2-Acetylthiamin pyrophosphate (acetyl-TPP) pH-rate profile for hydrolysis of acetyl-TPP and isolation of acetyl-TPP as a transient species in pyruvate dehydrogenase catalyzed reactions

Rate constants for the hydrolysis of acetyl-TPP were measured between pH values of 2.5 and 7.5 and plotted as log kobs versus pH. The pH-rate profile defined two legs, each with a slope of +1 but separated by a region of decreased slope between pH 4 and pH 6. The rates were insensitive to buffer concentrations. Each leg of the profile reflected specific-base-catalyzed hydrolysis of acetyl-TPP, analogous to the hydrolysis of 2-acetyl-3,4-dimethylthiazolium ion [Lienhard, G.E. (1966) J. Am. Chem. Soc. 88, 5642-5649]. The separation of the two legs of this profile has been shown to be caused by the ionization of a group exhibiting a pKa of 4.73 within acetyl-TPP that is remote from the acetyl group, the amino-pyrimidine ring, which is protonated below pH 4.73. The protonation level of this ring has been shown to control the equilibrium partitioning of acetyl-TPP among its carbinolamine, keto, and hydrate forms. The differential partitioning of these species is a major factor causing the separation between the two legs of the pH-rate profile. The characteristic pH-rate profile and the availability of synthetic acetyl-TPP [Gruys, K.J., Halkides, C.J., & Frey, P.A. (1987) Biochemistry 26, 7575-7585] have facilitated the isolation and identification of [1-14C]acetyl-TPP from acid-quenched enzymatic reaction mixtures at steady states. [1-14C]Acetyl-TPP was identified as a transient species in reactions catalyzed by the PDH complex or the pyruvate dehydrogenase component of the complex (E1). The pH-rate profile for hydrolysis of [1-14C]-acetyl-TPP isolated from enzymatic reactions was found to be indistinguishable from that for authentic acetyl-TPP, which constituted positive identification of the 14C-labeled enzymic species.     

High affinity of acid phosphatase encoded by PHO3 gene in Saccharomyces cerevisiae for thiamin phosphates

The enzymatic properties of acid phosphatase (orthophosphoric-monoester phosphohydrolase, EC 3.1.3.2) encoded by PHO3 gene in Saccharomyces cerevisiae, which is repressed by thiamin and has thiamin-binding activity at pH 5.0, were investigated to study physiological functions. The following results led to the conclusion that thiamin-repressible acid phosphatase physiologically catalyzes the hydrolysis of thiamin phosphates in the periplasmic space of S. cerevisiae, thus participating in utilization of the thiamin moiety of the phosphates by yeast cells: (a) thiamin-repressible acid phosphatase showed Km values of 1.6 and 1.7 microM at pH 5.0 for thiamin monophosphate and thiamin pyrophosphate, respectively. These Km values were 2-3 orders of magnitude lower than those (0.61 and 1.7 mM) for p-nitrophenyl phosphate; (b) thiamin exerted remarkable competitive inhibition in the hydrolysis of thiamin monophosphate (Ki 2.2 microM at pH 5.0), whereas the activity for p-nitrophenyl phosphate was slightly affected by thiamin; (c) the inhibitory effect of inorganic phosphate, which does not repress the thiamin-repressible enzyme, on the hydrolysis of thiamin monophosphate was much smaller than that of p-nitrophenyl phosphate. Moreover, the modification of thiamin-repressible acid phosphatase of S. cerevisiae with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide resulted in the complete loss of thiamin-binding activity and the Km value of the modified enzyme for thiamin monophosphate increased nearly to the value of the native enzyme for p-nitrophenyl phosphate. These results also indicate that the high affinity of the thiamin-repressible acid phosphatase for thiamin phosphates is due to the thiamin-binding properties of this enzyme.     

Pyruvate dehydrogenase and 3-fluoropyruvate: chemical competence of 2-acetylthiamin pyrophosphate as an acetyl group donor to dihydrolipoamide

The pyruvate dehydrogenase component (E1) of the pyruvate dehydrogenase complex catalyzes the decomposition of 3-fluoropyruvate to CO2, fluoride anion, and acetate. Acetylthiamin pyrophosphate (acetyl-TPP) is an intermediate in this reaction. Incubation of the pyruvate dehydrogenase complex with 3-fluoro[1,2-14C]pyruvate, TPP, coenzyme A (CoASH), and either NADH or pyruvate as reducing systems leads to the formation of [14C]acetyl-CoA. In this reaction the acetyl group of acetyl-TPP is partitioned by transfer to both CoASH (87 +/- 2%) and water (13 +/- 2%). When the E1 component is incubated with 3-fluoro[1,2-14C]pyruvate, TPP, and dihydrolipoamide, [14C]acetyldihydrolipoamide is produced. The formation of [14C]acetyldihydrolipoamide was examined as a function of dihydrolipoamide concentration (0.25-16 mM). A plot of the extent of acetyl group partitioning to dihydrolipoamide as a function of 1/[dihydrolipoamide] showed 95 +/- 2% acetyl group transfer to dihydrolipoamide when dihydrolipoamide concentration was extrapolated to infinity. It is concluded that acetyl-TPP is chemically competent as an intermediate for the pyruvate dehydrogenase complex catalyzed oxidative decarboxylation of pyruvate.     

Role of water in the energy of hydrolysis of phosphoanhydride and phosphoester bonds

The observed equilibrium constants for hydrolysis (Kobs) of a phosphoester and a phosphoanhydride bond were measured under a variety of conditions likely to alter the interactions of reactants and products with water. These included increasing the pH of the medium from 5.0 to 10.0, increasing the MgCl2 concentration form 0 to 200 mM, and decreasing the water activity of the medium by adding either dimethyl sulfoxide (50%, v/v) or polyethylene glycol 6,000-8,000 (50%, w/v). The Kobs for phosphoesters such as phosphoserine, glucose phosphate, glycerol phosphate, and ethylene glycol phosphate varied little over this wide range of conditions, the extreme values of Kobs being 12 and 200 M. In contrast, the Kobs for the phosphoanhydride bond of pyrophosphate varied from a value greater than 20,000 to 0.1 M. In totally aqueous media at a pH between 7.0 and 8.0 and in the presence of 0.5-1.0 mM MgCl2, the energy of hydrolysis of pyrophosphate was 1.2-4.0 kcal/mol greater than that of phosphoserine. However, when the water activity was decreased by adding polyethylene glycol to the medium within the same pH and MgCl2 concentration range, the energy of hydrolysis of phosphoserine became 2.0-2.5 kcal/mol greater than that of pyrophosphate. The results suggest that for phosphoesters, the solvation energies of reactants and products, unlike the case of phosphoanhydride bonds, are not the major factors in determining the energy of hydrolysis.     

Escherichia coli alpha-ketoglutarate dehydrogenase complex

The alpha-ketoglutarate dehydrogenase complex from Escherichia coli catalyzes the hydrolysis of S-succinyl-CoA to succinate and CoASH. The reaction rate is dependent upon the presence of thiamin pyrophosphate and NADH, as well as the functional integrity of the alpha-lipoyl groups associated with the enzyme. The Km value for S-succinyl-CoA is 9.3 X 10(-5) M, and the maximum velocity is 0.02 mumol X min-1 X mg of protein-1 at pH 7 and 25 degrees C. This hydrolysis can be rationalized on the basis that succinyl thiamin pyrophosphate is generated under reductive succinylation conditions. Occasional diversion of succinyl thiamin pyrophosphate to hydrolysis produces succinate.     

2-Acetylthiamin pyrophosphate: an enzyme-bound intermediate in thiamin pyrophosphate-dependent reactions

Several enzymes catalyze reactions that may involve acetylthiamin pyrophosphate (acetyl-TPP) as an intermediate. These enzymes are phosphoketolase, pyruvate oxidase and several pyruvate oxidoreductases. Acetyl-TPP can be synthesized and used as a carrier to analyze quenched reaction mixtures for the presence of [14C]acetyl-TPP. Synthetic acetyl-TPP exhibits unusual chemical properties and a unique pH-rate profile that serves as a powerful means of characterizing [14C]acetyl-TPP that has been isolated from quenched enzymatic reaction mixtures. Using this and other methods, extensive evidence has been obtained for the involvement of acetyl-TPP in certain reactions catalyzed by the pyruvate dehydrogenase complex (PDH complex) of Escherichia coli. Acetyl-TPP is chemically competent as an intermediate in the decarboxylation and dehydrogenation of pyruvate by the PDH complex; and it is transiently formed during the course of this reaction. It may be an enzyme-bound intermediate or it may be in equilibrium with such an intermediate. Acetyl-TPP is very likely to be an intermediate of the phosphoketolase reaction. However, no direct evidence linking it to the phosphoketolase reaction mechanism is yet available. It is unclear whether acetyl-TPP is an intermediate in the pyruvate oxidoreductase reactions. In one example, that of the ketoacid oxidoreductase of Halobacterium halobium, analysis by electron paramagnetic resonance spectroscopy indicates the involvement of a hydroxyethyl-TPP-radical as an intermediate. It is unknown whether the subsequent reaction of this radical with coenzyme A an an oxidized FeS cluster to produce acetyl coenzyme A and the reduced cluster involves the intermediate formation of acetyl-TPP.     

Crystal structure of thiamin pyrophosphokinase.

Thiamin pyrophosphate (TPP) is a coenzyme derived from vitamin B1 (thiamin). TPP synthesis in eukaryotes requires thiamin pyrophosphokinase (TPK), which catalyzes the transfer of a pyrophosphate group from ATP to thiamin. TPP is essential for central metabolic processes, including the formation of acetyl CoA from glucose and the Krebs cycle. Deficiencies in human thiamin metabolism result in beriberi and Wernicke encephalopathy. The crystal structure of mouse TPK was determined by multiwavelength anomalous diffraction at 2.4 A resolution, and the structure of TPK complexed with thiamin has been refined at 1.9 A resolution. The TPK polypeptide folds as an alpha/beta-domain and a beta-sandwich domain, which share a central ten-stranded mixed beta-sheet. TPK subunits associate as a dimer, and thiamin is bound in the dimer interface. Despite lacking apparent sequence homology with other proteins, the alpha/beta-domain resembles the Rossman fold and is similar to other kinase structures, including another pyrophosphokinase and a thiamin biosynthetic enzyme. Comparison of mouse and yeast TPK structures reveals differences that could be exploited in developing species-specific inhibitors of potential use as antimicrobial agents.     

Regulation of heart muscle pyruvate dehydrogenase kinase

1. The activity of pig heart pyruvate dehydrogenase kinase was assayed by the incorporation of [(32)P]phosphate from [gamma-(32)P]ATP into the dehydrogenase complex. There was a very close correlation between this incorporation and the loss of pyruvate dehydrogenase activity with all preparations studied. 2. Nucleoside triphosphates other than ATP (at 100mum) and cyclic 3':5'-nucleotides (at 10mum) had no significant effect on kinase activity. 3. The K(m) for thiamin pyrophosphate in the pyruvate dehydrogenase reaction was 0.76mum. Sodium pyrophosphate, adenylyl imidodiphosphate, ADP and GTP were competitive inhibitors against thiamin pyrophosphate in the dehydrogenase reaction. 4. The K(m) for ATP of the intrinsic kinase assayed in three preparations of pig heart pyruvate dehydrogenase was in the range 13.9-25.4mum. Inhibition by ADP and adenylyl imidodiphosphate was predominantly competitive, but there was nevertheless a definite non-competitive element. Thiamin pyrophosphate and sodium pyrophosphate were uncompetitive inhibitors against ATP. It is suggested that ADP and adenylyl imidodiphosphate inhibit the kinase mainly by binding to the ATP site and that the adenosine moiety may be involved in this binding. It is suggested that thiamin pyrophosphate, sodium pyrophosphate, adenylyl imidodiphosphate and ADP may inhibit the kinase by binding through pyrophosphate or imidodiphosphate moieties at some site other than the ATP site. It is not known whether this is the coenzyme-binding site in the pyruvate dehydrogenase reaction. 5. The K(m) for pyruvate in the pyruvate dehydrogenase reaction was 35.5mum. 2-Oxobutyrate and 3-hydroxypyruvate but not glyoxylate were also substrates; all three compounds inhibited pyruvate oxidation. 6. In preparations of pig heart pyruvate dehydrogenase free of thiamin pyrophosphate, pyruvate inhibited the kinase reaction at all concentrations in the range 25-500mum. The inhibition was uncompetitive. In the presence of thiamin pyrophosphate (endogenous or added at 2 or 10mum) the kinase activity was enhanced by low concentrations of pyruvate (25-100mum) and inhibited by a high concentration (500mum). Activation of the kinase reaction was not seen when sodium pyrophosphate was substituted for thiamin pyrophosphate. 7. Under the conditions of the kinase assay, pig heart pyruvate dehydrogenase forms (14)CO(2) from [1-(14)C]pyruvate in the presence of thiamin pyrophosphate. Previous work suggests that the products may include acetoin. Acetoin activated the kinase reaction in the presence of thiamin pyrophosphate but not with sodium pyrophosphate. It is suggested that acetoin formation may contribute to activation of the kinase reaction by low pyruvate concentrations in the presence of thiamin pyrophosphate. 8. Pyruvate effected the conversion of pyruvate dehydrogenase phosphate into pyruvate dehydrogenase in rat heart mitochondria incubated with 5mm-2-oxoglutarate and 0.5mm-l-malate as respiratory substrates. It is suggested that this effect of pyruvate is due to inhibition of the pyruvate dehydrogenase kinase reaction in the mitochondrion. 9. Pyruvate dehydrogenase kinase activity was inhibited by high concentrations of Mg(2+) (15mm) and by Ca(2+) (10nm-10mum) at low Mg(2+) (0.15mm) but not at high Mg(2+) (15mm).     

On the mechanism of action of thiamin enzymes in the presence of bivalent metal ions

Results on the interactions between the bivalent metal ions Zn2+, Cd2+, Hg2+, Co2+, Ni2+ and 'active aldehyde' thiamin derivatives are reviewed. The techniques used in these studies include spectroscopic methods, i.e., IR-Raman, UV-Vis, multidimensional and multinuclear NMR in solution and in solid state, and X-ray crystal structure determinations. More recently, potentiometric studies on thiamin pyrophosphate and 2-(alpha-hydroxyethyl)thiamin in combination with NMR and EPR techniques were also undertaken. All these studies lead to useful conclusions on the mechanism of action of thiamin enzymes in the presence of bivalent metal ions.     

GTP-specific pyrophosphorylation of thiamin in dark-grown soybean (Glycine max) seedling axes

ATP:thiamin pyrophosphotransferase (TPT: EC 2.7.6.2) was purified 5 900-fold from 48 h dark-grown soybean [ Glycine max (L.), Merr. cv. Ransom II] seedling axes. TPT activity was monitored during purification by measuring the formation of thiamin pyrophosphate (TPP) from [2-¹⁴C]-thiamin at optimal pH (7.3). Although other nucleoside triophosphates were active as pyrophosphate donors (apparent K_ms from 21 to 138 m M ), GTP was the preferred nucleotide with an apparent K_m of 0.021 m M . TPT activity was extremely sensitive to TPP formation, suggesting product feedback inhibition of TPT activity in vivo. Sulfhydryl, H⁺ and Mg²⁺ concentrations, either independently or in concert, were found to affect TPT activity.     

Structural basis for flip-flop action of thiamin pyrophosphate-dependent enzymes revealed by human pyruvate dehydrogenase

The derivative of vitamin B1, thiamin pyrophosphate, is a cofactor of enzymes performing catalysis in pathways of energy production. In alpha2beta2-heterotetrameric human pyruvate dehydrogenase, this cofactor is used to cleave the Calpha-C(=O) bond of pyruvate followed by reductive acetyl transfer to lipoyl-dihydrolipoamide acetyltransferase. The dynamic nonequivalence of two, otherwise chemically equivalent, catalytic sites has not yet been understood. To understand the mechanism of action of this enzyme, we determined the crystal structure of the holo-form of human pyruvate dehydrogenase at 1.95-A resolution. We propose a model for the flip-flop action of this enzyme through a concerted approximately 2-A shuttle-like motion of its heterodimers. Similarity of thiamin pyrophosphate binding in human pyruvate dehydrogenase with functionally related enzymes suggests that this newly defined shuttle-like motion of domains is common to the family of thiamin pyrophosphate-dependent enzymes.     

The isolation and preliminary characterization of apotransketolase from human erythrocytes

Human erythrocyte apotransketolase (EC 2.2.1.1) has been isolated with greater than 400 fold purification, and free of glyceraldehyde-3-phosphate dehydrogenase. The preparation has an absolute requirement for thiamin pyrophosphate in order to exhibit enzyme activity. Neither thiamin nor thiamin monophosphate could substitute for this requirement, nor were they inhibitory separately or together at concentrations of 1 mM. The K_m for thiamin pyrophosphate was 0.4 μM. The K_m for ribose-5-phosphate was 3 × 10^?4M and for xylulose-5-phosphate 1.8 × 10^?4M.     

Bovine heart pyruvate dehydrogenase kinase stimulation by alpha-ketoisovalerate

Purified bovine heart pyruvate dehydrogenase complex was used to investigate the effects of monovalent cations and alpha-ketoisovalerate on pyruvate dehydrogenase (PDH) kinase inhibition by thiamin pyrophosphate. Initial velocity patterns for thiamin pyrophosphate inhibition were consistent with hyperbolic non-competitive or hyperbolic uncompetitive inhibition at various K+ concentrations between 0 and 120 mM. The Kis, Kid, and Kin for thiamin pyrophosphate were in the range of 0.009 to 5.1 microM over the range of K+ concentrations tested. In the absence of K+, 1 mM alpha-ketoisovalerate had no effect on PDH kinase inhibition by thiamin pyrophosphate, whereas in the presence of 20 mM K+, alpha-ketoisovalerate stimulated PDH kinase activity almost 2-fold over the range of 0-80 microM thiamin pyrophosphate. Half-maximal stimulation by alpha-ketoisovalerate occurred at about 200 microM in the presence of 100 microM thiamin pyrophosphate and 20 mM K+. Similar but less extensive changes occurred in the presence of 100 microM thiamin pyrophosphate and 1 mM NH4+. Initial velocity patterns for PDH kinase inhibition by thiamin pyrophosphate in the presence of 2 mM alpha-ketoisovalerate were mixed noncompetitive, but alpha-ketoisovalerate increased the Vm and Km for adenosine 5'-triphosphate in the presence of inhibitor. In the presence of thiamin pyrophosphate, PDH kinase remained stimulated after chromatography on Sephadex G-25 to remove alpha-ketoisovalerate. The results indicate that acylation of pyruvate dehydrogenase complex by alpha-ketoisovalerate results in PDH kinase stimulation but only in the presence of monovalent cations and thiamin pyrophosphate.     

The in vitro interaction of naphthyridinomycin with deoxyribonucleic acids

The binding of naphthyridinomycin (NAP) to deoxyribonucleic acid was investigated using radioisotope labeled antibiotic. Dithiothreitol (DTT) enhances complex formation in a concentration dependent fashion but was found to be slightly inhibitory at concentrations above 10 mM. [C3H3]-NAP-DNA complexes, formed in the presence or absence of reducing reagents, were stable to Sephadex G-25 chromatography and precipitation with ethanol, indicating a strong bond formed between the drug and DNA. Time course studies showed that the difference between the binding of activated and non-activated antibiotic was a DTT-dependent burst. This was followed by a second phase of binding which was similar in both the activated and non-activated antibiotics. The activation of the antibiotic by DTT was a reversible reaction at pH 7.9. The activated form at pH 5.0 was extremely stable and did not revert to the unactivated form even after an 8-h incubation period. Antibiotic-DNA complex formation was pH independent between pH 5.0 and 7.0 for activated NAP. The non-activated antibiotic bound to DNA much better at pH 5.0 than at physiological pH values. Release of antibiotic from complexes (as followed by long term dialysis) formed in the presence of DTT and at pH 5.0 was biphasic, suggesting that the drug can bind to DNA in more than one way. A constant rate of antibiotic release was observed at pH 7.9 with or without DTT. At pH 2.0 and pH 12.0, greater than 95% of the antibiotic is released from the complexes. Most of the acid released antibiotic is NAP while most of the base released antibiotic had decomposed to a more polar compound. NAP binds well to calf thymus DNA, poly(dG) . poly(dC), and T4 DNA but shows significantly less affinity for poly(dA) . poly(dT), poly(dA . dT) . poly(dA . dT), poly(dG), poly(dC), poly(dI) . poly(dC) or poly(dG . dC) . poly(dG . dC). This specificity of NAP for DNA is similar to that observed for the pyrrolo(1,4)benzodiazepine antibiotics and saframycin A and S; all of which bind to double stranded DNA through their carbinolamine or masked carbinolamine functionalities. Two mechanisms which can explain the need for activation of NAP are also proposed.     

Proton magnetic resonance studies of alpha-keto acids.

Pulsed Fourier transform proton magnetic resonance was used to study alpha-ketoglutaramic, and several other alpha-keto acids in aqueous solutions as a function of pH. Most alpha-keto acids were found to exist in equilibrium with the hydrate (gem-doil). The equilibrium position favors the nonhydrated alphs-keto acid at neutral pH, but at low pH values (below the pKa of the alpha-carboxylic acid group) the hydrate predominates. We found evidence that alpha-ketoglutaric acid exists in a third equilibrium form which is assigned to the lactol. alpha-Ketoglutaramic acid (the alpha-keto acid analog of glutamine) which is known to exist predominantly in a cyclic form at pH 7.0 was shown to exist as a cyclic structure over a wide pH range. However, the cyclic form is an equilibrium mixture of 2-pyrrolidone-5-hydroxy-5-carboxylic and 1-pyrrolin-2-one-5-carboxylic acids.     

Isolation and Characterization of Thiamin Pyrophosphotransferase from Glycine max Seedlings

Thiamin:ATP pyrophosphotransferase (EC2.7.6.2) activity from soybean (Merr.) seedlings grown for 48 hours was determined by measuring the rate of [2-¹⁴C]thiamin incorporation into thiamin pyrophosphate. With partially purified (11-fold) enzyme, optimal activity occurred between pH 7.1 and 7.3, depending on the buffer system that was used. Assays were routinely conducted at a final pH of 8.1 in order to minimize interference from competing reactions. Enzyme activity required the presence of a divalent cation, and a number of nucleoside triphosphates proved to be active as pyrophosphate donors. Apparent K_m values of 18.3 millimolar and 4.64 micromolar were obtained for Mg·ATP and thiamin, respectively. Among the compounds tested, pyrithiamin and thiamin pyrophosphate were most effective in inhibiting thiamin pyrophosphotransferase activity. Based on Sephadex G-100 gel filtration, soybean thiamin pyrophosphotransferase has a molecular weight of 49,000.     

Structural biology of enzymes of the thiamin biosynthesis pathway

Thiamin pyrophosphate is an essential cofactor of carbohydrate and branched-chain amino acid metabolism. Although its mechanistic role is well studied, the biosynthesis of thiamin has only recently been understood. Thiamin biosynthesis in Escherichia coli and Bacillus subtilis show some similarities, but diverge at key steps of thiazole formation. The biosynthesis of thiamin in eukaryotes is at a very early stage of understanding. Structural and mechanistic studies on thiamin biosynthetic enzymes have played a key role in increasing our understanding of thiamin pyrophosphate biosynthesis and have revealed unexpected evolutionary ties.     

CRYSTALLINE ACETYL DERIVATIVES OF PEPSIN

Crystalline pepsin has been acetylated by the action of ketene in aqueous solution at pH 4.07–5.5. As acetylation proceeds the activity decreases, the decrease being more rapid at pH 5.0–5.5 than at 4.0–4.5. Three acetyl derivatives have been isolated from the reaction mixture and obtained in crystalline form. The crystal form of these derivatives is similar to that of pepsin. Fractionation and solubility determinations show that these preparations are not mixtures or solid solutions of the original pepsin with an inactive derivative. A compound which contains three or four acetyl groups and which has lost all of its original primary amino groups can be isolated after short acetylation. It has the same activity as the original pepsin. A second derivative containing six to eleven acetyl groups has also been isolated. It has about 60 per cent of the activity of the original pepsin. A third derivative having twenty to thirty acetyl groups and about 10 per cent of the activity of original pepsin can be isolated after prolonged acetylation. The 60 per cent active derivative on standing in strong acid solution loses some of its acetyl groups and at the same time regains the activity of the original pepsin. The compound obtained in this way is probably the same as the completely active three acetyl derivative obtained by mild acetylation. These results show that acetylation of three or four of the primary amino groups of pepsin causes no change in the specific activity of the enzyme but that the introduction of acetyl groups in other parts of the molecule results in a marked loss in activity. The solubilities, amino nitrogen content, acetyl content, isoelectric point, and the specific activity have been determined by a variety of methods and found to be different from the corresponding properties of crystalline pepsin. The pH-activity curves, acid and alkali inactivation, and titration curves were not significantly different from the same respective properties of pepsin.     

Histochemical applications of two phenanthridinium compounds

The fluorescent compounds ethidium monoazide and ethidium bromide were found to react intensely with nucleic acids of fixed, paraffin embedded tissues of rat and mouse. For routine staining, 10(-5) M solutions of ethidium bromide and its monoazide analogue were virtually identical in their reactions. Fresh frozen sections of the tissues reacted in the same manner as fixed, paraffin embedded samples. Fluorescence of DNA and RNA in rat pancreas could be selectively abolished by taking advantage of the greater sensitivity of RNA to acid hydrolysis. Hydrolysis in aqueous solutions (1 N HCl at 55-60 C) abolished RNA fluorescence in 5 min, whereas 20 min or longer were required to destroy DNA fluorescence. DNA fluorescence was selectively abolished by 3 hr in 0.1 N HCl in anhydrous methanol while the RNA remained unaffected. Rat pancreas stained with the 10(-5) M ethidium compounds below pH 5.0 showed reduced RNA fluorescence, but the DNA continued to fluoresce brightly at pH 0.6. Reducing the pH of the staining solution to pH 1.0, therefore, was an additional method of selectively abolishing RNA fluorescence. Ethidium solutions in 5.0 M NaCl at pH 5.0 had little effect on DNA or RNA fluorescence. This new method of examining nucleic acids in fixed tissue samples opens new approaches to the histochemistry of these substances. The method also offers new possibilities for the study of mutagenic drug-DNA interactions.     

Histochemical Applications of Two Phenanthridinium Compounds

The fluorescent compounds ethidium monoazide and ethidium bromide were found to react intensely with nucleic acids of fixed, paraffin embedded tissues of rat and mouse. For routine staining, 10^-5 M solutions of ethidium bromide and its monoazide analogue were virtually identical in their reactions. Fresh frozen sections of the tissues reacted in the same manner as fixed, paraffin embedded samples. Fluorescence of DNA and RNA in rat pancreas could be selectively abolished by taking advantage of the greater sensitivity of RNA to acid hydrolysis. Hydrolysis in aqueous solutions (1 N HCl at 55-60 C) abolished RNA fluorescence in 5 min, whereas 20 min or longer were required to destroy DNA fluorescence. DNA fluorescence was selectively abolished by 3 hr in 0.1 N HCl in anhydrous methanol while the RNA remained unaffected. Rat pancreas stained with the 10^-5 M ethidium compounds below pH 5.0 showed reduced RNA fluorescence, but the DNA continued to fluoresce brightly at pH 0.6. Reducing the pH of the staining solution to pH 1.0, therefore, was an additional method of selectively abolishing RNA fluorescence. Ethidium solutions in 5.0 M NaCl at pH 5.0 had little effect on DNA or RNA fluorescence. This new method of examining nucleic acids in fixed tissue samples opens new approaches to the histochemistry of these substances. The method also offers new possibilities for the study of mutagenic drug-DNA interactions.