Functional tyrosyl residues of carboxypeptidase A. The effect of protein structure on the reactivity of tyrosine-198

Coupling of bovine carboxypeptidase A with diazotized 5-amino-1H-tetrazole increases esterase activity, decreases peptidase activity slightly, and modifies one tyrosyl residue. Subsequent nitration of the azoenzyme has no further effect on esterase activity, decreases peptidase activity markedly, and modifies a second tyrosyl residue. Analysis of the azopeptides isolated from a chymotrypsin digest of the doubly modified enzyme by affinity, ion exchange, and high pressure liquid chromatography indicates that the principal residue modified by diazo-1H-tetrazole is Tyr-248. Analysis of the nitropeptides isolated by similar procedures indicates that nitration occurs mainly at Tyr-198. This residue becomes susceptible to modification only as a consequence of a conformational change that accompanies azo coupling of Tyr-248. These results describe a unique example of the influence of protein structure on the reactivity of functional amino acid residues and illustrate an important aspect of chemical modification of enzymes.     

Cascade of autophosphorylation in the beta-subunit of the insulin receptor

Insulin stimulated autophosphorylation of the beta-subunit of the insulin receptor purified from Fao hepatoma cells or purified from Chinese hamster ovary (CHO/HIRC) or Swiss 3T3 (3T3/HIRC) cells transfected with the wild-type human insulin receptor cDNA. Autophosphorylation of the purified receptor occurred in at least two regions of the beta-subunit: the regulatory region containing Tyr-1146, Tyr-1150, and Tyr-1151, and the C-terminus containing Tyr-1316 and Tyr-1322. In the presence of antiphosphotyrosine antibody (alpha-PY), autophosphorylation of the purified receptor was inhibited nearly 80% during insulin stimulation. Tryptic peptide mapping showed that alpha-PY inhibited autophosphorylation of both tyrosyl residues in the C-terminus and one tyrosyl residue in the regulatory region, either Tyr-1150 or Tyr-1151. Thus, a bis-phosphorylated form of the regulatory region accumulated in the presence of alpha-PY, which contained Tyr(P)-1146 and either Tyr(P)-1150 or 1151. In intact Fao, CHO/HIRC, and 3T3/HIRC cells, insulin stimulated tyrosyl phosphorylation of the beta-subunit of the insulin receptor. Tryptic peptide mapping indicated that the regulatory region of the beta-subunit was mainly (greater than 80%) bis-phosphorylated; however, all three tyrosyl residues of the regulatory region were phosphorylated in about 20% of the receptors. As the phosphotransferase was activated by tris-phosphorylation but not bis-phosphorylation of the regulatory region of the beta-subunit (White et al.: Journal of Biological Chemistry 263:2969-2980, 1988), the extent of autophosphorylation in the regulatory region may play an important regulatory role during signal transmission in the intact cell.     

A cascade of tyrosine autophosphorylation in the beta-subunit activates the phosphotransferase of the insulin receptor

We identified the major autophosphorylation sites in the insulin receptor and correlated their phosphorylation with the phosphotransferase activity of the receptor on synthetic peptides. The receptor, purified from Fao hepatoma cells on immobilized wheat germ agglutinin, undergoes autophosphorylation at several tyrosine residues in its beta-subunit; however, anti-phosphotyrosine antibody (alpha-PY) inhibited most of the phosphorylation by trapping the initial sites in an inactive complex. Exhaustive trypsin digestion of the inhibited beta-subunit yielded two peptides derived from the Tyr-1150 domain (Ullrich, A, Bell, J. R., Chen, E. Y., Herrera, R., Petruzzelli, L. M., Dull, T. J., Gray, A., Coussens, L., Liao, Y.-C., Tsubokawa, M., Mason, A., Seeburg, P. H., Grunfeld, C., Rosen, O. M., and Ramachandran, J. (1985) Nature 313, 756-761) called pY4 and pY5. Both peptides contained 2 phosphotyrosyl residues (2Tyr(P], one corresponding to Tyr-1146 and the other to Tyr-1150 or Tyr-1151. In the absence of the alpha-PY additional sites were phosphorylated. The C-terminal domain of the beta-subunit contained phosphotyrosine at Tyr-1316 and Tyr-1322. Removal of the C-terminal domain by mild trypsinolysis did not affect the phosphotransferase activity of the beta-subunit suggesting that these sites did not play a regulatory role. Full activation of the insulin receptor during in vitro assay correlated with the appearance of two phosphopeptides in the tryptic digest of the beta-subunit, pY1 and pY1a, that were inhibited by the alpha-PY. Structural analysis suggested that pY1 and pY1a were derived from the Tyr-1150 domain and contained 3 phosphotyrosyl residues (3Tyr(P] corresponding to Tyr-1146, Tyr-1150, and Tyr-1151. The phosphotransferase of the receptor that was phosphorylated in the presence of alpha-PY at 2 tyrosyl residues in the Tyr-1150 domain was not fully activated during kinase assays carried out with saturating substrate concentrations which inhibited further autophosphorylation. During insulin stimulation of the intact cell, the 3Tyr(P) form of the Tyr-1150 domain was barely detected, whereas the 2Tyr(P) form predominated. We conclude that 1) autophosphorylation of the insulin receptor begins by phosphorylation of Tyr-1146 and either Tyr-1150 or Tyr-1151; 2) progression of the cascade to phosphorylation of the third tyrosyl residue fully activates the phosphotransferase during in vitro assay; 3) in vivo, the 2Tyr(P) form predominates, suggesting that progression of the autophosphorylation cascade to the 3Tyr(P) form is regulated during insulin stimulation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Nitration of functional tyrosyl residues in rabbit muscle phosphorylase b

Upon reaction of rabbit muscle phosphorylase $\text{b}$ with tetranitromethane in a stoichiometric ratio with respect to the tyrosyl content, 2 out of 34 phenolic groups per mole of monomer (M.W. 95,000) were nitrated with an almost complete loss of activity. Only one residue per monomer was nitrated in the presence of AMP, the major part of the activity being preserved. The sedimentation pattern of modified phosphorylase $\text{b}$ showed that, following nitration in the absence of AMP, the enzyme was fully dissociated into monomers, whereas, when the enzyme was nitrated in its presence, the dimeric structure was retained.     

Regulation of glycogen phosphorylase. Role of the peptide region surrounding the phosphoserine residue in determining enzyme properties.

A phosphopeptide which contains 14 residues including phosphoserine and which is derived from the NH2-terminal region of skeletal muscle glycogen phosphorylase (Nolan, C., Novoa, W. B., Krebs, E. G., and Fischer, E. H. (1964) Biochemistry 3, 542-551) has been shown to induce the enzymic properties of phosphorylase a in phosphorylase b and b'. When phosphorylase b is incubated with the phosphorylated tetradecapeptide, the following changes occur: (1) the enzyme becomes partially catalytically active in the absence of AMP; (2) the allosteric interactions of the enzyme are altered, as evidenced by the fact that phosphorylase b does not bind AMP cooperatively, and is no longer inhibited by glucose-6-P; and (3) the enzyme, normally present as a dimer, associates to a tetramer. Phosphorylase b' is a modified form of phosphorylase in which the phosphorylation site has been removed by limited tryptic attack. In the presence of phosphopeptide, 86% of the total enzyme activity can be induced in the absence of AMP. The properties of phosphorylases b and b' with phosphopeptide, cited above, are all characteristics of the phosphonenzyme, phosphorylase a. In addition, evidence is presented that these effects are specific. They are not the result of the polycationic nature of the peptide since they cannot be duplicated by spermine, and the phosphate group must also be present for the peptide to effect changes on the enzyme.     

Probing the free radicals formed in the metmyoglobin-hydrogen peroxide reaction

The reaction between metmyoglobin and hydrogen peroxide results in the two-electron reduction of H2O2 by the protein, with concomitant formation of a ferryl-oxo heme and a protein-centered free radical. Sperm whale metmyoglobin, which contains three tyrosine residues (Tyr-103, Tyr-146, and Tyr-151) and two tryptophan residues (Trp-7 and Trp-14), forms a tryptophanyl radical at residue 14 that reacts with O2 to form a peroxyl radical and also forms distinct tyrosyl radicals at Tyr-103 and Tyr-151. Horse metmyoglobin, which lacks Tyr-151 of the sperm whale protein, forms an oxygen-reactive tryptophanyl radical and also a phenoxyl radical at Tyr-103. Human metmyoglobin, in addition to the tyrosine and tryptophan radicals formed on horse metmyoglobin, also forms a Cys-110-centered thiyl radical that can also form a peroxyl radical. The tryptophanyl radicals react both with molecular oxygen and with the spin trap 3,5-dibromo-4-nitrosobenzenesulfonic acid (DBNBS). The spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO) traps the Tyr-103 radicals and the Cys-110 thiyl radical of human myoglobin, and 2-methyl-2-nitrosopropane (MNP) traps all of the tyrosyl radicals. When excess H2O2 is used, DBNBS traps only a tyrosyl radical on horse myoglobin, but the detection of peroxyl radicals and the loss of tryptophan fluorescence support tryptophan oxidation under those conditions. Kinetic analysis of the formation of the various free radicals suggests that tryptophanyl radical and tyrosyl radical formation are independent events, and that formation of the Cys-110 thiyl radical on human myoglobin occurs via oxidation of the thiol group by the Tyr-103 phenoxyl radical. Peptide mapping studies of the radical adducts and direct EPR studies at low temperature and room temperature support the conclusions of the EPR spin trapping studies.     

Reduced forms of the iron-containing small subunit of ribonucleotide reductase from Escherichia coli

The B2 subunit of ribonucleotide reductase from Escherichia coli contains a stable tyrosyl free radical and an antiferromagnetically coupled dimeric iron center with high-spin ferric ions. The tyrosyl radical is an oxidized form of tyrosine-122. This study shows that the B2 protein has a fully reduced state, denoted reduced B2, characterized by a normal nonradical tyrosine-122 residue and a dimeric ferrous iron center. Reduced B2 can be formed either from active B2 by a three-electron reduction in the presence of suitable mediators or from apoB2 by addition of two equimolar amounts of ferrous ions in the absence of oxygen. The oxidized tyrosyl radical and the ferric iron center can be generated from reduced B2 by the admission of air. The tyrosyl radical can be selectively reduced by one-electron reduction in the presence of a suitable mediator, yielding metB2, a form that seems identical with the form resulting from treatment of active B2 with hydroxyurea. 1H NMR was used to characterize the paramagnetically shifted resonances associated with the reduced iron center. Prominent resonances were observed around 45 ppm (nonexchangeable with solvent) and 57 ppm (exchangeable with solvent) at 37 degrees C. From the temperature dependence of the chemical shifts of these resonances it was concluded that the ferrous ions in reduced B2 are only weakly, if at all, antiferromagnetically coupled. By comparison with data on the similar iron center of deoxyhemerythrin it is suggested that the 57 ppm resonance should be assigned to protons in histidine ligands of the iron center.     

The phosphoenolpyruvate-dependent phosphotransferase system of Staphylococcus aureus. Complete tyrosine assignments in the 1H nuclear-magnetic-resonance spectrum of the phosphocarrier protein HPr.

Upon nitration of the phosphocarrier protein HPr three nitrated derivatives of the protein were isolated: mononitrated HPr, dinitrated HPr and trinitrated HPr. Tryptic digestion of the derivatives leads to nitrotyrosine-containing peptides which were isolated and characterized by amino acid analysis. This resulted in the determination of the positions of the nitrated tyrosyl residues in the amino acid sequence. In mononitrated HPr only Tyr-56 was modified, in dinitrated HPr both Tyr-56 and Tyr-37 had reacted with the nitrating agent; modification of all three tyrosyl residues in trinitrated HPr required more drastic reaction conditions. The nuclear magnetic resonance spectra of the three derivatives allowed the assignments of the tyrosine resonances as follows: Tyr-A and Tyr-B with pK values of 10.5 and 11.5 were designated Tyr-56 and Tyr-37 whereas Tyr-C, whose protons are not titratable before denaturation of the protein, was assigned to Tyr-6 in the amino acid sequence. The nitration studies, together with the titration behaviour of the three tyrosines, indicate the topology of the tyrosyl residues to be as follows: Tyr-56 is located at the surface, Tyr-37 is slightly buried, Tyr-6 is deeply buried. The nitrotyrosyl derivatives retain their biological activity.     

Transmembrane nitration of hydrophobic tyrosyl peptides. Localization,characterization, mechanism of nitration,and biological implications

We have shown previously that peroxynitrite-induced nitration of a hydrophobic tyrosyl probe is greater than that of tyrosine in the aqueous phase (Zhang, H., Joseph, J., Feix, J., Hogg, N., and Kalyanaraman, B. (2001) Biochemistry 40, 7675-7686). In this study, we have tested the hypothesis that the extent of tyrosine nitration depends on the intramembrane location of tyrosyl probes and on the nitrating species. To this end, we have synthesized membrane spanning 23-mer containing a single tyrosyl residue at positions 4, 8, and 12. The location of the tyrosine residues in the phospholipid membrane was determined by fluorescence and electron spin resonance techniques. Nitration was initiated by slow infusion of peroxynitrite, co-generated superoxide and nitric oxide ((.)NO), or a myeloperoxidase/hydrogen peroxide/nitrite anion (MPO/H(2)O(2)/NO(2)(-)) system. Results indicate that with slow infusion of peroxynitrite, nitration of transmembrane tyrosyl peptides was much higher (10-fold or more) than tyrosine nitration in aqueous phase. Peroxynitrite-dependent nitration of tyrosyl-containing peptides increased with increasing depth of the tyrosyl residue in the bilayer. In contrast, MPO/H(2)O(2)/ NO(2)(-)-induced tyrosyl nitration decreased with increasing depth of tyrosyl residues in the membrane. Transmembrane nitrations of tyrosyl-containing peptides induced by both peroxynitrite and MPO/H(2)O(2)/NO(2)(-) were totally inhibited by (.)NO that was slowly released from spermine NONOate. Nitration of peptides in both systems was concentration-dependently inhibited by unsaturated fatty acid. Concomitantly, an increase in lipid oxidation was detected. A mechanism involving (.)NO(2) radical is proposed for peroxynitrite and MPO/H(2)O(2)/NO(2)(-)-dependent transmembrane nitration reactions.     

Phospholipase C-gamma1 interacts with conserved phosphotyrosyl residues in the linker region of Syk and is a substrate for Syk.

Antigen receptor ligation on lymphocytes activates protein tyrosine kinases and phospholipase C-gamma (PLC-gamma) isoforms. Glutathione S-transferase fusion proteins containing the C-terminal Src-homology 2 [SH2(C)] domain of PLC-gamma1 bound to tyrosyl phosphorylated Syk. Syk isolated from antigen receptor-activated B cells phosphorylated PLC-gamma1 on Tyr-771 and the key regulatory residue Tyr-783 in vitro, whereas Lyn from the same B cells phosphorylated PLC-gamma1 only on Tyr-771. The ability of Syk to phosphorylate PLC-gamma1 required antigen receptor ligation, while Lyn was constitutively active. An mCD8-Syk cDNA construct could be expressed as a tyrosyl-phosphorylated chimeric protein tyrosine kinase in COS cells, was recognized by PLC-gamma1 SH2(C) in vitro, and induced tyrosyl phosphorylation of endogenous PLC-gamma1 in vivo. Substitution of Tyr-525 and Tyr-526 at the autophosphorylation site of Syk in mCD8-Syk substantially reduced the kinase activity and the binding of this variant chimera to PLC-gamma1 SH2(C) in vitro; it also failed to induce tyrosyl phosphorylation of PLC-gamma1 in vivo. In contrast, substitution of Tyr-348 and Tyr-352 in the linker region of Syk in mCD8-Syk did not affect the kinase activity of this variant chimera but almost completely eliminated its binding to PLC-gamma1 SH(C) and completely eliminated its ability to induce tyrosyl phosphorylation of PLC-gamma1 in vivo. Thus, an optimal kinase activity of Syk and an interaction between the linker region of Syk with PLC-gamma1 are required for the tyrosyl phosphorylation of PLC-gamma1.     

Involvement of tyrosyl residues in the structure-function relationships of D-beta-hydroxybutyrate dehydrogenase: a phospholipid-requiring enzyme

The involvement of tyrosyl residues in the function of D-beta-hydroxybutyrate dehydrogenase, a lipid-requiring enzyme, has been investigated by using several tyrosyl modifying reagents, i.e., N-acetylimidazole, a hydrophilic reagent, and 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole and tetranitromethane, two hydrophobic reagents. Modification of the tyrosyl residues highly inactivates the derived enzyme: Treatment of the enzyme with 7-chloro-4-nitro[14C]benzo-2-oxa-1,3-diazole leads to an absorbance at 380 nm and to an incorporation of about 1 mol of 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole per polypeptide chain for complete inactivation. Inactivation by N-acetylimidazole induces a decrease in absorbance at 280 nm which can be reversed by hydroxylamine treatment. On the other hand, the ligands of the active site, such as methylmalonate, a pseudosubstrate, and NAD+ (or NADH), do not protect the enzyme against inactivation. In contrast, the presence of phospholipids strongly protects the enzyme against hydrophobic reagents. Finally, previous modification of the enzyme with N-acetylimidazole does not affect the incorporation of 7-chloro-4-nitro[14C]benzo-2-oxa-1,3-diazole while modification with tetranitromethane does. These results indicate the existence of two classes of tyrosyl residues which are essential for enzymatic activity, and demonstrate their location outside of the active site. One of these residues appears to be located close to the enzyme-phospholipid interacting sites. These essential residues may also be essential for maintenance of the correct active conformation.     

Studies on the alkali light chains of vertebrate skeletal muscle myosin. Effect of tyrosyl modification on the ability to reassociate to heavy chains

The structures of the alkali light chain subunits A1 and A2 have been studied by examining the effect of the conformationally sensitive reagent tetranitromethane, which reacts specifically with tyrosyl residues. Whereas reaction in the presence of 6 M guanidine hydrochloride results in modification of the three tyrosyl residues of both these light chains, only two tyrosyl residues are exposed to the reagent in the native conformations of these proteins. By gel chromatography of the CNBr-cleaved chains it was demonstrated that the two reactive tyrosyls are those located in the CB-1 and CB-3 segments and that these tyrosyl residues are modified simultaneously and not sequentially. The unreactive tyrosyl residue is in the CB-6 segment and is separated by two residues from the single cysteinyl residue of these chains. It is found that the modified light chains cannot be made to reassociate with the heavy chains by the NH4Cl hybridization procedure of Wagner and Weeds [J. Mol. Biol. 109, 455-470 (1977)] or by the thermal hybridization procedure [Burke and Sivaramakrishnan (1981) Biochemistry 20, 5908-5913]. Furthermore, reduction of the nitrotyrosyl groups to aminotyrosyl residues by sodium dithionite does not restore this effect. The data suggest that regions of the light chains at CB-1 and CB-3 are involved in the association to the heavy chains.     

Interaction of tyrosyl, histidyl, and tryptophanyl peptides with DNA: specificity and mechanism of the interaction

In the Tyr-(Gly)_1-4-Tyr series maximal thermal stabilization of calf thymus DNA (δT_m=10°) occurred with the Tyr-(Gly)₂-Tyr peptide, where three base pairs could separate the two tyrosyl residues. Tyr-Gly-Tyr-Gly-Tyr stabilized the DNA by 6°. The alternating Trp-Gly-Trp-Gly-Trp and His-Gly-His-Gly-His peptides were equally as effective as the Tyr-Gly-Tyr-Gly-Tyr peptide in stabilizing calf thymus DNA against thermal denaturation. But the alternating Phe-Gly-Phe-Gly-Phe peptide afforded little stabilization, suggesting that a sidechain possessing both a conjugated π-electron system and an electron donor atom is necessary for DNA stabilization. Introduction of electron withdrawing iodo or nitro group into the tyrosyl sidechains almost completely abolished the stabilizing effect. Although the tyrosyl peptides seem to be specific for GC-base pairs, no correlation was found in natural DNA between% GC and% thermal stabilization. Eukaryotic DNAs showed twice the stabilization of prokaryotic DNAs with the same GC content.     

Evidence for radical formation at Tyr-353 in Mycobacterium tuberculosis catalase-peroxidase (KatG)

Mycobacterium tuberculosis KatG is a heme-containing catalase-peroxidase responsible for activation, through its peroxidase cycle, of the front line antituberculosis antibiotic isoniazid (isonicotinic acid hydrazide). Formation of Compound I (oxyferryl heme-porphyrin pi-cation radical), the classical peroxidase intermediate generated when the resting enzyme turns over with alkyl peroxides, is rapidly followed by production of a protein-centered tyrosyl radical in this enzyme. In our efforts to identify the residue at which this radical is formed, nitric oxide was used as a radical scavenging reagent. Quenching of the tyrosyl radical generated in the presence of NO was shown using electron paramagnetic resonance spectroscopy, and formation of nitrotyrosine was confirmed by proteolytic digestion followed by high performance liquid chromatography analysis of the NO-treated enzyme. These results are consistent with formation of nitrosyltyrosine by addition of NO to tyrosyl radical and oxidation of this intermediate to nitrotyrosine. Two predominant nitrotyrosine-containing peptides were identified that were purified and sequenced by Edman degradation. Both peptides were derived from the same M. tuberculosis KatG sequence spanning residues 346-356 with the amino acid sequence SPAGAWQYTAK, and both peptides contained nitrotyrosine at residue 353. Some modification of Trp-351 most probably into nitrosotryptophan was also found in one of the two peptides. Control experiments using denatured KatG or carried out in the absence of peroxide did not produce nitrotyrosine. In the mutant enzyme KatG(Y353F), which was constructed using site-directed mutagenesis, a tyrosyl radical was also formed upon turnover with peroxide but in poor yield compared with wild-type KatG. Residue Tyr-353 is unique to M. tuberculosis KatG and may play a special role in the function of this enzyme.     

Uridine(5')diphospho(1)-alpha-D-glucose. A binding study to glycogen phosphorylase b in the crystal

UDP-glucose is an R-state inhibitor of glycogen phosphorylase b, competitive with the substrate, glucose 1-phosphate and noncompetitive with the allosteric activator, AMP. Diffusion of 100 mM UDP-glucose into crystals of phosphorylase b resulted in a difference Fourier synthesis at 0.3-nm resolution that showed two peaks: (a) binding at the allosteric site and (b) binding at the catalytic site. At the allosteric site the whole of the UDP-glucose molecule can be located. It is in a well defined folded conformation with its uracil portion in a similar position to that observed for the adenine of AMP. The uracil and the glucose moieties stack against the aromatic side chains of Tyr-75 and Phe-196, respectively. The phosphates of the pyrophosphate component interact with Arg-242, Arg-309 and Arg-310. At the catalytic site, the glucose-1-P component of UDP-glucose is firmly bound in a position similar to that observed for glucose 1-phosphate. The pyrophosphate is also well located with the glucose phosphate interacting with the main-chain NH groups at the start of the glycine-loop alpha helix and the uridine phosphate interacting through a water molecule with the 5'-phosphate of the cofactor pyridoxal phosphate and with the side chains of residues Tyr-573, Lys-574 and probably Arg-569. However the position of the uridine cannot be located although analysis by thin-layer chromatography showed that no degradation had taken place. Binding of UDP-glucose to the catalytic site promotes extensive conformational changes. The loop 279-288 which links the catalytic site to the nucleoside inhibitor site is displaced and becomes mobile. Concomitant movements of residues His-571, Arg-569, and the loop 378-383, together with the major loop displacement, result in an open channel to the catalytic site. Comparison with other structural results shows that these changes form an essential feature of the T to R transition. They allow formation of the phosphate recognition site at the catalytic site and destroy the nucleoside inhibitor site. Kinetic experiments demonstrate that UDP-glucose activates the enzyme in the presence of high concentrations of the weak activator IMP, because of its ability to decrease the affinity of IMP for the inhibitor site.     

The binding sites of insulin-like growth factor I (IGF I) to type I IGF receptor and to a monoclonal antibody. Mapping by chemical modification of tyrosine residues

The surface topography of IGF I(insulin-like growth factor I) was investigated by chemical modification of amino acid residues in free IGF I and bound to type I IGF receptor or to monoclonal antibody MAB43. Tyrosine residues were modified either by chloramine-T or lactoperoxidase catalyzed iodination. In the free IGF I molecule, all 3 tyrosine residues, A19 (Tyr-60), B25 (Tyr-24), and C2 (Tyr-31), were iodinated. Monoclonal antibody MAB43 protected IGF I against modification at tyrosine residue A19, and in the type I IGF receptor-IGF I complex, all 3 tyrosine residues were shielded against iodine incorporation. These results allow the prediction of the binding domains in the IGF I molecule. The minimal receptor binding site in IGF I would include amino acid residues B25 to C2 and, possibly, the C-terminal part of the A-domain with tyrosine residue A19.     

Serum albumin: Search for new sites of interaction with organophosphorus compounds by the example of soman

Albumin is known to be able to interact with organophosphorus compounds (OPCs), but neither amino acid residues of albumin that are responsible for this interaction nor the nature of the forming bonds have been finally established. Catalytic and pseudocatalytic functions of albumin are under consideration. Possible sites of interaction of albumin with soman have been elucidated by the methods of molecular modeling. Structures of the soman-albumin complexes have been determined by molecular docking. Stability of the obtained complexes has been evaluated by the method of molecular dynamics. The chemical bond between soman and the tyrosine-411 residue has been found to form only after deprotonation of the latter. The tyrosine-150 residue of albumin binds soman more effectively than tyrosine-411, and the tyrosine-150-deprotonation does not determine the efficacy of the binding (sorption) of soman, but affects the stability of the formed bound. It was proposed that the albumin residues of tyrosine-150 and serine-193 could serve as sites of the catalytic interaction with soman. We hypothesized that the deprotonation of an amino acid residue in one albumin site influenced initiation of the ligand binding in the other albumin site (allosteric albumin regulation).     

Glycogen phosphorylase of skeletal muscles

A review is given on the affinity modification of pyridoxal phosphate and AMP-binding sites as well as on the chemical modification of essential amino acid residues of phosphorylase (histidine residue of the substrate-binding site and cysteine residue of the coenzyme-binding site). The role of allosteric effectors (AMP and glucose-6-phosphate) and functionally important centers of the protein in conformational transitions of rabbit muscle phosphorylase b is discussed. The kinetic properties of rabbit and bovine muscle phosphorylase are compared. Bovine muscle phosphorylase is shown to be a partly phosphorylated form of the enzyme. Some peculiarities of the pH-dependence of kinetic behaviour of the hybrid form of the bovine muscle enzyme are discussed.     

Investigation by photochemically-induced dynamic nuclear polarization and nuclear Overhauser enhancement 1H-NMR of the interaction between beta-endorphin and phospholipid micelles

The photochemically-induced dynamic nuclear polarization technique has been used to investigate the access of a photoexcited flavin dye to tyrosyl and histidyl residues in [Met]enkephalin and human and camel beta-endorphins, both alone and in the presence of n-dodecylphosphorylcholine micelles. The results indicate that the mode of binding of Tyr-1, but not of residue 27, is similar in the two endorphins and differs from that of Tyr-1 in [Met]enkephalin. In human beta-endorphin, accessibility and mobility of Tyr-27 are strongly reduced in the presence of lipid at physiological pH, whereas in camel beta-endorphin His-27 becomes immobilized only at high pH. Moreover, nuclear Overhauser enhancement experiments suggest a rigidifying influence of the peptide on the polar head groups of the micelles.     

Reaction of chicken egg white lysozyme with 7-chloro-4-nitrobenz-2-oxa-1,3-diazole. II. Sites of modification.

1. Procedure for the isolation of peptides from proteins bearing the chemically labile aromatic ether, O-tyrosyl-4-nitrobenz-2-oxa-1,3-diazole group, is described. 2. The tyrosyl residue reactive towards 7-chloro-4-nitrobenz-2-oxa-1,3-diazole in chicken egg white lysozyme (Aboderin, A. A., Boedefeld, E. and Luisi, P. L., (1973) Biochim. Biophys. Acta 328. 20-30) is tyrosine-23. The amino group in the protein whose reaction with the reagent is dependent on the prior reaction of tyrosine-23 is the epsilon-amino group of lysine-33.