THE INFLUENCE OF THE MODE OF NUTRITION ON THE DIGESTIVE SYSTEM OF OCHROMONAS MALHAMENSIS

The intracellular distribution and level of acid hydrolases in Ochromonas malhamensis were studied in cells grown osmotrophically in a defined medium, in a carbon-free starvation medium, and during phagotrophy in each of these media. By cytochemical techniques, little enzymic reaction product was observed in the vacuoles of osmotrophic cells grown in the defined medium. Starved cells, however, contained autophagic vacuoles and cannibalized other Ochromonas cells. Dense enzymic reaction product was observed in the digestive vacuoles and in the Golgi cisternae of these starved cells. Moreover, starved cells and cells grown in a nutritionally complete medium ingested Escherichia coli which appeared in digestive vacuoles containing enzymic reaction product. Biochemical assays for lysosomal acid phosphatase (E.C. 3.1.3.2 orthophosphoric monoester phosphohydrolase) and acid ribonuclease (E.C. 2.7.7.16 ribonucleate nucleotido-2'-transferase) were done on Ochromonas cultures in the same experimental treatments and under identical assay conditions as the cytochemical study. During starvation, the acid hydrolase specific activities were consistently twice those found in cells grown in an osmotrophic complete medium. Ochromonas fed E. coli showed no increase in acid hydrolase specific activity as compared to controls not fed E. coli. The latency of lysosomal acid hydrolases in cells fixed with glutaraldehyde was reduced, suggesting that this fixative increases lysosomal membrane permeability and may release enzymes or their reaction products into the cytoplasmic matrix during cytochemical analysis. This could explain the cytoplasmic staining artifact sometimes observed with glutaraldehyde-fixed cells when studied by the Gomori technique. This study confirms that Ochromonas malhamensis, a phytoflagellate, does produce digestive vacuoles and can ingest bacteria, thereby fulfilling its role as a heterotroph in an aquatic food chain. When Ochromonas is grown in a nutritionally complete osmotrophic medium, phagocytosis causes appearance of acid hydrolases in the digestive vacuoles, whereas the total activity of the enzymes remains unchanged. An organic carbon-free medium strongly stimulates acid hydrolaes activity and causes these enzymes to appear in the digestive vacuoles whether phagocytosis occurs or not.     

DYNAMICS OF ACRIDINE ORANGE-CELL INTERACTION : I. Interrelationships of Acridine Orange Particles and Cytoplasmic Reddening

The in vitro localization of acridine orange (AO) in living cells was monitored by means of fluorescence microscopy, quantitative cell viability studies, and photofluorimetric measurements following dye-cell interaction. The parameters, pH, time, dye concentration, and the metabolic state of the cell were found to exert a profound influence on the time course and distribution of staining. The parameters studied are mutually interdependent, and intracellular dye localization may be predictably altered by their appropriate manipulation. Conditions are defined whereby two morphologically distinct but physiologically interrelated reactions, namely, acridine orange particle (AOP) formation and cytoplasmic reddening (CR) may be caused, prevented, reversed, or modified. These results are explained in terms of the facilitation or inhibition of an intracytoplasmic dye-segregating mechanism, in turn affected by the rate of dye ingress and the physiological state of the cell. Whereas the accumulation of AO in AOP is compatible with cell viability, the appearance of CR is correlated with cell death. It is pointed out that meaningful interpretation of vital staining requires precise regulation of many parameters in the extracellular milieu. A scheme of cell compartmentalization with respect to AO is proposed to satisfactorily account for the effects of environmental variations on the distribution and ultimate fate of intracellular dye. The AOP are viewed as normally present acid phosphatase-positive multivesicular bodies.     

Acridine orange as an indicator of bacterial susceptibility to gentamicin

We have studied the response of Escherichia coli NCTC10418 to gentamicin with flow cytometry. The susceptibility of individual bacterial cells to the antibiotic was assessed by differential staining using the metachromatic dye, acridine orange. Exponential phase cultures were exposed to the minimum bactericidal concentration of gentamicin and analysed at regular intervals over 90 min. Within 60 min of exposure to the drug, two sub-populations of organisms could be distinguished in cultures by their different acridine orange-associated fluorescence emissions of <550 nm and >550 nm. The number of bacteria exhibiting acridine orange-associated fluorescence at >550 nm corresponded to counts of colony forming units.     

Fluorescence microscopy of viable mast cells stained with different concentrations of acridine orange.

Freshly harvested rat peritoneal mast cells were stained with different concentrations of acridine orange, a metachromatic fluorochrome known to form complexes with chromatin and muscopolysaccharides. Fluorescence metachromasia was observed in cytoplasmic granules in cell populations with intracelluar dye contents as low as 5 X 10(-16) mole per cell, one-half decade lower than required to produce metachromatic staining of the nucleus. Cytoplasmic granules did not stain uniformly throughout the cell; some granules exhibited red fluorescence and others green. As the amount of acridine orange uptake per cell was increased, cytoplasmic fluorescence became uniformly red and nuclear fluorescence gradually changed from green to yellow.     

Fluorescence microscopy of viable mast cells stained with different concentrations of acridine orange

Summary Freshly harvested rat peritoneal mast cells were stained with different concentrations of acridine orange, a metachromatic fluorochrome known to form complexes with chromatin and mucopolysaccharides. Fluorescence metachromasia was observed in cytoplasmic granules in cell populations with intracellular dye contents as low as 5×10^–16 mole per cell, one-half decade lower than required to produce metachromatic staining of the nucleus. Cytoplasmic granules did not stain uniformly throughout the cell; some granules exhibited red fluorescence and others green. As the amount of acridine orange uptake per cell was increased, cytoplasmic fluorescence became uniformly red and nuclear fluorescence gradually changed from green to yellow.     

Quantitative evaluation of the uptake capacity of intact thrombocytes using fluorescent dyes

A new approach to quantitative determination of fluorescent dye uptake by intact cells is suggested. Fluorescent amine acridine orange selectively accumulating in 5HT granules of platelets has been used. Fluorescence signal analysis allows the estimation of a relative granule volume and the ratios of acridine orange transfer over cytoplasmic and granule membranes. The following results were obtained in human and rabbit platelets: a relative granule size was 14 +/- 1 % and 29 +/- 2 % of the total cell volume, intra-granule to extra-granule dye concentration ratios were 2260 +/- 382 and 30000 +/- 5550, while intra-cytoplasm to extra-cytoplasm concentration ratios were 375 +/- 60 and 225 +/- 60, respectively.     

Thermodynamics of mucopolysaccharide–dye binding. II. Binding constant and cooperativity parameters of acridine orange–dermatan sulfate system

In the acridine orange–dermatan sulfate system, free and bound dye can be distinguished from each other spectroscopically. This permits the use of fluorometric methods to study the binding of acridine orange to the acid mucopolysaccharide dermatan sulfate. Experiments were conducted at 24°C in 10^?3 M citrate/phosphate buffer at pH = 7.0. The binding of the dye is highly cooperative, as evidenced by considerable interaction between adjacent bound dye molecules. Analysis of the data indicates that dermatan sulfate binds 2.3 ± 0.3 mol of acridine orange per dermatan sulfate uronic acid residue with a cooperative binding constant, K_q ranging from 4.9 to 6.0 × 10⁵ M^?1 which corresponds to a free energy of 7.74 ? ΔG° ? 7.86. The cooperativity parameter q apparently increases with increasing polymer-to-dye ratio.     

DEMONSTRATION OF ACID PHOSPHATASE-CONTAINING GRANULES AND CYTOPLASMIC BODIES IN THE EPITHELIUM OF FOETAL RAT DUODENUM DURING CERTAIN STAGES OF DIFFERENTIATION

Dense cytoplasmic bodies surrounded by one or two unit membranes and containing mitochondria, vesicles, ribosomes, rough and smooth surfaced endoplasmic reticulum, and lamellated membranes (myelin figures) have been observed in the differentiating mucosa of the duodenum of rat foetuses by electron microscopy. Generally, the cytoplasmic components in the bodies seem to be in varying stages of disintegration. The bodies are found in greatest number on the 17th and 18th day of gestation, i.e. at the onset of differentiation. At this period of development the epithelium is stratified, and the villus formation is initiated by invagination of the epithelium by buds of mesenchyme followed by a splitting of the epithelium along the sides of the invaginations. When the villi have formed, the stratified epithelium has changed to the simple columnar type and the dense bodies have largely disappeared. Simultaneously, the lumen has widened considerably. In a parallel study with the light microscope, frozen sections incubated for the demonstration of acid phosphatase activity revealed the reaction product to be localized in bodies of the same size and distribution as the dense bodies found by electron microscopy. Hence, it seems that the bodies are altered and enlarged lysosomes (cytolysomes) active during the intensive differentiative events in the small intestine during the last part of intra-uterine life.     

Induced circular dichroism of acridine orange bound to double-stranded RNA and transfer RNA

The induced circular dichroism (CD) in the visible region of acridine orange bound to the double-stranded RNA from cytoplasmic polyhedrosis virus and to yeast tRNA has been measured as a function of RNA phosphate-to-dye ratio (P/D), under the conditions of 0.01 M Na⁺ at pH 7.0. The shape of the CD spectrum of acridine orange bound to the double-stranded RNA was quite different from the spectrum of the dye bound to DNA. The CD spectral features of acridine orange bound to the double-stranded regions in tRNA closely resembled those of the double-stranded RNA-dye complex, suggesting that the dyes bind similarly to the two RNA's. It was further found that the CD spectrum of the tRNA-dye complex at sufficiently high P/D ratios, which is assignable to monomeric, intercalated dye to the base-paired parts in tRNA, is also distinct from the corresponding spectrum of the DNA-dye complex.     

FURTHER STUDIES ON THE INHIBITION OF CYPRIDINA LUMINESCENCE BY LIGHT,WITH SOME OBSERVATIONS ON METHYLENE BLUE

1. Eosin, erythrosin, rose bengale, cyanosin, acridine, and methylene blue act photodynamically on the luminescence of a Cypridina luciferin-luciferase solution. In presence of these dyes inhibition of luminescence, which without the dye occurs only in blue-violet light, takes place in green, yellow, orange, or red light, depending on the position of the absorption bands of the dye. 2. Inhibition of Cypridina luminescence without photosensitive dye in blue-violet light, or with photosensitive dye in longer wave-lengths, does not occur in absence of oxygen. Light acts by accelerating the oxidation of luciferin without luminescence. Eosin or methylene blue act by making longer wave-lengths effective, but there is no evidence that these dyes become reduced in the process. 3. The luciferin-oxyluciferin system is similar to the methylene white-methylene blue system in many ways but not exactly similar in respect to photochemical change. Oxidation of the dye is favored in acid solution, reduction in alkaline solution. However, oxidation of luciferin is favored in all pH ranges from 4 to 10 but is much more rapid in alkaline solution, either in light or darkness. There is no evidence that reduction of oxyluciferin is favored in alkaline solution. Clark''s observation that oxidation (blueing) of methylene white occurs in complete absence of oxygen has been confirmed for acid solutions. I observed no blueing in light in alkaline solution.     

ELECTRON MICROSCOPE HISTOCHEMICAL EVIDENCE FOR A PARTIAL OR TOTAL BLOCK OF THE TRICARBOXYLIC ACID CYCLE IN THE MITOCHONDRIA OF PRESYNAPTIC AXON TERMINALS

Respiration-linked, massive accumulation of Sr²⁺ is used to reveal the coupled oxidation of pyruvate, α-oxoglutarate, succinate, and malate by in situ mitochondria. All of these substrates were actively oxidized in the dendritic and perikaryal mitochondria, but no α-oxoglutarate or succinate utilization could be demonstrated in the mitochondria of the presynaptic axon terminals. A block at an early step of α-oxoglutarate and succinate oxidation is proposed to account for the negative histochemical results, since the positive reaction with pyruvate and malate proves that these mitochondria possess an intact respiratory chain and energy-coupling mechanism essential for Sr²⁺ accumulation. This indicates that the mitochondria in the axon terminals would be able to generate energy for synaptic function with at least some of the respiratory substrates. With regard to the block in the tricarboxylic acid cycle, the oxaloacetate necessary for citrate formation is suggested to be provided by fixation of CO₂ into some of the pyruvate.     

ELECTRON MICROSCOPE STUDIES ON ENZYME ACTIVITY AND THE ISOLATION OF THIOHYDANTOIN-INDUCED MYELIN FIGURES IN RAT LIVER

Characteristic cytoplasmic inclusions (myelin figures), consisting of concentric multilaminar paired membranes surrounding one or more lipid bodies, were produced in rat liver parenchymal cells by incorporating high doses of an anticonvulsant agent (Bax 422Z) into the animals' diet. Enzymatic reaction product (presumably lead phosphate) was found around the central fat of these myelin figures in liver which had been fixed in glutaraldehyde, incubated in Wachstein and Meisel's medium containing adenosine triphosphate or inosine tri- or diphosphate, postosmicated, embedded in epoxy resin, and examined in the electron microscope. In an attempt to isolate myelin figures, fresh liver from medicated rats was homogenized and differentially centrifuged. Thin sections of osmium tetroxide-fixed, Epon-embedded pellets from each fraction were examined with the electron microscope. The concentric membranous whorls, which are probably derived from cisternae of the endoplasmic reticulum, broke up as the cells were disrupted and became inextricably mixed with the microsomal fraction. However, when liver previously fixed in formalin for 24 hours was homogenized, the myelin figures remained intact.     

10N-nonyl acridine orange interacts with cardiolipin and allows the quantification of this phospholipid in isolated mitochondria.

The acridine orange derivative, 10N-nonyl acridine orange, is an appropriate marker of the inner mitochondrial membrane in whole cells. We use membrane model systems to demonstrate that 10N-nonyl acridine orange binds to negatively charged phospholipids (cardiolipin, phosphatidylinositol and phosphatidylserine). The stoichiometry has been found to be 2 mol 10N-nonyl acridine orange/mol cardiolipin and 1 mol dye/mol phosphatidylserine or phosphatidylinositol, while, with zwitterionic phospholipids, significant binding could not be detected. The affinity constants were 2 x 10(6) M-1 for cardiolipin-10N-nonyl-acridine-orange association and only 7 x 10(4) M-1 for that of phosphatidylserine and phosphatidylinositol association. The high affinity of the dye for cardiolipin may be explained by two essential interactions; firstly an electrostatic interaction between the quaternary ammonium of nonyl acridine orange and the ionized phosphate residues of cardiolipin and secondly, hydrophobic interactions between adjacent chromophores. A linear relationship was demonstrated between the cardiolipin content of model membranes and the incorporated dye. Consequently, a convenient and rapid method for cardiolipin quantification in membranes was established and applied to the cardiolipin-containing organelle, the mitochondrion.     

Zur Physikochemie der vitalen Kern- und Plasmafluorochromierung vonAllium cepa-Epidermen

Summary Microfluorimetrically recorded fluorescence bands of vitally stained nuclei and protoplasts from the inner epidermis of yellow onion(Allium cepa) scales are compared with fluorescence bands of Tarions model solutions. The strong fluorescent staining of the nucleus and the weaker hue of the cytoplasm after application of acridine orange is mainly due to the accumulation of monomeric dye cations in polar cytoplasmic lipids. Vital fluorescent staining with neutral red shows similar effects, but in addition an accumulation of the dye base in apolar lipids can be ascertained without doubt. On the other hand, the major accumulation of the acid fluorochrome uranin (sodium fluorescein) does not take place in polar cytoplasmic lipids but, apparently, rather in the form of anions in the water phase of the ground cytoplasm and inner nuclear plasm owing to a mechanism of plasmatic ion trap.The proof that dye ions are present in vitally stained protoplasm suggests the possibility, that the familiar phenomenon of vacuole contraction may depend on a Donnan effect in the case of basic dyes and might be a consequence of the raising of osmotic values by dye anions in the case of acid dyes.Experiments with three phases (dye solution-oil-blood plasma) yield fluorescent stainings of blood plasma with acridine orange, neutral red and uranin, which may be compared to vital staining of nuclei and cytoplasm. The well-known properties of blood plasma-lipids suggest a similar function of cytoplasmic lipids, viz. as a vehicle of lipid transport in a mainly aquatic, molecular-disperse phase. A diagram (Fig. 15) illustrates the cooperation between sheetlike lipoproteid complexes (boundary layers) and lipoproteid complexes of the ground cytoplasm dispersed as particles.     

CYTOPLASMIC DNA SYNTHESIS IN AMOEBA PROTEUS : I. On the Particulate Nature of the DNA-Containing Elements

The incorporation of tritiated thymidine in Amoeba proteus was reinvestigated in order to see if it could be associated with microscopically detectable structures. Staining experiments with basic dyes, including the fluorochrome acridine orange, revealed the presence of large numbers of 0.3 to 0.5 µ particles in the cytoplasm of all cells studied. The effect of nuclease digestion on the dye affinity of the particles suggests that they contain DNA as well as RNA. Centrifugation of living cells at 10,000 g leads to the sedimentation of the particles in the centrifugal third of the ameba near the nucleus. Analysis of centrifuged cells which had been incubated with H₃-thymidine showed a very high degree of correlation between the location of the nucleic acid-containing granules and that of acid-insoluble, deoxyribonuclease-sensitive labeled molecules and leads to the conclusion that cytoplasmic DNA synthesis in Amoeba proteus occurs in association with these particles.     

Improvement of metabolic competence of isolated nerve terminals by extracellular pyruvate

Neuronal activity is tightly coupled with brain energy metabolism. Numerous studies have proved that glucose is not a sole energy substrate for neurons; metabolic monocarboxylate intermediates derived from glucose (pyruvate and lactate) released by astrocytes are shown to be taken up and oxidized by neurons, and, moreover, could serve as neuroprotective agents. Herein, we presented the data that extracellular pyruvate (4 mM) in the presence of glucose caused the increase in synaptosomal ATP content from 3.48+/-0.30 to 4.38+/-0.23 nmol/mg of protein. This correlates with the enhanced accumulation of fluorescent dye acridine orange in the available and the recycling synaptic vesicles within the synaptosomes reflecting the improved generation of proton gradient through the synaptic vesicle membrane. We have also demonstrated the effect of extracellular pyruvate on distribution of [3H]GABA between synaptic vesicles and cytoplasm in loaded synaptosomes. To estimate [3H]GABA accumulation into the synaptic vesicles, Ca 2+-dependent 4-aminopyridine-triggered exocytotic neurotransmitter release was studied. Evaluation of cytosolic 1H]GABA pool was performed by measuring the Ca2+-independent transporter-mediated neurotransmitter release evoked by nipecotic acid or high K+. The presence of pyruvate resulted in doubled exocytotic release of [3H]GABA, and significantly attenuated Ca2+-independent release of cytosolic [3H]GABA. Together, these observations provide insight into the important role of glucose metabolic intermediate, pyruvate, in sustaining activity of vesicular inhibitory amino acid transporter and so normal inhibitory transmission. We propose to use pyruvate for keeping up synaptosomal preparations in state of metabolic stability.     

Decreased endo-lysosomal acidification capacity in methylene diphosphonate-resistant mutants of Dictyostelium discoideum

Abstract The in vivo capacity for endo-lysosomal acidification has been monitored in Dictyostelium discoideum amoebae with acridine orange, a fluorescent weak base dye commonly used to probe transmembrane pH gradients. In the presence of aerobic amoebae, the initial rate of fluorescence quenching was found to be proportional to cell density between 5 × 10⁵ and 2.5 × 10⁶ cells ml⁻¹ and independent of acridine orange concentration in the 1.5 to 7.5 μM range. The dye response was sensitive to agents that perturb endo-lysosomal acidification such as NaN₃, nigericin or imidazole. Several mutant cell lines whose growth was resistant to methylene diphosphonate were found to be partially deficient in the acridine orange quenching test, suggesting that endo-lysosomal acidification was altered in these mutants.     

Absorption and Fluorescence Spectra of Euchrysine Ggnx and Acridine Orange; Effects of Heparin, NaCl and a Cation Exchange Resin

The absorption and fluorescence spectra of two samples of dye labeled euchrysine were found to differ. One sample, labeled GGNX, had absorption and fluorescence maxima of 435 and 515 nanometers (nm) respectively. The other sample was not further labeled, but had absorption and fluorescence maxima of 492 and 535 nm. The latter values, as well as the shape of both the fluorescence and absorption curves of the second sample were superimposable on a recrystallized sample of acridine orange labeled correctly C. I. 46905. Euchrysine has two free amino groups which are fully methylated in acridine orange, therefore a nitrous acid test can differentiate the two dyes. The sample of euchrysine labeled GGNX gave a reaction, as did acridine yellow, C. I. 46025, but acridine orange, C. I. 46005, did not. Fluorescence metachromasy of euchrysine is less efficient than that of acridine orange in two ways: the shift in the spectrum is smaller by about 40 nm, making the separation of the colors more difficult both visually and by instruments and the metachromatic fluorescence has less than half of the intensity of acridine orange as measured at the peak for each dye. Confusion between these two dyes has occurred because suppliers have used the names interchangeably. For critical studies, the dye used should be identified by its Colour Index number.     

The interaction of glycolysis, gluconeogenesis and the tricarboxylic acid cycle in rat liver in vivo

1. The equations derived by Heath (1968) were applied to data from experiments on rats in four metabolic states: fed, post-absorptive, starved and 2hr. after an eventually lethal injury. The data used were: (a) The fractions of label injected as C1-, C2- and C3-pyruvate (where the prefix indicates the position of labelling) that are incorporated into carbon dioxide and glucose in post-absorptive and injured rats (yields). Yields could be corrected to yields on label taken up by the liver. (b) The (C5-label in glutamate)/(total label in glutamate) ratio in the liver after C2-pyruvate in rats in all four states. (c) The distribution of label within glutamate after C2-pyruvate or C2-alanine in the livers of fed, post-absorptive and starved rats. (d) The distribution of label within glucose after C2-lactate or C2-pyruvate in starved rats. (e) The relative specific radioactivities of pyruvate, aspartate, glutamate and (in two states only) of glucose 6-phosphate after injection of [U-(14)C]glucose into rats in all four states. These data were previously published, except those after (e) and some after (b) above, which are given in this paper. 2. In addition the concentrations of pyruvate, citrate, glutamate and aspartate in the livers of post-absorptive and injured rats were found. Injury decreased glutamate and citrate concentrations and to a smaller extent aspartate and pyruvate concentrations. 3. Non-steady-state theory showed that most of the data could be used without serious error in steady-state theory. Steady-state theory correlated all but one observation (the relative yields of (14)CO(2) from C2- and C3-pyruvate) listed after (a)-(e) above within the experimental errors, and gave rough estimates of the rates of pyruvate carboxylation, conversion of pyruvate and fat into acetyl-CoA and utilization of glutamate. The main conclusions were: (a) symmetrization of label in oxaloacetate both in the mitochondrion and in the cytoplasm was far from complete, because oxaloacetate did not equilibrate with fumarate in either. From this and other findings it was deduced: (b) that malate or fumarate or both left the mitochondrion, and not oxaloacetate; (c) that there was a loss from the mitochondrion of a fraction of the malate or fumarate or both formed from succinate, and (d) the resulting deficiency of oxaloacetate for the perpetuation of the tricarboxylic acid cycle was made up from pyruvate in fed and post-absorptive rats, but (e) in the starved rat could only be made up by utilization of glutamate. (f) In the fed rat the tricarboxylic acid cycle ran mostly on pyruvate, but in the post-absorptive and starved rat mostly on fat. (g) In the injured rat the tricarboxylic acid cycle was slowed, label in oxaloacetate was completely symmetrized (cf. conclusion a), and the tricarboxylic acid cycle utilized glutamate. (h) The conclusions were not invalidated by isotopic exchange, i.e. flux of label without net flux of compound, nor by interaction with lipogenic processes. (i) In the kidneys interaction between the tricarboxylic acid cycle and gluconeogenesis was different from in the liver, and was much less. The effects on the theory were roughly assessed, and were small. 4. The experiments and optimum experimental conditions required to check the theory are listed, and several predictions, open to experimental confirmation, are made.     

LOCALIZATION OF ACID PHOSPHATASE IN LIPOFUSCIN GRANULES AND POSSIBLE AUTOPHAGIC VACUOLES IN INTERSTITIAL CELLS OF THE GUINEA PIG TESTIS

The intracellular localization of acid phosphatase in guinea pig testicular interstitial cells was investigated by incubating nonfrozen thick sections of glutaraldehyde-perfused testis in a modified Gomori medium and preparing the tissue for electron microscopy. Lipofuscin pigment granules in these cells contain dense pigment, granular matrix, and often a lipid droplet. Reaction product is seen in the matrix of the pigment granules, and they may therefore be called residual bodies. At least some of the dense pigment appears to be derived from myelin figures and membrane whorls, since suitable intermediates can be seen. Lipid droplets found free in the cytoplasm are another possible source of pigment. In both cases the chemical mechanism is presumed to be autoxidation of unsaturated lipid. Acid phosphatase is present in the inner cisterna of Golgi elements. Enzyme activity also appears in possible autophagic vacuoles bounded by double membranes; the reaction product lies between the membranes. Consideration of the enzyme as a tracer suggests that the autophagic vacuoles are derived from the Golgi complex. Possible stages in the formation of these vacuoles by the inner Golgi cisternae are observed.