Heterogeneity of rat liver mitochondrial fractions and the effect of tri-iodothyronine on their protein turnover

1. Rat liver mitochondria were separated into heavy, light and fluffy fractions by differential centrifugation under standard conditions. 2. All mitochondrial fractions possessed soluble as well as membrane-bound enzymes typical of mitochondria. 3. The heavy fraction represented the stable mitochondrial structures and the fluffy particles appear to be loosely coupled. 4. The light mitochondrial fraction lacked the ability of coupled phosphorylation. 5. A study of mobility and isoelectric pH indicated a similarity in the basic membrane structure of all the mitochondrial fractions. 6. The turnover rates of proteins in the heavy and fluffy particles were almost identical; however, this rate was rapid for the light mitochondrial fraction. 7. On treatment with 3,3',5-tri-iodo-l-thyronine, succinoxidase activity was maximally stimulated much earlier in the light mitochondrial fraction than in the heavy fraction. The activity of the fluffy particles, however, remained almost unaffected. 8. Malate dehydrogenase activity in all the mitochondrial fractions was stimulated only at 40h after tri-iodothyronine treatment. 9. The pattern of incorporation of dl-[1-(14)C]leucine in vivo in the tri-iodothyronine-treated animals indicated a rapid initial incorporation and high synthetic ability of the light mitochondrial fraction. 10. The turnover pattern of proteins of the mitochondrial fractions from animals receiving repeated doses of tri-iodothyronine was remarkably different from the normal pattern and suggested that preformed soluble protein units may be incorporated in the light mitochondrial fraction during maturation to form the stable heavy mitochondria. 11. The amount of light-mitochondrial proteins decreased by 40% on thyroidectomy and increased by 160% on treatment with tri-iodothyronine. 12. The possible significance of these results is discussed in relation to mitochondrial genesis.     

Observations on iron uptake, iron metabolism, cytochrome c content, cytochrome a content and cytochrome c-oxidase activity in regenerating rat liver

1. Differential and density-gradient centrifugation were used to fractionate mitochondria and fluffy layer from normal and regenerating rat liver. The iron, cytochrome a and cytochrome c contents and cytochrome c-oxidase activity were studied as well as the uptake of (59)Fe into protein and cytochrome c. 2. A certain degree of heterogeneity was evident between the heavy-mitochondrial and light-mitochondrial fractions, and in their behaviour during liver regeneration. 3. The specific content of light-mitochondrial iron and cytochrome a was 1.3-1.4 times that of heavy mitochondria. Changes in cytochrome c-oxidase activity closely followed those of cytochrome a content during liver regeneration, but not for light mitochondria after 10 days. 4. Radioactive iron ((59)Fe) was most actively taken up by well-washed light mitochondria during early liver regeneration. After 22 days fluffy layer became preferentially labelled. This substantiates the view that fluffy layer partially represents broken-down mitochondria. 5. During early regeneration, light-mitochondrial fractions separated along a density gradient were about 3 times as radioactive, and showed distinct heterogeneity of (59)Fe-labelling, in contrast with near homogeneity for heavy mitochondria. 6. Immediately after partial hepatectomy fractions corresponding to density 1.155 were 5-10 times as radioactive as particles of greater density. The radioactivity decreased sharply after 6 days. 7. These particles of low density possessed higher NADH-cytochrome c-reductase (1.5-5-fold) and succinate-dehydrogenase (1.1-2-fold) activities than typical mitochondrial fractions. Their succinate-cytochrome c-reductase and cytochrome c-oxidase activities were slightly lower. 8. The results are discussed in relation to mitochondrial morphogenesis, and a possible route from submitochondrial particles is suggested.     

Biochemical heterogeneity of mitochondria]

Rat liver mitochondria were fractionated on the basis of their sedimentation coefficients in the gradient of ficoll. The fractions ("heavy", "middle" and "light" mitochondria) were heterogeneous with regard to the content of protein, DNA, cytochrome a + a3 and respiratory activity. Heterogeneity of mitochondria did not result from the damage or microsomal and lysosomal contamination. The biosynthesis of DNA, RNA and proteins in the different fractions of mitochondria was studied. In vivo incorporation of radioactive precursor into RNA was highest in the fractions of "middle" mitochondria, whereas in vitro the "heavy" mitochondria showed maximum activity in the synthesis of RNA. In vitro DNA synthes was maximum in the fractions of "heavy" mitochondria, protein synthesis in "heavy" and "light" mitochondria. Activity of the synthesis of RNA, DNA and proteins in vitro depends on the content of DNA and cytochrome a + a3 in the different fractions of mitochondria. It is supposed that heterogeneity of mitochondria may be connected with their biogenesis.     

Mitochondrial biogenesis during germination in maize embryos

Mitochondrial biogenesis and metabolism were investigated during maize (Zea mays) seed germination. Mitochondria from dry and imbibed seed exhibited NADH-dependent O(2) uptake that was completely inhibited by KCN and antimycin A. Mitochondria in the dry seed had a lower rate of succinate-dependent O(2) uptake relative to that measured in imbibed and germinated seed. The activities of the tricarboxylic acid (TCA) cycle enzymes, pyruvate dehydrogenase complex, 2-oxoglutarate dehydrogenase complex, NAD-malic enzyme, and citrate synthase, are similarly low in mitochondria from dry seed and this correlates with a lower relative abundance of the mitochondrial matrix-located citrate synthase and pyruvate dehydrogenase complex E1alpha-subunit polypeptides. Electron microscopy revealed that mitochondria in the dry seed have a poorly developed internal membrane structure with few cristae; following 24 h of germination the mitochondria developed a more normal structure with more developed cristae. The mitochondria from maize embryos could be fractionated into two subpopulations by Suc density gradient centrifugation: one subpopulation of buoyant density equivalent to 22% to 28% (w/w) Suc; the other equivalent to 37% to 42% (w/w) Suc. These two subpopulations had different activities of specific mitochondrial enzymes and contained different amounts of specific mitochondrial proteins as revealed by western-blot analysis. Both subpopulations from the dry embryo were comprised of poorly developed mitochondria. However, during imbibition mitochondria in the heavy fraction (37%-42% [w/w] Suc) progressively acquired characteristics of fully functional mitochondria found in the germinated seedling in terms of structure, enzymic activity, and protein complement. In contrast, mitochondria in the light fraction (22% to 28% [w/w] Suc) show no significant structural change during imbibition and the amounts of specific mitochondrial proteins decreased significantly during germination.     

DNA strand specificity of temporal RNA classes produced during infection of Bacillus subtilis by SP82.

The DNA of the Bacillus subtilis bacteriophage SP82 has been separated into heavy (H) and light (L) fractions by centrifugation in buoyant density gradients in the presence of polyguanylic acid. Competition-hybridization experiments were performed with these separated fractions using RNAs isolated from cells labeled at intervals which account for 80% of the lytic cycle and unlabeled competitor RNAs isolated from phage-infected cells at 2-min intervals throughout infection. The analysis of temporal RNA classes were facilitated by use of a double reciprocal plot of the data. Five temporal classes binding to the H fraction and three binding to the L fraction were detected; the possible existence of an additional class transcribed from the H fraction is discussed. RNA synthesized in the presence of chloramphenicol contains two of the three classes produced from L-DNA and two of the five classes transcribed from H-DNA.     

Further characterization of rat liver mitochondrial fractions. Lipid composition and synthesis, and protein profiles.

1. Heavy and light mitochondrial fractions obtained by differential centrifugation were further characterized with respect to their lipid composition and synthesis and protein profiles, as seen by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. 2. The light mitochondrial fraction was rich in total lipids, phospholipids and cholesterol. The cardiolipin content, however, was low. 3. Rates of [3H]glycerol incorporation into phospholipids of heavy mitochondria and microsomal fractions were almost identical. On the other hand, incorporation into the individual phospholipids in light mitochondria was about 4-6 times higher. Incorporation into cardiolipin of light mitochondria was about 10-fold higher than in the heavy mitochondria. 4. Analysis of protein profiles by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis showed that the pattern obtained for the light mitochondria was similar to that for heavy mitochondria. However, the light fraction was relatively poor in high-molecular-weight proteins and rich in low-molecular-weight proteins. The microsomal protein profile was altogether different. 5. The significance of these findings is discussed in relation to mitochondrial biogenesis.     

Biogenesis of Mitochondria in Imbibed Peanut Cotyledons : II. DEVELOPMENT OF LIGHT AND HEAVY MITOCHONDRIA

There are two types of mitochondria present in imbibed peanut cotyledons: a light type (density 1.182 grams per cubic centimeter) and a heavy type (density 1.205 grams per cubic centimeter). The membrane fractions from these two types can be distinguished using sucrose density gradient analysis, and differences in membrane density between the light and heavy types are reflected in differences in their protein N and phospholipid P composition. With increasing time after imbibition, there is a substantial increase in the amount and activity of the light type of mitochondria due to their de novo synthesis. The membrane density of the light mitochondrial fraction declines over 5 days after the start of imbibition as the phospholipid P to protein N ratio increases. The heavy mitochondrial fraction declines during the first 3 days after the start of imbibition, and then it remains at a low, but constant, level thereafter. Even during the decline, however, there is synthesis of proteins comparable to that into light mitochondria. The mitochondrial biogenesis that has been observed in peanut cotyledons is of the light type, the function and physiological importance of the minor heavy type is not known.     

Biochemical studies on sub-fractions of rat liver mitochondria

Highly purified mitochondria from rat liver were separated into six sub-fractions by differential centrifugation. The sub-fractions represent a spectrum from “heavy” to “very light” mitochondria. Enzymes representative of mitochondrial compartments were assayed to see whether functional differences occurred among the various mitochondrial sub-fractions. Respiratory control and NADH oxidase activity, both of which are indicators of mitochondrial structural integrity, were also measured. An enzyme marker for endoplasmic reticulum (glucose-6-phosphatase, G-6-Pase) was also assayed. Specific activities for monoamine oxidase (outer membrane marker), cytochrome oxidase (inner membrane marker) and malate-cytochrome c reductase did not vary within experimental error in all sub-fractions; similarly, for respiratory control and NADH oxidase activity. Malate dehydrogenase, a component of malate-cytochrome c reductase is located within the matrix surrounded by the inner membrane. Specific activity of adenylate kinase (located between the outer and inner membrane) decreased markedly from the “heavy” mitochondria to the “very light” fractions. Specific activity for G-6-Pase, very low in the “heavy” fractions, increased markedly in the “light” to “very light” fractions. Isopycnic density centrifugation on a linear sucrose density gradient of each of the fractions indicated that the correlation coefficient for the sucrose concentrations at which cytochrome oxidase and G-6-Pase activities peaked was 0.995. Thus the “light” to “very light” mitochondria may represent mitochondria whose outer membrane is still contiguous with the endoplasmic reticulum. Microsomes containing the endoplasmic reticulum peaked on the gradient at a significantly lower sucrose concentration than any of the mitochondrial sub-fractions. A buoyant effect of endoplasmic reticulum still attached to any of the mitochondrial sub-fractions would be expected to lower the density of attached mitochondria and thus give rise to “light” and “very light” mitochondria.     

The ribosomal cistrons of the water mold Achlya bisexualis

Total DNA was extracted from vegatative mycelia of the water mold Achlya bisexualis. Fractionation of the DNA in CsCl gradients resulted in two components: a major component with a buoyant density of 1.697 g cm^?3 and a minor component with a density of 1.685 g cm^?3. The minor component has been identified as mitochondrial DNA based on extractions from isolated mitochondria and Triton X-100 washed nuclei. Detergent washing of the nuclei yielded DNA in which the mitochondrial DNA component was absent, while the isolated mitochondrial preparations contained DNA enriched in the 1.685 g cm^?3 component. Hybridization studies of A. bisexualis DNA to rRNA show that the ribosomal cistrons have a buoyant density coincident with that obtained with the nuclear DNA. In addition, preliminary evidence indicates that the mitochondrial DNA does not hybridize to the cytoplasmic RNA under the conditions used for this study. Ribosomal RNA hybridized to about 0.65% of the total DNA.     

Some features of mitochondria and fluffy layer in regenerating rat liver

1. Mitochondria and fluffy layer were prepared from control and regenerating rat liver. Differential and density-gradient centrifugation were used to fractionate the preparations, which were examined for protein content, density and the activity of cytochrome c oxidase, succinate dehydrogenase, NAD–isocitrate dehydrogenase and NADP–isocitrate dehydrogenase. 2. During regeneration the mitochondrial protein content of the liver fell by 18% from the control value of 18·4mg. of protein/g. of liver (wet wt.) and by 3 weeks had risen to 130% of the control value. It then declined slowly. 3. The fluffy-layer protein content (4·7mg./g. of liver) varied inversely as the mitochondrial content and increased by 70% in the early stages (10 days) of liver regeneration. The results suggest that fluffy layer may partially represent both partly formed and broken-down mitochondria. 4. NAD– and NADP–isocitrate dehydrogenases differed in their behaviour during liver regeneration. 5. The succinate-dehydrogenase and NADP–isocitrate-dehydrogenase activity of fluffy layer was high and rose during the early stages of liver regeneration (1 week). Succinate dehydrogenase and cytochrome c oxidase were concentrated in the lighter fluffy-layer particles 10 days to 3 weeks after partial hepatectomy. The significance of this with respect to mitochondrial formation is discussed. 6. Mitochondrial fractions possessed a certain degree of heterogeneity in enzymic activity when separated according to size and density. The mean density of heavy mitochondria was 1·198, light mitochondria 1·193. Fluffy layer was nearly homogeneous in control liver, but during regeneration considerable heterogeneity became evident. The significance of the heterogeneity is discussed.     

Polyribosomes and messenger RNA from RAT liver mitochondria

Summary Rat liver mitochondrial polyribosomes were isolated free from cytoplasmic ribonucleoprotein contaminations in a number of criteria (sedimentation and buoyant density patterns, ribosomal RNA composition). Heterogeneous poly A containing RNA from mitochondrial polysomes was purified by two-stage cellulose chromatography. This RNA was in vitro labelled with¹²⁵I up to specific activity ~10⁶–10⁷ cts.min^–1.µg ^–1 and used for hybridization experiments with separate complementary strands of mitochondrial DNA and nuclear DNA fragments. The proportions of mitochondrial poly A containing RNA that is complementary to heavy and light strands of mtDNA were respectively 31.5% and 8.3%. Besides, a significant RNA fraction was complementary to unique sequences of nuclear DNA (2–3 copies per haploid genome). The hybrids that were formed possessed a high T_m indicative of a perfect base pairing. A dual intracellular origin of mitochondrial messenger RNA is discussed.     

Functional activity and ultrastructure of mitochondria isolated from myocardial apoptotic tissue

Apoptosis in myocardial tissue slices was induced by extended incubation under anoxic conditions. Mitochondria were isolated from the studied tissue. A new method of isolation of mitochondria in special conditions by differential centrifugation at 1700, 10,000, and 17,000g resulted in three fractions of mitochondria. According to the data of electron microscopy the heavy mitochondrial fraction (1700g) consisted of mitochondrial clusters only, the middle mitochondrial fraction (10,000g) consisted of mitochondria with typical for isolated mitochondria ultrastructure, and the light fraction consisted of small mitochondria (2 or 3 cristae) of various preservation. The heavy fraction contained unusual structural elements that we detected earlier in apoptotic myocardial tissue—small electron-dense mitochondria incorporated in bigger mitochondria. The structure of small mitochondria from the light fraction corresponded to that of the small mitochondria from these unusual elements—mitochondrion in mitochondrion. The most important functions of isolated mitochondria are strongly inhibited when apoptosis is induced in our model. The detailed study of the activities of the two fractions of the apoptotic mitochondria showed that the system of malate oxidation is completely altered, the activity of cytochrome c as electron carrier is partly inhibited, while succinate oxidase activity is completely preserved (complexes II, III, and IV of the respiration chain). Succinate oxidase activity was accompanied by high permeability of the internal membrane for protons: the addition of uncoupler did not stimulate respiration. ATP synthesis in mitochondria was inhibited. We demonstrated that in our model of apoptosis cytochrome c remains in the intermembrane space, and, consequently, is not involved in the cascade of activation of effector caspases. The possible mechanisms of induction of apoptosis during anoxia are discussed.     

Preparation and properties of mitochondria derived from synaptosomes.

A method has been developed whereby a fraction of rat brain mitochondria (synaptic mitochondria) was isolated from synaptosomes. This brain mitochondrial fraction was compared with the fraction of "free" brain mitochondria (non-synaptic) isolated by the method of Clark & Nicklas (1970). (J. Biol. Chem. 245, 4724-4731). Both mitochondrial fractions are shown to be relatively pure, metabolically active and well coupled. 2. The oxidation of a number of substrates by synaptic and non-synaptic mitochondria was studied and compared. Of the substrates studied, pyruvate plus malate was oxidized most rapidly by both mitochondrial populations. However, the non-synaptic mitochondria oxidized glutamate plus malate almost twice as rapidly as the synaptic mitochondria. 3. The activities of certain tricarboxylic acid-cycle and related enzymes in synaptic and non-synaptic mitochondria were determined. Citrate synthase (EC 4.1.3.7), isocitrate dehydrogenase (EC 1.1.1.41) and malate dehydrogenase (EC 1.1.1.37) activities were similar in both fractions, but pyruvate dehydrogenase (EC 1.2.4.1) activity in non-synaptic mitochondria was higher than in synaptic mitochondria and glutamate dehydrogenase (EC 1.4.1.3) activity in non-synaptic mitochondria was lower than that in synaptic mitochondria. 4. Comparison of synaptic and non-synaptic mitochondria by rate-zonal separation confirmed the distinct identity of the two mitochondrial populations. The non-synaptic mitochondria had higher buoyant density and evidence was obtained to suggest that the synaptic mitochondria might be heterogeneous. 5. The results are also discussed in the light of the suggested connection between the heterogeneity of brain mitochondria and metabolic compartmentation.     

Mitochondrial thymidine kinase and ribonucleotide reductase from rat liver and rat hepatoma 27]

Fractions of heavy and light mitochondria are isolated from homogenates of homologous rat tissues (intact liver, regenerating liver within 24 hours after hepatectomy and 27 hepatoma) by means of differential centrifugation. It is found that tumour mitochondria have higher heterogeneity and lower buyoant density than mitochondria from normal hepatocytes. The activity of two enzymes of DNA precursors synthesis (ribonucleotide reductase and thymidine kinase) in subcellular fractions is demonstrated to correlate with the tissue growth rate. A single injection of cyclic AMP into hepatectomised rats resulted in the retardation of the regeneration process, and the activity of both enzymes reached its normal level in all the fractions studied after 24 hours after the operation. Thymidine kinase and ribonucleotide reductase are located mainly in the mitochondrial matrix, however, pronounced enzyme activity is observed also in membrane fractions. The activity of the enzymes in the fraction of external mitochondria membranes in rapidly growing tissues is 2--3 times as high as in the same fraction from normal rat liver.     

Replication of bromodeoxyuridylate-substituted mitochondrial DNA in yeast.

The DNA of several strains of Saccharomyces cerevisiae was labeled by growing the culture in medium supplemented with thymidylate and bromodeoxyuridylate. It was thus possible to follow the course of mitochondrial DNA replication in density shift experiments by determining the buoyant density distribution of unreplicated and replicated DNAs in analytical CsCl gradients. DNA replication was followed for three generations after transfer of cultures from light medium to heavy medium and heavy medium to light medium. Under both conditions, the density shifts observed for mitochondrial DNA were those expected for semiconservative, nondispersive replication. This was further confirmed by analysis of the buoyant density of alkali-denatured hybrid mitochondrial DNA. With this method, no significant recombination between replicated and unreplicated DNA was detected after three generations of growth.     

Ram sperm mitochondrial DNA

Circular DNA was isolated from mitochondrial fractions of ram spermatozoa by SDS treatment followed by convex sucrose gradient centrifugation. The DNA had a contour length of 5.0 micron. Its buoyant density was 1.6983 g cm-3, which was smaller than two nuclear DNA components with buoyant densities of 1.6999 and 1.7156 g cm-3, found in ram spermatozoa. The Tm of the mitochondrial DNA was 69.7 degrees C. The mole fraction G+C calculated from the buoyant density and melting temperature was 39.1% and 38.6%, respectively.     

Purification and general properties of the DNA-binding protein (P16) from rat liver mitochondria

The mitochondrial DNA-binding protein P16 was isolated from rat liver mitochondrial lysates by affinity chromatography on single strand DNA agarose and separated from DNA in the preparation by alkaline CsCl isopycnic gradients. The top fraction of the gradients contained a single polypeptide species (Mr approximately equal to 15,200) based upon SDS PAGE. Digestion of single strand DNA-bound P16 with proteinase K produced a protease-insensitive, DNA-binding fragment (Mr approximately equal to 6,000) that has been purified by essentially the same procedures used for intact P16. The partial amino acid compositions for P16 and the DNA-binding fragment were obtained by conventional methods. Analysis of subcellular fractions revealed that nearly all of the cellular P16 was located in the mitochondria and that only trace amounts of protein of comparable electrophoretic mobility could be isolated from the nuclear or cytoplasmic fractions. The labeling of P16 with [35S]methionine in primary rat hepatocyte cultures was inhibited by more than 90% by the cytoplasmic translation inhibitor cycloheximide, but unaffected by the mitochondrial-specific agent chloramphenicol. These results indicate that P16 is synthesized on cytoplasmic ribosomes and imported into the mitochondria. The addition of purified P16 to deproteinized mitochondrial DNA resulted in the complete protection of the labeled nascent strands of displacement loops against branch migrational loss during cleavage of parental DNA with SstI, thus providing strong evidence that P16 is the single entity required for this in vitro function. Incubation of P16 with single strand phi X174 DNA, double strand (RF) phi X174 DNA, or Escherichia coli ribosomal RNA and subsequent analysis of the nucleic acid species for bound protein indicated a strong preference of P16 for single strand DNA and no detectable affinity for RNA or double strand DNA. Examination of P16-single strand phi X174 DNA complexes by direct electron microscopy revealed thickened, irregular fibers characteristic of protein-associated single strand DNA.     

Two membrane sites for DNA synthesis in Pneumococcus.

Summary A DNA membrane fraction extracted from pneumococci can be separated into two subfractions with respect to macromolecular composition and DNA synthesis by centrifugation in a 30–60% w/v neutral sucrose gradient. Each fraction can be rebanded in a sucrose gradient or centrifuged to equilibrium in a CsCl density gradient without altering the ability of the fractions to synthesize DNA. The fast sedimenting (heavy) fraction contains 45% of the DNA, and the bulk of the phospholipid, protein, and RNA. The light fraction contains 50% of the DNA, and lower, but significant amounts of phospholipid, RNA, and protein. Both fractions contain a DNA replication complex consisting of a number of enzymes involved in synthesizing DNA or DNA precursors, as well as RNA polymerase activity. However, the specific activity of DNA polymerase in the light fraction is much greater than that in the heavy fraction. In addition, the following results suggest that the former is concerned primarily with replication of the genome while the latter has characteristics of a repair function for the genome. (1) newly synthesized DNA can be detected within 30 s in the light fraction but not until 4 min in the heavy fraction. (2) an RNA-DNA single-stranded hybrid can be demonstrated during initial stages of DNA synthesis in the light, but not heavy fraction. (3) extensive semiconservative DNA replication occurs in the light fraction, whereas little such replication is detected in the heavy fraction. (4) DNA polymerase activity in the light fraction has several of the characteristics of a polymerase identified by others as being concerned with normal DNA replication, such as inhibition by N-ethylmaleimide, and relatively high rates of chain elongation (4.9×10⁴ nucleotides/min). In contrast, DNA polymerase activity in the heavy fraction has characteristic properties associated with DNA polymerase I, a possible repair enzyme. These include higher activity for a d(A-T)n template than that detected in the light fraction, no effect of N-ethylmaleimide, and relatively low rates of chain elongation (9×10³ nucleotides/min).     

Isolation of pancreatic autophagic vacuoles induced by vinblastine or neutral red. Separation of autophagosomes and autolysosomes by Percoll density gradient centrifugation

Our purpose was to elaborate a cell fractionation method for the preparation and purification of macroautophagic vacuoles (AVs) and their subfractions: autophagosomes and autolysosomes. To overcome the difficulties caused in liver and some other cell types by the overlapping buoyant densities and sizes of different subclasses of lysosomes and other subcellular particles, we chose the murine pancreatic acinar cell as experimental system in which enormous numbers of large-sized AVs are readily accumulated upon certain treatments. As we measured by electron microscopic morphometry, cytoplasmic volume fraction of AVs was as small as 0.31% in the untreated cells, while it was elevated to 8.1% 4 h after the injection of 50 mg/kg body weight vinblastine sulfate (a widely used inducer of macroautophagy). From vinblastine-treated pancreas, a 5500g sediment containing AVs and mitochondria (AV-M fraction) was obtained by differential centrifugation. This fraction was resolved in a 50% Percoll gradient (15 min, 92,000g) into three distinct particle populations. Mitochondria were localized near the upper boundary of the gradient at a buoyant density of 1.075 to 1.08, whereas directly under them light AVs (1.085-1.09) were banded. Heavy AVs (1.13-1.14) formed a broad layer near the bottom of the tube. Electron microscopic comparison of the morphology of these fractions and AVs in situ showed that light AVs correspond to AVs in early, whereas heavy AVs to AVs in advanced and late stages of degradation of the segregated material. The activity of lysosomal enzymes were found low in both fractions, being several times higher in the heavy than in the light one.(ABSTRACT TRUNCATED AT 250 WORDS)