The interaction of Ca2+-binding proteins with the carbocyanine dye stains-all

The interaction of the carbocyanine dye Stains-all with the Ca²⁺-binding proteins calmodulin, troponin C, and parvalbumin has been monitored by means of absorption spectra and CD. In the absence of Ca²⁺, complexes with Stains-all of all three proteins exhibit at high dye: protein mole ratios an intense J absorption band at 600–650 nm, which is associated with a characteristic CD spectrum. In the cases of calmodulin and troponin C, the J-band is progressively lost as the dye: protein ratio decreases and is replaced by bands of the γ and β types at 450–550 nm, which likewise give rise to characteristic CD spectra. For parvalbumin, only the J-band is observed; its intensity is undiminished at the lowest dye: protein ratios examined. In the presence of excess Ca²⁺ the J-band is lost for all three proteins. For calmodulin and troponin C it is replaced by σ- and β-bands; in the case of parvalbumin the bound dye is released. A tentative model has been proposed to account for these observations.     

Simultaneous differential staining of nucleic acids, proteins, conjugated proteins and polar lipids by a cationic carbocyanine dye.

The multiple interactions of the cationic carbocyanine dye, 1-ethyl-naptho-[1,2d]thiazolin-2-ylidene)-2-methylpropenyl]naptho[1,2d]thiazolium bromide, 'Stains-described. Many of these substances could be distinguished from one another on the basis of color in conjunction with chemical and enzymatic digestions. Further studies with this dye have shown that under certain conditions polar lipids as well may be distinguished from these substances. Stains-all has a highly sensitive metachromatic reaction for the presence of polar lipids. It is possible to detect the lipids in large part because they are green and contrast with a red- or pink-stained protein background and with the blue-purple of nuclei or cartilage. Where other green substances occur as in sialoglycoproteins of mucous or membranes, the lipids can be distinguished because they are extracted by chloroform-methanol (2:1) or pyridine.     

Spinach ferredoxin is a calcium-binding protein

Spinach-leaf ferredoxin was identified as a calcium-binding protein by ⁴⁵Ca autoradiography on nitrocellulose membranes and with the cationic carbocyanine dye 1-ethyl-2-[3-(1-ethylnaphtho[1,2-d]thiazolin-2-ylidene)-2-methylpropenyl] naphtho[1,2-d]thiazolium bromide (stains-all). Binding of ⁴⁵Ca was observed at pH 6.8 and pH 7.8 and in the presence of 5 mM and 20 mM MgCl₂. At the higher MgCl₂ concentration the Ca²⁺-binding capacity is reduced. Only micromolar concentrations of LaCl₃, however, are required to achieve a similar effect. Both the oxidized and reduced forms of ferredoxin bind calcium.Abbreviations PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulfate - stains-all 1-ethyl-2-[3-(1-ethylnaphtho[1,2-d]thiazolin-2-ylidene)-2-methylpropenyl] naptho[1,2-d]thiazolium bromide     

Metabolic activation of a mutagen, 2-amino-6-methyldipyrido-[1,2-a:3′,2′-d]imidazole. Identification of 2-hydroxyamino-6-methyldipyrido[1,2-a:3′,2′-d]imidazole and its reaction with DNA

A potent mutagen, 2-amino-6-methyldipyrido[1,2-a:3′,2′-d]imidazole(Glu-P-1), isolated from pyrolysates of L-glutamic acid and casein, was metabolically activated and bound to DNA. An activated form was identified as 2-hydroxyamino-6-methyldipyrido[1,2-a:3′,2′-d]imidazole(N-OH-Glu-P-1). Synthetic N-OH-Glu-P-1 reacted with DNA only after O-acetylation to give a modified DNA, which on hydrolysis gave 2-(C⁸-guanyl)amino-6-methyldipyrido[1,2-a:3′,2′-d]imidazole(gua-Glu-P-1). The same adduct was isolated from DNA modified with Glu-P-1 by microsomes in vitro, as reported earlier.     

Smooth-muscle endoplasmic reticulum contains a cardiac-like form of calsequestrin

It is proposed that smooth-muscle endoplasmic reticulum contains calsequestrin and that this protein in smooth muscle resembles cardiac calsequestrin more than the skeletal-muscle form. This proposal is based on seven similarities between the smooth-muscle protein and cardiac calsequestrin. Proteins with an Mr of 55,000 can be extracted from the membranes of smooth muscle and of cardiac muscle using 100 mM Na2CO3. The protein from smooth muscle binds to phenyl-Sepharose in the absence of Ca2+ and is released by 10 mM CaCl2, as has been observed for cardiac calsequestrin. The protein from smooth muscle comigrates with the cardiac calsequestrin on Laemmli-type SDS-polyacrylamide gel electrophoresis. The protein of Mr 55,000 from smooth muscle and cardiac calsequestrin both strain blue with the carbocyanine dye Stains-all. Both proteins present similar one-dimensional Cleveland peptide maps although minor differences might exist. From an analysis of subcellular membranes separated by sucrose gradient centrifugation it is concluded that the protein with Mr 55,000 from the smooth muscle is confined to the endoplasmic reticulum, the same subcellular structure from which, in heart muscle, calsequestrin can be isolated. Antibodies raised against canine cardiac calsequestrin bind to a protein of similar Mr in smooth-muscle endoplasmic reticulum. In addition to the calsequestrin, three other extrinsic proteins with an Mr of 130,000, 100,000 and 63,000, stain blue with Stains-all and occur in the endoplasmic reticulum of smooth muscle.     

Conformation of alginate and pectate chains monitored by the binding of the dye stains-all.

The carbocyanine dye Stains-all displays spectral colour shifts or metachromasia upon binding to proteins, polysaccharides and other anionic substrates. The conformational status of the binding region of the substrate appears to govern the metachromatic features of the bound Stains-all. We have used this property to derive information about the conformational differences between the two anionic polysaccharides alginate and pectate. The stronger induction of circular dichroism in the 500 nm region of the dye by pectate is indicative of a greater extent of helical order in this polymer in solution than in the alginate or perhaps even hyaluronate chains.     

Purification of a sarcoplasmic reticulum protein that binds Ca2+ and plasma lipoproteins

A protein in the sarcoplasmic reticulum of rabbit skeletal and cardiac muscle was identified because of its ability to bind 125I-labeled low density lipoprotein (LDL) with high affinity after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This protein, referred to as the 165-kDa protein, is restricted to striated muscle. It was not detected in 14 other tissues, including several that contain smooth muscle, but it appears in rat L6 myoblasts when they differentiate into myocytes. Immunofluorescence and immunoelectron microscopic studies revealed that the protein is present throughout the sarcoplasmic reticulum and the terminal cisternae. It binds 45Ca2+ on nitrocellulose blots and stains metachromatically with Stains-all, a cationic dye that stains Ca2+-binding proteins. It does not appear to be a glycoprotein, and it appears slightly larger than the 160-kDa glycoprotein previously described in sarcoplasmic reticulum. The 165-kDa protein binds LDL, beta-migrating very low density lipoprotein, and a cholesterol-induced high density lipoprotein particle that contains apoprotein E as its sole apoprotein with much higher affinity than it binds high density lipoprotein. The protein is stable to boiling and to treatment with sodium dodecyl sulfate, but it becomes sensitive to these treatments when its cystine residues are reduced and alkylated. The protein was purified 1300-fold to apparent homogeneity from rabbit skeletal muscle membranes. It differs from the cell surface LDL receptor in that 1) its apparent molecular weight is not changed by reduction and alkylation; 2) it is present in Watanabe-heritable hyperlipidemic rabbits, which lack functional LDL receptors; 3) binding of lipoproteins is not inhibited by EDTA; and 4) it is located within the lumen of the sarcoplasmic reticulum where it has no access to plasma lipoproteins. It is unlikely that this protein ever binds lipoproteins in vivo; however, its lipoprotein binding activity has facilitated its purification to homogeneity and suggests that this protein has unusual structural features. The role of the 165-kDa protein in Ca2+ homeostasis in the sarcoplasmic reticulum, if any, remains to be determined.     

The interaction of calmodulin with the carbocyanine dye (Stains-all)

The dye "Stains-all" combines with calmodulin to yield a series of complex species whose absorption and circular dichroism spectra are sensitive to the presence of Ca2+ or Mg2+. At high dye:calmodulin ratios, the dominant complex formed is characterized by a strong absorption band at 600-650 nm, which is associated with a biphasic circular dichroism band. These spectral features are abolished in the presence of Ca2+.     

Affinity labeling of annexin VI with a triazine dye, Cibacron blue 3GA. Probable interaction of the dye with C-terminal nucleotide-binding site within the annexin molecule.

Annexin VI (AnxVI) from porcine liver, a member of the annexin family of Ca(2+)- and membrane-binding proteins, has been shown to bind ATP in vitro with a K(d) in the low micromolar concentration range. However, this protein does not contain within its primary structure any ATP-binding consensus motifs found in other nucleotide-binding proteins. In addition, binding of ATP to AnxVI resulted in modulation of AnxVI function, which was accompanied by changes in AnxVI affinity to Ca2+ in the presence of ATP. Using limited proteolytic digestion, purification of protein fragments by affinity chromatography on ATP-agarose, and direct sequencing, the ATP-binding site of AnxVI was located in a C-terminal half of the AnxVI molecule. To further study AnxVI-nucleotide interaction we have employed a functional nucleotide analog, Cibacron blue 3GA (CB3GA), a triazine dye which is commonly used to purify multiple ATP-binding proteins and has been described to modulate their activities. We have observed that AnxVI binds to CB3GA immobilized on agarose in a Ca(2+)-dependent manner. Binding is reversed by EGTA and by ATP and, to a lower extent, by other adenine nucleotides. CB3GA binds to AnxVI also in solution, evoking reversible aggregation of protein molecules, which resembles self-association of AnxVI molecules either in solution or on a membrane surface. Our observations support earlier findings that AnxVI is an ATP-binding protein.     

Multivalent interactions of calcium/calmodulin-dependent protein kinase II with the postsynaptic density proteins NR2B, densin-180, and alpha-actinin-2

Dendritic calcium/calmodulin-dependent protein kinase II (CaMKII) is dynamically targeted to the synapse. We show that CaMKIIalpha is associated with the CaMKII-binding proteins densin-180, the N-methyl-D-aspartate receptor NR2B subunit, and alpha-actinin in postsynaptic density-enriched rat brain fractions. Residues 819-894 within the C-terminal domain of alpha-actinin-2 constitute the minimal CaMKII-binding domain. Similar amounts of Thr286-autophosphorylated CaMKIIalpha holoenzyme [P-T286]CaMKII bind to alpha-actinin-2 as bind to NR2B (residues 1260-1339) or to densin-180 (residues 1247-1495) in glutathione-agarose cosedimentation assays, even though the CaMKII-binding domains share no amino acid sequence similarity. Like NR2B, alpha-actinin-2 binds to representative splice variants of each CaMKII gene (alpha, beta, gamma, and delta), whereas densin-180 binds selectively to CaMKIIalpha. In addition, C-terminal truncated CaMKIIalpha monomers can interact with NR2B and alpha-actinin-2, but not with densin-180. Soluble alpha-actinin-2 does not compete for [P-T286]CaMKII binding to immobilized densin-180 or NR2B. However, soluble densin-180, but not soluble NR2B, increases CaMKII binding to immobilized alpha-actinin-2 by approximately 10-fold in a PDZ domain-dependent manner. A His6-tagged NR2B fragment associates with GST-densin or GST-actinin but only in the presence of [P-T286]CaMKII. Similarly, His6-tagged densin-180 or alpha-actinin fragments associate with GST-NR2B in a [P-T286]CaMKII-dependent manner. In addition, GST-NR2B and His6-tagged alpha-actinin can bind simultaneously to monomeric CaMKII subunits. In combination, these data support a model in which [P-T286]CaMKIIalpha can simultaneously interact with multiple dendritic spine proteins, possibly stabilizing the synaptic localization of CaMKII and/or nucleating a multiprotein synaptic signaling complex.     

Photolabeling of myelin basic protein in lipid vesicles with the hydrophobic reagent 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine

The hydrophobic photolabel 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine([125I]TID) was used to label myelin basic protein or polylysine in aqueous solution and bound to lipid vesicles of different composition. Although myelin basic protein is a water soluble protein which binds electrostatically only to acidic lipids, unlike polylysine it has several short hydrophobic regions. Myelin basic protein was labeled to a significant extent by TID when in aqueous solution indicating that it has a hydrophobic site which can bind the reagent. However, myelin basic protein was labeled 2-4-times more when bound to the acidic lipids phosphatidylglycerol, phosphatidylserine, phosphatidic acid, and cerebroside sulfate than when bound to phosphatidylethanolamine, or when in solution in the presence of phosphatidylcholine vesicles. It was labeled 5-7-times more than polylysine bound to acidic lipids. These results suggest that when myelin basic protein is bound to acidic lipids, it is labeled from the lipid bilayer rather than from the aqueous phase. However, this conclusion is not unequivocal because of the possibility of changes in the protein conformation or degree of aggregation upon binding to lipid. Within this limitation the results are consistent with, but do not prove, the concept that some of its hydrophobic residues penetrate partway into the lipid bilayer. However, it is likely that most of the protein is on the surface of the bilayer with its basic residues bound electrostatically to the lipid head groups.     

Isolation of a terminal cisterna protein which may link the dihydropyridine receptor to the junctional foot protein in skeletal muscle

The isolated dihydropyridine receptor and junctional foot protein were employed as protein ligands in overlay experiments to investigate the mode of interaction of these two proteins. As previously demonstrated by Brandt et al. [Brandt et al. (1990) J. Membr. Biol. 113, 237-251], the DHP receptor directly binds to an intrinsic terminal cisterna protein of Mr 95,000 (95-kDa protein). The junctional foot protein also binds to an Mr 95,000 protein showing similar organelle distribution to the 95-kDa protein which binds to the dihydropyridine receptor. The 95-kDa protein which binds to the dihydropyridine receptor was isolated to over 85% purity employing sequential column chromatography. Junctional foot protein and dihydropyridine receptor overlays of the column fractions at successive stages of isolation show an identical pattern of distribution, indicating that both probes bind to the same protein. When CHAPS-solubilized terminal cisterna/triads were passed through Sepharose with attached 95-kDa protein, the junctional foot protein was specifically retained, as evidenced by ryanodine binding. The junctional foot protein was incompletely released by 1 M NaCl. The alpha 1 subunit but not the beta subunit of the dihydropyridine receptor was also specifically retained, as evidenced by immunoblotting employing dihydropyridine receptor subunit-specific antibodies. A 170-kDa Stains-all blue staining protein, which appears to be bound to the luminal side of the terminal cisterna, was also retained on the 95-kDa protein column. From these findings, a model for the triad junction is proposed.     

RNA-dependent activation of primer RNA production by influenza virus polymerase: different regions of the same protein subunit constitute the two required RNA-binding sites.

The capped RNA primers required for the initiation of influenza virus mRNA synthesis are produced by the viral polymerase itself, which consists of three proteins PB1, PB2 and PA. Production of primers is activated only when the 5'- and 3'-terminal sequences of virion RNA (vRNA) bind sequentially to the polymerase, indicating that vRNA molecules function not only as templates for mRNA synthesis but also as essential cofactors which activate catalytic functions. Using thio U-substituted RNA and UV crosslinking, we demonstrate that the 5' and 3' sequences of vRNA bind to different amino acid sequences in the same protein subunit, the PB1 protein. Mutagenesis experiments proved that these two amino acid sequences constitute the functional RNA-binding sites. The 5' sequence of vRNA binds to an amino acid sequence centered around two arginine residues at positions 571 and 572, causing an allosteric alteration which activates two new functions of the polymerase complex. In addition to the PB2 protein subunit acquiring the ability to bind 5'-capped ends of RNAs, the PB1 protein itself acquires the ability to bind the 3' sequence of vRNA, via a ribonucleoprotein 1 (RNP1)-like motif, amino acids 249-256, which contains two phenylalanine residues required for binding. Binding to this site induces a second allosteric alteration which results in the activation of the endonuclease that produces the capped RNA primers needed for mRNA synthesis. Hence, the PB1 protein plays a central role in the catalytic activity of the viral polymerase, not only in the catalysis of RNA-chain elongation but also in the activation of the enzyme activities that produce capped RNA primers.     

Interaction of Cibacron Blue F3GA with glutamine synthetase: use of the dye as a conformational probe. 1. Studies using unfractionated dye samples

Cibacron Blue F3GA dye has been used to probe subtle conformational changes in protein structure associated with the conversion of Escherichia coli glutamine synthetase (GS) between relaxed, taut, oxidized, and dissociated forms. Binding of the dye to each form of the enzyme elicits a different spectral perturbation of the dye which can be detected by difference spectroscopy. By following time-dependent changes in the difference spectrum associated with the binding of dye to the enzyme, it was demonstrated that dissociation of subunits provoked either by urea or by relaxation of the enzyme at pH 8.5 is a multiphasic process. In the presence of 3-4 M urea, dissociation of taut GS is associated with an almost instantaneous, transient increase in absorbancy of the difference spectrum at 638 nm and, after a lag, by a progressive decrease in absorbancy at 585 nm and an increase at 700 nm. The kinetics of these changes vary as a function of temperature, pH, and the concentrations of KCl, MnCl2, and urea, probably reflecting differences in the rates of GS relaxation and in the formation of aggregates of intermediate sizes. Results of direct binding measurements show that the taut and relaxed forms of GS can bind only 1-1.3 equiv of dye per subunit, whereas dissociated subunits bind up to 3.0 equiv per subunit. The Kd of the dye-taut GS complex as calculated from binding data was 0.55 microM. The binding of dye to taut GS was inhibited by its substrate, ADP, and by the allosteric effectors AMP and tryptophan. On the basis of the abilities of ADP, AMP, and tryptophan to inhibit the binding of dye to GS, dissociation constants of the respective GS-ligand complexes were 2.4, 121, and 1170 microM, respectively, in good agreement with previously determined values. From the difference spectra obtained between a given concentration of dye in a 5.0-cm cell and 10 times that concentration in a 0.5-cm cell, it was established that at concentrations greater than 5 microM a significant fraction of the dye is present as stacked aggregates. Because only the dye monomer binds to GS, the difference spectrum between dye and dye bound to GS is due in part to GS-promoted shifts in the equilibrium between stacked and unstacked dye molecules. Consequently, with increasing dye concentrations, the amplitude of the dye vs. dye + GS difference spectrum can continue to increase, even after the GS becomes saturated with dye.(ABSTRACT TRUNCATED AT 400 WORDS)     

Purification and characterization of a novel abundant protein in rat bile that binds azo dye metabolites and copper

Following intravenous administration to rats of the azo dye hepatocarcinogen 3'-methyl-N,N-dimethyl-4-aminoazo-[14C]benzene, 60-70% of the injected dose was recovered in bile in 2 h. Approximately 10% of bile radioactivity was trichloroacetic acid-precipitable, not extracted by n-butanol and non-dialyzable. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of bile followed by fluorography revealed two major and several minor proteins to which radiolabelled azo dye metabolites were bound; one of these major proteins (50 kDa) was purified from bile and shown to be homogeneous by SDS-polyacrylamide gel electrophoresis, isoelectric focusing (pI 7) under denaturing conditions and N-terminal analysis. The protein (MBP) comprises 15% of the total bile protein. Amino acid analysis revealed a preponderance of acidic and hydrophobic amino acids. The absorption spectrum of the native protein had a major peak at 280 nm and minor peaks at 345, 400, 600 and 650 nm. The fluorescence spectrum showed a major excitation maxima at 285 and 350 nm and corresponding emission maxima at 345 and 440 nm. Atomic absorption spectroscopy revealed 5 atoms of Cu per mol protein. Approximately 90% of the Cu was EPR silent. MBP did not react with antisera directed against rat serum IgA, albumin or ceruloplasmin; nor did these proteins react against antisera to MBP. Seven distinct peptide bands ranging from 5 to 18 kDa were obtained when MBP was subjected to CNBr cleavage and the digests were analyzed by SDS-polyacrylamide gel electrophoresis. The [14C]-Me-DAB derived radioactivity was present in only two of the peptides, indicating specific binding sites for azodye metabolites.     

Selective retention and formation of a delta5-androstenediol-receptor complex in cell nuclei of the rat vagina.

Cellular protein binding of a number of androstene and androstane derivatives that promote the growth of the vagina in rats has been studied. It was found that cell nuclei of the rat vagina contain a tissue-specific protein that binds 3beta,17beta-dihydroxy-androst-5-ene (delta5-androstenediol), a unique steroid causing growth and keratinization of the vaginal epithelium. The formation of the steroid-protein complex can be demonstrated by the administration of delta5-[3H]androstenediol to ovariectomized rats or by the incubation of minced vagina with the radioactive steroid. The steroid can interact with purified vaginal cell nuclei even in the absence of a cytosol preparation, forming the same steroid-protein complex. The formation of the complex is temperature-dependent; it occurs much more readily at 37 degrees than at 0 degrees. The delta5-[3H]androstenediol-protein complex migrated as about 4 S in a sucrose gradient medium containing 0.4 M KCl. A similar complex can be detected when nuclei of vaginal cells are incubated with 3alpha,17beta-dihydroxy-5alpha-androstane, 3beta,17beta-dihydroxy-5alpha-androstane, and 3beta-hydroxy-androst-5-en-17-one which also have the capability of stimulating vaginal epithelium, although in somewhat different ways. These steroids may bind to different groups of chromatin-bound receptor proteins in various layers of vaginal epithelium. The delta5-androstenediol binding protein is not found in the vaginal cytosol fraction that contains receptor proteins for estrogens and progestins, nor in the cytosol or nuclei of rat uterus cells, but not in muscle, brain, kidney, or liver. Testosterone and 5alpha-dihydrostestosterone bind weakly to the protein, whereas cortisol, androstenedione, 17beta-estradiol, and progesterone do not bind to the same protein by any significant extent.     

Induction of metachromasia and circular dichroism in the dye 1,9-dimethyl methylene blue by ATP

The theoretical prediction of induction of metachromasia [V Czikkely, H D Foersterling & H Kuhn (1970), Chem Phys Lett, 6,207] in a dye by a polyanion having only four to six anionic sites is proved experimentally, for the first time, in ATP--1.9-dimethyl methylene blue system. The findings show that ATP induces metachromasia in the dye at neutral pH, when ATP molecule remains fully charged providing four anionic sites to the dye cations. Conductometric titration shows that the dye molecules bind stoichiometrically to ATP (four dyes/ATP). However ATP at acidic pH and ADP and AMP at any pH fail to induce metachromasia. This is also the first report of induction of circular dichroism in bound dyes by ATP. Though the chiral moiety of ribose sugar in ATP may induce dichroism in the bound achiral dyes, the observed high molar ellipticity values indicate aggregation of bound dyes with twist in one sense initiated by the twisted conformation of the triphosphate chain in ATP. This inference on the state of conformation of ATP in its native environment is in agreement with that derived from PMR and spin lattice relaxation technique. It is thus interesting that the conformation of crystalline disodium ATP, as concluded from X-ray crystallography, is maintained by tetrasodium ATP in dilute aqueous solution--the native environment of ATP.     

Protein substrates activate the ATP-dependent protease La by promoting nucleotide binding and release of bound ADP

The interaction of protein substrates with protease La from Escherichia coli enhances its ability to hydrolyze ATP and peptide bonds. These studies were undertaken to clarify how unfolded proteins allosterically stimulate this ATPase activity. The tetrameric protease can bind four molecules of ATP, which activates proteolysis, or four molecules of ADP, which inhibits enzymatic activity. Protein substrates stimulate binding of the nonhydrolyzable ATP analog [3H] adenyl-5'yl imidodiphosphate, although they do not increase the net binding of [3H]ATP or [3H]ADP. Once bound, ATP is quickly hydrolyzed to ADP, which remains noncovalently associated with protease La even through repeated gel filtrations. Exposure to protein substrates (e.g. denatured bovine serum albumin at 37 degrees C) induces the release of all the bound ADP from the enzyme. Nonhydrolyzable ATP analogs bound to the enzyme were not released by these substrates. Proteins that are not degraded (e.g. native bovine serum albumin) and oligopeptides that only bind to the catalytic site do not induce ADP release. Thus, polypeptide substrates have to interact with an allosteric site to induce this effect. The protein-induced ADP release is inhibited by high concentrations of Mg2+ and is highly temperature-dependent. Protein substrates promoted [3H]ATP binding in the presence of ADP and Mg2+ (i.e. ATP-ADP exchange) and reduced the ability of ADP to inhibit the enzyme's peptidase and ATPase activities. These results indicate that: 1) ADP release is a rate-limiting step in protease La function; 2) bound ADP molecules inhibit protein and ATP hydrolysis in vivo; 3) denatured proteins interact with the enzyme's regulatory site and promote ADP release, ATP binding, and their own hydrolysis.     

Mutagenic activity of methyl-substituted tri- and tetracyclic aromatic sulfur heterocycles

A number of polycyclic aromatic sulfur heterocycles have been identified in coal-derived products and in shale oils. The mutagenic activity of some of these compounds, including dibenzothiophene, benzo[b]naphtho[1,2-d]thiophene, benzo[b]naphtho[2,1-d]thiophene and benzo[b]naphtho[2,3-d]thiophene have been determined using the Salmonella/microsome mutagenicity test. These compounds demonstrated either very weak or no mutagenic activity. The methyl derivatives of each of these four compounds were assayed for mutagenic activity. Salmonella typhimurium TA98 was used as the tester strain. All assays required a rat-liver homogenate metabolic activator. Five of the methylated derivatives, 1-methylbenzo[b]naphtho[1,2-d]thiophene, 3-methylbenzo[b]naphtho[1,2-d]thiophene, 1-methylbenzo[b]-naphtho[2,1-d]thiophene, 6-methylbenzo[b]naphtho[2,1-d]thiophene and 4-methylbenzo[b]naphtho[2,3-d]thiophene demonstrated mutagenic activity. However, activity was observed only at high concentrations of the metabolic activator.