Synthesis, isolation, and characterization of conjugates of ovalbumin with monomethoxypolyethylene glycol using cyanuric chloride as the coupling agent

The experimental conditions for the preparation of conjugates of ovalbumin (OA) and monomethoxypolyethylene glycol (mPEG) of a preselected average degree of conjugation, n, using cyanuric chloride as the coupling agent, have been investigated with emphasis on purification and characterization of the products. These conjugates served as prototypes of tolerogenic mPEG derivatives of antigenic proteins which were capable of suppressing in mammals the immunological response to the corresponding unmodified antigens. In other studies in this laboratory, the tolerogenicity of OA(mPEG)n conjugates was found to be a function of n. The reproducibility of the reaction leading to the production of OA(mPEG)n conjugates was shown to depend primarily on the reactivity of the mPEG-cyanuric chloride intermediate, which--for best results--had to be synthesized under completely anhydrous conditions. Isolation of the OA(mPEG)n conjugates was optimized by the use of ion-exchange chromatography whereby rapid removal of large amounts of uncoupled intermediate from the conjugate was achieved; the conditions of fractionation were affected by the degree of conjugation. This method of purification was superior to dialysis, ultrafiltration, and gel filtration. Furthermore, by the application of analytical hydrophobic interaction HPLC it was possible to differentiate among conjugates of different degrees of conjugation and to establish the absence of any detectable free OA in any of the preparations. The quantity of mPEG in the conjugates was determined directly by NMR.     

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.     

Optimization of butanediol dimethacrylate crosslinked polystyrene: A novel polymeric support for solid phase peptide synthesis

Studies leading to optimization of butanedioldimethacrylate-crosslinked polystyrene supports (BDDMA–PS) forsolid phase peptide synthesis are delineated. BDDMA–PScopolymers with different crosslink densities were prepared andfunctionalised with chloromethyl groups. The reactivity of theLys(2-Cl-Z)-OH residue bound to these polymers through a benzylester linkage was investigated by following the kinetics ofacylation by the HOBt active ester of Boc-Alanine. From theresults it was observed that the rate of peptide bond formationwas maximum for a 2% BDDMA crosslinked resin. This resin wascompared with a 2% DVB-crosslinked polystyrene resin (DVB–PS). Synthesis of an extremely insoluble, hydrophobic,antiparallel -sheeted difficult sequencepeptide LMVGGVVIA ( 34–42), C-terminal fragment of -amyloid protein, (1–42), wascarried out on both 2% DVB–PS and 2% BDDMA-crosslinkedpolystyrene supports. The synthesis of the peptide was carriedout using Boc amino acid strategy. Greater extent of swellingof the resino peptide, increased coupling efficiency during theassembly of amino acids and relatively high purity of synthesised peptide were observed in the case of 2% BDDMA–PS polymer.     

Solid-phase synthesis of amidine-substituted phenylbenzimidazoles and incorporation of this DNA binding and recognition motif into amino acid and peptide conjugates

Amidine-substituted phenylbenzimidazoles are well-established DNA-binding structural motifs that have contributed to the development of diverse classes of DNA-targeted agents; this ring system not only assists in increasing the overall DNA affinity of an agent, but can also influence its site selectivity. Seeking a means to conveniently exploit these attributes, a protocol for the on-resin synthesis of amino acid- and peptide-phenylbenzimidazole-amidine conjugates was developed to facilitate installation of phenylbenzimidazole-amidines into peptide chains during the course of standard solid-phase syntheses. Building from a resin-bound amino acid or peptide on Rink amide resin, 4-formyl benzoic acid was coupled to the resin-bound free amine followed by introduction of 3,4-diamino-N′-hydroxybenzimidamide (in the presence of 1,4-benzoquinone) to construct the benzimidazole heterocycle. Finally, the resin-bound N′-hydroxybenzimidamide functionality was reduced to an amidine via 1 M SnCl₂·2H₂O in DMF prior to resin cleavage to release final product. This procedure permits the straightforward synthesis of amino acids or peptides that are N-terminally capped by a phenylbenzimidazole-amidine ring system. Employing this protocol, a series of amino acid–phenylbenzimidazole-amidine (Xaa-R) conjugates was synthesized as well as dipeptide conjugates of the general form Xaa-Gly-R (where R is the phenylbenzimidazole-amidine and Xaa is any amino acid).     

A facile method to prepare C-terminal fluorescently labelled peptides by an Fmoc strategy

Summary Spectrophotometric peptide probes, derivatized at the C-terminus, are conveniently prepared by means of an Fmoc solid-phase strategy. Using a resin such as Sasrin, the fully protected peptide can be cleaved from the resin with hydrazine, yielding the protected peptide-hydrazide which is subsequently oxidized to the azide. An amino-containing chromophore or fluorophore such as 5-[(2-aminoethyl)-amino]-naphthalene sulfonic acid (EDANS) can be coupled directly to this activated carboxyl group. This allows for specific placement of the fluorophore at the C-terminal carboxyl group in the presence of trifunctional amino acids.     

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.     

Improvement of oxygen-carrying properties of human hemoglobin by chemical modification with a benzene hexacarboxylate-monosubstituted polyoxyethylene

Benzene hexacarboxylate-monosubstituted polyoxyethylene on contact with Hb decreases its oxygen affinity, probably because it specifically interacts with the amino groups of the phosphate-binding site. This site specificity was used to direct the covalent coupling of this polymeric reagent with hemoglobin, in the vicinity of this cleft in order to obtain conjugates with low oxygen affinity and well-defined molecular weight. Such conjugates could thus be regarded as potential candidates for blood substitutes. Covalent fixation of this polymeric site-labeling reagent onto hemoglobin was carried out with the oxy and the deoxy form in the presence of a water soluble carbodiimide. It turns out that the oxygen-binding properties of the resulting hemoglobin derivatives depend on the reaction conditions, yet in all cases the oxygen affinity of the modified protein was lower than that of native hemoglobin and was no longer affected by organic phosphates. These results indicate that phosphate-binding site amines are probably involved in the covalent coupling, although in some conjugates (especially those prepared with high ratios of reagents) other amino groups participate also in the linking to the polymer. Chromatographic analysis and trypic peptide mapping of some conjugates evidenced that the -terminal valine residue was in fact the preferential binding site of hexacarboxylate-monosubstituted polyoxyethylene.     

I. Photoaffinity probes provide a general method to prepare synthetic peptide-conjugates

A general synthetic strategy is described for the preparation of peptide-conjugates where the peptides contain the NH₂ terminal, COOH terminal, or internal regions of the protein sequence. Glycoprotein D of herpes simplex virus type 1 is used as a representative protein. Ten-residue peptide fragments of the native sequence were synthesized using standard solid-phase methodology. Photoprobes stable to conditions of synthesis and HF cleavage were coupled directly to the protected-peptide resin during synthesis. This one-step procedure eliminates the potential modification of functional groups in the sequence of interest that can occur when using chemically labile bifunctional reagents. Since the photoprobe is inert until photolysis, the synthetic peptide-probe can be readily purified by high-performance liquid chromatography before cross-linking to the carrier molecule. The following photoprobe derivatives were investigated: thep-azidobenzoyl,p-nitrophenylalanyl, andp-benzoylbenzoyl groups. The benzophenone photoprobes were shown to give the highest incorporation of peptide-probe with the protein carrier over a wide range ofpH and solvent conditions. For solid-phase synthesis three benzophenone photoprobes can be used: benzoylbenzoic acid, benzoylbenzoylglycine, andN ^e-(4-benzoylbenzoyl)-N -t-butyloxycarbonyl-lysine.     

Intracellular fate and nuclear targeting of plasmid DNA

One of the major steps limiting nonviral gene transfer efficiency is the entry of plasmid DNA from the cytoplasm into the nucleus of the transfected cells. The nuclear localization signal (NLS) of the SV40 large T antigen is known to efficiently induce nuclear targeting of proteins. We have developed two chemical strategies for covalent coupling of NLS peptides to plasmid DNA. One method involves a site-specific labeling of plasmid DNA by formation of a triple helix with an oligonucleotide–NLS peptide conjugate. After such modification with one NLS peptide per plasmid molecule, plasmid DNA remained fully active in cationic lipid-mediated transfection. In the other method, we randomly coupled 5–115 p-azidotetrafluorobenzyllissamine–NLS peptide molecules per plasmid DNA by photoactivation. Oligonucleotide–NLS and plasmid–lissamine–NLS conjugates interacted specifically with the NLS-receptor importin . Plasmid–lissamine–NLS conjugates were not detected in the nucleus, after cytoplasmic microinjection. Plasmids did not diffuse from the site of injection and plasmid–lissamine–NLS conjugates appeared to be progressively degraded in the cytoplasm. The process of plasmid DNA sequestration/degradation stressed in this study might be as important in limiting the efficiency of nonviral gene transfer as the generally recognized entry step of plasmid DNA from the cytoplasm into the nucleus     

Hemoglobin-dialdehyde dextran conjugates: Improvement of their oxygen-binding properties with anionic groups

We studied the conjugates formed between hemoglobin and sulfated or unsulfated oxidized dextran. It appears that the presence of sulfated groups favors imino bond formation between the protein and the polymer, as the average molecular size of the conjugates is larger in this case. Under neutral conditions, the oxygen-binding properties of the conjugates depend on the presence or absence of oxygen during the coupling reaction. With unsulfated dextran, oxyhemoglobin leads to conjugates with increased oxygen affinity (P ₅₀/P ₅₀ native hemoglobin 0.5) compared to that of free hemoglobin (P ₅₀=4 mm Hg), whereas deoxyhemoglobin leads to conjugates with decreased oxygen affinity (P ₅₀/P ₅₀ native hemoglobin 3). The use of sulfated dextran reinforces this lowering in oxygen affinity, which indicates that sulfated dextran acts as a permanent macromolecular effector of hemoglobin (P ₅₀/P ₅₀ native hemoglobin 4). Moreover, it can be assumed that some of the linkages involve the 2,3-diphosphoglycerate binding site, as the strong effector inositol hexaphosphate has only a slight effect on the oxygen-binding properties of the conjugate prepared in the deoxy state (P ₅₀/P ₅₀ native hemoglobin close to 4.4 and 6, respectively, for unsulfated and sulfated conjugates). Although dextran substituted with benzenehexacarboxylic acid (BHC) leads to a low-oxygen-affinity conjugate when linked to oxyhemoglobin through amide bonds (P ₅₀/P ₅₀ native hemoglobin 5), oxidized dextran modified with BHC leads, with oxyhemoglobin, to a conjugate whose oxygen affinity is close to that of free hemoglobin (P ₅₀/P ₅₀ native hemoglobin 1.2).     

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.     

Side reactions in the synthesis of phosphotyrosine-containing peptides

Summary A series of phosphopeptides Tyr(PO₃H₂)-Val-Pro-Xxx-Leu (Xxx=Met, Met(O), Nle, Dab or Cys), derived from the native platelet-derived growth factor- receptor (PDGF-) sequence, has been prepared to study their interaction with the src-homology 2 (SH2) domains of the p85 subunit of PI3 kinase. The phosphopeptides were synthesized using Fmoc methodology incorporating N-Boc dibenzyl-protected phosphotyrosine (Boc-Tyr[PO₃(Bzl)₂]) as the N-terminal amino acid, since the benzyl groups can be removed during resin cleavage with TFA. Only peptides containing methionine were found to exist partially as S-benzyl sulfonium salts after TFA cleavage from the resin. The desired peptide could be obtained from the S-benzyl sulfonium salt by hydrogenolysis.     

Studies Towards the Synthesis of Peptide-Oligonucleotide Conjugates

Abstract

We describe a peptide fragment, solid-phase coupling strategy for synthesis of peptide-oligonucleotide conjugates. Model conjugates contained a hydrophobic tetrapeptide, a hydrophobic influenza virus fusion nonapeptide, or a basic octapeptide of the HIV-1 Tat protein coupled to either dT₁₂ or a 16-mer anti-Tat oligodeoxyribonucleotide. Conjugation yields were improved by removal of internucleotide 2-cyanoethyl groups prior to peptide coupling and by use of a C12 spacer between peptide and oligonucleotide.     

Utilization of some non coded amino acids as isosters of peptide building blocks

Summary In our study on non coded amino acids and their utilization in peptide chemistry we synthesized methylene-thio (CH₂—S) and methyleneoxy (CH₂—O) group containing amino acids and pseudodipeptides which could be used as building blocks for the construction of peptide hormone analogues. The (CH₂—S) isoster of peptide bond exhibits increased flexibility, lipophility and resistance to proteolytic enzymes. This group exhibits similar properties as the isosteric disulfide bond in the side chain of cystine residue. The (CH₂—O) isoster is moreover similar in its geometry to extended conformation of peptide bond. As a consequence, the changed profile of biological activities could be expected for peptide hormone analogues containing such isosteric moiety. The (CH₂—S) isosters of the peptide bond were prepared by alkylation of thiolates of 2-mercaptocarboxylic acids, the disulfide bond by alkylation of cysteine or homocysteine. The (CH₂—O) isosters were prepared by (AcO)₄Rh₂ catalyzed addition of carbenes of alkyl diazocarboxylates to N-protected aminoalcohols. Pseudodipeptides H—Leu—(CH₂—S)—Gly—NH₂ and H—Leu—(CH₂—O)—Gly—NH₂ were introduced into the C-terminal part of the oxytocin molecule using solution methods of peptide chemistry. Both inserted isosteric bonds were resistant against proteolytic degradation, the first one was found to decrease an enzymic cleavage of the distant Tyr²-Ile³ bond in the corresponding analogue, too. The (CH₂—S) isosters of the disulfide bond containing an orthogonal protection of their-amino (Fmoc) and-(OAll, OH) or-(OBu⁺, OH) carboxylic groups were applied in the solid phase synthesis of the aminoterminal 1-deamino-15-pentadecapeptide of endothelin-I which represents a strong vasoactive agent. The solid phase synthesis was carried out by the step-wise protocol on the Rink or Merrifield type resin using orthogonally protected carba cystine building blocks.     

Interaction of apolipoprotein[a] with apolipoproteinB-100 Cys3734 region in lipoprotein[a] is confirmed immunochemically

Monospecific polyclonal antibodies (MPAbs) to apoB-100 regions Cys3734 and Cys4190 were isolated by affinity chromatography using the synthetic polypeptides, Q₃₇₃₀VPSSKLDFREIQIYKK₃₇₄₆ and G₄₁₈₂IYTREELSTMFIREVG₄₁₉₈, respectively, coupled to a hydrophilic resin. Molecular modeling and fluroescence labeling studies have suggested that Cys67 located in kringle type 9 (LPaK9, located between residues 3991 and 4068 of the apo[a] sequence inferred by cDNA) of the apo[a] molecule is disulfide linked to Cys3734 of apoB-100 in human lipoprotein[a] (Lp[a]). This possibility has been further explored with MPAbs. Four species of MPAbs directed to a Cys3734 region of apoB-100 (3730–3746) were isolated from goat anti-human LDL serum by a combination of synthetic peptide (Q₃₇₃₀VPSSKLDFREIQIYKK₃₇₄₆) affinity chromatography and preparative electrophoresis (electrochromatography). MPAbs to the Cys4190 region of apoB-100, a second or alternative disulfide link-site between apo[a] and apoB-100, were also isolated using a synthetic peptide (G₄₁₈₂IYTREELSTMFIREVG₄₁₉₈) affinity resin. Results of immunoassays showed that binding of these four MPAbs to Lp[a] was significantly lower than to LDL. In contrast, MPAbs to the apoB-100 region 4182–4198 which contains Cys4190, a second or alternative disulfide link-site between apo[a] and apoB-100, displayed a less significant difference in binding to Lp[a] and LDL. These results provide additional evidence that the residues 3730–3746 of apoB-100 interact significantly with apo[a] in Lp[a], and that Cys3734 is a likely site for the disulfide bond connecting apo[a] and apoB-100.Abbreviations amino acids single letter, e.g., alanine, A, etc. - BSA bovine serum albumin - d density (g/ml) - aca -aminocaproic acid - ELISA enzyme-linked immunosorbant assay - DTT dithiothreitol - HRP horseradish peroxidase - MAb monoclonal antibody - MPAb monospecific polyclonal antibody - PAGE polyacrylamide gel electrophoresis - PMSF phenylmethylsulfonyl fluoride - SDS sodium dodecyl sulfate - Na₂EDTA sodium ethylenediaminetetraacetate - NaN₃ sodium azide - TRIS (hydroxymethyl)aminomethane     

Properties of Bioconjugates of Streptokinase with Anionic Polyamidoamine Dendrimers of Various Generations

Covalent conjugates of streptokinase (SK) with polyamidoamine (PAMAM) dendrimers G1.5, G2.5, and G3.5 (SK–G1.5, SK–G2.5, and SK–G3.5) with the protein–polymer molar ratios of (1: 1), (1: 5), and (1: 10) were obtained and their properties were studied as compared to the properties of free SK. It was shown that the initial rates of formation of the modified Pm. SK complex, activation of plasminogen, and lysis of the plasma clot under the action of SK–dendrimer conjugates decreased with increasing number of bound dendrimers (from 1 to 10) and increased with increasing dendrimer generation (from G1.5 up to G3.5). Conjugates SK–G3.5 (1: 1) and (1: 5) were the most active compared to other conjugates. It was found that the catalytic efficiency of plasminogen activation (k_Pg/K_Pg) by conjugates SK–G3.5 (1: 1) (0.15 μM^–1 min^–1) and SK–G3.5 (1: 5) (0.12 μM^–1 min^–1) was comparable to the efficiency of free SK (0.18 μM^–1 min^–1). Probably, small in size, soft, and easily deformable dendrimers G1.5 and G2.5 are able to penetrate into the internal shielded cavities of the native SK molecule and there modify amino groups that are important for the effective formation of the Pm · SK complex. By contrast, the larger and more rigid molecule of dendrimer G3.5 modifies, mainly, exposed lysine residues in the SK molecule, without affecting the latent internal lysines. Conjugates SK–G3.5 (1: 1) and (1: 5), which had the maximum activator activity, retained up to 85% of thrombolytic activity compared to the activity of free SK. In addition, due to modification of the exposed lysines—most sensitive to proteolysis in the SK molecule—with dendrimer G3.5, which has the highest density of negative charge on its surface, SK–G3.5 (1: 1) and (1: 5) conjugates were more stable in plasma and caused less exhaustion of plasma levels of plasminogen, α2-antiplasmin, and fibrinogen than free SK in vitro. Thus, thrombolytic activity of the SK–dendrimer conjugates depends on the degree of modification of the amino groups of SK, size, stiffness, and density of the negative charge on the surface of the PAMAM dendrimer. Conjugates SK–G3.5 (1: 1) and (1: 5) are potential candidates for the development of a new thrombolytic agent.     

Superpotency and superaffinity phenomena in the stimulation of steroidogenesis in adrenocortical cells by adrenocorticotropin-tobacco mosaic virus conjugates

Summary Adrenocorticotropin-(1-24)-tetracosapeptide was covalently attached to tobacco mosaic virus in two different manners: (i) through a handle near the C-terminus on tyrosine-(23) and (ii) through a handle at the N-terminus on serine-(1). Compounds of type (i) with their N-terminal message sequence freely exposed on the virion surface were considerably more potent for stimulating steroidogenesis in isolated adrenocortical cells than those of type (ii) with a more congested message. Conjugates with 50 or less hormone molecules per virion were less potent per peptide unit than the free handle-substituted hormones, whereas conjugates with 150 ACTH units exhibited superpotency effects. Superpotency disappeared when the substituted virions were disaggregated into (substituted) capsomers, suggesting influences of hormone clustering and virion geometry on biological activity. Superpotent stimulation was irreversible under conditions that immediately inhibited steroidogenesis by ACTH (dilution, addition of a peptide antagonist). Thus, superpotency might be caused by superaffinity arising from a slow rate of dissociation of the conjugates from the target cell receptors. The reason for the slow dissociation rate is still unclear: possible explanations include cooperative affinity, rapid internalization of the conjugate-receptor complexes, or decreased rates of peptide degradation at the receptor site.Abbreviations ACTH_1–39 adrenocorticotropin-(1–39)-nonatriacontapeptide - ACTH_1–24 adrenocorticotropin-(1–24)-tetracosapeptide - ACTH_6–24 adrenocorticotropin-(6–24)-nonadecapeptide - TMV tobacco mosaic virus wild strain To whom reprints should be addressed.     

Helical formation of a 13-residue C-peptide analogue of ribonuclease A in sodium dodecyl sulfate solution

The conformation of a 13-residue C-peptide analogue of ribonuclease A——in surfactant solutions was studied by CD. The CD spectrum of the peptide in excess NaDodSO₄ solution was typical for a helical conformation; the spectrum appeared to be virtually independent of pH (2.5–6) and temperature (3–25°C). Analysis of the CD data indicated a helicity of about 65–70% with no α-sheet and β-turn; this corresponded to 8 or 9 residues in the helical form or slightly more than two turns of α-helix. This compares with an average of about one turn of α-helix for the C-peptide analogue in water at pH 4.7 and 7°C. The conformation of the peptide in cationic surfactant, dodecyl ammonium chloride, and nonionic surfactant, dodecyl heptaoxyethylene ether, solution resembled that in water. We concluded that the C-peptide analogue can develop a maximum helicity close to the corresponding segment in ribonuclease A in hydrophobic environment provided by the clustering of NaDodSO₄ molecules to the cationic side groups of the peptide, except that the end effects may destabilize two or three residues each at both ends of the helix. Thus, in the interior of a protein molecule this hydrophobic effect may overshadow the charged-group effect than can be explained by the helix dipole model for the helical segments on the exterior of the protein molecule.     

Tolerance induction in mice by conjugates of monoclonal immunoglobulins and monomethoxypolyethylene glycol. Transfer of tolerance by T cells and by T cell extracts

The specific tolerance induced in mice by conjugates of human monoclonal IgG (HIgG) with monomethoxypolyethylene glycol (mPEG) was transferred to normal mice by spleen cells or a surface immunoglobulin negative (sIg-) Lyt-2+ subpopulation of these cells. Although transferable tolerance was demonstrable 6 to 14 days after treatment of the cell donors with tolerogen, the state of tolerance persisted in the treated mice for at least 43 days. Moreover, an extract prepared by freezing and thawing of the sIg- spleen cells obtained from mice 6 days after treatment with HIgG(mPEG)20 was capable of reducing (greater than 85%) the immune response of normal mice to heat aggregated HIgG. On the basis of these results, it is suggested that similar tolerogenic mPEG derivatives of xenogeneic monoclonal immunoglobulins (XIg) may prove to be useful therapeutic agents in man when administered before treatment with the unmodified XIg.     

Cobalt(III)-induced hexamerization of PEGylated insulin

Insulin conjugates in which the B1Phe residue has been chemically modified often exhibit a reduced tendency to associate into hexamers due to weakened interactions between subunits. The purpose of this study was to prepare a hexamer formulation for such insulin conjugates by using Co(III) as a coordinating metal ion. PEGylated insulin in which monomethoxypoly(ethylene glycol) (mPEG, M_r 5000 or 20,000) had been site-specifically attached to B1Phe was chosen as a model conjugate. Hexamerization of mPEG-insulin upon H₂O₂-mediated oxidation of Co(II) was kinetically and quantitatively analysed by visible spectrometry and size-exclusion HPLC. Co(III) mPEG-insulin hexamers thus obtained were extremely stable, existing mostly as a hexameric form even at nanomolar concentrations. A remarkable increase in hydrodynamic volumes was observed for Co(III) mPEG(20k)-insulin hexamers (1600 kDa), as well as Co(III) mPEG(5k)-insulin hexamers (300 kDa). Our results demonstrate the potential benefits of Co(III) hexamer formulation for weakly associating insulin conjugates in the treatment of diabetes.