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Photosynthesis

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Photosynthetic organisms convert light to chemical energy. ... Within 10 ps one electron moves to a bacteriopheophytin molecule (Bpheo or BP) ... – PowerPoint PPT presentation

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Title: Photosynthesis


1
  • Photosynthesis
  • Step 1 conversion of light into redox energy.
  • Photosynthetic organisms convert light to
    chemical energy.
  • - Absorption of a photon changes a component's
    affinity for electrons from relatively
    electropositive (an electron acceptor) to highly
    electronegative (an electron donor).
  • Step 2 electron flow.
  • Through a cyclic pathway (eg. photosynthetic
    bacteria, electrons flow back re-reduce the
    original donor).
  • Through a non-cyclic pathway (eg. Thylakoid
    photosynthesis, electrons are transferred
    uphill'' from H2O to NADP).
  • Step 3 ATP produced via a proton gradient,
    analogous to mitochondria.
  • - Energy transducing membranes contain
    ATP-synthase.

2
Redox potentials
3
  • Structure of a Bacterial Reaction Centre
  • Reaction centre from Rhodopseudomonas viridis is
    built up from four sub-units (L, M, H a
    cytochrome).
  • - L (258 amino acids) M (273 amino acids) have
    25 sequence identity.
  • - Reaction centre contains four
    bacteriochlorophyll molecules (two of which form
    the special pair'') two bacteriopheophytin
    molecules (chlorophyll molecules without Mg2)
    two quinone molecules one Fe atom.
  • - The functional role of the Fe is (probably) to
    stabilize the four-helix bundle (removal does not
    affect electron transfer).
  • - The cytochrome subunit has four bound hemes
    delivers electrons to the special pair when
    oxidised).
  • First membrane protein structure solved
    Deisenhofer et al., Nature 318, 618 (1985).
  • Nobel prize in Chemistry in1988.

4
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5
  • The special pair''
  • The bacterial reaction centre of Rhodobacter
    sphaeroides contains
  • a chromophore which absorbs at 870 nm.
  • - Formed by two chlorophyll molecules
    approximately 7.6 Å apart.
  • - Labeled the special pair'', P870.
  • A chlorophyll molecule is like a heme but
    contains an Mg2 (rather than Fe2).
  • Absorb light in the visible region because they
    have conjugated double-bond systems.

6
  • Electron flow in the Bacterial Reaction Centres
  • Em,7 of the P870 /P870 couple is 500 mV (ie.
    electropositive).
  • Photoabsorption leads to an electronically
    excited species P870 which has an Em,7 -550 mV
    (ie. electronegative).
  • Within 10 ps one electron moves to a
    bacteriopheophytin molecule (Bpheo or BP).
  • - Like chorophyl but with Mg2 replaced by two
    protons.
  • - Pathway via a chlorophyll which flanks the
    special pair.
  • Within 200 ps the electron is transferred from
    Bphe- to a bound ubquinone (UQ), making a
    semi-quinone.
  • - Named the QA site.
  • Approximately 20 ms later the electron is
    transferred from the QA UQ, to the UQ at the QB
    site.

7
  • Second half of electron flow
  • The oxidised special pair P870 relaxes to
    its ground state (rather quickly) and becomes
    P870.
  • Since the Em,7 of the P870 / P870 couple is
    500 mV (ie. electropositive) it can be reduced by
    a cytochrome c2 (Em,7 of the cytochrome c2 ox/red
    couple of 340 mV).
  • Photo absorption leads to an electronically
    excited species P870 and again a second
    electron is transferred to the boundsemi-quinone
    at the UB site as above.
  • The bound UQ2- at site B then takes up two
    protons from the bulk phase, and is released at
    UQH2 (ie quinol) into the lipid bilayer.

8
  • Stabilisation of semi-quinone?
  • Structural studies of the light-adapted reaction
    centre show movements of quinol at QB site.
  • - Quinone accepts an electron and is reduced.
  • - H-bonding changes.
  • - Becomes more tightly bound reducing the danger
    of a highly reactive semi-quinol being released
    to membrane.
  • Not clear this study is truely physiological
    (ie. not steady-state conditions).

9
  • What happens to the electrons which reduce
    quinone to quinol?
  • Electrons donated to the membrane quinone/quinol
    pool.
  • Quinol donates electrons to the bc1 complex
    (complex IV, of the mitochondria).
  • The bc1-complex pumps protons passes the
    electrons to a cytochrome c2.
  • Cytochrome c2 returns the electrons to the
    reaction centre eventually back to the special
    pair.

10
  • Proton pumping by the bc1-complex
  • Structurally functionally related to the bc1
    complex of the mitochondria respiratory chain.
  • Two quinol binding sites in the bc1 complex.
  • - The Q0 site near the P-side of the membrane.
  • - The Q1 site near the N-side of the membrane.
  • One electron from the Q0 quinol binding site to
    the Q1 quinone binding site, and one (via the
    Reiske protein) to cytochrome c.
  • - Oxidation of UQH2 to UQ at Q0 releases two H.
  • - Reduction of UQ to UQH2 at Q1 takes up two H.
  • Overall two protons are taken up from the
    N-side four protons are released to the P-side,
    for every two quinol molecules to bind (Q-cycle).

11
  • Adding up protons
  • For the bacterial reaction centre every two
    photons cause two protons to be taken up from the
    N-side at the QB site.
  • Each quinol molecule to bind to the Q0 quinol
    binding site of the bf-complex causes
  • - Two protons to be released to the P-side.
  • In addition one electron flows to a quinone at
    the Q1 site.
  • - For every two UQH2 consumed at the Q0 site one
    UQH2 is recovered at the Q1 site.
  • - This can in turn be consumed at the Q0 site.
  • - The overall effect is that two further protons
    are released to the P-side taken up from the
    N-side per quinol generated by the bacterial
    reaction centre.
  • Totals two protons pumped per photon absorbed.

12
  • What happens to the proton gradient?
  • Proton pumping creates a proton-motive
    potential.
  • This potential is harvested by ATP-synthase.

13
  • Antennae
  • The reaction centre can turn-over 100 cycles per
    second.
  • - Even in bright sunlight photon-absorption
    rates insufficient.
  • Antennae complexes capture photons transfer
    the energy to the reaction centre.
  • - Absorbed light over a wide range of wavelengths
    lt 870 nm by an assembly of polypeptides with
    attached pigments.

Chlorophyll
Carotene
14
  • Light harvesting complex 1 (LH1)
  • - Forms the so-called core'' complex,
    intimately associated with the reaction centre.
  • - Contains 24 bacteriochlorophyll 24 carotenoid
    molecules.
  • Light harvesting complex II (LHII).
  • - Arranged surrounding the LH1 core.
  • - Nine transmembrane a-helix a-apopproteins are
    packed side-by-side to form a hollow 18 Å
    cylinder.
  • - Nine transmembrane b-helix b-apopproteins form
    an outer cylinder of 34 Å radius.
  • - Contains 18 bacteriochlorophyll 9 carotenoid
    molecules.

15
  • Structure of LHCI
  • Showed a ring arrangement.
  • - How does QB move in out?
  • Identified Puff-X protein.
  • - Provides a pathway for QB to move in out.
  • - The gap in chlorophyll arrangements not
    problematic for energy storage.

16
  • Energy transfer to the reaction centre
  • Over 99 of bacteriochlorophyll molecules
    absorb light at shorter wavelength than the
    reaction centre.
  • - First excited state of a bacteriochlorophyll
    lasts 1 ns.
  • - Energy is rapidly transferred to the reaction
    centre.
  • Resonance energy transfer.
  • - Depends on an overlap between fluorescence
    emission spectrum of the donor excitation
    spectrum of an acceptor.
  • - Affected by relative orientations of donor
    acceptor.
  • - Occurs on about 1 ps time scale over a 2 nm
    distance.
  • Delocalised exciton coupling.
  • - Occurs over distances lt 1.5 nm.
  • - Direct interactions between molecular orbitals.
  • -Very rapid energy transfer.

17
  • Bright light
  • Levels of LH2 controlled by molecular mechanisms
    within the cell.
  • - Takes several hours.
  • Change from cloudy day to sunlight problematic.
  • - Supply of electrons from cytochrome c rate
    limiting?
  • - Rebinding of quinone to QB rate limiting?
  • Futile re-reduction of P870 pumps in lots of
    heat can cause problems.

18
  • How is an electron stabilised at QA?
  • Illuminated crystals at 100 K recorded
    structural differences.
  • Recorded X-ray diffraction observed structural
    changes.

19
  • Observed movements model
  • Clear movements in the cytoplasmic domain of
    subunit H.
  • Suggest an opening of a water filled-cavity.
  • - Change dielectric properties within the
    protein.
  • Cluster of four histidine residues implicated.
  • - Take up protons lower electrostatic energy of
    QA-.
  • Need about 15 kJ/mol stabilisation seems
    reasonable.

20
  • Summary
  • The bacterial reaction centre was the first
    membrane protein structure solved by X-ray
    diffraction.
  • Energy transduction by photosynthetic purple
    bacteria provides a model for cyclic electron
    transfer generation of ATP.
  • - Structural details as to why reverse
    electron-transfer reactions are hindered remain
    to be solved.
  • Light is efficiently harvested by surrounding
    complexes directed to the reaction centre.
  • Basic principles extend to photosynthesis in
    plants.
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