Protein radiohalogenation: observations on the design of N-succinimidyl ester acylation agents

In previous studies we have demonstrated that antibodies radioiodinated with N-succinimidyl 3-iodobenzoate (SIB) are less susceptible to loss of radioiodine in vivo than antibodies iodinated directly by electrophilic substitution on their tyrosine residues with Iodogen. Since the Bolton-Hunter reagent, N-succinimidyl 3-(4-hydroxy-3-iodophenyl)propionate, is identical with SIB except that it contains a hydroxyl group on the aromatic ring and a two-methylene spacer, a comparison of their coupling chemistry and in vivo behavior was performed to better understand the structural requirements for a useful iodinated acylation agent. Protein concentration and pH had a significant effect on the coupling efficiency of both SIB and the Bolton-Hunter reagent; however, protein-labeling yields with SIB were generally higher by a factor of 2. Paired-label biodistribution studies in mice demonstrated that thyroid uptake (a monitor of dehalogenation) of antibody labeled by the Bolton-Hunter method was twice that of antibody labeled with SIB but only 7% of that observed for antibody labeled with Iodogen. These results suggest that even minor differences in iodination site can profoundly alter the retention of label on a protein in vivo.     

Bright oligothiophene N-succinimidyl esters for efficient fluorescent labeling of proteins and oligonucleotides

The synthesis of multicolor fluorescent oligothiophene N-succinimidyl esters (TSEs) is reported, and their optical properties are discussed with the aid of ab initio calculations. The esters were coupled to proteins and to 3'-amino-modified oligonucleotides in mild conditions and with similar modalities. A comparative study of the bioconjugate of IgG1 anti-CD3 antibody labeled with a blue fluorescent TSE and with fluorescein isothiocyanate (FITC) is reported, showing that the former achieves higher photoluminescence intensity and optical stability than the latter. Fluorescence resonance energy transfer experiments with TSE-labeled oligonucleotides and examples of cellular imaging via TSE-labeled proteins are reported.     

A versatile procedure for the radioiodination of proteins and labeling reagents

For tracer or analytical studies it is often useful to label proteins by direct iodination or by reacting them with an iodinated reagent. A simple iodination technique with hydrogen peroxide is described for use with either carrier-free or low-specific-activity iodine. The method introduces less oxidative damage to proteins than any other procedure tested, yet the efficiency of labeling approaches that offered by the chloramine T or Iodogen methods. The method has been applied to the facile and inexpensive preparation of the iodinated Bolton-Hunter reagent. This peroxide iodination procedure should be particularly useful for labeling proteins or peptides for structural investigations or for immunoassays.     

A versatile procedure for the radioionization of proteins and labeling reagents

For tracer or analytical studies it is often useful to label proteins by direct iodination or by reacting them with an iodinated reagent. A simple iodination technique with hydrogen peroxide is described for use with either carrier-free or low-specific-activity iodine. The method introduces less oxidative damage to proteins than any other procedure tested, yet the efficiency of labeling approaches that offered by the chloramine T or Iodogen methods. The method has been applied to the facile and inexpensive preparation of the iodinated Bolton-Hunter reagent. This peroxide iodination procedure should be particularly useful for labeling proteins or peptides for structural investigations or for immunoassays.     

Radiohalogenation of proteins: an overview of radionuclides, labeling methods, and reagents for conjugate labeling.

Direct labeling of proteins with radionuclides of iodine will continue to be the method of choice to answer questions addressed in many future studies. However, it seems likely that a increasing number of applications of radiohalogenated proteins will require, or benefit from, conjugate labeling. While many radiohalogen conjugates have been studied, a large proportion of them have only undergone preliminary studies to date, leaving a question of their overall utility. Phenolic conjugates give good radioiodination labeling yields, but mixtures of radiohalogenated products and problems with in vivo stability can be expected. This fact, along with the fact that phenolic compounds do not have a general application to radiohalogens, makes them less attractive than other alternatives. Radiohalogen labeling through the use of organometallic intermediates has proven to be facile, resulting in high yields of high specific activity labeled small-molecule conjugates. Although the choice of which organometallic intermediate to use may depend somewhat on the radionuclide employed, arylstannanes appear to have the most general applicability. Fluorine-18 labeling of small-molecule conjugates has been best accomplished by ipso aromatic nucleophilic substitution (exchange) reactions. Radiohalogenated small molecules have been prepared which can be conjugated with specific functional groups (e.g. amines, sulfhydryl groups, and carbohydrates) or conjugated nonspecifically with groups in the proximity of the conjugate when it is photolyzed. On the basis of previous studies, good conjugation yields (i.e. 60-90%) can be expected for reactions with specific groups, whereas low yields (i.e. 1-5%) can be expected for conjugations with reactive nitrenes and carbenes. However, recent developments in the chemistry of conjugates that produce nitrenes and carbenes will likely improve the radiolabeling yields. There have been too few comparative studies to readily assess which is the best approach to take when beginning a study involving radiohalogenation of a protein or peptide. However, it is clear that radiohalogenated conjugates of proteins can offer an advantage over direct labeling in that conjugates may be designed which provide some control over in vivo stability and secondary distribution of metabolites. Conjugates can be prepared which are designed to utilize in vivo biochemical processes to release a radiohalogenated small molecule from a tissue (i.e. kidney or liver) or retain the radioactivity at the target tissue (e.g. tumor). Aside from the designing of conjugates with linking molecules for desired biological effects, the ultimate future goal for the radiolabeling chemical should be to prepare protein conjugates which can be radiohalogenated in a single one-step procedure.     

Synthesis of undecagold cluster molecules as biochemical labeling reagents. 2. Bromoacetyl and maleimido undecagold clusters

Derivatives of heptakis[4,4',4"-phosphinidynetris(benzenemethanamine) ]undecagold, 1, molecular formula Au11(CN)3[P(C6H4CH2NH3)]7, are described. These include undecagold complexes with a single free primary amino group, a single bromoacetyl group, and a single maleimido group per molecule. Hydrolysis of mono(N-phthalyl)icosa(N-acetyl)-1 at pH 3.2 and 46 degrees C under anaerobic conditions and in the presence of NaBH3CN produces icosa(N-acetyl)-1. Partial acylation of 1 with 1.3 equiv of 2,3-dimethylmaleic anhydride followed by complete acetylation with acetic anhydride produces a mixture consisting largely of mono- and bis(dimethylmaleyl)peracetyl-1. Hydrolysis of 2,3-dimethylmaleimides at pH 3.2 for 1 at 25 degrees C produces a mixture of icosa(N-acetyl)-1, with a single free amino group, and nondea(N-acetyl)-1. This mixture can be quantitatively separated by cation-exchange chromatography at pH 7, giving homogeneous icosa(N-acetyl)-1 in an overall yield of 55%. Icosa(N-acetyl)-1 serves as the starting material for the synthesis of the alkylating derivatives mono(N-bromoacetyl)icosa(N-acetyl)-1 and mono[N-(p-maleimidobenzoyl)]icosa(N-acetyl)-1. These derivatives can be used for alkylating proteins in preparation for electron microscopy.     

Synthesis of N-succinimidyl 4-guanidinomethyl-3-[*I]iodobenzoate: a radio-iodination agent for labeling internalizing proteins and peptides

This protocol describes a detailed procedure for the synthesis of N-succinimidyl 4-guanidinomethyl-3-[*I]iodobenzoate ([*I]SGMIB), an agent useful in the radio-iodination of proteins, including monoclonal Abs, and peptides that undergo internalization after receptor or antigen binding. In this procedure, the tin precursor N-succinimidyl 4-[N1,N2-bis(tert-butyloxycarbonyl)guanidinomethyl]-3-(trimethylstannyl)benzoate (Boc-SGMTB, 3) was first radio-iodinated to [*I]Boc-SGMIB, a derivative of [*I]SGMIB with the guanidine function protected with Boc groups. Treatment of [*I]Boc-SGMIB with trifluoroacetic acid delivered the final product. The total time for the synthesis and purification of [*I]Boc-SGMIB and its subsequent de-protection is approximately 140 min.     

Monoadduct forming photochemical reagents for labeling nucleic acids for hybridization.

We describe the synthesis of three angelicin derivatives which can be used for labeling nucleic acids with biotin. These compounds were used to label nucleic acids in the presence of lysed cell constituents. The resulting labelled nucleic acids show hybridization to a genus specific probe for E. coli. The relative comparison of sensitivity indicates that a polyamine linker is better than a polyethylene oxide linker between the biotin and angelicin moieties.     

Synthesis of N-succinimidyl 4-[18F]fluorobenzoate, an agent for labeling proteins and peptides with 18F

This protocol describes the step-by-step procedure for the synthesis of N-succinimidyl 4-[18F]fluorobenzoate ([18F]SFB), an agent widely used for labeling proteins and peptides with the positron-emitting radionuclide 18F. The protocols for the synthesis of unlabeled SFB and the quaternary salt precursor 4-formyl-N,N,N-trimethyl benzenaminium trifluoromethane sulfonate also are described. For the [18F]SFB synthesis, the quaternary salt is first converted to 4-[18F]fluorobenzaldehyde. Oxidation of the latter provides 4-[18F]fluorobenzoic acid, which is converted to [18F]SFB by treatment with N,N-disuccinimidyl carbonate. Using this method, [18F]SFB can be synthesized in decay-corrected radiochemical yields of 30%-35% and a specific radioactivity of 11-12 GBq micromol(-1). The total synthesis and purification time required is about 80 min, starting from delivery of the [18F]fluoride. [18F]SFB remains an optimal reagent for labeling proteins and peptides with 18F because of good conjugation yields and metabolic stability.     

Affinity labeling of folate transport proteins with the N-hydroxysuccinimide ester of the gamma-isomer of fluorescein-methotrexate

Fluorescein-methotrexate, a derivative in which the fluorophore is linked via a diaminopentane spacer to either the alpha- or gamma-carboxyl group of the glutamate moiety in the drug [Gapski et al. (1975) J. Med. Chem. 18, 526-528], has been synthesized by an improved procedure and separated by DEAE-Trisacryl chromatography into the alpha- and gamma-isomers (alpha-F-MTX and gamma-F-MTX). Each isomer was characterized by mass spectrometry, elemental analysis, absorbance spectrum, TLC, and reversed-phase HPLC. Identity of the isomers was established by the following enzymatic criteria: (a) gamma-F-MTX (but not the alpha-isomer) was hydrolyzed at the pteroate-glutamate bond by carboxypeptidase G2 to yield 4-amino-4-deoxy-10-methylpteroate and gamma-glutamyldiaminopentane-fluorescein; and (b) gamma-F-MTX was a much better inhibitor of human dihydrofolate reductase than the alpha-isomer (Ki values of 0.079 and 4.6 nM). alpha- and gamma-F-MTX were comparable as inhibitors (Ki values of 1.6 and 0.6 microM) of the transport system for reduced folates and MTX in L1210 cells, but the transporter in Lactobacillus casei was inhibited only by the gamma-isomer (Ki = 4.3 microM). The gamma-isomer, therefore, was selected for covalent labeling of proteins. When L. casei folate transport protein (18 kDa) was treated with gamma-F-MTX that had been activated with N-hydroxysuccinimide (NHS), the protein was readily visualized as a fluorescent band on SDS-PAGE electrophoretograms. The probe was also able to detect the transporter in membranes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fatty acid acylation of vaccinia virus proteins.

Labeling of vaccinia virus-infected cells with [3H]myristic acid resulted in the incorporation of label into two viral proteins with apparent molecular weights of 35,000 and 25,000 (designated M35 and M25, respectively). M35 and M25 were expressed in infected cells after the onset of viral DNA replication, and both proteins were present in purified intracellular virus particles. Virion localization experiments determined M25 to be a constituent of the virion envelope, while M35 appeared to be peripherally associated with the virion core. M35 and M25 labeled by [3H]myristic acid were stable to treatment with neutral hydroxylamine, suggesting an amide-linked acylation of the proteins. Chromatographic identification of the protein-bound fatty acid moieties liberated after acid methanolysis of M25, isolated from infected cells labeled during a 4-h pulse, resulted in the recovery of 25% of the protein-bound fatty acid as myristate-associated label and 75% as palmitate, indicating that interconversion of myristate to palmitate had occurred during the labeling period. Similar analyses of M25 and M35, isolated from infected cells labeled during a 0.5-h pulse, determined that 46 and 43%, respectively, of the protein-bound label had been elongated to palmitate even during this brief labeling period. In contrast, M25 and M35 isolated from purified intracellular virions labeled continuously during 24 h of growth contained 75 and 70%, respectively, myristate-associated label, suggesting greater stability of these proteins or a favored interaction of the proteins containing myristate with the maturing or intracellular virion.     

Engineering outer-membrane proteins in Pseudomonas putida for enhanced heavy-metal bioadsorption

Metallothioneins (MTs) are small, cysteine-rich proteins with a strong metal-binding capacity that are ubiquitous in the animal kingdom. Recombinant expression of MT fused to outer-membrane components of gram-negative bacteria may provide new methods to treat heavy-metal pollution in industrial sewage. In this work, we have engineered Pseudomonas putida, a per se highly robust microorganism able to grow in highly contaminated habitats in order to further increase its metal-chelating ability. We report the expression of a hybrid protein between mouse MT and the beta domain of the IgA protease of Neisseria in the outer membrane of Pseudomonas cells. The metal-binding capacity of such cells was increased three-fold. The autotranslocating capacity of the beta domain of the IgA protease of Neisseria, as well as the correct anchoring of the transported protein into the outer membrane, have been demonstrated for the first time in a member of the Pseudomonas genus.     

Enzymatic labeling of arbitrary proteins.

This paper describes an enzymatic labeling technique (ELT), using transglutaminases. On the basis of the ELT, isotopic nuclei are easily incorporated into the gamma-carboxyamide groups of glutamine residues in arbitrary proteins, without changing their chemical structures. We have also shown that, by using ELT, protein aggregation was easily checked for NMR studies and that it can be applicable for the screening of weakly bound ligands for proteins. Owing to the simple preparation of the isotope-labeled proteins, ELT should be useful for speeding up various structural and functional analyses of arbitrary proteins.     

Fatty acylation of cellular proteins. Temporal and subcellular differences between palmitate and myristate acylation

Previous studies demonstrated that palmitate and myristate are covalently linked to distinct sets of cellular proteins and that the linkages through which these fatty acids are attached to the polypeptide chains are different (Olson, E. N., Towler, D. A., and Glaser, L. (1985) J. Biol. Chem. 260, 3784-3790). In the present study, the kinetics and subcellular sites of acylation of proteins with palmitate and myristate were examined in the BC3H1 muscle cell line. Acylation with myristate was an extremely early modification that appeared to take place cotranslationally or shortly thereafter for a variety of soluble and membrane-bound proteins. In contrast, acylation of proteins with palmitate was a post-translational event that occurred exclusively on membrane proteins. To begin to understand the intracellular pathways that acyl proteins follow during their maturation, the degree of glycosylation, and the nature of the interaction of these proteins with membranes were examined. The majority of acyl proteins were tightly associated with membranes and could not be removed by conditions that release peripheral proteins from membranes. However, only a minor fraction of acylated proteins were N-glycosylated. These data suggest that the acyltransferases that attach palmitate and myristate to proteins are present in different subcellular locations and demonstrate that these fatty acids are attached to newly synthesized acyl proteins at different times during their maturation. The lack of carbohydrate on the majority of integral membrane acyl proteins suggests that these proteins may follow intracellular pathways that are different from those followed by cell surface glycoproteins.     

Photogenerated reagents for membrane labeling. 2. Phenylcarbene and adamantylidene formed within the lipid bilayer

Phenylcarbene and adamantylidene have been generated photochemically from the corresponding diazirines within lipid bilayers. Reasonable yields of labeled fatty acid side chains have been observed. The products have been characterized by gas chromatography-mass spectrometry and derive both from the insertion of the carbene into carbon-hydrogen bonds of saturated fatty acids and from the addition of the carbene to the carbon-carbon double bonds of unsaturated fatty acids. In contrast to the results found using phenylnitrene, the lipid labeling by carbene is not reduced by the water-soluble scavenger glutath ione. Carbenes generated from diazirines are evidently superior reagents for the photolabeling of lipids and should be useful for identifying the intrinsic hydrophobic sections of membrane proteins.     

Fluorescent reagents for the labeling of glycoconjugates in solution and on cell surfaces

Rhodamine and fluoresceine containing hydrazides were synthesized and used for fluorescent labeling of glycoconjugates on cell surface or in solution. The procedure involves the oxidation of the glycoconjugates with sodium metaperiodate or galactose oxidase to form an aldehyde group which reacts with the respective hydrazides. The method was applied for the modification of cell surface sialic acid and galactose residues on thymocytes and nematodes as well as for the labeling of glycoproteins and gangliosides in solution. The many possible application of these highly fluorescent compounds in the study of cell surface events is considered.