Dihydroxypropylation of amino groups of proteins: use of glyceraldehyde as a reversible agent for reductive alkylation

The mode of derivatization of amino groups of proteins by glyceraldehyde, an aldotriose, depends on the presence or absence of reducing agent. In the presence of sodium cyanoborohydride, the Schiff base adducts of the aldehyde with the amino groups are reduced, and dihydroxypropylation of amino groups takes place (reductive mode). The reductively glycated lysine residue, N epsilon-(2,3-dihydroxypropyl)lysine, is a substituted alpha-amino alcohol. This alpha-amino alcoholic function of the derivatized lysine should be susceptible to periodate oxidation, and this oxidation is anticipated to result in the regeneration of the lysine residue. This aspect has been now investigated. Indeed, on mild periodate oxidation (15 mM periodate, 15 min at room temperature) of dihydroxypropylated ribonuclease A, nearly 95% of its N epsilon-(2,3-dihydroxypropyl)lysine residues were regenerated to lysine residues. The removal of the dihydroxypropyl groups by periodate oxidation could be accomplished within a wide pH range with little variation in the recovery of lysines. The possible usefulness of this reversible chemical modification procedure in the primary structural studies of proteins was investigated with a tryptic peptide of dihydroxypropylated streptococcal M5 protein, namely, DHP-T4. This 12-residue tryptic peptide contains one internal N epsilon-(dihydroxypropyl)lysine. The dihydroxypropylated peptide released most of its dihydroxypropyl groups on mild periodate oxidation. Redigestion of the periodate-treated peptide with trypsin generated the two expected peptides, demonstrating the generation of a trypsin-susceptible site. Reductive dihydroxypropylation of amino groups of RNase A resulted in the loss of its enzyme activity, the extent of inactivation increasing with the concentration of the glyceraldehyde used.(ABSTRACT TRUNCATED AT 250 WORDS)     

A chemical approach for the localization of membrane sites involved in lymphocyte activation.

The aldehyde groups formed on periodate oxidation of cell surface sialyl residues were used to insert a mitogenic site onto the lymphocyte membrane by attachment of biotin hydrazide or 2,4-dinitrophenyl hydrazine. The biotin- or 2,4-dinitrophenyl-conjugated cells were both agglutinated and stimulated when cultured with avidin or anti-2,4-dinitrophenyl antibody respectively. On the other hand, biotin or DNP-conjugated cells, modified via functional groups on the membrane proteins, were agglutinated but not stimulated when cultured with avidin or anti-DNP antibody respectively. Our results show that the specific interaction of a protein at the periodate oxidation site leads to blastogenesis.     

Capture of peptides with N-terminal serine and threonine: a sequence-specific chemical method for Peptide mixture simplification

The objective of this study was to evaluate a sequence-specific chemistry for the ability to specifically capture peptides that contain N-terminal serine or threonine residues from mixtures. The first step is the oxidation of the 1,2-amino alcohol structure -CH(NH(2))CH(OH)- of peptides containing N-terminal serine or threonine with periodate. The newly formed aldehyde reacts with a labeling reagent containing a hydrazide, RCONHNH(2), to form a hydrazone-peptide conjugate, RCONHN=CH-peptide. Biotin-labeled conjugates can then be isolated by affinity purification with streptavidin. The method described in this report can be useful in simplifying the complex mixtures of peptides that are generated in typical proteomic analysis, where proteins are digested with trypsin and analyzed using liquid chromatography mass spectrometry data. The sequence-specific peptide selection not only reduces the complexity of digest mixtures, but also provides additional information for peptide identification. The targeted peptides are those that have either serine or threonine adjacent to a protease cleavage site. The sequence information should greatly aid in both database matching for protein identification and for de novo sequence determination.     

Covalent attachment of immunoglobulins to liposomes via glycosphingolipids

We describe a method for covalent binding of proteins to large unilamellar liposomes which involves the periodate oxidation of glycosphingolipids in the vesicle membrane. Proteins such as IgG and F(ab′)₂ may then be attached to the aldehyde groups on the glycolipid by Schiff-base formation at pH 9.5 and reduction with NaBH₄, or by reductive amination with NaBH₃CN at pH 8.4. Exposure of the vesicles to periodate, protein coupling and separation from unbound protein by a novel method of flotation in discontinuous dextran gradients does not release the vesicle contents when performed at pH 8.4. Studies on the oxidation of neutral glycolipid-containing vesicles, and on the oxidation of encapsulated glycerol 1-phosphate show that periodate influx into neutral vesicles during a 4 h exposure is appreciable at pH 5.5 but not at pH 8.4. Under optimal conditions, approx. 20% of the protein may be coupled to vesicles, and a ratio of 100–200 μg of protein/μmol of lipid is readily achieved. This method will be of great importance for the antibody-mediated targeting of vesicles to cells.     

The identity of a cyanogen bromide fragment of bovine dentin collagen containing the site of an intermolecular cross-link.

A peptide fraction isolated from a cyanogen bromide digest of bovine dentin collagen had a molecular weight of 46000. Its size and amino acid composition indicated that it could not consist of peptides derived from the cleavage of a single alpha chain. On reduction with tritiated sodium borohydride, radioactivity was incorporated primarily into 5, 5'-dihydroxylysinonorleucine without degradation at the peptide backbone. Periodate cleavage of the reduced or nonreduced peptide fraction generated one fragment of molecular weight 28000 and one of 18000 completely accounting for the size of the parent peptide. On amino acid analysis the constituent single-chain peptides were determined to be alpha2CB4 and alpha1CB6. Both peptides isolated after periodate oxidation of the tritiated borohydride reduced cross-link peptide were found to contain (3H)hydroxynorvaline. These data show that some hydroxylysine of alpha2CB4, a helical region peptide, was present in aldehyde form and could act as the aldehyde donor icross-link, Schiff's base formation. The only cross-linkage of this alpha2CB4 acting as an aldehyde donor peptide to alpha1CB6 would be a helical region to helical region bond, perhaps accounting for the unusual stability and low solubility of dentin collagen.     

Reversible modification of arginine residues. Application to sequence studies by restriction of tryptic hydrolysis to lysine residues.

1, 2-Cyclohexanedione reacts specifically with the guanidino group of arginine or arginine residues at pH 8 to 9 in sodium borate buffer in the temperature range of 25-40 degrees. The single product, N-7, N-8-(1,2-dihydroxycyclohex-1,2-ylene)-L-arginine (DHCH-arginine) is stable in acidic solutions and in borate buffers (pH 8 to 9). DHCH-Arginine is converted to N-7-adipyl-L-arginine by periodate oxidation. The structures of the two compounds were elucidated by chemical and physicochemical means. Arginine or arginyl residues can be regenerated quantitatively from DHCH-arginine by incubation at 37 degrees in hydroxylamine buffer at pH 7.0 FOR 7 TO 8 hours. Analysis of native egg white lysozyme and native as well as oxidized bovine pancreatic RNase, which were treated with cyclohexanedione, showed that only arginine residues were modified. The utility of the method in sequence studies was shown on oxidized bovine pancreatic ribonuclease A. Arginine modification was complete in 2 hours at 35 degrees in borate buffer at pH 9.0 with a 15-fold molar excess of the reagent. The derived peptides showed that tryptic hydrolysis was entirely limited to peptide bonds involving lysine residues, as shown both by two-dimensional peptide patterns and by isolation of the resulting peptides. The stability of DHCH-arginyl residues permits isolation of labeled peptides.     

Selective 'in synthesis' labeling of peptides with biotin and rhodamine

A new method is described for the selective 'in synthesis' labeling of peptides by rhodamine or biotin at a single, predetermined epsilon-amino group of a lysine residue. The alpha-amino group and other lysyl residues of the peptide remain unmodified. Peptides are assembled by the Fmoc approach, which requires mild operative conditions for the final deprotection and cleavage, and ensures little damage of the reporter group. The labeling technique involves the previous preparation of a suitable Lysine derivative, easily obtained from commercially-available protected amino acids. This new derivative, where the reporter group (biotin, or rhodamine) acts now as permanent protection of lysyl side chain functions, is then inserted into the synthesis program as a conventional protected amino acid, and linked to the preceding residue by aid of carbodiimide. A simpler, alternative method is also described for the selective 'in synthesis' labeling of peptides with N-terminal lysyl residues. Several applications of labeled peptides are reported.     

Use of thiazolidine-mediated ligation for site specific biotinylation of mouse EGF for biosensor immobilisation

Summary Biosensors provide a sophisticated and discriminating means of probing biomolecular interactions. Specific ligands such as peptides and proteins can be immobilized onto sensor surfaces by a number of means including covalent attachment via amine, thiol or aldehyde chemistry, capture via biotin-avidin interaction or the use of specific tags. We have devised a simple chemoselective ligation method to selectively conjugate an anchoring functionality onto N-terminal serine or threonine residues of peptides and proteins allowing them to be immobilised onto the sensor surface in a defined orientation. It is based on the specific reaction of the 1,2-aminothiol of cysteine with an aldehyde under acidic conditions to form a stable thiazolidine product. The carbonyl precursors are derived from the 1,2-aminoalcohols of Ser or Thr that can be selectively and rapidly converted to the aldehyde form by periodate oxidation. Biotinylation of the aldehyde is then achieved via simple conjugation with a novel water-soluble dipeptide that contains a lysine residue bearing an Nε-cysteine-derived 1,2-aminothiol and an Nα-biotin moiety. Use of this method allowed selective biotinylation of a native form of murine EGF (mEGF_2-53) that has an N-terminal serine residue. This derivative was then immobilised onto a streptavidin biosensor surface, and the resultant surface activity compared with those obtained by immobilising recombinant human EGF or the soluble extracellular domain of the EGF receptor (sEGFR_1-621) using amine coupling (NHS/EDC) chemistry. The surface recognised the recombinant sEGFR with a similar K _D to that of human EGF immobilised using NHS/EDC chemistry, or if the receptor was immobilised and murine EGF injected.     

New cyclization reaction at the amino terminus of peptides and proteins

Mild oxidation with periodate of the 1-amino-2-ol moiety of N-terminal seryl or threonyl peptides and proteins leads to a terminal aldehyde function O=CH-CO- which usually may be exploited for bioconjugate formation (e.g., via oximation with an O-alkyl hydroxylamine). We report that, when followed by a prolyl residue, the O=CH-CO- group can undergo a rapid cyclization and dehydration reaction through nucleophilic attack by the amide nitrogen of the third amino acid residue of the chain. We have characterized the resulting heterocycle, which is stable in aqueous acid, by mass spectrometry and NMR. Quantitative oximation can nevertheless be achieved in such cases by performing a one-pot oxidation-oximation without isolation of the intermediate aldehyde, as is demonstrated with cholera toxin B subunit.     

Aldehyde modification of peptide immunogen enhances protein-reactive antibody response to toxic shock syndrome toxin-1.

Introduction of aldehyde groups into protein conjugates enhanced the immune response to a coupled peptide without the use of strong adjuvants. Synthetic peptides representing the N-terminal (residues 1-16) and internal (residues 53-65) epitopes of toxic shock syndrome toxin-1 (TSST-1) were coupled to carrier protein, and carbonyl tags were introduced by Amadori reaction with glycolaldehyde. Modified and unmodified antigens in alum were used to immunize rabbits and the reactivities of antisera were compared. Aldehyde modification augmented the response detected by ELISA, which included enhanced binding to peptides and to native TSST-1. In western blot, TSST-1 was detected by antiserum elicited to the N-terminal peptide, but not that generated to the peptide representing the internal sequence. The same antiserum also neutralized TSST-1 activity in a lymphocyte proliferation assay. The circular dichroism spectrum of the N-terminal peptide indicated a propensity for helical conformation, similar to the structure at the corresponding sequence of the native protein. These data suggest that aldehyde modification can boost immunogenicity of peptide-based vaccines, generating epitope-specific immune responses against the cognate protein antigens without using potent adjuvants.     

Use of thiazolidine-mediated ligation for site specific biotinylation of mouse EGF for biosensor immobilisation

Biosensors provide a sophisticated and discriminating means of probing biomolecular interactions. Specific ligands such as peptides and proteins can be immobilized onto sensor surfaces by a number of means including covalent attachment via amine, thiol or aldehyde chemistry, capture via biotin-avidin interaction or the use of specific tags. We have devised a simple chemoselective ligation method to selectively conjugate an anchoring functionality onto N-terminal serine or threonine residues of peptides and proteins allowing them to be immobilised onto the sensor surface in a defined orientation. It is based on the specific reaction of the 1,2-aminothiol of cysteine with an aldehyde under acidic conditions to form a stable thiazolidine product. The carbonyl precursors are derived from the 1,2-aminoalcohols of Ser or Thr that can be selectively and rapidly converted to the aldehyde form by periodate oxidation. Biotinylation of the aldehyde is then achieved via simple conjugation with a novel water-soluble dipeptide that contains a lysine residue bearing an N-cysteine-derived 1,2-aminothiol and an N-biotin moiety. Use of this method allowed selective biotinylation of a native form of murine EGF (mEGF_2-53) that has an N-terminal serine residue. This derivative was then immobilised onto a streptavidin biosensor surface, and the resultant surface activity compared with those obtained by immobilising recombinant human EGF or the soluble extracellular domain of the EGF receptor (sEGFR_1-621) using amine coupling (NHS/EDC) chemistry.The surface recognised the recombinant sEGFR with a similar K_D to that of human EGF immobilised using NHS/EDC chemistry, or if the receptor was immobilised and murine EGF injected.     

Biochemical and Biological Characterization of a New Oxidized Avidin with Enhanced Tissue Binding Properties

Chicken avidin and bacterial streptavidin are widely employed in vitro for their capacity to bind biotin, but their pharmacokinetics and immunological properties are not always optimal, thereby limiting their use in medical treatments. Here we investigate the biochemical and biological properties of a new modified avidin, obtained by ligand-assisted sodium periodate oxidation of avidin. This method allows protection of biotin-binding sites of avidin from inactivation caused by the oxidation step and delay of avidin clearance from injected tissue by generation of aldehyde groups from avidin carbohydrate moieties. Oxidized avidin shows spectroscopic properties similar to that of native avidin, indicating that tryptophan residues are spared from oxidation damage. In strict agreement with these results, circular dichroism and isothermal titration calorimetry analyses confirm that the ligand-assisted oxidation preserves the avidin protein structure and its biotin binding capacity. In vitro cell binding and in vivo tissue residence experiments demonstrate that aldehyde groups provide oxidized avidin the property to bind cellular and interstitial protein amino groups through Schiff''s base formation, resulting in a tissue half-life of 2 weeks, compared with 2 h of native avidin. In addition, the efficient uptake of the intravenously injected ¹¹¹In-BiotinDOTA (ST2210) in the site previously treated with modified avidin underlines that tissue-bound oxidized avidin retains its biotin binding capacity in vivo. The results presented here indicate that oxidized avidin could be employed to create a stable artificial receptor in diseased tissues for the targeting of biotinylated therapeutics.     

A new amino acid derivative with a masked side-chain aldehyde and its use in peptide synthesis and chemoselective ligation.

A new amino acid derivative with a diol side-chain, L-2-amino-4,5-dihydroxy-pentanoic acid (Adi), has been prepared from L-allylglycine by suitable protection, for use in peptide synthesis, as Fmoc-L-Adi(Trt)2. This building block enables the introduction of a side-chain aldehyde at any position in a given peptide sequence without use of specialized side-chain protection schemes. The aldehyde is revealed by mild oxidation with sodium periodate, circumventing the problematic release of reactive peptidic aldehydes in TFA solution. Peptides with aldehyde side-chains are useful for chemo-selective ligation, reacting selectively with oxyamines to yield oxime links, while all other peptide functions can be left unprotected. The utility of the new building block has been demonstrated by the synthesis of peptide dimers and a cyclo-peptide.     

Protein/polysaccharide cogel formation based on gelatin and chemically modified schizophyllan

In the work, aldehyde groups were quantitatively introduced into schizophyllan (SPG) side chains through periodate oxidation. The periodate-oxidized SPG (POSPG) forms an elastic gel with gelatin. The cogel formation is based on the Schiff-base reaction between the amino groups of gelatin chains and the aldehyde groups of POSPG chains. The POSPG/gelatin cogel has an elastomeric character with a very small value of loss tangent. The gelation kinetics and gel properties were discussed as a function of POSPG concentration, gelatin concentration, oxidation degree, temperature, and pH. This method can be used to design a large variety of cogels between SPG and proteins.     

C n.m.r. study of the pH behaviour of N-methylated peptides related to the N-terminus of glycophorins

¹³C nuclear magnetic resonance spectroscopy (¹³C n.m.r.) was used to determine the pH titration parameters for the N-terminal N,N-[¹³C]dimethylamino and N,N-[¹³C]monomethylamino groups of glycophorins A^M and A^N, and some 28 related glycoproteins, glycopeptides and peptides. The results show that glycosylation of the Ser and Thr residues at positions 2, 3 and 4 of the glycophorins have a pronounced effect on the titration parameters. Substitution of amino acids 4 and 5 in the glycophorin sequence appears to minimally affect our titration parameters. Internal hydrogen-bonding involving the N-terminal Ser residue may explain some of the unusual pH titration results observed for glycophorin A^M.     

Surface aggregation and membrane penetration by peptides: relation to pore formation and fusion

The peptide GALA undergoes a conformational change to an amphipathic alpha -helix when the pH is reduced, inducing leakage of contents from vesicles. Leakage from neutral or negativelycharged vesicles at pH 5.0 was similar and could be adequately explained by a mathematical model which assumed that GALA becomes incorporated into the vesicle bilayer and irreversibly aggregates to form a pore consisting of M =10+/-2 peptides. Increasing cholesterol content in the membranes resulted in reduced leakage, and increased reversibility of surface aggregation of the peptide. Employing fluorescently labelled peptides confirmed that the degree of reversibility of surface aggregation of GALA was significantly larger in cholesterol containing liposomes. Orientation of the peptide GALA in bilayers was determined by a bodipy-avidin/ biotin binding assay. The peptide was labelled by biotin at the N- or Cterminus and bodipy-avidin molecules were added externally or were preencapsulated in the vesicles. The peptides are arranged in the pore perpendicularly to the membrane, such that 3/4 of the N-termini are on the internal side of the membrane. The pores are stable and persist for at least 10 min. When the peptides form an aggregate of size smaller than M, the orientation of the peptide is mostly parallel to the surface and the biotinylated peptide does not translocate. When a critical size of the aggregate is attained, a rearrangement of the peptide occurs, which amounts to rapid penetration and formation of a pore structure. Induction of fusion by peptides may be antagonistic to pore formation, the outcome being dependent on vesicle aggregation.     

Semisynthesis of human ghrelin: condensation of a Boc-protected recombinant peptide with a synthetic O-acylated fragment

The creation of peptide using a combination of recombinant expression and chemical synthesis can be a powerful tool for the production of a wide variety of polypeptides modified by phosphorylation, glycosylation, etc. We have developed a new method for the preparation of a recombinant peptide with a free N(alpha)-amino group and protected N(epsilon)-amino groups, and have used this method in the semisynthesis of human ghrelin. Ghrelin, a natural ligand for growth hormone secretagogue receptor, is a 28-residue peptide with an essential n-octanoyl modification on Ser3. A 7-residue N-terminal fragment of ghrelin containing the octanoyl modification was prepared by Fmoc chemistry. In the preparation of it, all reactions were performed on the 2-chlorotrityl resin. Additionally, TBDMS and tBu turned out to be the most effective protection groups for the Ser3 and the Ser2, Ser6, respectively. For preparation of a 21-residue C-terminal fragment, we established a two-step protease processing method for the partially protected segment. A recombinant precursor peptide was Boc protected and subsequently cleaved using two distinct proteases, OmpT and Kex2. The peptides were then coupled to each other and, after deprotection, resulted in fully active human ghrelin.     

Biotinylated fluorescent peptide substrates for the sensitive and specific determination of cathepsin D activity.

Cathepsin D (CatD) is a member of the mammalian aspartic protease family and is involved in cellular protein degradation and in several pathological processes. A sensitive and specific assay for the determination of CatD activity in biological samples was developed. The peptide amide substrates Amca-EDKPILF downward arrowFRLGK(biotin)-CONH2 (I), Amca-EEKPIC(Acm)F downward arrowFRLGK(biotin)-CONH2 (II) and Amca-EEKPISF downward arrowFRLGK(biotin)-CONH2 (III) contain a CatD cleavage site (F downward arrowF) flanked by a N-terminal Amca-fluorophore (7-amino-4-methylcoumarin-3-acetic acid) and a C-terminal biotin moiety. Substrates II and III proved to be specific substrates containing only one cleavage site for CatD. After cleavage of the Phe-Phe bond by CatD all biotin conjugated peptides were removed with streptavidin-coated magnetic beads. The remaining fluorescent peptides in solution represent the amount of digested substrate. The versatility of this CatD digest and pull down assay was demonstrated by measuring the activity of CatD in different subcellular fractions of human EBV-transformed B cells and human monocytes. The described method based on the designed CatD substrates represents a valuable tool for routine assays.     

The oxime bond formation as an efficient chemical tool for the preparation of 3',5'-bifunctionalised oligodeoxyribonucleotides

The simultaneous conjugation of peptides or carbohydrates at the 3'- and 5'-end of oligodeoxyribonucleotides was achieved very efficiently through chemoselective oxime bond formation. The method employs bifunctionalised oligonucleotides in single step without the need of protection strategy, under mild acidic conditions. The conjugates were obtained in high yields by reacting an oxyamine containing reporter groups (peptide, mono- and disaccharide) with an oligonucleotide carrying an aldehyde at each extremity.