Arsenate uptake, sequestration and reduction by a freshwater cyanobacterium: a potenial biologic control of arsenic in South Texas

Markley, Christopher Thomas

29 August 2005

The toxicity and adverse health effects of arsenic are widely known. It is generally accepted that sorption/desorption reactions with oxy-hydroxide minerals (iron, manganese) control the fate and transport of inorganic arsenic in surface waters through adsorption and precipitation-dissolution processes. In terrestrial environments with limited reactive iron, recent data suggest organoarsenicals are potentially important components of the biogeochemical cycling of arsenic in near-surface environments. Elevated arsenic levels are common in South Texas from geogenic processes (weathering of As-containing rock units) and anthropogenic sources (a byproduct from decades of uranium mining). Sediments collected from South Texas show low reactive iron concentrations, undetectable in many areas, making oxy-hydroxide controls on arsenic unlikely. Studies have shown that eukaryotic algae isolated from arsenic-contaminated waters have increased tolerance to arsenate toxicity and the ability to uptake and biotransform arsenate. In this experiment, net uptake of arsenic over time by a freshwater cyanobacterium never previously exposed to arsenate was quantified as a function of increasing As concentrations and increasing N:P ratios. Toxic effects were not evident when comparing cyanobacterial growth, though extractions indicate accumulation of intracellular arsenic by the cyanobacterium. Increasing N:P ratios has minimal effect on net arsenate uptake over an 18 day period. However, cyanobacteria were shown to reduce arsenate at rates faster than the system can re-oxidize the arsenic suggesting gross arsenate uptake may be much higher. Widespread arsenate reduction by cyanobacterial blooms would increase arsenic mobility and potential toxicity and may be useful as a biomarker of arsenic exposure in oxic surface water environments.

Arsenic

Biotransformation

Sequestration

Cyanobacteria

Arsenate uptake, sequestration and reduction by a freshwater cyanobacterium: a potenial biologic control of arsenic in South Texas

Markley, Christopher Thomas

29 August 2005

The toxicity and adverse health effects of arsenic are widely known. It is generally accepted that sorption/desorption reactions with oxy-hydroxide minerals (iron, manganese) control the fate and transport of inorganic arsenic in surface waters through adsorption and precipitation-dissolution processes. In terrestrial environments with limited reactive iron, recent data suggest organoarsenicals are potentially important components of the biogeochemical cycling of arsenic in near-surface environments. Elevated arsenic levels are common in South Texas from geogenic processes (weathering of As-containing rock units) and anthropogenic sources (a byproduct from decades of uranium mining). Sediments collected from South Texas show low reactive iron concentrations, undetectable in many areas, making oxy-hydroxide controls on arsenic unlikely. Studies have shown that eukaryotic algae isolated from arsenic-contaminated waters have increased tolerance to arsenate toxicity and the ability to uptake and biotransform arsenate. In this experiment, net uptake of arsenic over time by a freshwater cyanobacterium never previously exposed to arsenate was quantified as a function of increasing As concentrations and increasing N:P ratios. Toxic effects were not evident when comparing cyanobacterial growth, though extractions indicate accumulation of intracellular arsenic by the cyanobacterium. Increasing N:P ratios has minimal effect on net arsenate uptake over an 18 day period. However, cyanobacteria were shown to reduce arsenate at rates faster than the system can re-oxidize the arsenic suggesting gross arsenate uptake may be much higher. Widespread arsenate reduction by cyanobacterial blooms would increase arsenic mobility and potential toxicity and may be useful as a biomarker of arsenic exposure in oxic surface water environments.

Arsenic

Biotransformation

Sequestration

Cyanobacteria

Studien zur Biotransformation von Guanidinen und Amidinen mit Hepatozyten und Mikrosomen /

Wohlers, Hanke.

January 1994

Thesis (doctoral)--Christian-Albrechts-Universität zu Kiel, 1994.

Studien zur Charakterisierung der enzymatischen Grundlagen der Biotransformation von Aziden /

Brass, Kirsten.

January 2002

Thesis (doctoral)--Christian-Albrechts-Universität zu Kiel, 2002.

Azide. Biotransformation. Enzym.

KINETICS AND REGULATION OF PHASE II XENOBIOTIC METABOLISM IN ISOLATED RAT HEPATOCYTES AND PERFUSED LIVER

Sundheimer, David William

January 1979

No description available.

Biotransformation (Metabolism)

Drugs -- Toxicology.

Biotransformation of monoterpenes and their chlorination products

Misra, Girish

05 1900

No description available.

Monoterpenes

Biodegradation

Biotransformation (Metabolism)

Regio- and stereospecific biohydroxylation of small-ring molecules

Broad, Susan Ann

January 1997

No description available.

610.28

Biotransformation; Beauveria bassiana

The chemistry of reactive nitrosamines and related DNA adducts /

Gu, Feng,

January 1997

Thesis (Ph. D.)--University of Missouri-Columbia, 1997. / Typescript. Vita. Includes bibliographical references (leaves 225-231). Also available on the Internet.

Untersuchungen zur Biotransformation der Arzneistoffe Ifosfamid und Trofosfamid /

Küpker, Frank.

January 1993

Universiẗat, Diss.--Münster, 1993.

Untersuchungen zur Wirkung akuter und subakuter Alkoholbelastungen auf Pharmakokinetik und Biotransformation des Nicotins bei einmaliger Nicotin-Gabe und unter steady-state-Bedingungen /

Wichmann, Rüdiger.

January 1994

Techn. Univ., Diss.--Braunschweig, 1994.