Prochlorococcus can use the Pro1404 transporter to take up glucose at nanomolar concentrations in the Atlantic Ocean
Prochlorococcus can use the Pro1404 transporter to take up glucose at nanomolar concentrations in the Atlantic Ocean
Prochlorococcus is responsible for a significant part of CO2 fixation in the ocean. Although it was long considered an autotrophic cyanobacterium, the uptake of organic compounds has been reported, assuming they were sources of limited biogenic elements. We have shown in laboratory experiments that Prochlorococcus can take up glucose. However, the mechanisms of glucose uptake and its occurrence in the ocean have not been shown. Here, we report that the gene Pro1404 confers capability for glucose uptake in Prochlorococcus marinus SS120. We used a cyanobacterium unable to take up glucose to engineer strains that express the Pro1404 gene. These recombinant strains were capable of specific glucose uptake over a wide range of glucose concentrations, showing multiphasic transport kinetics. The Ks constant of the high affinity phase was in the nanomolar range, consistent with the average concentration of glucose in the ocean. Furthermore, we were able to observe glucose uptake by Prochlorococcus in the central Atlantic Ocean, where glucose concentrations were 0.5–2.7 nM. Our results suggest that Prochlorococcus are primary producers capable of tuning their metabolism to energetically benefit from environmental conditions, taking up not only organic compounds with key limiting elements in the ocean, but also molecules devoid of such elements, like glucose.
high-affinity glucose transport, marine cyanobacteria, multiphasic uptake kinetics
8597-8602
Munoz-Marin, M. de C.
f5cf9e3b-8696-4dcd-8081-0845a20dc986
Luque, I.
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Zubkov, M.V.
b1dfb3a0-bcff-430c-9031-358a22b50743
Hill, P.G.
03ff729d-1c24-45f8-8bf7-3bcc9bf882e9
Diez, J.
93aff376-ab92-4a05-b721-970a1f77c37c
Garcia-Fernandez, J.M.
8deb0436-9a80-4aec-b5ec-d0dd021af583
May 2013
Munoz-Marin, M. de C.
f5cf9e3b-8696-4dcd-8081-0845a20dc986
Luque, I.
0a3cd65c-3565-4a83-9a43-cd40818cce5d
Zubkov, M.V.
b1dfb3a0-bcff-430c-9031-358a22b50743
Hill, P.G.
03ff729d-1c24-45f8-8bf7-3bcc9bf882e9
Diez, J.
93aff376-ab92-4a05-b721-970a1f77c37c
Garcia-Fernandez, J.M.
8deb0436-9a80-4aec-b5ec-d0dd021af583
Munoz-Marin, M. de C., Luque, I., Zubkov, M.V., Hill, P.G., Diez, J. and Garcia-Fernandez, J.M.
(2013)
Prochlorococcus can use the Pro1404 transporter to take up glucose at nanomolar concentrations in the Atlantic Ocean.
Proceedings of the National Academy of Sciences, 110 (21), .
(doi:10.1073/pnas.1221775110).
Abstract
Prochlorococcus is responsible for a significant part of CO2 fixation in the ocean. Although it was long considered an autotrophic cyanobacterium, the uptake of organic compounds has been reported, assuming they were sources of limited biogenic elements. We have shown in laboratory experiments that Prochlorococcus can take up glucose. However, the mechanisms of glucose uptake and its occurrence in the ocean have not been shown. Here, we report that the gene Pro1404 confers capability for glucose uptake in Prochlorococcus marinus SS120. We used a cyanobacterium unable to take up glucose to engineer strains that express the Pro1404 gene. These recombinant strains were capable of specific glucose uptake over a wide range of glucose concentrations, showing multiphasic transport kinetics. The Ks constant of the high affinity phase was in the nanomolar range, consistent with the average concentration of glucose in the ocean. Furthermore, we were able to observe glucose uptake by Prochlorococcus in the central Atlantic Ocean, where glucose concentrations were 0.5–2.7 nM. Our results suggest that Prochlorococcus are primary producers capable of tuning their metabolism to energetically benefit from environmental conditions, taking up not only organic compounds with key limiting elements in the ocean, but also molecules devoid of such elements, like glucose.
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Published date: May 2013
Keywords:
high-affinity glucose transport, marine cyanobacteria, multiphasic uptake kinetics
Organisations:
Marine Biogeochemistry
Identifiers
Local EPrints ID: 355653
URI: http://eprints.soton.ac.uk/id/eprint/355653
ISSN: 0027-8424
PURE UUID: f4e63331-cbb6-4ced-a10b-3bc74251f2c9
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Date deposited: 09 Aug 2013 16:01
Last modified: 14 Mar 2024 14:36
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Contributors
Author:
M. de C. Munoz-Marin
Author:
I. Luque
Author:
M.V. Zubkov
Author:
P.G. Hill
Author:
J. Diez
Author:
J.M. Garcia-Fernandez
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