Electronic Journal of Biotechnology Universidad Católica de Valparaíso ISSN: 0717-3458 Vol. 7, Num. 3, 2004, pp. 305-312

Electronic Journal of Biotechnology, Vol. 7, No.3, December, 2004, pp. 302-309

RESEARCH ARTICLE

The ubiquity of heavy metals in the biosphere results in the introduction of high amounts of toxic metals into the food chain from various sources. In the present study, one of the strongest nitrogen fixing cyanobacterium of the rice fields, Aulosira fertilissima, was subjected to nickel and chromium stress and the ameliorating effect of immobilization was investigated. Cell immobilization could protect the organism's growth against the toxicity of both heavy metals at LC₅₀ as compared to lethal concentrations. The nitrate reductase activity in free cells treated with the metals was substantially inhibited but immobilized cells treated with 0.1 ppm nickel was not affected by the metal treatment. Cell immobilization also resulted in a significant protection against sub-lethal concentration of chromium but to a lesser degree than it did with sub- lethal levels of nickel. Control immobilized cells also had higher Nitrogenase activity than control free cells. Nickel and chromium addition markedly decreased the enzyme activity in free cells but immobilized cells exposed to sublethal concentrations of both metals could overcome this decrease. Glutamine synthetase showed similar response under immobilized conditions compared to free cells with both metals. The addition of algal filtrate in 3:1 ratio further increased the nitrogenase activity compared with immobilized cells treated with sublethal doses of both metals. Immobilization facilitated higher uptake of nickel as compared to chromium. The observations of the present study clearly demonstrate the protective effect of immobilization on Aulosira fertilissima against Nickel and chromium toxicity. Rice field ecosystem thus possess a bidirectional natural metal ameliorating system where Aulosira mats act as a naturally immobilized system and the decay of Aulosira along with other cyanobacteria act as natural chelators protecting the rice plants from deleterious effects of the heavy metals. Most importantly is that the immobilization process protects the cyanobacterial nitrogen fixing process allowing it to maintain nitrogen economy of the fields in spite of the presence of heavy metals.

Keywords: Aulosira, chromium, immobilization, nickel, toxicity

Heavy metals are ubiquitous in the biosphere where they occur as part of the natural constituents of chemicals to which biota and human beings are frequently exposed. This results in introduction of substantial amounts of potentially toxic metals into the food chain. Microorganisms form a group of inseparable interacting communities, which are subjected to such unfavourable alteration of the aquatic and other ecosystems. Cyanobacteria, a group of prokaryotic, photosynthetic nitrogen fixers are present in every ecological niche and therefore, exposed to the toxic effects of the metals. The effects of a few metals have been studied with respect to growth, nitrogenase activity and carbon fixation, (Ting et al.1990; Cano et al. 1993; Gambrell, 1994; Blackwell et al. 1995; Chuan and Liu, 1996; James, 1996; Bohme, 1998; Kimbrough et al. 1999; Zaccaro et al. 1999; Barman et al. 2000; Kisku et al. 2000; Kotas and Stasicka, 2000; Suresh Babu et al. 2000; Armienta et al. 2001; Epniewska and Bucior, 2001; Suresh Babu et al. 2001). What has not been attempted is the study of naturally immobilized cyanobacteria such as Aulosira fertilissima, in ameliorating toxicity using similar immobilized conditions in the laboratory. This paper discusses the role of immobilization in ameliorating nickel and chromium toxicity on the enzymes of the nitrogen assimilating pathway in treated and non-treated cells and under free cell conditions. Additional role of algal filtrate has also been studied and compared to immobilized cells for their potential to mitigate the toxicity of the metals.

Incubation and maintenance of culture

Aulosira fertilissima was obtained from Indian Agriculture Research Institute, New Delhi, India and was cultured in Fogg's (N^-) medium (1949). The cultures were kept in an air-conditioned culture room, which was illuminated by three 40W fluorescent tubes at a distance of 50 cm for 12 hrs daily. The cultures received 2500- 3000 Lux light intensity and a temperature of 27 ± 2ºC.

Immobilization procedure

Algal cultures were agitated vigorously with sterilized glass beads in test tubes, to disrupt the clumps formed. The separated algal filaments were harvested by centrifugation. Immobilization was done by the cell entrapment method using calcium alginate as described by Singh et al. 1989. The beads thus formed were washed with doubled distilled water and suspended in culture media containing different concentrations of metal solutions. A control-immobilized sample was also taken in which none of the heavy metals were added. Similarly, the free cell suspension of Aulosira fertilissima was also subjected to heavy metal treatment. LC₅₀ values of the organisms for nickel and chromium were determined by standard plate count method with an exposure time to the metals equivalent to the generation (doubling) time of the organism i.e. 65 hrs. Sub lethal concentrations of nickel and chromium were used in all further experiments.

Metal solution

Nickel and chromium solutions with different concentrations were prepared by dissolving NiCl₂.6H₂O and K₂Cr₂O₇ in double distilled water and were filtered with 0.45 μ Millipore filter before adding to the medium.

Growth measurement

Growthexperiment was carried out in culture tubes each containing 10 ml basal medium.The growth was measured by Chlorophyll extraction. Chlorophyll was extracted in 10 ml of either 100% methanol or 80% acetone. The tubes were shaken for 5 min and then placed overnight in dark, in a refrigerator so as to ensure complete extraction. The optical density of the extract was measured with a Systronic 169 spectrophotometer at 663 nm. The amount of Chlorophyll extracted was calculated according to the equation of Mackinney, 1941.

Chlorophyll µg/ml = optical density x 12.63 x dilution factor

The generation time was calculated by growth equation of Kratz and Myers, 1955.

Where, N₁= Initial OD / Protein concentration at time T₁, and N₂ = Final OD/ Protein concentration at time T₂.

Nitrate reductase measurement

Glutamine synthetase measurement

Estimation of Glutamine synthetase activity was done by γ- glutamyl transferase as described by Shapiro and Stadman, 1970, modified by Stacey et al. 1977. A standard of different concentration of glutamyl hydroxamate was prepared and optical density was read at 540 nm. The transferase activity was calculated as µ mole g - glutamyl hydroxamate µg^-1 Chl ah^-1.

Nitrogenase measurement

Nitrogenase activity was measured by Acetylene Reduction Assay given by Stewart et al. 1968. Aliquots (2 ml) of exponentially growing cultures were placed in 8 ml vacutainer tubes and sealed with washed serum stoppers. 10% acetylene gas was injected into the tubes. Reaction was run for 60 min at 28ºC and 2500 Lux. The reaction was terminated by injecting 0.2 ml of 2N NaOH. The ethylene produced was analyzed in a Gas Liquid Chromatograph fitted with a Porapak R. column and a hydrogen flame ionization detector. Nitrogenase activity was expressed in terms of n moles C₂H₄µg^-1 Chl ah^-1

Metal uptake studies

The uptake of nickel and chromium was under-taken in an Atomic Absorption Spectrophotometer Model 2380 Perkin Elmer and expressed in mgl^-1 by the method described by Singh et al. 1989. The result has been calculated by the difference observed in the concentration of both metals comparing the initial value (mgl^-1) added in culture medium containing the cyanobacterium/immobilized beads and the value (mgl^-1) remaining in the medium after 8 days.

Toxicity mitigating studies

The amelioration of heavy metal toxicity was studied with algal filtrate. The algal filtrate was prepared by centrifuging two months old cultures of Aulosira fertilissima. This filtrate was added in different ratios to the medium, i.e. 25:75, 50:50, 75:25 and 100. Best results were obtained in 75:25 ratio and therefore shown in this study.

Comparative studies between immobilized and free cells were made with 9 alginate beads containing the algal cells and 2 ml of free cells in culture media. The beads were made in such a way that 9 of them and 2 ml of free suspended cells contained the same amount of Chlorophyll a (0.12 mg) at 0 hour.

The growth of Aulosira fertilissima was significantly inhibited with the increasing concentrations of the heavy metals. LC₅₀ value of the organism for nickel was found to be 0.1 ppm and that of chromium was 20 ppm after exposure to the metals for a period equivalent to the generation time of the cyanobacterium. After the eighth day of inoculation, immobilized control cultures showed 63% increase in growth over free control cells. Further, it was observed that immobilization has significant protective effect on growth against the toxicity of the heavy metals at sub- lethal concentrations of both metals (Figure 1 and Figure 2). Immobilization restored growth of Aulosira fertilissima as compared to free cells under 0.1 ppm nickel treatment. This was followed by immobilized cell treated with 20 ppm chromium (5% increase). No significant protection to growth was obtained by immobilization with lethal concentration of the metals i.e. 1 ppm of nickel and 40 ppm of chromium.

Nitrate reductase activity of free and immobilized cells was also studied (Figure 3 and Figure 4). The enzyme activity in free cells treated with nickel and chromium was substantially inhibited. Immobilization enabled Aulosira fertilissima to not only overcome the toxicity but also to enhance nitrate reductase activity when exposed to 0.1 ppm nickel. The protection however was less in sublethal concentrations of chromium treated cells. In contrast, no restoration of the enzyme activity was noted due to immobilization when Aulosira fertilissima was treated with lethal concentrations of both nickel and chromium.

Nitrogenase activity in Aulosira fertilissima with and without nickel and chromium in free and immobilized cells gave some interesting results (Figure 5). Nitrogenase activity was higher in control immobilized cells than in control free cells. Although, the activity with nickel and chromium markedly decreased in heavy metal- treated free cells, this decrease was overcome in the treated immobilized cells, and the activity was similar to the control immobilized cells. Table 1 reveals the percentage increase in nitrogenase activity in immobilized cells in comparison to free cells.

Very similar observations where obtained when glutamine synthetase activity was studied in which immobilization was found to have a protective effect against metal toxicity compared to free cells especially under sublethal conditions, (Figure 6).

Table 2 shows the percentage increase in glutamine synthetase activity in immobilized cells in comparison to free cells.

Aulosira is known for its high rates of nitrogen fixation in rice fields and therefore nitrogenase activity was also studied in the presence of metals, under immobilized conditions and free cells along with algal filtrate in the ratio of 3:1 (Figure 7). The results show that addition of algal filtrate could enhance nitrogenase activity even more than what was observed with immobilized cells treated with 0.1 ppm nickel. This enhancement was much higher than the control free cells. In chromium treated cells, addition of algal filtrate also further enhanced the enzyme activity but it was less than with nickel.

Table 3 shows the percentage increase in nitrogenase activity in free cells treated with 3:1 algal filtrate in comparison to control free cells.

Uptake studies of metals showed higher uptake of both metals by immobilization (Figure 8 and Table 4).

Nickel was taken up at higher rates than chromium in Aulosira fertilissima.

The observations in the present study clearly indicate a protective effect of immobilization on Aulosira fertilissima against nickel and chromium toxicity. The mechanism of toxicity of metals to cyanobacteria are not fully known but several heavy metals retard the flow of electrons in electron transfer reaction in mitochondria and chloroplast and thus can be expected to have a detrimental effect on respiration, photosynthesis and other processes related to it. The observed protection due to calcium alginate immobilization on Chlorophyll a content, nitrate reductase activity, nitrogenase and glutamine synthetase at 20 ppm of chromium and 0.1 ppm of nickel could be due to the metal binding capacity of alginate. Alginate, which is a mixture of polyguluronic acid and polymannuronic acid, has abundant hydroxyl groups which bind the metal ions and prevent them from entering the cells in full concentration thereby protecting against the decrease of Chlorophyll a content and enzyme activities as observed in free cells. Banerjee and Mishra, 2002 have also shown the mitigating effect of immobilization on cyanobacteria subjected to heavy metal stress.

Basically, immobilization brings about increase in growth by producing direct contact between cell and medium, thus increasing the surface area available for various cellular reactions. On the other hand, the increase in nitrate reductase activity maybe due to change in the cellular behavior by directly modifying the intrinsic characteristics of the culture as beads by forming a monolayer on the surface of the culture medium thus increasing not only surface area but also increasing availability of other important environmental parameters like light and oxygen concentration,(Banerjee and Mishra, 2002; Marsac and Houmard, 1993).

The increase in nitrate reductase, nitrogenase and glutamine synthetase activity in nickel treated cells might be due to increase in surface area of thylakoids, thereby increasing the photosynthetic potential by active synthesis of thylakoidal protein and associated pigments (Trehan and Maneesha, 1991). This, on the other hand, produces the stimulatory effect on nitrate reductase because of increased reductant supply on which the enzyme is naturally dependent.  

Chromium failed to stimulate the nitrate reductase activity in lethal doses because chromium is known to inhibit protein synthesis (Rai and Dubey, 1988) and so it might be interfering with nitrate reductase synthesis causing the failure of immobilization to stabilize nitrate reductase activity. It however, had a stimulatory effect on nitrate reductase, nitrogenase and glutamine synthetase in sub-lethal doses. In fact, under immobilized conditions the toxicity of chromium to the enzymes in free cells was overcome suggesting that chromium may have been restricted from entering the cells by metal binding ligands in alginate.

The observations that the addition of the algal filtrate had marked stimulatory effect comparable to immobilized control cells with nickel and chromium suggest the complexing of the metals with organic extracellular material in the filtrate, (Srivastava et al. 1999a, Srivastava et al. 1999b). The slightly higher activity with the filtrates compared to immobilized cells can be attributed to the presence of other bioactive substances in the filtrate which in turn stimulate the enzyme activity. Cyanobacteria are known to release organic substances that can chelate free metal ions. The analysis of algal filtrate of Aulosira fertilissima revealed the presence of some major amino acids along with polysaccharides. Banerjee and Sharma, 1994 also reported the mitigating effect of algal filtrate on Lead toxicity in Anabaena flos aquae.The presence of methionine as one of the amino acids is very significant, which may result in binding of the metals with sulphydryl groups. Further, the polysaccharides may act as chelators, (Caire et al. 1997; Krajnc et al. 1995).

The uptake of both the metals was higher in immobilized condition in comparison to free cells, due to the presence of abundant hydroxyl groups in the alginate, which bind the metal ions. Similar effects were observed by Brun et al. 1998; Gloaguen et al. 1996; Ye et al. 1997.

Rice field ecosystems possess a bidirectional natural metal ameliorating system where Aulosira mats act as immobilized cells and decay of Aulosira and other cyanobacteria act as natural chelators protecting the rice plants from the deleterious effects of heavy metals. The presence of nickel and chromium at sub-lethal levels as used in this study, which under natural environments is not negligible, could very effectively be removed from the proximity of the cyanobacteria in the fields by its own natural mechanism. This is very significant for India as the rice fields get their water for irrigation from sources that are often highly contaminated with these two metals as a result of dumping of idols and other effluents from paint, tannery and leather industries. The presence of these metals could have a direct bearing on the nitrogen economy of these fields if the cyanobacteria are adversely affected.

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