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  1. Sabullah, M.K., Ahmad, S.A., Shukor, M.Y., Gansau, A.J., Syed, M.A., Sulaiman, M.R., et al.
    MyJurnal
    Due to the latest industrial development, many dangerous chemicals have been released directly or indirectly which resulted in the polluted water bodies. Water rehabilitation is an alternative way to restore the quality of water, followed by the environmental management to control the waste discharge to ensure the balance of the degradation rates or detoxifying by environmental factors. However, this process consumed a lot of time and cost. Besides, most of the metal ions, especially copper which is capable to bioaccumulate in aquatic organism and at the elevated level may cause physiological and biochemical alteration which leads to mortality. Environmental monitoring is the initial step presupposed evaluating the potential toxicity of effluent gushing at its purpose to discharge, avoiding the determining effects of contaminant in water bodies. Due to the high sensitivity of the aquatic life towards dissolving toxicant, the fish has been utilized as the biological measurement (Biomarker) to indicate the existence of toxicant exposure and/or the impact towards the evaluation of molecular, cellular to physiological level. Thus, this paper gives an overview of the manipulation of fish as a biomarker of heavy metals through behavior response, hepatocyte alteration, enzymatic reaction and proteomic studies which have proven to be very useful in the environmental pollution monitoring.
  2. Yadzir, Z.H.M., Gafar, A.A., Rahman, M.F., Yakasai, M.H., Abdullah, M.A., Shamaan, N.A., et al.
    MyJurnal
    Contamination of organic xenobiotic pollutants and heavy metals in a contaminated site allows
    the use of multiple bacterial degraders or bacteria with the ability to detoxify numerous toxicants
    at the same time. A previously isolated SDS- degrading bacterium, Acinetobacter baumannii
    strain Serdang 1 was shown to reduce molybdenum to molybdenum-blue. The bacterium works
    optimally at pH 6.5, the temperature range between 25 and 34°C with glucose serves as the best
    electron donor for molybdate reduction. This bacterium required additional concentration of
    phosphate at 5.0 mM and molybdate between 15 and 25 mM. The absorption spectrum of the
    molybdenum blue obtained is similar to the molybdenum blue from other earlier reported
    molybdate reducing bacteria, as it resembles a reduced phosphomolybdate closely. Ag(i), As(v),
    Pb(ii) and Cu(ii) inhibited molybdenum reduction by 57.3, 36.8, 27.7 and 10.9%, respectively, at
    1 p.p.m. Acrylamide was efficiently shown to support molybdenum reduction at a lower
    efficiency than glucose. Phenol, acrylamide and propionamide could support the growth of this
    bacterium independently of molybdenum reduction. This bacterium capability to detoxify several
    toxicants is an important tool for bioremediation in the tropical region.
  3. Yakasai, M.H., Rahman, M.F., Khayat, M.E., Shukor, M.Y., Shamaan, N.A., Rahim, M.B.H.A.
    MyJurnal
    The presence of both heavy metals and organic xenobiotic pollutants in a contaminated site
    justifies the application of either a multitude of microbial degraders or microorganisms having
    the capacity to detoxify a number of pollutants at the same time. Molybdenum is an essential
    heavy metal that is toxic to ruminants at a high level. Ruminants such as cow and goats
    experience severe hypocuprosis leading to scouring and death at a concentration as low as
    several parts per million. In this study, a molybdenum-reducing bacterium with amide-degrading
    capacity has been isolated from contaminated soils. The bacterium, using glucose as the best
    electron donor reduces molybdenum in the form of sodium molybdate to molybdenum blue. The
    maximal pH reduction occurs between 6.0 and 6.3, and the bacterium showed an excellent
    reduction in temperatures between 25 and 40 oC. The reduction was maximal at molybdate
    concentrations of between 15 and 25 mM. Molybdenum reduction incidentally was inhibited by
    several toxic heavy metals. Other carbon sources including toxic xenobiotics such as amides
    were screened for their ability to support molybdate reduction. Of all the amides, only
    acrylamide can support molybdenum reduction. The other amides; such as acetamide and
    propionamide can support growth. Analysis using phylogenetic analysis resulted in a tentative
    identification of the bacterium as Pseudomonas sp. strain 135. This bacterium is essential in
    remediating sites contaminated with molybdenum, especially in agricultural soil co-contaminated
    with acrylamide, a known soil stabilizer.
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