Behaviour of rat-liver mitochondria during centrifugation in a sucrose gradient

Association of monoamine oxidase and malate dehydrogenase with liver peroxisomes of genetically obese (ob/ob and db/db) mice

1. Liver post-nuclear supernatants (PNS) from genetically obese (ob/ob and db/db), lean (+/?), and albino mice were fractionated by dual centrifugation in B-XIV zonal rotors and subcellular fractions were analysed by marker-enzyme estimations and by electron microscopy. 2. Rate-dependent banding of PNS yielded a peroxisome-enriched region (PER) well-separated from mitochondria. 3. Density-dependent banding of PER in ob/ob and db/db mice only, yielded purified peroxisomes which were associated with malate dehydrogenase (cytosolic) and monoamine oxidase. 4. Markers for the mitochondrial matrix, intermembrane space and inner membrane compartments were absent from the peroxisomes. 5. The experimental results are interpreted as indicating that peroxisomes of genetically obese mice are either altered so that protein import is imprecise or so that their attachment to mitochondria is more extensive.

Temperature, pressure and cholesterol effects on bilayer fluidity; a comparison of pyrene excimer/monomer ratios with the steady-state fluorescence polarization of diphenylhexatriene in liposomes and microsomes

Pyrene excimer/monomer (E/M) ratios have been compared with the steady-state fluorescence polarization (P) of diphenylhexatriene (DPH) in multilamellar liposomes of dilaurylphosphatidylcholine and rat liver microsomes. The purpose was to use the well-understood properties of DPH to reveal the nature of bilayer fluidity which pyrene manifests as an E/M ratio. Reducing the temperature (from 37 degrees C to 8 degrees C), increasing the hydrostatic pressure (from 0.1 to 70 MPa), and, in liposomes, cholesterol enrichment (up to 0.30 mole fraction) separately decreased the E/M ratios and increased P. The pyrene membrane/buffer partition coefficient was affected by temperature but not by pressure, and in the case of cholesterol enrichment, it was assumed to be unaffected. Plots of P as a function of the E/M ratio showed the two to be closely correlated (r = 0.99 in liposomes and 0.96 in microsomes), independent of the treatment used to reduce fluidity. The apparent activation volume and enthalpy for excimer formation was calculated and compared with published data. Pyrene E/M ratios probably reflect the intermolecular volume (fluidity) of the outer region of the bilayer, which is reduced by a decrease in temperature and an increase in pressure and cholesterol. DPH reports the bilayer interior, which is similarly ordered by the experimental treatments. The regional distinction between the two probes, however, accounts for the divergence of E/M ratios and P, which has been reported in membranes enriched with fluidizing fatty acids.

Subcellular distribution of rat pituitary homogenates by poly(ethylene glycol)-dextran countercurrent partitioning

Rat pituitary homogenates were subjected to two phase countercurrent partition in a poly(ethylene glycol)-dextran mixture using a simple apparatus with enhanced gravity to facilitate the phase separations. Assay of the fractions for organelle marker enzymes and prolactin after 17 transfers showed similar distributions for endoplasmic reticulum, lysosomes, prolactin granules and plasma membrane at the lowest dextran concentrations. Increasing the dextran concentrations had a differential effect on the various organelles. Excellent resolution of endoplasmic reticulum from the other organelles was obtained and marked organelle heterogeneity was demonstrated. Two-phase countercurrent partition thus offers an alternative approach to the subcellular fractionation of pituitary homogenates and should prove useful in separating endoplasmic reticulum from plasma membrane and other cell components.

Subcellular fractionation of rat liver homogenates using two-polymer phase systems in a toroidal-coil centrifuge

The principal organelles of rat liver homogenates were fractionated by two-phase partition chromatography using toroidal-coil centrifugation with a mixture of dextran T 500 and poly(ethylene glycol) 6000 in 0.26 M-sucrose containing 10 mM-sodium phosphate/phosphoric acid buffer, pH 7.4. The effects of varying the following parameters on organelle elution profiles, as reflected by their marker-enzyme activities, were studied: centrifuge speed; the composition and relative proportion of dextran-rich and poly(ethylene glycol)-rich phases in the eluent; flow rate; sample volume; homogenate concentration; helix diameter; tubing bore and the number of loops in the coil. Optimal resolution of the organelles was achieved with a toroidal coil of internal diameter 1.07 mm with a 4.55 mm helix diameter on a 0.42 m-diameter rotor running at 1000 rev./min. The eluent was prepared by combining, in a ratio of 93:7 (v/v), the poly(ethylene glycol)-rich upper phase and dextran-rich lower phase obtained from a phase mixture containing 3.3% (w/w) dextran and 5.4% (w/w) poly(ethylene glycol). The flow rate of the eluent was 14ml/h. Optimal conditions for separation of the organelles were evaluated. Resolution of plasma membrane and lysosomes was achieved. Separation of endoplasmic reticulum, which showed marked heterogeneity, from plasma membrane was also demonstrated. DNA and marker enzymes for peroxisomes, mitochondria and cytosol showed distinct elution profiles.

The effect of retroviral transformation on DNA replication and DNA polymerase-gamma activity in chick embryo fibroblast mitochondria

The effect of transformation by oncogenic Rous sarcoma viruses on the replication of mitochondrial DNA (mtDNA) in chick embryo fibroblasts (CEF) was investigated, extending our previous report of a three- to five-fold increase in the rate of mtDNA replication, which is strictly linked to the expression of the transformed state, is mitochondria-specific, and is not attributable to virus production per se or different growth rates between normal and transformed CEF. In this paper, in vivo pulse-label and pulse-chase analysis shows an increased specific activity in all the replicative and topological forms of transformed cell mtDNA I, labeled within a 10-min pulse, 30-min chase period, reflecting about the same proportion of total label incorporated into D-loop strands (approximately 9S) relative to full-length closed circular forms (approximately 37S) of mtDNA from both cell types. In contrast to the concomitant changes observed in many other systems with elevated DNA synthesis, neither the estimated intramitochondrial pool size of the labeled DNA precursor (dTTP), nor the total level of the mtDNA-replicating enzyme (mt gamma-polymerase) is increased in the transformed cells. Notably, however, in both cell types the mitochondrial dTTP pools relative to the mtDNA complement are significantly larger than whole-cell pools relative to the nuclear DNA complement, confirming recent reports in HeLa cells. The solubilized mt gamma-polymerases from normal and transformed CEF, respectively, are both precipitated by 50% ammonium sulfate, inhibited by N-ethylmaleimide, have similar sedimentation coefficients, and exhibit optimal activity when poly(rA) . d(pT)10 is used as the template-primer. On the other hand, the transformed cell enzyme demonstrates an altered response to thiol compounds, a decreased tendency to aggregate during sedimentation, and is significantly less tightly attached to the mitochondria than the normal cell enzyme. We conclude that, as a result of transformation, an increased fraction of mtDNA molecules replicate at a given time, and that this increased replication rate in vivo is correlated with the expression of several altered endogenous properties, which possibly include a modified intramitochondrial structural attachment of the mt gamma-polymerase in situ. This experimental system may be well suitable for use in the identification of regulatory factors which function during the replication of the mitochondrial genome in vivo.

Subcellular fractionation of striatum: sedimentation properties of dopaminergic synaptosomes

Linear sucrose density gradient centrifugation of a crude synaptosomal-mitochondrial preparation of rat striatum was performed at 82,500g for 7.5, 15 and 30 min and 1, 4 and 20 h. After centrifugation various marker enzyme activities were measured throughout the gradients, viz. tyrosine hydroxylase (TH) and DOPA decarboxylase (DD) as markers of dopaminergic synaptosomes, lactate dehydrogenase (LDH) as a general synaptosomal marker and monoamine oxidase (MAO) as a mitochondrial marker. At all centrifugation times the distribution patterns of TH and DD activity coincided almost perfectly. Notable differences were found between the sedimentation properties of these TH/DD-containing particles and LDH-containing particles: TH and DD were symmetrically distributed in the gradient much sooner than LDH, at all centrifugation times the top of the TH and DD curves was lying deeper in the gradient than the highest LDH activity, and TH and DD became enriched in the gradients to a much greater extent than LDH. It is concluded that rat striatal dopaminergic synaptosomes form a relatively homogeneous population of particles sedimenting faster into the gradients than the bulk of striatal synaptosomes does. This distinct sedimentation behaviour of the dopaminergic synaptosomes can be usefully applied for analytical purposes.

Enzyme analysis and subcellular fractionation of human peripheral blood lymphocytes with special reference to the localization of putative plasma membrane enzymes

Human lymphocytes were isolated from defibrinated blood by Ficoll-Hypaque centrifugation with erythrocyte hypotonic lysis. Homogenates of mixed lymphocytes were subjected to analytical subcellular fractionation by sucrose gradient centrifugation in a Beaufay automatic zonal rotor. The principal organelles were characterized by their marker enzymes: cytosol (lactate dehydrogenase), plasma membrane (5'-nucleotidase), endoplasmic reticulum (neutral alpha-glucosidase), mitochondria (malate dehydrogenase), lysosomes (N-acetyl-beta-glucosaminidase), peroxisomes (catalase). gamma-Glutamyl transferase was exclusively localized to the plasma membrane. Leucine amino-peptidase, especially when assayed in the presence of Co2+, was also partially localized to the plasma membrane. Experiments with diazotized sulphanilic acid, a non-permeant enzyme inhibitor, showed that these plasma membrane enzymes are present on the cell surface. No detectable alkaline phosphatase was found in the lymphocytes. Acid phosphatase and beta-glucuronidase were localized to lysosomes and there was some evidence for lysosomal heterogeneity. Leucine amino peptidase, optimal at pH 8.0, showed a partial localization to intracellular vesicles, possibly lysosomes, especially when assayed in the presence of EDTA. These studies provide a technique for determining the intracellular distribution of hitherto unassigned lymphocyte constituents and serve as a basis for investigating the cell pathology of lymphocytic disorders.

Studies on the non-linear osmotic pressure-volume relationship in mitochondria and entry of sucrose into the matrix space during centrifugation

The two-compartment sucrose-space hypothesis was refuted recently (Sitaramam, V. and Sarma, M.K.J. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 3441-3445), using the novel technique of enzyme osmometry of matrix enzymes based on the following premise: a shift in the discontinuity (break-point) of the activity profile of an occluded enzyme as a function of external osmolarity (i.e., osmotic profiles) would imply a shift in the internal solute content of the same compartment as that of the enzyme. A systematic re-evaluation of the osmotic profiles of mitochondrial enzyme systems has revealed that the activities of several matrix and inner membrane enzyme systems exhibited break-points larger than those of osmolysis (i.e., actual release of marker enzymes into the medium) of mitochondria. The experimental findings were consistent with (i) entry of sucrose across the inner membrane consequent to enhanced permeability effects by gravitational field, and (ii) dependence of the kinetic constant of several membrane-bound enzymes/carrier proteins, respiratory coupling and ADP/O ratio on the volume of mitochondria (i.e., osmotic stretch of the inner membrane).

Microanalytical partition of rat-liver homogenates by poly(ethylene glycol)-dextran counter-current distribution

1. The principal organelles from rat liver homogenates were fractionated by counter-current partition between solutions of dextran T50 and poly(ethylene glycol) 6000 in 0.25 M sucrose containing 10 mM sodium phosphate/phosphoric acid buffer, pH 7.4. 2. A small-volume (1.3-ml sample well)counter-current partition apparatus capable of 17 transfers, in which separation of the phases was enhanced by low-speed centrifugation, was used. 3. Variations in distribution of organelles was observed with increasing concentration of dextran and/or poly(ethylene glycol). At a constant polymer composition of 5.0% (w/w) dextran and 4.0% (w/w) poly(ethylene glycol), increasing concentrations of sodium chloride (2.5 mM, 5 mM and 10 mM) also altered the partition of the organelles. 4. Useful analytical resolution of the various organelles was achieved. In particular, separation of endoplasmic reticulum from plasma membrane components was obtained.

Gravitational field enhances permeability of biological membranes to sucrose: an experimental refutation of sucrose-space hypothesis

Isotonic conditions for the integrity of subcellular organelles are shown to be remarkably influenced by the concentration of sucrose present during their isolation by centrifugation. Using the technique of enzyme osmometry, we show that the content of sucrose in synaptosomes reflects nearly total equilibration across the membrane during centrifugation, due to altered permeability of membranes. Presence of sucrose in the matrix space of mitochondria, as demonstrated by enzyme osmometry of matrix enzymes, indicates that the sucrose-space hypothesis is invalid.

Pressure-induced inactivation of sarcoplasmic reticulum adenosine triphosphatase during high-speed centrifugation

Sarcoplasmic reticulum vesicles were found to be highly sensitive to high-speed centrifugation in metal-deprived mediums at low temperature (4 degrees C). The irreversible modifications induced were easily detected from observation of the environment-sensitive spectrum of an iodoacetamide spin-label bound to the ATPase. Centrifugation also resulted in vesicle aggregation and inhibition of calcium transport, ATPase activity, and phosphoenzyme formation. These denaturation-like phenomena were prevented in the presence of sucrose, or by nucleotide binding, or, again, by cation binding to the ATPase high-affinity calcium binding sites and were only present when centrifugation was performed at low temperature. The crucial parameter during this process was found to be the hydrostatic pressure which developed in the centrifuge tube. SR vesicles exposed to 800 bars in a pressure bomb displayed the same features. It is suggested that irreversible denaturation takes place after one or both of the two following well-documented effects of pressure: a rise in the lipid order/disorder transition temperature or dissociation of the oligomeric structure of the calcium pump.

Permeability of mitochondria to sucrose induced by hydrostatic pressure

When subjected to increasing pressure at 0 degree C, rat liver mitochondria become permeable to sucrose, causing them to swell and their outer membrane to rupture. Afterwards they are lysed and their matrix content is released into the medium. This permeation to sucrose may be prevented to some extent by increasing the temperature at which compression is carried out. 0.75 mM imipramine protects mitochondria against lysis caused by hydrostatic pressure, but does not oppose their permeation to sucrose nor the swelling resulting from the compression. At this concentration, the drug does not exhibit a significant effect on the lateral phase separations which take place in the inner mitochondrial membrane under pressure. The mitochondria of rat fetal liver (21 days), kidney and Morris hepatoma 16 become permeable to sucrose when they are subjected to compression; under these conditions, lateral phase separations occur in their inner membrane. Contrary to liver mitochondria, the former do not undergo lysis. Taking into account both present and previous results, events leading to mitochondrial membrane deterioration by hydrostatic pressure may be summarized in the following way. Pressure first leads to a phase transition of the membrane lipids, thus causing a permeation to sucrose; as a result the mitochondria swell because they have absorbed osmotic water. The membrane lipids freeze increasingly as the pressure increases; the inner membrane becomes fragile and finally, in the case of the adult liver organelles, can no longer resist the swelling. All these events can be avoided by increasing the temperature; imipramine only prevents inner membrane lysis.

Subcellular fractionation of human intestinal mucosa by large-scale zonal centrifugation. I. Characterization of subcellular organelles in the distal part of the ileum

The subcellular organelles in human ileal mucosa have been characterized by large-scale rate zonal and isopycnic density-gradient centrifugation. Mucosal scrapings were obtained from surgical specimens and the cells disrupted by extrusion under controlled pressure. The homogenized cells were then centrifuged to prepare a cell extract and the extract fractionated in a single-step procedure by zonal centrifugation on a continuous sucrose gradient. The subcellular organelles (brush borders, basal-lateral membranes, lysosomes, mitochondria, and endoplasmic reticulum) were located in the density gradient by assay of marker enzymes. Since a large number of analyses can be done on each fraction of interest, this fractionation technique may be used to study a variety of compounds and concepts involved in the subcellular physiology and pathology of human ileal mucosa.

Analytical subcellular fractionation of needle-biopsy specimens from human liver

1. Fragments (2-20 mg wet wt.) of closed needle-biopsy specimens from human liver were disrupted in iso-osmotic sucrose and subjected to low-speed centrifugation. The supernatant was layered on a linear sucrose-density gradient in the Beaufay small-volume automatic zonal rotor. The following organelles, with equilibrium densities (g/ml) and principal marker enzyme shown in parentheses, were resolved: plasma membrane (1.12-1.14; 5'-nucleotidase); lysosomes (1.15-1.20; N-acetyl-beta-glucosaminidase); mitochondria (1.20; malate dehydrogenase); endoplasmic reticulum (1.17-1.21; neutral alpha-glucosidase); peroxisomes (1.22-1.24; catalase). 2. The distribution of particulate alkaline phosphatase and, to a lesser degree, leucine 2-naphthylamidase followed that of 5'-nucleotidase. gamma-Glutamyltransferase was associated with membranes of significantly higher equilibrium density than was 5'-nucleotidase. 3. The distribution of 12 acid hydrolases was determined in the density-gradient fractions. beta-Glucosidase had a predominantly cytosolic localization, but the other enzymes showed a broad distribution of activity throughout the gradient. Evidence was presented for two populations of lysosomes with equilibrium densities of 1.15 and 1.20 g/ml, but containing differing amounts of each enzyme. Further evidence of lysosomal heterogeneity was demonstrated by studying the distribution of isoenzymes of hexosaminidase and of acid phosphatase. 4. The resolving power of the centrifugation procedure can be further enhanced with membrane perturbants. Digitonin (0.12 mM) selectively disrupted lysosomes, markedly increased the equilibrium density of plasma-membrane components and lowered the density of the endoplasmic reticulum, but did not affect the mitochondria or peroxisomes. Pyrophosphate (15 mM) selectively lowered the equilibrium density of the endoplasmic reticulum.

Effect of high pressure, detergents and phospholipase on the break in the Arrhenius plot of Azotobacter nitrogenase

It is shown that lipids are responsible for the breaks in the Arrhenius plots of Azotobacter nitrogenase. The physical evidence is that temperature at which the break occurs increases with increasing pressure by 20 K/1000 atm. This is in agreement with the pressure dependence of the transition temperature of several synthetic phospholipids. We also find the same pressure dependence for the broad transitions observed in Escherichia coli phosphatidylethanolamine and in the membrane lipids from Azotobacter itself. Detergents and phospholipase remove the break. Reconstruction can be performed only with specific phospholipids.

Lateral phase separations and structural integrity of the inner membrane of rat-liver mitochondria. Effect of compression. Implications in the centrifugation of these organelles

When maintained in the vicinity of the lower transition temperature of their membrane lipids, rat-liver mitochondria undergo lysis as shown by the release of malate dehydrogenase, (an enzyme located within the mitochondrial matrix), in the surrounding medium. Structural changes take place in the membranes of mitochondria subjected to increasing pressure at 0 degrees C, when the pressure reaches 750 kg/cm2. Freeze-fracture electron microscopy shows the appearance of smooth areas devoid of particles in fracture faces of mitochondrial membranes, together with zones, where aggregated particles can be seen. Concurrently, a suppression of the malate dehydrogenase structure-linked latency is observed. These structural changes can be prevented by increasing the temperature at which compression is performed. The freeze-etching observations suggest that lateral phase separations occur in mitochondrial membranes subjected to high pressure. This can be explained by supposing that pressure promotes the gel-phase appearance in a lipid system and raises the transition temperature since the transition liquid crystal lead to gel is accompanied by a decrease in volume. The deterioration of mitochondria subjected to high pressure is interpreted as a result of the lateral phase separation induced by compression in the membranes. These results are discussed with respect to our interpretation of the damaging effects that hydrostatic pressure, generated by centrifugation, exerts on rat-liver mitochondria.