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High-light-inducible proteins control associations between chlorophyll synthase and the Photosystem II biogenesis factor Ycf39

High-light-inducible proteins control associations between chlorophyll synthase and the Photosystem II biogenesis factor Ycf39
High-light-inducible proteins control associations between chlorophyll synthase and the Photosystem II biogenesis factor Ycf39

The biogenesis of Photosystem II is a complicated process requiring numerous auxiliary factors to assist in all steps of its assembly. The cyanobacterial protein Ycf39 forms a stress-induced complex with 2 small chlorophyll-binding, High-light-inducible proteins C and D (HliC and HliD), and has been reported to participate in the insertion of chlorophyll molecules into the central D1 subunit of Photosystem II. However, how this process is organized remains unknown. Here, we show that Ycf39 and both HliC and HliD can form distinct complexes with chlorophyll synthase (ChlG) in the model cyanobacterium Synechocystis sp. PCC 6803. We isolated and characterized ChlG complexes from various strains grown under different conditions and provide a mechanistic view of the docking of Ycf39 to ChlG via HliD and the structural role of HliC. In the absence of stress, chlorophyll is produced by the ChlG-HliD2-ChlG complex, which is stabilized by chlorophyll and zeaxanthin molecules bound to the HliD homodimer. The switch to high light leads to stress pressure and greatly elevated synthesis of HliC, resulting in the replacement of HliD homodimers with HliC-HliD heterodimers. Unlike HliD, HliC cannot interact directly with ChlG or Ycf39. Therefore, the original ChlG-HliD2-ChlG complex is converted into a ChlG-HliD-HliC hetero-trimer that presumably binds transiently to Ycf39 and the nascent D1 polypeptide. We speculate that this molecular machinery promotes the delivery of chlorophyll to D1 upon high-light-induced chlorophyll deficiency. The HliD homodimers formed under standard, nonstress growth conditions and attached to ChlG could serve as an emergency chlorophyll reserve.

0032-0889
Wysocka, Anna
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Kulik, Natalia
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Shukla, Mahendra K
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Opatíková, Monika
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Kouřil, Roman
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Jackson, Philip J.
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Brindley, Amanda A.
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Janouškovec, Jan
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Kiss, Éva
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Hitchcock, Andrew
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Komenda, Josef
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Hunter, C. Neil
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Sobotka, Roman
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Wysocka, Anna
b5feeb81-1867-4a06-b05e-d7b95775159e
Kulik, Natalia
2ea46680-d3f6-478f-aac9-927e52daaf15
Shukla, Mahendra K
ec25d803-5a51-4e10-92b2-933244e74f7b
Opatíková, Monika
c31777e1-5ee8-425c-9e70-bdea620fb57f
Kouřil, Roman
58de0ea9-337b-422a-872d-506f53e8d81b
Jackson, Philip J.
01e45068-e098-486c-85ad-4333f4f0a33f
Brindley, Amanda A.
5736a351-5ea2-4484-867d-f34420efa8eb
Janouškovec, Jan
fbaa4a5d-872e-465b-b2c3-bb35df455cc6
Kiss, Éva
8c3bea65-95a4-497b-8f17-3c5a48674e31
Hitchcock, Andrew
a2bfbf37-97f5-4bd8-bf2f-a2035356b511
Komenda, Josef
fbc50fa0-2c03-4e98-9726-583b5e7dc289
Hunter, C. Neil
d738ea61-3cf9-47fb-957a-a04b96330f26
Sobotka, Roman
8141039e-3909-441d-8523-0e1802372e6e

Wysocka, Anna, Kulik, Natalia, Shukla, Mahendra K, Opatíková, Monika, Kouřil, Roman, Jackson, Philip J., Brindley, Amanda A., Janouškovec, Jan, Kiss, Éva, Hitchcock, Andrew, Komenda, Josef, Hunter, C. Neil and Sobotka, Roman (2025) High-light-inducible proteins control associations between chlorophyll synthase and the Photosystem II biogenesis factor Ycf39. Plant Physiology, 198 (2), [kiaf213]. (doi:10.1093/plphys/kiaf213).

Record type: Article

Abstract

The biogenesis of Photosystem II is a complicated process requiring numerous auxiliary factors to assist in all steps of its assembly. The cyanobacterial protein Ycf39 forms a stress-induced complex with 2 small chlorophyll-binding, High-light-inducible proteins C and D (HliC and HliD), and has been reported to participate in the insertion of chlorophyll molecules into the central D1 subunit of Photosystem II. However, how this process is organized remains unknown. Here, we show that Ycf39 and both HliC and HliD can form distinct complexes with chlorophyll synthase (ChlG) in the model cyanobacterium Synechocystis sp. PCC 6803. We isolated and characterized ChlG complexes from various strains grown under different conditions and provide a mechanistic view of the docking of Ycf39 to ChlG via HliD and the structural role of HliC. In the absence of stress, chlorophyll is produced by the ChlG-HliD2-ChlG complex, which is stabilized by chlorophyll and zeaxanthin molecules bound to the HliD homodimer. The switch to high light leads to stress pressure and greatly elevated synthesis of HliC, resulting in the replacement of HliD homodimers with HliC-HliD heterodimers. Unlike HliD, HliC cannot interact directly with ChlG or Ycf39. Therefore, the original ChlG-HliD2-ChlG complex is converted into a ChlG-HliD-HliC hetero-trimer that presumably binds transiently to Ycf39 and the nascent D1 polypeptide. We speculate that this molecular machinery promotes the delivery of chlorophyll to D1 upon high-light-induced chlorophyll deficiency. The HliD homodimers formed under standard, nonstress growth conditions and attached to ChlG could serve as an emergency chlorophyll reserve.

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Accepted/In Press date: 14 April 2025
e-pub ahead of print date: 25 May 2025
Published date: 6 June 2025

Identifiers

Local EPrints ID: 502842
URI: http://eprints.soton.ac.uk/id/eprint/502842
DOI: doi:10.1093/plphys/kiaf213
ISSN: 0032-0889
PURE UUID: 34f744ad-c9a9-48c9-a6d3-feff9f497e00
ORCID for Jan Janouškovec: ORCID iD orcid.org/0000-0001-6547-749X

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Date deposited: 09 Jul 2025 16:36
Last modified: 22 Aug 2025 02:34

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Contributors

Author: Anna Wysocka
Author: Natalia Kulik
Author: Mahendra K Shukla
Author: Monika Opatíková
Author: Roman Kouřil
Author: Philip J. Jackson
Author: Amanda A. Brindley
Author: Jan Janouškovec ORCID iD
Author: Éva Kiss
Author: Andrew Hitchcock
Author: Josef Komenda
Author: C. Neil Hunter
Author: Roman Sobotka

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