The heterogeneity of bound acetylcholine and synaptic vesicles

Synaptic vesicles containing radioactive acetylcholine have been isolated from slices of Torpedo electric organ incubated with radioactive choline. The recently synthesized radioactive acetylcholine is preferentially removed from the vesicles by iso-osmotic gel filtration. There is therefore a small compartment of loosely bound recently synthesized acetylcholine within the monodisperse vesicle fraction. The specific radioactivity of this compartment correlates most closely with the ;free' acetylcholine of electric organ that is lost when the tissue is homogenized. Membrane-associated vesicles did not contain any particular enrichment of this compartment. On standing at 6 degrees C the loosely bound compartment stabilizes so that it survives iso-osmotic filtration. A study of this phenomenon revealed that it was proportional to the extent of the loss of tightly bound acetylcholine from the vesicles. Incubation with Ca(2+), at pH5.5, or partial hypo-osmotic shock, caused losses of tightly bound acetylcholine and proportional increases in the stabilization of loosely bound acetylcholine of vesicles. Incubation at 20 degrees C caused less loss of tightly bound, and less stabilization of loosely bound, acetylcholine. A theoretical treatment of these exchanges also shows that the random factors promoting loss of tightly bound acetylcholine are statistically correlated with those which cause stabilization of loosely bound acetylcholine. The reciprocal relationship between the exchanges is inconsistent with there being two distinct populations of vesicles, one containing recently synthesized, loosely bound acetylcholine and the other containing tightly bound acetylcholine. It is proposed that all the vesicles contain a core of tightly bound acetylcholine and a surface layer of loosely bound acetylcholine. The origin of the extravesicular acetylcholine and also of the acetylcholine released on stimulation is discussed in the light of these results.     

LES COMPARTIMENTS D''ACETYLCHOLINE DE L''ORGANE ELECTRIQUE DE LA TORPILLE ET LEURS MODIFICATIONS PAR LA STIMULATION

Abstract— Changes in ‘free’ and ‘bound’ acetylcholine before and after stimulation have been investigated in vivo and in slices of electric organ of Torpedo marmorata incubated or superfused with physiological saline solutions. Spontaneous miniature end-plate potentials could be recorded and on electrical stimulation discharges of up to 30 V could be elicited. The electrical response fell off rapidly on repetitive stimulation. ‘Bound’ acetylcholine is that which relhains after the tissue has been homogenized since any ‘free’ acetylcholine is hydrolysed by the esterases when the tissue is disrupted. ‘Free’ acetylcholine can therefore be determined as the difference between the total acetylcholine found when the tissue is extracted with trichloroacetic acid and that which remains when the tissue is homogenized. Most of the ‘bound’ acetylcholine is present in synaptic vesicles. Stimulation of the tissue until the electrical response had fallen was accompanied by a drop in the level of ‘free’ acetylcholine. Lowered calcium and increased magnesium concentrations in the medium caused a decrease in the electrical response to stimulation and a decrease in the fall of ‘free’ acetylcholine. In other experiments, a decrease of both compartments was noticed at the end of the stimulation period. However the drop in ‘bound’ acetylcholine could also be elicited after the ‘free’ had fallen, by continuing the stimulation. When anticholinesterases were put in the medium, acetylcholine released on stimulation could be collected. On pre-incubation of the slice with [¹⁴C]choline, the acetylcholine stores became labelled. The specific radioactivity of the ‘free’ acetylcholine fluctuated on serial stimulations, whereas the specific radioactivity of the ‘bound’ acetylcholine remained stable under these experimental conditions. It is concluded that the ‘free’ compartment of acetylcholine is the most immediately available for release on stimulation.     

An antiserum specific for cholinergic synaptic vesicles from electric organ

Rabbit antisera to highly purified synaptic vesicles from the electric organ of Narcine brasiliensis, an electric ray, reveal a unique population of synaptic vesicle antigens in addition to a population shared with other electric organ membranes. Synaptic vesicle antigens were detected by binding successively rabbit antivesicle serum and radioactive goat anti-rabbit serum. To remove antibodies directed against antigens common to synaptic vesicles and other electric organ fractions, the antivesicle serum was extensively preadsorbed against an electric organ membrane fraction that was essentially free of synaptic vesicles. The adsorbed serum retained 40% of its ability to bind to synaptic vesicles, suggesting that about half of the antigenic determinants are unique. Vesicle antigens were quantified with a radioimmunoassay (RIA) that utilized precipitation of antibody-antigen complexes with Staphylococcus aureus cells. By this assay, the vesicles, detected by their acetylcholine (ACh) content and the antigens detected by the RIA, have the same buoyant density after isopycnic centrifugation of crude membrane fractions on sucrose and glycerol density gradients. The ratio of ACh to antigenicity was constant across the vesicle peaks and was close to that observed for vesicles purified to homogeneity. Even though the vesicles make up only approximately 0.5% of the material in the original homogenate, the ratio of acetylcholine to vesicle antigenicity could still be measured and also was indistinguishable from that of pure vesicles. We conclude that synaptic vesicles contain unique antigenic determinants not present to any measurable extent in other fractions of the electric organ. Consequently, it is possible to raise a synaptic vesicle- specific antiserum that allows vesicles to be detected and quantified. These findings are consistent with earlier immunohistochemical observations of specific antibody binding to motor nerve terminals.     

EFFECT OF ELECTRICAL STIMULATION ON THE YIELD AND COMPOSITION OF SYNAPTIC VESICLES FROM THE CHOLINERGIC SYNAPSES OF THE ELECTRIC ORGAN OF TORPEDO: A COMBINED BIOCHEMICAL, ELECTROPHYSIOLOGICAL AND MORPHOLOGICAL STUDY

Abstract— The effect of stimulating the electric organ of Torpedo marmorata , anaesthetized with 0.01% Tricaine methane sulphonate, by means of electrical stimulation (5/s) administered via an electrode placed on the electric lobe has been studied electrophysiologically, biochemically and morphologically. The response of the organ declined to about 50 per cent of its initial value after about 500 stimuli, by a further 10 per cent after another 500 stimuli and then to about 12 per cent of the initial value after a further 1000 stimuli. Thereafter the response fell off progressively. However, even when the response was less than 1 per cent of its initial value, the organ had considerable powers of recuperation during a 30-s rest period, to 30–50 per cent of its initial value.
The fall in response was accompanied by a reduction in vesicle size and number, an increase in the area of the presynaptic membrane and a fall in the protein, total nucleotide, ATP and acetylcholine content of the vesicle fraction isolated from the stimulated tissue. However, whereas vesicle numbers and the protein and total nucleotide content of the vesicle fraction fell by only about 50 per cent, vesicular ATP and acetylcholine levels were reduced to about 10 per cent. An analysis of the covariance of vesicular ATP and acetylcholine showed an initial loss of an acetylcholine-rich (relative to ATP) population of vesicles. The early loss of vesicular protein and nucleotide and vesicle numbers as well as the morphological changes seen would be consistent with a loss of vesicles due to fusion with the external membrane. The preferential loss of acetylcholine and ATP from the vesicle fraction indicates that the vesicles surviving the stimulation procedure have been utilized in a number of cycles causing the progressive fall in vesicle volume, and acetylcholine and ATP content.     

Adenosine triphosphate. A constituent of cholinergic synaptic vesicles

1. Synaptic vesicles separated by density-gradient centrifugation from extracts of the cholinergic nerve terminals of the electric organ of Torpedo marmorata were found to contain appreciable amounts of ATP as well as acetylcholine. 2. Vesicular ATP was stable in the presence of concentrations of apyrase and myokinase that rapidly destroyed equivalent amounts of endogenous or added free ATP; pre-treatment of cytoplasmic extracts of electric tissue with these enzymes destroyed endogenous free ATP, but did not affect the vesicular ATP. 3. When [U-(14)C]ATP was added to electric tissue at the time of comminution and extraction of the vesicles, all the radioactivity was associated with soluble components in the subsequent fractionation: none was associated with vesicles or membrane fragments; thus it is unlikely that vesicular ATP can be accounted for by the sequestration of endogenous free ATP within any vesicles formed during comminution and extraction of the tissue. 4. When synaptic vesicles were passed through iso-osmotic columns of Bio-Gel A-5m, which separates vesicles from soluble proteins and small molecules, all the recovered ATP and acetylcholine passed through together in the void volume. 5. Regression analysis showed that vesicular ATP content was highly correlated with vesicular acetylcholine content in different experiments, the molar ratio acetylcholine/ATP being 5.32+/-(s.e.m.) 0.45 (21 expts.) for the peak density-gradient fraction. The ratio varied, however, somewhat across the density-gradient peak suggesting some degree of chemical heterogeneity in the vesicle population.     

ISOLATION OF [3H]ACETYLCHOLINE POOLS BY SUBCELLULAR FRACTIONATION OF CEREBRAL CORTEX SLICES INCUBATED WITH [3H]CHOLINE

Abstract— Subcellular fractions were isolated from tissue incubated in [³H]choline with or without the addition of 33 mM-KCl. Radioactive and bioassayable ACh were measured in the synaptosomes, synaptosomal cytoplasm and in the vesicles. After incubation with KCI the vesicles, as isolated, contained ACh of a lower specific activity than the cytoplasmic ACh. Therefore the vesicle fraction as isolated does not represent the source of the high specific activity ACh released upon K⁺ stimulation. However the vesicle fraction is heterogeneous. Most of the bioassayable ACh but little of the radioactive ACh in the vesicles passed through iso-osmotic Sephadex columns. These results raise the question of the existence of vesicles which contain highly radioactive ACh but which lose it during their isolation by current methods. Different possible forms of heterogeneity are discussed.     

EFFECTS OF ACETYLCHOLINE ON THE IN CORPORATION OF [32P]ORTHOPHOSPHATE IN VITRO INTO THE PHOSPHOLIPIDS OF SUBSYNAPTOSOMAL MEMBRANES FROM GUINEA-PIG BRAIN

-Synaptosomes prepared from guinea-pig cerebral cortex were incubated with ³²P₁ in a medium with or without 10^?4 M-acetylcholine and 10^?4 M-eserine. They were then subjected to osmotic shock and density-gradient centrifugation for the preparation of subsynaptosomal fractions and the phospholipids of each fraction were separated by two-dimensional thin-layer chromatography. The fraction containing synaptic vesicles and that containing mitochondria were the most highly labelled of the sub-synaptosomal fractions. Phosphatidic acid followed by phosphatidylinositol had the highest specific activity of the phospholipids studied. Acetylcholine caused a marked increase in the specific activity of the vesicular but not of the mitochondrial phosphatidic acid. Phosphatidylinositol specific activity also increased in the presence of acetylcholine but the increase was more reproducible in the fraction containing microsomal membranes than in the vesicle fraction. The other phospholipids were relatively poorly labelled and no effect of acetylcholine on the incorporation of ³²P₁ into these lipids could be detected. Acetylcholine also caused a decrease in the amount of phosphatidic acid in the synaptic vesicles.     

Choline metabolism in the cerebral cortex of guinea pigs. Stable-bound acetylcholine

1. The turnover of synaptosomal (vesicular-cytoplasmic) and stable-bound (vesicular) acetylcholine isolated from cortical tissue was investigated after the administration, under local anaesthesia, of [N-Me-(3)H]choline into the lateral ventricles of guinea pigs. 2. Radioactive acetylcholine and choline present in acid extracts of subcellular fractions were separated by a combination of liquid and column ion-exchange and thin-layer chromatography. 3. The specific radioactivity and pattern of labelling of acetylcholine present in a fraction of monodisperse synaptic vesicles was found to be essentially the same as that of synaptosomal acetylcholine. 4. The specific radioactivity of stable-bound acetylcholine present in partially disrupted synaptosomes (fraction H) at short times (10-20min) after the injection of [N-Me-(3)H]choline was very variable and inversely related to the yield of acetylcholine in that fraction. 5. Evidence was found for the existence of two small, but highly labelled pools of acetylcholine, one which could be isolated in fraction H and the other which was lost when synaptosomes, after isolation by gradient centrifugation, were left at 0 degrees C or pelleted. 6. It is concluded that the results are best explained by metabolic differences among the nerve-ending compartments (thought to be vesicles) which contain stable-bound acetylcholine. Computer simulation of our experiments supports this possibility and suggests that the highly labelled pool in fraction H is present in vesicles close to the external membrane.     

Botulinum neurotoxin inhibits the release of newly synthesized acetylcholine from torpedo electric organ synaptosomes

In previous reports, we have shown that botulinum neurotoxin inhibits acetylcholine release from Torpedo marmorata electric organ and from its synaptosomal fraction. Here, we have focussed our attention on the study of the effect of botulinum neurotoxin on the metabolism of acetylcholine, namely, the precursors supply, the synthesis activity and the storage of the neurotransmitter into nerve endings isolated from Torpedo electric organ. Radiolabelled acetylcholine precursors (acetate and choline) uptake, choline O-acetyltransferase activity, and the compartmentalization of the transmitter into the synaptosomes were not modified by botullinum neurotoxin. When labelled nerve ending were depolarized by K⁺, the specific radioactivity of acetylcholine in the free pool fell markedly, but the specific radioactivity in the bound pool remained constant. Botulinum neurotoxin prevented this K⁺-induced decrease of specific radioactivity in the free pool.     

Identification of a heparan sulphate-containing proteoglycan as a specific core component of cholinergic synaptic vesicles from Torpedo marmorata.

Cholinergic synaptic vesicles isolated from the electric organ of Torpedo marmorata were found to contain a proteoglycan in their core. The glycosaminoglycan part co-migrates upon thin layer electrophoresis with heparan sulphate and shows a chemical composition characteristic for this carbohydrate. [35S]Sulphate injected into the electric lobes of Torpedo, which contain the perikarya of the electromotor neurons innervating the electric organs, appeared 48 h later in covalently bound form in the synaptic vesicle fraction. The radiolabel had been incorporated into the vesicular heparan sulphate. Upon SDS-polyacrylamide gel electrophoresis fluorography of labelled vesicles a major and a minor band are formed both migrating above a protein standard of mol. wt. 200 000. Similarly, a major peak in the void volume and a minor peak in the included volume are seen upon gel filtration in Ultrogel AcA 34 in the presence of SDS. We interpret the minor fraction as being formed by the loss of glycosaminoglycan from the major fraction. The proteoglycan is located inside the vesicle since antibodies directed against it form immunoprecipitates only with vesicles lysed by detergent treatment. The experiments show that it is possible to label a synaptic organelle specifically by axonal transport.     

STUDIES ON SOLUBLE PROTEINS RELEASED FROM THE SYNAPTIC VESICLES OF RAT BRAIN CORTEX

Abstract— The soluble proteins released from the synaptic vesicles of rat cerebral cortex were studied. One fraction (D₄) of these proteins was released in parallel with release of acetylcholine when synaptic vesicles were incubated at 37°C for 10 min in isotonic medium. Another fraction (Dj) was liberated from synaptic vesicles when their membranes were ruptured by mild treatment under hyposmotic conditions and freeze-thawing after release of D₁ fraction. Fractions D₁ and D₂ contained 12 and 9 per cent, respectively, of the total protein in the synaptic vesicles. Some properties of these fractions were investigated by zone electrophoresis and ultracentrifugation, and by measuring their binding capacities for [¹⁴C]acetylcholine and various enzyme activities related to acetylcholine metabolism.     

Changes in cholinergic synaptic vesicle populations and the ultrastructure of the nerve terminal membranes of Narcine brasiliensis electron organ stimulated to fatigue in vivo

Narcine brasiliensis electric organ was stimulated to fatigue in vivo. Electrical display of organ output and biochemical assay of bound acetylcholine (ACh) and ATP in isolated vesicles were used to assess the state of fatigue relative to denervated control organs of the same fish. A morphometric analysis of the fate of the synaptic vesicle populations in the nerve terminals was carried out. Statistically significant morphological changes in vesicle populations and plasma membranes were observed between control and fatigued electroplaque stacks from individual fish. Pooled data from several fish were used to evaluate the possible role of the different vesicle types in neurotransmission. Fatigue resulted in the loss of 49% of the total vesicle population and a 76% loss of vesicles with bound calcium (Ca). An approximately equivalent increase in the nerve-terminal plasma membrane area was measured. This was predominantly in the form of fingerlike protrusions and/or invaginations of the terminals which were present in the control organs but which were significantly increased by stimulation. Vesicle attachments to the nerve terminal membrane were reduced by 90%. This suggests that the failure in transmission may be due to reduction in the number of vesicles which are loaded with transmitter and can attach to the terminal membrane. The Ca-binding capacity of the lost vesicles was not transferred to the plasma membranes. This result was interpreted as support for the hypothesis that vesicle-bound ATP provides the Ca-binding site.     

SUBCELLULAR LOCALIZATION OF NEWLY-FORMED [3H]ACETYLCHOLINE IN RAT CEREBRAL CORTEX IN VITRO

—Slices from rat brain cortex were incubated for either 5 or 60 min in a medium containing [³H]choline and 4·7 or 25 mm -KCl. Bioassayable ACh and labelled ACh were determined in the incubation medium, in the total tissue homogenate and in subcellular fractions. Raising the KCl concentration from 4·7 to 25 mm stimulated the release and synthesis of total and of labelled ACh. In medium containing 25 mm -KCl the amounts of ACh decreased in the tissue and in the nerve ending cytoplasm, but remained constant in the synaptic vesicles. After incubation in 25 mm -KCl medium the ACh in the vesicles was labelled to the same extent as the cytoplasmic ACh but after incubation in 4·7 mm -KCl medium vesicular ACh was labelled less than cytoplasmic ACh. During 5 min incubation in medium containing 25 mm -KCl the ratio of labelled to total ACh was much higher in the medium than in the homogenate, the vesicles or the cytoplasm. During the last 15 min of the 60 min incubation the ratio of labelled to total ACh in the medium was still higher than that in the tissue fractions, but less so than during the 5 min incubation. It is concluded that the vesicular and cytoplasmic fractions are not identical with the store in the tissue from which newly-synthesized ACh is preferentially released.     

猪肺血管紧张素转换酶的提纯

本文报道了猪肺血管紧张素转换酶(ACE)的提纯方法及其鉴定,并讨论了方法的改进。肺匀浆经1.6—2.6mol/L硫酸铵沉淀,Sephadex G-200凝胶过滤,DEAE-Sephaeel及羟基磷灰石柱层析步骤,从168克肺中获得4.5毫克酶蛋白纯品。活力回收45.2％,比活力15.6单位/毫克蛋白;和匀浆上清比较,提纯390倍。经聚丙烯酰胺凝胶电泳(pH8.3)鉴定为一条带。按SDS聚丙烯酰胺凝胶电泳(SDS-PAGE)测得其分子量为132,000道尔顿。酶蛋白在-30℃貯存10月,比活力丢失30％。     

Characterization of a membrane protein from cholinergic synaptic vesicles isolated from the electric organ of Torpedo marmorata

Rabbits were immunized with cholinergic synaptic vesicles isolated from the electric organ of Torpedo marmorata. The resultant antiserum had one major antibody activity against an antigen called the Torpedo vesicle antigen. This antigen could not be demonstrated in muscle, liver or blood and is therefore, suggested to be nervous-tissue specific. The vesicle antigen was quantified in various parts of the nervous system and in subcellular fractions of the electric organ of Torpedo marmorata and was found to be highly enriched in synaptic vesicle membranes. The antigen bound to concanavalin A, thereby demonstrating the presence of a carbohydrate moiety. By means of charge-shift electrophoresis, amphiphilicity was demonstrated, indicating that the Torpedo vesicle antigen is an intrinsic membrane protein. The antigen was immunochemically unrelated to other brain specific proteins such as 14-3-2, S-100, the glial fibrillary acidic protein and synaptin. Furthermore, it was unrelated to two other membrane proteins, the nicotinic acetylcholine receptor and acetylcholinesterase, present in Torpedo electric organ. The antiserum against Torpedo synaptic vesicles did not react with preparations of rat brain synaptic vesicles or ox adrenal medullary chromaffin granules.     

DIFFERENT RECOVERY RATES OF THE ELECTROPHYSIOLOGICAL, BIOCHEMICAL AND MORPHOLOGICAL PARAMETERS IN THE CHOLINERGIC SYNAPSES OF THE TORPEDO ELECTRIC ORGAN AFTER STIMULATION

—During stimulation there occurred a decay in electrical response, vesicular acetylcholine, ATP and nucleotide as well as a loss of vesicle number and a decrease in vesicle diameter in the electric organ of Torpedo. These alterations were re-established during a subsequent recovery period. The different parameters recovered at different rates. Firstly, electrical response to single pulses recovered to prestimulation values within about 5 h. Vesicle number and diameter as well as bouton size were found to be re-established fully after 24 h. The newly formed vesicles appeared to be empty as vesicular acetylcholine, ATP and total nucleotide recovered much more slowly and were back to control values after about three days. Acetylcholine reappeared more quickly in the vesicles than ATP. Only after recovery of the vesicular pool of transmitter and ATP did the electric organ regain full stability of the electric discharge pattern on restimulation.     

Single-channel current recordings of acetylcholine receptors in electroplax isolated from theElectrophorus electricus main and Sachs' electric organs

Summary Extensive chemical kinetic measurements of acetylcholine receptor-controlled ion translocation in membrane vesicles isolated from the electroplax ofElectrophorus electricus have led to the proposal of a minimum model which accounts for the activation, desensitization, and voltage-dependent inhibition of the receptor by acetylcholine, suberyldicholine, and carbamoylcholine. Comparison of chemical kinetic measurements of the dynamic properties of the acetylcholine receptor in vesicles with the properties of the receptor in cells obtained from the same organ and animal have been hampered by an inability to make the appropriate measurements withElectrophorus electricus electroplax cells. Here we report a method for exposing and cleaning the surface of electroplax cells obtained from both the Main electric organ and the organ of Sachs and the results of single-channel current recordings which have now become possible. The single-channel current recordings were made in the presence of either carbamoylcholine or suberyldicholine, as a function of temperature and transmembrane voltage. Both the channel open times and the single-channel conductance were measured. The data were found to be consistent with the model based on chemical kinetic measurements using receptor-rich membrane vesicles prepared from the Main electric organ ofE. electricus.     

Boar acrosin is a two-chain molecule. Isolation and primary structure of the light chain; homology with the pro-part of other serine proteinases

Cholinergic synaptic vesicles from the electric organ of Torpedo marmorata are associated with a Mg2+-ATPase insensitive to ouabain and oligomycin. Treatment of vesicle membranes with dichloromethane releases a Mg2+-ATPase with apparent molecular mass of around 250 kDa as determined by gel filtration. The vesicular ATPase resembles the mitochondrial F1-ATPase in these properties. Gel electrophoresis of the solubilized ATPase shows however that only a single 50-kDa band is present as compared to the alpha-subunit (52 kDa) and beta-subunit (50 kDa) of electric organ mitochondrial F1-ATPase present in this range of molecular mass range. In agreement, covalent photoaffinity labelling of isolated vesicles with azido-ATP shows a 50-kDa band. Vesicle ghosts were found to accumulate [14C]methylamine in an ATP-dependent manner indicating the presence of an inwardly directed proton pump. We conclude that cholinergic vesicles contain a proton pump probably driven by the Mg2+-ATPase here described, which generates an electrochemical gradient across the vesicle membrane and is necessary for uptake and storage of acetylcholine within the vesicles.     

THE FORMATION OF CHOLINE AND OF ACETYLCHOLTNE BY BRAIN IN VITRO

Abstract— Free choline and acetylcholine (ACh) in mouse or rat brain were assayed biologically. The subcellular distribution of ACh in brain slices that had been incubated in the presence of eserine was compared to that in control brain; during incubation, the ACh outside nerve endings increased four-fold, the ACh released from synaptosomes by osmotic shock doubled but the ACh bound firmly within nerve endings did not increase. The two nerve ending stores of ACh were labelled to similar specific radioactivities when slices were incubated with [³H]choline, but the specific radioactivity of the ACh formed was much lower than that of the added choline. Tissue incubated in the presence of eserine released choline and ACh into the medium and the tissue levels of both substances increased. Brain tissue exposed to Na⁺-free medium lost 84 per cent of its ACh and 66 per cent of its free choline; the amounts of both substances returned towards control values during subsequent incubation in a normal-Na⁺ medium (choline-free). Both the ACh outside nerve endings and the ACh associated with synaptosomes were depleted when tissue was incubated in Na⁺-free medium.     

Identification of a phenylalanine ammonia-Iyase inactivating factor in harvested head lettuce (Lactuca sativa)

Exposing head lettuce ( Lactuca sativa L., crisphead or Iceberg type) leaf tissue to hormonal levels of ethylene (10 μl l⁻¹) at 5°C promotes the de novo synthesis of phenylalanine ammonia-lyase (PAL, EC 4.3.1.5) and an increase in its activity. It also promotes the appearance of the postharvest physiological disorder called russet spotting (RS). Discontinuing ethylene exposure after 4 days resulted in a rapid decline in PAL activity which was delayed by treating excised midrib leaf tissue with actinornycin D or cycloheximide at 5°C. Only cycloheximide delayed the loss of PAL activity in tissue that was transferred from 5 to 15°C. Activity of PAL from Rhodolorula glutinis was. slowly lost during incubation in buffer alone, but there was a logarithmic decline in its activity over time when it was incubated with aliquots of the resuspended 10000 g pellet from homogenized, lettuce tissue affected with RS. The in vitro loss in PAL activity was 9–fold higher in extracts from lettuce showing RS symptoms than from control lettuce, boiled samples or the buffer control. The PAL-inactivating factor isolated from lettuce affected with RS had a pH optimum around 8.0. It appears that the rapid loss in PAL activity after the discontinuation of exposure to ethylene is dependent on the de novo synthesis of a PAL-inactivating factor.