FORMATION OF MITOCHONDRIA IN NEUROSPORA CRASSA : A Study Based on Mitochondrial Density Changes

The choline concentration used in the growth medium influences the density of mitochondria produced by the chol-1 mutant of Neurospora. Isopycnic centrifugation in sucrose gradients can be used to determine the density of mitochondria, and can resolve into two populations, mitochondria derived from a mixture of cells grown at low (1 µg/ml choline chloride) and high (10 µg/ml choline chloride) choline levels. In an experiment in which cells are shifted from low to high choline growth conditions, mitochondria obtained after varying time periods show a gradual decrease in density tending toward the level typical of high choline mitochondria. Over a 90-minute period of observation, during which time there is an increase of mitochondrial protein mass of ~ 50 per cent over that initially present, the mitochondria change density as a single population. These results are consistent with the view that mitochondria grow by random accretion of new lecithin into existing mitochondrial structures, and also that the mitochondrial population increases by division.     

IL-15Rα deficiency leads to mitochondrial and myofiber differences in fast mouse muscles

The purpose of this study was to determine mitochondrial changes in fast muscles from interleukin-15 receptor alpha knockout (IL-15RαKO) mice. We tested the hypothesis that fast muscles from IL-15RαKO mice would have a greater mitochondrial density and altered internal structure compared to muscles from control mice. In fast muscles from IL-15RαKO mice, mitochondrial density was 48% greater with a corresponding increase in mitochondrial DNA content. Although there were no differences in the relative size of isolated mitochondria, internal complexity was lower in mitochondria from IL-15RαKO mice. These data support an increase in mitochondrial biogenesis and provide direct evidence for a greater density and altered internal structure of mitochondria in EDL muscles deficient in IL-15Rα.     

Cytological effects of platelet-derived growth factor on mitochondrial ultrastructure in fibroblasts

The goal of this study was to evaluate morphofunctional changes in mitochondrial ultrastructure after platelet-derived growth factor application in fibroblasts as an indicator of mitochondrial activation in processes like wound healing. NRK-49F fibroblasts were synchronized, incubated with PDGF (platelet-derived growth factor) and studied by electron microscopy. Volume density (Vv), numerical density (Nv) and surface density (Sv) were measured by stereological analysis. Application of PDGF on NRK-49F caused an increase in mitochondrial volume density by 57% and surface area of cristae per mitochondrion by 65%. The numerical density of the mitochondria was decreased in the PDGF-treated cells by 23%, but at the same time their mean volume was increased. Furthermore, the mitochondria had a complex and highly variable shape both in control and PDGF-treated cells, possibly indicating the existence of a mitochondrial reticulum. The results demonstrated that biochemically active membrane systems in fibroblast mitochondria are enlarged as a direct effect of small doses of platelet-derived growth factor and support the concept that this factor and related peptides serve as mitogens for connective tissue forming cells. Thus, in mitogenic processes like wound healing, the high energy demand of fibroblasts is provided by the increase of the inner surface of mitochondria.     

A glyoxysomal role for microbodies in germinating conidia ofBotryodiplodia theobromae

Microbodies increase in number during germination of conidia ofBotryodiplodia theobromae and display an intimate association with lipid bodies. Activities of the glyoxylate bypass enzymes, isocitrate lyase and malate synthase, the tricar☐ylic acid cycle enzymes, malate dehydrogenase and citrate synthase, and the enzymes of β-oxidation, crotonase and thiolase, increased during germination. In germinating conidia, isociatrate lyase, malate synthase, and catalase were localized in microbodies, which had an equilibrium density of 1.223 g cm⁻³ after isopycnic centrifugation on sucrose density gradients. Malate dehydrogenase and citrate synthase, together with succinate dehydrogenase, were confined to the mitochondria, which had an equilibrium density at 1.185 g cm⁻³. Thiolase and β-acyl-CoA dehydrogenase activities were present in both mitochondria and microbodies, but a third enzyme of β-oxidation, crotonase, was found only in the mitochondria. This distribution of enzymes between the mitochondria and microbodies (glyoxysomes) of a germinating fungal spore is different from that found in germinating seeds of vascular plants.     

Ultrastructure of neurons of the human sympathetic ganglia after sudden death (morphometric study)

Six cases of urgent autopsies after a sudden cardiac death (SCD) of persons at the age 40-60 years and 5 control cases have been investigated. Osmiophilic mitochondria with inclusions make 1% of the whole neuronal cytoplasm volume. If we take all mitochondria as 100%, volumetric density of mitochondria with osmiophilic inclusions makes 9.6%. Volumetric density of mitochondria at SCD in comparison with the control is significantly higher in connection with increase of their size. In other components of cytoplasm, in particular in lysosomes and lipofuscin, no changes are revealed.     

Developmental Changes in the Epidermal Surface Cells of Salamander Larva

Epidermal surface cells were studied ultrastructurally and histochemically at various larval stages in Salamandra salamandra. The most outstanding cellular structures undergoing changes were found to be secretory vesicles, mitochondria and tonofilaments. The highest density of secretory vesicles was noticed immediately after birth, declining in number at later stages and almost disappearing at metamorphosis. The mitochondria, whose appearance at early stages indicates a high metabolic activity, hypertrophy and degenerate close to metamorphosis. Simultaneously, there is an increase in the cellular tonofilaments' density reaching its climax with keratinization.     

Heterogeneity of chondrocyte mitochondria: A study of the Ca2+ concentration and density banding characteristics of normal and rachitic cartilage

Previous morphological studies of the mineralizing epiphysis suggested that some mitochondria were concerned with Ca²⁺ accumulation while others were associated with cellular energetics and metabolism. To determine if there was mitochondrial heterogeneity in chondrocytes of the epiphyseal growth plate, mitochondria were isolated from four different regions of the plate and subjected to continuous sucrose gradient centrifugation. Centrifugation of the organelles in a narrow density sucrose gradient (1.5–2.0 M) in the presence of inhibitors of Ca²⁺ transport (ruthenium red and 5,5′-dithiobis-(2-nitrobenzoic acid)) revealed that considerable heterogeneity existed. In the least calcified zone 20% of the mitochondria formed a low density band of low Ca²⁺ concentration (309 nmol/mg protein). Organelles isolated from more calcified tissue zones showed a concomitant increase in Ca²⁺ concentration (up to 5700 nmol/mg protein) as well as an increase in the total percentage of mitochondria sedimenting in 2.0 M sucrose. The banding patterns of mitochondria isolated from rachitic and hypertrophic cartilage were similar. In addition, similarities were also noted in the Ca²⁺ concentration and the cytochrome oxidase activities of mitochondria of these tissues. During recovery from the rachitic condition, there was a change in the density centrifugation characteristics of this tissue and a substantial increase was noted in the proportion of mitochondria sedimenting in 2.0 M sucrose. The Ca²⁺ concentration of mitochondria of this rapidly calcifying tissue suggested that the critical Ca²⁺ concentration necessary for initiation of the calcification mechanism was 4 μmol/mg protein.     

Modeling mitochondrial dynamics during in vivo axonal elongation

Many models of axonal elongation are based on the assumption that the rate of lengthening is driven by the production of cellular materials in the soma. These models make specific predictions about transport and concentration gradients of proteins both over time and along the length of the axon. In vivo, it is well accepted that for a particular neuron the length and rate of growth are controlled by the body size and rate of growth of the animal. In terms of modeling axonal elongation this radically changes the relationships between key variables. It raises fundamental questions. For example, during in vivo lengthening is the production of material constant or does it change over time? What is the density profile of material along the nerve during in vivo elongation? Does density change over time or vary along the nerve? To answer these questions we measured the length, mitochondrial density, and estimated the half-life of mitochondria in the axons of the medial segmental nerves of 1st, 2nd, and 3rd instar Drosophila larvae. The nerves were found to linearly increase in length at an average rate of 9.24 microm h(-1) over the 96 h period of larval life. Further, mitochondrial density increases over this period at an average rate of 4.49x10(-3) (mitochondria microm(-1))h(-1). Mitochondria in the nerves had a half-life of 35.2h. To account for the distribution of the mitochondria we observe, we derived a mathematical model which suggests that cellular production of mitochondria increases quadratically over time and that a homeostatic mechanism maintains a constant density of mitochondria along the nerve. These data suggest a complex relationship between axonal length and mass production and that the neuron may have an "axonal length sensor."     

Structural and enzymic changes in fat body mitochondria of the blowfly,Aldrichina grahami,during larval growth

Changes in the properties of fat body mitochondria from the blowfly, Aldrichina grahami, during larval growth were examined by electron microscopy and enzyme assay. Early in the last instar, the fat body contained many large mitochondria (1.5 μm i.d,) with a mean buoyant density of 1.19. After the larvae stopped eating, the number of fat body mitochondria decreased, their size was reduced (1.0 μm i.d.) and their mean buoyant density became 1.23. The two mitochondrial populations were demonstrated in the larval fat body by differential centrifugation and by membrane filtration. The relative amounts of the two populations were dependent on the age of the larvae. The appearance of the smaller mitochondria are likely to be due to mitochondrial degeneration. The greater density of the smaller mitochondria compared with the larger may be due to the increased ‘leakiness’ of the organelles with the age of the larvae causing an increase in the accessibility of the matrix space to sucrose.     

Comparative subcellular fractionation of control and cold-adapted rat brown and white adipose tissue with special reference to peroxisomal and mitochondrial distributions

A new technique for single-step subcellular fractionation of adipose tissue homogenates by analytical sucrose density gradient centrifugation in a vertical pocket reorientating rotor is described. The density gradient distributions of mitochondrial and peroxisomal marker enzymes in brown and white adipose tissue of control and cold exposed rats are compared. The equilibrium density of brown fat mitochondria was found to be significantly increased compared with white fat mitochondria. GDP binding activity was localized solely to the mitochondria in both control and cold-adapted brown adipose tissue. Brown and white fat mitochondria fractions were isolated by differential centrifugation and the specific activities of various enzymes in the homogenate and mitochondrial preparations determined. The specific activity of creatine kinase in brown adipose tissue was found to be ten-fold higher than in white fat and subcellular fractionation studies showed the activity to have an exclusively cytosolic distribution in both tissues. GDP binding activity and some of the mitochondrial enzymes showed, in brown adipose, a striking increase in total activity in cold adapted rats compared to control animals. For some enzyme activities there was a small increase when expressed per mg tissue or per mg mitochondrial protein. When expressed per mg DNA i.e. per cell, there was a reduced specific activity of the mitochondrial and peroxisomal enzymes in both brown and white adipose tissue on cold adaptation.     

Mitochondrial development during Drosophila oogenesis: distribution, density and in situ RNA hybridizations.

The changes in distribution and density of mitochondria and the level of mitochondrial RNA during Drosophila oogenesis were studied simultaneously in the 3 cell types ie follicle cells, nurse cells and oocyte, making up the egg chamber. Up to stage 6, mitochondrial density (mitochondrial and cellular areas ratio) was elevated and increased similarly in both follicle and nurse cells. Thereafter the mitochondrial density of follicle cells continued to increase and that of the nurse cells declined markedly while the nurse cell mitochondria assembled in dense groups and decreased in size. This can be related to a transfer of nurse cell cytoplasm, including mitochondria, to the oocyte. In the oocyte from stage 4 to stage 7 we observed a significant decrease of the mitochondrial density due to the absence of mitochondrial biogenesis. Then the cytoplasm transfer caused mitochondrial density to increase up to the level found in the nurse cells at the end of oogenesis. The mature oocyte contains enough mitochondria to supply 15,000 somatic cells. Our results strongly suggest that the variations in size, distribution and density of mitochondria relate to the particular energetic requirements of the different cell types during the first half of oogenesis. Later they relate to the developmental requirements of the nurse cells and the oocyte, in particular the storage of mitochondria in the oocyte. The level of mitochondrial RNA was studied through in situ hybridization. Throughout oogenesis the follicle and nurse cell RNA evolved similarly. Up to stage 9, there was no change in RNA densities in these cells, suggesting a correlation with the cell volume and/or the nuclear DNA content. Thereafter the cellular RNA concentration declined rapidly. In the oocyte the RNA concentration evolved differently especially from stage 10 to the end, the RNA density being stabilized. This can be related to the injection of nurse cell mitochondria, followed by their assignment to reserve status. Our results suggest that the mt RNA density is under extramitochondrial control mechanisms.     

Effect of energy metabolism inhibitors on the morphometric parameters and 3-dimensional structure of L-cell mitochondria

It has been shown by stereological analysis that the earlier discovered changes in the structure of mitochondria in cyanide treated L-cells (decrease in numerical density of mitochondria, increase in volume density of mitochondria, and surface density of mitochondrial membranes) are prevented by oligomycin, and they do not occur in the presence of oligomycin and protonophorous uncoupler carbonylcyanide m-chlorphenyl hydrazone applied separately. Proceeding from three-dimension reconstructed mitochondrial models it has been shown that cyanide treatment of L-cells for 23 hours causes a transformation of mitochondria as discrete column-like structures into a network of mitochondrial reticulum oriented from the nucleus to the periphery of the cell. After the treatment of L-cells with cyanide together with oligomycin, or with oligomycin and protonophore applied separately, the mitochondria retain the structure of discrete column-like for mations characteristic of the control cells. It is assumed that the functioning ATP-system is a physiological prerequisite of the formation of mitochondrial reticulum under conditions of the inhibited respiratory energy metabolism in the cell.     

Physiological Cost of Physical Exercise and Mitochondrial Volume in Working Muscles of Subjects Exposed to Long-Term Hypokinesia: Effects of Local Resistance Exercise

The results of changes in the physiological cost of 30-min submaximal aerobic bicycle ergometric exercise and characteristics of the mitochondrial apparatus of m. vastus lateralis were assessed comparatively during 120-day (–6°) antiorthostatic hypokinesia either without prophylactic measures or with low-intensity resistance exercise training for 60 days using a Penguin exercise suit. Hypokinesia was accompanied by an increase in the working heart rate and lactate accumulation in the blood during the test exercise, as well as by a decrease in the myofibril size and the volume density of mitochondria in the m. vastus lateralis fibers. The patterns of dynamic changes in the lactate concentration in the blood during exercise training and in the volume density of central mitochondria were found to be similar. A correlation between the rate of lactate accumulation in the blood during the test exercise and the volume density of mitochondria in the working muscle appeared after long-term (60 days) exposure to hypokinesia. The use of the Penguin exercise suit in dynamic mode during prolonged (60-day) exposure to hypokinesia completely prevented the following effects: atrophy of slow-type fibers, a decrease in the volume density of central mitochondria, and an increase in the level of lactate accumulation in the blood under conditions of a standard submaximal aerobic exercise load. The correlation links between the oxidative potential of working muscle and the energy supply of muscular work are discussed.     

Biogenesis of Mitochondria in Germinating Peanut Cotyledons II. Changes in Cytochromes and Mitochondrial DNA

Biogenesis of mitochondria occurs in the germinating cotyledons of peanuts. This process was demonstrated by measuring both constitutive and enzymatic properties of mitochondria as a function of germination time. Direct counting by phase contrast microscopy of sucrose density gradient preparations showed that the number of mitochondria increased markedly during germination. DNA with a buoyant density distinct from the major cellular DNA was associated with these mitochondrial preparations. During germination the amount of this DNA in mitochondrial pellets increased. This increase closely paralleled the increase in number of mitochondria.

Succinoxidase and succinic dehydrogenase increased during germination. Both activities were confined to the mitochondrial fraction. The rate of increase of succinoxidase activity was significantly greater than the rate of increase of succinic dehydrogenase and both increased at least initially at a greater rate than the amount of mitochondrial DNA or numbers of mitochondria.

The amounts of cytochromes present in mitochondrial preparations were measured spectrophotometrically. All of the cytochromes increased in amount during germination. The rate of increase of cytochrome a — a₃ very close to the rate of increase in succinoxidase activity.

     

Heterogeneity of chondrocyte mitochondria: A study of the Ca concentration and density banding characteristics of normal and rachitic cartilage

Previous morphological studies of the mineralizing epiphysis suggested that some mitochondria were concerned with Ca²⁺ accumulation while others were associated with cellular energetics and metabolism. To determine if there was mitochondrial heterogeneity in chondrocytes of the epiphyseal growth plate, mitochondria were isolated from four different regions of the plate and subjected to continuous sucrose gradient centrifugation. Centrifugation of the organelles in a narrow density sucrose gradient (1.5–2.0 M) in the presence of inhibitors of Ca²⁺ transport (ruthenium red and 5,5′-dithiobis-(2-nitrobenzoic acid)) revealed that considerable heterogeneity existed. In the least calcified zone 20% of the mitochondria formed a low density band of low Ca²⁺ concentration (309 nmol/mg protein). Organelles isolated from more calcified tissue zones showed a concomitant increase in Ca²⁺ concentration (up to 5700 nmol/mg protein) as well as an increase in the total percentage of mitochondria sedimenting in 2.0 M sucrose. The banding patterns of mitochondria isolated from rachitic and hypertrophic cartilage were similar. In addition, similarities were also noted in the Ca²⁺ concentration and the cytochrome oxidase activities of mitochondria of these tissues. During recovery from the rachitic condition, there was a change in the density centrifugation characteristics of this tissue and a substantial increase was noted in the proportion of mitochondria sedimenting in 2.0 M sucrose. The Ca²⁺ concentration of mitochondria of this rapidly calcifying tissue suggested that the critical Ca²⁺ concentration necessary for initiation of the calcification mechanism was 4 μmol/mg protein.     

Division of Physarum mitochondria during starvation

Microplasmodia of Physarum polycephalum used in this study form spherules after 18 h of starvation. Stereological morphometry revealed that between the 2nd and the 5th hour of starvation the number of mitochondria in 1 mm3 of cytoplasm rises from about 12 to 24 millions and the mean volume of mitochondria drops from circa 4.6 to 3.0 microns3. This denotes the synchronous division of mitochondria. The daughter mitochondria show an increase in density of the matrix and a decrease in condensation of the net of tubular cristae. The mitochondrial division, decrease in activity of the respiratory chain and maximum of its cyanide resistance occur at the same time.     

COBALT AS A MITOCHONDRIAL DENSITY MARKER IN A STUDY OF CYTOPLASMIC EXCHANGE DURING MATING OF SCHIZOPHYLLUM COMMUNE

A slow in vivo uptake of cobalt from a growth medium resulted in an increase in density of mitochondria of Schizophyllum commune. Differential labeling of donor and resident mycelia, and subsequent analysis of resident mycelia surrounding donor implants, detected cobalt-dense mitochondria and demonstrated exchange of mitochondria after hyphal fusion. Transfer of mitochondria occurred in fully compatible, common-A, and common-AB matings, but was not detected in common-B matings of the tetrapolar Basidiomycete S. commune.     

Mitochondrial development during Drosophila oogenesis: distribution,density and in situ RNA hybridizations

The changes in distribution and density of mitochondria and the level of mitochondrial RNA during Drosophila oogenesis were studied simultaneously in the 3 cell types ie follicle cells, nurse cells and oocyte, making up the egg chamber. Up to stage 6, mitochondrial density (mitochondrial and cellular areas ratio) was elevated and increased similarly in both follicle and nurse cells. Thereafter the mitochondrial density of follicle cells continued to increase and that of the nurse cells declined markedly while the nurse cell mitochondria assembled in dense groups and decreased in size. This can be related to a transfer of nurse cell cytoplasm, including mitochondria, to the oocyte. In the oocyte from stage 4 to stage 7 we observed a significant decrease of the mitochondrial density due to the absence of mitochondrial biogenesis. Then the cytoplasm transfer caused mitochondrial density to increase up to the level found in the nurse cells at the end of oogenesis. The mature oocyte contains enough mitochondria to supply 15 000 somatic cells. Our results strongly suggest that the variations in size, distribution and density of mitochondria relate to the particular energetic requirements of the different cell types during the first half of oogenesis. Later they relate to the developmental requirements of the nurse cells and the oocyte, in particular the storage of mitochondria in the oocyte. The level of mitochondrial RNA was studied through in situ hybridization. Throughout oogenesis the follicle and nurse cell RNA evolved similarly. Up to stage 9, there was no change in RNA densities in these cells, suggesting a correlation with the cell volume and/or the nuclear DNA content. Thereafter the cellular RNA concentration declined rapidly. In the oocyte the RNA concentration evolved differently especially from stage 10 to the end, the RNA density being stabilized. This can be related to the injection of nurse cell mitochondria, followed by their assignment to reserve status. Our results suggest that the mt RNA density is under extramitochondrial control mechanisms.     

A comparative morphometric analysis of the effects of thyroxine and ACTH on the zona fasciculata of rat adrenal cortex.

The effects of thyroxine and ACTH on the ultrastructure of cells of the adrenal zona fasciculata were studied by morphometric analysis and compared by two-way analysis of variance. The results indicate that the effects of thyroxine and ACTH are different and independent. The statistically significant differences in effect of thyroxine and ACTH are: thyroxine causes an increase in the volume fraction of mitochondria and a decrease in the volume fraction of endoplasmic reticulum independent of ACTH; thyroxine causes a decrease in surface density of mitochondria and endoplasmic reticulum in the absence of ACTH, but in the presence of ACTH this effect is moderated by an interaction of throxine and ACTH. There were no statistically significant effects of either thyroxine or ACTH on volume fraction or surface density of liposomes.     

Structural changes in L-cell mitochondria exposed to cyanide

Using light and electron microscopy, as well as stereological analysis, a study was made of structural changes in mitochondria of cultured L-cells acted upon with 1 mM cyanide. After 23 hours of incubation, in cells cultured in the presence of cyanide the volume density of mitochondria, the volume of the average mitochondrion and the surface area of its membranes increased nearly twice as much. Concurrently, the number of mitochondria decrease also practically two-fold without any reliable changes in the surface area of membranes per unit of mitochondrion volume. A shorter (7 hours) incubation of L-cells in the presence of cyanide results in a decreased volume density of mitochondria in the cytoplasm, decreased volume of the average mitochondrion, without any significant changes in other above mentioned parameters. It is supposed that the changes in mitochondria under a prolonged cyanide treatment of cells are conditioned by the fusion of mitochondria as well as by a compensatory increase in the total surface of mitochondrial membranes.