An improved 2,4,6-trinitrobenzenesulfonic acid method for the determination of amines.

The use of 2,4,6-trinitrobenzenesulfonic acid (TNBS) as a reagent for determining the concentrations of amines has been widely accepted (1–3) since its introduction in 1960 by Satakeet al. (4). The original procedure has since been modified by Mokrasch (5) to permit the determination of amines, amino acids, and proteins in mixtures. In both procedures the trinitrophenylation reaction is followed by a quenching step, after which the amino content is related to the increase in absorbance at 340 nm (4) or 420 nm (5). We have studied the trinitrophenylation reaction and have found that amino content can be related directly to the absorbance of the trinitrophenylation reaction mixture after a relatively short incubation period (15–30 min). Therefore, it is unnecessary to quench this reaction. We describe herein an extremely convenient procedure for the determination of amines, amino acids, and proteins where the quenching step employed by previous investigators has been eliminated. The proposed method has a greater sensitivity than previously described techniques employing TNBS.     

Specific modification of free lysine amino groups of histidine decarboxylase from Micrococcus sp. n. by trinitrobenzene sulfonic acid]

It has been found that 14 lysine residues are accessible for trinitrobenzene sulfonic acid (TNBS) in the molecule of histidine decarboxylase (HDC). The other 62 lysine residues in the molecule of native HDC are masked and inaccessible for TNBS. It is demonstrated that the SH- and alpha-amino groups of methionine are not modified by TNBS. A correlation between the decarboxylase activity of the enzyme and the degree of its trinitrophenylation has been studied. HDC, whose molecule contains 3--9 TNP groups, retains up to 90--97% of its initial activity. Trinitrophenylation of 14 lysine residues induces inactivation of HDC by 33--34%, which probably depends on conformational changes or steric hindrances, occurring in the catalytic site of the modified active centre of HDC. Using circular dichroism and fluorescence methods as well as disc-electrophoresis in polyacrylamide gel, it has been shown that trinitrophenylation does not cause any significant changes in the enzyme structure. The TNP groups have been found to be localized in the large and small subunits of the HDC molecule.     

Trinitrophenylation of rabbit skeletal myosin by 2,4,6-trinitrobenzene sulfonate and treatment of trinitrophenyl myosin with dithiothreitol

Rabbit skeletal myosin was trinitrophenylated with 2,4,6-trinitrobenzene sulfonate (TNBS) in the presence or absence of inorganic pyrophosphate (PP1). When myosin trinitrophenylated either in the presence or absence of PP1 was treated with dithiothreitol (DTT), the absorbance at 345 nm of both trinitrophenylated myosins was decreased, as though the trinitrophenyl groups bound to myosin were removed. The DTT treatment also essentially reversed the inhibition of the EDTA-ATPase and Ca-ATPase activities that was caused by trinitrophenylation of myosin. These effects of trinitrophenylation and of DTT treatment were independent of the presence or absence of PP1 during the trinitrophenylation. In contrast, the PP1-induced formation of a difference spectrum of trinitrophenylated myosin was not affected by the DTT treatment. On the basis of these observations, it is suggested that the "reactive lysine residues," trinitrophenylation of which resulted in inhibition of the ATPase activities, are different from those whose trinitrophenyl groups show an altered spectrum on addition of PP1.     

Identification of lysine residue at or near active site of luffin-a, a ribosome-inactivating protein from seeds of Luffa cylindrica

Luffin-a, a ribosome-inactivating protein from the seeds of sponge gourd (Luffa cylindrica), was modified with 2,4,6-trinitrobenzenesulfonic acid (TNBS) at pH 8.0 and 20 degrees C. The inhibitory activity of the modified luffin-a on protein synthesis using rabbit reticulocyte lysate was lost rapidly at a rate compatible with that of the modification of a single highly reactive amino group in the initial stage of the reaction. By cation-exchange FPLC of the products of 5-min modification, TNP-luffin-a containing one modified amino group was obtained and shown to have only 6.7% of the activity of native luffin-a without any gross conformational change. The amino acid composition and sequence of the TNP-peptide, isolated by reverse-phase HPLC of the tryptic digest of the TNP-luffin-a, unambiguously demonstrate the trinitrophenylation of lysine residue at position 231. From these results, it was concluded that Lys231 of luffin-a is highly reactive to TNBS and is located at or near the active site of luffin-a.     

A convenient manual trinitrobenzenesulfonic acid method for monitoring amino acids and peptides in chromatographic column effluents.

The trinitrobenzenesulfonic acid (TNBS) method of R. Fields (1971, Biochem. J., 124, 581–590) has been modified for the manual detection of amino acids and peptides in chromatographic column effluent by changing the reaction conditions to 1 mm TNBS in 0.4 m potassium borate buffer, pH 9.2, at room temperature for 30 to 50 min. The reaction with amines and the spontaneous hydrolysis of TNBS are stopped by neutralization to pH 6.25 with sodium monobasic phosphate (0.33 m). Sodium sulfite (3 mm) is added to increase the absorptivity of the product. The TNBS reagent blank is less than 0.100 A₄₂₀ after 50 min of reaction. Since the ΔA₄₂₀ of the reagent blank is ～0.002/min before quenching the reaction, and zero afterward, the time required for reaction and for absorbance measurements need not be controlled precisely. Alkaline hydrolysis of peptides is carried out prior to detection to increase the sensitivity of the method. This procedure is convenient for the manual determination of 5 to 100 nmol of amino acids in the 50–100 samples required to define a chromatographic elution profile.     

Trinitrophenylation of nucleic acids and their constituents.

1. Under relatively mild conditions, nucleic acids and their constituents were trinitrophenylated with 2,4,6-trinitrobenzenesulfonate (TNBS) in aqueous solution (pH 8-11), yielding reddish-orange trinitrophenyl (TNP) derivatives. Guanine residues were trinitrophenylated on the base residues at the 2-amino group (N2-TNP derivatives), and in addition, 2'- and 3'-hydroxyl groups of the ribose moieties of nucleosides or nucleotides were trinitrophenylated to form Meisenheimer complexes. 2. The preparation of TNP derivatives (N2-TNP-guanine, -guanosine, N2, O-bis-TNP-guanosine, O-TNP-guanosine, -adenosine, -cytidine , and -uridine), their rates of formation, absorption spectra (UV, visible, and infrared), molar extinction coefficients, Rf value, electrophoretic mobilities, and stability in acid or alkaline solution, are presented. 3. Trinitrophenylation of several kinds of nucleic acid was investigated. Calf thymus DNA and yeast transfer RNA showed a resistance to trinitrophenylation compared to guanosine 3'(2')-phosphate, yeast RNA or denatured calf thymus DNA. TNP-RNA showed resistance to the action of ribonucleases T1 and T2 [EC 3.1.4.8 and 3.1.4.23]. 4. Trinitrophenylation reactions using 2,4,6-trinitrochlorobenzene and 2,4,6-trinitrofluorobenzene were compared with that using TNBS as regards specificity and reaction rate.     

Modulation of the properties of immobilized CALB by chemical modification with 2,3,4-trinitrobenzenesulfonate or ethylendiamine. Advantages of using adsorbed lipases on hydrophobic supports

Lipase B from Candida antarctica (CALB) has been adsorbed on octyl-agarose or covalently immobilized on cyanogen bromide agarose. Then, both biocatalysts have been modified with ethylenediamine (EDA) or 2,4,6-trinitrobenzensulfonic acid (TNBS) just using one reactive or using several modifications in a sequential way (the most complex preparation was CALB–TNBS–EDA–TNBS). Covalently immobilized enzyme decreased the activity by 40–60% after chemical modifications, while the adsorbed enzyme improved the activity on p-nitrophenylbutyrate (pNPB) by EDA modification (even by a 2-fold factor). These biocatalysts were further characterized. The results showed that the effects of the chemical modification on the enzyme features were strongly dependent on the immobilization protocol utilized, the experimental conditions where the catalyst will be utilized, and the substrate. Significant changes in the activity/pH profile were observed after the chemical modifications. The effect of the modifications on the enzyme activity depends on the substrate and the reaction conditions: enzyme specificity is strongly altered by the chemical modification. Moreover, enzyme activity versus pNPB (using octyl-CALB–EDA) or versus R methyl mandelate (using octyl-CALB–TNBS) increased by almost a 2-fold factor at pH 5. The stability of the modified enzymes at different pH and in the presence of organic solvents generally decreased after the modifications, usually by no more than a 2-fold factor. However, under some conditions, some stabilization was found. CALB enantioselectivity in the hydrolysis of R/S methyl mandelate could be also improved by these chemical modifications (e.g., E-value went from 11 to 16 using octyl-CALB–TNBS at pH 5). Therefore, solid phase chemical modification of immobilized lipases may become a powerful tool in the design of lipase libraries with very different properties, each immobilized preparation may be used to produce a variety of forms with altered properties.     

The reaction of chemical probes with the erythrocyte membrane

Summary Trinitrobenzenesulfonate (TNBS), fluorodinitrobenzene (FDNB) and suberimidate have been reacted with intact human erythrocytes. TNBS does not penetrate the cell membrane significantly at 23 °C in bicarbonate-NaCl buffer, pH 8.6, as estimated by the labeling of the N-terminal valine of hemoglobin. Hence, under these conditions it can be used as a vectorial probe. However, at 37 °C, especially in phosphate buffer, at pH 8.6, TNBS does penetrate the cell membrane. FDNB and suberimidate both penetrate the erythrocyte membrane. The time course reaction of TNBS with intact erythrocytes over a 24-hr period at 23 °C is complex and shows transition zones for both membrane phosphatidylethanolamine (PE) and membrane proteins. No significant cell lysis occurs up to 10 hr. The fraction of total PE or phosphatidylserine (PS) which reacts with TNBS by this time period can be considered to be located on the outer surface of the cell membrane. Under these conditions it can be shown that 10 to 20% of the total PE and no PS is located on the outer surface of the membrane and hence these amino phospholipids are asymmetrically arranged. The pH gradient between the inside and outside of the cell in our system is 0.4 pH units. Nigericin has no effect on the extent of labeling of PE or PS by TNBS. Isotonic sucrose gives a slight enhancement of the labeling of PE by TNBS. Hence, the inability of PE and PS to react with the TNBS is considered not due to the inside of the cell having a lower pH. The extent of reaction of TNBS with PE is not influenced by changing the osmolarity of the medium or by treatment of cells with pronase, trypsin, phospholipase A or phospholipase D. However, bovine serum albumin (BSA) does protect some of the PE molecules from reacting with TNBS.Cells treated with suberimidate were suspended in either isotonic NaCl or in distilled water. In both cases the suberimidate-treated cells became refractory to hypotonic lysis. Pretreatment of cells with TNBS did not prevent them from interacting with suberimidate and becoming refractory to lysis. However, pretreatment of cells with the penetrating probe FDNB abolished the suberimidate, effect. Electron-microscopic analysis of the cells showed a continuous membrane in the case of cells suspended in isotonic saline. The cells suspended in water did not lyse but their membranes had many large holes, sufficient to let the hemoglobin leak out. Since the hemoglobin did not leak out we know that the hemoglobin is cross-linked into a large supramolecular aggregate.     

The reaction of chemical probes with the erythrocyte membrane.

Trinitrobenzenesulfonate (TNBS), fluorodinitrobenzene (FDNB) and suberimidate have been reacted with intact human erythrocytes. TNBS does not penetrate the cell membrane significantly at 23 degrees C in bicarbonate-NaCl buffer, pH 8.6, as estimated by the labeling of the N-terminal valine of hemoglobin. Hence, under these conditions it can be used as a vectorial probe. However, at 37 degrees C, especially in phosphate buffer, at pH 8.6, TNBS does penetrate the cell membrane. FDNB and suberimidate both penetrate the erythrocyte membrane. The time course reaction of TNBS with intact erythrocytes over a 24-hr period at 23 degrees C is complex and shows transition zones for both membrane phosphatidylethanolamine (PE) and membrane proteins. No significant cell lysis occurs up to 10 hr. The fraction of total PE or phosphatidylserine (PS) which reacts with TNBS by this time period can be considered to be located on the outer surface of the cell membrane. Under these conditions it can be located on the outer surface of the cell membrane. Under these conditions it can be shown that 10 to 20% of the total PE and no PS is located on the outer surface of the membrane and hence these amino phospholipids are asymmetrically arranged. The pH gradient between the inside and outside of the cell in our system is 0.4 pH units. Nigericin has no effect on the extent of labeling of PE or PS by TNBS. Isotonic sucrose gives a slight enhancement of the labeling of PE by TNBS. Hence, the inability of PE and PS to react with the TNBS is considered not due to the inside of the cell having a lower pH. The extent of reaction of TNBS with PE is not influenced by changing the osmolarity of the medium or by treatment of cells with pronase, trypsin, phospholipase A or phospholipase D. However, bovine serum albumin (BSA) does protect some of the PE molecules from reacting with TNBS. Cels treated with suberimidate were suspended in either isotonic NaCl or in distilled water. In both cases the suberimidate-treated cells became refractory to hypotonic lysis. Pretreatment of cells with TNBS did not prevent them from interacting with suberimidate and becoming refractory to lysis. However, pretreatment of cells with the penetrating probe FDNB abolished the suberimidate effect. Electron-microscopic analysis of the cells showed a continuous membrane in the case of cells suspended in isotonic saline. The cells suspended in water did not lyse but their membranes had many large holes, sufficient to let the hemoglobin leak out. Since the hemoglobin did not leak out we know that the hemoglobin is cross-linked into a large supramolecular aggregate.     

Chemical Decoupling of ATPase Activation and Force Production from the Contractile Cycle in Myosin by Steric Hindrance of Lever-Arm Movement

The myosin motor protein generates force in muscle by hydrolyzing Adenosine 5′-triphosphate (ATP) while interacting transiently with actin. Structural evidence suggests the myosin globular head (subfragment 1 or S1) is articulated with semi-rigid catalytic and lever-arm domains joined by a flexible converter domain. According to the prevailing hypothesis for energy transduction, ATP binding and hydrolysis in the catalytic domain drives the relative movement of the lever arm. Actin binding and reversal of the lever-arm movement (power stroke) applies force to actin. These domains interface at the reactive lysine, Lys84, where trinitrophenylation (TNP-Lys84-S1) was observed in this work to block actin activation of myosin ATPase and in vitro sliding of actin over myosin. TNP-Lys84-S1's properties and interactions with actin were examined to determine how trinitrophenylation causes these effects. Weak and strong actin binding, the rate of mantADP release from actomyosin, and actomyosin dissociation by ATP were equivalent in TNP-Lys84-S1 and native S1. Molecular dynamics calculations indicate that lever-arm movement inhibition during ATP hydrolysis and the power stroke is caused by steric clashes between TNP and the converter or lever-arm domains. Together these findings suggest that TNP uncouples actin activation of myosin ATPase and the power stroke from other steps in the contraction cycle by inhibiting the converter and lever-arm domain movements.     

Interaction of membrane aminophospholipids of E. coli with fluorodinitrobenzene and trinitrobenzenesulfonate.

E. coli cells were reacted with TNBS in bicarbonate-NaCl buffer, pH 8.5 (buffer A) and in phosphate-NaCl buffer, pH 7.0 (buffer B). In buffer A, DNP-GPE is the major product when FDNB is used. DNP-PE and DNP-LPE are formed in lesser amounts. Phospholipase A activity is high in buffer A. When TNBS is used, the labeling of the lipid components is less than with FDNB and more TNP-PE is formed relative to TNP-GPE. This data suggests that the phospholipases which are located primarily on the outer L-membrane of the cell wall act to a lesser extent on TNP-PE than on DNP-PE. E. coli cells were prelabeled with TNBS and FDNB in buffer A, washed and incubated in buffer A. The endogenous labeled DNP-PE gradually decreased with time with a concomitant increase in DNP-LPE and DNP-GPE due to phospholipase A activity. In contrast, the endogenous labeled TNP-PE also decreased with time as did the endogenous labeled TNP-LPE but a new orange lipid was produced. This lipid is believed to be a derivative of TNP-PE in which one of the nitro groups has been reduced to an amino group by nitroreductase. E. coli cells were prelabeled with TNBS and FDNB in buffer A, washed and incubated in buffer B. Under these conditions with both TNBS and FDNB there is an increase in TNP-PE and DNP-PE with a concomitant decrease in TNP-LPE, TNP-GPE, DNP-LPE and DNP-GPE. These results show that at neutral pH acylation occurs to regenerate TNP-PE and DNP-PE. E. coli cells were incubated with exogenous DNP-GPE or TNP-GPE in buffer A. The DNP-GPE and TNP-GPE were rapidly hydrolyzed by a phosphodiesterase to DNP-ethanolamine and TNP-ethanolamine. An orange derivative was formed which was provisionally identified as a derivative of DNP-ethanolamine or TNP-ethanolamine in which a nitro group has been reduced to an amino group by nitroreductase. The phospholipases and acylating enzymes present in the cell wall of E. coli are active on the dinitrophenyl and trinitrophenyl derivatives of PE and LPE and may act in concert to model and repair the plasma membrane.     

A microassay for proteases using succinylcasein as a substrate.

A photometric assay for proteases has been developed. A chemically modified casein whose amino groups were succinylated was used as a substrate. After incubation with trypsin, chymotrypsin, thermolysin, and subtilisin, the extent of hydrolysis of the substrate was determined with trinitrobenzene sulfonate (TNBS). The whole procedure of the assay was performed in the microtiter plate wells and the increase in the absorbance resulting from the reaction between TNBS and newly formed amino groups in the substrate was able to be determined with a high sensitivity by a microtiter plate reader, enabling the simultaneous measurement of a number of samples. Application of this method to the measurement of proteolytic activity contained in the protein extract of Tapes philippinarum is demonstrated.     

Kinetic study of the reaction between trinitrobenzenesulfonic acid and amino acids with a trinitrobenzenesulfonate ion-selective electrode

Potentiometric studies of the reaction between trinitrobenzenesulfonic acid (TNBS) and several amino acids with the TNBS electrode indicate that the reaction is first-order with respect to TNBS and amino acid concentration. The reaction is zero-order with respect to hydroxide concentration at pH greater than 10.5, indicating that the nonprotonated amino group is the reactive species. Rate constants were calculated for each amino acid and a simple mechanism of the reaction is proposed.     

Identical behavior of the two active sites of myosin with respect to trinitrophenylation.

Myosin and its active subfragments were trinitrophenylated under conditions in which mainly the active site(s) was modified. Proteins modified at the active site(s) could be separated by affinity chromatography on agarose-ATP columns. By two independent methods, ATPase activity measurements and analysis of elution patterns on agarose-ATP columns, it was shown that the introduction of two trinitrophenyl groups per myosin or one per heavy meromyosin subfragment 1 molecule is responsible for the remarkable change in the ATPase activities. Heavy meromyosin subfragment 1 prepared from trinitrophenylated myosin retained the original degree of trinitrophenylation per "active head." The kinetic constant of trinitrophenylation of the epsilon-amino group of lysine at the active site was found to be 2000 S-1-M-1, whereas a much smaller constant of 2.2 S-1-M-1 was obtained for the trinitrophenylation of the unessential lysyl residues of myosin. By using affinity chromatography, we could follow the formation of mono- and ditrinitrophenyl myosin. The amounts of these myosin derivatives at various extents of the reaction corresponded approximately to the calculated amounts, assuming a random and independent trinitrophenylation of the two myosin "heads." It is concluded that in each of the two heads of myosin there is one ATPase active site and these two sites behave in an identical manner with respect to trinitrophenylation.     

Differential reaction of cell membrane phospholipids and proteins with chemical probes.

The major aims of this study were to determine the degree of phospholipid asymmetry and the neighbor analysis of phospholipids in different types of cell membranes. For this study a penetrating probe (FDNB), a non-penetrating probe (TNBS) and a cross-linking probe (DFDNB) were used. The reaction of hemoglobin, membrane protein and membrane PE and PS of erythrocytes with DFNB and TNBS was studied over a concentration range of 0.5 to 10 mM probe. TNBS reacts to an extremely small extend with hemoglobin over the concentration range 0.4 to 4 mM whereas FDNB reacts with hemoglobin to a very large extent (50 fold more than TNBS). The reaction of membrane protein of intact erythrocytes reaches a sharp plateau at 1 mM TNBS whereas the reaction of membrane protein goes to a much larger extent with FDNB with no plateau seen up to 4 mM FDNB. This data shows that TNBS does not significantly penetrate into the cell under our conditions whereas FDNB does penetrate into the cell. The results show that there are four fold more reactive sites on proteins localized on the inner surface of the erythrocyte membrane as compared to the outer surface. TNBS at 0.5 to 2 mM concentration does not label membrane PS and labels membrane PE to a small extent. The reaction of PE with TNBS shows an initial plateau at 2 mM probe and a second slightly higher plateau between 4 to 10 mM probe. TNBS from 0.5-2.0 mM does not react with PS, but between 3 to 10 mM concentration, a very small amount of PS reacts with TNBS. Hence above 2 mM TNBS or FDNB a perturbation occurs in the membrane such that more PE and PS are exposed and react with these probes. These results demonstrate that essentially no PS is localized on the outer surface of the membrane and only 5% of the total membrane PE is localized on the outer surface of the erythrocyte membrane. TNBS and FDNB were reacted with yeast, E. coli, and Acholeplasma cells. With yeast cells, FDNB reacts to a much larger extent with PE than does TNBS, indicating that FDNB penetrates into the cell and labels more PE molecules. With E. coli, but not with erythrocytes or yeast cells, phospholipase A activity was very pronounced at pH 8.5 giving rise to a large amount of DNP-GPE from DNP-PE. A phosphodiesterase was also present which hydrolyized DNP-GPE to DNP-ethanolamine. The multilayered structure of the E. coli cell envelop did not permit a definitive interpretation of the results. It is clear, however, that TNBS and FDNB react to a different extent with PE in this cell. The Acholeplasma membrane had no detectable PE or PS but contains amino acid esters of phosphatidylglycerol. The reaction of these components with TNBS and FDNB indicate that these aminoacyl-PG are localized on both surfaces of the membrane, with 31% being on the outer surface and 69% on the inner surface...     

Trinitrophenylation of smooth muscle myosin

The reaction of trinitrobenzenesulfonate with gizzard myosin was studied. The initial phase of the reaction involved two residues and at this level of modification the following was observed: the Mg2+-ATPase of myosin, the actin-activated ATPase of phosphorylated myosin and the phosphorylation kinetics of myosin were not affected. However, trinitrophenylation did induce an activation of the actin-activated ATPase of dephosphorylated myosin and in this respect mimicked the effect of light chain phosphorylation. The Mg2+-dependence of actin-activated ATPase also is altered on trinitrophenylation. These alterations of enzymatic properties could be at least partly explained by the finding that trinitrophenylation favored the 6S conformation of myosin.     

Reaction of 1-fluoro-2,4-dinitrobenzene and 2,4,6-trinitrobenzenesulphonic acid with membranes of sarcoplasmic reticulum.

Membranes of sarcoplasmic reticulum were labelled with 1-fluoro-2,4-dinitro[3H]benzene at pH 6.5 and with 2,4,6-trinitrobenzenesulphonate at pH 9.2. Conditions were chosen to restrict reaction to amino groups, and the effect of blockings of these groups by methyl acetimidate was determined. All proteins were labelled to some extent by both reagents, but, whereas the trinitrophenylation of both lipid and protein amino groups was almost completely blocked by methyl acetimidate, the dinitrophenylation of the ATPase at pH 6.5 was much less affected. The seven amino groups on the ATPase that were labelled under these conditions did not react with methyl acetimidate. This reagent can therefore be used to enhance the specificity of fluorodinitrobenzene for amino groups in a hydrophobic environment. The amino groups on the minor proteins and on the phospholipids that reacted with fluorodinitrobenzene at pH 6.5 were probably in an aqueous environment, since the reaction was blocked by methyl acetimidate.     

Studies of the phosphoenzyme intermediate of the yeast plasma membrane proton-translocating ATPase

The yeast plasma membrane proton-pumping ATPase forms a phosphorylated intermediate during the hydrolysis of ATP. The fraction of enzyme phosphorylated during steady-state ATP hydrolysis was studied as a function of substrate concentration (MgATP), Mg2+ concentration, and pH. The dependence of the fraction of enzyme phosphorylated on the concentration of MgATP is sigmoidal, and the isotherms can be fit with parameters and mechanisms similar to those used to describe ATP hydrolysis. The isotherm is significantly more sigmoidal at pH 5.5 than at pH 6.0, with the limiting percentage (100.mol of phosphate/mol of enzyme) of enzyme phosphorylated being 70% and 6%, respectively, at the two pH values. The maxima in the steady-state rate of ATP hydrolysis occur at higher concentrations of Mg2+ and higher pH than the maxima in the fraction of enzyme phosphorylated. This suggests that the rate-determining step for ATP hydrolysis is different from that for enzyme phosphorylation and the hydrolysis of phosphoenzyme is enhanced by Mg2+ and high pH. The rate of phosphoenzyme formation was investigated with the quenched-flow method, but only a lower bound of 140 s-1 could be obtained for the rate constant at MgATP concentrations greater than 2.5 mM. Since the turnover number for ATP hydrolysis under similar conditions is 14 s-1, the rate-determining step in ATP hydrolysis occurs after enzyme phosphorylation.     

Asymmetry of lipid organization in cholinergic synaptic vesicle membranes.

The lipid composition of purified Torpedo cholinergic synaptic vesicles was determined and their distribution between the inner and outer leaflets of the vesicular membrane was investigated. The vesicles contain cholesterol and phospholipids at a molar ratio of 0.63. The vesicular phospholipids are (mol% of total phospholipids): phosphatidylcholine (40.9); phosphatidylethanolamine (24.6); plasmenylethanolamine (11.5); sphingomyelin (12); phosphatidylserine (7.3); phosphatidylinositol (3.7). The asymmetry of the synaptic vesicle membranes was investigated by two independent approaches: (a) determining accessibility of the amino lipids to the chemical label trinitrobenzenesulphonic acid (TNBS); (b) determining accessibility of the vesicular glycerophospholipids to phospholipase C (Bacillus cereus). TNBS was found to render the vesicles leaky and thus cannot be used reliably to determine the asymmetry of Torpedo synaptic vesicle membranes. Incubation of the vesicles with phospholipase C (Bacillus cereus) results in biphasic hydrolysis of the vesicular glycerophospholipids. About 45% of the phospholipids are hydrolysed in less than 1 min, during which no vesicular acetylcholine is released. In the second phase, the hydrolysis of the phospholipids slows down markedly and is accompanied by loss of all the vesicular acetylcholine. These findings suggest that the lipids hydrolysed during the first phase are those comprising the outer leaflet. Analysis of the results thus obtained indicate that the vesicular membrane is asymmetric: all the phosphatidylinositol, 77% of the phosphatidylethanolamine, 47% of the plasmenylethanolamine and 58% of the phosphatidylcholine were found to reside in the outer leaflet. Since phosphatidylserine is a poor substrate for phospholipase C (B. cereus), its distribution between the two leaflets of the synaptic vesicle membrane is only suggestive.     

Preparation of 32P-labeled inositides and their degradation by soluble kidney enzymes.

A method is described for the preparation of radioactive inositol lipids for studies of their enzymic degradation. Kidney cytosol fractions have been used to produce diesteratic cleavage. High voltage electrophoresis at pH 4.3 is used to separate D-myoinositol 1 : 2-cyclic phosphate and D-myoinositol 1-phosphate from hydrolysis of phosphatidylinositol. Radioactivity co-migrating with myoinositol diphosphate and triphosphate is separated by electrophoresis at pH 1.5 following enzymatic hydrolysis of phosphatidylinositol phosphate and phosphatidylinositol diphosphate. Relative activities for hydrolysis of the various inositides suggest the presence of more than one phosphodiesterase.