First evidence of mitochondrial lensing in two species of the “Typhloplanoida” (Plathelminthes,Rhabdocoela): phylogenetic implications

 Based on electron-microscopical observations the light-sensing organs of Proxenetes deltoides and Ptychopera westbladi, representatives of the ”Typhloplanoida” Trigonostominae, are described. The photoreceptors in both species belong to the type of rhabdomeric pigment cup ocelli. P. deltoides has a single pigment cell and three sensory cells. P. westbladi possesses eyes made up of a single pigmented cup cell and a single sensory cell. The dioptric apparatus in the eyes of P. deltoides is formed by three proliferations of the cup cell containing giant mitochondria. In P. westbladi, the elements focalizing incoming light also consist of modified mitochondria which are arranged in the section of the cup cell covering the eye cavity. With regard to the new findings, mitochondrial lensing is hypothesized as an autapomorphy of a monophylum encompassing distinct taxa or all members of the free-living Rhabdocoela; the Neodermata also belong to this monophylum. Accepted: 21 March 1996     

Giant mitochondria in the mature egg cell ofPelargonium zonale

Summary Giant mitochondrial nuclei (known as nucleoids or mt-nuclei), which contain extremely large amounts of DNA, were studied in thin sections of the mature egg and proembryo (2 and 6 days after double fertilization) ofPelargonium zonale. Samples were embedded in Technovit 7100 resin, stained with 4,6-diamidino-2-phenylindole (DAPI) and examined by immuno-gold electron microscopic cytochemistry. The egg cell contained giant mitochondria (either long and stretched or cup-shaped) which contained a large amount of DNA (more than 4 megabase pairs). However, the other cells, such as synergids, the central cell and nucellus contained small spherical mitochondria. Giant mitochondria in the egg cell were often found to make mitochondria complexes due to the grouping of cupule-shaped mitochondria. Immuno-gold electron microscopic cytochemistry revealed that the mitochondrial DNA is localized in the electron transparent of the giant mitochondria. Apparently, the large mitochondria in the egg cell divided in stages to form small, spherical mitochondria during the early stages of embryogenesis and the DNA content in individual large mitochondrion also decreased significantly. The amount of mitochondrial DNA reached approximately 800 kbp in the globular embryo 6 days after double fertilization. The formation of giant mitochondria in mature eggs has significant aspects after double fertilization.     

Shared molecular characteristics of successfully transformed mitochondrial genomes in <Emphasis Type="Italic">Chlamydomonas</Emphasis><Emphasis Type="Italic">reinhardtii</Emphasis>

Three types of respiratory deficient mitochondrial strains have been reported in Chlamydomonas reinhardtii: a deficiency due to (i) two base substitutions causing an amino acid change in the apocytochrome b (COB) gene (i.e., strain named dum-15), (ii) one base deletion in the COXI gene (dum-19), or (iii) a large deletion extending from the left terminus of the genome to somewhere in the COB gene (dum-1, -14, and -16). We found that these respiratory deficient strains of C. reinhardtii can be divided into two groups: strains that are constantly transformable and those could not be transformed in our experiments. All transformable mitochondrial strains were limited to the type that has a large deletion in the left arm of the genome. For these mitochondria, transformation was successful not only with purified intact mitochondrial genomes but also with DNA-constructs containing the compensating regions. In comparison, mitochondria of all the non-transformable strains have both of their genome termini intact, leading us to speculate that mitochondria lacking their left genome terminus have unstable genomes and might have a higher potential for recombination. Analysis of mitochondrial gene organization in the resulting respiratory active transformants was performed by DNA sequencing and restriction enzyme digestion. Such analysis showed that homologous recombination occurred at various regions between the mitochondrial genome and the artificial DNA-constructs. Further analysis by Southern hybridization showed that the wild-type genome rapidly replaces the respiratory deficient monomer and dimer mitochondrial genomes, while the E. coli vector region of the artificial DNA-construct likely does not remain in the mitochondria.     

Protective action of l-carnitine on cardiac mitochondrial function and structure against fatty acid stress

Cardiovascular risks are frequently accompanied by high serum fatty acid levels. Although recent studies have shown that fatty acids affect mitochondrial function and induce cell apoptosis, l-carnitine is essential for the uptake of fatty acids by mitochondria, and may attenuate the mitochondrial dysfunction and apoptosis of cardiocytes. This study aimed to elucidate the activity of l-carnitine in the prevention on fatty acid-induced mitochondrial membrane permeability transition and cytochrome c release using isolated cardiac mitochondria from rats. Palmitoyl-CoA-induced mitochondrial respiration that was observed with l-carnitine was inhibited with oligomycin. The palmitoyl-CoA-induced mitochondrial membrane depolarization and swelling were greatly inhibited by the presence of l-carnitine. In ultrastructural observations, terminally swollen and ruptured mitochondria with little or no distinguishable cristae structures were induced by treatment with palmitoyl-CoA. However, the severe morphological damage in cardiac mitochondria was dramatically inhibited by pretreatment with l-carnitine. Treatment with l-carnitine also attenuated 4-hydroxy-l-phenylglycine- and rotenone-induced mitochondrial swelling even when the l-carnitine could not protect against the decrease in oxygen consumption associated with these inhibitors. Furthermore, l-carnitine completely inhibited palmitoyl-CoA-induced cytochrome c release. We concluded that l-carnitine is essential for cardiac mitochondria to attenuate the membrane permeability transition, and to maintain the ultrastructure and membrane stabilization, in the presence of high fatty acid β-oxidation. Consequently, the cells may be protected against apoptosis by l-carnitine through inhibition of the fatty acid-induced cytochrome c release.     

Photoreceptors with mitochondrial lenses inPogaina suecica (Plathelminthes,Rhabdocoela)

Summary The photoreceptors ofPogaina suecica correspond to the type of pigment cup ocelli. Each eye consists of one cup cell and three sensory cells. The most conspicuous differentiations of these eyes are lens elements formed by giant mitochondria densely filled with homogeneous electron-dense material. From electron microscopical findings available to date it is hypothesized that mitochondrial lensing might be an autapomorphy of a taxon comprising the Provorticidae Kirgisellinae, Dalyelliidae and Graffillidae groups which are ascribed to the paraphyletic Dalyellioida.Abbreviations l _1–3 lenses - npc nucleus of the pigment cell - pc pigment cell - pg pigment granule - rh rhabdomeres - sc _1–3 sensory cells     

An ultrastructural comparative study of the sperm of<Emphasis Type="Italic"> Hyla pseudopseudis</Emphasis>,<Emphasis Type="Italic"> Scinax rostratus</Emphasis>, and<Emphasis Type="Italic"> S. squalirostris</Emphasis> (Amphibia: Anura: Hylidae)

We make detailed comparisons of the ultrastructure of the spermatozoon among three species of the family Hylidae, Hyla pseudopseudis, Scinax rostratus, and S. squalirostris. The acrosome complex consists of two conical structures covering the nuclear rostrum, the acrosome vesicle, and the subacrosomal cone. The nucleus has a moderately condensed chromatin with a conical shape in longitudinal sections and a circular shape in cross-sections. In H. pseudopseudis, mitochondria are numerous and circular, and in S. rostratus and S. squalirostris there are fewer mitochondria that are more elongate in longitudinal and transverse sections. In H. pseudopseudis, the mitochondrial collar starts adjacent to the distal centriole, occupying the whole midpiece, whereas in both Scinax species the mitochondrial collar starts only at the posterior one-third of the midpiece. In both Scinax species, the presence of juxta-axonemal fiber, axial sheath, and axial fiber in the tail are seemingly plesiomorphic characters, widespread among bufonoid frogs. In H. pseudopseudis, however, the absence of axial fiber and axial sheath seems to be derived from the typical bufonoid condition. The differences between Hyla and Scinax sperm endorse the separation of the two genera and suggest that sperm ultrastructure can be a useful tool to investigate relationships at the intrafamily level.     

Fluorescence microscopic study of the formation of giant mitochondrial nuclei in the young ovules ofPelargonium zonale

Summary The size of mitochondrial genomes in higher plants are known to range from 200 to 2400 kilobase pairs. However, we failed to identify cytochemically any mitochondria that contain an identifiable master mitochondrial genome. In the present experiments, we have found the giant mitochondrial nuclei which have the capacity for including the master mitochondrial genome in the young ovaries ofPelargonium zonale by use of a 4-6-diamidino-2-phenylindole (DAPI) epifluorescence microscopy, a Technovit embedding, and a video-intensified photon counting system.     

Oxidative stress by <Emphasis Type="Italic">Helicobacter pylori</Emphasis> causes apoptosis through mitochondrial pathway in gastric epithelial cells

Helicobacter pylori is a gram negative bacterium that infects the human stomach of approximately half of the world’s population. It produces oxidative stress, and mitochondria are one of the possible targets and the major intracellular source of free radicals. The present study was aimed at determining mitochondrial alterations in H. pylori-infected gastric epithelial cells and its relationship with oxidative stress, one of the recognized causes of apoptotic processes. Cells were treated with a strain of H. pylori for 24 h. Cellular oxidative burst, antioxidant defense analysis, mitochondrial alterations and apoptosis-related processes were measured. Our data provide evidence on how superoxide acts on mitochondria to initiate apoptotic pathways, with these changes occurring in the presence of mitochondrial depolarization and other morphological and functional changes. Treatment of infected cells with Vitamin E prevented increases in intracellular ROS and mitochondrial damage consistent with H. pylori inducing a mitochondrial ROS mediated programmed cell death pathway.     

Giant mitochondria in chloroplast-deprivedEuglena gracilis late after N-succinimidylofloxacin treatment

Euglena gracilis cells were treated with N-succinimidylofloxacin. After two years of cultivation of chloroplast-free mutants a number of anomalous mitochondria have been observed. Aberrant mitochondria about 5–8 μm long and wide with unusual shape, disfigured mitochondria with enormous size, giant swollen oval-shaped megamitochondria, narrow and very long (50–60 μm) mitochondria localized at the cell perimeter were found in addition to normal mitochondria. The volume percentage of aberrant mitochondria in 58% of cells reached 65%. Swollen mitochondria probably do not fulfil the mitochondrial function and may cause cell death with subsequent elimination of injured mitochondria.     

Behavior of mitochondria, microtubules, and actin in the triangular yeastTrigonopsis variabilis

Summary Dimorphic yeastTrigonopsis variabilis is a unique species that can form either an ellipsoidal or a triangular cell depending upon nutritional conditions. This fluorescence microscopic study was intended to correlate morphological changes of mitochondria in the triangular cells with the distribution of the cytoskeleton. In addition, unique features in the behavior of the cytoskeleton were also examined during triangular cell formation. In log-phase cells stained with 4,6-diamidino-2-phenylindole, mitochondrial nucleoids appeared as a string of beads throughout the vegetative growth. The profile of mitochondria stained by 3,3-dihexyloxacarbocyanine iodide showed a network corresponding to the fluorescence images of mitochondrial nucleoids in both mother and daughter cells. Cell-cycle-dependent fragmentation of mitochondria was not discerned. As the culture reached stationary phase, a network of mitochondria gradually changed to form unique rings that were located near the angles of triangular cells. When examined by immunofluorescence microscopy with anti-tubulin antibody, microtubules were found to be well developed along the sides of cells in the cytoplasm ofT. variabilis interphase cells. Although distributions of microtubules and mitochondria are different during cell cycle as a whole, cytoplasmic microtubules frequently extended along a part of the mitochondria in budded cells, suggesting correlation of microtubules and mitochondria. Rhodamine-phalloidin staining revealed both actin patches and cables. Actin cables elongated from mother cells into the buds and showed close proximity to mitochondria, although complete overlapping of both structures was rare. Moreover, actin patches localized on the mitochondrial network at a frequency of 65%. These results suggested that actin cables and patches, as well as microtubules, participated in the distribution of mitochondria. The localization of actin patches separated towards opposite ends at a bud tip when the bud grew to medium size. The unique localization of actin patches is responsible for bi-directional growth of the bud, forming triangular cells.     

MORPHOLOGICAL VARIABILITY OF MITOCHONDRIAL FINE STRUCTURE IN CULTURED GONYAULAX POLYEDRA (PYRRHOPHYTA)1

Mitochondria in Gonyaulax polyedra Stein have a highly variable morphology which depends on their location within the cell. The morphology ranges from mitochondria, 1 μm in cross section, with highly dense cristae which are located within the central sphere of golgi bodies to giant pleomorphic mitochondria, 5–8 μm in cross section containing condensed “chromosome” structures and located in the more peripheral regions of the cell. Elongated mitochondria containing microtubule-like elements ware also observed.     

Three-dimensional periodic cubic membrane structure in the mitochondria of amoebaeChaos carolinensis

Summary Through computer simulation of images produced by the transmission electron microscope (TEM), we have identified three-dimensional periodic cubic membrane structures in giant amoebae (Chaos carolinensis) mitochondria. The cubic membranes are based on the highly curved three-dimensional periodic cubic surfaces, sharing the same geometry of mathematically defined periodic minimal surfaces. The double-membrane structures identified here divide space into three separate and convoluted subspaces. Specimen preparation, specifically the tendency to cut oblique sections, of this membrane crystal has added to the complexity of the resulting TEM projections and until now prevented researchers from recognizing them. It is the added complexity of the oblique sections, though, that allows us to match the TEM projection to a computer simulation of the same with confidence. In this study, formation of cubic membrane structures in amoeba mitochondria was found to be dependent on diet. The cubic structures only occurred in the absence of food, and disappeared in the presence of food, suggesting a structural adaptation and possible advantages for amoeba's survival in nature. The verification of mathematically well-defined structures in unfed amoeba mitochondria is also important to the understanding of the mitochondrial bioenergetics in relation to the topology of the inner membrane, where major cellular energy production as well as free-radical generation are taking place. This understanding may carry great impact upon human health as far as aging and age-related degenerative diseases are concerned, especially as mitochondrial disorders have been implicated in these processes.Abbreviations G gyroid - D double diamond - P primitive - TEM transmission electron microscopy - PCS periodic cubic surface     

Giant mitochondria do not fuse and exchange their contents with normal mitochondria

Giant mitochondria accumulate within aged or diseased postmitotic cells as a consequence of insufficient autophagy, which is normally responsible for mitochondrial degradation. We report that giant mitochondria accumulating in cultured rat myoblasts due to inhibition of autophagy have low inner membrane potential and do not fuse with each other or with normal mitochondria. In addition to the low inner mitochondrial membrane potential in giant mitochondria, the quantity of the OPA1 mitochondrial fusion protein in these mitochondria was low, but the abundance of mitofusin-2 (Mfn2) remained unchanged. The combination of these factors may explain the lack of mitochondrial fusion in giant mitochondria and imply that the dysfunctional giant mitochondria cannot restore their function by fusing and exchanging their contents with fully functional mitochondria. These findings have important implications for understanding the mechanisms of accumulation of age-related mitochondrial damage in postmitotic cells.     

Mitofusins Mfn1 and Mfn2 coordinately regulate mitochondrial fusion and are essential for embryonic development

Mitochondrial morphology is determined by a dynamic equilibrium between organelle fusion and fission, but the significance of these processes in vertebrates is unknown. The mitofusins, Mfn1 and Mfn2, have been shown to affect mitochondrial morphology when overexpressed. We find that mice deficient in either Mfn1 or Mfn2 die in midgestation. However, whereas Mfn2 mutant embryos have a specific and severe disruption of the placental trophoblast giant cell layer, Mfn1-deficient giant cells are normal. Embryonic fibroblasts lacking Mfn1 or Mfn2 display distinct types of fragmented mitochondria, a phenotype we determine to be due to a severe reduction in mitochondrial fusion. Moreover, we find that Mfn1 and Mfn2 form homotypic and heterotypic complexes and show, by rescue of mutant cells, that the homotypic complexes are functional for fusion. We conclude that Mfn1 and Mfn2 have both redundant and distinct functions and act in three separate molecular complexes to promote mitochondrial fusion. Strikingly, a subset of mitochondria in mutant cells lose membrane potential. Therefore, mitochondrial fusion is essential for embryonic development, and by enabling cooperation between mitochondria, has protective effects on the mitochondrial population.     

Variability of mitochondrial population in Chlamydomonas reinhardii

Several details have been published cocerning the mitochondrial number and shapes at various stages of the synchronized vegetative and generative cell cycle in Chlamydomonas reinhardii. The present study, based on ultrathin serial sections and threedimensional reconstructions, completes these data. Quantitative analysis of serial micrographs makes it possible to give specific details of mitochondrial volumes in cells at early intermediate stages of the vegetative life cycle. Our investigations clearly show that mitochondria have a relatively wide range of sizes, within certain limits, and vary like the mitochondrial shapes; in fact, they vary in various cells at various stages as well as in several cells at the same stage and even in one and the same cell. Thus, we present a plastic insight into the dynamically changing micromorphology of the mitochondrial population in Chlamydomonas reinhardii.     

Behavior of nuclei during zoosporogenesis in Bryopsis plumosa (Bryopsidales, Chlorophyta)

The behavior of nuclei during zoosporogenesis in Bryopsis plumosa (Bryopsidales, Chlorophyta) was examined by fluorescence and electron microscopy. Each mature filamentous sporophyte had a single lenticular nucleus, which was about 25 m in diameter and embedded in a thick cytoplasmic layer. At the commencement of multinucleation, giant nuclei with large vacuolated nucleoli, giant nuclei containing chromosomes, and dumbbell-shaped nuclei were observed. Sometimes, two small nuclei also appeared in the thick cytoplasm where the giant nucleus had presumably been present. Electron microscopy revealed the existence of ribbon-like structures resembling synaptonemal complexes within the nucleus having a large vacuolated nucleolus. Nuclei extended their distribution by repetitive divisions. A pair of centrioles was adjacent to the interphase nucleus. When the nuclei were distributed throughout the cell, they became localized nearly equidistantly from one another, each being surrounded by several chloroplasts. At this stage, many centrioles lay along the nuclear surface. The bulk of cytoplasm was then divided into many masses of protoplasm, each of which developed into a uninucleate, stephanokontic zoospore with a whorl of flagella.     

A mitochondrial plasmid that promotes mitochondrial fusion inPhysarum polycephalum

Summary We have identified a novel mitochondrial plasmid of about 16 kbp inPhysarum polycephalum. This plasmid was apparently responsible for promoting mitochondrial fusion. Only in strains carrying the plasmid, small spherical mitochondria fused with one another to form large knotted multinucleate mitochondria which subsequently nderwent fusion between the areas (mt-nuclear) that contained the mitochondrial DNA (mtDNA) derived from individual mitochondria. Several successive mitochondrial divisions followed, accompanied by mt-nuclear divisions. The resulting mitochondria contained recombinant mtDNAs, but the plasmid was transmitted to all mitochondria without any structural change.     

Behavior of mitochondria and their nuclei during amoebae cell proliferation inPhysarum polycephalum

Summary We investigated the manner of mitochondrial DNA (mtDNA) replication and distribution during the culture ofPhysarum polycephalum amoebae cells by microphotometry, anti-BrdU immunofluorescence microscopy, and quantitative hybridization analysis. In amoebae cells ofP. polycephalum, the number of mitochondria per cell and the shape of both mitochondria and mitochondrial nuclei (mt-nuclei) noticeably changed over the culture period. At the time of transfer, about 27 short ellipsoidal shaped mitochondria, which each contained a small amount of DNA, were observed in each cell. The number of mitochondria per cell decreased gradually, while the amount of mtDNA in an mt-nucleus and the length of mt-nuclei increased gradually. Midway through the middle logarithmic growth phase, the number of mitochondria per cell reached a minimum (about 10 mitochondria per cell), but most mtnuclei assumed an elongated shape and contained a large amount of mtDNA. During the late log- and stationary-growth phase, the number of mitochondria per cell increased gradually, while the amount of DNA in an mt-nucleus and mt-nuclei length decreased gradually. Upon completion of the stationary phase, the number and condition of mitochondria within cells returned to that first observed at the time of transfer. The total amount of mtDNA in a cell increased about 1.6-fold the first day, decreased immediately, then maintained a constant level ranging from 130 to 160 T. Except for the fact that mtDNA synthesis began earlier than synthesis of cell nuclei, the rate of increase in mtDNA paralleled that of cell-nuclear DNA throughout the culture. These results indicate that mtDNA is continuously replicated in pace with cell proliferation and the rate of mitochondrial division varies during culture; this mitochondrial division does not synchronize with either mtDNA replication or cell division. Furthermore, we observed the spatial distribution of DNA replication sites along mt-nuclei. Replication began at several sites scattered along an mt-nucleus, and the number of replication sites increased as the length of mt-nuclei increased. These results indicate that mtDNA replication progresses in adjacent replicons, which are collectively termed a mitochondrial replicon cluster.Abbreviations DAPI 4,6-diamidino-2-phenylindole - VIMPCS video-intensified microscope photon counting system - BrdU 5-bromodeoxyuridine - FITC fluorescein isothiocyanate     

Male gametophyte development inPlumbago zeylanica: cytoplasm localization and cell determination in the early generative cell

Summary The behavior of the generative cell during male gametophyte development inPlumbago zeylanica was examined by epifluorescence microscopy and electron microscopy with organelle nucleoid as a cytoplasm marker. When the thin sections stained with 4,6-diamidino-2-phenylindoIe (DAPI) were observed under an epifluorescence microscope, two types of fluorescence spots were detected in the cytoplasm of the pollen cells before the second mitosis. The spots emitting stronger fluorescence were confirmed as plastid nucleoids and those emitting dimmer fluorescence were mitochondrial nucleoids. Before the first mitosis, both plastid and mitochondrial nucleoids distributed randomly in the cytoplasm of the microspore. A small lenticular generative cell formed with attachment to the interior of the intine after the mitosis. Small vacuoles were found in the lenticular cell. In the cytoplasm of the lenticular cell, both plastid nucleoids and the small vacuoles were distributed randomly at the very beginning but began to migrate in opposite directions immediately. Plastid nucleoids aggregated to the side of the cell that faces the pollen center and the small vacuoles aggregated to the side of the cell that attaches to the inline. As the result, the lenticular generative cell appeared highly polarized in cytoplasm location soon after the first mitosis. In accordance with the definition of the cytoplasm polarization, the primary wall between the generative and the vegetative cells began to flex and the lenticular generative cell started to protrude towards the pollen center. When the generative cell peeled away from the inline, it was spherical in shape with the pole that aggregated plastids towards the vegetative nucleus. But the cell direction appeared to be transformed immediately. The pole that aggregated small vacuoles turned to the position towards the vegetative nucleus and the pole that aggregated plastid nucleoids turned to the position countering to the vegetative nucleus. A cellular protuberance formed at the edge of the pole that aggregated small vacuoles and elongated into a tapered end that got into contact with the vegetative nucleus. The polarization of the cytoplasm kept constant throughout the second mitosis. The small vacuoles that apportioned to the sperm cell which attached the vegetative nucleus (the leading sperm cell) disappeared during sperm cell maturation. Plastid nucleoids were apportioned to the other sperm cell (the trailing sperm cell) completely. Mitochondrial nucleoids became undetectable after the second mitosis.     

Synthesized esters of ferulic acid induce release of cytochrome c from rat testes mitochondria

Ferulic acid plays a chemopreventive role in cancer by inducing tumor cells apoptosis. As mitochondria play a key role in the induction of apoptosis in many cells types, here we investigate the mitochondrial permeability transition (MPT) and the release of cytochrome c induced by ferulic acid and its esters in rat testes mitochondria, in TM-3 and MLTC-1 cells. While ferulic acid, but not its esters, induced MPT and cytochrome c release in rat testes isolated mitochondria, in TM-3 cells we found that both ferulic acid and its esters induced cytochrome c release from mitochondria in a dose-dependent manner, suggesting a potential target of these compounds in the induction of cell apoptosis. The apoptosis induced by ferulic acid is therefore associated with the mitochondrial pathway involving cytochrome c release and caspase-3 activation. Cione and Tucci have equally contributed to this article.