Oxidative and phosphorylative activity of mitochondria from pea cotyledons during maturation of the seed

Summary The respiration rate and the activity of some mitochondrial enzymes from pea cotyledons have been followed during the final phases of seed development, when the relative water content of the cotyledons dropped from 65 to 13%. Succinate, malate and -ketoglutarate oxidase activity, and succinate and malate dehydrogenase activity per cotyledon increased when the relative water content dropped from 65 to about 55%. A further drop of the relative water content was accompanied by a strong decrease of the activity of the succinate and malate oxidase system, but only a slight decrease of succinate and malate dehydrogenase activity. Mitochondrial fractions from air-dry, mature cotyledons showed a low activity of the succinate and malate oxidase system but their dehydrogenase activity was relatively high. The phosphorylation efficiency and respiratory control gradually decreased during maturation. These results indicate that during maturation of the pea seed certain mitochondrial enzymes partly lose their activity.     

Response of the Succulent Leaves of Peperomia magnoliaefolia to Dehydration: Water Relations and Solute Movement in Chlorenchyma and Hydrenchyma

Relative water content, solute concentrations, and osmolality were determined in the water storage tissue (hydrenchyma) and the assimilatory tissue (chlorenchyma) of the succulent leaves of Peperomia magnoliaefolia (Jac) (Piperaceae) during slow desiccation. Relative water loss was significantly greater for the hydrenchyma than for the chlorenchyma. When whole leaves had lost 50% of their initial water content, the concomitant decrease of the relative water content of the hydrenchyma was 75 to 85%, but of the chlorenchyma only 15 to 25%. In spite of this differential water loss, the osmolality in both tissues increased to the same extent, indicating solute flow from the hydrenchyma to the chlorenchyma during desiccation. Solute translocation appeared to be unspecific, probably reflecting symplastic mass flow from one tissue to the other. The observed volume preservation of the chlorenchyma stabilized photosynthesis of Peperomia magnoliaefolia (Jac) leaves, which was less inhibited by a given decrease of the relative water content of the whole leaves than in nonsucculent leaves.     

The Mercury Content and Antioxidant System in Insectivorous Animals (Insectivora,Mammalia) and Rodents (Rodentia,Mammalia) of Various Ecogenesis Conditions

This study is aimed at analyzing the total mercury in the tissues of mammals adapted to a semiaquatic or subterranean lifestyle and at analyzing the possible role of their antioxidant system in heavy metal detoxication. The water shrew Neomis fodiens Pennant, 1771, European mole Talpa europaea Linnaeus, 1758, muskrat Ondatra zibethicus Linnaeus, 1766, and water vole Arvicola terrestris Linnaeus, 1758 were the species under study. Our results indicate that mercury accumulation in the tissue depends on the age, tissue type, and diet of the species. The highest mercury content was recorded in water shrew tissues compared to other species. Age-dependent accumulation of the toxicant in the animals is reported. A correlation between mercury accumulation and catalase activity in the kidneys of the animals studied was found.     

In Vivo Volume and Hemoglobin Dynamics of Human Red Blood Cells

Human red blood cells (RBCs) lose ∼30% of their volume and ∼20% of their hemoglobin (Hb) content during their ∼100-day lifespan in the bloodstream. These observations are well-documented, but the mechanisms for these volume and hemoglobin loss events are not clear. RBCs shed hemoglobin-containing vesicles during their life in the circulation, and this process is thought to dominate the changes in the RBC physical characteristics occurring during maturation. We combine theory with single-cell measurements to investigate the impact of vesiculation on the reduction in volume, Hb mass, and membrane. We show that vesicle shedding alone is sufficient to explain membrane losses but not volume or Hb losses. We use dry mass measurements of human RBCs to validate the models and to propose that additional unknown mechanisms control volume and Hb reduction and are responsible for ∼90% of the observed reduction. RBC population characteristics are used in the clinic to monitor and diagnose a wide range of conditions including malnutrition, inflammation, and cancer. Quantitative characterization of cellular maturation processes may help in the early detection of clinical conditions where maturation patterns are altered.     

Pig reticulocytes. IV. In vitro maturation of naturally occurring reticulocytes with permeability loss to glucose

Naturally occurring reticulocytes of week old piglets were used to characterize the maturation process under in vitro conditions. When the reticulocytes were suspended in tissue culture medium fortified with metabolic substrates, nearly all cells were viable after 24 hours incubation and usually more than 85% of the initial cell population survived after an 80 hour period. In cells maintained as long as a week in incubation, an adequate level of total adenine nucleotide with a large accumulation of IMP was found. In most cases, reticulocytes lose their reticular materials within two days and assume normal erythrocyte configuration. Concomitant with the morphological change, the cell volume decreases toward normal erythrocyte size, the extent of which can be accounted for by the intracellular loss of salt and accompanying water. As in the in vivo reticulocyte maturation process, reticulocytes undergoing in vitro maturation lose their membrane permeability to glucose. These findings suggest that the process of reticulocyte maturation occurring in cell culture approaches that which naturally occurs in vivo. Thus, these cells may be used to delineate the mechanism of the loss of membrane transport of glucose which normally occurs in the adult pig cells.     

Feathers as a Tool to Assess Mercury Contamination in Gentoo Penguins: Variations at the Individual Level

Feathers have been widely used to assess mercury contamination in birds as they reflect metal concentrations accumulated between successive moult periods: they are also easy to sample and have minimum impact on the study birds. Moult is considered the major pathway for mercury excretion in seabirds. Penguins are widely believed to undergo a complete, annual moult during which they do not feed. As penguins lose all their feathers, they are expected to have a low individual-variability in feather mercury concentration as all feathers are formed simultaneously from the same somatic reserves. This assumption is central to penguin studies that use feathers to examine the annual or among-individual variation in mercury concentrations in penguins. To test this assumption, we measured the mercury concentrations in 3–5 body feathers of 52 gentoo penguins (Pygoscelis papua) breeding at Bird Island, South Georgia (54°S 38°W). Twenty-five percent of the penguins studied showed substantial within-individual variation in the amount of mercury in their feathers (Coefficient of Variation: 34.7–96.7%). This variation may be caused by differences in moult patterns among individuals within the population leading to different interpretations in the overall population. Further investigation is now needed to fully understand individual variation in penguins’ moult.     

Biophysical and Hormonal Changes Linked to Postharvest Needle Abscission in Balsam Fir

Efforts are being made to determine significant biophysical and physiological events related to postharvest needle abscission. It is known that initial postharvest average water consumption is 0.2 mL g^?1 day^?1 (based on dry shoot tissue), but gradually decreases by up to 75 %. It is hypothesized that some degree of water deficit is manifested through changes in several biophysical and hormonal factors. Parameters including needle loss, water use, relative water content, electrical capacitance, membrane injury, and xylem pressure potential were measured once every 5 days on balsam fir branches collected from a clonal orchard. In addition, needles were sampled at the beginning of the experiment and during peak needle abscission which were then subjected to endogenous hormonal analysis. Peak needle abscission occurred within 24 days. During this time water use decreased by 70 %, relative water content decreased by 23 %, capacitance decreased by 64 %, membrane injury increased by 100 %, needle break strength decreased by 50 %, and xylem pressure potential decreased fourfold. Abscisic acid increased by 32-fold and trans-zeatin riboside increased by fourfold during peak abscission compared to fresh branches. Other cytokinins, such as cis-zeatin riboside, isopentenyl adenosine, trans-zeatin-O-glucoside, and dihydrozeatin riboside all doubled during abscission. Finally, there was a 95 % decrease in indole-3-acetic acid. Observed changes in all biophysical parameters, as well as abscisic acid, could be indicative of a possible postharvest water stress or dehydration. It is possible that dehydration-induced changes in biophysical and hormonal factors trigger and/or modulate postharvest needle abscission.     

NMR studies of intracellular free calcium, free magnesium and sodium in the guinea pig reticulocyte and mature red cell

During the maturation process reticulocytes lose their intracellular organelles and undergo changes in membrane lipid composition and ion transport properties. While several reports indicate differences in the levels of magnesium, sodium and calcium in reticulocytes and erythrocytes, controversy remains concerning the actual magnitude and direction of ionic alterations during reticulocyte maturation. One problem with all of these studies is that the techniques used are invasive and are limited to measuring only the total cell ion content. We have used 31P, 23Na and 19F nuclear magnetic resonance (NMR) spectroscopy to compare the intracellular free ion and phosphometabolite levels in guinea pig reticulocytes and mature red blood cells. In contrast to a sharply decreased concentration of ATP in erythrocytes in comparison to reticulocytes, the intracellular free magnesium, measured using 31P-NMR, was increased by about 65% upon maturation (150 mumol/l cell water in reticulocytes in comparison to 250 mumol/l cell water in erythrocytes). Sizeable but opposite changes in intracellular sodium (5.5 mumol/ml cells in reticulocytes vs. 8.5 mumol/ml cells in erythrocytes) and intracellular free calcium (99 nM vs. 31 nM in reticulocytes and mature red cells, respectively) were also observed, suggesting that alterations in the kinetics of membrane ion transport systems, accompanying changes in phospholipid and cholesterol content, occur during the process of red cell maturation. However, in contrast to dog red blood cells, there was no evidence for the presence of a Na+/Ca2+ exchanger in guinea pig reticulocytes or erythrocytes.     

The effect of osmotic stress on behaviour and water content of infective larvae of Trichostrongylus colubriformis

The role of the cuticle and sheath in the water dynamics of the infective larvae of Trichostrongylus colubriformis under osmotic stress and the effect of osmotic stress on behaviour have been investigated. In hypotonic solutions larvae lose the activity response to mechanical stimulation and there was also some increase in coiling. Larvae can regulate their water content in hypotonic solutions but lose water slowly in hypertonic solutions. Removal of the sheath by exposure to sodium hypochloritc or to a ‘natural’ stimulus had little effect on the water dynamics of infective larvae. The sheath thus appears to be freely permeable to water when hydrated whereas the cuticle has a very restricted permeability.     

Mercury in the muscle tissue of fish in the Central and South Vietnam

The content of mercury has been determined in the muscle tissue of 18 fish species in rivers, lakes, and reservoirs of Central and South Vietnam. The region is characterized by lower metal concentrations than those in water bodies in temperate and northern latitudes. In 76% of samples (n = 986), the content of Hg was ≤0.5 μg Hg/g of dry (≤0.1 μg/g of wet) tissue weight. In water bodies and watercourses of tropical latitudes, interspecific variations in fish can be one of the factors responsible for a wide range of Hg variation within the same species.     

The nature of precipitates formed in the outer cell wall following fixation of leaf tissue with Gilson solution

Summary The nature of precipitates formed in the outer cell walls of leaf tissue fixed in Gilson solution, used extensively to demonstrate ectodesmata, is described. Electron-microbe X-ray analysis established that the crystalline precipitates contained both mercury and chlorine. Based on solubility in water and ethanol, birefringence and ratio of mercury to chlorine, the chemical form is probably mercurous chloride. Further treatment of the leaf tissue with potassium iodide caused the crystalline precipitate to turn black and lose birefringence when viewed with plane-polarized light. Analysis of this precipitate showed the presence of only mercury, chlorine having been lost.     

Changes in size,hydration and low molecular weight osmotic effectors during meiotic maturation of Fundulus oocytes in vivo

• 1.1. Gains in the water content of the Fundulus heteroclitus follicle account for over 90% of the total wet weight increase, and consequentially most of the size increase, associated with meiotic maturation.
• 2.2. Increases in intracellular Na⁺ and K⁺ actually exceed the accompanying increases in oocyte water, resulting in net gains in the concentration of these solutes. Changes in oocyte osmolality during maturation are mostly closely paralleled by variations in the concentration of K⁺.
• 3.3. Concentrations of various free amino acids, including taurine, remain constant or decline during maturation.
• 4.4. Taken together, these results suggest that an influx of K⁺, followed by osmotically-obliged water, is a primary cause of water uptake during oocyte maturation in F. heteroclitus.

     

Alleviation of Mercury Toxicity in Wheat by the Interaction of Mercury-Tolerant Plant Growth-Promoting Rhizobacteria

Heavy metal contamination of agricultural soils has increased along with industrialization. Mercury is a toxic heavy metal and a widespread pollutant in the ecosystem. Mercury-tolerant and plant growth-promoting rhizobacteria (PGPR) HG 1, HG 2, and HG 3 were isolated from the rhizosphere of plants growing in a mercury-contaminated site. These isolates were able to grow in the presence of mercury ranging from 10 to 200 µM in minimal medium and 25 to 500 µM in LB medium. The strains were characterized by morphological, biochemical, and plant growth-promoting traits. In the present study, these PGPR strains were analyzed for their involvement in metal stress tolerance in Triticum aestivum (wheat). Two bacterial strains, namely, Enterobacter ludwigii (HG 2) and Klebsiella pneumoniae (HG 3), showed better growth promotion of T. aestivum seedlings under metal stress. Different growth parameters like, water content and biochemical properties were analyzed in the PGPR-inoculated wheat plants under 75 µM HgCl₂. Shoot length, root length, shoot dry weight, root dry weight and relative water content (RWC) were significantly higher in inoculated plants compared to uninoculated plants under stress condition. Proline content, electrolyte leakage, and malondialdehyde content (shoots and roots) were significantly lower in inoculated plants with respect to uninoculated plants under mercury stress. Therefore, it could be assumed that all these parameters collectively improve plant growth under mercury stress conditions in the presence of PGPR. Hence, these PGPRs can serve as promising candidates for increasing plant growth and also have immense potential for bioremediation of mercury-contaminated soils.     

Analytical and experimental studies on the relationship between Na+, K+, and water uptake during volume increases associated with Fundulus oocyte maturation in vitro

Summary Oocytes of marine and estuarine teleosts often undergo pronounced volume increases during the maturation phase of development that precedes ovulation and fertilization. To examine the physiological correlates of these volume increases, prematuration follicles of the saltmarsh teleost, Fundulus heteroclitus, were cultured in vitro with a maturation-inducing steroid (17-hydroxy-20-dihydroprogesterone). Mean follicle volume rose significantly (75%) during a 40-h incubation period. Similar to the situation previously found in vivo, uptake of water by the maturing follicle was responsible for this volume increase in vitro, with the water content increasing from 62% to 78% of the total follicle mass. The follicle contents of two probable osmotic effectors-Na⁺ and K⁺-also rose, the increase in K⁺ being twice that of Na⁺. The influx of K⁺ even exceeded water uptake, resulting in a net increase in the concentration of this cation. It thus appears that the influx of these cations, in particular K⁺, is a major cause of the uptake of osmotically obligated water and subsequent volume increase experienced by maturing F. heteroclitus follicles. In a search for operant mechanisms, it was found that follicle hydration, but not maturation, was strictly dependent on external K⁺ in a concentration-dependent manner. The mechanism by which K⁺ accumulates in the follicle was insensitive to ouabain, so that a typical Na⁺, K⁺-ATPase mechanism does not appear to be involved. The ability of external K⁺ to promote follicle hydration was gradually lost during the maturation process as the oocyte dissociated from the surrounding granulosa cells in preparation for ovulation. Removal of all associated somatic cells prior to maturation prevented subsequent steroid-initiated hydration but not maturation. The results suggest that K⁺ may be translocated from surrounding granulosa cells to the oocyte via gap junctions during maturation.Abbreviations GVBD germinal vesicle breakdown     

Changes in water content and volume accompanying exsheathment of Haemonchus contortus

Davey K. G. and Rogers W. P. 1982. Changes in water content and volume accompanying exsheathment of Haemonchus contortus, International Journal for Parasitology12: 93–96. The exchange water volume was determined for ensheathed larvae, for larvae exsheathed by exposure to CO₂ and for larvae desheathed by exposure to a solution of NaOCl. Larvae exsheathed by exposure to CO₂ lose approx. 66 pl. of water while those desheathed by exposure to NaOCl lose approx. 50 pl. Larvae first desheathed by exposure to NaOCl lose a further 20 pl of water when subsequently exposed to CO₂. Volumes calculated from linear measurements of larvae demonstrate that larvae exsheathed by exposure to CO₂ lose about 69 pl of their total volume, while those desheathed by NaOCl lose about 54 pl. It is concluded that exsheathment may involve at least two parallel processes. Both processes are initiated by CO₂, while one is mimicked by exposure to NaOCl.     

Biomonitoring of mercury pollution: A case study from the Dniester River

Biomonitoring of mercury pollution of Dubasari reservoir of the Dniester River has been carried out using macrophytes, epiphytosuspensions and lichens. Macrophytes uptake mercury from water column and bottom sediments in the succession Potamogeton pectinatus L. > Myriophyllum verticillatum L. > Potamogeton perfoliatus L. > Butomus umbellatus L. These species possess the properties of bio-indicators. The mercury content in their biomass is in good positive correlation (r = 0.908–0.990) with the mercury content both in water and bottom sediments. It has been shown that the maximum mercury content in these bio-indicators is found in the area of the Rezina–Rybnitsa industrial complex that consists of two cement plants and a metallurgical one. The use of lichens as bio-indicators for the ecological state of the air in the vicinity of the investigated aquatic ecosystem and of the epiphytosuspensions precipitated on submerged macrophytes, denote the active state of the source for mercury pollution of the Dubasari reservoir.     

Functional groups of woody species in semi‐arid regions at low latitudes

In seasonally dry environments, woody species have different survival strategies. However, little is known about how environmental variables affect the phenology and water dynamics of these species. We aim to understand which variables initiate the vegetative phenophases of species in a tropical semiarid climate at 3°S latitude, where variation in photoperiod is minimal and rainfall is seasonal. We hypothesize that groups of species with similar vegetative phenologies, under similar conditions, are functionally similar in terms of water storage and use. We analyse the relationship between functional characteristics related to the acquisition and utilization of water, such as wood density, water storage capacity, water potential and vegetative phenology. The attributes were ordered by multidimensional scaling, and a multiple response permutation procedure was used to test consistency of the groups. Canonical correspondence analysis and Mantel tests were used to evaluate the phenophase response to environmental variables. We found four functional groups: (i) deciduous low wood density, which lose 75% of their leaves one month before the end of the rains; (ii) evergreen high wood density; (iii) early deciduous high wood density, which lose 75% of their leaves one month after the end of the rains; and (iv) late deciduous high wood density, which lose 75% of their leaves two months after the end of the rains. As expected, the vegetative phenodynamics of the deciduous high wood density group were mainly influenced by water availability. The evergreens did not show a correlation with rainfall. Only leaf shedding of the late deciduous, and the vegetative phenophases of the evergreens, responded to an increase in temperature and photoperiod. Bud‐break responded to increased photoperiod and soil humidity in the deciduous low wood density group. The foliar periodicity groups can be explained by the presence of species that differ mainly in their mechanisms of water acquisition and use.     

Biochemical changes occurring during final maturation of eggs of some marine and freshwater teleosts

Biochemical changes which occur during post-vitellogenic meiotic maturation of oocytes were investigated by measuring the concentrations of various phosphorus-containing fractions of the ovaries and mature eggs of four marine species with pelagic eggs, plaice, Pleuronecles platessa , cod, Gadus morhua , haddock, Melanogrammus aeglefinus , and whiting, Merlangius merlangus , and three freshwater species with demersal eggs, rainbow trout, Salmo gairdneri , pike, Esox lucius , and powan, Coregonus lavarelus . In the former group, protein phosphate was deposited at normal vertebrate levels in the ovaries during vitellogenesis but was exhausted during maturation, its decrease correlating with the uptake of water which rendered the mature egg buoyant in sea water. In plaice, phospholipid phosphate declined slightly during maturation, while inorganic phosphate increased by an amount slightly less than that which disappeared from the protein fraction. No such changes occurred on maturation in these three fractions in the freshwater species, in which little or no water uptake occurred. In plaice, the approximately five-fold increase in the water content of the oocyte was accompanied by a corresponding five-fold increase in the amount of potassium, the major inorganic cation of the oocyte. These pelagic eggs appear to be unique among the eggs of vertebrates in their high water content ( c . 92%) and in the fact that the protein phosphate is almost entirely utilized before fertilization, while, in those freshwater fishes and other oviparous vertebrates that have been examined, the egg is of much lower water content (50–70%) and most of the protein phosphate, like the other major yolk constituents, is used during embryonic growth. This utilization at such an early stage in the life cycle constitutes an extreme example of heterochrony.     

温室滴灌条件下土壤水分亏缺对番茄产量及其形成过程的影响

采用小区试验,在温室滴灌条件下研究了不同生育阶段土壤水分状况对番茄果实大小、坐果数、畸形果及产量形成过程的影响,分析了温室滴灌条件下番茄总产量与灌水量的关系.结果表明：番茄苗期适度水分亏缺（田间持水量的50%～55%）可提高坐果率,畸形果形成减少,但果实总体偏小,果实成熟主要集中在采摘后期;开花坐果期过度水分亏缺（田间持水量的65%以下）虽可促进果实成熟,但降低了坐果数,易形成小果和畸形果;采摘期水分过高（田间持水量的80%以上）或过低（田间持水量的65%以下）均可降低番茄产量,水分亏缺（田间持水量的65%以下）则使坐果数降低、畸形果增加.各水分处理对果实成熟时间无明显影响;温室番茄总产量、灌溉水利用效率与全生育期灌水总量之间均呈二次抛物线关系;当番茄土壤水分（占田间持水量的百分比）下限控制在苗期60%～65%、开花坐果期70%～75%、成熟采摘期70%～75%时,番茄畸形果形成量减少,产量及坐果率较高,可作为滴灌条件下温室番茄适宜的土壤水分控制指标.     

Macrophage--T cell interactions. I. The uptake by T cells of Fc receptors released from macrophages.

Using a rosette assay for the detection of cells carrying Fc receptors (Fc+) we have been able to show that in nylon wool (NWC), separated spleen cells from different strains of mice 12 to 18% are Fc+.Within 4 hr of culture in vitro at 37 °C, 75 to 85% of the Fc+ cells lose their Fc receptors and remain Fc receptor negative even after culture for 24 hr. However the addition of 5 to 10% syngeneic (but not allogeneic) peritoneal macrophages in the NWC, resulted in the preservation of the Fc receptors on 75 to 85% of the Fc+ cells originally present.Brief exposure of NWC which have been cultured in vitro for 4 hr (lost their Fc receptors) to supernates from 3 hr cultures of peritoneal macrophages reconstituted the fc+ cells by 75 to 85%. Only the supernates from syngeneic, but not allogeneic macrophages are active. Evidence is presented which indicates that these supernates contain Fc receptor molecules of small molecular weight. These molecules can be removed by antisera directed against the I region of the major histocompatibility complex.