Cytochrome b₆f complex

Cytochrome b6f complex
Crystal structure of the cytochrome b6f complex from C. reinhardtii (1q90). Hydrocarbon boundaries of the lipid bilayer are shown by red and blue lines (thylakoid space side and stroma side, respectively).
Identifiers
Symbol	B6F
TCDB	3.D.3
OPM superfamily	92
OPM protein	4pv1
Membranome	258

The cytochrome b₆f complex (plastoquinol/plastocyanin reductase or plastoquinol/plastocyanin oxidoreductase; EC 7.1.1.6) is an enzyme found in the thylakoid membrane in chloroplasts of plants, cyanobacteria, and green algae, that catalyzes the transfer of electrons from plastoquinol to plastocyanin:

plastoquinol + 2 oxidized plastocyanin + 2 H⁺ [side 1] ${\displaystyle \rightleftharpoons }$ plastoquinone + 2 reduced plastocyanin + 4 H⁺ [side 2].^[1]

The reaction is analogous to the reaction catalyzed by cytochrome bc₁ (Complex III) of the mitochondrial electron transport chain. During photosynthesis, the cytochrome b₆f complex is one step along the chain that transfers electrons from Photosystem II to Photosystem I, and at the same time pumps protons into the thylakoid space, contributing to the generation of an electrochemical (energy) gradient^[2] that is later used to synthesize ATP from ADP.

Enzyme structure[edit]

The cytochrome b₆f complex is a dimer, with each monomer composed of eight subunits.^[3] These consist of four large subunits: a 32 kDa cytochrome f with a c-type cytochrome, a 25 kDa cytochrome b₆ with a low- and high-potential heme group, a 19 kDa Rieske iron-sulfur protein containing a [2Fe-2S] cluster, and a 17 kDa subunit IV; along with four small subunits (3-4 kDa): PetG, PetL, PetM, and PetN.^[3][4] The total molecular weight is 217 kDa.

The crystal structures of cytochrome b₆f complexes from Chlamydomonas reinhardtii, Mastigocladus laminosus, and Nostoc sp. PCC 7120 have been determined.^{[2][5][6][7][8][9]}

The core of the complex is structurally similar to the cytochrome bc₁ core. Cytochrome b₆ and subunit IV are homologous to cytochrome b,^[10] and the Rieske iron-sulfur proteins of the two complexes are homologous.^[11] However, cytochrome f and cytochrome c₁ are not homologous.^[12]

Cytochrome b₆f contains seven prosthetic groups.^[13][14] Four are found in both cytochrome b₆f and bc₁: the c-type heme of cytochrome c₁ and f, the two b-type hemes (b_p and b_n) in bc₁ and b₆f, and the [2Fe-2S] cluster of the Rieske protein. Three unique prosthetic groups are found in cytochrome b₆f: chlorophyll a, β-carotene, and heme c_n (also known as heme x).^[5]

The inter-monomer space within the core of the cytochrome b6f complex dimer is occupied by lipids,^[9] which provides directionality to heme-heme electron transfer through modulation of the intra-protein dielectric environment.^[15]

Biological function[edit]

In photosynthesis, the cytochrome b₆f complex functions to mediate the transfer of electrons and of energy between the two photosynthetic reaction center complexes, Photosystem II and Photosystem I, while transferring protons from the chloroplast stroma across the thylakoid membrane into the lumen.^[2] Electron transport via cytochrome b₆f is responsible for creating the proton gradient that drives the synthesis of ATP in chloroplasts.^[4]

In a separate reaction, the cytochrome b₆f complex plays a central role in cyclic photophosphorylation, when NADP⁺ is not available to accept electrons from reduced ferredoxin.^[16] This cycle, driven by the energy of P700⁺, contributes to the creation of a proton gradient that can be used to drive ATP synthesis. It has been shown that this cycle is essential for photosynthesis,^[17] helping to maintain the proper ratio of ATP/NADPH production for carbon fixation.^[18][19]

The p-side quinol deprotonation-oxidation reactions within the cytochrome b6f complex have been implicated in the generation of reactive oxygen species.^[20] An integral chlorophyll molecule located within the quinol oxidation site has been suggested to perform a structural, non-photochemical function in enhancing the rate of formation of the reactive oxygen species, possibly to provide a redox-pathway for intra-cellular communication.^[21]

Reaction mechanism[edit]

The cytochrome b₆f complex is responsible for "non-cyclic" (1) and "cyclic" (2) electron transfer between two mobile redox carriers, plastoquinol (QH₂) and plastocyanin (Pc):

Cytochrome b₆f catalyzes the transfer of electrons from plastoquinol to plastocyanin, while pumping two protons from the stroma into the thylakoid lumen:

QH₂ + 2Pc(Cu²⁺) + 2H⁺ (stroma) → Q + 2Pc(Cu⁺) + 4H⁺ (lumen)^[16]

This reaction occurs through the Q cycle as in Complex III.^[22] Plastoquinol acts as the electron carrier, transferring its two electrons to high- and low-potential electron transport chains (ETC) via a mechanism called electron bifurcation.^[23] The complex contains up to three plastoquinone molecules that form an electron transfer network that are responsible for the operation of the Q cycle and its redox-sensing and catalytic functions in photosynthesis.^[24]

Q cycle[edit]

First half of Q cycle

1. QH₂ binds to the positive 'p' side (lumen side) of the complex. It is oxidized to a semiquinone (SQ) by the iron-sulfur center (high-potential ETC) and releases two protons to the thylakoid lumen^{[citation needed]}.
2. The reduced iron-sulfur center transfers its electron through cytochrome f to Pc.
3. In the low-potential ETC, SQ transfers its electron to heme b_p of cytochrome b6.
4. Heme b_p then transfers the electron to heme b_n.
5. Heme b_n reduces Q with one electron to form SQ.

Second half of Q cycle

1. A second QH₂ binds to the complex.
2. In the high-potential ETC, one electron reduces another oxidized Pc.
3. In the low-potential ETC, the electron from heme b_n is transferred to SQ, and the completely reduced Q²⁻ takes up two protons from the stroma to form QH₂.
4. The oxidized Q and the reduced QH₂ that has been regenerated diffuse into the membrane.

Cyclic electron transfer[edit]

Unlike Complex III, cytochrome b₆f catalyzes another electron transfer reaction that is central to cyclic photophosphorylation. The electron from ferredoxin (Fd) is transferred to plastoquinone and then the cytochrome b₆f complex to reduce plastocyanin, which is reoxidized by P700 in Photosystem I.^[25] The exact mechanism of the reduction of plastoquinone by ferredoxin is still under investigation. One proposal is that there exists a ferredoxin:plastoquinone-reductase or an NADP dehydrogenase.^[25] Since heme x does not appear to be required for the Q cycle and is not found in Complex III, it has been proposed that it is used for cyclic photophosphorylation by the following mechanism:^[23][26]

1. Fd (red) + heme x (ox) → Fd (ox) + heme x (red)
2. heme x (red) + Fd (red) + Q + 2H⁺ → heme x (ox) + Fd (ox) + QH₂

References[edit]

Further reading[edit]

• Sarewicz, M; Pintscher, S; Pietras, R; Borek, A; Bujnowicz, Ł; Hanke, G; Cramer, WA; Finazzi, G; Osyczka, A (24 February 2021). "Catalytic Reactions and Energy Conservation in the Cytochrome bc(1) and b(6)f Complexes of Energy-Transducing Membranes". Chemical Reviews. 121 (4): 2020–2108. doi:10.1021/acs.chemrev.0c00712. PMC 7908018. PMID 33464892.

External links[edit]

• Structure-Function Studies of the Cytochrome b₆f Complex - Current research on cytochrome b₆f in William Cramer's Lab at Purdue University, USA
• UMich Orientation of Proteins in Membranes families/superfamily-3 - Calculated positions of b6f and related complexes in membranes
• Cytochrome+b6f+Complex at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
• Plastoquinol-plastocyanin+reductase at the U.S. National Library of Medicine Medical Subject Headings (MeSH)