Orf Gregory S, Tank Marcus, Vogl Kajetan, Niedzwiedzki Dariusz M, Bryant Donald A, Blankenship Robert E
Departments of Chemistry and Biology, Washington University in St. Louis, St. Louis, MO 63130, USA.
Biochim Biophys Acta. 2013 Apr;1827(4):493-501. doi: 10.1016/j.bbabio.2013.01.006. Epub 2013 Jan 24.
Chlorosomes are light-harvesting antenna complexes that occur in green photosynthetic bacteria which have only been shown naturally to contain bacteriochlorophyll (BChl) c, d, or e as the principal light-harvesting pigments. BChl f has long been thought to be an obvious fourth member of the so-called Chlorobium chlorophylls, because it possesses a C-7 formyl group like BChl e and lacks a methyl group at C-20 like BChl d. In organisms that synthesize BChl c or e, the bchU gene product encodes the enzyme that methylates the C-20 position of these molecules. A bchU null mutant of the green sulfur bacterium Chlorobaculum limnaeum strain 1677(T), which normally synthesizes BChl e, has recently been generated via insertional inactivation, and it produces chlorosomes containing BChl f [Vogl et al., 2012]. In this study, chlorosomes containing BChl f and monomeric BChl f in pyridine were characterized using a variety of spectroscopic techniques, including fluorescence emission and excitation spectroscopy, fluorescence lifetime and quantum yield determinations, and circular dichroism. These spectroscopic measurements, as well as Gaussian simulation of the data, show that chlorosomes containing BChl f are less efficient in energy transfer than those with BChl e. This can primarily be attributed to the decreased spectral overlap between the oligomeric BChl f (energy donor) fluorescence emission and the BChl a (energy acceptor) absorption in the chlorosome baseplate. This study allows us to hypothesize that, if they exist in nature, BChl f-containing organisms most likely live in rare high-light, anoxic conditions devoid of Chl a, d, or BChl e filtering.
K. Vogl, M. Tank, G.S. Orf, R.E. Blankenship, D.A. Bryant, Bacteriochlorophyll f: properties of chlorosomes containing the "forbidden chlorophyll," Front. Microbiol. 3 (2012) 298.
叶绿体是存在于绿色光合细菌中的捕光天线复合体,这些细菌仅天然含有细菌叶绿素(BChl)c、d或e作为主要捕光色素。长期以来,BChl f一直被认为是所谓绿菌属叶绿素中明显的第四个成员,因为它像BChl e一样具有C-7甲酰基,并且像BChl d一样在C-20处缺少一个甲基。在合成BChl c或e的生物体中,bchU基因产物编码使这些分子的C-20位置甲基化的酶。绿色硫细菌嗜盐碱绿杆菌菌株1677(T)通常合成BChl e,其bchU缺失突变体最近通过插入失活产生,它产生含有BChl f的叶绿体[Vogl等人,2012年]。在本研究中,使用多种光谱技术对含有BChl f的叶绿体和吡啶中的单体BChl f进行了表征,包括荧光发射和激发光谱、荧光寿命和量子产率测定以及圆二色性。这些光谱测量以及数据的高斯模拟表明,含有BChl f的叶绿体在能量转移方面比含有BChl e的叶绿体效率更低。这主要可归因于叶绿体基板中寡聚BChl f(能量供体)荧光发射与BChl a(能量受体)吸收之间的光谱重叠减少。这项研究使我们能够假设,如果它们存在于自然界中,含有BChl f的生物体很可能生活在罕见的高光、缺氧条件下,且没有Chl a、d或BChl e过滤。
K. Vogl、M. Tank、G.S. Orf、R.E. Blankenship、D.A. Bryant,细菌叶绿素f:含有“禁阻叶绿素”的叶绿体的性质,《微生物前沿》3(2012年)298。
