reagents used 4,7,10-trioxa-1,13-tridecanediamine as water-soluble spacers between an aminoisophthalate core and the biotin or chelation group. The mAb conjugates were radioiodinated to evaluate cell binding as a function of substitution. Radioiodination was used so that a direct comparison with unmodified mAb could be made. Evaluation of the number of conjugates per antibody versus cell binding immunoreactivities indicated that minimizing the number of conjugates was best. Interestingly, a decrease of radioiodination yield as a function of the number of isothiocyanate containing conjugates per mAb was noted. The decreased yields were presumably due to the presence of thiourea functionality formed in the conjugation reaction. Radiolabeling with (111)In and (90)Y was facile at room temperature for conjugates containing the CHX-A' ', but elevated temperature (e.g., 45 degrees C) was required to obtain good yields with the DOTA chelate. Stability of (90)Y labeled mAb in serum, and when challenged with 10 mM EDTA, was high. However, challenging the (90)Y labeled mAb with 10 mM DTPA demonstrated high stability for the DOTA containing conjugate, but low stability for the CHX-A' ' containing conjugate. Thus, the choice between these two chelating moieties might be made on requirements for facile and gentle labeling versus very high in vivo stability. Application of the trifunctional biotinylation reagents to the blood clearance of labeled antibodies in EAA is under investigation. The new reagents may also be useful for other applications.     

Structural insights into the conformation and oligomerization of E2~ubiquitin conjugates

Post-translational modification of proteins by ubiquitin (Ub) regulates a host of cellular processes, including protein quality control, DNA repair, endocytosis, and cellular signaling. In the ubiquitination cascade, a thioester-linked conjugate between the C-terminus of Ub and the active site cysteine of a ubiquitin-conjugating enzyme (E2) is formed. The E2~Ub conjugate interacts with a ubiquitin ligase (E3) to transfer Ub to a lysine residue on a target protein. The flexibly linked E2~Ub conjugates have been shown to form a range of structures in solution. In addition, select E2~Ub conjugates oligomerize through a noncovalent "backside" interaction between Ub and E2 components of different conjugates. Additional studies are needed to bridge the gap between the dynamic monomeric conjugates, E2~Ub oligomers, and the mechanisms of ubiquitination. We present a new 2.35 ? crystal structure of an oligomeric UbcH5c~Ub conjugate. The conjugate forms a staggered linear oligomer that differs substantially from the "infinite spiral" helical arrangement of the only previously reported structure of an oligomeric conjugate. Our structure also differs in intraconjugate conformation from other structurally characterized conjugates. Despite these differences, we find that the backside interaction mode is conserved in different conjugate oligomers and is independent of intraconjugate relative E2-Ub orientations. We delineate a common intraconjugate E2-binding surface on Ub. In addition, we demonstrate that an E3 CHIP (carboxyl terminus of Hsp70 interacting protein) interacts directly with UbcH5c~Ub oligomers, not only with conjugate monomers. These results provide insights into the conformational diversity of E2~Ub conjugates and conjugate oligomers, and into their compatibility and interactions with E3s, which have important consequences for the ubiquitination process.     

Characterization of lysozyme-estrone glucuronide conjugates. The effect of the coupling reagent on the substitution level and sites of acylation.

Estrone glucuronide conjugates of hen egg white lysozyme were prepared by the mixed anhydride and active ester coupling procedures. Both methods gave good yields of conjugates, but the active ester procedure gave a more diverse range of products, making it less suitable for preparing conjugates for homogeneous enzyme immunoassay. Conjugation of lysozyme with estrone glucuronide by the mixed anhydride procedure gave one major derivative exclusively acylated at lysine residue 33 whereas conjugation by the active ester method gave six derivatives which were acylated at one or more of lysine residues 33, 97, and 116. None of the lysine residues 1, 13, and 96, or the N-terminal alpha-amino group, were acylated in any of the conjugates isolated. The correlation of the conjugate structures with the protein environments of the amino groups in the crystal structure of lysozyme suggested that the sites of acylation were determined not only by the chemical nature of the acylating reagent but also by the surface accessibility and nucleophilicity of the individual lysine residues.     

Enzymic preparation of protein G-peroxidase conjugates catalysed by transglutaminase

Transglutaminases (TGases, EC 2.3.2.13) have proved to be valuable enzymes for site-directed protein coupling via N(epsilon)-(gamma-L-glutamyl)lysine bonds. Their use in conjugate synthesis would overcome many problems caused by chemical reagents. In this approach, we show for the first time that two proteins with different functionalities, namely soybean peroxidase and protein G, can be cross-linked by bacterial TGase with retention of their activities. Soybean peroxidase and protein G were chosen for the enzymic preparation of a bifunctional conjugate among a series of other TGase substrates detected by enzymic incorporation of small fluorescent or biotinylated molecules. The highest yields of conjugate were obtained with a 15-fold excess of peroxidase in phosphate buffer, pH 7.0. Size exclusion chromatography enabled both purification of the conjugates and recovery of the starting materials. Analysis of bifunctionality revealed the coupling of protein G with an average of three peroxidase molecules.     

Avidin-HRP conjugates in biotin-avidin immunoenzyme cytochemistry

Summary Avidin-HRP conjugates were prepared, analysed and tested for avidin-biotin immunocytochemistry. Suitable biotinylation of enzymes, antigens and antibody was obtained by reacting biotin at equimolar ratio to epsilon aminogroups in proteins. The avidin-biotin interaction was used for immunocytochemical detection of phenomena in the field of immunology, i.e. immune complex trapping, specific antibody forming cells and in serology for the cytochemical detection of human auto-antibodies to basement membrane components. Avidin-HRP conjugation using the two step glutaraldehyde method gave a very small amount of monomeric, low molecular weight conjugate with excellent performance. Avidin-HRP conjugation using the periodate method was modified at two points. The first modification concerns the molar ratio of avidin to HRP in the reaction mixture which was brought to about equimolarity. The second modification concerns the periodate concentration which was decreased five fold, ten fold and twenty fold. Decreasing the periodate concentration decreased the amount of polymeric conjugate. Optimal amounts of monomeric, low molecular weight conjugate were obtained with a ten fold decrease of the periodate concentration. Comparable cytochemical results were obtained with monomeric conjugates obtained using both preparation methods.In honour of Professor P. van Duijn     

Avidin-HRP conjugates in biotin-avidin immunoenzyme cytochemistry

Avidin-HRP conjugates were prepared, analysed and tested for avidin-biotin immunocytochemistry. Suitable biotinylation of enzymes, antigens and antibody was obtained by reacting biotin at equimolar ratio to epsilon aminogroups in proteins. The avidin-biotin interaction was used for immunocytochemical detection of phenomena in the field of immunology, i.e. immune complex trapping, specific antibody forming cells and in serology for the cytochemical detection of human auto-antibodies to basement membrane components. Avidin-HRP conjugation using the two step glutaraldehyde method gave a very small amount of monomeric, low molecular weight conjugate with excellent performance. Avidin-HRP conjugation using the periodate method was modified at two points. The first modification concerns the molar ratio of avidin to HRP in the reaction mixture which was brought to about equimolarity. The second modification concerns the periodate concentration which was decreased five fold, ten fold and twenty fold. Decreasing the periodate concentration decreased the amount of polymeric conjugate. Optimal amounts of monomeric, low molecular weight conjugate were obtained with a ten fold decrease of the periodate concentration. Comparable cytochemical results were obtained with monomeric conjugates obtained using both preparation methods.     

Nonenzymatic biotinylation of a biotin carboxyl carrier protein: unusual reactivity of the physiological target lysine

Enzyme-catalyzed addition of biotin to proteins is highly specific. In any single organism one or a small number of proteins are biotinylated and only a single lysine on each of these proteins is modified. A detailed understanding of the structural basis for the selective biotinylation process has not yet been elucidated. Recently certain mutants of the Escherichia coli biotin protein ligase have been shown to mediate "promiscuous" biotinylation of proteins. It was suggested that the reaction involved diffusion of a reactive activated biotin intermediate, biotinoyl-5'-AMP, with nonspecific proteins. In this work the reactivity of this chemically synthesized intermediate toward the natural target of enzymatic biotinylation, the biotin carboxyl carrier protein, was investigated. The results indicate that the intermediate does, indeed, react with target protein, albeit at a significantly slower rate than the enzyme-catalyzed process. Surprisingly, analysis of the products of nonenzymatic biotinylation indicates that of five lysine residues in the protein only the physiological target side chain is modified. These results indicate that either the environment of this lysine residue or its intrinsic properties render it highly reactive to nonenzymatic biotinylation mediated by biotinoyl-5'-AMP. This reactivity may be important for its selective biotinylation in vivo.     

K8 and K12 are biotinylated in human histone H4.

Folding of DNA into chromatin is mediated by binding to histones such as H4; association of DNA with histones is regulated by covalent histone modifications, e.g. acetylation, methylation, and biotinylation. We sought to identify amino-acid residues that are biotinylated in histone H4, and to determine whether acetylation and methylation of histones affect biotinylation. Synthetic peptides spanning fragments of human histone H4 were biotinylated enzymatically using biotinidase. Peptide-bound biotin was probed with streptavidin-peroxidase. Peptides based on the N-terminal sequence of histone H4 were effectively recognized by biotinidase as substrates for biotinylation; in contrast, peptides based on the C-terminal sequences were not biotinylated. Substitution of K8 or K12 with alanine or arginine decreased biotinylation, suggesting that these lysines are targets for biotinylation; K8 and K12 are also known targets for acetylation. Chemical acetylation or methylation of a given lysine decreased subsequent enzymatic biotinylation of neighboring lysines, consistent with cross-talk among histone modifications. Substitution of a given lysine (positive charge) with glutamate (negative charge) abolished biotinylation of neighboring lysines, providing evidence that the net charge of histones has a role in biotinylation. An antibody was generated that specifically recognized histone H4 biotinylated at K12. This antibody was used to detect biotinylated histone H4 in nuclear extracts from human cells. These studies suggest that K8 and K12 in histone H4 are targets for biotinylation, that acetylation and biotinylation compete for the same binding sites, and that acetylation and methylation of histones affect biotinylation of neighboring lysines.     

Refined crystal structures of "aged" and "non-aged" organophosphoryl conjugates of gamma-chymotrypsin

"Aged" organophosphoryl conjugates of serine hydrolases differ from the corresponding "non-aged" conjugates in their striking resistance to nucleophilic reactivation. The refined X-ray structures of "aged" and "non-aged" organophosphoryl conjugates of gamma-chymotrypsin were compared in order to understand the molecular basis for this resistance of "aged" conjugates. "Aged" and "non-aged" crystalline organophosphoryl-gamma-chymotrypsin conjugates were obtained by prolonged soaking of native gamma-chymotrypsin crystals with appropriate organophosphates. Thus, a representative "non-aged" conjugate, diethylphosphoryl-gamma-chymotrypsin, was obtained by soaking native crystals with paraoxon (diethyl-p-nitrophenyl phosphate), and a closely related "aged" conjugate, monoisopropyl-gamma-chymotrypsin, was obtained by soaking with diisopropylphosphorofluoridate. In both crystalline conjugates, the refined structures clearly reveal a high occupancy of the active site by the appropriate organophosphoryl moiety within covalent bonding distance of Ser195 O gamma. Whereas in the "non-aged" conjugate both ethyl groups can be visualized clearly, in the putative "aged" conjugate, as expected, only one isopropyl group is present. There is virtually no difference between the "aged" and "non-aged" conjugates either with respect to the conformation of the polypeptide backbone as a whole or with respect to the positioning of the side-chains within the active site. In the "aged" conjugate, however, close proximity (2.6 A) of the negatively charged phosphate oxygen atom of the dealkylated organophosphoryl group to His57 N epsilon 2 indicates the presence of a salt bridge between these two moieties. In contrast, in the "non-aged" conjugate the DEP moiety retains its two alkyl groups; thus, lacking a negative oxygen atom, it does not enter into such a charge-charge interaction and its nearest oxygen atom is 3.6 A away from His57 N epsilon 2. It is suggested that steric constraints imposed by the salt bridge in the "aged" conjugate lie at the basis of its resistance to reactivation.     

Facile synthesis of multivalent nitrilotriacetic acid (NTA) and NTA conjugates for analytical and drug delivery applications

High-affinity nitrilotriacetic acids (NTA) have great potential in the molecular manipulation of His-tagged proteins. We have developed a facile method to synthesize multivalent NTA and its conjugates. Starting with appropriately protected lysine, we synthesized the mono-NTA synthons functionalized with either an amino group or a carboxylic group. We then obtained tri-NTA through the condensation of the amino NTA and the carboxylic NTA. Using amino tri-NTA as the key intermediate, we synthesized a series of tri-NTA conjugates with a variety of functional units including biotin, dialkyl, fluorescein, and a hydroxybenzimidate moiety. The biotin-tri-NTA was employed to convert a Biacore streptavidin chip into a high-affinity tri-NTA chip. The equilibrium dissociation constants of tri-NTA/His-tagged protein complexes measured by surface plasmon resonance are in the 20 nM range. Histidine(6)-tagged yeast cytosine deaminase (His6-yCD) was incorporated onto the liposome surface by the lipid-tri-NTA conjugate without any activity loss. Fluorescein-tri-NTA formed a stable 1:1 complex with His6-yCD without significant fluorescence quenching. Specific tri-NTA derivatives for the radiolabeling and coupling of two His-tagged proteins to each other are described. Thus, we have added to the toolbox a number of high-affinity tri-NTA adaptors for the manipulation of His-tagged molecules.     

Microscale synthesis of dextran-based multivalent N-linked oligosaccharide probes

We developed a convenient method for the synthesis of dextran-based multivalent probes containing N-linked oligosaccharides which is efficient even in a small scale. Oligosaccharides were derivatized with succinic dihydrazide and dimethylamine borane under a mild acidic condition. The derivatized oligosaccharides were then conjugated in a good yield to periodate-oxidized dextran (500 kDa). Thus, the conjugates containing 120 to 140 oligosaccharide chains per dextran molecule were successfully synthesized. Their practical advantage was shown by the example that the asialofetuin oligosaccharide-dextran conjugate has much higher affinity to Ricinus communis agglutinin (RCA-I) than asialofetuin oligosaccharide itself or asialofetuin. The conjugates were further labeled with fluorescent reagent or biotinylation reagent containing a hydrazino group by the use of the unreacted aldehyde groups of the oxidized dextran, yielding probes with similar densities of fluorophores or biotin groups. Direct binding of the biotinylated asialofetuin oligosaccharide-dextran probe to RCA-I coated on the titer plate at a concentration of 50 ng/50 microl was easily detected using 50 fmol (as oligosaccharides) of the probe. The method for the synthesis of dextran-based oligosaccharide probes will facilitate the investigation of carbohydrate-mediated molecular interactions based on the native oligosaccharide structures.     

Drug delivery systems employing 1,6-elimination: releasable poly(ethylene glycol) conjugates of proteins

Using lysozyme as a representative protein substrate that loses its activity when PEGylation takes place on the epsilon-amino group of lysine residues, various amounts of a novel releasable PEG linker (rPEG) were conjugated to the protein. rPEG-lysozyme conjugates were relatively stable in pH 7.4 buffer for over 24 h. However, regeneration of native protein from the rPEG conjugates occurred in a predictable manner during incubation in high pH buffer or rat plasma, as demonstrated by enzymatic activity and structural characterization. The rates of regeneration were also correlated with PEG number: native lysozyme was released more rapidly from the monosubstituted conjugate than from the disubstituted conjugate, suggesting possible steric hindrance to the approach of cleaving enzymes. Recovery of normal activity and structure for the regenerated native lysozyme was shown by a variety of assays.     

Biotinylation in the hyperthermophile Aquifex aeolicus.

Biotin protein ligase (BPL) catalyses the biotinylation of the biotin carboxyl carrier protein (BCCP) subunit of acetyl CoA carboxylase and this post-translational modification of a single lysine residue is exceptionally specific. The exact details of the protein-protein interactions involved are unclear as a BPL:BCCP complex has not yet been isolated. Moreover, detailed information is lacking on the composition, biosynthesis and role of fatty acids in hyperthermophilic organisms. We have cloned, overexpressed and purified recombinant BPL and the biotinyl domain of BCCP (BCCP Delta 67) from the extreme hyperthermophile Aquifex aeolicus. In vitro assays have demonstrated that BPL catalyses biotinylation of lysine 117 on BCCP Delta 67 at temperatures of up to 70 degrees C. Limited proteolysis of BPL with trypsin and chymotrypsin revealed a single protease-sensitive site located 44 residues from the N-terminus. This site is adjacent to the predicted substrate-binding site and proteolysis of BPL is significantly reduced in the presence of MgATP and biotin. Chemical crosslinking with 1-ethyl-3-(dimethylamino-propyl)-carbodiimide (EDC) allowed the isolation of a BPL:apo-BCCP Delta 67 complex. Furthermore, this complex was also formed between BPL and a BCCP Delta 67 mutant lacking the lysine residue (BCCP Delta 67 K117L) however, complex formation was considerably reduced using holo-BCCP Delta 67. These observations provide evidence that addition of the biotin prosthetic group reduces the ability of BCCP Delta 67 to heterodimerize with BPL, and emphasizes that a network of interactions between residues on both proteins mediates protein recognition.     

Reduction of kidney uptake in radiometal labeled peptide linkers conjugated to recombinant antibody fragments. Site-specific conjugation of DOTA-peptides to a Cys-diabody

Arano and co-workers (Arano et al. (1999) Cancer Res. 59, 128-134) have synthesized peptides with an N-terminal radioiodinated hippuric acid and a C-terminal lysine linked to antibody fragments via the epsilon-amino group of lysine that show reduced kidney uptake compared to antibody fragments directly radioiodinated. This approach takes advantage of the lysine specific carboxypeptidase activity of the kidney brush border enzymes that cleave off the radiolabeled peptide linker from the antibody fragment prior to uptake by proximal tubule cells. On the basis of their approach, we have synthesized a tetrapeptide with an N-terminal DOTA (1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid) and a C-terminal (N(epsilon)-maleoyl)lysine that was site-specifically conjugated to an anti-CEA diabody (Yazaki et al. (2001) Bioconjugate Chem. 12, 220-228) that was engineered to contain a C-terminal cysteine (Cys-diabody). Biodistributions of the In-111-radiolabeled conjugate in nude mice show significantly reduced kidney uptake (a maximum of 82%ID/g at 6 h) compared to In-111 radiolabeled DOTA-diabody (184%ID/g at 6 h) in which DOTA was conjugated to endogenous lysine residues using DOTA-active ester chemistry. To further reduce kidney uptake, a homologous compound with a C-terminal (N(epsilon)-amino-1,6-hexane-bis-vinyl sulfone)lysine was synthesized and site-specifically conjugated to the Cys-diabody. Biodistributions of this In-111-labeled conjugate reduced kidney uptake to 54%ID/g at 6 h. To explore the effect of the relative positions of the chelate vs the cys-diabody on kidney uptake, we also synthesized a tetrapeptide with an N-terminal bromoacetate for conjugation to Cys-diabody and a C-terminal (N(epsilon)-amidino-propyl-3-thio-vinylsulfonyl-DO3A)lysine. This peptide essentially reverses the positions of the chelate and Cys-diabody attachment points on the peptide, while retaining the linker length on the epsilon-amino group of the lysine. In this case, biodistributions of the In-111-radiolabeled conjugate in nude mice showed high kidney uptake (189%ID/g at 6 h), comparable to that obtained with the In-111-radiolabeled active ester conjugated DOTA-diabody (184%ID/g at 6 h). We conclude that the peptide linker strategy of Arano and co-workers to reduce kidney uptake can be successfully applied to chelate/radiometal complexes and requires that the chelate/radiometal be located at the N-terminus of the peptide and the antibody fragment attachment site on the epsilon-amino group of the lysine. Furthermore, we demonstrated a role for the attachment chemistry to the epsilon-amino group of the lysine on the magnitude of kidney uptake.     

Comparison of three types of reagents for detection of Bacteroides fragilis by direct immunofluorescence

Three different methods were used to prepare conjugates for the detection of rods of the Bacteroides fragilis group by direct immunofluorescence. Lyophilized conjugates were prepared. Three sets (five in each) of monovalent conjugates against serotype strains of B. fragilis (including conjugate E/E1 + E2) and polyvalent conjugate (A + B + C + D + E1 + E2) were obtained. Each conjugate was prepared in two variants: 1. unabsorbed, 2. absorbed with tissue powder prior to lyophilization. Conjugates obtained by precipitation of sera with 50% ethanol and direct coupling of gammaglobulins with stain were found to meet the requirement for good fluorescence reagents and are well suited for the detection of B. fragilis by direct immunofluorescence. Absorption of the conjugates with tissue powder before lyophilization did not affect their quality.     

Use of biotin derivatives to probe conformational changes in proteins

Sulfosuccinimidyl-6-(biotinamido) hexanoate and derivatives thereof covalently bind to the epsilon-amino group of lysine residues. Our observation that access of the biotin derivative to specific lysine residues depends on conformational properties of the entire polypeptide chain prompted us to investigate whether differential biotinylation patterns of a protein can be used as indicators for conformational changes. Bovine serum albumin is a soluble protein with characteristic unfolding kinetics upon exposure to high temperature. First, we show that biotinylation patterns of proteins are highly reproducible. Second, we demonstrate by mass spectrometry and tandem mass spectrometry that unfolding of the protein correlates with the accessibility of the biotin derivative to specific lysine residues. We have applied this experimental strategy to the analysis of a cell-surface protein, viz. the human band 3 anion exchanger of erythrocytes infected with the malaria parasite Plasmodium falciparum. We found that Lys(826) in a highly flexible loop can be biotinylated in non-infected (but not infected) erythrocytes, confirming earlier observations (Winograd, E., and Sherman, I. W. (2004) Mol. Biochem. Parasitol. 138, 83-87) based on epitope-specific monoclonal antibodies suggesting that this region undergoes a conformational change upon infection.     

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.     

Biotinylation of reactive amino groups in native recombinant human interleukin-1 beta

Recombinant human interleukin-1 beta (rIL-1 beta) was chemically modified by a 10-fold molar excess (reagent:protein) of sulfosuccinimidyl 6-(biotinamido) hexanoate (sulfo-NHS-LC-biotin) or sulfosuccinimidobiotin (sulfo-NHS-biotin) under mild conditions. The primary product was purified in each case by cation exchange high performance liquid chromatography (HPLC) and digested with endoproteinase Lys C. Peptide mapping by C18 reverse phase HPLC permitted identification of three sites of biotinylation using both reagents; N-terminal alanine, lysine 93, and lysine 94. Few additional singly modified rIL-1 beta products were obtained under these conditions, despite the presence of 15 lysine residues in this protein. These data support the view that the N terminus as well as the trilysine sequence (residues 92-94) are readily susceptible to chemical modification and are exposed on the surface of the protein. Chromatography of intact biotinylated rIL-1 beta by C4 reverse phase HPLC resolved a protein modified exclusively at the N-terminal alanine from two proteins modified singly at either lysine 93 or lysine 94. In addition, a protein product modified at lysine 103 was also obtained when rIL-1 beta was similarly modified with sulfo-NHS-biotin. Since the only difference between the two biotinylation reagents relates to spacer length and its associated hydrophobicity, these data suggest that lysine 103 is not as accessible to surface modification reagents as are lysine 93, lysine 94, or alanine 1. Initial experiments indicate that none of the modifications described above decrease thymocyte proliferation by more than one order of magnitude. Therefore, these amino acid residues are not crucial for bioactivity, and we anticipate the use of these monobiotinylated proteins in structure/function analysis of IL-1 beta.     

Fluorescent ligands for the hemagglutinin of influenza A: synthesis and ligand binding assays

Two fluorescent conjugates of sialic acid have been prepared, with a convenient synthetic route that involves preparation of an unsaturated benzyl ester by cross-metathesis, followed by combined hydrogenation/ hydrogenolysis to provide a sialoside bearing a delta-carboxybutyl group, suitable for coupling with the chosen fluorophores. The fluorescent conjugates bound to bromelain-cleaved hemagglutinin (BHA) with affinities in the low microM range. Binding was accompanied by approximately 4.5-fold fluorescence enhancement for the dansyl conjugate 1 and approximately 3-fold fluorescence quenching for the pyrene conjugate 3.