A new modified Edman procedure for analysis of N-terminal valine adducts in hemoglobin by LC–MS/MS

A rapid and sensitive method using liquid chromatography–tandem mass spectrometry (LC–MS/MS) for simultaneous determination of adducts from acrylamide, glycidamide and ethylene oxide to N-terminal valines in hemoglobin (Hb) was developed. This new procedure is based on the same principles as the N-alkyl Edman procedure for analysis of adducts from electrophilic agents to N-terminal valines in Hb. The N-substituted valines can be detached, enriched and measured selectively as thiohydantoins by the use of an Edman reagent, in this case fluorescein isothiocyanate (FITC). This procedure is denoted as the “adduct FIRE procedure” as the FITC reagent is used for measurement of adducts (R) formed from electrophilic compounds with a modified Edman procedure. In this study, fluorescein thiohydantoin (FTH) analytes of N-substituted valines from acrylamide, glycidamide and ethylene oxide, as well as their corresponding hepta- and tri-deuterium-substituted analogues, were synthesized. These analytes (n = 8) were then characterized by LC–MS/MS (ESI, positive ion mode) and obtained product ions were interpreted. A considerable work with optimization of the FIRE procedure™, resulted in a procedure in which low background levels of the studied adducts could be measured from 250 μL lyzed whole blood samples (human non-smokers). The analytes were enriched and purified with solid phase extraction columns and analyzed by LC–MS/MS with LOQ down to 1 pmol adduct/g Hb. Compared to other procedures for determination of N-terminal Hb adducts, the introduction of FITC has led to a simplified procedure, where whole blood also can be used, giving new opportunities and reduced hand on time with increased sample throughput.     

Reaction of acetaldehyde with hemoglobin

Acetaldehyde reacted with hemoglobin at neutral pH and 37 degrees C to form adducts that were stable to dialysis and that were not reduced by sodium borohydride. Hemoglobin tetramers having 2, 3, and probably 4 molar eq of bound aldehyde were isolated by cation exchange chromatography. The sites of attachment of the aldehyde were the free amino groups of the N-terminal valine residues of the alpha and beta chains of hemoglobin. Derivatization of the beta chains caused a greater increase in the acidity of the hemoglobin than did derivatization of the alpha chains. Derivatization of the beta chains was also preferred over that of the alpha chains. Acetaldehyde derivatives of the N-terminal octapeptide of hemoglobin S (beta sT-1 peptide), Val-Gly-Gly, and tetraglycine were formed readily, contained 1 M eq of acetaldehyde/mol of peptide, and were not reduced by sodium borohydride. In contrast, Ala-Pro-Gly failed to form a 1:1 adduct with acetaldehyde. 13C NMR analysis of the peptide adducts formed with [1,2-13C]acetaldehyde indicated that tetrahedral diastereomeric derivatives were produced. The 13C chemical shifts of the adducts formed between hemoglobin and [1,2-13C]acetaldehyde were identical to those of the peptide adducts although resonances from the individual diastereomeric adducts at each hemoglobin site could not be resolved. The results cited above as well as other evidence indicate that acetaldehyde reacts with the amino termini of hemoglobin to form stable cyclic imidazolidinone derivatives. An exchange of acetaldehyde residues between peptides was also documented.     

A novel manual method for protein-sequence analysis.

A novel manual method for protein-sequence analysis is described. Three peptides, the hexapeptide (Leu-TRP-Met-Arg-Phe-Ala), insulin A chain and glucagon were used to test this technique. Peptides (1 or 2 nmol) were hydrolysed with acid and their qualitative amino acid compositions were confirmed by reacting with 4-NN-dimethylaminoazobenzene-4'-sulphonylchloride and 4-NN-dimethylaminoazobenzene 4'-isothiocyanate. Sequence determination of 20-200 nmol of peptide was then performed by the combined use of phenyl isothiocyanate and 4-NN-dimethylaminoazobenzene 4'-isothiocyanate, a new procedure that is analogous to the dansyl-Edman method with the replacement of dansyl chloride by 4-NN-dimethylaminoazobenzene 4'-isothiocyanate as the N-terminal residue determination reagent. On t.l.c. this new N-terminal reagent gave brightly coloured 4-NN-dimethylaminoazobenzene-4-thiohydantoins of amino acids and showed the following advantages: (1) the detection sensitivity is in the pmol range; (2) u.v. observation is not required; (3) there is no destruction of acid-labile amino acids; (4) two-dimensional t.l.c. separation is adequate to identify 24 amino acids, except leucine and isoleucine (this pair of amino acids can be resolved by using 4-NN-dimethylaminoazobenzene-4'-sulphonyl chloride); (5) the determination of a new N-terminal residue (from coupling to t.l.c. identification) takes only 3 h; (6) the colour difference beteen isothiocyanate, thiocarbamoyl and thiohydantoin derivatives facilitates the identifications.     

Determination of hemoglobin adducts from aldehydes formed during lipid peroxidation in vitro.

This study was performed in order to investigate the formation of hemoglobin (Hb) adducts from some aldehydes, known to be formed during the peroxidation of polyunsaturated fatty acids. Hb was reacted in vitro with aldehydes followed by reduction of hemolysate with sodium borohydride and isolation of globin. Using the N-alkyl Edman method, globin samples were derivatized with pentafluorophenyl isothiocyanate for specific splitting off of N-substituted N-terminal valines. Adducts formed were then characterized by gas chromatography mass spectrometry using different ionization techniques. It was shown that adducts from saturated aldehydes were Schiff bases and those from alpha,beta-unsaturated aldehydes were mixtures of Schiff bases and 1,4-addition products. Aldehyde adducts were also measured in Hb from erythrocytes induced for lipid peroxidation. Incubation of the erythrocytes in presence of arachidonic acid led to increased levels of adducts.     

Mass spectrometric determination of early and advanced glycation in biology

Protein glycation in biological systems occurs predominantly on lysine, arginine and N-terminal residues of proteins. Major quantitative glycation adducts are found at mean extents of modification of 1–5 mol percent of proteins. These are glucose-derived fructosamine on lysine and N-terminal residues of proteins, methylglyoxal-derived hydroimidazolone on arginine residues and N^ε-carboxymethyl-lysine residues mainly formed by the oxidative degradation of fructosamine. Total glycation adducts of different types are quantified by stable isotopic dilution analysis liquid chromatography-tandem mass spectrometry (LC-MS/MS) in multiple reaction monitoring mode. Metabolism of glycated proteins is followed by LC-MS/MS of glycation free adducts as minor components of the amino acid metabolome. Glycated proteins and sites of modification within them – amino acid residues modified by the glycating agent moiety - are identified and quantified by label-free and stable isotope labelling with amino acids in cell culture (SILAC) high resolution mass spectrometry. Sites of glycation by glucose and methylglyoxal in selected proteins are listed. Key issues in applying proteomics techniques to analysis of glycated proteins are: (i) avoiding compromise of analysis by formation, loss and relocation of glycation adducts in pre-analytic processing; (ii) specificity of immunoaffinity enrichment procedures, (iii) maximizing protein sequence coverage in mass spectrometric analysis for detection of glycation sites, and (iv) development of bioinformatics tools for prediction of protein glycation sites. Protein glycation studies have important applications in biology, ageing and translational medicine – particularly on studies of obesity, diabetes, cardiovascular disease, renal failure, neurological disorders and cancer. Mass spectrometric analysis of glycated proteins has yet to find widespread use clinically. Future use in health screening, disease diagnosis and therapeutic monitoring, and drug and functional food development is expected. A protocol for high resolution mass spectrometry proteomics of glycated proteins is given.     

Studies on the methyl isocyanate adducts with globin

Isocyanates such as methylisocyanate (MIC), an intermediate in the synthesis of carbamate pesticides, or diisocyanates, used in the production of plastics, are highly reactive toxic compounds that spontaneously bind to biological macromolecules. In vivo formation of stable adducts with blood protein globin offers possibilities for biomonitoring of internal exposure to various reactive species. Thus, biomonitoring of the isocyanates through determination of their specific adducts with globin is a challenge. In this study, we characterized the adducts formed in human globin upon treatment with 100-fold molar excess of MIC. The globin was subject to enzymatic hydrolysis with pronase, and the hydrolysate was analysed by high performance liquid chromatography with positive atmospheric pressure chemical ionization mass spectrometric detection (HPLC/APCI-MS). The two major MIC adducts were those with N-terminal Val and side-chain of Lys, as confirmed by comparison with the synthetic standards. About 20 other adducts were observed, and several of them were tentatively identified using their MS and MS/MS spectra. Whereas detection of the adducts with Tyr and His was expected, the adducts with Trp and Phe, and a Lys adduct containing two MIC moieties, were probably analytical artifacts resulting from the transcarbamoylation during globin hydrolysis rather than products of direct carbamoylation. The other detected products were MIC-Val-His, derived from the N-terminal dipeptide of globin beta-chain, and dipeptides consisting of MIC-Lys attached to Gly, Val, Leu, Thr, and Glu. Failure to detect the corresponding non-modified dipeptides suggests that the pronase action may be hampered by the amino acid modification. MIC is known as a metabolic intermediate of the industrial solvents N,N-dimethylformamide (DMF) and N-methylformamide (MF) in humans and rats. The HPLC/APCI-MS analysis of globin from rats injected with DMF or MF, 1000 mg/kg, revealed the presence of the MIC adducts with both Val and Lys. The level of the Val adduct in globin from the DMF-dosed rats, determined using Edman degradation and GC/MS, was ca. 40 nmol/g, which is a level common in workers occupationally exposed to DMF. This suggests that also the Lys adduct in such human globin samples can be feasible to analysis and is therefore considered for further studies as a potential biomarker of exposure to DMF.     

Hemoprotein-mediated reduction of nitrated DNA bases in the presence of reducing agents

DNA damages by reactive nitrogen oxide species may contribute to the multistage carcinogenesis processes associated with chronic infections and inflammation. The nitrated DNA adducts 8-nitroguanine (8NG) and 8-nitroxanthine (8NX) have been shown to derive from these reactive nitrogen oxide species, but they are not stable in DNA since they undergo spontaneous depurination. We herein report that hemin and hemoproteins, including hemoglobin and cytochrome c, mediate reduction of 8NG and 8NX to their corresponding amino analogues in the presence of reducing agents under physiologically relevant conditions. This reaction is believed to involve the reduced heme moiety produced from the reduction of oxidized hemoglobin or cytochrome c by reducing agents. The combination of hemoglobin and dihydrolipoic acid generated the reduced products in high yields. Ascorbate, quercetin, and glutathione are also capable of reducing these nitrated DNA adducts. The hemoglobin macromolecule reduces 8NG and 8NX formed in nitryl chloride-treated calf thymus DNA, as evidenced by the formation of the amino adducts using reversed-phase HPLC with photodiode array detection. Hemin is more efficient than equal molar of heme on hemoglobin in reducing 8NG-containing DNA, indicating the role of protein in impeding the reaction. Furthermore, we also show that the reduction product 8-aminoguanine is persistent on DNA. These findings suggest that reduction of nitrated DNA by the heme/antioxidant system might represent a possible in vivo pathway to modify DNA nitration.     

Identification of the membrane anchor of microsomal rat liver cytochrome P-450

Cytochrome P450IIB1 isolated from rat liver microsomes was incorporated into phosphatidylcholine/phosphatidylethanolamine/phosphatidylserine (10:5:1 w/w) liposomes. Trypsinolysis of proteoliposomes and sequencing of the membrane-bound domains revealed that only one peptide, comprising amino acid residues 1-21, spans the membrane. Modification of the N-terminal methionine by membrane-impermeable fluorescein isothiocyanate occurred with the protein in solution but not in proteoliposomes. We conclude that in proteoliposomes cytochrome P-450 spans the membrane only with amino acid residues 1-21, the N-terminal methionine facing the lumen.     

Binding of 3-hydroxybenzo[a]pyrene to bovine hemoglobin and albumin

Previous studies examined the bioavailability and first-pass biotransformation of 3-hydroxy[(3)H]benzo[a]pyrene ([(3)H]-3-OHBaP) in an isolated perfused catfish intestinal model. This work showed that 3-OHBaP, or a metabolite formed in intestine, bound covalently to blood protein. In this study, the blood adducts were characterized in vitro by incubating bovine ferric hemoglobin or albumin with [(3)H]-3OHBaP under various conditions. Incubation of 2 microM [(3)H]-3-OHBaP with hemoglobin for 1 h resulted in 7.49 pmol bound/mg protein, while albumin binding was 1.37 pmol/mg protein. Mild acid hydrolysis released only 5% of the radioactivity from 3-OHBaP-hemoglobin adducts. After gel filtration, the 3-OHBaP-hemoglobin adducts were examined by HPLC analysis. A single peak of radioactivity was detected at the same retention time as the heme component of hemoglobin. Unbound 3-OHBaP was oxidized to BaP-3,6-dione during incubation with ferric hemoglobin. Treatment of hemoglobin with ascorbic acid decreased the formation of hemoglobin adducts by 33%, while hydrogen peroxide treatment increased adduct formation by 44%. Incubation of [(3)H]-BaP-3-beta-D-glucuronide (BaP-3G) with hemoglobin and beta-glucuronidase resulted in greater binding to hemoglobin than incubation with [(3)H]-3-OHBaP alone. The hemoglobin adduct obtained from [(3)H]-BaP-3G also co-migrated with heme. These results indicate that an oxidative process is involved in formation of the heme adduct and that 3-OHBaP or BaP-3G might be a precursor of the bound metabolite.     

N-terminal sequence analysis of polypeptide at the picomole level.

This paper describes a manual method for N-terminal sequence analysis of polypeptides at subnanomole sensitivity. The polypeptide is degraded stepwise by using the dimethylaminoazobenzene isothiocyanate/phenyl isothiocyanate double-coupling method, and the released dimethylaminoazobenzenethiohydantoins of amino acids were identified by reversed-phase high-pressure liquid chromatography. The dimethylaminoazobenzenethiohydantoins are coloured compounds and can be detected in the visible region with the sensitivity limit of 1 pmol (signal-to-baseline noise ratio 5). A high-pressure liquid-chromatographic method was developed for complete analysis of all amino acid dimethylaminoazobenzenethiohydantoin derivatives, including the by-products of serine and threonine. Thus, without use of an automatic sequenator or radioactive materials, it is possible to determine the complete sequence of peptides and N-terminal sequence of proteins with less than 1 nmol of material.     

New sensitive determination method of benzidine-hemoglobin adducts by gas chromatography-electron impact mass spectrometry

A gas chromatographic-mass spectrometric assay was developed for the determination of benzidine (BZ)-hemoglobin adducts. Adducts were released from hemoglobin by alkaline hydrolysis and extraction at pH 8 with ethyl ether. The dried extract was completely derivatized with N-methyl-N-(tert.-butyldimethylsilyl) trifluoroacetamide (MTBDMSTFA)-NH(4)I (1000:3) under catalysis of dithioerythritol. The recovery of BZ, acetylbenzidine (ABZ) and diacetylbenzidine (DABZ) in the extraction procedure was 76-98%. The detection limits of the assay were 0.1 ng/g for both BZ and ABZ, and 0.5 ng/g for DABZ based upon assayed hemoglobin of 0.1 g. The method was applied to the determination of BZ-hemoglobin adducts formed in young female Sprague-Dawley rats after treatment for 1, 2 and 3 weeks with 0.008% BZ via the drinking water. Two adducts were detected by proposed procedure. The structure of these adducts could be assigned to BZ and ABZ. After 1 week, the total mean amount of adducts determined was 2.8 ng/g hemoglobin. The adduct levels increased up to about 7.5 ng/g after a week and, thereafter, remained essentially constant. The relative contribution of BZ and ABZ to the total hemoglobin adduct level was strongly treatment time-dependent. After 1 week, the BZ and ABZ adducts were formed at similar levels, whereas after 3 weeks the ABZ adducts was predominant. Treatment of rats for 3 weeks in the dose range 12.2-36.8 mg of BZ in drinking water resulted in a dose-proportional increase in the total amount of hemoglobin adducts formed.     

NMR study of the sites of human hemoglobin acetylated by aspirin.

Acetylation of hemoglobin by aspirin and other acetylating agents has been used to generate hemoglobin analogs with altered structural and functional properties, and may prove useful in the treatment of sickle cell disease. We have studied the acetylation of human hemoglobin using [1'-(13)C]acetylsalicylic acid in combination with two-dimensional HMQC and HSQC NMR analysis. The spectra of the acetylated hemoglobin exhibit a number of well resolved resonances. Several spectral assignment strategies were used: blocking the 2, 3-DPG binding site non-covalently with inositol hexaphosphate or covalently with a cross-linking agent, selective carbamylation of the N-terminal valine amino groups with cyanate, spin-labeling the hemoglobin at betaCys93, and analysis of a hemoglobin triple mutant: betaV1MH2DeltaK144R, in which betaLys144 is replaced by an arginine residue. These studies support the conclusion that the most rapidly acetylated residue is betaLys82 rather than betaLys144, as previously reported. Further, it is apparent that acetyl betaLys82 can give rise to several resonances due to additional acetylation of betaLys82' or other nearby residues. An additional assignment strategy involving comparison of the chemical shifts of the acetyl resonances observed for adducts of diamagnetic carbonmonoxyhemoglobin with the shifts observed in paramagnetic cyanomethemoglobin provides information about the location of the acetyl derivatives relative to the heme irons. This approach is limited, however, by the lack of well defined structural information for the lysine residues on the protein surface. Additional tentative assignments have also been made, using the above approaches.     

Amino acid sequence of yeast hemoglobin. A two-domain structure.

The complete amino acid sequence of a hemoglobin from yeast (Candida norvegensis) has been determined by peptide and cDNA sequence analyses. The protein is composed of 387 amino acid residues and its amino terminus was blocked by an acetyl group. A computer search showed that the sequence of 155 N-terminal residues has 39% homology with that of Vitreoscilla hemoglobin. On the other hand, the sequence of 230 C-terminal residues showed a small, but notable, degree of similarity with that of a methemoglobin reductase found in human erythrocyte, i.e. NADH-cytochrome b5 oxido-reductase. We therefore conclude that yeast hemoglobin consists of two distinct domains; one is a heme-containing oxygen binding domain of the N-terminal region and the other is an FAD-containing reductase domain found in the C-terminal region.     

A complete quantitative N-terminal analysis method

A complete quantitative N-terminal analysis (QNA) technique based on the application of dimethylaminoazobenzene isothiocyanate is described. The method allows recovery of all free N-terminal amino acids, including Asn, Gln, Trp, Ser, and Thr in quantitative yield. N-Termini of polypeptides as little as 5 pmol can be reliably and reproducibly determined by this method. This QNA method is useful in many aspects of protein structure analysis. (a) QNA is useful in assessing the purity, identity, and quantity of a polypeptide preparation. It has also been applied in our lab as a routine guarding step to prevent impure or ill-characterized samples from occupying the space of the gas-phase sequenator. (b) QNA of a trypsinized protein generates a miniaturized amino acid composition which is useful both in characterizing the identity of a protein and in comparing the homology of structurally related proteins. (c) QNA can be used to follow the pathway and preferential cleavage sites of limited proteolysis. (d) QNA is useful in characterizing selectively modified Lys and Arg residues. The details of this QNA method and the results of its applications are presented here.     

Adducts between nucleophilic amino acids and hexahydrophthalic anhydride,a structure inducing both types I and IV allergy

Haptens causing type I allergy have been shown to predominantly form lysine adducts in the carrier protein, while many haptens giving rise to type IV allergy preferentially form adducts with cysteine residues. Hexahydrophthalic anhydride derivatives are strong sensitizers capable of inducing allergic rhinitis, asthma and urticaria (type I allergy) and allergic contact dermatitis (type IV allergy). The ability of hexahydrophthalic anhydride (HHPA) to form adducts with nucleophilic amino acids and a model peptide in vitro is presented. Adduct formation was monitored by high-performance liquid chromatography with ultraviolet light/vis detection (LC-UV/vis) and high-performance liquid chromatography with mass spectrometric detection (LC/MS). The characterization was obtained by nuclear magnetic resonance spectroscopy (NMR) and mass spectrometry (MS and MS/MS). It was found that HHPA formed adducts with N^α-acetylated lysine and cysteine and the non-acetylated α-amino group of proline and, to some extent, also with other nucleophilic amino acids. The adducts with lysine and proline were chemically stable. Addition of one HHPA to a model carrier peptide with all important nucleophilic amino acid residues showed N-terminal proline to be the major site of reaction. The addition of a second hapten gave a lysine adduct, but a minor cysteine adduct was also found. The cysteine–HHPA adducts were shown to be chemically unstable and participated in further reactions with lysine forming lysine–HHPA adducts. The results will be useful for understanding the formation of HHPA–protein adducts with the capability of being markers of exposure, and also to a deeper understanding of the chemical structures causing types I and IV allergy.     

Adducts between nucleophilic amino acids and hexahydrophthalic anhydride, a structure inducing both types I and IV allergy.

Haptens causing type I allergy have been shown to predominantly form lysine adducts in the carrier protein, while many haptens giving rise to type IV allergy preferentially form adducts with cysteine residues. Hexahydrophthalic anhydride derivatives are strong sensitizers capable of inducing allergic rhinitis, asthma and urticaria (type I allergy) and allergic contact dermatitis (type IV allergy). The ability of hexahydrophthalic anhydride (HHPA) to form adducts with nucleophilic amino acids and a model peptide in vitro is presented. Adduct formation was monitored by high-performance liquid chromatography with ultraviolet light/vis detection (LC-UV/vis) and high-performance liquid chromatography with mass spectrometric detection (LC/MS). The characterization was obtained by nuclear magnetic resonance spectroscopy (NMR) and mass spectrometry (MS and MS/MS). It was found that HHPA formed adducts with N(alpha)-acetylated lysine and cysteine and the non-acetylated alpha-amino group of proline and, to some extent, also with other nucleophilic amino acids. The adducts with lysine and proline were chemically stable. Addition of one HHPA to a model carrier peptide with all important nucleophilic amino acid residues showed N-terminal proline to be the major site of reaction. The addition of a second hapten gave a lysine adduct, but a minor cysteine adduct was also found. The cysteine-HHPA adducts were shown to be chemically unstable and participated in further reactions with lysine forming lysine-HHPA adducts. The results will be useful for understanding the formation of HHPA-protein adducts with the capability of being markers of exposure, and also to a deeper understanding of the chemical structures causing types I and IV allergy.     

Covalent Fixation of Soluble Derivatized Dextrans to Model Proteins in Low-Concentration Medium: Application to Factor IX and Protein C

Factor IX and protein C are zymogens implicated in blood clotting, and an increase in their plasmatic residence time would be of interest for the treatment of the disorders caused by their deficiency. In this context, the conjugation of these proteins to polymers such as modified dextrans could be used to approach the problem. Conjugate formation in concentrated medium ([protein]>50 g/L) is well documented, whereas drastic dilution ([protein] <1 g/L) is quite unfavorable. Before studying the binding of factor IX and protein C to polymers, the coupling of model proteins (human hemoglobin, Hb; human serum albumin, HSA) in low-concentration medium to benzenetetracarboxylate dextran (BTC-dextran) and dialdehyde dextran was investigated. To obtain soluble benzenetetracarboxylate dextran-based conjugates, the conditions of coupling were optimized; the use of sulfo-NHS was necessary to form a conjugate with benzenetetracarboxylate dextran. In fact, the O-acylurea intermediate formed between coupling agent [l-ethyl-3(3-dimethylaminopropyl) carbodiimide, EDC] and BTC-dextran must be stabilized. Concerning dialdehyde dextran, a more oxidized polymer and a higher pH of the buffer of coupling than for highly concentrated solution must be used to obtain a conjugate. Whatever polymer is used, HSA appeared clearly less reactive than Hb, which can be attributed to the better reactivity of N-terminal amino groups in this latter protein and to the marked affinity of benzenetetracarboxylate dextran for it. No soluble conjugate was formed between the same dextran derivatives and factor IX or protein C. Moreover, the activity of both coagulation factors was dramatically decreased by contact with EDC and glutaraldehyde, a small molecule. Thus, bad accessibility of protein amino groups is probably responsible for this lack of reactivity. Nevertheless, it could be shown that carboxylate and amino groups were essential to the activity of factor IX and protein C.     

Site-specific fluorescent derivatization and liquid chromatographic-mass spectrometric characterization of long R(3) IGF-I for bioanalytical applications

Recombinant Long R(3) IGF-I was derivatized with fluorescein isothiocyanate (FITC) at a single location by careful selection of reaction conditions (i.e. pH, and FITC/protein amino group ratio). High-performance liquid chromatography (LC) and electrospray mass spectrometry (MS) were used to confirm the extent of fluorescein conjugation. The protein conjugate was isolated and subjected to cyanogen bromide (CNBr) cleavage, followed by LC-MS to determine the site of modification. The isolated species of Long R(3) IGF-I-FITC was labeled at the N-terminal Met residue. Recognition of this fluorescent analog by monoclonal anti-IGF-I was preserved, indicating its potential for immunodiagnostic applications.