The role of epsilon-amino groups of lysine of human serum albumin in heat-induced protein denaturation. Increased stability of glycosylated and alkylated albumin in aggregation during heating

Human serum albumin was glycosidated by prolonged protein incubation in phosphate buffer, pH 6.8-7.0, with excess glucose at 37 degrees C. epsilon-amino groups of lysine residues of the albumin molecule were alkylated by pyridoxal-5-phosphate in the presence of NaBH4. The solutions of glycosidated and alkylated serum albumin were incubated at different temperature values in the range of 20 to 80 degrees C in phosphate buffer, pH 7.0, over 30 min. The nondenatured monomer and the resulting aggregated were isolated by TSK-HW-55-gel column chromatography and polyacrylamide gel electrophoresis. The stability of modified proteins elevated in parallel to the increase in the number of the ligand molecules covalently bound to albumin amino groups. The 1-3% aqueous solutions of glycosidated serum albumin containing 3-4 glucose residues and those of alkylated albumin containing 6-7 residues of pyridoxal-5-phosphate were stable on heating up to 80 degrees C and did not form aggregates. Under these conditions the initial serum albumin completely aggregated. Preincubation of the aggregated albumin with glucose at 37 degrees C resulted in protein "renaturation" to the monomeric form with a small number of dimers and trimers.     

Probe dependence of correlation times in heme-free extrinsically labeled human hemoglobin

Human heme-free hemoglobin was labeled at beta 93 with either N-iodoacetylaminoethyl-5-naphthalene-1-sulfonate (AEDANS) or fluorescein iodoacetamide (FIA), at beta 1 with pyridoxal-5-phosphate (PLP) and at the heme pocket with anilinonaphthalene-8-sulfonate (ANS). The correlation times associated with these probes ranged from approximately 12 ns for FIA and AEDANS to nearly 20 ns for ANS and PLP. This indicates the presence of internal flexibility in apohemoglobin with librational motions dominated by the mobilities of the monomeric subunits and of the entire dimeric molecules, variously weighted by the different probes. It was not possible to detect motions characterized by correlation times of about 5 ns such as were present in AEDANS-labeled oxyhemoglobin.     

Serine Hydroxymethyltransferase from Mung Bean (Vigna radiata) Is Not a Pyridoxal-5'-Phosphate-Dependent Enzyme

Serine hydroxymethyltransferase from mammalian and bacterial sources is a pyridoxal-5′-phosphate-containing enzyme, but the requirement of pyridoxal-5′-phosphate for the activity of the enzyme from plant sources is not clear. The specific activity of serine hydroxymethyltransferase isolated from mung bean (Vigna radiata) seedlings in the presence and absence of pyridoxal-5′-phosphate was comparable at every step of the purification procedure. The mung bean enzyme did not show the characteristic visible absorbance spectrum of a pyridoxal-5′-phosphate protein. Unlike the enzymes from sheep, monkey, and human liver, which were converted to the apoenzyme upon treatment with l-cysteine and dialysis, the mung bean enzyme similarly treated was fully active. Additional evidence in support of the suggestion that pyridoxal-5′-phosphate may not be required for the mung bean enzyme was the observation that pencillamine, a well-known inhibitor of pyridoxal-5′-phosphate enzymes, did not perturb the enzyme spectrum or inhibit the activity of mung bean serine hydroxymethyltransferase. The sheep liver enzyme upon interaction with O-amino-d-serine gave a fluorescence spectrum with an emission maximum at 455 nm when excited at 360 nm. A 100-fold higher concentration of mung bean enzyme-O-amino-d-serine complex did not yield a fluorescence spectrum. The following observations suggest that pyridoxal-5′-phosphate normally present as a coenzyme in serine hydroxymethyltransferase was probably replaced in mung bean serine hydroxymethyltransferase by a covalently bound carbonyl group: (a) inhibition by phenylhydrazine and hydroxylamine, which could not be reversed by dialysis and or addition of pyridoxal-5′ phosphate; (b) irreversible inactivation by sodium borohydride; (c) a spectrum characteristic of a phenylhydrazone upon interaction with phenylhydrazine; and (d) the covalent labeling of the enzyme with substrate/product serine and glycine upon reduction with sodium borohydride. These results indicate that in mung bean serine hydroxymethyltransferase, a covalently bound carbonyl group has probably replaced the pyridoxal-5′-phosphate that is present in the mammalian and bacterial enzymes.     

Rotational dynamics of 4-aminobutyrate aminotransferase

The fluorescence dye 1-anilinonaphthalene-8-sulfonate (ANS) was used as a probe of non-polar binding sites in 4-aminobutyrate aminotransferase. ANS binds to a single binding site of the dimeric protein with a K_d of 6 μM. Nanosecond emission anisotropy measurements were performed on the ANS-enzyme in an effort to detect independent rotation of the subunits in the native enzyme. The observed rotational correlation time (φ = 65 ns) corresponds to the rotation of a rather rigid dimeric structure. The microenvironment surrounding the natural probe pyridoxal-5-P covalently bound to the dimeric structure was explored using ³¹P-NMR at 72.86 MHz. In the native enzyme, the pyridoxal-5-P ³¹P-chemical shift is pH-independent, indicating that the phosphate group is well protected from the solvent. The correlation time determined from the ³¹P-spectrum of the aminotransferase exceeds the value calculated for the hydrated spherical model (φ = 40 ns). It is concluded that the phosphate of the pyridoxal-5-P molecule is rigidly bound to the active site of 4-aminobutyrate aminotransferase.     

Biochemical characterization and helix stabilizing properties of HSNP-C' from the thermoacidophilic archaeon Sulfolobus acidocaldarius

Helix stabilizing nucleoid protein HSNP-C' from the thermophilic archaeon Sulfolobus acidocaldarius has been characterized with respect to its interactions with nucleic acids by gel retardation assay, affinities to immobilized matrices, electron microscopy, and fluorescence titration. The amino acids implicated in the DNA binding site of the protein have been shown by selectively modifying specific amino acyl functional groups and looking at their effects on the DNA binding properties of the protein. Lysine, arginine, tryptophan, and tyrosine residues of the protein HSNP-C' were modified with pyridoxal-5-phosphate; 2,3-butanedione; BNPS-skatole; and tetranitromethane, respectively. The modification of residues was assessed according to standard procedures. The effect of the chemical modification on the function of the protein HSNP-C' with respect to DNA protein interactions was studied and the results indicate the definite involvement of tyrosines and also the significant involvement of the flanking tryptophan residues in the DNA binding domain on the protein.     

Red-edge excitation fluorescence measurements of several two-tryptophan-containing proteins.

The dependence of the fluorescence emission maximum of the tryptophan residues in several two-tryptophan-containing proteins (horse liver alcohol dehydrogenase, yeast 3-phosphoglycerate kinase, Staphylococcus aureus metalloprotease and bee venom phospholipase A2) on the excitation wavelengths has been studied. Using fluorescence-resolved spectroscopy, we have dissected the contributions of particular tryptophan residues located in different parts of the protein molecule. The results demonstrate that dipolar structural relaxation can occur in the environment of tryptophan residues buried within protein molecules. The observed spectral shifts upon red-edge excitation of these residues can depend on temperature or ligand binding, as demonstrated in case of metalloprotease and alcohol dehydrogenase. No spectral shifts upon red-edge excitation have been observed for tryptophan residues totally exposed to the rapidly relaxing aqueous solvent.     

Brain succinic semialdehyde dehydrogenase: identification of reactive lysyl residues labeled with pyridoxal-5'-phosphate

An NAD+ dependent succinic semialdehyde dehydrogenase from bovine brain was inactivated by pyridoxal-5'- phosphate. Spectral evidence is presented to indicate that the inactivation proceeds through formation of a Schiff's base with amino groups of the enzyme. After NaBH(4) reduction of the pyridoxal-5'-phosphate inactivated enzyme, it was observed that 3.8 mol phosphopyridoxyl residues were incorporated/enzyme tetramer. The coenzyme, NAD+, protected the enzyme against inactivation by pyridoxal-5'-phosphate. The absorption spectrum of the reduced and dialyzed pyridoxal-5'-phosphate-inactivated enzyme showed a characteristic peak at 325 nm, which was absent in the spectrum of the native enzyme. The fluorescence spectrum of the pyridoxyl enzyme differs completely from that of the native enzyme. After tryptic digestion of the enzyme modified with pyridoxal-5'-phosphate followed by [3H]NaBH4 reduction, a radioactive peptide absorbing at 210 nm was isolated by reverse-phase HPLC. The sequences of the peptide containing the phosphopyridoxyllysine were clearly identical to sequences of other mammalian succinic semialdehyde dehydrogenase brain species including human. It is suggested that the catalytic function of succinic semialdehyde dehydrogenase is modulated by binding of pyridoxal-5'-phosphate to specific Lys(347) residue at or near the coenzyme-binding site of the protein.     

Spectrofluorimetric studies on C-terminal 34 kDa fragment of caldesmon

Analysis of the tryptophan fluorescence emission spectra of caldesmon and its 34 kDa C-terminal fragment indicates that all tryptophan residues are located on the surface of the molecule, accessible to solvent. All three tryptophan residues of the 34 kDa fragment and four of the five tryptophan residues of intact protein are accessible to free water, whereas one located in the N-terminal region of molecule is accessible only to bound water molecules. The temperature dependence of the fluorescence parameters indicates higher thermal stability of the 34 kDa fragment than the whole caldesmon molecule. The interaction of the 34 kDa fragment of caldesmon (like that of the intact molecule) with calmodulin is accompanied by a blue shift of the fluorescence emission maximum and an increase in the relative quantum yield. Computer-calculated binding constants show that the binding of calmodulin to the 34 kDa fragment (K = 2.5 x 10(5) M-1) is of two orders of magnitude weaker than that to intact caldesmon (K = 1.4 x 10(7) M-1). The interaction with tropomyosin results in a blue shift of the spectrum of the 34 kDa fragment, yet there is no effect on the spectrum of intact caldesmon. Binding constants of tropomyosin to caldesmon (K = 3.8 x 10(5) M-1) and its 34 kDa fragment (K = 2.3 x 10(5) M-1) are similar. Binding of calmodulin to caldesmon and to the 34 kDa fragment affects their interaction with tropomyosin.     

Interaction of pyridoxal-5-phosphate with human serum albumin and pancreatic ribonuclease

Pyridoxal-5-phosphate (in a lesser degree, pyridoxal) interacts with both non-protonated and protonated exposed epsilon-amino groups of lysine residues and with alpha-amino groups in human serum albumin and pancreatic ribonuclease A. The reaction of Schiff base formation proceeds within a wide pH range--from 3.0 to 12.0. At a great pyridoxal-5-phosphate excess in ribonuclease A in neutral or slightly acidic aqueous media all the ten epsilon-amino groups of lysine residues and the alpha-amino groups of Lys-1 become modified. The formation of aldimine bonds of pyridoxal-5-phosphate with protonated amino groups in acidic media is determined by ionization of its phenol hydroxyl and phosphate residues. Acetaldehyde, propionic aldehyde and pyridine aldehyde interact only with non-protonated amino groups of the proteins. The equilibrium constants of pyridoxal-5-phosphate and other aldehydes binding to proteins and amino acids were determined. The rate constants of Schiff base formation for pyridoxal-5-phosphates with some amino acids and primary sites of proteins for direct and reverse reactions were calculated.     

Inactivation of brain myo-inositol monophosphate phosphatase by pyridoxal-5'-phosphate

Myo-inositol monophosphate phosphatase (IMPP) is a key enzyme in the phosphoinositide cell-signaling system. This study found that incubating the IMPP from a porcine brain with pyridoxal-5'-phosphate (PLP) resulted in a time-dependent enzymatic inactivation. Spectral evidence showed that the inactivation proceeds via the formation of a Schiff's base with the amino groups of the enzyme. After the sodium borohydride reduction of the inactivated enzyme, it was observed that 1.8 mol phosphopyridoxyl residues per mole of the enzyme dimer were incorporated. The substrate, myo-inositol-1-phosphate, protected the enzyme against inactivation by PLP. After tryptic digestion of the enzyme modified with PLP, a radioactive peptide absorbing at 210 nm was isolated by reverse-phase HPLC. Amino acid sequencing of the peptide identified a portion of the PLP-binding site as being the region containing the sequence L-Q-V-S-Q-Q-E-D-I-T-X, where X indicates that phenylthiohydantoin amino acid could not be assigned. However, the result of amino acid composition of the peptide indicated that the missing residue could be designated as a phosphopyridoxyl lysine. This suggests that the catalytic function of IMPP is modulated by the binding of PLP to a specific lysyl residue at or near its substrate-binding site of the protein.     

The reactivity of tryptophan residues in proteins. Stopped-flow kinetics of fluorescence quenching.

The quenching of tryptophan fluorescence by N-bromosuccinamide, studied by the fluorescence stopped-flow technique, was used to compare the reactivities of tryptophan residues in protein molecules. The reaction of N-bromosuccinamide with the indole group of N-acetyltryptophanamide, a model compound for bound tryptophan, followed second-order kinetics with a rate constant of (7.8 +/- 0.8) . 10(5) dm3 . mol-1 . s-1 at 23 degrees C. The rate does not depend on ionic strength or on the pH near neutrality. The non-fluorescent intermediate formed from N-acetyltryptophanamide on the reaction with N-bromosuccinamide appears to be a bromohydrin compound. The second-order rate constant for fluorescence quenching of tryptophan in Gly-Trp-Gly by N-bromosuccinamide was very similar, (8.8 +/- 0.8) . 10(5) dm3 . mol-1 . s-1. Apocytochrome c has the conformation of a random coil with the single tryptophan largely exposed to the solvent. The rate constant for the fluorescence quenching of the tryptophan in apocytochrome c by N-bromosuccinamide was (3.7 +/- 0.3) . 10(5) dm3 . mol-1 . s-1. The fluorescence quenching by N-bromosuccinamide of the tryptophan residues incorporated in alpha-chymotrypsin at pH 7.0 showed three exponential terms from which the following rate constants were derived: 1.74 . 10(5), 0.56 . 10(5) and 0.11 . 10(5) dm3 . mol-1 . s-1. This protein is known to have eight tryptophan residues in the native state, six residues at the surface, and two buried. Three of the surface tryptophans have the indole rings protruding out of the molecule and may account for the fastest kinetic phase of the quenching process. The intermediate phase may be due to three surface tryptophans whose indole rings point inwards, and the slowest to the two interior tryptophan residues.     

Residues 377-389 from the δ subunit ofTorpedo californica acetylcholine receptor are located in the cytoplasmic surface

Torpedo californica acetylcholine receptor (AcChR) enriched, sealed vesicles have been specifically labeled on the cytoplasmic surface with pyridoxal 5′-phosphate (Perez-Ramirez, B., and Martinez-Carrion, M., 1989,Biochemistry 28, 5034–5040). After chromatography of the peptide fragments produced by tryptin digestion of labeled AcChR, several fractions containing the phosphopyridoxyl label were obtained. Edman degradation identified one of the fractions, with sequence SRSELMFEKQSER, as corresponding to residues 377–389 in theδ subunit (primary structure). The latter must be a cytoplasmic region of this transmembranous protein, and residueδK385 must reside in a water-soluble exposed domain of the cytosolic side of the membrane. Introduction of phosphopyridoxyl residues allows for their potential use as probes of conformational changes in the cytosolic surface of the receptor molecule.     

Amino acid sequence of the phosphopyridoxyl peptide from P-protein of the chicken liver glycine cleavage system

A pyridoxal 5'-phosphate-containing peptide which contained 54 amino acid residues was isolated from chicken liver P-protein of the glycine cleavage system following reduction with NaB3H4, carboxymethylation, and proteolysis with lysylendopeptidase. Two peptides which comprise the two halves of the phosphopyridoxyl peptide were isolated from apo-P-protein. Sequence analysis of these three peptides provided the primary structure of the phosphopyridoxyl peptide and revealed that the cofactor is linked to Lys-35. The pyridoxal 5'-phosphate-binding site has the His-Lys(PLP)-X structure characteristic of known pyridoxal 5'-phosphate-dependent amino acid decarboxylases, tryptophan synthase, and serine hydroxymethyltransferase.     

Ricin structure: the study by the fluorescence quenching method

To elucidate the details of pH-induced conformational transformation of ricin [I] in the region surrounding tryptophan residues, we studied parameters of fluorescence of the native toxin and its isolated A- and B-subunits at pH 4.0, 5.0 and 7.4. The studies were carried out using resolution of fluorescence spectra according to different degree of tryptophan accessibility to ionic (iodide) and non-ionic organic (acrylamide) quenchers. Application of the new method allowed to reveal three classes of tryptophan residues differing in their accessibility to quenchers alpha-residues are accessible neither to ions nor to organic molecules; beta-residues are accessible only to organic molecules; while surface gamma-residues are accessible to both types of quenchers. The fluorescence spectra were assessed for each class of tryptophan residues. The major part of them was shown to be localized in apolar rigid microenvironment. Fluorescence of ricin and especially of its isolated subunits proved to be strongly dependent on the pH value. At pH less than 5 the structure of B-chain loosens, this process being reflected by an increase in accessibility of tryptophan residues to quenchers. In acidic solution at least one out of seven tryptophan residues in the ricin molecule undergoes conformational transformation. Positive charge prevails in the regions surrounding quencher-accessible tryptophan residues. Binding of lactose leads to a slight compactization of the toxin structure that causes, in its turn, short-wave shifts of the fluorescence spectra and reduction of Stern-Volmer constants for intraglobular tryptophan residues.     

Presentation of RGDS epitopes on self-assembled nanofibers of branched peptide amphiphiles

Branched peptide amphiphile (PA) molecules bearing biological epitopes were designed and synthesized using orthogonal protecting group chemistry on amine groups at lysine residues. These molecules self-assemble into high-aspect-ratio cylindrical nanofibers, and their branched architecture enhances accessibility of epitopes for protein binding and also allows the presentation of more than one epitope in a single molecule. The RGDS cell adhesion epitope was used as a model bioactive signal on PA molecules for potential biomedical applications. Aggregation of the branched PA molecules into nanofibers was demonstrated by TEM and through shifts in the protonation profiles of peripheral amines. These systems also formed self-supporting gels in the presence of physiological fluids and other biologically relevant macromolecules such as synovial fluid and DNA, an important property for their potential use in medicine. Fluorescence anisotropy measurements on the PAs with tryptophan residues were performed to examine the effect of branching on packing and mobility of the peptides in the self-assembled nanofibers. The mobility of tryptophan residues was observed to be restricted upon packing of PA molecules into nanofibers. However, relative to linear analogues, branched molecules retain more mobility in the supramolecular aggregates.     

Yeast 5S rRNA binding to ribosomal protein L1a alters the fluorescence of tryptophan residues lying outside the binding site.

The yeast ribosomal protein L1a contains two tryptophan residues located at positions 95 and 183. Spectrofluorometric analysis showed that the average tryptophan environment is moderately polar. Quenching studies of the yeast 5S rRNA-L1a protein complex (RNP) with acrylamide and iodide revealed tryptophan heterogeneity. The two tryptophan residues are located in the non-RNA-binding region of the L1a molecule. However, dissociation of the yeast 5S rRNA-L1a protein RNP complex to its components resulted in a decline of tryptophan fluorescence. The observation implied that the environment of the tryptophan-containing L1a regions which were not known to be involved in RNA binding was influenced by association with the 5S rRNA molecule.     

A study of subtilisin types Novo and Carlsberg by circular polarization of fluorescence.

The circular polarization of the luminescence of a chromophore, in addition to its circular dichroism and optical rotatory dispersion, is a manifestation of its asymmetry. In the study of proteins, the circular polarization of luminescence yields more specific information than circular dichroism or optical rotatory dispersion since nonfluorescent chromophores do not contribute, and the spectra of the tyrosine and the tryptophan residues are much better resolved in emission than in absorption. The circular polarization of the fluorescence of the tyrosine and tryptophan residues in derivatives of subtilisin Carlsberg and subtilisin Novo were indeed resolved in this study. The tyrosine residues in the Carlsberg protein, and both tyrosine and tryptophan residues in the Novo protein, were found to be heterogeneous with respect to their optical activity and emission spectra. Changes in the environment of the emitting tyrosine residues in both proteins and in the tryptophan residues in the Novo protein were found on changing the pH from 5.0 to 8.3. The pH dependence of the enzymatic activity of these proteins may thus be due, at least in part, to conformational changes in the molecules. Fluorescence circular polarization also revealed that covalently bound inhibitors at the active site of subtilisin Novo affect the environment of the emitting aromatic side chains, presumably via changes in conformation.     

States of tryptophan residues in castor bean hemagglutinin: the perturbing effects of solvents on tryptophans in hemagglutinin and its complexes as analyzed by UV-difference spectroscopy

The states of tryptophan residues in castor bean hemagglutinin (CBH) were analyzed by solvent perturbation studies employing ultraviolet difference spectroscopy. Eight out of 22 tryptophan residues in CBH were exposed to ethylene glycol and glycerol, suggesting that the remaining 14 tryptophan residues are buried in the interior of the CBH molecule. The fraction of tryptophan residues accessible to the perturbant decreased with increase in the molecular size of the perturbant, and only 2 tryptophan residues were exposed to polyethylene glycol 600. Upon binding with raffinose, 2 tryptophan residues were shielded from the perturbing effect of the solvent, and binding of lactose reduced the number of tryptophan residues accessible to the perturbant by 1 mol per mol of protein. Binding of galactose, however, did not change the accessibility of tryptophan to the perturbant. On the other hand, the accessibility of tyrosine to the perturbant remained unchanged after binding with raffinose and lactose, suggesting that tyrosine is not directly involved in the saccharide binding of CBH. Based on these results, it is proposed that one tryptophan residue at the saccharide-binding site on each B-chain of CBH lies on the surface of the protein molecule and is located at a subsite which is accessible to a glucopyranoside moiety in the lactose molecule or a glycopyranosyl-fructofuranosyl moiety in the raffinose molecule, whereas such a residue is not present at the galactopyranoside-recognition site.     

Gelling properties of apohemoglobin S alone and in mixtures with hemoglobin S

Apohemoglobin S formed a gel in the cold (5 degrees C) with a protein concentration in the supernatants after centrifugation of the gels (Csat) near 27 g/dl, in 0.02 M phosphate buffer at pH 7.2. Under the same experimental conditions in mixtures of apohemoglobin S and deoxyhemoglobin S the solubility of hemoglobin S in the cold was decreased from Csat greater than 40 g/dl in the absence to about 18 g/dl in the presence of apohemoglobin S. Conversely, in the same mixture, Csat of apohemoglobin S was decreased to about 5 g/dl. Also, gelling occurred in mixtures of oxyhemoglobin S and its apoderivative. Apohemoglobin A alone did not form gels; however, it induced fiber formation in deoxyhemoglobin S in the cold; unlike apohemoglobin S, it was not included in the precipitate. Gels of apohemoglobin S were not birefringent, and inspection at the electron microscope failed to show the presence of organized structures. Excluded volume effects were probably at the origin of the decreased solubility of hemoglobin S and apohemoglobin S in the presence of each other.     

Antisense suppression of proline degradation improves tolerance to freezing and salinity in Arabidopsis thaliana

The location of tryptophan residues in the actin macromolecule was studied on the basis of the known 3D structure. For every tryptophan residue the polarity and packing density of their microenvironments were evaluated. To estimate the accessibility of the tryptophan residues to the solvent molecules it was proposed to analyze the radial dependence of the packing density of atoms in the macromolecule about the geometric center of the indole rings of the tryptophan residues. The proposed analysis revealed that the microenvironment of tryptophan residues Trp-340 and Trp-356 has a very high density. So these residues can be regarded as internal and inaccessible to solvent molecules. Their microenvironment is mainly formed by non-polar groups of protein. Though the packing density of the Trp-86 microenvironment is lower, this tryptophan residue is apparently also inaccessible to solvent molecules, as it is located in the inner region of macromolecule. Tryptophan residue Trp-79 is external and accessible to the solvent. All residues that can affect tryptophan fluorescence were revealed. It was found that in the close vicinity of tryptophan residues Trp-79 and Trp-86 there are a number of sulfur atoms of cysteine and methionine residues that are known to be effective quenchers of tryptophan fluorescence. The most essential is the location of SG atom of Cys-10 near the NE1 atom of the indole ring of tryptophan residue Trp-86. On the basis of microenvironment analysis of these tryptophan residues and the evaluation of energy transfer between them it was concluded that the contribution of tryptophan residues Trp-79 and Trp-86 must be low. Intrinsic fluorescence of actin must be mainly determined by two other tryptophan residues--Trp-340 and Trp-356. It is possible that the unstrained conformation of tryptophan residue Trp-340 and the existence of aromatic rings of tyrosine and phenylalanine and proline residues in the microenvironments of tryptophan residues Trp-340 and Trp-356 are also essential to their blue fluorescence spectrum.