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Research Journal of Microbiology

Year: 2007 | Volume: 2 | Issue: 1 | Page No.: 50-57
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Research Article

Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)

R. Karthikeyan, S. Vijayalakshmi and T. Balasubramanian

ABSTRACT

Attempts have been made to quantify the heavy metal and heavy metal resistant bacteria in the two stations in Uppanar estuary (Lat 11°43’ Long 79° 49’). The distribution of selected heavy metals (Hg, Cd, Cu and Zn) and the level of metals in the sediment was in the order of Zn>Cu>Cd>Hg. The existence of profound seasonal variation in the distribution of metals and heavy metal resistant bacteria in the sediments was observed. The metals and their resistant bacteria were maximum during monsoon and minimum during summer. The higher level of metal concentration and bacterial population were recorded near common effluent discharge from SIPCOT industrial complex, as it receives more quantities of industrial waste.
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R. Karthikeyan, S. Vijayalakshmi and T. Balasubramanian, 2007. Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India) . Research Journal of Microbiology, 2: 50-57.

URL: https://scialert.net/abstract/?doi=jm.2007.50.57

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INTRODUCTION

Heavy metals in the sediment are essential to assess the extent of metal pollution. The distribution of heavy metals in solution has widely been recognized as a major factor in the geochemical behavior, transport and biological effects of these elements in natural waters. Moreover, sediment has aptly been called as Trace element trap (Eugenia et al., 2004; Chester and Dooley, 1979) because they eventually receive almost all the heavy metals, which enter the aquatic environment (Greig and McGrath, 1977). The scavenging by suspending particles results in large concentration of pollutants being retained in estuarine sediments (Jurascic and Prohic, 1986). Sediment samples have also been widely used to monitor heavy metal pollution in coastal areas (Aksu et al., 1998; Shiber, 1980; Holms, 1986; Langston, 1986; Kouadio and Trefry, 1987; Lynsby and Brix, 1987; Prohic and Kniewald, 1987). Heavy metal contamination could frequently be identified and integrated more effectively through analysis.

The interaction between microorganism and heavy metal may result in either reduction or remediation of toxicity nature of the pollutant or either toxicity may be magnified. In view of reducing the toxicity by making use of the beneficial microorganisms and to prevent synergistic magnification of the toxicity, it is necessary to gain the information about the behavior of the microbes with heavy metal pollutants. Metals, like mercury and cadmium, have been extensively studied because of their effects on human health. The studies on the toxicity of copper to aquatic organisms were conducted (Steeman-Nielsen and Kamp-Nielsen, 1970; Sunda and Ferguson, 1981).

Toxicity studies have shown a wide range of tolerance to heavy metals by the aquatic microorganisms (Pekey et al., 2004; Hodson et al., 1979) and it inhibits various biological processes such as respiration (Hassall, 1963; McBrien and Hassall, 1965), photosynthesis (McBrien and Hassall, 1965; Steeman-Nielsen and Anderson, 1970) and cell division (Kanazawa and Kanazawa, 1969). Hewitt and Nicholas (1963) and Bowen and Gibbons (1979) studied the toxicity of heavy metals and found that they are strongly complexed with organic molecule and compete with transport systems of other essential metals and modify the structure of enzymes.

The metal resistant bacteria occurring in the environment may start to detoxify the heavy metal. So it is important to study the effects of heavy metals on microorganisms. Though many works have been carried out to monitor the pollution in the estuarine environment, only few works have been carried out to understand the interaction of microorganisms and heavy metals. Hence the present study was designed to find out the interaction between microorganisms and heavy metals.

MATERIALS AND METHODS

The Uppanar estuary is located at Cuddalore (Lat 11°43’ Long 79°49’). It originates from the north eastern part of the Shervarayan hills and opens into the Bay of Bengal near Cuddalore. Apart from the Municipal and domestic sewage the Uppanar estuary receives industrial effluents from SIPCOT (Small Industries Promotion Corporation of Tamil Nadu) Industrial complex. Most of industries are wet process industries and hence consume large quantity of water. In the present study two stations were selected, they are representing: Station 1- effluent discharge of an industry and Station 2- common effluents discharge site of many industries (Fig. 1).

Image for - Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)
Fig. 1: Map showing the sampling site

Sediment samples were collected for a period of one year (August 2002 - July 2003) from stations I and II. Samples were collected with the aid of cleaned and dried corer and samples were transferred to clean polyethylene cover. The samples were stored frozen until analysis. The preserved sediment sub samples were dried at 110°C to constant weight for estimation of metals. For extraction of mercury, cadmium, copper and zinc from the sediments, an improved acid digestion procedure was adopted by Watling and Watling (1982). The residue formed was then dissolved in 10 mL of 10% v/v nitric acid solution and the same was then aspirated into the Atomic Absorption Spectrophotometer and finally the concentration quantified is expressed in μg/g.

For the bacteriological analysis samples were collected with sediment corer and the central portion was aseptically transferred to new polythene bags. Total Heterotrophic Bacterial (THB) population in the sediment samples were enumerated by adapting spread plate technique.

Isolation of Heavy Metal Resistance Bacteria (HMRB) from the serially diluted sample 0.1 mL of the sample was inoculated in to nutrient broth tubes which is previously amended with mercury (HgCl) (0.01, 0.1, 0.5, 1.0, 2.5 and 5.0 ppb) cadmium (CdCl) (0.1, 0.5, 1.0, 2.5, 5.0 and 10.0 ppm), copper (CuCl2) (10, 20, 30, 40, 50 and 100 ppm) and zinc (ZnSO4) (50,100, 200, 400, 800 and 1200 ppm). The tubes were placed in shaker at room temperature. Bacterial colonies were enumerated by spread plate method described by Austin et al. (1977). Colonies were identified up to generic level with the schemes of Buchanan et al. (1974).

RESULTS AND DISCUSSION

The month wise concentration of sediment fraction of heavy metals in Table 1 shows that higher level of mercury, cadmium, copper and zinc concentration were recorded at station 2 could be attributed to the Industrial effluents discharged from the SIPCOT industrial common effluent discharge and land drainage along with sewages and domestic wastes from the near by areas. The higher concentration of copper and zinc at station 2 than the station 1, could be attributed to the discharge of fertilizer, pesticide and rodenticide containing heavy metals from the near by farm lands (Haynes et al., 2005). Moreover, the sediment at station 2 was clayey compared to station 1, this clayey in nature was found to adsorb higher level of metals form the water column (Seralathan, 1981; Katz and Kappan, 1981) and this would have been another possible reason for the higher level of zinc concentration in station 2. Similar findings were also reported in Swartkops river (Watling and Watling, 1982), Newport estuary (Cross et al., 1970) and Abukir bay (Saad et al., 1981).

The higher concentration of metals observed during monsoon could be attributed to the heavy rain fall and subsequent river runoff, bringing much industrial and land derived materials along with domestic, municipal and agricultural wastes, which include residues of heavy metal containing pesticides.

Table 1: Month wise distribution of heavy metals concentration (μg L-1) from station 1 and 2
Image for - Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)

The load of metals was found to be lower during summer months and this could be due to the meager metal rich freshwater influx. This observation was supported by earlier reports in the Kodiakkarai coastal area by Pragatheeswaran et al. (1988).

In the present study, total heterotrophic bacterial population in the sediments showed higher density value during monsoon and premonsoon seasons at both stations ranged from 46.5 to 71.3x104 CFU g-1 at station 1 and 27.2 to 79.8x105 CFU g-1 at station 2. An increase in population density was noticed during the monsoon season (71.3x104 CFU g-1) at station 1 and 79.8x105 CFU g-1) at station 2 (Fig. 2).

Kannan and Vasantha (1986) has reported viable counts of THB ranging from 1.9 to 10.9x103 CFU g-1 in Vellar estuary. The estimated THB from the Uppanar estuary was higher than the previous work. This work was supported by Sathyamurthy et al. (1990) from Pichavaram mangrove. The higher population was attributed to industrial discharge and terrigenous materials through land run-off, carrying high bacterial population (Timoney, 1998).

In present study THB (in control sediment) varied from 22.2 to 60.3x104 CFU g-1 and at station 1 and station 2, respectively (9.7 to 65.5x104 CFU g-1) (Fig. 3). Heavy metal resistant bacterial population showed maximum occurrence during pre monsoon and monsoon seasons at both stations. The maximum growth was attributed to higher heavy metal discharge through industrial effluent or land run-off (Table 2-5).

The higher population of HMRB at station 2 than the station 1 this is due to high heavy metal input form the common effluent discharge (mercury 6.93, cadmium 9.62, Copper 85.7, Zinc 48.536 μg g-1 maximum value at station 2). These results corroborates with Tanaka et al. (1974). Form their results the availability of heavy metals is an important factor governing the distribution of HMRB population.


Image for - Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)
Fig. 2: Number of total heterotrophic bacteria in the sediment samples of station I and II (X 104 CFU g-1)

Image for - Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)
Fig. 3: Number of bacteria in the Controls of station I and II (X 104 CFU g-1)

Table 2: Number of mercury resistant bacteria in the sediment samples of station I and II (X 104CFU g-1)
Image for - Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)

Table 3: Number of cadmium resistant bacteria in the sediment samples of station I and II (X 104CFU g-1)
Image for - Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)

Table 4: Number of copper resistant bacteria in the sediment samples of station I and II (X 104CFU g-1)
Image for - Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)

The present investigation was also supported by findings of Timoney (1998) at Hudson Shelf Valley of New York in metal resistant Bacillus sp. Similarly Austin et al. (1977) have also observed larger population of metal resistant bacteria in heavily polluted sites in Chesapeake Bay.

No changes occur on the growth and multiplication of bacteria at the lower concentration of heavy metals (Hg, Cd and Zn). Thus maximum population densities were recorded at 0.01 ppm (Hg), 0.1 ppm (Cd), 40 ppm (Cu) and 200 ppm (Zn) concentrations. The minimum was recorded at 5 ppm (Hg), 10 ppm (Cd), 10 ppm (Cu) and 50 ppm (Zn) concentrations. Hence, the bacteria grown in the medium containing higher concentration of metals were considered as metals resistant bacteria.

Table 5: Number of zinc resistant bacteria in the sediment samples of station I and II (X 104CFU g-1)
Image for - Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)

Table 6: Percentage composition of heavy metal resistant bacteria from sediment samples at station I and II
Image for - Monthly Variation of Heavy Metal and Metal Resistant Bacteria from Uppanar Estuary (South East Coast of India)

Increasing the concentration of heavy metals (Hg, Cd and Cu) led to decreased bacterial population. But in the case of zinc maximum population density of THB was recorded at 800 ppm and minimum was recorded at 50 ppm concentration (Table 2-5).

The microorganisms have been extensively demonstrated as sensitive to metal pollutants. These heavy metals may be responsible for occurrence of metal resistant bacteria in the estuaries (Kan-atireklap et al., 1998). The higher percentage of heavy metal resistant bacteria in Cochin backwater was attributed to the input of heavy metal wastes from near by industry (Lakshmanaperumalsamy and Purushothaman, 1982).

Totally 51 isolates were collected, of which, the Bacillus constituted 26.3% and followed by Aeromonas (13.1%) at station 1 and 2. At both station Bacillus was dominant form (Table 6). Among all the above genera Bacillus is predominantly recorded, which was supported by Audus (1970), he reported herbicide resistant Bacillus sp. in the soil. Lakshmanapurumalsamy and Purushothaman (1982) described the Bacillus dominance in Vellar estuary and Nelson and Colwell (1975) reported eight genera of metal resistant bacteria from the Chasapeake Bay. Timoney (1998) isolated metal resistant Bacillus bacterial strains form the polluted site and Clark et al. (1977) also isolated the mercury resistant bacteria from coastal water and sediments.

In the present observation a comparison was made between the heavy metals concentration and HMRB in sediment. The station 2 was found to have higher level of heavy metals and heavy metal resistant bacteria. At both stations, Microccous, Flavabacterium, Achromobacter, Pseudomonas, Bacillus, Vibrio and Corynebacterum and Bacillus were the dominant genera, which were resistant to heavy metals.

CONCLUSIONS

In the present study, the microbes resist heavy metal toxicity. Attempts have been made therefore to quantity the THB and heavy metals resistant bacteria in the two stations in the Uppanar estuary. The sediment heavy metals have also been monitored. The results showed the existence of profound seasonal variation in the physio-chemical condition in the estuarine environment. Further, the station 2 was found to be moderately polluted with heavy metal compared with station 1, as it receives more quantities of municipal and Industrial effluent.

The sediment quality parameters were found to have compared with the distribution pattern of microbial population. The station 2 was found to have higher number of total heterotrophic bacteria and heavy metal resistant bacteria. Totally 51 isolates were collected, of which, the Bacillus constituted and followed by Aeromonas at station 1 and 2. At both station Bacillus was dominant form. Among all the above genera Bacillus is predominantly recorded.

REFERENCES

  1. Aksu, A.E., D. Yasar and O. Uslu, 1998. Assessment of marine pollution in Izmir Bay: Heavy metal and organic compound concentrations in surfical sediments. Turk. J. Eng. Environ. Sci., 22: 387-416.
    Direct Link
  2. Audus, L.J., 1970. The action of herbicides on the microflora of the soil. Proceedings of the 10th British Weed Control Conference, November 16-19, 1970, IEEE Xplore, pp: 1036-1051.
  3. Austin, T., D. Allen, A. Mills and R.R. Colwell, 1977. Numerical taxonomy of heavy metal-tolerant bacteria isolated from an estuary. Can. J. Microbiol., 23: 1433-1447.
    PubMedDirect Link
  4. Bowen, H.J.M. and M. Gibbons, 1979. Environmental Chemistry of the Elements. Academic Press, New York.
  5. Buchanan, R.E., N.E. Gibbons, S.T. Cowen, T.G. Holt and J. Liston et al., 1974. Bergey's Manual of Determinative Bacteriology. Williams and Willkins Co., Baltimore.
  6. Chester, R. and J.K. Dooley, 1979. Heavy metals in relation to the biology of the mummichog, Fundulus heteroclitus. J. Fish. Biol., 14: 309-328.
    CrossRefDirect Link
  7. Clark, D.L., A.A. Weiss and S. Silver, 1977. Mercury and organomicrobial resistant determined by plasmids in Pseudomonas sp. J. Bacteriol., 132: 136-196.
  8. Cross, F.A., D.W. Duke and J.N. Willis, 1970. Biogeo-chemistry of trace elements in the coastal plain estuary: Distribution of mangrove iron and zinc in sediment water and polychaetous worms. Chesapeake Sci., 11: 221-234.
    Direct Link
  9. Eugenia, J.O., G. Sanchez and G. Mercado, 2004. Cleaner production and environmentally sound biotechnology for the prevention of upstream nutrient pollution in the Mexican coast of the Gulf of Mexico. Ocean Coastal Manage., 47: 641-670.
    Direct Link
  10. Greig, R.A. and R.A. McGrath, 1977. Trace metals in sediments of Raritan Bay. Mar. Pollut. Bull., 8: 188-192.
    CrossRef
  11. Hassall, K.A., 1963. Uptake of copper and its physiological effects on Chlorells vulgaris. Physiol. Plant., 16: 323-332.
    CrossRefDirect Link
  12. Hewitt, E.J. and P.J.D. Nicholas, 1963. Cation and Anion Inhibition and Interaction in Metabolism and in Enzyme Activity. In: Metabolic Inhibitor, Hochster, R.M. and J.H. Quastel (Eds.). Academic Press, New York, pp: 311-436.
  13. Hodson, P.V., U. Borgmann and H. Shear, 1979. Toxicity of Copper to Aquatic Biota: Copper in the Environment Health Effects. Vol. 2, Wiley-Interscience, New York, pp: 307-372.
  14. Holmes, C.W., 1986. Trace metal seasonal variations in Texas marine sediments. Mar. Chem., 20: 13-27.
    CrossRef
  15. Jurascic, C.M. and E. Prohic, 1986. Transfer of heavy metals by suspended matter in the Krka River Estuary. Yugoslavia. Rapp. Comm. Int. Mer. Medit., 30: 133-133.
  16. Kan-Atireklap, S., N.T. Yen, S. Tanabe and A.N. Subramanian, 1998. Butyltin compound and organochlorine residues in green mussel from Thailand coastal water. Environ. Chem., 67: 409-424.
    Direct Link
  17. Kanazawa, T. and K. Kanazawa, 1969. Specific inhibitory effect of copper on cellular division in Chlorella. Plant Cell Physiol., 10: 495-502.
    Direct Link
  18. Kannan, L. and K. Vasantha, 1986. Distribution of heterotrophic bacteria in Vellar esturay, East coast of India. Indian J. Mar. Sci., 15: 267-268.
  19. Katz, A. and I.R. Kappan, 1981. Heavy metal behavior in coastal sediments of Southern California: A critical review and synthesis. Mar. Chem., 10: 261-299.
    CrossRef
  20. Kouadio, I. and J.H. Trefry, 1987. Sediment trace metal concentration in the Ivory coasts, West Africa. Water Air Soil Pollut., 32: 145-154.
    CrossRefDirect Link
  21. Lakshmanaperumalsamy, P. and A. Purushothaman, 1982. Heterotrophic bacteria associated with seaweed. Proc. Indian Acad. Sci., 91: 487-493.
    Direct Link
  22. Langston, W.J., 1986. Metals in sediment and benthic organisms in their mersey estuary. Estuar. Coast. Shelf Sci., 23: 239-261.
    CrossRef
  23. Lynsby, J.E. and H. Brix, 1987. Monitoring of heavy metals contamination in the Limford, Denmark using biological indicators and sediment. Sci. Total. Environ., 64: 239-252.
    CrossRef
  24. McBrien, D.C.H. and K.A. Hassall, 1965. Loss of cell potassium by Chlorella vulgaris after contact with toxic amounts of copper sulphate. Physiol. Plant, 18: 1059-1065.
    CrossRefDirect Link
  25. Nelson, J.P. and R.R. Colwell, 1975. The ecology of mercury resistant bacteria in Chesapeake Bay. Microbial Ecol., 1: 191-218.
    Direct Link
  26. Pekey, H., D. Karakas and M. Bakoglu, 2004. Source apportionment of trace metals in surface waters of a polluted stream using multivariate statistical analyses. Mar. Pollut. Bull., 49: 809-818.
    Direct Link
  27. Pragatheeswaran, V., P. Anbazhagan, R. Natarajan and T. Venugopalan, 1988. Distribution of heavy metals and organic carbon in sediments off Madras and Visakhapatnam. Mahasagar-Bull. Natn. Inst. Oceanogr., 19: 39-44.
  28. Prohic, E. and G. Kniewald, 1987. Heavy metal distribution in recent sediments of the Kaka River estuary-An example of sequential extraction analysis. Mar. Chem., 22: 279-297.
    CrossRef
  29. Sathyamurthy, K., R. Baburajendran, A. Purushothaman and V. Ramaiyan, 1990. Heterotrophic bacteria from Mangrove. Indian J. Microbiol., 30: 337-341.
    Direct Link
  30. Seralathan, P., 1981. Trace element geochemistry of modern deltaic sediments of the Cauvery river, East coast of India. Indian J. Mar. Sci., 16: 235-239.
  31. Shiber, J.G., 1980. Trace metals in edibel marine molluscs and crustaceans from Lebanon. Hydrobiologica, 83: 465-476.
    CrossRefDirect Link
  32. Steeman-Nielsen, E. and S. Andersen, 1970. Copper ions as poison in the sea and in freshwater. Mar. Biol., 6: 93-97.
    CrossRefDirect Link
  33. Sunda, W.G. and R.L. Ferguson, 1981. Sensitivity of Natural Bacterial Communities to Addition of Copper and Cupric Ion Activity. In: A Bioassay of Copper Complexation in Trace Metal in Seawater, Wong, C.S., E. Boyle, K.W. Bruland, J.D. Burton and E.D. Goldberg (Eds.). Plenum Press, New York, pp: 871-891.
  34. Tanaka, N., M. Nakanistin and H. Kadota, 1974. Nutritional Interrelation Between Bacteria and Phytoplankton in a Pelagic Ecosystem. In: Effect of the Ocean Environment on Microbial Activities, Colwell and Morita (Eds.). Univ. Park Press, Baltimore, USA., pp: 495-509.
  35. Timoney, 1998. Survey of metal tolerance in moderately halophilic bacteria. Applied Envirn. Microbiol., 55: 2385-2390.
    Direct Link
  36. Watling, R.J. and H.R. Waltling, 1982. Metal surveys in South African estuaries. VI Sundays River. Water, SA., 8: 192-195.

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