Photosystem II

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1 Background
2 Photosynthesis
3 Electron Transfer
4 Oxygen Evolution
5 3D structures of photosystem II

Background

This structure of Photosystem II was crystallized from the cyanobacteria, Thermosynechococcus elongatus, at 3.0Å ^[1] and at 3.50 Å ^[2]. PDB codes are 2axt and 1s5l, respectively. Cyanobacteria and plants both contain Photosystem II while photosynthetic bacteria contain the bacterial reaction center. This photosynthetic protein complex is associated with a variety of functional ligands. It is a composed mainly of alpha-helices. Nineteen are in each monomer, with multiple extrinsic subunits associated with the oxygen evolving complex missing from this crystallization. Photosystem II is a membrane bound protein complex that in plants is associated with the thylakoid membrane of chloroplasts. regions correlate with membrane associated nature of the protein. Hydrophobic helices make up the transmembranal portion, while polar residues are concentrated externally on either side of the membrane.

Photosynthesis

Photosystem II is an integral part of photosynthesis, the conversion of light energy into chemical energy by living organisms. Photosystem II is linked to a variety of other proteins, including Photosytem I. These proteins ultimately produce NADPH and ATP that power the Calvin cycle. Using this energy, glucose is synthesized from carbon dioxide and water. See also Photosynthesis.

Electron Transfer

structure of chlorophyll a

surround Photosystem II and capture energy from sunlight, exciting electrons. Chlorophyll are highly conjugated and absorb visible light, along with accessory light harvesting pigments such as . Beta carotene absorbs visible light of other wavelengths and also protects Photosystem II by destroying reactive oxygen species that result from this photoexcitation. Electrons are passed from chlorophyll to . Pheophytin are very similar to chlorophyll except they contain 2 H⁺ instead of a Mg²⁺ ion. From the pheophytin, electrons transferred to , which are reduced. Located between each pair of quinones, an iron helps to transfer the electron. These plastoquinones eventually move to a plastoquinone pool which travels to another large protein subunit, cytochrome b ₆/ f. Eventually these electrons reduce NADP⁺ to NADPH. The through Photosystem II is shown, with beta-carotenes, pheophytins, iron and plasotoquinones.

Oxygen Evolution

Another important facet of Photosystem II is its ability to oxidize water to oxygen with its . These centers are structures with 3 manganese, 4 oxygen and a calcium linked to a fourth manganese^[2]. Oxidation of water leaves 2 H ⁺ on the lumenal side of the membrane, helping to establish the proton gradient essential for ATP synthesis in the CF₁CF₀-ATP sythase protein.

structure of beta carotene

reduced plastoquinone

3D structures of photosystem II

Photosystem II 3D structures

Additional Resources

For additional information, see: Photosynthesis

References

↑ Loll B, Kern J, Saenger W, Zouni A, Biesiadka J. Towards complete cofactor arrangement in the 3.0 A resolution structure of photosystem II. Nature. 2005 Dec 15;438(7070):1040-4. PMID:16355230 doi:http://dx.doi.org/10.1038/nature04224
↑ ^2.0 ^2.1 Ferreira KN, Iverson TM, Maghlaoui K, Barber J, Iwata S. Architecture of the photosynthetic oxygen-evolving center. Science. 2004 Mar 19;303(5665):1831-8. Epub 2004 Feb 5. PMID:14764885 doi:http://dx.doi.org/10.1126/science.1093087

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Category: Topic Page

@@ Line 1: / Line 1: @@
-<applet load="1s5l" size="500" frame="true" align="right" />
+<StructureSection load='3a0b' size='350'  caption='Photosystem II, [[3a0b]]' scene='' >
-[[Image:1s5l.gif|250px|left]]
 ==Background==
-This structure of photosystem II was crystallized from the bacteria, ''Thermosynechococcus elongatus'', at 3.50 Å.  It is representative of the photosystem II found in cyanobacteria and plants.  This photosynthetic protein is associated with a variety of ligands that give its function. It is a <scene name='Photosystem_II/Psii_dimer/1'>dimer</scene> composed mainly of alpha-helices.  Fifteen <scene name='Photosystem_II/Protein_only/1'>subunits</scene> are in each monomer, with multiple subunits associated with the oxygen evolving complex missing from this crystallization.  Photosystem II is a membrane bound protein in the thylakoid membrane of chloroplasts.  <scene name='Photosystem_II/Hydrophobic_polar/1'>Polar and hydrophobic</scene> residues how the protein situates within the membrane.  The hydrophobic transmembranal residues are gray, while polar residues, concentrated externally, are purple.
+This structure of '''Photosystem II''' was crystallized from the cyanobacteria, ''Thermosynechococcus elongatus'', at 3.0Å <ref>PMID: 16355230</ref> and at 3.50 Å <ref name="Archit">PMID: 14764885</ref>. PDB codes are [[2axt]] and [[1s5l]], respectively.  Cyanobacteria and plants both contain Photosystem II while photosynthetic bacteria contain the bacterial reaction center.  This photosynthetic protein complex is associated with a variety of functional ligands. It is a <scene name='Photosystem_II/Psii_dimer/1'>dimer</scene> composed mainly of alpha-helices.  Nineteen <scene name='Photosystem_II/Protein_only/1'>subunits</scene> are in each monomer, with multiple extrinsic subunits associated with the oxygen evolving complex missing from this crystallization.  Photosystem II is a membrane bound protein complex that in plants is associated with the thylakoid membrane of chloroplasts.  <scene name='Photosystem_II/Hydrophobic_polar/1'>Polar and hydrophobic</scene> regions correlate with membrane associated nature of the protein.  '''<span style="color:gray;background-color:black;font-weight:bold;">Hydrophobic</span>''' helices make up the transmembranal portion, while '''<FONT COLOR="#C031C7">polar</FONT>''' residues are concentrated externally on either side of the membrane.
 ==Photosynthesis==
-Photosystem II is an integral part of photosynthesis, the conversion of light energy into chemical energy by living organisms.  Photosystem is connected to a variety of other proteins, including photosytem I.  These proteins ultimately produce NADPH and ATP that power the Calvin cycle, producing glucose for the organism.  [[Image:Chlorophyll_a.svg.png|thumb|175px|left|structure of chlorophyll ''a'']]
+Photosystem II is an integral part of photosynthesis, the conversion of light energy into chemical energy by living organisms.  Photosystem II is linked to a variety of other proteins, including Photosytem I.  These proteins ultimately produce NADPH and ATP that power the [[Calvin cycle]].  Using this energy, glucose is synthesized from carbon dioxide and water.  See also [[Photosynthesis]].
 ==Electron Transfer==
-<scene name='Photosystem_II/Chlorophyll_green/1'>Chlorophyll</scene> surround Photosystem II and capture energy from sunlight, exciting electrons.  Highly conjugated, these chlorophyll absorb visible light, along with as accessory light harvesting pigments such as <scene name='Photosystem_II/Betacarotene/1'>beta carotene</scene> that can absorb at other wavelengths.
+[[Image:Chlorophyll_a.svg.png|thumb|170px|left|structure of chlorophyll ''a'']]
-Beta carotene also protects photosystem II by destroying reactive oxygen species that result from this photoexcitation.  [[Image:b-car.svg.png|b-car.svg.png|thumb|700px|structure of beta carotene]]
+<scene name='Photosystem_II/Chlorophyll_green/4'>Chlorophyll</scene> surround Photosystem II and capture energy from sunlight, exciting electrons.  Chlorophyll are highly conjugated and absorb visible light, along with accessory light harvesting pigments such as <scene name='Photosystem_II/Betacarotene/3'>beta carotene</scene>. Beta carotene absorbs visible light of other wavelengths and also protects Photosystem II by destroying reactive oxygen species that result from this photoexcitation. Electrons are passed from chlorophyll to <scene name='Photosystem_II/Pheophytin_purple/5'>pheophytin</scene>.  Pheophytin are very similar to chlorophyll except they  contain 2 H<sup>+</sup> instead of a Mg<sup>2+</sup> ion.  From the pheophytin, electrons transferred to <scene name='Photosystem_II/Quinone_pink/5'>plastoquinones</scene>, which are reduced.  Located between each pair of quinones, an iron helps to transfer the electron. These plastoquinones eventually move to a plastoquinone pool which travels to another large protein subunit, cytochrome b <sub>6</sub>/ f.  Eventually these electrons reduce NADP<sup>+</sup> to NADPH.  The <scene name='Photosystem_II/Electron_pathway/3'>electron pathway</scene> through Photosystem II is shown, with '''<span style="color:orange;background-color:black;font-weight:bold;">beta-carotenes</span>''', '''<FONT COLOR="#571B7e">pheophytins</FONT>''', '''<FONT COLOR="#E42217">iron</FONT>''' and '''<FONT COLOR="#F535AA">plasotoquinones</FONT>'''.
+{{Clear}}
+==Oxygen Evolution==
+Another important facet of Photosystem II is its ability to oxidize water to oxygen with its <scene name='Photosystem_II/Oxygen_evolving_centers/11'>oxygen evolving centers</scene>.  These centers are <scene name='Photosystem_II/Single_oxygen_evolving/1'>cubane-like</scene> structures with 3 '''<FONT COLOR="#8D38C9">manganese</FONT>''', 4 '''<FONT COLOR="#C11B17">oxygen</FONT>''' and a '''<span style="color:lime;background-color:black;font-weight:bold;">calcium</span>''' linked to a fourth manganese<ref name="Archit" />.  Oxidation of water leaves 2 H <sup>+</sup> on the lumenal side of the membrane, helping to establish the proton gradient essential for ATP synthesis in the CF<sub>1</sub>CF<sub>0</sub>-ATP sythase protein.
+[[Image:b-car.svg.png|b-car.svg.png|thumb|left|400px|structure of beta carotene]]
+[[Image:plastoquinone.jpg|thumb|300px|left|reduced plastoquinone]]
+==3D structures of photosystem II==
+[[Photosystem II 3D structures]]
+</StructureSection>
+==Additional Resources==
+For additional information, see: [[Photosynthesis]]
+<br />
-Electrons are passed from chlorophyll to <scene name='Photosystem_II/Pheophytin_purple/3'>pheophytin</scene>.  Pheophytin are very similar to chlorophyll except they  contain 2 H<sup>+</sup> instead of a Mg<sup>2+</sup> ion.  From the pheophytin, electrons go to
-<scene name='Photosystem_II/Quinone_pink/3'>plastoquinones</scene>, which are reduced.  Between each pair of quinones, an iron, in red, helps to transfer the electron between them. These plastoquinones eventually move to a plastoquinone pool which goes to another large protein subunit, cytochrome b <sub>6</sub>/ f.  Eventually these electrons reduce NADP<sup>+</sup> to NADPH.  Here the <scene name='Photosystem_II/Electron_pathway/1'>electron pathway</scene> is shown, with beta-carotenes, pheophytins, iron and plasotoquinones.
-[[Image:plastoquinone.jpg|thumb|300px|right|reduced plastoquinone]]
-==Oxygen Evolution==
-Another important facet of photosystem II is its ability to oxidize water to oxygen with its <scene name='Photosystem_II/Oxygen_evolving_centers/5'>oxygen evolving centers</scene>.  These <scene name='Photosystem_II/Oxygen_evolving_centers/3'>centers</scene> were shown to be cubane-like Mn<sub>3</sub>CaO<sub>4</sub>cluster linked to a fourth Mn by a mono-μ-oxo bridge. [1]  Purple represents manganese, red represents oxygen and green is for calcium.  Oxidation of water to leaves 2 H <sup>+</sup> on the lumenal side of the membrane, helping to establish the proton gradient essential for ATP synthesis in the CF<sub>1</sub>CF<sub>0</sub>-ATP sythase protein.
 ==References==
-[1] Ferreira, K.N., Iverson, T.M., Maghlaoui, K., Barber, J., Iwata, S.  "Architecture of the photosynthetic oxygen-evolving center."  Science, March 19, 2004, 303 (5665), 1831-8.
+<references/>
-[2] Garrett, R.H., Grisham, C.M.  ''Biochemistry, 3rd Edition.''  Belmont, CA: Thomson Brooks/ Cole, 2005.
+[[Category:Topic Page]]

Photosystem II

From Proteopedia

Current revision

Contents

Background

Photosynthesis

Electron Transfer

Oxygen Evolution

3D structures of photosystem II

Additional Resources

References

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