Your search keyword '"Cutter LS"' showing total 6 results

1. Microbial rhodopsins are major contributors to the solar energy captured in the sea

Author

Gómez-Consarnau, L, Raven, JA, Levine, NM, Cutter, LS, Wang, D, Seegers, B, Arístegui, J, Fuhrman, JA, Gasol, JM, Sañudo-Wilhelmy, SA, Gómez-Consarnau, L, Raven, JA, Levine, NM, Cutter, LS, Wang, D, Seegers, B, Arístegui, J, Fuhrman, JA, Gasol, JM, and Sañudo-Wilhelmy, SA

Abstract

Copyright © 2019 The Authors, some rights reserved; All known phototrophic metabolisms on Earth rely on one of three categories of energy-converting pigments: chlorophyll-a (rarely -d), bacteriochlorophyll-a (rarely -b), and retinal, which is the chromophore in rhodopsins. While the significance of chlorophylls in solar energy capture has been studied for decades, the contribution of retinal-based phototrophy to this process remains largely unexplored. We report the first vertical distributions of the three energy-converting pigments measured along a contrasting nutrient gradient through the Mediterranean Sea and the Atlantic Ocean. The highest rhodopsin concentrations were observed above the deep chlorophyll-a maxima, and their geographical distribution tended to be inversely related to that of chlorophyll-a. We further show that proton-pumping proteorhodopsins potentially absorb as much light energy as chlorophyll-a–based phototrophy and that this energy is sufficient to sustain bacterial basal metabolism. This suggests that proteorhodopsins are a major energy-transducing mechanism to harvest solar energy in the surface ocean.

Published

2019

2. Growth rate-dependent synthesis of halomethanes in marine heterotrophic bacteria and its implications for the ozone layer recovery.

Author

Gómez-Consarnau L, Klein NJ, Cutter LS, and Sañudo-Wilhelmy SA

Subjects

Bacteria genetics, Climate, Global Warming, Humans, Ozone, Stratospheric Ozone

Abstract

Halomethanes (e.g., CH 3 Cl, CH 3 Br, CH 3 I and CHBr 3 ) are ozone-depleting compounds that, in contrast to the human-made chlorofluorocarbons, marine organisms synthesize naturally. Therefore, their production cannot be totally controlled by human action. However, identifying all their natural sources and understanding their synthesis regulation can help to predict their production rates and their impact on the future recovery of the Earth's ozone layer. Here we show that the synthesis of mono-halogenated halocarbons CH 3 Cl, CH 3 Br, and CH 3 I is a generalized process in representatives of the major marine heterotrophic bacteria groups. Furthermore, halomethane production was growth rate dependent in all the strains we studied, implying uniform synthesis regulation patterns among bacterioplankton. Using these experimental observations and in situ halomethane concentrations, we further evaluated the potential production rates associated with higher bacterial growth rates in response to global warming in a coastal environment within the Southern California Bight. Our estimates show that a 3°C temperature rise would translate into a 35%-84% increase in halomethane production rate by 2100. Overall, these data suggest that marine heterotrophic bacteria are significant producers of these climate-relevant gases and that their contribution to the atmospheric halogen budget could increase in the future, impacting the ozone layer recovery., (© 2020 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2021

3. Microbial rhodopsins are major contributors to the solar energy captured in the sea.

Author

Gómez-Consarnau L, Raven JA, Levine NM, Cutter LS, Wang D, Seegers B, Arístegui J, Fuhrman JA, Gasol JM, and Sañudo-Wilhelmy SA

Abstract

All known phototrophic metabolisms on Earth rely on one of three categories of energy-converting pigments: chlorophyll- a (rarely - d ), bacteriochlorophyll- a (rarely - b ), and retinal, which is the chromophore in rhodopsins. While the significance of chlorophylls in solar energy capture has been studied for decades, the contribution of retinal-based phototrophy to this process remains largely unexplored. We report the first vertical distributions of the three energy-converting pigments measured along a contrasting nutrient gradient through the Mediterranean Sea and the Atlantic Ocean. The highest rhodopsin concentrations were observed above the deep chlorophyll- a maxima, and their geographical distribution tended to be inversely related to that of chlorophyll- a . We further show that proton-pumping proteorhodopsins potentially absorb as much light energy as chlorophyll- a -based phototrophy and that this energy is sufficient to sustain bacterial basal metabolism. This suggests that proteorhodopsins are a major energy-transducing mechanism to harvest solar energy in the surface ocean.

Published

2019

4. Mosaic patterns of B-vitamin synthesis and utilization in a natural marine microbial community.

Author

Gómez-Consarnau L, Sachdeva R, Gifford SM, Cutter LS, Fuhrman JA, Sañudo-Wilhelmy SA, and Moran MA

Subjects

Alphaproteobacteria genetics, Alphaproteobacteria metabolism, Bacteria genetics, Coenzymes biosynthesis, Coenzymes metabolism, Flavobacteriaceae genetics, Flavobacteriaceae metabolism, Transcriptome, Vitamin B Complex biosynthesis, Bacteria metabolism, Microbial Consortia, Vitamin B Complex metabolism

Abstract

Aquatic environments contain large communities of microorganisms whose synergistic interactions mediate the cycling of major and trace nutrients, including vitamins. B-vitamins are essential coenzymes that many organisms cannot synthesize. Thus, their exchange among de novo synthesizers and auxotrophs is expected to play an important role in the microbial consortia and explain some of the temporal and spatial changes observed in diversity. In this study, we analyzed metatranscriptomes of a natural marine microbial community, diel sampled quarterly over one year to try to identify the potential major B-vitamin synthesizers and consumers. Transcriptomic data showed that the best-represented taxa dominated the expression of synthesis genes for some B-vitamins but lacked transcripts for others. For instance, Rhodobacterales dominated the expression of vitamin-B 12 synthesis, but not of vitamin-B 7 , whose synthesis transcripts were mainly represented by Flavobacteria. In contrast, bacterial groups that constituted less than 4% of the community (e.g., Verrucomicrobia) accounted for most of the vitamin-B 1 synthesis transcripts. Furthermore, ambient vitamin-B 1 concentrations were higher in samples collected during the day, and were positively correlated with chlorophyll-a concentrations. Our analysis supports the hypothesis that the mosaic of metabolic interdependencies through B-vitamin synthesis and exchange are key processes that contribute to shaping microbial communities in nature., (© 2018 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2018

5. Multiple B-vitamin depletion in large areas of the coastal ocean.

Author

Sañudo-Wilhelmy SA, Cutter LS, Durazo R, Smail EA, Gómez-Consarnau L, Webb EA, Prokopenko MG, Berelson WM, and Karl DM

Subjects

Biotin analysis, Biotin metabolism, California, Carbon metabolism, Chromatography, Liquid methods, Ecosystem, Food, Methionine analysis, Methionine metabolism, Oceanography methods, Oceans and Seas, Phytoplankton growth & development, Riboflavin analysis, Riboflavin metabolism, Salinity, Tandem Mass Spectrometry methods, Thiamine analysis, Thiamine metabolism, Vitamin B 12 analysis, Vitamin B 12 metabolism, Vitamin B 6 analysis, Vitamin B 6 metabolism, Vitamin B Complex analysis, Marine Biology methods, Phytoplankton metabolism, Seawater chemistry, Seawater microbiology, Vitamin B Complex metabolism

Abstract

B vitamins are some of the most commonly required biochemical cofactors in living systems. Therefore, cellular metabolism of marine vitamin-requiring (auxotrophic) phytoplankton and bacteria would likely be significantly compromised if B vitamins (thiamin B(1), riboflavin B(2), pyridoxine B(6), biotin B(7), and cobalamin B(12)) were unavailable. However, the factors controlling the synthesis, ambient concentrations, and uptake of these key organic compounds in the marine environment are still not well understood. Here, we report vertical distributions of five B vitamins (and the amino acid methionine) measured simultaneously along a latitudinal gradient through the contrasting oceanographic regimes of the southern California-Baja California coast in the Northeast Pacific margin. Although vitamin concentrations ranged from below the detection limits of our technique to 30 pM for B(2) and B(12) and to ∼500 pM for B(1), B(6), and B(7), each vitamin showed a different geographical and depth distribution. Vitamin concentrations were independent of each other and of inorganic nutrient levels, enriched primarily in the upper mesopelagic zone (depth of 100-300 m), and associated with water mass origin. Moreover, vitamin levels were below our detection limits (ranging from ≤0.18 pM for B(12) to ≤0.81 pM for B(1)) in extensive areas (100s of kilometers) of the coastal ocean, and thus may exert important constraints on the taxonomic composition of phytoplankton communities, and potentially also on rates of primary production and carbon sequestration.

Published

2012

6. Aeolian contamination of Se and Ag in the North Pacific from Asian fossil fuel combustion.

Author

Ranville MA, Cutter GA, Buck CS, Landing WM, Cutter LS, Resing JA, and Flegal AR

Subjects

Air Pollutants analysis, Asia, Climate, Environmental Pollutants analysis, Pacific Ocean, Sample Size, Seasons, Solutions, Fossil Fuels adverse effects, Seawater analysis, Selenium analysis, Silver analysis, Water Pollutants, Chemical analysis

Abstract

Energy production from fossil fuels, and in particular the burning of coal in China, creates atmospheric contamination that is transported across the remote North Pacific with prevailing westerly winds. In recent years this pollution from within Asia has increased dramatically, as a consequence of vigorous economic growth and corresponding energy consumption. During the fourth Intergovernmental Oceanographic Commission baseline contaminant survey in the western Pacific Ocean from May to June, 2002, surface waters and aerosol samples were measured to investigate whether atmospheric deposition of trace elements to the surface North Pacific was altering trace element biogeochemical cycling. Results show a presumably anthropogenic enrichment of Ag and of Se, which is a known tracer of coal combustion, in the North Pacific atmosphere and surface waters. Additionally, a strong correlation was seen between dissolved Ag and Se concentrations in surface waters. This suggests that Ag should now also be considered a geochemical tracer for coal combustion, and provides further evidence that Ag exhibits a disturbed biogeochemical cycle as the result of atmospheric deposition to the North Pacific.

Published

2010