Jodi S Blum (Former Employee)
Science and Products
Filter Total Items: 18
Characterization of the extremely arsenic-resistant Brevibacterium linens strain AE038-8 isolated from contaminated groundwater in Tucumán, Argentina Characterization of the extremely arsenic-resistant Brevibacterium linens strain AE038-8 isolated from contaminated groundwater in Tucumán, Argentina
Brevibacterium linens AE038-8, isolated from As-contaminated groundwater in Tucumán (Argentina), is highly resistant to arsenic oxyanions, being able to tolerate up to 1 M As(V) and 75 mM As(III) in a complex medium. Strain AE038-8 was also able to reduce As(V) to As(III) when grown in complex medium but paradoxically it could not do this in a defined minimal medium with sodium acetate...
Authors
Daniela Maizel, Jodi S. Blum, Marcela A. Ferrero, Sagar M. Utturkar, Steven D. Brown, Barry P. Rosen, Ronald S. Oremland
A microbial arsenic cycle in sediments of an acidic mine impoundment: Herman Pit, Clear Lake, California A microbial arsenic cycle in sediments of an acidic mine impoundment: Herman Pit, Clear Lake, California
The involvement of prokaryotes in the redox reactions of arsenic occurring between its +5 [arsenate; As(V)] and +3 [arsenite; As(III)] oxidation states has been well established. Most research to date has focused upon circum-neutral pH environments (e.g., freshwater or estuarine sediments) or arsenic-rich “extreme” environments like hot springs and soda lakes. In contrast, relatively...
Authors
Jodi S. Blum, Shelley McCann, S. Bennett, Laurence G. Miller, J. R. Stolz, B. Stoneburner, C. Saltikov, Ronald S. Oremland
Microbiological reduction of Sb(V) in anoxic freshwater sediments Microbiological reduction of Sb(V) in anoxic freshwater sediments
Microbiological reduction of millimolar concentrations of Sb(V) to Sb(III) was observed in anoxic sediments from two freshwater settings: (1) a Sb- and As-contaminated mine site (Stibnite Mine) in central Idaho and 2) an uncontaminated suburban lake (Searsville Lake) in the San Francisco Bay Area. Rates of Sb(V) reduction in anoxic sediment microcosms and enrichment cultures were...
Authors
Ronald S. Oremland, Thomas R. Kulp, Laurence G. Miller, Franco Braiotta, Samuel M. Webb, Benjamin D Kocar, Jodi S. Blum
Desulfohalophilus alkaliarsenatis gen. nov., sp. nov., an extremely halophilic sulfate- and arsenate-respiring bacterium from Searles Lake, California Desulfohalophilus alkaliarsenatis gen. nov., sp. nov., an extremely halophilic sulfate- and arsenate-respiring bacterium from Searles Lake, California
A haloalkaliphilic sulfate-respiring bacterium, strain SLSR-1, was isolated from a lactate-fed stable enrichment culture originally obtained from the extreme environment of Searles Lake, California. The isolate proved capable of growth via sulfate-reduction over a broad range of salinities (125–330 g/L), although growth was slowest at salt-saturation. Strain SLSR-1 was also capable of...
Authors
Jodi Switzer Blum, Thomas R. Kulp, Sukkyun Han, Brian Lanoil, Chad W. Saltikov, John F. Stolz, Laurence G. Miller, Ronald S. Oremland
A bacterium that can grow by using arsenic instead of phosphorus A bacterium that can grow by using arsenic instead of phosphorus
Life is mostly composed of the elements carbon, hydrogen, nitrogen, oxygen, sulfur, and phosphorus. Although these six elements make up nucleic acids, proteins, and lipids and thus the bulk of living matter, it is theoretically possible that some other elements in the periodic table could serve the same functions. Here, we describe a bacterium, strain GFAJ-1 of the Halomonadaceae...
Authors
Felisa Wolfe-Simon, Jodi S. Blum, T.R. Kulp, Gordon W. Rattray, S.E. Hoeft, J. Pett-Ridge, J.F. Stolz, S.M. Webb, P.K. Weber, P.C.W. Davies, A.D. Anbar, R.S. Oremland
Microbiology: A microbial arsenic cycle in a salt-saturated, extreme environment Microbiology: A microbial arsenic cycle in a salt-saturated, extreme environment
Searles Lake is a salt-saturated, alkaline brine unusually rich in the toxic element arsenic. Arsenic speciation changed from arsenate [As(V)] to arsenite [As(III)] with sediment depth. Incubated anoxic sediment slurries displayed dissimilatory As(V)-reductase activity that was markedly stimulated by H2 or sulfide, whereas aerobic slurries had rapid As(III)-oxidase activity. An anaerobic
Authors
R.S. Oremland, T.R. Kulp, J.S. Blum, S.E. Hoeft, S. Baesman, L.G. Miller, J.F. Stolz
Science and Products
Filter Total Items: 18
Characterization of the extremely arsenic-resistant Brevibacterium linens strain AE038-8 isolated from contaminated groundwater in Tucumán, Argentina Characterization of the extremely arsenic-resistant Brevibacterium linens strain AE038-8 isolated from contaminated groundwater in Tucumán, Argentina
Brevibacterium linens AE038-8, isolated from As-contaminated groundwater in Tucumán (Argentina), is highly resistant to arsenic oxyanions, being able to tolerate up to 1 M As(V) and 75 mM As(III) in a complex medium. Strain AE038-8 was also able to reduce As(V) to As(III) when grown in complex medium but paradoxically it could not do this in a defined minimal medium with sodium acetate...
Authors
Daniela Maizel, Jodi S. Blum, Marcela A. Ferrero, Sagar M. Utturkar, Steven D. Brown, Barry P. Rosen, Ronald S. Oremland
A microbial arsenic cycle in sediments of an acidic mine impoundment: Herman Pit, Clear Lake, California A microbial arsenic cycle in sediments of an acidic mine impoundment: Herman Pit, Clear Lake, California
The involvement of prokaryotes in the redox reactions of arsenic occurring between its +5 [arsenate; As(V)] and +3 [arsenite; As(III)] oxidation states has been well established. Most research to date has focused upon circum-neutral pH environments (e.g., freshwater or estuarine sediments) or arsenic-rich “extreme” environments like hot springs and soda lakes. In contrast, relatively...
Authors
Jodi S. Blum, Shelley McCann, S. Bennett, Laurence G. Miller, J. R. Stolz, B. Stoneburner, C. Saltikov, Ronald S. Oremland
Microbiological reduction of Sb(V) in anoxic freshwater sediments Microbiological reduction of Sb(V) in anoxic freshwater sediments
Microbiological reduction of millimolar concentrations of Sb(V) to Sb(III) was observed in anoxic sediments from two freshwater settings: (1) a Sb- and As-contaminated mine site (Stibnite Mine) in central Idaho and 2) an uncontaminated suburban lake (Searsville Lake) in the San Francisco Bay Area. Rates of Sb(V) reduction in anoxic sediment microcosms and enrichment cultures were...
Authors
Ronald S. Oremland, Thomas R. Kulp, Laurence G. Miller, Franco Braiotta, Samuel M. Webb, Benjamin D Kocar, Jodi S. Blum
Desulfohalophilus alkaliarsenatis gen. nov., sp. nov., an extremely halophilic sulfate- and arsenate-respiring bacterium from Searles Lake, California Desulfohalophilus alkaliarsenatis gen. nov., sp. nov., an extremely halophilic sulfate- and arsenate-respiring bacterium from Searles Lake, California
A haloalkaliphilic sulfate-respiring bacterium, strain SLSR-1, was isolated from a lactate-fed stable enrichment culture originally obtained from the extreme environment of Searles Lake, California. The isolate proved capable of growth via sulfate-reduction over a broad range of salinities (125–330 g/L), although growth was slowest at salt-saturation. Strain SLSR-1 was also capable of...
Authors
Jodi Switzer Blum, Thomas R. Kulp, Sukkyun Han, Brian Lanoil, Chad W. Saltikov, John F. Stolz, Laurence G. Miller, Ronald S. Oremland
A bacterium that can grow by using arsenic instead of phosphorus A bacterium that can grow by using arsenic instead of phosphorus
Life is mostly composed of the elements carbon, hydrogen, nitrogen, oxygen, sulfur, and phosphorus. Although these six elements make up nucleic acids, proteins, and lipids and thus the bulk of living matter, it is theoretically possible that some other elements in the periodic table could serve the same functions. Here, we describe a bacterium, strain GFAJ-1 of the Halomonadaceae...
Authors
Felisa Wolfe-Simon, Jodi S. Blum, T.R. Kulp, Gordon W. Rattray, S.E. Hoeft, J. Pett-Ridge, J.F. Stolz, S.M. Webb, P.K. Weber, P.C.W. Davies, A.D. Anbar, R.S. Oremland
Microbiology: A microbial arsenic cycle in a salt-saturated, extreme environment Microbiology: A microbial arsenic cycle in a salt-saturated, extreme environment
Searles Lake is a salt-saturated, alkaline brine unusually rich in the toxic element arsenic. Arsenic speciation changed from arsenate [As(V)] to arsenite [As(III)] with sediment depth. Incubated anoxic sediment slurries displayed dissimilatory As(V)-reductase activity that was markedly stimulated by H2 or sulfide, whereas aerobic slurries had rapid As(III)-oxidase activity. An anaerobic
Authors
R.S. Oremland, T.R. Kulp, J.S. Blum, S.E. Hoeft, S. Baesman, L.G. Miller, J.F. Stolz