Abstract
Studies on membrane development in purple bacteria during adaptation to alterations in light intensity and oxygen tension are reviewed. Anoxygenic phototrophic such as the purple α-proteobacterium Rhodobacter sphaeroides have served as simple, dynamic, and experimentally accessible model organisms for studies of the photosynthetic apparatus. A major landmark in photosynthesis research, which dramatically illustrates this point, was provided by the determination of the X-ray structure of the reaction center (RC) in Blastochloris viridis (Deisenhofer and Michel, EMBO J 8:2149–2170, 1989), once it was realized that this represented the general structure for the photosystem II RC present in all oxygenic phototrophs. This seminal advance, together with a considerable body of subsequent research on the light-harvesting (LH) and electron transfer components of the photosynthetic apparatus has provided a firm basis for the current understanding of how phototrophs acclimate to alterations in light intensity and quality. Oxygenic phototrophs adapt to these changes by extensive thylakoid membrane remodeling, which results in a dramatic supramolecular reordering to assure that an appropriate flow of quinone redox species occurs within the membrane bilayer for efficient and rapid electron transfer. Despite the high level of photosynthetic unit organization in Rba. sphaeroides as observed by atomic force microscopy (AFM), fluorescence induction/relaxation measurements have demonstrated that the addition of the peripheral LH2 antenna complex in cells adapting to low-intensity illumination results in a slowing of the rate of electron transfer turnover by the RC of up to an order of magnitude. This is ascribed to constraints in quinone redox species diffusion between the RC and cytochrome bc 1 complexes arising from the increased packing density as the intracytoplasmic membrane (ICM) bilayer becomes crowded with LH2 rings. In addition to downshifts in light intensity as a paradigm for membrane development studies in Rba. sphaeroides, the lowering of oxygen tension in chemoheterotropically growing cells results in a gratuitous formation of the ICM by an extensive membrane biogenesis process. These membrane alterations in response to lowered illumination and oxygen levels in purple bacteria are under the control of a number of interrelated two-component regulatory circuits reviewed here, which act at the transcriptional level to regulate the formation of both the pigment and apoprotein components of the LH, RC, and respiratory complexes. We have performed a proteomic examination of the ICM development process in which membrane proteins have been identified that are temporally expressed both during adaptation to low light intensity and ICM formation at low aeration and are spatially localized in both growing and mature ICM regions. For these proteomic analyses, membrane growth initiation sites and mature ICM vesicles were isolated as respective upper-pigmented band (UPB) and chromatophore fractions and subjected to clear native electrophoresis for isolation of bands containing the LH2 and RC–LH1 core complexes. In chromatophores, increasing levels of LH2 polypeptides relative to those of the RC–LH1 complex were observed as ICM membrane development proceeded during light-intensity downshifts, along with a large array of other associated proteins including high spectral counts for the F1FO–ATP synthase subunits and the cytochrome bc 1 complex, as well as RSP6124, a protein of unknown function, that was correlated with increasing LH2 spectral counts. In contrast, the UPB was enriched in cytoplasmic membrane (CM) markers, including electron transfer and transport proteins, as well as general membrane protein assembly factors confirming the origin of the UPB from both peripheral respiratory membrane and sites of active CM invagination that give rise to the ICM. The changes in ICM vesicles were correlated to AFM mapping results (Adams and Hunter, Biochim Biophys Acta 1817:1616–1627, 2012), in which the increasing LH2 levels were shown to form densely packed LH2-only domains, representing the light-responsive antenna complement formed under low illumination. The advances described here could never have been envisioned when the author was first introduced in the mid-1960s to the intricacies of the photosynthetic apparatus during a lecture delivered in a graduate Biochemistry course at the University of Illinois by Govindjee, to whom this volume is dedicated on the occasion of his 80th birthday.
This is a preview of subscription content, log in via an institution to check access.
Abbreviations
- AFM:
-
Atomic force microscopy
- BChl:
-
Bacteriochlorophyll a
- BP:
-
Bacteriophytochrome
- CM:
-
Cytoplasmic membrane
- FIRe:
-
Fluorescence induction and relaxation
- FRRF:
-
Fast repetition rate fluorescence
- ICM:
-
Intracytoplasmic membrane
- LH:
-
Light harvesting
- LH1:
-
Core light-harvesting complex
- LH2:
-
Peripheral light-harvesting complex
- PSI:
-
Photosystem I
- PSII:
-
Photosystem II
- QA :
-
Primary reaction center ubiquinone
- QB :
-
Secondary reaction center ubiquinone
- RC:
-
Photochemical reaction center
- UPB:
-
Upper-pigmented band
- UQ:
-
Ubiquinone
References
Aagaard J, Sistrom WR (1972) Control of synthesis of reaction center bacteriochlorophyll in photosynthetic bacteria. Photochem Photobiol 15:209–225
Adams PG, Hunter CN (2012) Adaptation of intracytoplasmic membranes to altered light intensity in Rhodobacter sphaeroides. Biochim Biophys Acta 1817:1616–1617
Allen JP, Feher G, Yeates TO, Rees DC, Deisenhofer J, Michel H, Huber R (1986) Structural homology of reaction centers from Rhodopseudomonas sphaeroides and Rhodopseudomonas viridis as determined by X-ray diffraction. Proc Natl Acad Sci USA 83:8589–8593
Axelrod HL, Okamura M (2005) The structure and function of the cytochrome c 2: reaction center electron transfer complex from Rhodobacter sphaeroides. Photosynth Res 85:101–114
Bahatyrova S, Frese RN, Siebert CA, van der Werf KO, van Grondelle R, Niederman RA, Bullough PA, Otto C, Olsen JD, Hunter CN (2004) The native architecture of a photosynthetic membrane. Nature 430:1058–1062
Bauer C, Setterdahl A, Wu J, Robinson B (2008) Regulation of gene expression in response to oxygen tension. In: Hunter CN, Daldal F, Thurnauer MC, Beatty JT (eds) The purple phototrophic bacteria. Springer, Dordrecht, pp 707–725
Bowman WC, Du S, Bauer CE, Kranz RG (1999) In vitro activation and repression of photosynthesis gene transcription in Rhodobacter capsulatus. Mol Microbiol 33:429–437
Bowyer JR, Hunter CN, Ohnishi T, Niederman RA (1985) Photosynthetic membrane development in Rhodopseudomonas sphaeroides: spectral and kinetic characterization of redox components of light-driven electron flow in apparent photosynthetic membrane growth initiation sites. J Biol Chem 260:3295–3304
Braatsch S, Gomelsky M, Kuphal S, Klug G (2002) A single flavoprotein, AppA, integrates both redox and light signals in Rhodobacter sphaeroides. Mol Microbiol 45:827–836
Braatsch S, Johnson JA, Noll K, Beatty JT (2007) The O2-responsive repressor PpsR2 but not PpsR1 transduces a light signal sensed by the BphP1 phytochrome in Rhodopseudomonas palustris CGA009. FEMS Microbiol Lett 272:60–64
Chang CH, Tiede D, Tang J, Smith U, Norris J, Schiffer M (1986) Structure of Rhodopseudomonas sphaeroides R-26 reaction center. FEBS Lett 205:82–86
Chuartzman SG, Nevo R, Shimoni E, Charuvi D, Kiss V, Ohad I, Brumfeld V, Reich Z (2008) Thylakoid membrane remodeling during state transitions in Arabidopsis. Plant Cell 20:1029–1039
Cogdell RJ, Howard TD, Bittl R, Schlodder E, Geisenheimer I, Lubitz W (2000) How carotenoids protect bacterial photosynthesis. Philos Trans R Soc Lond B 355:1345–1349
Cohen-Bazire G, Sistrom WR, Stanier RY (1957) Kinetic studies of pigment synthesis by non-sulfur purple bacteria. J Cell Comp Physiol 49:25–68
Deisenhofer J, Michel M (1989) Nobel lecture: the photosynthetic reaction centre from the purple bacterium Rhodopseudomonas viridis. EMBO J 8:2149–2170
Drews G, Niederman RA (2002) Membrane biogenesis in anoxygenic photosynthetic prokaryotes. Photosynth Res 73:87–94
Eraso JM, Kaplan S (1994) prrA, a putative response regulator involved in oxygen regulation of photosynthesis gene expression in Rhodobacter sphaeroides. J Bacteriol 176:32–43
Evans K, Fordham-Skelton AP, Mistry H, Reynolds CD, Lawless AM, Papiz MZ (2005) A bacteriophytochrome regulates the synthesis of LH4 complexes in Rhodopseudomonas palustris. Photosynth Res 85:169–180
Evans K, Georgiou T, Hillon T, Fordham-Skelton A, Papiz M (2008) Bacteriophytochromes control photosynthesis in Rhodopseudomonas palustris. In: Hunter CN, Daldal F, Thurnauer MC, Beatty JT (eds) The purple phototrophic bacteria. Springer, Dordrecht, pp 799–809
Feniouk BA, Junge W (2008) Proton translocation and ATP synthesis by the FOF1-ATPase of purple bacteria. In: Hunter CN, Daldal F, Thurnauer MC, Beatty JT (eds) The purple phototrophic bacteria. Springer, Dordrecht, pp 475–493
Francia F, Dezi M, Rebecchi A, Mallardi A, Palazzo G, Melandri BA, Venturoli G (2004) Light harvesting complex 1 stabilizes P+QB− charge separation in reaction centers of Rhodobacter sphaeroides. Biochemistry 43:14199–14210
Giraud E, Fardoux J, Fourrier N, Hannibal L, Genty B, Bouyer P, Dreyfus B, Verméglio A (2002) Bacteriophytochrome controls photosystem synthesis in anoxygenic bacteria. Nature 417:202–205
Giraud E, Zappa S, Vuillet L, Adriano JM, Hannibal L, Fardoux J, Berthomieu C, Bouyer P, Pignol D, Verméglio A (2005) A new type of bacteriophytochrome acts in tandem with a classical bacteriophytochrome to control the antennae synthesis in Rhodopseudomonas palustris. J Biol Chem 280:32389–32397
Gomelsky M, Kaplan S (1995a) Genetic evidence that PpsR from Rhodobacter sphaeroides 2.4.1 functions as a repressor of puc and bchF expression. J Bacteriol 177:1634–1637
Gomelsky M, Kaplan S (1995b) AppA, a novel gene encoding a trans-acting factor involved in the regulation of photosynthesis gene expression in Rhodobacter sphaeroides 2.4.1. J Bacteriol 177:4609–4618
Gomelsky M, Klug G (2002) BLUF: a novel FAD-binding domain involved in sensory transduction in microorganisms. Trends Biochem Sci 27:497–500
Hunter CN, vanGrondelle R, Holmes NG, Jones OTG, Niederman RA (1979) Fluorescence yield properties of a fraction enriched in newly synthesized bacteriochlorophyll a-protein complexes from Rhodopseudomonas sphaeroides. Photochem Photobiol 30:313–316
Hunter CN, Pennoyer JD, Sturgis JN, Farrelly D, Niederman RA (1988) Oligomerization states and associations of light-harvesting pigment–protein complexes of Rhodobacter sphaeroides as analyzed by lithium dodecyl sulfate-polyacrylamide gel electrophoresis. Biochemistry 27:3459–3467
Hunter CN, Tucker JD, Niederman RA (2005) The assembly and organisation of photosynthetic membranes in Rhodobacter sphaeroides. Photochem Photobiol Sci 4:1023–1027
Hunter CN, Daldal F, Thurnauer MC, Beatty JT (eds) (2008) The purple phototrophic bacteria. Advances in photosynthesis and respiration, vol 28. Springer, Dordrecht
Kim SK, Mason JT, Knaff DB, Bauer CE, Setterdahl AT (2006) Redox properties of the Rhodobacter sphaeroides transcriptional regulatory proteins PpsR and AppA. Photosynth Res 89:89–98
Kirchhoff H, Haase W, Wegner S, Danielsson R, Ackermann R, Albertsson PA (2007) Low-light-induced formation of semicrystalline photosystem II arrays in higher plant chloroplasts. Biochemistry 46:11169–11176
Klug G, Masuda S (2008) Regulation of genes by light. In: Hunter CN, Daldal F, Thurnauer MC, Beatty JT (eds) The purple phototrophic bacteria. Springer, Dordrecht, pp 727–741
Koblízek M, Shih JD, Breitbart SI, Ratcliffe EC, Kolber ZS, Hunter CN, Niederman RA (2005) Sequential assembly of photosynthetic units in Rhodobacter sphaeroides as revealed by fast repetition rate analysis of variable bacteriochlorophyll a fluorescence. Biochim Biophys Acta 1706:220–231
Lavergne J, Verméglio A, Joliot P (2008) Functional coupling between reaction centers and cytochrome bc 1 complexes. In: Hunter CN, Daldal F, Thurnauer MC, Beatty JT (eds) The purple phototrophic bacteria. Springer, Dordrecht, pp 509–536
Mank NN, Berghoff BA, Hermanns YN, Klug G (2012) Regulation of bacterial photosynthesis genes by the small noncoding RNA PcrZ. Proc Natl Acad Sci USA 109:16306–16311
Masuda S, Bauer CE (2002) AppA is a blue light photoreceptor that antirepresses photosynthesis gene expression in Rhodobacter sphaeroides. Cell 110:613–623
Metz S, Haberzettl K, Frühwirth S, Teich K, Hasewinkel C, Klug G (2012) Interaction of two photoreceptors in the regulation of bacterial photosynthesis genes. Nucleic Acids Res 40:5901–5909
Monger TG, Cogdell RJ, Parson WW (1976) Triplet states of bacteriochlorophyll and carotenoids in chromatophores of photosynthetic bacteria. Biochim Biophys Acta 449:136–153
Niederman RA (2006) Structure, function and formation of bacterial intracytoplasmic membranes. In: Shively JM (ed) Complex intracellular structures in prokaryotes, microbiology monographs, vol 2. Springer, Berlin, pp 193–227
Niederman RA, Mallon DE, Langan JJ (1976) Membranes of Rhodopseudomonas sphaeroides. IV. Assembly of chromatophores in low-aeration cell suspensions. Biochim Biophys Acta 440:429–447
Niederman RA, Mallon DE, Parks LC (1979) Membranes of Rhodopseudomonas sphaeroides. VI. Isolation of a fraction enriched in newly synthesized bacteriochlorophyll a-protein complexes. Biochim Biophys Acta 555:210–220
Papiz MZ, Prince SM, Howard T, Cogdell RJ, Isaacs NW (2003) The structure and thermal motion of the B800–850 LH2 complex from Rhodopseudomonas acidophila at 2.0 Å resolution and 100 K: new structural features and functionally relevant motions. J Mol Biol 326:1523–1538
Parson WW, Warshel A (2008) Mechanism of charge separation in purple bacterial reaction centers. In: Hunter CN, Daldal F, Thurnauer MC, Beatty JT (eds) The purple phototrophic bacteria. Springer, Dordrecht, pp 355–377
Ponnampalam SN, Bauer CE (1997) DNA binding characteristics of CrtJ. A redox-responding repressor of bacteriochlorophyll, carotenoid, and light harvesting-II gene expression in Rhodobacter capsulatus. J Biol Chem 272:18391–18396
Qian P, Hunter CN, Bullough PA (2005) The 8.5 Å projection structure of the core RC-LH1-PufX dimer of Rhodobacter sphaeroides. J Mol Biol 349:948–960
Reilly PA, Niederman RA (1986) Role of apparent membrane growth initiation sites during photosynthetic membrane development in synchronously dividing Rhodopseudomonas sphaeroides. J Bacteriol 167:153–159
Rhee K-H, Morris EP, Barber J, Kühlbrandt W (1998) Three-dimensional structure of the plant photosystem II reaction centre at 8 Å resolution. Nature 396:283–286
Rochaix JD (2007) Role of thylakoid protein kinases in photosynthetic acclimation. FEBS Lett 581:2768–2775
Roszak AW, Howard TD, Southall J, Gardiner AT, Law CJ, Isaacs NW, Cogdell RJ (2003) Crystal structure of the RC-LH1 core complex from Rhodopseudomonas palustris. Science 302:1969–1972
Schumacher A, Drews G (1979) Effects of light intensity on membrane differentiation in Rhodopseudomonas capsulata. Biochim Biophys Acta 547:417–428
Sturgis JN, Niederman RA (2008a) Atomic force microscopy reveals multiple patterns of antenna organization in purple bacteria: implications for energy transduction mechanisms and membrane modeling. Photosynth Res 95:269–278
Sturgis JN, Niederman RA (2008b) Organization and assembly of light-harvesting complexes in the purple bacterial membrane. In: Hunter CN, Daldal F, Thurnauer MC, Beatty JT (eds) The purple phototrophic bacteria. Springer, Dordrecht, pp 253–273
Sturgis JN, Hunter CN, Niederman RA (1988) Spectra and extinction coefficients of near-infrared absorption bands in membranes of Rhodobacter sphaeroides mutants lacking light-harvesting and reaction center complexes. Photochem Photobiol 48:243–247
Sturgis JN, Tucker JD, Olsen JD, Hunter CN, Niederman RA (2009) Atomic force microscopy studies of native photosynthetic membranes. Biochemistry 48:3679–3698
Swem LR, Bauer CE (2002) Coordination of ubiquinol oxidase and cytochrome ccb 3 oxidase expression by multiple regulators. J Bacteriol 184:2815–2820
Swem LR, Kraft BJ, Swem DL, Setterdahl AT, Masuda S, Knaff DB, Zaleski JM, Bauer CE (2003) Signal transduction by the global regulator RegB is mediated by a redox-active cysteine. EMBO J 22:4699–4708
Swem LR, Gong X, Yu CA, Bauer CE (2006) Identification of a ubiquinone-binding site that affects autophosphorylation of the sensor kinase RegB. J Biol Chem 281:6768–6775
Tavano CL, Donohue TJ (2006) Development of the bacterial photosynthetic apparatus. Curr Opin Microbiol 9:625–631
Tucker JD, Siebert CA, Escalante M, Adams PG, Olsen JD, Otto C, Stokes DL, Hunter CN (2010) Membrane invagination in Rhodobacter sphaeroides is initiated at curved regions of the cytoplasmic membrane, then forms both budded and fully detached spherical vesicles. Mol Microbiol 76:833–847
Vredenberg WJ, Duysens LN (1963) Transfer of energy from bacteriochlorophyll to a reaction centre during bacterial photosynthesis. Nature 197:355–357
Woronowicz K, Niederman RA (2010) Proteomic analysis of the developing intracytoplasmic membrane in Rhodobacter sphaeroides during adaptation to low light intensity. Adv Exp Med Biol 675:161–178
Woronowicz K, Sha D, Frese RN, Niederman RA (2011a) The accumulation of the light-harvesting 2 complex during remodeling of the Rhodobacter sphaeroides intracytoplasmic membrane results in a slowing of the electron transfer turnover rate of photochemical reaction centers. Biochemistry 50:4819–4829
Woronowicz K, Sha D, Frese RN, Sturgis JN, Nanda V, Niederman RA (2011b) The effects of protein crowding in bacterial photosynthetic membranes on the flow of quinone redox species between the photochemical reaction center and the ubiquinol-cytochrome c 2 oxidoreductase. Metallomics 3:765–774
Woronowicz K, Olubanjo OB, Sung HC, Lamptey J, Niederman RA (2012) Differential assembly of polypeptides of the light-harvesting 2 complex encoded by distinct operons during acclimation of Rhodobacter sphaeroides to low light intensity. Photosynth Res 111:125–138
Woronowicz K, Harrold JW, Kay JM, Niederman RA (2013) Structural and functional proteomics of intracytoplasmic membrane assembly in Rhodobacter sphaeroides. J Mol Microbiol Biotechnol 23(1–2):48–62
Zeilstra-Ryalls JH, Kaplan S (1995) Aerobic and anaerobic regulation in Rhodobacter sphaeroides 2.4.1: the role of the fnrL gene. J Bacteriol 177:6422–6431
Zeng X, Choudhary M, Kaplan S (2003) A second and unusual pucBA operon of Rhodobacter sphaeroides 2.4.1: genetics and function of the encoded polypeptides. J Bacteriol 185:6171–6184
Acknowledgments
Work in the author’s laboratory was supported by grants from the U. S. Department of Energy (Grant No. DE-FG02-08ER15957 from the Chemical Sciences, Geosciences and Biosciences Division, Office of Basic Energy Sciences, Office of Science) and the National Science Foundation (Subaward No. 12-764). I thank Kamil Woronowicz, Raoul Frese, Oluwatobi B. Olubanjo, and Daniel Sha for their participation in these studies.
Author information
Authors and Affiliations
Corresponding author
Additional information
For: SPECIAL ISSUE of Photosynthesis Research devoted to “Photosynthesis Education” in honor of Professor Govindjee on the occasion of his 80th birthday.
Guest editors: Suleyman I. Allakhverdiev, Gerald Edwards and Jian-Ren Shen.
Rights and permissions
About this article
Cite this article
Niederman, R.A. Membrane development in purple photosynthetic bacteria in response to alterations in light intensity and oxygen tension. Photosynth Res 116, 333–348 (2013). https://doi.org/10.1007/s11120-013-9851-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11120-013-9851-0