Influence of Hydrocarbons on Plant Cell Ultrastructure and Main Metabolic Enzymes
Influence of octane and benzene on plant cell
ultrastructure and enzymes of basic metabolism, such as nitrogen
assimilation and energy generation have been studied. Different
plants: perennial ryegrass (Lolium perenne) and alfalfa (Medicago
sativa); crops- maize (Zea mays L.) and bean (Phaseolus vulgaris);
shrubs – privet (Ligustrum sempervirens) and trifoliate orange
(Poncirus trifoliate); trees - poplar (Populus deltoides) and white
mulberry (Morus alba L.) were exposed to hydrocarbons of different
concentrations (1, 10 and 100 mM). Destructive changes in bean and
maize leaves cells ultrastructure under the influence of benzene
vapour were revealed at the level of photosynthetic and energy
generation subcellular organells. Different deviations at the level of
subcellular organelles structure and distribution were observed in
alfalfa and ryegrass root cells under the influence of benzene and
octane, absorbed through roots. The level of destructive changes is
concentration dependent. Benzene at low 1 and 10 mM concentration
caused the increase in glutamate dehydrogenase (GDH) activity in
maize roots and leaves and in poplar and mulberry shoots, though to
higher extent in case of lower, 1mM concentration. The induction
was more intensive in plant roots. The highest tested 100mM
concentration of benzene was inhibitory to the enzyme in all plants.
Octane caused induction of GDH in all grassy plants at all tested
concentrations; however the rate of induction decreased parallel to
increase of the hydrocarbon concentration. Octane at concentration 1
mM caused induction of GDH in privet, trifoliate and white mulberry
shoots. The highest, 100mM octane was characterized by inhibitory
effect to GDH activity in all plants. Octane had inductive effect on
malate dehydrogenase in almost all plants and tested concentrations,
indicating the intensification of Trycarboxylic Acid Cycle.
The data could be suggested for elaboration of criteria for plant
selection for phytoremediation of oil hydrocarbons contaminated
soils.
[1] Leahy, J.G. and R. R. Colwell, "Microbial degradation of hydrocarbons
in the environment", Microbio. Rev., vol. 54, pp. 305-315, 1990.
[2] Ferro, A., J. Kennedy, W. Doucette, S. Nelson, G. Jauregui, B.
McFarland, and B. Bugbee, "Fate of benzene in soils planted with
alfalfa: Uptake, volatilization, and degradation", in Phytoremediation of
Soil and Water Contaminants, E.L. Kruger, T.A. Anderson, J.R. Coats,
Eds, American Chemical Society: Washington, D.C., 1997, pp. 223-237.
[3] Harms, H., Bokern, M., Kolb, M., Bock, C., "Transformation of organic
contaminants by different plant systems", in Phytoremediation.
Transfor¬mation and control of contaminants, McCutcheon, S.C.,
Schnoor, J.L. Eds. Wiley-Interscience, Hoboken, New Jersey, 2003, pp.
285-316, 2003.
[4] Qiu, X., T.W. Leland, S.I. Shah, D.L. Sorensen, and E.W. Kendall,
"Field study: Grass remediation for clay soil contaminated with
polycyclic aromatic hydrocarbons", in Phytoremediation of Soil and
Water Contaminants, E.L. Kruger, T.A. Anderson, J.R. Coats, Eds.,
American Chemical Society: Washington, D.C, 1997, pp. 186-199.
[5] Sandermann, H. "Plant metabolism of xenobiotics", Trends. Biochem.
Sci., vol. 17, pp. 82-84, 1992.
[6] Tsao, D.T. Phytoremediation. Advances in Biochemical Engineering and
Biotechnology. Springer, Berlin Heidelberg New York, 2003.
[7] Wiltse, C.C., W.L. Rooney, Z. Chen, A.P. Schwab, and M.K. Banks.
"Greenhouse evaluation of agronomic and crude oil-phytoremediation
potential among alfalfa genotypes", J. Env. Qual., vol.27, pp. 169-173,
1998.
[8] Bartha, R. "Biotechnology of petroleum pollutant biodegradation",
Micro. Ecol., vol.12, pp. 155-17, 1986.
[9] Durmishidze S, Ugrekhelidze D. "Enzymatic cleavage of the aromatic
ring of benzene and simple phenols in plants", in Proc. 6th FEBS
Meeting, Madrid, 1969, p.915.
[10] Mitaishvili T., Scalla R., Ugrekhelidze D., Tsereteli B., Sadunishvili T.,
Kvesitadze G. "Transformation of aromatic compounds in plants grown
under aseptic conditions", Zeitsschrift fur Naturforschung, 60c, pp. 97-
102, 2005.
[11] Betsiashvili M., Sadunishvili T., Amashukeli N., Tsulukidze N.,
Shapovalova N., Dzamukashvili N., Nutsubidze N."Effect of aromatic
hydrocarbons on main metabolic and energetic enzymes in maize,
ryegrass and kidney bean seedlings", Bull.Georgian Acad. Sci., vol. 170,
pp.172-174, 2004.
[12] Chrikishvili D, Sadunishvili T, Zaalishvili G."Benzoic acid
transformation via conjugation with peptides and final fate of conjugates
in higher plants", Ecotoxicol. Environ. Saety., vol.64, 3, pp. 390-399,
2006.
[13] Kvesitadze G., Gordeziani M., Khatisashvili G., Sadunishvili T.,
Ramsden J.J. "Review: Some aspects of the enzymatic basis of
phytoremediation", Journal of Biological Physics and Chemistry, vol.1,
2, pp. 49-57, 2001.
[14] Zaalishvili, G., Sadunishvili, T., Scalla, R. Laurent, F. and Kvesitadze,
G. "Electron Microscopic Investigation of Nitrobenzene Distribution
and Effect on Plant Root Tip Cells Ultrastructure", Ecotoxicol. Environ.
Safety, vol. 52, 3, pp. 190-197, 2002.
[15] Kvesitadze G., Kokonashvili G., Sadunishvili T. "Enzymes of nitrogen
and energy metabolism from the liver of spiny dogfish and in the
preparation Katrex", Applied Biochemistry and Microbiology, vol.29, 1,
pp.131-137, 1993.
[16] Sadunishvili, T., Gvarliani N., Nutsubidze, N., Kvesitadze, G. "Effect of
methionine sulfoximine on nitrogen metabolism and externally supplied
ammonium assimilation in Kidney bean". Ecotoxicol. Environ. Saf., vol.
34, pp. 70-75, 1996.
[17] Bradford M. "A rapid and sensitive method for the quantitativation of
microgram quantities of protein utilizing the principle of protein-dye
binding", Anal. Biochem., vol. 72, pp. 248-254, 1976.
[18] Kvesitadze, G., Khatisashvili, G., Sadunishvili, T., Ramsden, J.J.
Biochemical Mechanisms of Detoxification in Higher Plants. Basis of
Phytoremediation. Springer, Berlin Heidelberg New York, 2006.
[19] Buadze, O., Kvesitadze, G. "Effect of low-molecular-weght alkanes on
the cell photosynthetic apparatus", Ecotoxicol. Environ. Saf., vol. 38, pp.
36-44, 1997.
[20] Buadze, O., Sadunishvili, T., Kvesitadze, G. "The effect of 1,2-
benzantracene and 3,4-benzpyrene on the ultrastructure of maize cells",
International Biodeterioration and Biodegradation, vol. 41, pp.119-125,
1998.
[21] Zaalishvili, G., Lomidze, E., Buadze, O., Sadunishvili, T. Tkhelidze, P.,
Kvesitadze, G. "Electron microscopic investigation of benzidine effect
on maize root tip cells ultrastructure, DNA synthesis and calcium
homeostasis", International Biodeterioration and Biodegradation, vol.
46, 2, pp.133-140, 2000.
[22] Miflin B.J. and Habash D.Z. "The role of glutamine synthetase and
glutamate dehydrogenase in nitrogen assimilation and possibilities for
improvement in the nitrogen utilization of crops", Journal of
Experimental Botany, vol. 53, No. 370, pp. 979-987, 2002.
[1] Leahy, J.G. and R. R. Colwell, "Microbial degradation of hydrocarbons
in the environment", Microbio. Rev., vol. 54, pp. 305-315, 1990.
[2] Ferro, A., J. Kennedy, W. Doucette, S. Nelson, G. Jauregui, B.
McFarland, and B. Bugbee, "Fate of benzene in soils planted with
alfalfa: Uptake, volatilization, and degradation", in Phytoremediation of
Soil and Water Contaminants, E.L. Kruger, T.A. Anderson, J.R. Coats,
Eds, American Chemical Society: Washington, D.C., 1997, pp. 223-237.
[3] Harms, H., Bokern, M., Kolb, M., Bock, C., "Transformation of organic
contaminants by different plant systems", in Phytoremediation.
Transfor¬mation and control of contaminants, McCutcheon, S.C.,
Schnoor, J.L. Eds. Wiley-Interscience, Hoboken, New Jersey, 2003, pp.
285-316, 2003.
[4] Qiu, X., T.W. Leland, S.I. Shah, D.L. Sorensen, and E.W. Kendall,
"Field study: Grass remediation for clay soil contaminated with
polycyclic aromatic hydrocarbons", in Phytoremediation of Soil and
Water Contaminants, E.L. Kruger, T.A. Anderson, J.R. Coats, Eds.,
American Chemical Society: Washington, D.C, 1997, pp. 186-199.
[5] Sandermann, H. "Plant metabolism of xenobiotics", Trends. Biochem.
Sci., vol. 17, pp. 82-84, 1992.
[6] Tsao, D.T. Phytoremediation. Advances in Biochemical Engineering and
Biotechnology. Springer, Berlin Heidelberg New York, 2003.
[7] Wiltse, C.C., W.L. Rooney, Z. Chen, A.P. Schwab, and M.K. Banks.
"Greenhouse evaluation of agronomic and crude oil-phytoremediation
potential among alfalfa genotypes", J. Env. Qual., vol.27, pp. 169-173,
1998.
[8] Bartha, R. "Biotechnology of petroleum pollutant biodegradation",
Micro. Ecol., vol.12, pp. 155-17, 1986.
[9] Durmishidze S, Ugrekhelidze D. "Enzymatic cleavage of the aromatic
ring of benzene and simple phenols in plants", in Proc. 6th FEBS
Meeting, Madrid, 1969, p.915.
[10] Mitaishvili T., Scalla R., Ugrekhelidze D., Tsereteli B., Sadunishvili T.,
Kvesitadze G. "Transformation of aromatic compounds in plants grown
under aseptic conditions", Zeitsschrift fur Naturforschung, 60c, pp. 97-
102, 2005.
[11] Betsiashvili M., Sadunishvili T., Amashukeli N., Tsulukidze N.,
Shapovalova N., Dzamukashvili N., Nutsubidze N."Effect of aromatic
hydrocarbons on main metabolic and energetic enzymes in maize,
ryegrass and kidney bean seedlings", Bull.Georgian Acad. Sci., vol. 170,
pp.172-174, 2004.
[12] Chrikishvili D, Sadunishvili T, Zaalishvili G."Benzoic acid
transformation via conjugation with peptides and final fate of conjugates
in higher plants", Ecotoxicol. Environ. Saety., vol.64, 3, pp. 390-399,
2006.
[13] Kvesitadze G., Gordeziani M., Khatisashvili G., Sadunishvili T.,
Ramsden J.J. "Review: Some aspects of the enzymatic basis of
phytoremediation", Journal of Biological Physics and Chemistry, vol.1,
2, pp. 49-57, 2001.
[14] Zaalishvili, G., Sadunishvili, T., Scalla, R. Laurent, F. and Kvesitadze,
G. "Electron Microscopic Investigation of Nitrobenzene Distribution
and Effect on Plant Root Tip Cells Ultrastructure", Ecotoxicol. Environ.
Safety, vol. 52, 3, pp. 190-197, 2002.
[15] Kvesitadze G., Kokonashvili G., Sadunishvili T. "Enzymes of nitrogen
and energy metabolism from the liver of spiny dogfish and in the
preparation Katrex", Applied Biochemistry and Microbiology, vol.29, 1,
pp.131-137, 1993.
[16] Sadunishvili, T., Gvarliani N., Nutsubidze, N., Kvesitadze, G. "Effect of
methionine sulfoximine on nitrogen metabolism and externally supplied
ammonium assimilation in Kidney bean". Ecotoxicol. Environ. Saf., vol.
34, pp. 70-75, 1996.
[17] Bradford M. "A rapid and sensitive method for the quantitativation of
microgram quantities of protein utilizing the principle of protein-dye
binding", Anal. Biochem., vol. 72, pp. 248-254, 1976.
[18] Kvesitadze, G., Khatisashvili, G., Sadunishvili, T., Ramsden, J.J.
Biochemical Mechanisms of Detoxification in Higher Plants. Basis of
Phytoremediation. Springer, Berlin Heidelberg New York, 2006.
[19] Buadze, O., Kvesitadze, G. "Effect of low-molecular-weght alkanes on
the cell photosynthetic apparatus", Ecotoxicol. Environ. Saf., vol. 38, pp.
36-44, 1997.
[20] Buadze, O., Sadunishvili, T., Kvesitadze, G. "The effect of 1,2-
benzantracene and 3,4-benzpyrene on the ultrastructure of maize cells",
International Biodeterioration and Biodegradation, vol. 41, pp.119-125,
1998.
[21] Zaalishvili, G., Lomidze, E., Buadze, O., Sadunishvili, T. Tkhelidze, P.,
Kvesitadze, G. "Electron microscopic investigation of benzidine effect
on maize root tip cells ultrastructure, DNA synthesis and calcium
homeostasis", International Biodeterioration and Biodegradation, vol.
46, 2, pp.133-140, 2000.
[22] Miflin B.J. and Habash D.Z. "The role of glutamine synthetase and
glutamate dehydrogenase in nitrogen assimilation and possibilities for
improvement in the nitrogen utilization of crops", Journal of
Experimental Botany, vol. 53, No. 370, pp. 979-987, 2002.
@article{"International Journal of Biological, Life and Agricultural Sciences:53978", author = "T. Sadunishvili and E. Kvesitadze and M. Betsiashvili and N. Kuprava and G. Zaalishvili and G. Kvesitadze", title = "Influence of Hydrocarbons on Plant Cell Ultrastructure and Main Metabolic Enzymes", abstract = "Influence of octane and benzene on plant cell
ultrastructure and enzymes of basic metabolism, such as nitrogen
assimilation and energy generation have been studied. Different
plants: perennial ryegrass (Lolium perenne) and alfalfa (Medicago
sativa); crops- maize (Zea mays L.) and bean (Phaseolus vulgaris);
shrubs – privet (Ligustrum sempervirens) and trifoliate orange
(Poncirus trifoliate); trees - poplar (Populus deltoides) and white
mulberry (Morus alba L.) were exposed to hydrocarbons of different
concentrations (1, 10 and 100 mM). Destructive changes in bean and
maize leaves cells ultrastructure under the influence of benzene
vapour were revealed at the level of photosynthetic and energy
generation subcellular organells. Different deviations at the level of
subcellular organelles structure and distribution were observed in
alfalfa and ryegrass root cells under the influence of benzene and
octane, absorbed through roots. The level of destructive changes is
concentration dependent. Benzene at low 1 and 10 mM concentration
caused the increase in glutamate dehydrogenase (GDH) activity in
maize roots and leaves and in poplar and mulberry shoots, though to
higher extent in case of lower, 1mM concentration. The induction
was more intensive in plant roots. The highest tested 100mM
concentration of benzene was inhibitory to the enzyme in all plants.
Octane caused induction of GDH in all grassy plants at all tested
concentrations; however the rate of induction decreased parallel to
increase of the hydrocarbon concentration. Octane at concentration 1
mM caused induction of GDH in privet, trifoliate and white mulberry
shoots. The highest, 100mM octane was characterized by inhibitory
effect to GDH activity in all plants. Octane had inductive effect on
malate dehydrogenase in almost all plants and tested concentrations,
indicating the intensification of Trycarboxylic Acid Cycle.
The data could be suggested for elaboration of criteria for plant
selection for phytoremediation of oil hydrocarbons contaminated
soils.", keywords = "Higher plants, hydrocarbons, cell ultrastructure,glutamate and malate dehydrogenases.", volume = "3", number = "9", pages = "436-6", }
