Sivakumar Velautham, Wang Ruili, Hastings Gary
Department of Physics and Astronomy, Georgia State University, Atlanta, Georgia 30303, USA.
Biochemistry. 2005 Feb 15;44(6):1880-93. doi: 10.1021/bi0497493.
Time-resolved step-scan Fourier transform infrared (FTIR) difference spectroscopy, with 5 mus time resolution, has been used to produce P700(+)A(1)(-)/P700A(1) FTIR difference spectra in intact photosystem I particles from Synechococcus sp. 7002 and Synechocystis sp. 6803 at 77 K. Corresponding spectra were also obtained for fully deuterated photosystem I particles from Synechococcus sp. 7002 as well as fully (15)N- and (13)C-labeled photosystem I particles from Synechocystis sp. 6803. Static P700(+)/P700 FTIR difference spectra at 77 K were also obtained for all of the unlabeled and labeled photosystem I particles. From the time-resolved and static FTIR difference spectra, A(1)(-)/A(1) FTIR difference spectra were constructed. The A(1)(-)/A(1) FTIR difference spectra obtained for unlabeled trimeric photosystem I particles from both cyanobacterial strains are very similar. There are some mode frequency differences in spectra obtained for monomeric and trimeric PS I particles. However, the spectra can be interpreted in an identical manner, with the proposed band assignments being compatible with all of the data obtained for labeled and unlabeled photosystem I particles. In A(1)(-)/A(1) FTIR difference spectra obtained for unlabeled photosystem I particles, negative bands are observed at 1559 and 1549-1546 cm(-)(1). These bands are assigned to amide II protein vibrations, as they downshift approximately 86 cm(-)(1) upon deuteration and approximately 13 cm(-)(1) upon (15)N labeling. Difference band features at 1674-1677(+) and 1666(-) cm(-)(1) display isotope-induced shifts that are consistent with these bands being due to amide I protein vibrations. The observed amide modes suggest alteration of the protein backbone (possibly in the vicinity of A(1)) upon A(1) reduction. A difference band at 1754(+)/1748(-) cm(-)(1) is observed in unlabeled spectra from both strains. The frequency of this difference band, as well as the observed isotope-induced shifts, indicate that this difference band is due to a 13(3) ester carbonyl group of chlorophyll a species, most likely the A(0) chlorophyll a molecule that is in close proximity to A(1). Thus A(1) reduction perturbs A(0), probably via a long-range electrostatic interaction. A negative band is observed at 1693 cm(-)(1). The isotope shifts associated with this band are consistent with this band being due to the 13(1) keto carbonyl group of chlorophyll a, again, most likely the 13(1) keto carbonyl group of the A(0) chlorophyll a that is close to A(1). Semiquinone anion bands are resolved at approximately 1495(+) and approximately 1414(+) cm(-)(1) in the A(1)(-)/A(1) FTIR difference spectra for photosystem I particles from both cyanobacterial strains. The isotope-induced shifts of these bands could suggest that the 1495(+) and 1414(+) cm(-)(1) bands are due to C-O and C-C modes of A(1)(-), respectively.
时间分辨步进扫描傅里叶变换红外(FTIR)差示光谱法,具有5微秒的时间分辨率,已被用于在77K下从聚球藻属7002和集胞藻属6803完整的光系统I颗粒中产生P700(+)A(1)(-)/P700A(1) FTIR差示光谱。还获得了来自聚球藻属7002的完全氘代光系统I颗粒以及来自集胞藻属6803的完全(15)N和(13)C标记的光系统I颗粒的相应光谱。还获得了所有未标记和标记的光系统I颗粒在77K下的静态P700(+)/P700 FTIR差示光谱。根据时间分辨和静态FTIR差示光谱,构建了A(1)(-)/A(1) FTIR差示光谱。从两种蓝藻菌株获得的未标记三聚体光系统I颗粒的A(1)(-)/A(1) FTIR差示光谱非常相似。单体和三聚体PS I颗粒获得的光谱存在一些模式频率差异。然而,这些光谱可以以相同的方式解释,所提出的谱带归属与为标记和未标记的光系统I颗粒获得的所有数据兼容。在未标记的光系统I颗粒的A(1)(-)/A(1) FTIR差示光谱中,在1559和1549 - 1546 cm(-)(1)处观察到负带。这些带被指定为酰胺II蛋白质振动,因为它们在氘代时向下移动约86 cm(-)(1),在(15)N标记时向下移动约13 cm(-)(1)。在1674 - 1677(+)和1666(-) cm(-)(1)处的差示谱带特征显示出同位素诱导的位移,这与这些带是由于酰胺I蛋白质振动一致。观察到的酰胺模式表明在A(1)还原时蛋白质主链(可能在A(1)附近)发生了改变。在两种菌株的未标记光谱中均观察到1754(+)/1748(-) cm(-)(1)处的差示谱带。该差示谱带的频率以及观察到的同位素诱导位移表明该差示谱带是由于叶绿素a物种的13(3)酯羰基,最有可能是与A(1)紧密相邻的A(0)叶绿素a分子。因此,A(1)还原可能通过长程静电相互作用扰动A(0)。在1693 cm(-)(1)处观察到一个负带。与该带相关的同位素位移与该带是由于叶绿素a的13(1)酮羰基一致,同样,最有可能是靠近A(1)的A(0)叶绿素a的13(1)酮羰基。在来自两种蓝藻菌株的光系统I颗粒的A(1)(-)/A(1) FTIR差示光谱中,半醌阴离子带在约1495(+)和约1414(+) cm(-)(1)处得到分辨。这些带的同位素诱导位移可能表明1495(+)和1414(+) cm(-)(1)处的带分别是由于A(1)(-)的C - O和C - C模式。
