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Heavy metal-induced oxidative stress in algae

Heavy metals, depending on their oxidation states, can be highly reactive and, as a consequence, toxic to most organisms. They are produced by an expanding variety of anthropogenic sources suggesting an increasingly important role for this form of pollution. The toxic effect of heavy metals appears to be related to production of reactive oxygen species (ROS) and the resulting unbalanced cellular redox status. Algae respond to heavy metals by induction of several antioxidants, including diverse enzymes such as superoxide dismutase, catalase, glutathione peroxidase and ascorbate peroxidase, and the synthesis of low molecular weight compounds such as carotenoids and glutathione. At high, or acute, levels of metal pollutants, damage to algal cells occurs because ROS levels exceed the capacity of the cell to cope. At lower, or chronic, levels algae accumulate heavy metals and can pass them on to organisms of other trophic levels such as mollusks, crustaceans, and fishes. We review here the evidence linking metal accumulation, cellular toxicity, and the generation of ROS in aquatic environments.

EFFECTS OF CADMIUM ON GROWTH AND SUPEROXIDE DISMUTASE ACTIVITY OF THE MARINE MICROALGA TETRASELMIS GRACILIS (PRASINOPHYCEAE)1

Marine planktonic algae are frequently exposed to metallic contaminants. Because heavy metals can be assimilated and accumulated by algal cells, they can then be transferred to higher trophic levels of food chains. We studied the effects of cadmium on protein production and the growth of the marine prasinophyte Tetraselmis gracilis (Kylin) Butcher. By means of toxicological assays, we estimated the LC50 of cadmium as 3.2 ppm and 1.8 ppm after 48 h and 96 h of exposure to this heavy metal, respectively. The growth curves and survival percentages of cell cultures in the presence of cadmium were determined, and a proportional reduction of both parameters with increasing metal concentrations was found. When chronically exposed to sublethal concentrations of cadmium, T. gracilis contained high levels of superoxide dismutase (SOD) activity, one of the main enzymes of the cells antioxidant defense mechanism. Under these growth conditions, total SOD activity in crude extracts was increased by 41% (at 1.5 ppm) and 107% (at 3.0 ppm). Assays of SOD activity in nondenaturing polyacrylamide gels also showed a similar induction by cadmium. These results show that cadmium has potentially toxic properties since it significantly inhibited the growth of T. gracilis at low concentrations and promoted the induction of SOD activity, suggestive of an oxidative stress state. Besides being the first report of SOD in T. gracilis, this work describes experimental evidence of SOD induction by cadmium in this species.

Different regulatory mechanisms modulate the expression of a dinoflagellate iron-superoxide dismutase.

Regulation of antioxidant enzymes is critical to control the levels of reactive oxygen species in cell compartments highly susceptible to oxidative stress. In this work, we studied the regulation of a chloroplastic iron superoxide dismutase (Fe-SOD) fromLingulodinium polyedrum (formerly Gonyaulax polyedra) under different physiological conditions. A cDNA-encoding Fe-SOD was isolated from this dinoflagellate, showing high sequence similarity to cyanobacterial, algal, and plant Fe-SODs. Under standard growth conditions, on a 12:12-h light-dark cycle,Lingulodinium polyedrum Fe-SOD exhibited a daily rhythm of activity and cellular abundance with the maximum occurring during the middle of the light phase. Northern analyses showed that this rhythmicity is not related to changes in Fe-SOD mRNA levels, indicative of translational regulation. By contrast, conditions of metal-induced oxidative stress resulted in higher levels of Fe-SOD transcripts, suggesting that transcriptional control is responsible for increased protein and activity levels. Daily (circadian) and metal-induced up-regulation of Fe-SOD expression in L. polyedrum are thus mediated by different regulatory pathways, allowing biochemically distinct changes appropriate to oxidative challenges.

Response of Superoxide Dismutase to Pollutant Metal Stress in the Marine Dinoflagellate Gonyaulax polyedra

The response of superoxide dismutase (SOD) activity in the marine dinoflagellate Gonyaulax polyedra to chronic (5.0 ppb Hg, 0.5 ppm Cd, 2.0 ppm Pb and 0.1 ppm Cu, during 30 days) and acute (10.0 ppb Hg, 1.0 ppm Cd, 5.0 ppm Pb and 0.25 ppm Cu, during 48 hours) exposure to metals was investigated. Under chronic exposure to Hg, Cd, Pb, and Cu, total SOD activity of metal-treated cells increased during the first day of exposure to plateau levels of 134, 148, 127, and 139% of control values respectively. Under acute metal exposure, SOD activity increases were of similar magnitude but much more rapid (within several hours) and of shorter duration. In addition, assays for oxidative damage to lipids revealed high levels of lipid peroxidation in cells kept in either chronic or acute exposure to metals reaching values 2-fold greater than the control group. Changes in SOD activity were dependent on the metal, its concentration, and the time of exposure. Non-denaturing polyacrylamide gels revealed induction of Fe-SOD and Mn-SOD but not Cu-Zn-SOD isoforms in cells kept under acute exposure to metals. These results suggest that oxidative stress may be an important mediator of metal toxicity in algal systems, with SOD providing antioxidant protection.

Radical Ion Generation Processes of Organic Compounds in Electrospray Ionization Mass Spectrometry

In electrospray ionization mass spectrometry (ESI-MS), charge formation is proposed to occur as a result of acid-base reactions or a coordination with metal cations. However, the increasing number of papers have reported the formation of radical ions (molecular ions) as a result of loss of one or two electrons. In this paper, we present an overview of the current literature on the balance between the formation of molecular ions and of protonated forms of organic compounds in ESI-MS. Correlations between the radical formation process and the ionization energy, calculated by molecular orbital methods or obtained by eletrochemical techniques, were applied to explain this apparently unexpected behavior. The use of high level theoretical methods especially designed to produce accurate thermochemical data is also reported.

DIURNAL FLUCTUATION OF NITRATE REDUCTASE ACTIVITY IN THE MARINE RED ALGA GRACILARIA TENUISTIPITATA (RHODOPHYTA)1

The biochemical characteristics and diurnal changes in activity of the enzyme nitrate reductase (NR; EC 1.6.6.1) from the marine red alga Gracilaria tenuistipitata var. liui Zhang et Xia are described. Different assay conditions were tested to determine the stability of NR. The crude extract of G. tenuistipitata has a NR specific activity of 10.2 U.mg−1, which is higher than the NR activities found for other algae, plants, and fungi. This NR is highly active at a slightly alkaline pH and is stable over a wide range of temperature, with an optimal activity at 20° C. The apical portions of the thallus contain 64.9 ± 6.6% of the total NR specific activity. The apparent Michaelis‐Menten (Km) constant found for KNO3 was 197 μM, and it was 95 μM for NADH. The NR from G. tenuistipitata can be included in the NADH‐specific group, because no activity was found when NADPH was used as an electron donor. In extracts of algae grown under either continuously dim light or a light‐dark cycle, the activity of NR exhibits a daily rhythm, peaking at the middle of the light phase, when activity is 30‐fold higher than during the night phase.

Biochemical composition of two red seaweed species grown on the Brazilian coast

BACKGROUND Algae species have been used as an important source of food because they are highly nutritive considering their vitamin, protein, mineral, fiber, essential fatty acid and carbohydrate contents. However, a large number of seaweeds have been poorly studied, especially Brazilian species. Two red macroalgae species from the Brazilian coast (Plocamium brasiliense and Ochtodes secundiramea) were assessed with respect to their total lipid, fatty acid, total nitrogen, protein, amino acid and total carbohydrate contents. RESULTS The total lipid contents (dry weight) were 36.3 and 35.4 g kg(-1); fatty acid contents were 9.3 and 12.1 g kg(-1); total nitrogen contents were 37.4 and 24.9 g kg(-1); protein contents were 157.2 and 101.0 g kg(-1); amino acid contents were 127.5 and 91.4 g kg(-1); and total carbohydrate contents were 520.3 and 450.7 g kg(-1) for P. brasiliense and O. secundiramea, respectively. CONCLUSION Considering these compositions, both algae species were determined to have sources of protein, essential amino acids and carbohydrates similar to the edible seaweeds Laminaria japonica and Palmaria palmata.

Acute and chronic effects of toxic metals on viability, encystment and bioluminescence in the dinoflagellate Gonyaulax polyedra

Toxicity bioassays based on survival were carried out with cells of the marine dinoflagellate Gonyaulax polyedra exposed to mercury (Hg2+ ), cadmium (Cd2+), lead (Pb2+) and copper (Cu2+). The toxicity scale of these metals found was Hg2+ > Cu2+ > Cd2+ > Pb2+. Cells exposed to metals promptly underwent encystment, which is an important strategy for surviving metal exposure. Following 48 h exposure to Cu2+, complete excystment occurred within 96 h after reinoculation of cells in fresh metal-free media, and with Pb2+ partial recovery occurred in that time. Bioluminescence was affected by the metals in a dose-dependent manner primarily by increasing the frequency of flashing, but the glow emission was also altered with acute Cu2+ and Pb2+ treatments. Several physiological processes in G. polyedra are under circadian control. Chronic exposures to metals caused no substantial alterations in the circadian rhythm of bioluminescence glow, indicating that the biological clock of this dinoflagellate is not sensitive to these metals at the concentrations tested.

A Circadian Rhythm in the Activity of Superoxide Dismutase in the Photosynthetic Alga Gonyaulax polyedra

The activity of superoxide dismutase in cell-free extracts of Gonyaulax made at different times of day and night was found to be three to four times higher during the day. This rhythm continued in cells kept in constant light, indicating that the regulation can be attributed to the cellular circadian clock.

Long-term intermittent feeding, but not caloric restriction, leads to redox imbalance, insulin receptor nitration, and glucose intolerance.

Calorie restriction is a dietary intervention known to improve redox state, glucose tolerance, and animal life span. Other interventions have been adopted as study models for caloric restriction, including nonsupplemented food restriction and intermittent, every-other-day feedings. We compared the short- and long-term effects of these interventions to ad libitum protocols and found that, although all restricted diets decrease body weight, intermittent feeding did not decrease intra-abdominal adiposity. Short-term calorie restriction and intermittent feeding presented similar results relative to glucose tolerance. Surprisingly, long-term intermittent feeding promoted glucose intolerance, without a loss in insulin receptor phosphorylation. Intermittent feeding substantially increased insulin receptor nitration in both intra-abdominal adipose tissue and muscle, a modification associated with receptor inactivation. All restricted diets enhanced nitric oxide synthase levels in the insulin-responsive adipose tissue and skeletal muscle. However, whereas calorie restriction improved tissue redox state, food restriction and intermittent feedings did not. In fact, long-term intermittent feeding resulted in largely enhanced tissue release of oxidants. Overall, our results show that restricted diets are significantly different in their effects on glucose tolerance and redox state when adopted long-term. Furthermore, we show that intermittent feeding can lead to oxidative insulin receptor inactivation and glucose intolerance.