Cell cycle arrest associated with anoxia-induced quiescence, anoxic preconditioning, and embryonic diapause in embryos of the annual killifish Austrofundulus limnaeus

Embryos of the annual killifish Austrofundulus limnaeus can enter into dormancy associated with diapause and anoxia-induced quiescence. Dormant embryos are composed primarily of cells arrested in the G(1)/G(0) phase of the cell cycle based on flow cytometry analysis of DNA content. In fact, most cells in developing embryos contain only a diploid complement of DNA, with very few cells found in the S, G(2), or M phases of the cell cycle. Diapause II embryos appear to be in a G(0)-like state with low levels of cyclin D1 and p53. However, the active form of pAKT is high during diapause II. Exposure to anoxia causes an increase in cyclin D1 and p53 expression in diapause II embryos, suggesting a possible re-entry into the cell cycle. Post-diapause II embryos exposed to anoxia or anoxic preconditioning have stable levels of cyclin D1 and stable or reduced levels of p53. The amount of pAKT is severely reduced in 12?dpd embryos exposed to anoxia or anoxic preconditioning. This study is the first to evaluate cell cycle control in embryos of A. limnaeus during embryonic diapause and in response to anoxia and builds a foundation for future research on the role of cell cycle arrest in supporting vertebrate dormancy.     

Differences in isolated mitochondria are insufficient to account for respiratory depression during diapause in artemia franciscana embryos

In response to cues signifying the approach of winter, adult Artemia franciscana produce encysted embryos that enter diapause. We show that respiration rates of diapause embryos collected from the field (Great Salt Lake, Utah) are reduced up to 92% compared with postdiapause embryos when measured under conditions of normoxia and full hydration. However, mitochondria isolated from diapause embryos exhibit rates of state 3 and state 4 respiration on pyruvate that are equivalent to those from postdiapause embryos with active metabolism; a reduction in these rates (15%-27%) is measured with succinate for two of three collection years. Respiratory control ratios for diapause mitochondria are comparable to or higher than those from postdiapause embryos. The P : O flux ratios are statistically identical. Our calculations suggest that respiration of intact, postdiapause embryos is operating close to the state 3 oxygen fluxes measured for isolated mitochondria. Cytochrome c oxidase (COX) activity is 53% lower in diapause mitochondria during one collection year; the minimal impact of this COX reduction on mitochondrial respiration appears to be due to the 31% excess COX capacity in A. franciscana mitochondria. Transmission electron micrographs of embryos reveal mitochondria that are well differentiated and structurally similar in both states. As inferred from the similar amounts of mitochondrial protein extractable, tissue contents of mitochondria in diapause and postdiapause embryos are equivalent. Thus, metabolic depression during diapause cannot be fully explained by altered properties of isolated mitochondria. Rather, mechanisms for active inhibition or substrate limitation of mitochondrial metabolism in vivo may be operative.     

Cell cycle regulation during development and dormancy in embryos of the annual killifish Austrofundulus limnaeus

Embryos of the annual killifish Austrofundulus limnaeus can enter into a state of metabolic dormancy, termed diapause, as a normal part of their development. In addition, these embryos can also survive for prolonged sojourns in the complete absence of oxygen. Dormant embryos support their metabolism using anaerobic metabolic pathways, regardless of oxygen availability. Dormancy in diapause is associated with high ATP and a positive cellular energy status, while anoxia causes a severe reduction in ATP content and large reductions in adenylate energy charge and ATP/ADP ratios. Most cells are arrested in the G₁/G₀ phase of the cell cycle during diapause and in response to oxygen deprivation. In this paper, we review what is known about the physiological and biochemical mechanisms that support metabolic dormancy in this species. We also highlight the great potential that this model holds for identifying novel therapies for human diseases such as heart attack, stroke and cancer.     

An inducible 70 kDa-class heat shock protein is constitutively expressed during early development and diapause in the annual killifish Austrofundulus limnaeus

The annual killifish Austrofundulus limnaeus inhabits ephemeral ponds in regions of northern South America, where they survive the periodic drying of their habitat as diapausing embryos. These diapausing embryos are highly resistant to a number of environmental insults such as high temperature, dehydration, anoxia, and increased salinity. Molecular chaperones are known to play a role in stabilizing protein structure and function during events of cellular stress. Relative levels of heat shock protein (Hsp)70 were measured in developing and diapausing embryos of A. limnaeus using quantitative Western blots. An inducible or embryo-specific form of Hsp70 is expressed during embryonic development in A. limnaeus and is elevated during diapause II in this species. Constitutive expression of Hsp70 during development may afford these embryos protection from environmental stresses during development more quickly than relying on the induction of a classic heat shock response.     

Cell cycle regulation during development and dormancy in embryos of the annual killifish Austrofundulus limnaeus

Embryos of the annual killifish Austrofundulus limnaeus can enter into a state of metabolic dormancy, termed diapause, as a normal part of their development. In addition, these embryos can also survive for prolonged sojourns in the complete absence of oxygen. Dormant embryos support their metabolism using anaerobic metabolic pathways, regardless of oxygen availability. Dormancy in diapause is associated with high ATP and a positive cellular energy status, while anoxia causes a severe reduction in ATP content and large reductions in adenylate energy charge and ATP/ADP ratios. Most cells are arrested in the G₁/G₀ phase of the cell cycle during diapause and in response to oxygen deprivation. In this paper, we review what is known about the physiological and biochemical mechanisms that support metabolic dormancy in this species. We also highlight the great potential that this model holds for identifying novel therapies for human diseases such as heart attack, stroke and cancer.     

Patterns of ubiquitylation and SUMOylation associated with exposure to anoxia in embryos of the annual killifish Austrofundulus limnaeus

Embryos of the annual killifish Austrofundulus limnaeus acquire extreme tolerance to anoxia during embryonic development. These embryos can survive environmental and cellular conditions that would likely result in death in the majority of vertebrate cells, despite experiencing a massive loss of ATP. It is highly likely that the initial response to anoxia must quickly alter cellular physiology to reprogram cell signaling and metabolic pathways to support anaerobiosis. Covalent protein modifications are a mechanism that can quickly act to effect large-scale changes in protein structure and function and have been suggested by others to play a key role in mammalian ischemia tolerance. Using Western blot analysis, we explored patterns of protein ubiquitylation and SUMOylation in embryos of A. limnaeus exposed to anoxia and anoxic preconditioning. Surprisingly, we report stage-specific protein ubiquitylation patterns that suggest different mechanisms for altering protein turnover in dormant and actively developing embryos that both survive long-term anoxia. Anoxic preconditioning does not appear to alter levels of ubiquitin conjugates in a unique manner. Global SUMOylation of proteins does not change in response to anoxia, but there are stage-specific changes in SUMOylation of specific protein bands. Contrary to other systems, global changes in protein SUMOylation may not be required to support long-term tolerance to anoxia in embryos of A. limnaeus. These data lead us to conclude that embryos of A. limnaeus respond to anoxia in a unique manner compared to other vertebrate models of anoxia tolerance and may provide novel mechanisms for engineering vertebrate tissues to survive long-term anoxia.     

Proton leak induced by reactive oxygen species produced during in vitro anoxia/reoxygenation in rat skeletal muscle mitochondria

Superoxide anion generation and the impairment of oxidative phosphorylation yield were studied in rat skeletal muscle mitochondria submitted to anoxia/reoxygenationk in vitro. Production of superoxide anion was detected after several cycles of anoxia/reoxygenationk. Concomitantly, a decrease of state 3 respiration and phosphorylation yield (ADP/O) were observed. The latter resulted from a proton leak. The presence of palmitic acid during anoxia/reoxygenationk cycles led to a dose-dependent inhibition of superoxide anion production together with a partial protection of the ADP/O ratio measured after anoxia/reoxygenationk. The ADP/O decrease was shown to be due to a permeability transition pore-sustained proton leak, as it was suppressed by cyclosporine A. The permeability transition pore activation was induced during anoxia/reoxygenationk by superoxide anion, as it was cancelled by the spin trap (POBN), which scavenges superoxide anion and by palmitic acid, which induces mitochondrial uncoupling. It can be proposed that the palmitic acid-induced proton leak cancels the production of superoxide anion by mitochondria during anoxia/reoxygenationk and therefore prevents the occurrence of the superoxide anion-induced permeability transition pore-mediated proton leak after anoxia/reoxygenationk.     

Effects of temperature, sorbitol, alanine and diapause hormone on the embryonic development in Bombyx mori: in vitro tests of old hypotheses

Abstract.  An in vitro culture method is described in which embryonic development in Bombyx mori is traced at various temperatures and treatments. The results show that the induction, intensification and termination of diapause are distinct processes. Prediapause embryos, explanted from 40-h-old diapause-destined eggs and cultured in Grace's medium, continue to develop to the appendage-formation stage without arrest, which indicates that the isolated embryos have not entered diapause, whereas the development of embryos from diapausing eggs (15 days after being laid) is significantly slower. The rate of development of embryos dissected from diapause eggs increases during chilling (5 °C) and incubation (at 25 °C) gradually during chilling and dramatically at 25 °C. The in vitro experiments also reveal that sorbitol directly inhibits the development of embryos explanted from diapausing eggs but has no affect on the development of embryos from prediapause eggs. Neither alanine nor diapause hormone prevent isolated embryos from developing.     

How might you compare mitochondria from different tissues and different species?

Mitochondria were isolated from the liver, kidney and mixed hindlimb skeletal muscle of three vertebrate species; the laboratory rat Rattus norvegicus, the bearded dragon lizard Pogona vitticeps, and the cane toad Bufo marinus. These vertebrate species are approximately the same body mass and have similar body temperatures. The content of cytochromes B, C, C1, and A were measured in these isolated mitochondria by oxidised–reduced difference spectra. Adenine nucleotide translocase (ANT) was measured by titration of mitochondrial respiration with carboxyactractyloside and the protein and phospholipid content of isolated mitochondria were also measured. Fatty acid composition of mitochondrial phospholipids was measured. Mitochondrial respiration was measured at 37°C under states III and IV conditions as well as during oligomycin inhibition. Species differed in the ratios of different mitochondrial cytochromes. Muscle mitochondria differed from kidney and liver mitochondria by having a higher ANT content relative to cytochrome content. Respiration rates were compared relative to a number of denominators and found to be most variable when expressed relative to mitochondrial protein content and least variable when expressed relative to mitochondrial cytochrome A and ANT content. The turnover of cytochromes was calculated and found to vary between 1 and 94 electrons s⁻¹. The molecular activity of mitochondrial cytochromes was found to be significantly positively correlated with the relative polyunsaturation of mitochondrial membrane lipids.     

Studies on energy status and mitochondrial respiration during growth and senescence of mung bean cotyledons

Several characteristics of mitochondrial respiration and energy status have been studied during growth and senescence of mung bean ( Phaseolus radiatus L.) cotyledons. The results showed that mitochondrial oxygen consumption, respiratory control, ADP:O ratios, and energy charge changed in the cotyledons during germination and growth of the seedlings. The respiration rate of intact cotyledons approximately reflected the trend of the oxidative activities of the isolated mitochondria. An increase was observed in both whole cotyledon respiration and mitochondrial oxygen uptake at the onset of senescence of mung bean cotyledons (day 3 after germination), which thereafter declined gradually. The capacity and activity of the alternative pathway increased markedly in mitochondria isolated from senescent cotyledons. After the onset of senescence, the mung bean cotyledon mitochondria exhibited a decrease both in the respiratory control ratios and ADP:O ratios, and the cotyledons exhibited a gradual decline in energy charge. All these results showed an irreversible deterioration of energy conservation in mung bean cotyledons. The role(s) of the alternative pathway in senescent mung bean cotyledons is discussed.     

Hybridization increases mitochondrial production of reactive oxygen species in sunfish

Mitochondrial dysfunction and oxidative stress have been suggested to be possible mechanisms underlying hybrid breakdown, as a result of mito‐nuclear incompatibilities in respiratory complexes of the electron transport system. However, it remains unclear whether hybridization increases the production of reactive oxygen species (ROS) by mitochondria. We used high‐resolution respirometry and fluorometry on isolated liver mitochondria to examine mitochondrial physiology and ROS emission in naturally occurring hybrids of pumpkinseed (Lepomis gibbosus) and bluegill (L. macrochirus). ROS emission was greater in hybrids than in both parent species when respiration was supported by complex I (but not complex II) substrates, and was associated with increases in lipid peroxidation. However, respiratory capacities for oxidative phosphorylation, phosphorylation efficiency, and O₂ kinetics in hybrids were intermediate between those in parental species. Flux control ratios of capacities for electron transport (measured in uncoupled mitochondria) relative to oxidative phosphorylation suggested that the limiting influence of the phosphorylation system is reduced in hybrids. This likely helped offset impairments in electron transport capacity and complex III activity, but contributed to augmenting ROS production. Therefore, hybridization can increase mitochondrial ROS production, in support of previous suggestions that mitochondrial dysfunction can induce oxidative stress and thus contribute to hybrid breakdown.     

Oxidative phosphorylation of liver mitochondria from mice acclimatized to hypobaric hypoxia

Mice exposed to intermittent hypobaric hypoxia for 20 hours a day, 6 days a week, develop extracellular adaptive responses similar to those found in humans exposed to oxygen tension equivalent to that found at an altitude of 4500 m. Isolated liver mitochondria from these animals show no significant differences in rates of substrate-stimulated respiration, ADP-stimulated respiration and the respiratory control ratio (RCR), when compared with sea level controls. Undetectable or negligible differences in these parameters are also noted when sea level animals are exposed for one hour to severe hypoxia (7% O₂). We therefore conclude that the oxidative phosphorylation capacity of the isolated mouse liver mitochondria remains unaltered in both acute and chronic hypoxia. However thein vivo oxygen consumption by mice at this degree of hypoxia was markedly reduced. Lack of observable changes in oxidative phosphorylation could be accounted for by extracellular adaptations in mitochondria isolated from acclimatized animals. This explanation, however, is not consistent with the lack of changes on oxidative phosphorylation in mitochondria isolated from mice undergoing acute hypoxia at sea level. It is then suggested that isolated mitochondrial preparations are of limited value for investigating biochemical mechanisms underlying the variation of cellular respiration occurringin vivo.     

Depression of protein synthesis during diapause in embryos of the annual killifish Austrofundulus limnaeus

Rates of protein synthesis are substantially depressed in diapause II embryos of Austrofundulus limnaeus. Inhibition of oxygen consumption and heat dissipation with cycloheximide indicates that 36% of the adenosine triphosphate (ATP) turnover in prediapausing embryos (8 d postfertilization [dpf]) is caused by protein synthesis; the contribution of protein synthesis to ATP turnover in diapause II embryos is negligible. In agreement with the metabolic data, incorporation of amino acids (radiolabeled via (14)CO(2)) into perchloric acid-precipitable protein decreases by over 93% in diapause II embryos compared with embryos at 8 dpf. This result represents a 36% reduction in energy demand because of depression of protein synthesis during diapause. Adjusting for changes in the specific radioactivity of the free amino acid pool at the whole-embryo level yields rates of protein synthesis that are artifactually high and not supportable by the observed rates of oxygen consumption and heat dissipation during diapause. This result indicates a regionalized distribution of labeled amino acids likely dictated by a pattern of anterior to posterior cell cycle arrest. AMP/ATP ratios are strongly correlated with the decrease in rates of protein synthesis, which suggests a role for adenosine monophosphate (AMP) in the control of anabolic processes. The major depression of protein synthesis during diapause II affords a considerable reduction in energy demand and extends the duration of dormancy attainable in these embryos.     

Developmental and metabolic changes induced by anoxia in diapausing and non-diapausing flesh fly pupae

Summary Anaerobic metabolism was compared in nondiapausing (ND) and diapausing (D) pupae of the flesh fly,Sarcophage crassipalpis using in vivo¹³C NMR spectroscopy. Anoxia-induced changes in the development of ND and D pupae were correlated with oxidative metabolism and mitochondrial integrity. ND pupae tolerated 1 day of anoxia without any obvious developmental effect, while D pupae tolerated up to 6 days of anoxia. Longer exposure to anoxia (3 days in ND pupae and up to 14 days in D pupae) allowed development to the pharate adult stage but precluded eclosion. Four-day anoxia applied to ND pupae during 4–6 days post-pupariation arrested development in a stage indistinguishable from diapause. This morphological stasis was accompanied by 80% suppression of oxidative metabolism and a 100% increase in glycerol concentration. However, unlike a true diapause, this arrest could not be terminated with 20-hydroxyecdysone or hexane. Four-day anoxia treatment applied to D pupae stimulated development and raised their oxygen consumption. The anoxia-induced changes in oxidative metabolism were not accompanied by mitochondrial changes. Exposure to 95%PO₂ atmosphere had no apparent developmental or metabolic effects on ND or D pupae. Major metabolites (lipids, trehalose, glycogen, glycerol, glutamine, and alanine) were detected in the ND and D pupae but their rates of turnover differed. Anoxia induced synthesis of glycerol and alanine in both D and ND pupae. Injected labeled glucose was incorporated primarily into trehalose and glycogen by both D and ND pupae. The rate of incorporation in ND pupae was approximately twice that observed in D pupae. Anoxia resulted in glycerol and alanine synthesis in both groups of pupae, but more glycerol was labeled in ND pupae and more alanine in D pupae. Glycogen and trehalose were depleted in the D pupae under anoxia. Cold acclimation had no effect on the steady-state or rate of synthesis of metabolites.     

The African turquoise killifish: A research organism to study vertebrate aging and diapause

The African turquoise killifish has recently gained significant traction as a new research organism in the aging field. Our understanding of aging has strongly benefited from canonical research organisms—yeast, C. elegans, Drosophila, zebrafish, and mice. Many characteristics that are essential to understand aging—for example, the adaptive immune system or the hypothalamo‐pituitary axis—are only present in vertebrates (zebrafish and mice). However, zebrafish and mice live more than 3 years and their relatively long lifespans are not compatible with high‐throughput studies. Therefore, the turquoise killifish, a vertebrate with a naturally compressed lifespan of only 4–6 months, fills an essential gap to understand aging. With a recently developed genomic and genetic toolkit, the turquoise killifish not only provides practical advantages for lifespan and longitudinal experiments, but also allows more systematic characterizations of the interplay between genetics and environment during vertebrate aging. Interestingly, the turquoise killifish can also enter a long‐term dormant state during development called diapause. Killifish embryos in diapause already have some organs and tissues, and they can last in this state for years, exhibiting exceptional resistance to stress and to damages due to the passage of time. Understanding the diapause state could give new insights into strategies to prevent the damage caused by aging and to better preserve organs, tissues, and cells. Thus, the African turquoise killifish brings two interesting aspects to the aging field—a compressed lifespan and a long‐term resistant diapause state, both of which should spark new discoveries in the field.     

Characterization of the respiratory activity of mitochondria isolated from an insect cell line CP-1268Laspeyresia pomonella

Summary Mitochondria have been isolated from the codling mothLaspeyresia pomonella, CP-1268 cell line. The mitochondrial fraction was isolated from pooled 4 d, exponential growth phase, cultures. The mitochondria were determined to be intact based on the demonstration of respiratory control, the effects of 2,4 dinitrophenol and oligomycin on respiration, the inability to oxidize NADH, and the inability of cytochromec to enhance respiration. The isolated mitochondria were able to oxidize succinate, pyruvate, malate, α-ketoglutarate, and α-glycerophosphate efficiently. Of the substrates tested, the CP-1268 mitochondria oxidized succinate most efficiently. The respiratory control ratios ranged from a high of 4.6 for pyruvate to a low of 1.7 with α-glycerophosphate. These findings confirm that the mitochondria were tightly coupled. The data also confirm the presence of three sites of oxidative phosphorylation because NAD-linked substrates had ADP-to-O ratios approaching 3 and flavoprotein linked substrates had values approaching 2.     

Low hydrogen peroxide production in mitochondria of the long‐lived Arctica islandica: underlying mechanisms for slow aging

The observation of an inverse relationship between lifespan and mitochondrial H₂O₂ production rate would represent strong evidence for the disputed oxidative stress theory of aging. Studies on this subject using invertebrates are surprisingly lacking, despite their significance in both taxonomic richness and biomass. Bivalve mollusks represent an interesting taxonomic group to challenge this relationship. They are exposed to environmental constraints such as microbial H₂S, anoxia/reoxygenation, and temperature variations known to elicit oxidative stress. Their mitochondrial electron transport system is also connected to an alternative oxidase that might improve their ability to modulate reactive oxygen species (ROS) yield. Here, we compared H₂O₂ production rates in isolated mantle mitochondria between the longest‐living metazoan—the bivalve Arctica islandica—and two taxonomically related species of comparable size. In an attempt to test mechanisms previously proposed to account for a reduction of ROS production in long‐lived species, we compared oxygen consumption of isolated mitochondria and enzymatic activity of different complexes of the electron transport system in the two species with the greatest difference in longevity. We found that A. islandica mitochondria produced significantly less H₂O₂ than those of the two short‐lived species in nearly all conditions of mitochondrial respiration tested, including forward, reverse, and convergent electron flow. Alternative oxidase activity does not seem to explain these differences. However, our data suggest that reduced complex I and III activity can contribute to the lower ROS production of A. islandica mitochondria, in accordance with previous studies. We further propose that a lower complex II activity could also be involved.     

The proton leak across the mitochondrial inner membrane

The proton conductance of the mitochondrial inner membrane increases at high protonmotive force in isolated mitochondria and in mitochondria in situ in rat hepatocytes. Quantitative analysis of its importance shows that about 20-30% of the oxygen consumption by resting hepatocytes is used to drive a heat-producing cycle of proton pumping by the respiratory chain and proton leak back to the matrix. The flux control coefficient of the proton leak pathway over respiration rate varies between 0.9 and zero in mitochondria depending on the rate of respiration, and has a value of about 0.2 in hepatocytes. Changes in the proton leak pathway in situ will therefore change respiration rate. Mitochondria isolated from hypothyroid animals have decreased proton leak pathway, causing slower state 4 respiration rates. Hepatocytes from hypothyroid rats also have decreased proton leak pathway, and this accounts for about 30% of the decrease in hepatocyte respiration rate. Mitochondrial proton leak may be a significant contributor to standard metabolic rate in vivo.     

疲劳性运动中线粒体电子漏引起质子漏增加

以大鼠递增强度力竭性竭性跑台运动为疲劳运动模型,观察了运动后大鼠骨骼肌线粒体电子漏和质子漏的变化。结果表明,运动性疲劳状态下大鼠骨骼肌线粒体超氧阴离子生成增加,脂质过氧线粒体质子漏增多是氧化磷酸化偶联程度下降的重要因素。实验结果支持电子漏引起质子漏的假说。     

Changes in the mitochondrial proteome of developing maize seed embryos

Mitochondria are required for seed development, but little information is available about their function and role during this process. We isolated the mitochondria from developing maize (Zea mays L. cv. Nongda 108) embryos and investigated the mitochondrial membrane integrity and respiration as well as the mitochondrial proteome using two proteomic methods, the two‐dimensional gel electrophoresis (2‐DE) and sequential windowed acquisition of all theoretical fragment ion mass spectra (SWATH). Mitochondrial membrane integrity and respiration were maintained at a high level up to 21 days after pollination (DAP) and decreased thereafter, while total mitochondrial number, cytochrome c oxidase activity and respiration per embryo exhibited a bell‐shaped change with peaks at 35–45 DAP. A total of 286 mitochondrial proteins changed in abundance during embryo development. During early stages of seed development (up to 21 DAP), proteins involved in energy production, basic metabolism, protein import and folding as well as removal of reactive oxygen species dominated, while during mid or late stages (35–70 DAP), some stress‐ and detoxification‐related proteins increased in abundance. Our study, for the first time, depicted a relatively comprehensive map of energy production by mitochondria during embryo development. The results revealed that mitochondria were very active during the early stages of maize embryo development, while at the late stages of development, the mitochondria became more quiescent, but well‐protected, presumably to ensure that the embryo passes through maturation, drying and long‐term storage. These results advance our understanding of seed development at the organelle level.