PDF(179 KB)
PDF(179 KB)
PDF(179 KB)
光合放氧复合物结构及其放氧机理的研究*
- 韩广业;李淑芹**;唐崇钦;李良璧;匡廷云
作者信息
+
Progress on the Structure of Photosynthetic Oxygen Evolving Complex and the Mechanism of Photosynthetic Water Oxidation
- Han Guangye;Li Shuqin**;Tang Chongqin;Li Liangbi;Kuang Tingyun
Author information
+
文章历史
+
摘要
光合水氧化是地球上最重要的生化过程之一.光合放氧生物包括光系统Ⅰ(PSⅠ)和光系统Ⅱ(PSⅡ)两种类型反应中心,光系统Ⅱ反应中心能以水作为电子给体,利用光能氧化水产生质子和氧气.对于水如何被氧化这个难题前人已做了大量的工作,但到目前为止放氧复合物(OEC)的结构及水氧化的机理仍不清楚.本文结合当前研究结果,就光合放氧复合物的结构及光合放氧机理进行了综述,希望能有助于推进这方面的工作.
Abstract
Photosynthetic water oxidation is one of the most important biochemical processes on Earth. Oxygen-evolving photosynthetic organisms contain two types of photosynthetic reaction center, called photosystem I (PS I) and photosystem II (PS II). The PS II reaction center uses water as a source of electrons, light energy being used to oxidize water to provide protons and oxygen. How water is oxidized is a difficult problem that has already taken many years of work to understand, however, both the structure of oxygen evolving complex (OEC) and the mechanism of water oxidation still remain to be understood. In this review, we collected the current research results on this area and it will hopefully stimulate further work on the structure of oxygen evolving complex and the mechanism of water oxidation.
关键词
光合作用 / 光系统Ⅱ / 放氧复合物结构 / 水氧化机理 {{custom_keyword}} /
Key words
photosynthesis / photosystem II / structure of oxygen evolving complex / mechanism of water oxidation {{custom_keyword}} /
中图分类号:
Q26
Q945
{{custom_clc.code}}
({{custom_clc.text}})
{{custom_sec.title}}
{{custom_sec.title}}
参考文献
[ 1 ] Michael R J , Paul K F. Current Biology , 2001 , 1 : 318 —321
[2] Yachandra V K, Sauer K, Klein M P. Chem. Rev. , 1996 , 96 :2927 —2950
[3] Hanley J , Deligiannakis Y, Pascal A , Faller P , et al . Biochemistry , 1999 , 38 : 8189 —8195
[4] Ruttinger W, Dismukes G C. Chem. Rev. , 1997 , 97 : 1 —20
[5] Enami I , Tohri S , Kamo M. Biochim. Biophys. Acta , 1997 ,1320 : 17 —26
[6] Büchel C , Barber J , Ananyev G M, et al . Proc. Natl . Acad.Sci . USA , 1999 , 96 : 14288 —14293
[7] Kok B , Foxbush B , McGloin P. Photochem. Photobiol . , 1970 ,11 : 457 —475
[8] Van Leeuwen P J , Heimann C , Gast P , et al . Photosyn. Res. ,1992 , 34 : 145 —145
[9] Hasegawa K, Kusunoki M, Inoue Y, et al . Biochemistry , 1998 ,37 : 9457 —9465
[10] Ono T, Noguchi T, Inoue Y, et al . Science , 1992 , 258 : 1335 —1337
[11] Roelofs T A , Liang W, Latimer M J , et al . Proc. Natl . Acad.Sci . USA , 1996 , 93 : 3335 —3340
[12] Iuzzolini L , Dittmer J , Dêrner W, et al . Biochemistry , 1998 ,37 : 17112 —17119
[13] Messinger J , Nugent J H A , Evans M C W. Biochemistry , 1997 ,36 : 11055 —11060
[14] ! hrling K A , Peterson S , Styring S. Biochemistry , 1997 , 36 :13148 —13152
[15] Boussac A , Zimmermann J L , Rutherford A W, et al . Nature ,1990 , 347 : 303 —306
[16] Boussac A , Rutherford A W. Biochemistry , 1992 , 31 : 7441 —7445
[17] Berthomieu C , Boussac A. Biochemistry , 1995 , 34 : 1541 —1548
[18] Tang X S , Randall D W, Force D A , et al . J . Am. Chem.Soc. , 1996 , 118 : 7638 —7639
[19] Zouni A , Witt H T, Kern J , et al . Nature , 2001 , 409 : 739 —743
[20] Chu H A , Nguyen A P , Debus R J . Biochemistry , 1995 , 34 :5839 —5858
[21] Tang X S , Diner B A , Larsen B S. Proc. Natl . Acad. Sci .USA , 1994 , 91 : 704 —708
[22] Magnuson A , Andreasson L E. Biochemistry , 1997 , 36 : 3254 —3261
[23] Ghirardi M L , Preston C , Seibert M. Biochemistry , 1998 , 37 :13567 —13574
[24] Debus R J . Biochim. Biophys. Acta , 2001 , 1503 : 164 —186
[25] Sandusky P O , Yocum C F. Biochim. Biophys. Acta , 1986 ,849 : 85 —93
[26] Wincencjusz H , van Gorkom H J , Yocum C F. Biochemistry ,1997 , 36 : 3663 —3670
[27] Wincencjusz H , Yocum C F , van Gorkom H J . Biochemistry ,1998 , 37 : 8595 —8604
[28] Cinco R , Robblee J , Rompel A , et al . J . Phys. Chem. B ,1998 , 102 : 8248 —8256
[29] Yocum C F. Biochim. Biophys. Acta , 1991 , 1059 : 1 —15
[30] 'delroth P , Lindberg K, Andreasson L E. Biochemistry , 1995 ,34 : 9021 —9027
[31] Yachandra V K, De Rose V J , Latimer M J , et al . Science ,1993 , 260 : 675 —679
[32] Debus R J . Biochim. Biophys. Acta , 1992 , 1102 : 269 —352
[33] Bakou A , Buser C , Dandulakis G, et al . Biochim. Biophys. Acta , 1992 , 1099 : 131 —136
[34] Ananyev G M, Dismukes GC. Biochemistry , 1997 , 36 : 11342 —11350
[35] Zhang C X, Pan J , Li L B , Kuang T Y. Science in China (Series C) , 2002 , 42 : 337 —346
[36] Lindberg K, V? nng? rd T, Andréasson L E. Photosyn. Res. ,1993 , 38 : 410 —408
[37] Randall D W, Sturgeon B E , Ball J A , et al . J . Am. Chem.Soc. , 1995 , 117 : 11780 —11789
[38] Carrell T G, Tyryshkin A M, Dismukes G C. J . Biol . Inorg.Chem. , 2002 , 7 : 2 —22
[39] Boussac A , Zimmermann J L , Rutherford A W, et al . Nature ,1990 , 347 : 303 —306
[40] Lavergne J , Junge W. Photosyn. Res. , 1993 , 38 : 279 —296
[41] Huamann M, Junge W. Biochemistry , 1994 , 33 : 864 —872
[42] Hoganson C W, Lydakis-Simantiris N , Tang X2S , et al . Photosyn. Res. , 1995 , 46 : 177 —184
[43] Kretschmann H , Schlodder E , Witt H T. Biochim. Biophys. Acta , 1996 , 1274 : 1 —8
[44] Debus R J , Barry B A , Sithole I , et al . Biochemistry , 1988 , 27 :9071 —9074
[45] Metz J G, Nixon P J , Ronger M, et al . Biochemistry , 1989 , 28 :6960 —6969
[46] Hoganson C W, Babcock G T. Biochemistry , 1988 , 27 : 5848 —5855
[47] Gilchrist M L , Ball J A , Randall D W, et al . Proc. Natl . Acad.Sci . USA , 1995 , 92 : 9545 —9549
[48] Peloquin J M, Campbell K A , Britt R D. J . Am. Chem. Soc. ,1998 , 120 : 6840 —6841
[49] Lakashmi K V , Eaton S S , Eaton G R , et al . J . Phys. Chem. B ,1998 , 102 : 8327 —8335
[50] Dorlet P , Valentin M D , Babcok G T, et al . J . Phys. Chem. B ,1998 , 102 : 8239 —8247
[51] Debus R J , Barry B A , Babcock G T, et al . Proc. Natl . Acad.Sci . USA , 1988 , 85 : 427 —430
[52] Vermaas W J F , Rutherford A W, Hansson O. Proc. Natl . Acad.Sci . USA , 1998 , 95 : 8477 —8481
[53] Koulougliotis D , Tang X S , Diner B A , et al . Biochemistry ,1995 , 34 : 2850 —2856
[54] Vass I , Styring S. Biochemistry , 1991 , 30 : 830 —839
[55] Berthomieu C , Hienerwadel R , Boussac A , et al . Biochemistry ,1998 , 37 : 10548 —10554
[56] Force D A , Randall D W, Britt R D. Biochemistry , 1997 , 36 :12062 —12070
[57] Tommos C , McCracken J , Styring S , et al . J . Am. Chem. Soc. ,1998 , 120 : 10441 —10452
[58] Diner B A , Force D A , Randall D W, et al . Biochemistry , 1998 ,37 : 17931 —17943
[59] Candeias L P , Turconi S , Nugent J H A. Biochim. Biophys. Acta , 1998 , 1363 : 1 —5
[60] Haumann M, Mulkidjanian A , Junge W. Biochemistry , 1999 ,38 : 1258 —1267
[61] Babcock G T, Tommos C. Biochim , Biophys. Acta , 2000 , 1458 :199 —219
[62] Ahlbrink R , Haumann M, Cherepanov D , et al . Biochemistry ,1998 , 37 : 1131 —1142
[63] Roffey R A , Kramer D M, Govindjee , et al . Biochim. Biophys.Acta , 1994 , 1185 : 257 —270
[64] Roffey R A , van Wijk K J , Sayre R T, et al . J . Biol . Chem. ,1994 , 269 : 5115 —5121
[65] Hays A M, Vassiliev I R , Golbeck J H , et al . Biochemistry ,1998 , 37 : 11352 —11365
[66] Campbell K A , Peloquin J M, Diner B A , et al . J . Am. Chem.Soc. , 1997 , 119 : 4787 —4788
[67] Hienerwadel R , Boussac A , Breton J , et al . Biochemistry , 1997 ,36 : 14712 —14723
[68] Hoganson C W, Babcock G T. Science , 1997 , 277 : 1953 —1956
[69] Tommos C , Babcock G T. Acc. Chem. Res. , 1998 , 31 (1) :18 —25
[70] Rappaport F , Lavergne J . Biochim. Biophys. Acta , 2001 , 1503 :246 —259
[71] Messinger J , Badger M, Wydrzynsi T. Proc. Natl . Acad. Sci .USA , 1995 , 92 (8) : 3209 —3213
[72] Vrettos J S , Limbug J , Brudvig G W. Biochim. Biophys. Acta ,2001 , 1503 : 229 —245
[73] Hillier W, Messinger J , Wydrzynski T. Biochemistry , 1998 , 37(48) : 16908 —16914
[74] Renger G. Physiol . Plant , 1997 , 100 : 828 —841
[75] Hendry G, Wydrzynski T. Biochemistry , 2002 , 41 : 13328 —13334
[76] Daniel P. Photosyn. Res. , 1988 , 17 : 189 —216
[77] Homann P H. Biochim. Biophys. Acta , 1985 , 809 : 311 —319
[78] Wincencjusz H , Yocum C F , van Gorkom H J . Biochemistry ,1999 , 38 : 3719 —3725
[79] Hasegawa K, Kimura Y, Ono T. Biochemistry , 2002 , 41 :13839 —13850
[80] Vander Meulen K A , Hobson A , Yocum C F. Biochemistry ,2002 , 41 : 958 —966
[81] Kimura Y, Hasegawa K, Ono T. Biochemistry , 2002 , 41 :5844 —5853
[82] Seidler A. Biochim. Biophys. Acta , 1996 , 1277 : 35 —60
[83] Briker T M. Biochemistry , 1992 , 31 : 4623 —4628
[84] Shutova T, Irrgang K D , Shubin V , et al . Biochemistry , 1997 ,36 : 6350 —6358
[85] Yu Y, Li R , Xu C H , et al . Physiol . Plantarum , 2001 , 111 :108 —115
[86] Betts S D , Ross J R , Pichersky E , et al . Biochemistry , 1997 ,36 : 4047 —4053
[87] Enami I , Kamo M, Ohta H , et al . J . Biol . Chem. , 1998 , 273 :4629 —4634
[88] Hong S K, Pawlikowski S A , Vander Meulen K A , et al . Biochim. Biophys. Acta , 2001 , 1504 : 262 —274
[89] Maria E , Ewen B M, Fredriksson P O , et al . J . Biol . Chem. ,1996 , 271 : 28918 —28924
[90] Hiller W, Hendry G, Burnap R L , et al . J . Biol . Chem. , 2001 ,276 : 46917 —46924
[91] Nugent J H A , Rich A M, Evans M C W. Biochim. Biophys. Acta , 2001 , 1503 : 138 —146
[92] Brudvig G W, Crabtree R H. Proc. Natl . Acad. Sci . USA ,1985 , 83 : 4586 —4588
[93] Limburg J , Szalai V A , Brudvig G W. J . Chem. Soc. , Dalton Trans. , 1999 , 1353 —1361
[94] Zhang C X, Pan J , Li L B , Kuang T Y. Chinese Science Bulletin , 1999 , 44 : 2209 —2215
[95] Siegbahn F E M, Crabtree R H. J . Am. Chem. Soc. , 1999 ,121 : 117 —121
[96] Pecoraro V L , Baldwin M J , Caudle M T, et al . Pure Appl .Chem. , 1998 , 70 : 925 —929
{{custom_fnGroup.title_cn}}
脚注
{{custom_fn.content}}
/
| 〈 |
|
〉 |