Differential assimilation of inorganic carbon and leucine by Prochlorococcus in the oligotrophic North Pacific Subtropical Gyre

The light effect on photoheterotrophic processes in Prochlorococcus, and primary and bacterial productivity in the oligotrophic North Pacific Subtropical Gyre was investigated using 14C-bicarbonate and 3H-leucine. Light and dark incubation experiments were conducted in situ throughout the euphotic z...

Full description

Bibliographic Details
Main Authors: Karin M. Björkman, Matthew J. Church, Joseph K. Doggett, David M. Karl
Format: Article
Language:English
Published: Frontiers Media S.A. 2015-12-01
Series:Frontiers in Microbiology
Subjects:
Online Access:http://journal.frontiersin.org/Journal/10.3389/fmicb.2015.01401/full
id doaj-f4c2ea83a8194976a1708e23253d1f94
record_format Article
spelling doaj-f4c2ea83a8194976a1708e23253d1f942020-11-24T22:09:19ZengFrontiers Media S.A.Frontiers in Microbiology1664-302X2015-12-01610.3389/fmicb.2015.01401171638Differential assimilation of inorganic carbon and leucine by Prochlorococcus in the oligotrophic North Pacific Subtropical GyreKarin M. Björkman0Karin M. Björkman1Matthew J. Church2Matthew J. Church3Joseph K. Doggett4Joseph K. Doggett5David M. Karl6David M. Karl7University of HawaiiUniversity of HawaiiUniversity of HawaiiUniversity of HawaiiUniversity of HawaiiUniversity of HawaiiUniversity of HawaiiUniversity of HawaiiThe light effect on photoheterotrophic processes in Prochlorococcus, and primary and bacterial productivity in the oligotrophic North Pacific Subtropical Gyre was investigated using 14C-bicarbonate and 3H-leucine. Light and dark incubation experiments were conducted in situ throughout the euphotic zone (0-175 m) on nine expeditions to Station ALOHA over a three-year period. Photosynthetrons were also used to elucidate rate responses in leucine and inorganic carbon assimilation as a function of light intensity. Taxonomic group and cell-specific rates were assessed using flow cytometric sorting. The light:dark assimilation rate ratios of leucine in the top 150 m were ~7:1 for Prochlorococcus, whereas the light:dark ratio for the non-pigmented bacteria was not significant different from 1:1. Prochlorococcus assimilated leucine in the dark at per cell rates similar to the non-pigmented bacteria, with a contribution to the total community bacterial production, integrated over the euphotic zone, of approximately 20% in the dark and 60% in the light. Depth-resolved primary productivity and leucine incorporation showed that the ratio of Prochlorococcus leucine:primary production peaked at 100 m then declined steeply below the deep chlorophyll maximum (DCM). The photosynthetron experiments revealed that, for Prochlorococcus at the DCM, the saturating irradiance (Ek) for leucine incorporation was reached at approximately half the light intensity required for light saturation of 14C-bicarbonate assimilation. Additionally, high and low red fluorescing Prochlorococcus populations (HRF and LRF), co-occurring at the DCM, had similar Ek values for their respective substrates, however, maximum assimilation rates, for both leucine and inorganic carbon, were two times greater for HRF cells. Our results show that Prochlorococcus contributes significantly to bacterial production estimates using 3H-leucine, whether or not the incubations are conducted in the dark or light, and this should be considered when making assessments of bacterial production in marine environments where Prochlorococcus is present. Furthermore, Prochlorococcus primary productivity showed rate to light-flux patterns that were different from its light enhanced leucine incorporation. This decoupling from autotrophic growth may indicate a separate light stimulated mechanism for leucine acquisition.http://journal.frontiersin.org/Journal/10.3389/fmicb.2015.01401/fullProchlorococcusRadioisotopesPhotoheterotrophyNorth Pacific Subtropical GyreStation ALOHAFlow cytometric cell sorting
collection DOAJ
language English
format Article
sources DOAJ
author Karin M. Björkman
Karin M. Björkman
Matthew J. Church
Matthew J. Church
Joseph K. Doggett
Joseph K. Doggett
David M. Karl
David M. Karl
spellingShingle Karin M. Björkman
Karin M. Björkman
Matthew J. Church
Matthew J. Church
Joseph K. Doggett
Joseph K. Doggett
David M. Karl
David M. Karl
Differential assimilation of inorganic carbon and leucine by Prochlorococcus in the oligotrophic North Pacific Subtropical Gyre
Frontiers in Microbiology
Prochlorococcus
Radioisotopes
Photoheterotrophy
North Pacific Subtropical Gyre
Station ALOHA
Flow cytometric cell sorting
author_facet Karin M. Björkman
Karin M. Björkman
Matthew J. Church
Matthew J. Church
Joseph K. Doggett
Joseph K. Doggett
David M. Karl
David M. Karl
author_sort Karin M. Björkman
title Differential assimilation of inorganic carbon and leucine by Prochlorococcus in the oligotrophic North Pacific Subtropical Gyre
title_short Differential assimilation of inorganic carbon and leucine by Prochlorococcus in the oligotrophic North Pacific Subtropical Gyre
title_full Differential assimilation of inorganic carbon and leucine by Prochlorococcus in the oligotrophic North Pacific Subtropical Gyre
title_fullStr Differential assimilation of inorganic carbon and leucine by Prochlorococcus in the oligotrophic North Pacific Subtropical Gyre
title_full_unstemmed Differential assimilation of inorganic carbon and leucine by Prochlorococcus in the oligotrophic North Pacific Subtropical Gyre
title_sort differential assimilation of inorganic carbon and leucine by prochlorococcus in the oligotrophic north pacific subtropical gyre
publisher Frontiers Media S.A.
series Frontiers in Microbiology
issn 1664-302X
publishDate 2015-12-01
description The light effect on photoheterotrophic processes in Prochlorococcus, and primary and bacterial productivity in the oligotrophic North Pacific Subtropical Gyre was investigated using 14C-bicarbonate and 3H-leucine. Light and dark incubation experiments were conducted in situ throughout the euphotic zone (0-175 m) on nine expeditions to Station ALOHA over a three-year period. Photosynthetrons were also used to elucidate rate responses in leucine and inorganic carbon assimilation as a function of light intensity. Taxonomic group and cell-specific rates were assessed using flow cytometric sorting. The light:dark assimilation rate ratios of leucine in the top 150 m were ~7:1 for Prochlorococcus, whereas the light:dark ratio for the non-pigmented bacteria was not significant different from 1:1. Prochlorococcus assimilated leucine in the dark at per cell rates similar to the non-pigmented bacteria, with a contribution to the total community bacterial production, integrated over the euphotic zone, of approximately 20% in the dark and 60% in the light. Depth-resolved primary productivity and leucine incorporation showed that the ratio of Prochlorococcus leucine:primary production peaked at 100 m then declined steeply below the deep chlorophyll maximum (DCM). The photosynthetron experiments revealed that, for Prochlorococcus at the DCM, the saturating irradiance (Ek) for leucine incorporation was reached at approximately half the light intensity required for light saturation of 14C-bicarbonate assimilation. Additionally, high and low red fluorescing Prochlorococcus populations (HRF and LRF), co-occurring at the DCM, had similar Ek values for their respective substrates, however, maximum assimilation rates, for both leucine and inorganic carbon, were two times greater for HRF cells. Our results show that Prochlorococcus contributes significantly to bacterial production estimates using 3H-leucine, whether or not the incubations are conducted in the dark or light, and this should be considered when making assessments of bacterial production in marine environments where Prochlorococcus is present. Furthermore, Prochlorococcus primary productivity showed rate to light-flux patterns that were different from its light enhanced leucine incorporation. This decoupling from autotrophic growth may indicate a separate light stimulated mechanism for leucine acquisition.
topic Prochlorococcus
Radioisotopes
Photoheterotrophy
North Pacific Subtropical Gyre
Station ALOHA
Flow cytometric cell sorting
url http://journal.frontiersin.org/Journal/10.3389/fmicb.2015.01401/full
work_keys_str_mv AT karinmbjorkman differentialassimilationofinorganiccarbonandleucinebyprochlorococcusintheoligotrophicnorthpacificsubtropicalgyre
AT karinmbjorkman differentialassimilationofinorganiccarbonandleucinebyprochlorococcusintheoligotrophicnorthpacificsubtropicalgyre
AT matthewjchurch differentialassimilationofinorganiccarbonandleucinebyprochlorococcusintheoligotrophicnorthpacificsubtropicalgyre
AT matthewjchurch differentialassimilationofinorganiccarbonandleucinebyprochlorococcusintheoligotrophicnorthpacificsubtropicalgyre
AT josephkdoggett differentialassimilationofinorganiccarbonandleucinebyprochlorococcusintheoligotrophicnorthpacificsubtropicalgyre
AT josephkdoggett differentialassimilationofinorganiccarbonandleucinebyprochlorococcusintheoligotrophicnorthpacificsubtropicalgyre
AT davidmkarl differentialassimilationofinorganiccarbonandleucinebyprochlorococcusintheoligotrophicnorthpacificsubtropicalgyre
AT davidmkarl differentialassimilationofinorganiccarbonandleucinebyprochlorococcusintheoligotrophicnorthpacificsubtropicalgyre
_version_ 1725812589931266048