用于区分标准形式的蓝藻超氧化物歧化酶的比较分析

Comparative analysis of cyanobacterial superoxide dismutases to discriminate canonical forms.

作者信息

Priya Balakrishnan, Premanandh Jagadeesan, Dhanalakshmi Raman T, Seethalakshmi Thangaraj, Uma Lakshmanan, Prabaharan Dharmar, Subramanian Gopalakrishnan

机构信息

National Facility for Marine Cyanobacteria (Sponsored by Department of Biotechnology, Government of India), Bharathidasan University, Tiruchirappalli - 620 024, India.

出版信息

BMC Genomics. 2007 Nov 27;8:435. doi: 10.1186/1471-2164-8-435.

BACKGROUND

Superoxide dismutases (SOD) are ubiquitous metalloenzymes that catalyze the disproportion of superoxide to peroxide and molecular oxygen through alternate oxidation and reduction of their metal ions. In general, SODs are classified into four forms by their catalytic metals namely; FeSOD, MnSOD, Cu/ZnSOD and NiSOD. In addition, a cambialistic form that uses Fe/Mn in its active site also exists. Cyanobacteria, the oxygen evolving photosynthetic prokaryotes, produce reactive oxygen species that can damage cellular components leading to cell death. Thus, the co-evolution of an antioxidant system was necessary for the survival of photosynthetic organisms with SOD as the initial enzyme evolved to alleviate the toxic effect. Cyanobacteria represent the first oxygenic photoautotrophs and their SOD sequences available in the databases lack clear annotation. Hence, the present study focuses on structure and sequence pattern of subsets of cyanobacterial superoxide dismutases.

RESULT

The sequence conservation and structural analysis of Fe (Thermosynechococcus elongatus BP1) and MnSOD (Anabaena sp. PCC7120) reveal the sharing of N and C terminal domains. At the C terminal domain, the metal binding motif in cyanoprokaryotes is DVWEHAYY while it is D-X-[WF]-E-H-[STA]-[FY]-[FY] in other pro- and eukaryotes. The cyanobacterial FeSOD differs from MnSOD at least in three ways viz. (i) FeSOD has a metal specific signature F184X3A188Q189.......T280......F/Y303 while, in Mn it is R184X3G188G189......G280......W303, (ii) aspartate ligand forms a hydrogen bond from the active site with the outer sphere residue of W243 in Fe where as it is Q262 in MnSOD; and (iii) two unique lysine residues at positions 201 and 255 with a photosynthetic role, found only in FeSOD. Further, most of the cyanobacterial Mn metalloforms have a specific transmembrane hydrophobic pocket that distinguishes FeSOD from Mn isoform. Cyanobacterial Cu/ZnSOD has a copper domain and two different signatures G-F-H-[ILV]-H-x-[NGT]-[GPDA]-[SQK]-C and G-[GA]-G-G-[AEG]-R-[FIL]-[AG]-C-G, while Ni isoform has an nickel containing SOD domain containing a Ni-hook HCDGPCVYDPA.

CONCLUSION

The present analysis unravels the ambiguity among cyanobacterial SOD isoforms. NiSOD is the only SOD found in lower forms; whereas, Fe and Mn occupy the higher orders of cyanobacteria. In conclusion, cyanobacteria harbor either Ni alone or a combination of Fe and Ni or Fe and Mn as their catalytic active metal while Cu/Zn is rare.

背景

超氧化物歧化酶（SOD）是普遍存在的金属酶，通过其金属离子的交替氧化和还原催化超氧化物歧化为过氧化物和分子氧。一般来说，SOD根据其催化金属分为四种形式，即铁超氧化物歧化酶（FeSOD）、锰超氧化物歧化酶（MnSOD）、铜锌超氧化物歧化酶（Cu/ZnSOD）和镍超氧化物歧化酶（NiSOD）。此外，还存在一种在其活性位点使用铁/锰的兼性形式。蓝藻是能进行光合作用并产生氧气的原核生物，会产生活性氧，这些活性氧会损害细胞成分导致细胞死亡。因此，抗氧化系统的共同进化对于光合生物的生存是必要的，SOD作为最初进化出来的酶，可减轻毒性作用。蓝藻是最早的产氧光合自养生物，数据库中可用的蓝藻SOD序列缺乏清晰的注释。因此，本研究聚焦于蓝藻超氧化物歧化酶子集的结构和序列模式。

结果

对铁超氧化物歧化酶（嗜热栖热菌BP1）和锰超氧化物歧化酶（鱼腥藻PCC7120）的序列保守性和结构分析揭示了N端和C端结构域的共享。在C端结构域，蓝原核生物中的金属结合基序是DVWEHAYY，而在其他原核生物和真核生物中是D-X-[WF]-E-H-[STA]-[FY]-[FY]。蓝藻铁超氧化物歧化酶与锰超氧化物歧化酶至少在三个方面存在差异，即：（i）铁超氧化物歧化酶具有金属特异性特征F184X3A188Q189.......T280......F/Y303，而在锰超氧化物歧化酶中是R184X3G188G189......G280......W303；（ii）天冬氨酸配体在铁超氧化物歧化酶中从活性位点与W243的外层球残基形成氢键，而在锰超氧化物歧化酶中是Q262；（iii）仅在铁超氧化物歧化酶中发现的位于201和255位的两个具有光合作用的独特赖氨酸残基。此外，大多数蓝藻锰金属形式具有特定的跨膜疏水口袋，这将铁超氧化物歧化酶与锰同工型区分开来。蓝藻铜锌超氧化物歧化酶具有一个铜结构域和两个不同的特征G-F-H-[ILV]-H-x-[NGT]-[GPDA]-[SQK]-C和G-[GA]-G-G-[AEG]-R-[FIL]-[AG]-C-G，而镍同工型具有一个含镍的超氧化物歧化酶结构域，包含一个镍钩HCDGPCVYDPA。