Multiple mechanisms for the targeting of photosystem I subunits F, H, K, L, and N into and across the thylakoid membrane
Multiple mechanisms for the targeting of photosystem I subunits F, H, K, L, and N into and across the thylakoid membrane
The photosystem I (PSI) complex in higher plants contains eight nuclear- encoded subunits, of which two (PSI-F and -N) are synthesized with bipartite presequences containing cleavable thylakoid transfer sequences. Previous studies on four other chloroplast proteins bearing bipartite presequences have shown that they are transported across the thylakoid membrane by two distinct mechanisms. One mechanism is ΔpH-dependent and hence sensitive to uncouplers, whereas the other is inhibited by azide. We show that PSI-F is targeted by the latter pathway, since its translocation across the thylakoid membrane is inhibited by azide but not by nigericin. Translocation is furthermore unaffected by the presence of high concentrations of the lumenal 23-kDa photosystem II (PSII) protein, which is known to be transported by the ΔpH-dependent pathway. In contrast, translocation of PSI-N across the thylakoid membrane is completely blocked by saturating concentrations of pre- 23-kDa protein. Three proteins are now known to be synthesized with thylakoid transfer signals in both higher plants and cyanobacteria (PSI-F, plastocyanin, and the 33-kDa PSII protein), and all three are transported by the azide-sensitive, possibly see-dependent pathway. In contrast, PSI-N and the 23-kDa and 16-kDa PSII proteins (transported by the ΔpH-driven pathway in higher plants) are all absent in cyanobacteria. These data suggest that the ΔpH-dependent translocation mechanism for these proteins may also have arisen relatively recently during the evolution of the chloroplast. Three additional PSI proteins (PSI-H, -K, and -L) are synthesized in the cytosol with stroma-targeting presequences and hence integrate into the thylakoid membrane by means of information in the mature proteins. We show that the integration mechanisms are insensitive to azide in each case, and nigericin causes only a slight inhibition of integration in each case. We therefore suggest that these proteins are targeted into the thylakoid membrane by a separate pathway(s).
27303-27309
Mant, Alexandra
63319e45-deeb-45ad-a30d-e05b42052a0d
Nielsen, Vibeke Skovgaard
e861adce-7ecc-4dd5-8cd2-4749f7774e19
Knott, Tracy G.
52a0b2aa-b57a-4d38-b808-333a7d1855a5
Møller, Birger Lindberg
3710d2e8-db6a-4a46-beab-b46fe819eba8
Robinson, Colin
678e0157-d628-44e8-83de-3591b07c673f
4 November 1994
Mant, Alexandra
63319e45-deeb-45ad-a30d-e05b42052a0d
Nielsen, Vibeke Skovgaard
e861adce-7ecc-4dd5-8cd2-4749f7774e19
Knott, Tracy G.
52a0b2aa-b57a-4d38-b808-333a7d1855a5
Møller, Birger Lindberg
3710d2e8-db6a-4a46-beab-b46fe819eba8
Robinson, Colin
678e0157-d628-44e8-83de-3591b07c673f
Mant, Alexandra, Nielsen, Vibeke Skovgaard, Knott, Tracy G., Møller, Birger Lindberg and Robinson, Colin
(1994)
Multiple mechanisms for the targeting of photosystem I subunits F, H, K, L, and N into and across the thylakoid membrane.
The Journal of Biological Chemistry, 269 (44), .
Abstract
The photosystem I (PSI) complex in higher plants contains eight nuclear- encoded subunits, of which two (PSI-F and -N) are synthesized with bipartite presequences containing cleavable thylakoid transfer sequences. Previous studies on four other chloroplast proteins bearing bipartite presequences have shown that they are transported across the thylakoid membrane by two distinct mechanisms. One mechanism is ΔpH-dependent and hence sensitive to uncouplers, whereas the other is inhibited by azide. We show that PSI-F is targeted by the latter pathway, since its translocation across the thylakoid membrane is inhibited by azide but not by nigericin. Translocation is furthermore unaffected by the presence of high concentrations of the lumenal 23-kDa photosystem II (PSII) protein, which is known to be transported by the ΔpH-dependent pathway. In contrast, translocation of PSI-N across the thylakoid membrane is completely blocked by saturating concentrations of pre- 23-kDa protein. Three proteins are now known to be synthesized with thylakoid transfer signals in both higher plants and cyanobacteria (PSI-F, plastocyanin, and the 33-kDa PSII protein), and all three are transported by the azide-sensitive, possibly see-dependent pathway. In contrast, PSI-N and the 23-kDa and 16-kDa PSII proteins (transported by the ΔpH-driven pathway in higher plants) are all absent in cyanobacteria. These data suggest that the ΔpH-dependent translocation mechanism for these proteins may also have arisen relatively recently during the evolution of the chloroplast. Three additional PSI proteins (PSI-H, -K, and -L) are synthesized in the cytosol with stroma-targeting presequences and hence integrate into the thylakoid membrane by means of information in the mature proteins. We show that the integration mechanisms are insensitive to azide in each case, and nigericin causes only a slight inhibition of integration in each case. We therefore suggest that these proteins are targeted into the thylakoid membrane by a separate pathway(s).
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Published date: 4 November 1994
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Local EPrints ID: 413059
URI: http://eprints.soton.ac.uk/id/eprint/413059
ISSN: 0021-9258
PURE UUID: b2e1ad0c-a0ae-46f3-bae8-f785c7bf2c88
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Date deposited: 14 Aug 2017 16:31
Last modified: 12 Dec 2021 03:27
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Author:
Alexandra Mant
Author:
Vibeke Skovgaard Nielsen
Author:
Tracy G. Knott
Author:
Birger Lindberg Møller
Author:
Colin Robinson
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