Jump to content

Photosystem: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
Trevinas (talk | contribs)
added a link
Removing Photosynthesi_s.png; it has been deleted from Commons by Aafi because: No permission since 2 September 2024:.
 
(38 intermediate revisions by 20 users not shown)
Line 1: Line 1:
{{Short description|Structural units of protein involved in photosynthesis}}
[[Image:Thylakoid membrane 3.svg|thumb|400px|right|Light-dependent reactions of photosynthesis at the thylakoid membrane]]
[[Image:Thylakoid membrane 3.svg|thumb|400px|right|Light-dependent reactions of photosynthesis at the thylakoid membrane]]
'''Photosystems''' are functional and structural units of [[protein complex]]es involved in [[photosynthesis]]. Together they carry out the primary [[photochemistry]] of [[photosynthesis]]: the [[Absorption (electromagnetic radiation)|absorption of light]] and the transfer of [[Förster resonance energy transfer|energy]] and [[Electron transfer|electrons]]. Photosystems are found in the [[thylakoid membrane]]s of plants, algae, and cyanobacteria. These membranes are located inside the [[chloroplast]]s of plants and algae, and in the cytoplasmic membrane of photosynthetic bacteria. There are two kinds of photosystems: PSI and PSII.


PSII will absorb red light, and PSI will absorb far-red light. Although photosynthetic activity will be detected when the photosystems are exposed to either red or far-red light, the photosynthetic activity will be the greatest when plants are exposed to both [[wavelength]]s of light. Studies have actually demonstrated that the two wavelengths together have a synergistic effect on the photosynthetic activity, rather than an additive one.<ref>{{Cite journal|date=2017-02-01|title=Far-red light is needed for efficient photochemistry and photosynthesis|journal=Journal of Plant Physiology|language=en|volume=209|pages=115–122|doi=10.1016/j.jplph.2016.12.004|issn=0176-1617|last1=Zhen|first1=Shuyang|last2=Van Iersel|first2=Marc W.|pmid=28039776|doi-access=free}}</ref>
'''Photosystems''' are functional and structural units of [[protein complex]]es involved in [[photosynthesis]]. Together they carry out the primary [[photochemistry]] of [[photosynthesis]]: the [[Absorption (electromagnetic radiation)|absorption of light]] and the transfer of [[Förster resonance energy transfer|energy]] and [[Electron transfer|electrons]]. Photosystems are found in the [[thylakoid membrane]]s of plants, algae and cyanobacteria, which are located inside the [[chloroplast]]s of plants and algae, and in the cytoplasmic membrane of photosynthetic bacteria. There are two kinds of photosystems: PSI and PSII.

Each photosystem has two parts: a reaction center, where the photochemistry occurs, and an [[Light-harvesting complexes of green plants|antenna complex]], which surrounds the reaction center. The antenna complex contains hundreds of [[chlorophyll]] molecules which funnel the excitation energy to the center of the photosystem. At the reaction center, the energy will be trapped and transferred to produce a high energy molecule.<ref name=":0">{{Cite book|author=Taiz, Lincoln|url=http://worldcat.org/oclc/1035316853|title=Fundamentals of plant physiology|year=2018|isbn=978-1-60535-790-4|oclc=1035316853}}</ref>

The main function of PSII is to efficiently split water into oxygen molecules and protons. PSII will provide a steady stream of electrons to PSI, which will boost these in energy and transfer them to NADP{{sup|+}} and [[Hydronium|H{{sup|+}}]] to make [[Nicotinamide adenine dinucleotide phosphate|NADPH]]. The hydrogen from this NADPH can then be used in a number of different processes within the plant.<ref name=":0" />


==Reaction centers==
==Reaction centers==
{{main|photosynthetic reaction centre}}
{{main|photosynthetic reaction centre}}
Reaction centers are multi-protein complexes found within the [[Thylakoid|thylakoid membrane.]]
At the heart of a photosystem lies the [[photosynthetic reaction centre|reaction center]], which is an [[enzyme]] that uses light to [[redox|reduce]] molecules (provide with electrons). This reaction center is surrounded by [[light-harvesting complex]]es that enhance the absorption of light.


At the heart of a photosystem lies the [[photosynthetic reaction centre|reaction center]], which is an [[enzyme]] that uses light to [[redox|reduce]] and oxidize molecules (give off and take up electrons). This reaction center is surrounded by [[light-harvesting complex]]es that enhance the absorption of light.
Two families of reaction centers in photosystems exist: type I reaction centers (such as [[photosystem 1|photosystem I]] ([[P700]]) in chloroplasts and in green-sulphur bacteria) and type II reaction centers (such as [[photosystem II]] ([[P680]]) in chloroplasts and in non-sulphur purple bacteria). The two photosystems originated from a common ancestor, but have since diversified.<ref name=pmid16887904>{{cite journal | vauthors = Sadekar S, Raymond J, Blankenship RE | title = Conservation of distantly related membrane proteins: photosynthetic reaction centers share a common structural core | journal = Molecular Biology and Evolution | volume = 23 | issue = 11 | pages = 2001–7 | date = November 2006 | pmid = 16887904 | doi = 10.1093/molbev/msl079 | doi-access = free }}</ref><ref name="pmid29603081">{{cite journal | vauthors = Orf GS, Gisriel C, Redding KE | title = Evolution of photosynthetic reaction centers: insights from the structure of the heliobacterial reaction center | journal = Photosynthesis Research | volume = 138 | issue = 1 | pages = 11–37 | date = October 2018 | pmid = 29603081 | doi = 10.1007/s11120-018-0503-2 | osti = 1494566 | s2cid = 4473759 }}</ref>


In addition, surrounding the reaction center are [[pigment]]s which will absorb light. The pigments which absorb light at the highest energy level are found furthest from the reaction center. On the other hand, the pigments with the lowest energy level are more closely associated with the reaction center. Energy will be efficiently transferred from the outer part of the antenna complex to the inner part. This funneling of energy is performed via resonance transfer, which occurs when energy from an excited molecule is transferred to a molecule in the ground state. This ground state molecule will be excited, and the process will continue between molecules all the way to the reaction center. At the reaction center, the electrons on the special chlorophyll molecule will be excited and ultimately transferred away by electron carriers. (If the electrons were not transferred away after excitation to a high energy state, they would lose energy by fluorescence back to the ground state, which would not allow plants to drive photosynthesis.) The reaction center will drive photosynthesis by taking light and turning it into chemical energy<ref>{{Cite journal|last1=Gisriel|first1=Christopher|last2=Sarrou|first2=Iosifina|last3=Ferlez|first3=Bryan|last4=Golbeck|first4=John H.|last5=Redding|first5=Kevin E.|last6=Fromme|first6=Raimund|date=2017-09-08|title=Structure of a symmetric photosynthetic reaction center–photosystem|journal=Science|language=en|volume=357|issue=6355|pages=1021–1025|doi=10.1126/science.aan5611|issn=0036-8075|pmid=28751471|bibcode=2017Sci...357.1021G |doi-access=free}}</ref> that can then be used by the chloroplast.<ref name=":0" />
Each of the photosystem can be identified by the [[wavelength]] of light to which it is most reactive (700 [[nanometer]]s for [[photosystem 1|PSI]] and 680 nanometers for [[photosystem 2|PSII]] in chloroplasts), the amount and type of light-harvesting complex present and the type of terminal electron acceptor used.

Two families of reaction centers in photosystems can be distinguished: type I reaction centers (such as [[photosystem 1|photosystem I]] ([[P700]]) in chloroplasts and in green-sulfur bacteria) and type II reaction centers (such as [[photosystem II]] ([[P680]]) in chloroplasts and in non-sulfur purple bacteria). The two photosystems originated from a common ancestor, but have since diversified.<ref name=pmid16887904>{{cite journal | vauthors = Sadekar S, Raymond J, Blankenship RE |author3-link=Robert E. Blankenship| title = Conservation of distantly related membrane proteins: photosynthetic reaction centers share a common structural core | journal = Molecular Biology and Evolution | volume = 23 | issue = 11 | pages = 2001–7 | date = November 2006 | pmid = 16887904 | doi = 10.1093/molbev/msl079 | doi-access = }}</ref><ref name="pmid29603081">{{cite journal | vauthors = Orf GS, Gisriel C, Redding KE | title = Evolution of photosynthetic reaction centers: insights from the structure of the heliobacterial reaction center | journal = Photosynthesis Research | volume = 138 | issue = 1 | pages = 11–37 | date = October 2018 | pmid = 29603081 | doi = 10.1007/s11120-018-0503-2 | osti = 1494566 | s2cid = 4473759 }}</ref>

Each of the photosystem can be identified by the [[wavelength]] of light to which it is most reactive (700 [[nanometer]]s for PSI and 680 nanometers for PSII in chloroplasts), the amount and type of light-harvesting complex present, and the type of terminal electron acceptor used.


Type I photosystems use [[ferredoxin]]-like iron-sulfur cluster proteins as terminal electron acceptors, while type II photosystems ultimately shuttle electrons to a [[quinone]] terminal electron acceptor. Both reaction center types are present in chloroplasts and cyanobacteria, and work together to form a unique photosynthetic chain able to extract electrons from water, creating oxygen as a byproduct.
Type I photosystems use [[ferredoxin]]-like iron-sulfur cluster proteins as terminal electron acceptors, while type II photosystems ultimately shuttle electrons to a [[quinone]] terminal electron acceptor. Both reaction center types are present in chloroplasts and cyanobacteria, and work together to form a unique photosynthetic chain able to extract electrons from water, creating oxygen as a byproduct.


==Structure==
==Structure of PSI and PSII==
A reaction center comprises several (>24 or >33) protein subunits, that provide a scaffold for a series of cofactors. The cofactors can be pigments (like [[chlorophyll]], [[pheophytin]], [[carotenoids]]), quinones, or [[Iron–sulfur cluster|iron-sulfur clusters]].<ref>{{cite book|last1=Jagannathan|first1=B|last2=Golbeck|first2=JH|title=Photosynthesis:Microbial|journal=Encyclopedia of Microbiology, 3rd ed|date=2009|pages=325–341|doi=10.1016/B978-012373944-5.00352-7|isbn=9780123739445}}</ref>
A reaction center comprises several (about 25-30)<ref>{{Cite journal|last1=Caffarri|first1=Stefano|last2=Tibiletti|first2=Tania|last3=Jennings|first3=Robert C.|last4=Santabarbara|first4=Stefano|date=June 2014|title=A Comparison Between Plant Photosystem I and Photosystem II Architecture and Functioning|journal=Current Protein & Peptide Science|volume=15|issue=4|pages=296–331|doi=10.2174/1389203715666140327102218|issn=1389-2037|pmc=4030627|pmid=24678674}}</ref> protein subunits, which provide a scaffold for a series of cofactors. The cofactors can be pigments (like [[chlorophyll]], [[pheophytin]], [[carotenoids]]), quinones, or [[Iron–sulfur cluster|iron-sulfur clusters]].<ref>{{cite book|last1=Jagannathan|first1=B|last2=Golbeck|first2=JH|title=Photosynthesis:Microbial|journal=Encyclopedia of Microbiology, 3rd ed|date=2009|pages=325–341|doi=10.1016/B978-012373944-5.00352-7|isbn=9780123739445}}</ref>

Each photosystem has two main subunits: an [[Light-harvesting complexes of green plants|antenna complex]] (a light harvesting complex or LHC) and a reaction center. The antenna complex is where light is captured, while the reaction center is where this light energy is transformed into chemical energy. At the reaction center, there are many polypeptides that are surrounded by pigment proteins. At the center of the reaction center is a special pair of chlorophyll molecules.

Each PSII has about 8 LHCII. These contain about 14 [[Chlorophyll a|chlorophyll ''a'']] and chlorophyll ''b'' molecules, as well as about four [[carotenoid]]s. In the reaction center of PSII of plants and cyanobacteria, the light energy is used to split water into oxygen, protons, and electrons. The protons will be used in proton pumping to fuel the ATP synthase at the end of an [[electron transport chain]]. A majority of the reactions occur at the D1 and D2 subunits of PSII.


==In oxygenic photosynthesis==
==In oxygenic photosynthesis==


For oxygenic photosynthesis, both [[Photosystem I|photosystems I]] and [[Photosystem II|II]] are required. Oxygenic photosynthesis can be performed by plants and cyanobacteria; cyanobacteria are believed to be the progenitors of the photosystem-containing chloroplasts of [[eukaryotes]]. Photosynthetic bacteria that cannot produce oxygen have [[Light-dependent_reactions#In_bacteria|a single photosystem similar to either]].
Both [[photosystem I]] and [[Photosystem II|II]] are required for oxygenic photosynthesis. Oxygenic photosynthesis can be performed by plants and cyanobacteria; cyanobacteria are believed to be the progenitors of the photosystem-containing chloroplasts of [[eukaryotes]]. Photosynthetic bacteria that cannot produce oxygen have only one photosystem, which is [[Light-dependent reactions#In bacteria|similar to either PSI or PSII]].

At the core of photosystem II is P680, a special chlorophyll to which incoming excitation energy from the antenna complex is funneled. One of the electrons of excited P680* will be transferred to a non-[[Fluorescence|fluorescent]] molecule, which ionizes the chlorophyll and boosts its energy further, enough that it can split water in the oxygen evolving complex (OEC) of PSII and recover its electron.{{cn|date=June 2022}} At the heart of the OEC are 4 Mn atoms, each of which can trap one electron. The electrons harvested from the splitting of two waters fill the OEC complex in its highest-energy state, which holds 4 excess electrons.<ref name=":0" />


Electrons travel through the [[cytochrome b6f complex|cytochrome ''b6f'' complex]] to photosystem I via an electron transport chain within the [[thylakoid membrane]]. Energy from PSI drives this process{{cn|date=June 2022}} and is harnessed (the whole process is termed [[chemiosmosis]]) to pump protons across the membrane, into the thylakoid lumen space from the chloroplast stroma. This will provide a potential energy difference between lumen and stroma, which amounts to a proton-motive force that can be utilized by the proton-driven [[ATP synthase]] to generate ATP. If electrons only pass through once, the process is termed noncyclic photophosphorylation, but if they pass through PSI and the proton pump multiple times it is called cyclic photophosphorylation.
When photosystem II absorbs light, electrons in the reaction-center chlorophyll are excited to a higher energy level and are trapped by the primary electron acceptors.


When the electron reaches photosystem I, it fills the electron deficit of light-excited reaction-center chlorophyll P700{{sup|+}} of PSI. The electron may either continue to go through cyclic electron transport around PSI or pass, via ferredoxin, to the enzyme NADP{{sup|+}} reductase. Electrons and protons are added to NADP{{sup|+}} to form NADPH.
Photoexcited electrons travel through the [[cytochrome b6f complex]] to photosystem I via an electron transport chain set in the [[thylakoid membrane]]. This energy fall is harnessed, (the whole process termed [[chemiosmosis]]), to transport hydrogen (H<sup>+</sup>) through the membrane, into the thylakoid lumen, to provide a potential energy difference between the thylakoid lumen space and the chloroplast stroma, which amounts to a proton-motive force that can be used to generate ATP. The protons are transported by the [[plastoquinone]]. If electrons only pass through once, the process is termed noncyclic photophosphorylation.
This reducing (hydrogenation) agent is transported to the Calvin cycle to react with [[glycerate 3-phosphate]], along with ATP to form [[glyceraldehyde 3-phosphate]], the basic building block from which plants can make a variety of substances.


== Photosystem repair ==
When the electron reaches photosystem I, it fills the electron deficit of the reaction-center chlorophyll of photosystem I.
In intense light, plants use various mechanisms to prevent damage to their photosystems. They are able to release some light energy as heat, but the excess light can also produce [[reactive oxygen species]]. While some of these can be detoxified by [[antioxidant]]s, the remaining oxygen species will be detrimental to the photosystems of the plant. More specifically, the D1 subunit in the reaction center of PSII can be damaged. Studies have found that [[deg1]] proteins are involved in the degradation of these damaged D1 subunits. New D1 subunits can then replace these damaged D1 subunits in order to allow PSII to function properly again.<ref>{{Cite journal|last1=Kapri-Pardes|first1=Einat|last2=Naveh|first2=Leah|last3=Adam|first3=Zach|date=March 2007|title=The Thylakoid Lumen Protease Deg1 Is Involved in the Repair of Photosystem II from Photoinhibition in Arabidopsis|journal=The Plant Cell|volume=19|issue=3|pages=1039–1047|doi=10.1105/tpc.106.046573|issn=1040-4651|pmc=1867356|pmid=17351117}}</ref>
ATP is generated when the [[ATP synthase]] transports the protons present in the lumen to the stroma, through the membrane. The electrons may either continue to go through cyclic electron transport around PS I or pass, via ferredoxin, to the enzyme NADP<sup>+</sup> reductase. Electrons and hydrogen ions are added to NADP<sup>+</sup> to form NADPH.
This reducing agent is transported to the Calvin cycle to react with [[glycerate 3-phosphate]], along with ATP to form [[glyceraldehyde 3-phosphate]], the basic building-block from which plants can make a variety of substances.


==See also==
==See also==

Latest revision as of 03:26, 10 September 2024

Light-dependent reactions of photosynthesis at the thylakoid membrane

Photosystems are functional and structural units of protein complexes involved in photosynthesis. Together they carry out the primary photochemistry of photosynthesis: the absorption of light and the transfer of energy and electrons. Photosystems are found in the thylakoid membranes of plants, algae, and cyanobacteria. These membranes are located inside the chloroplasts of plants and algae, and in the cytoplasmic membrane of photosynthetic bacteria. There are two kinds of photosystems: PSI and PSII.

PSII will absorb red light, and PSI will absorb far-red light. Although photosynthetic activity will be detected when the photosystems are exposed to either red or far-red light, the photosynthetic activity will be the greatest when plants are exposed to both wavelengths of light. Studies have actually demonstrated that the two wavelengths together have a synergistic effect on the photosynthetic activity, rather than an additive one.[1]

Each photosystem has two parts: a reaction center, where the photochemistry occurs, and an antenna complex, which surrounds the reaction center. The antenna complex contains hundreds of chlorophyll molecules which funnel the excitation energy to the center of the photosystem. At the reaction center, the energy will be trapped and transferred to produce a high energy molecule.[2]

The main function of PSII is to efficiently split water into oxygen molecules and protons. PSII will provide a steady stream of electrons to PSI, which will boost these in energy and transfer them to NADP+ and H+ to make NADPH. The hydrogen from this NADPH can then be used in a number of different processes within the plant.[2]

Reaction centers

[edit]

Reaction centers are multi-protein complexes found within the thylakoid membrane.

At the heart of a photosystem lies the reaction center, which is an enzyme that uses light to reduce and oxidize molecules (give off and take up electrons). This reaction center is surrounded by light-harvesting complexes that enhance the absorption of light.

In addition, surrounding the reaction center are pigments which will absorb light. The pigments which absorb light at the highest energy level are found furthest from the reaction center. On the other hand, the pigments with the lowest energy level are more closely associated with the reaction center. Energy will be efficiently transferred from the outer part of the antenna complex to the inner part. This funneling of energy is performed via resonance transfer, which occurs when energy from an excited molecule is transferred to a molecule in the ground state. This ground state molecule will be excited, and the process will continue between molecules all the way to the reaction center. At the reaction center, the electrons on the special chlorophyll molecule will be excited and ultimately transferred away by electron carriers. (If the electrons were not transferred away after excitation to a high energy state, they would lose energy by fluorescence back to the ground state, which would not allow plants to drive photosynthesis.) The reaction center will drive photosynthesis by taking light and turning it into chemical energy[3] that can then be used by the chloroplast.[2]

Two families of reaction centers in photosystems can be distinguished: type I reaction centers (such as photosystem I (P700) in chloroplasts and in green-sulfur bacteria) and type II reaction centers (such as photosystem II (P680) in chloroplasts and in non-sulfur purple bacteria). The two photosystems originated from a common ancestor, but have since diversified.[4][5]

Each of the photosystem can be identified by the wavelength of light to which it is most reactive (700 nanometers for PSI and 680 nanometers for PSII in chloroplasts), the amount and type of light-harvesting complex present, and the type of terminal electron acceptor used.

Type I photosystems use ferredoxin-like iron-sulfur cluster proteins as terminal electron acceptors, while type II photosystems ultimately shuttle electrons to a quinone terminal electron acceptor. Both reaction center types are present in chloroplasts and cyanobacteria, and work together to form a unique photosynthetic chain able to extract electrons from water, creating oxygen as a byproduct.

Structure of PSI and PSII

[edit]

A reaction center comprises several (about 25-30)[6] protein subunits, which provide a scaffold for a series of cofactors. The cofactors can be pigments (like chlorophyll, pheophytin, carotenoids), quinones, or iron-sulfur clusters.[7]

Each photosystem has two main subunits: an antenna complex (a light harvesting complex or LHC) and a reaction center. The antenna complex is where light is captured, while the reaction center is where this light energy is transformed into chemical energy. At the reaction center, there are many polypeptides that are surrounded by pigment proteins. At the center of the reaction center is a special pair of chlorophyll molecules.

Each PSII has about 8 LHCII. These contain about 14 chlorophyll a and chlorophyll b molecules, as well as about four carotenoids. In the reaction center of PSII of plants and cyanobacteria, the light energy is used to split water into oxygen, protons, and electrons. The protons will be used in proton pumping to fuel the ATP synthase at the end of an electron transport chain. A majority of the reactions occur at the D1 and D2 subunits of PSII.

In oxygenic photosynthesis

[edit]

Both photosystem I and II are required for oxygenic photosynthesis. Oxygenic photosynthesis can be performed by plants and cyanobacteria; cyanobacteria are believed to be the progenitors of the photosystem-containing chloroplasts of eukaryotes. Photosynthetic bacteria that cannot produce oxygen have only one photosystem, which is similar to either PSI or PSII.

At the core of photosystem II is P680, a special chlorophyll to which incoming excitation energy from the antenna complex is funneled. One of the electrons of excited P680* will be transferred to a non-fluorescent molecule, which ionizes the chlorophyll and boosts its energy further, enough that it can split water in the oxygen evolving complex (OEC) of PSII and recover its electron.[citation needed] At the heart of the OEC are 4 Mn atoms, each of which can trap one electron. The electrons harvested from the splitting of two waters fill the OEC complex in its highest-energy state, which holds 4 excess electrons.[2]

Electrons travel through the cytochrome b6f complex to photosystem I via an electron transport chain within the thylakoid membrane. Energy from PSI drives this process[citation needed] and is harnessed (the whole process is termed chemiosmosis) to pump protons across the membrane, into the thylakoid lumen space from the chloroplast stroma. This will provide a potential energy difference between lumen and stroma, which amounts to a proton-motive force that can be utilized by the proton-driven ATP synthase to generate ATP. If electrons only pass through once, the process is termed noncyclic photophosphorylation, but if they pass through PSI and the proton pump multiple times it is called cyclic photophosphorylation.

When the electron reaches photosystem I, it fills the electron deficit of light-excited reaction-center chlorophyll P700+ of PSI. The electron may either continue to go through cyclic electron transport around PSI or pass, via ferredoxin, to the enzyme NADP+ reductase. Electrons and protons are added to NADP+ to form NADPH. This reducing (hydrogenation) agent is transported to the Calvin cycle to react with glycerate 3-phosphate, along with ATP to form glyceraldehyde 3-phosphate, the basic building block from which plants can make a variety of substances.

Photosystem repair

[edit]

In intense light, plants use various mechanisms to prevent damage to their photosystems. They are able to release some light energy as heat, but the excess light can also produce reactive oxygen species. While some of these can be detoxified by antioxidants, the remaining oxygen species will be detrimental to the photosystems of the plant. More specifically, the D1 subunit in the reaction center of PSII can be damaged. Studies have found that deg1 proteins are involved in the degradation of these damaged D1 subunits. New D1 subunits can then replace these damaged D1 subunits in order to allow PSII to function properly again.[8]

See also

[edit]

References

[edit]
  1. ^ Zhen, Shuyang; Van Iersel, Marc W. (2017-02-01). "Far-red light is needed for efficient photochemistry and photosynthesis". Journal of Plant Physiology. 209: 115–122. doi:10.1016/j.jplph.2016.12.004. ISSN 0176-1617. PMID 28039776.
  2. ^ a b c d Taiz, Lincoln (2018). Fundamentals of plant physiology. ISBN 978-1-60535-790-4. OCLC 1035316853.
  3. ^ Gisriel, Christopher; Sarrou, Iosifina; Ferlez, Bryan; Golbeck, John H.; Redding, Kevin E.; Fromme, Raimund (2017-09-08). "Structure of a symmetric photosynthetic reaction center–photosystem". Science. 357 (6355): 1021–1025. Bibcode:2017Sci...357.1021G. doi:10.1126/science.aan5611. ISSN 0036-8075. PMID 28751471.
  4. ^ Sadekar S, Raymond J, Blankenship RE (November 2006). "Conservation of distantly related membrane proteins: photosynthetic reaction centers share a common structural core". Molecular Biology and Evolution. 23 (11): 2001–7. doi:10.1093/molbev/msl079. PMID 16887904.
  5. ^ Orf GS, Gisriel C, Redding KE (October 2018). "Evolution of photosynthetic reaction centers: insights from the structure of the heliobacterial reaction center". Photosynthesis Research. 138 (1): 11–37. doi:10.1007/s11120-018-0503-2. OSTI 1494566. PMID 29603081. S2CID 4473759.
  6. ^ Caffarri, Stefano; Tibiletti, Tania; Jennings, Robert C.; Santabarbara, Stefano (June 2014). "A Comparison Between Plant Photosystem I and Photosystem II Architecture and Functioning". Current Protein & Peptide Science. 15 (4): 296–331. doi:10.2174/1389203715666140327102218. ISSN 1389-2037. PMC 4030627. PMID 24678674.
  7. ^ Jagannathan, B; Golbeck, JH (2009). Photosynthesis:Microbial. pp. 325–341. doi:10.1016/B978-012373944-5.00352-7. ISBN 9780123739445. {{cite book}}: |journal= ignored (help)
  8. ^ Kapri-Pardes, Einat; Naveh, Leah; Adam, Zach (March 2007). "The Thylakoid Lumen Protease Deg1 Is Involved in the Repair of Photosystem II from Photoinhibition in Arabidopsis". The Plant Cell. 19 (3): 1039–1047. doi:10.1105/tpc.106.046573. ISSN 1040-4651. PMC 1867356. PMID 17351117.
[edit]