Energy Metabolism in Rhizomes of Acorus calamus (L.) and in Tubers of Solanum tuberosum (L.) With Regard to their Anoxia Tolerance

Rhizomes of the marsh plant Acorus calamus (L.) and tubers of the flooding-intolerant Solanum tuberosum (L.) var. Bintje, both kept under strict anoxia, differ markedly in their fermentation properties. The fermentation capacities as measured by ADH and LDH activities and their respective product concentrations were estimated. While rhizomes of Acorus calamus, having high ADH and low LDH activities, accumulate mainly ethanol, tubers of Solanum tuberosum tend towards lactic acid fermentation. The total amount of adenine nucleotides is quite stable in Acorus calamus, whereas they show a sharp decline in S. tuberosum during the first 6h of anoxia. The adenylate energy charge of A. calamus recovers after a short initial drop (AEC > 0.8). AEC values of S. tuberosum decrease rapidly and remain at very low values (AEC ～ 0.3). Tuber tissues became soft and lost viability after about 48–72 h of anoxia at 25 °C. This might be due to tissue acidification and impaired energy metabolism, but not to the lack of energy reserves. Energy metabolism of A. calamus is well adapted to anoxia.     

Reduction in hypoxia-reoxygenation-induced myocardial mitochondrial damage with exogenous methane

Albeit previous experiments suggest potential anti-inflammatory effect of exogenous methane (CH₄) in various organs, the mechanism of its bioactivity is not entirely understood. We aimed to investigate the potential mitochondrial effects and the underlying mechanisms of CH₄ in rat cardiomyocytes and mitochondria under simulated ischaemia/reperfusion (sI/R) conditions. Three-day-old cultured cardiomyocytes were treated with 2.2% CH₄-artificial air mixture during 2-hour-long reoxygenation following 4-hour-long anoxia (sI/R and sI/R + CH₄, n = 6-6), with normoxic groups serving as controls (SH and SH + CH₄; n = 6-6). Mitochondrial functions were investigated with high-resolution respirometry, and mitochondrial membrane injury was detected by cytochrome c release and apoptotic characteristics by using TUNEL staining. CH₄ admixture had no effect on complex II (CII)-linked respiration under normoxia but significantly decreased the complex I (CI)-linked oxygen consumption. Nevertheless, addition of CH₄ in the sI/R + CH4 group significantly reduced the respiratory activity of CII in contrast to CI and the CH₄ treatment diminished mitochondrial H₂O₂ production. Substrate-induced changes to membrane potential were partially preserved by CH₄, and additionally, cytochrome c release and apoptosis of cardiomyocytes were reduced in the CH₄-treated group. In conclusion, the addition of CH₄ decreases mitochondrial ROS generation via blockade of electron transport at CI and reduces anoxia-reoxygenation-induced mitochondrial dysfunction and cardiomyocyte injury in vitro.     

Sensing soil oxygen

Abstract. Under natural conditions where gaseous exchange between soil and atmosphere is restricted by excess water, the concentration of O₂ in the rooting zone can become very low while reduced ions and organic compounds that are potentially phytoxic may accumulate. Mechanisms by which shoots and roots detect, and adjust to, this O₂-deficient environment are reviewed. Injury to roots and their inability to function because of insufficient O₂ is communicated to the shoot in a variety of ways, so that it adjusts physiologically. Roots may acclimate metabolically to a gradual fall in O₂ supply, so that they either improve their tolerance of anoxia, or partially avoid O₂-deficiency by structural changes that aid internal transfer of O₂ to the roots from the shoot. Molecular mechanisms regulating such metabolic changes, including environmental cues, are discussed.     

Plant Anaerobic Stress as a Novel Trend in Ecological Physiology,Biochemistry, and Molecular Biology: 1. Establishment of a New Scientific Discipline

This review attempted to follow the establishment of a novel branch of biology arisen at the interfaces between plant physiology, biochemistry, and molecular biology—plant anaerobic stress. Most attention was given to the early period of these investigations, the activity of the members of International Society for Plant Anaerobiosis in particular, and the contribution of Russian scientists, who played a significant role at that time in the establishment and international recognition of this new trend. In this connection, the following points are considered: (1) Crawford's metabolic theory, which could not withstand experimental verification but induced an active discussion, thus stimulating further investigations in this field; (2) a concept of two main strategies of plant adaptation to anaerobic stress (true and apparent adaptation), which was put forward based on the following experimental data: (a) a discovery of a paradoxical phenomenon of hyper-sensitivity, but not hyper-resistance to anoxia, of the flood-tolerant plant roots (“apparent” tolerance); (b) the elucidation of the physiological role of oxygen transported from aerated organs of flood-tolerant plants to the roots inhabiting anaerobic environment; (c) demonstration of the key role of both energy metabolism, and (d) substrate providing for glycolysis and ethanolic fermentation in plants manifesting “true” tolerance to oxygen deprivation; (3) the discovery of plant stress proteins; and finally (4) pH-stat theory put forward by Davies.     

Late Wenlock (Middle Silurian) global Bioevent: Possible chemical cause for mass graptolite mortalities

Graptolites nearly became extinct in the latest Wenlock in all preserved stratigraphic sequences of this age. Graptolite mortalities occurred along the western coast of Laurentia and at sites that surrounded the Proto‐Tethys. Graptolite mass mortalities took place among deep‐water, open ocean dwelling organisms. After the mass mortalities, only the Pristiograptus dubius group and retiolids surface or near‐surface dwellers, survived. For a period of time, little speciation or diversification occurred. The base of the Ludlow is marked by diversification, with appearances of S. colonus, M. nilssoni and other groups which occur in near surface waters. None of the extensive plate movements postulated for the Silurian readily explain the mass extinctions that occurred. During the Silurian, global temperatures were warmer than present and atmospheric oxygen concentrations were lower, creating extensive oceanic anoxia. Below the oxygenated surface layers of the ocean, was an anoxic, non‐sulfidic zone (i.e. nitrate‐reducing) above a sulfidic zone. Graptolites lived over a range of depth from the oxygenated zone to either near or in the nitrate‐reducing zones. As the oxygen concentration declined through the Silurian, the depth of the oxic zone would have become shoaler with expanding anoxia. Late Wenlock graptolites that were unable to migrate to shallower depths, living in borderline oxygen conditions, could have been killed, resulting in the mortalities of the late Wenlock. Only those graptolites that were surface dwellers survived, adapted and reradiated.     

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.