Is Propionylcholine Present in or Synthesized by Electric Organ?

When small blocks comprising four columns of electrocytes were excised from electric organs of Torpedo marmorata after stimulation in vivo via the electric lobe at 1 Hz for 1 h and allowed to recover at 20-22 degrees C for several hours in medium containing 100 microM d4 choline and 500 microM propionate, small quantities of propionylcholine amounting to no more than 1% of the endogenous acetylcholine of the tissue could be detected in tissue extracts by gas chromatography-mass spectrometry (GCMS). Kinetic studies demonstrated that there was no nonexchangeable propionylcholine in the tissue and in the absence of added propionate, propionylcholine levels were less than 0.2% of tissue acetylcholine. Vesicular propionylcholine amounted to less than 0.5% of vesicular acetylcholine and the distribution of d0 and d4 propionylcholine suggested that an appreciable proportion (up to one-third) of this could be an artifact of preparation for GCMS determinations. Propionylcholine formation during extraction and demethylation of an artificial mixture of acetylcholine, choline, and propionate was indeed detected. It is concluded that propionylcholine has no significance as an endogenous or as a false transmitter at this terminal, in conformity with the work of Sheridan et al. [Z. Zellforsch. 74, 281-307 (1966)] but in contrast to the report of O'Regan [J. Neurochem. 39, 764-772 (1982)].     

A Kinetic Study of Stimulus-Induced Vesicle Recycling in Electromotor Nerve Terminals Using Labile and Stable Vesicle Markers

The kinetics of recovery, by recycling electromotor synaptic vesicles, of the biophysical parameters of the reserve population has been studied in perfused blocks of electric organ of Torpedo marmorata prestimulated in vivo, followed by density gradient separation of the extracted vesicles in a zonal rotor using labile (acetylcholine and ATP) and stable (proteoglycan) vesicle markers. Stimulation in vivo at 0.15 Hz for 3.3 h depleted tissue acetylcholine much less than stimulation at 1 Hz for 1 h but nevertheless generated a much larger pool of recycled vesicles that recovered more slowly. At the lower rate of stimulation, recovery of the biophysical characteristics of the reserve population by the recycled vesicles, identified by their content of newly synthesized transmitter, was essentially complete by 8 h. The stable proteoglycan marker was immunochemically assayed and was bimodally distributed in the vesicle-containing portion of the density gradient even in experiments with unstimulated or recovered tissue. The second peak corresponded with that of newly synthesized transmitter and was thus identified as containing the recycled vesicles. Its normalized acetylcholine/proteoglycan ratio was lower than that of the first peak, which is consistent with earlier findings that recycled vesicles, before recovery, are only partially loaded with transmitter. However, as expected, the proportion of total vesicular proteoglycan and acetylcholine associated with the recycled vesicle fraction was very much lower in preparations derived from unstimulated or recovered tissue than in those from recently stimulated tissue.     

Isoosmotic isolation of rat brain synaptic vesicles, some of which contain tyrosine hydroxylase

Rat brain synaptic vesicles were isoosmotically isolated and examined for Mg(2+)-ATPase [EC 3.6.1.3.] and tyrosine hydroxylase [EC 1.14.16.2.] associated with the synaptic vesicles. Synaptosomes in 0.32 M sucrose were disrupted by freezing and thawing treatment, and the cytosol fraction was fractionated on a Sephacryl S-500 column with a mean exclusion size of 200 nm. Peak I at the void volume was a mixture of large vesicular membranes, small amounts of synaptic vesicles and coated vesicles, etc. Peak II consisted of non- and granulated synaptic vesicles of 35-40 nm diameter, and peak III of soluble proteins. The synaptic vesicles in peak II reacted with antibodies against the H(+)-ATPase A-subunit, vesicular acetylcholine transporter, and vesicular monoamine transporter. However, they showed little Mg(2+)-ATPase activity. Tyrosine hydroxylase was observed in either peak II or III on blotting with an anti-tyrosine hydroxylase antibody. These results imply that tyrosine hydroxylase exists in soluble and bound forms to synaptic vesicles in nerve terminals.     

The release of acetylcholine: from a cellular towards a molecular mechanism

The isolation of synaptic vesicles rich in acetylcholine (ACh) from the electric organ of Torpedo has indeed strengthened the hypothesis of transmitter exocytosis, but soon after it was found that non-vesicular free ACh was released and renewed upon stimulation. In contrast, vesicular ACh and the number of vesicles remained stable during physiological stimulations. In addition free ACh variations (representing the cytoplasmic pool) were correlated to the release kinetics as measured by the electroplaque discharge. Consequently, the mechanism releasing ACh from the cytoplasm in a packet form was searched at the presynaptic membrane itself. With synaptosomes isolated from the electric organ of Torpedo, it became possible to freeze them rapidly at the peak of ACh release and study their membrane and contents after cryofracture. A statistical analysis showed that the main structural change was the occurrence of large intramembrane particles at the peak of ACh release and under all release conditions. This impressive change contrasted with the stability in the number of vesicles. Another role for the vesicle was envisaged during intense stimulations when the cytoplasmic ACh and ATP pools become exhausted. The decrease in ATP leads to an increase in calcium and protons in the cytoplasm; this signals the depletion of vesicular ACh and ATP stores in the cytoplasm. Release can go on, while ATP promotes the uptake of calcium by vesicles. At the end of its cycle the vesicle will be full of calcium and will perhaps release it. As far as the mechanism of ACh release is concerned it probably depends on a membrane component (perhaps the large particles) activated by calcium and able to translocate ACh in a quantal or subquantal form. In most recent work we showed that if a lyophilized presynaptic membrane was used to make proteoliposomes filled with ACh, they released ACh upon calcium action.     

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.     

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.     

Exchangeability of radioactive acetylcholine with the bound acetylcholine of synaptosomes and synaptic vesicles

1. The exchangeability with added radioactive acetylcholine of the acetylcholine in isolated presynaptic nerve terminals (synaptosomes) and isolated synaptic vesicles was studied by a Sephadex-column method. 2. A substantial proportion of the synaptosomal acetylcholine is exchangeable with added radioactive acetylcholine. It is liberated by hypo-osmotic shock and ultrasonic treatment, and behaves as though it occupies the cytoplasmic compartment of synaptosomes. 3. Methods of isolating vesicles from hypo-osmotically ruptured synaptosomes in optimum yield are discussed. 4. The acetylcholine of synaptic vesicles isolated on a sucrose density gradient is released by hypo-osmotic conditions, suggesting that it is enclosed by a semi-permeable membrane; however, it is not easily released by ultrasonic treatment. 5. Added radioactive acetylcholine does not exchange with vesicular acetylcholine under a variety of different conditions. These include addition of ATP and Mg(2+), and pre-loading of the synaptosome with radioactive acetylcholine before hypo-osmotic rupture. This failure to exchange is discussed in terms of the possible storage mechanism of vesicular acetylcholine.     

The isolation of pure cholinergic synaptic vesicles from the electric organs of elasmobranch fish of the family Torpedinidae

1. Zonal centrifuging permitted the separation, on the milligram scale and in a form largely free from contamination by soluble cytoplasmic protein or membrane fragments derived from other structures, of synaptic vesicles from the purely cholinergic terminals of the electric organ of Torpedo. Up to 100g of tissue could be processed in a single run. 2. As much as 46% of the bound acetylcholine from the original tissue preparation was recovered as a single peak of density equivalent to 0.38m-sucrose-0.21m-NaCl and with a concentration of up to 680nmol of acetylcholine/mg of protein. 3. The limiting concentration of acetylcholine in isolated vesicles when allowance had been made for non-vesicular protein appeared to be about 600nmol/mg of protein. 4. Vesicle counts by a ;bead-tagging' procedure indicated an acetylcholine content of about 360mumol/ml of vesicles; thus the vesicle protein content would be about 60% (w/v). 5. Calculations showed that the core of the vesicle, accounting for about 55% of the vesicle volume, could be largely filled with acetylcholine and protein.     

Thiamine and Cholinergic Transmission in the Electric Organ of Torpedo

The electric organ of Torpedo marmorata was found to contain as much as 120 +/- 24 nmol of thiamine per g of fresh tissue. The vitamin was distributed as nonesterified thiamine (32%), thiamine monophosphate (22%), thiamine diphosphate (8%), and an important proportion of thiamine triphosphate (38%). A high level of thiamine triphosphate was found in synaptosomes isolated from the electric organ. In contrast, the synaptic vesicles did not show any enrichment in thiamine, whereas they contained a marked peak of acetylcholine (ACh) and ATP. Thus thiamine seems to be very abundant in cholinergic nerve terminals; its localization is apparently extravesicular, either in the axoplasm or in association with plasma membrane. When calcium was reduced and magnesium increased in the external medium, the efficiency of transmission was diminished, owing to inhibition of ACh release; in a parallel manner the degree of thiamine phosphorylation was found to increase--this condition is known to modify the repartition of ACh between vesicular and extravesicular compartments. Electrical stimulation, which causes periodic variations of the level of ACh and ATP, also caused significant changes in thiamine esters. In addition, related changes of the vitamin and the transmitter were observed under other conditions, suggesting a functional link between the metabolism of thiamine and that of ACh in cholinergic nerve terminals.     

Isolation of mitotic apparatus containing vesicles with calcium sequestration activity

We present the first report of isolated mitotic apparatus with vesicular calcium sequestration. Phase-contrast, differential interference contrast and polarized light microscopy as well as transmission and scanning electron microscopic examinations revealed structures comparable to mitotic apparatus in vivo. Numerous membrane-bound vesicles which retained their osmotic activity were present throughout. Microtubules, yolk, ribosomes and condensed chromatin were also present. The protein composition of mitotic apparatus was not dramatically altered by treatment with 0.5% Triton X-100, even though vesicles were destroyed and yolk was extracted. Calcium sequestration was demonstrated with ATP-dependent accumulation of ⁴⁵Ca by mitotic apparatus whose vesicles were left intact. Compared with controls for which no nucleotide was added, accumulation by mitotic apparatus with intact vesicles was enhanced to 184% when it was present. When ATP was supplemented with the divalent ionophore A23187, the calcium retention level was comparable to that of the control to which no nucleotide was added. Finally, the calcium accumulation by mitotic apparatus treated with either of the nonhydrolyzable ATP analogs AMPPCP or AMPPNP resulted in calcium retention levels similar to those of controls. The solubilization of vesicles with Triton X-100 abolished calcium accumulation in the presence or absence of any of the above additives. Resolution of vesicles on sucrose step gradients after ⁴⁵Ca-oxalate loading with ATP or AMPPCP indicates that a specific vesicular fraction sequesters ⁴⁵Ca.     

The subcellular distribution of [N-Me-3H]-acetylcholine synthesized by brain in vivo

1. Three forms of acetylcholine occur in subcellular fractions of brain tissue: free acetylcholine, present in the high-speed supernatant from eserinized sucrose homogenates; stable bound acetylcholine, present in synaptic vesicles; and labile bound acetylcholine, present in the cytoplasm of synaptosomes (detached presynaptic nerve terminals). 2. The relationship between these forms has been investigated by isolating the subcellular fractions from the cortical tissue of cats and guinea pigs excised 1hr. after infiltration of [N-Me-(3)H]choline into the cortex in vivo. 3. Since choline is a ubiquitous metabolite, means were devised for isolating the radioactive acetylcholine on columns of the weak acid ion-exchange resin IRF-97; control experiments with samples of extracts treated with acetylcholinesterase showed that the radioactivity attributed to acetylcholine migrated to the choline peak after cholinesterase treatment. 4. The specific radioactivities of the various forms of acetylcholine were different: labile bound (synaptosomal cytoplasmic) acetylcholine had the highest, stable bound (vesicular) acetylcholine the next highest, and the high-speed-supernatant form the lowest. 5. It is concluded that the various forms of acetylcholine could not have arisen during fractionation from a single pre-existing pool of acetylcholine.     

Translocation of cytosolic acetylcholine into synaptic vesicles and demonstration of vesicular release

The rate of translocation of newly synthesized acetylcholine (ACh) from the presynaptic cytosol of Torpedo electric organ nerve terminals into synaptic vesicles and the extent to which ACh release from these neurons is mediated by a vesicular mechanism were investigated. For this purpose the compound 2(4-phenylpiperidino)cyclohexanol (AH5183), which inhibits the active transport of ACh into isolated cholinergic synaptic vesicles, was employed. Preincubation of purified Torpedo nerve terminals (synaptosomes) with AH5183 does not affect the intraterminal synthesis of [3H]ACh but results in a marked inhibition (85%) of its Ca2+-dependent K+-evoked release. By contrast, the evoked release of the endogenous nonlabeled ACh is not affected by this compound. When AH5183 is added during radiolabeling, it causes a progressively smaller inhibition of [3H]ACh release which is completely abolished if the drug is added after the preparation has been labeled. These findings suggest that most of the newly synthesized synaptosomal [3H]ACh (85%) is released by a vesicular mechanism and that some [3H]ACh (15%) may be released by a different process. The translocation of cytosolic [3H]ACh into the synaptic vesicles was monitored by determining the time course of the loss of susceptibility of [3H]ACh release to AH5183. It was found not to be coupled kinetically to [3H]ACh synthesis and to lag behind it. The nature of the intraterminal processes underlying this lag is discussed.     

Biosynthesis of acetyl-coenzyme A in the electric organ of Torpedo marmorata in relation to acetylcholine metabolism.

Formation of acetyl-CoA through acetyl-CoA synthetase (forward reaction) and through choline acyltransferase (backward reaction) was investigated in tissue extract from the electric organ of Torpedo marmorata. When the tissue extract was submitted to gel filtration on Sephadex G-25, the formation of acetyl-CoA by acetyl-CoA synthetase appeared fully dependent on ATP and CoA and partially dependent on acetate (an endogenous supply of acetate is discussed). Choline acetyltransferase was a potent source of acetyl-CoA, only requiring acetylcholine and CoA, and was much more efficient than acetyl-CoA synthetase for concentrations of acetylcholine likely to be present in nerve endings.     

Characterization, by Size, Density, Osmotic Fragility, and Immunoaffinity, of Acetylcholine- and Vasoactive Intestinal Polypeptide-Containing Storage Particles from Myenteric Neurones of the Guinea-Pig

When cytoplasmic extracts of guinea-pig myenteric neurones are submitted to centrifugal density gradient fractionation in a zonal rotor acetylcholine is bimodally distributed in the gradient, in a peak (I) rich in synaptic vesicles of the classic type and in a denser peak (II/VI) rich in densecored vesicles and vasoactive intestinal polypeptide (VIP). The putative stable synaptic vesicle markers synaptophysin (p38), vesicular proteoglycan, and Mg2+-activated ATPase were also bimodally distributed, with a peak coincident with peak I and another, broader peak embracing peak II/VI, and neighbouring peaks of other neuropeptides resolved from peak II/VI by the density gradient separation procedure used. To establish whether the stable markers, acetylcholine and VIP in peak II/VI were present in one particle or several, attempts were made to separate them by particle-exclusion chromatography and differential osmotic fragility. These were unsuccessful, leading us to conclude that the storage particles in peak II/VI contain both neurotransmitters and all three putative stable synaptic vesicle markers. It is suggested that such particles are the counterparts, in cholinergic neurones of the myenteric plexus, of the dense-cored, enkephalin- and noradrenaline-containing vesicles of certain adrenergic neurones and, like the latter, may exist in a precursor-product relationship with the classic synaptic vesicles containing the small-molecular-mass transmitters and found in the same nerve terminals.     

Veratridine-activated release of adenosine-5'-triphosphate from synaptosomes: evidence for calcium dependence and blockade by tetrodotoxin.

Cholinergic synaptosomes from squid brain were found to release almost 50% of their total endogenous ATP when exposed to veratridine, an alkaloid which activates action potential sodium channels in nervous tissue. Veratridine also depolarizes synaptosomes and induces transmitter release by a mechanism which is dependent upon free Ca⁺⁺ in the medium and is inhibited by tetrodotoxin, a specific veratridine inhibitor. ATP release activated by veratridine was also found to be calcium dependent and tetrodotoxin-sensitive. A new filter assay was developed to measure the kinetics of ATP release quantitatively, and veratridine-activated ATP release from synaptosomes was found to be complete in less than 30 seconds. Since ATP is a major component of cholinergic vesicles, this finding supports the concept that transmitter release from synaptosomes may occur from a vesicular rather than from a cytoplasmic pool.     

The Isolation of Actin from Pea Roots by DNase I Affinity Chromatography

Native actin can be isolated from pea (Pisum sativum L.) roots by DNase I affinity chromatography, but the resulting yields and quality of actin are variable. By use of two assays for actin, a DNase I inhibition assay and a gel scanning assay, we identified several factors that increased actin yield. ATP is required for the actin in crude pea root extracts to bind to immobilized DNase I. Low amounts of ATP are hydrolyzed rapidly by an endogenous ATPase in the extract, and the actin then irreversibly loses the ability to bind to DNase I. High ATP concentrations (5-10 mm) or inhibition of the ATPase (with 10 mm pyrophosphate) are required for pea actin to retain DNase I binding ability. When adequate amounts of ATP are present, actin binding from the extract is further enhanced by basic pH, formamide, and soluble polyvinyl-pyrrolidone. Once actin is bound to the DNase I-agarose and washed free of extract, high ATP concentrations are not required to keep actin bound. Actin eluted from the DNase I-agarose with formamide retained its ability to polymerize into filaments with the addition of KCl and Mg²⁺. The advantages and disadvantages of this procedure and its application to other plant materials are discussed.     

ASPECTS OF ACETYLCHOLINE METABOLISM IN THE ELECTRIC ORGAN OF TORPEDO MARMORATA

Abstract— —The synthesis of acetylcholine and its compartmentation were studied in the electric organ of Torpedo marmorata. When electric organ was homogenized in iso-osmotic NaCl-sucrose some 55 per cent of its acetylcholine content was lost unless very potent cholinesterase inhibitors were present. Slices of electric organ incubated in a suitable medium were found to synthesize radioactive-labelled acetylcholine from [ N-Me-³ H] choline. The specific activity of the labelled acetylcholine was higher in the trichloracetic acid extract of the organ slices than in an NaCl-sucrose homogenate. Acetylcholine-containing vesicles isolated from the NaCl-sucrose homogenate contained labelled acetylcholine with about the same specific activity as the parent homogenate. There was thus a fraction of acetylcholine in the incubated tissue of higher specific radioactivity that was lost when the tissue was homogenized. The acetylcholine-containing vesicles lose their acetylcholine when submitted to gel filtration under hypo-osmotic conditions. On standing at 5°C there were only small losses of acetylcholine from the vesicles but at 20°C the losses were substantial. Vesicles containing labelled acetylcholine were studied. On gel filtration under iso-osmotic conditions there was a considerable loss of labelled acetylcholine without a concomitant loss of bio-assayable acetylcholine. The pools of radioactive and bio-assayable acetylcholine are therefore not homogeneous in the vesicles as isolated.     

EFFECTS OF ACTINOMYCIN D AND PUROMYCIN ON THE ACTH-INDUCED ULTRASTRUCTURAL TRANSFORMATION OF MITOCHONDRIA OF CORTICAL CELLS OF RAT ADRENALS IN TISSUE CULTURE

The ultrastructure of the mitochondria of the cultured cortical cells of rat adrenals was studied. In vivo it was found that the zona fasciculata mitochondria have vesicular internal structure. 600-A vesicles appear free in the matrix or as protrusions of the inner mitochondrial membrane. In tissue cultures of the fetal and newborn rat adrenal cortex it was seen that ACTH induces transformation of the tubulo-vesicular internal structure of the mitochondria to 600-A vesicles. Actinomycin D and puromycin inhibited this transformation if they were added with ACTH. When added alone, these inhibitors of protein synthesis induced no change in the ultrastructure of the mitochondria in cultured cortical cells of rat adrenals.     

ATP-stimulated degradation of endogenous proteins in cell-free extracts of BHK 21/C13 fibroblasts. A key role for the proteinase, macropain, in the ubiquitin-dependent degradation of short-lived proteins.

Baby hamster kidney (BHK) 21/C13 cell proteins, labeled with [35S]methionine, [14C]leucine or [3H]leucine in intact cells, were degraded in soluble, cell-free extracts by an ATP-stimulated process. The stimulatory effect of ATP appeared to require ATP hydrolysis and was mediated to a large extent by ubiquitin. Although the cell extracts contained endogenous ubiquitin, supplementation with exogenous ubiquitin increased ATP-dependent proteolysis by up to 2-fold. Furthermore, antibodies against the E1 ubiquitin conjugating enzyme specifically inhibited both conjugation of [125I]ubiquitin to endogenous proteins and ATP/ubiquitin-dependent proteolysis. Addition of purified E1 to antibody-treated extracts restored conjugation and proteolysis. Proteins containing the amino acid analogues canavanine and azatryptophan were also degraded in vitro by an ATP/ubiquitin-dependent process but at a rate up to 2-fold faster than normal proteins. These results indicate that soluble, cell-free extracts of BHK cells can selectively degrade proteins whose rates of degradation are increased in intact cells. Treatment of cell-free extracts with antibodies against the high molecular weight proteinase, macropain, also greatly inhibited the ATP/ubiquitin-dependent degradation of endogenous proteins. Proteolysis was specifically restored when purified macropain L was added to the antibody-treated extracts. Treatment of cell extracts with both anti-macropain and anti-E1 antibodies reduced ATP/ubiquitin-dependent proteolysis to the same extent as treatment with either antibody alone. Furthermore, proteolysis could be restored to the double antibody treated extracts only after addition of both purified E1 and macropain. These results provide strong evidence for an important role for macropain in the ATP/ubiquitin-dependent degradation of endogenous proteins in BHK cell extracts.     

Partial characterization of protein kinase-catalyzed phosphorylation of low molecular weight proteins in purified preparations of pigeon heart sarcolemma and sarcoplasmic reticulum.

Pigeon heart microsomes contain three minor size protein kinase substrates of minimal molecular weights of 22 000, 15 000, and 11500, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. When the microsomes were partially loaded with calcium oxalate and subjected to rate zonal and isopycnic centrifugations in sucrose density gradient columns, the 22 000 and the 15 000 dalton proteins settled in the heaviest fraction, which was composed mainly of vesicles of sarcoplasmic reticular membranes; the 11 500 dalton protein was concentrated in the lightest fractions, which consisted chiefly of vesicles of sarcolemmal origin. During incubation of the membrane fractions with Mg [gamma-32P]ATP significant amounts of 32P were incorporated into all these proteins. Incorporation of 32P into the 15 000 dalton protein was moderately and 32P incorporation into the 22 000 dalton protein was markedly enhanced in the presence of exogenous soluble cyclic AMP-dependent protein kinase and cyclic AMP. The phosphorylation of the three proteins was virtually unaffected by Ca2+ concentrations up to 0.1 mM and by ethyleneglycol-bis-(beta-aminoethyl-ether)-N,N'-tetraacetic acid in the absence of added Ca2+. Phosphorylation of the 22 000 and the 11 500 dalton proteins occurred mainly at serine residues. In the 15 000 dalton protein threonine residues were the main site of endogenous phosphorylation. Nearly equal amounts of [32P]-phosphate were incorporated into threonine and serine residues of this protein, when phosphorylation was supported by exogenous cyclic AMP-dependent protein kinase and cyclic AMP. The 15 000 dalton protein could be removed from its membrane attachment by extraction with an acidic chloroform/methanol mixture. This step opens the way for the purification of this membrane-bound protein kinase substrate.