Inactivation of the geranylgeranyl reductase (ChlP) gene in the cyanobacterium Synechocystis sp. PCC 6803

Geranylgeranyl reductase catalyses the reduction of geranylgeranyl pyrophosphate to phytyl pyrophosphate required for synthesis of chlorophylls, phylloquinone and tocopherols. The gene chlP (ORF sll1091) encoding the enzyme has been inactivated in the cyanobacterium Synechocystis sp. PCC 6803. The resulting ΔchlP mutant accumulates exclusively geranylgeranylated chlorophyll a instead of its phytylated analogue as well as low amounts of α-tocotrienol instead of α-tocopherol. Whereas the contents of chlorophyll and total carotenoids are decreased, abundance of phycobilisomes is increased in ΔchlP cells. The mutant assembles functional photosystems I and II as judged from 77 K fluorescence and electron transport measurements. However, the mutant is unable to grow photoautotrophically due to instability and rapid degradation of the photosystems in the absence of added glucose. We suggest that instability of the photosystems in ΔchlP is directly related to accumulation of geranylgeranylated chlorophyll a. Increased rigidity of the chlorophyll isoprenoid tail moiety due to three additional CC bonds is the likely cause of photooxidative stress and reduced stability of photosynthetic pigment-protein complexes assembled with geranylgeranylated chlorophyll a in the ΔchlP mutant.     

Chlorophyll a phytylation is required for the stability of photosystems I and II in the cyanobacterium Synechocystis sp. PCC 6803

In oxygenic phototrophic organisms, the phytyl ‘tail’ of chlorophyll a is formed from a geranylgeranyl residue by the enzyme geranylgeranyl reductase. Additionally, in oxygenic phototrophs, phytyl residues are the tail moieties of tocopherols and phylloquinone. A mutant of the cyanobacterium Synechocystis sp. PCC 6803 lacking geranylgeranyl reductase, ΔchlP, was compared to strains with specific deficiencies in either tocopherols or phylloquinone to assess the role of chlorophyll a phytylatation (versus geranylgeranylation). The tocopherol‐less Δhpt strain grows indistinguishably from the wild‐type under ‘standard’ light photoautotrophic conditions, and exhibited only a slightly enhanced rate of photosystem I degradation under strong irradiation. The phylloquinone‐less ΔmenA mutant also grows photoautotrophically, albeit rather slowly and only at low light intensities. Under strong irradiation, ΔmenA retained its chlorophyll content, indicative of stable photosystems. ΔchlP may only be cultured photomixotrophically (due to the instability of both photosystems I and II). The increased accumulation of myxoxanthophyll in ΔchlP cells indicates photo‐oxidative stress even under moderate illumination. Under high‐light conditions, ΔchlP exhibited rapid degradation of photosystems I and II. In conclusion, the results demonstrate that chlorophyll a phytylation is important for the (photo)stability of photosystems I and II, which, in turn, is necessary for photoautotrophic growth and tolerance of high light in an oxygenic environment.     

Conversion of Chlorophyll b to Chlorophyll a and the Assembly of Chlorophyll with Apoproteins by Isolated Chloroplasts

The photosynthetic apparatus is reorganized during acclimation to various light environments. During adaptation of plants grown under a low-light to high-light environment, the light-harvesting chlorophyll a/b-protein complexes decompose concomitantly with an increase in the core complex of photosystem II. To study the mechanisms for reorganization of photosystems, the assembly of chlorophyll with apoproteins was investigated using isolated chloroplasts. When [14C]chlorophyllide b was incubated with chloroplasts in the presence of phytyl pyrophosphate, it was esterified and some of the [14C]chlorophyll b was converted to [14C]chlorophyll a via 7-hydroxymethyl chlorophyll. [14C]Chlorophyll a and b were incorporated into chlorophyll-protein complexes. Light-harvesting chlorophyll a/b-protein complexes of PSII had a lower [14C]chlorophyll a to [14C]chlorophyll b ratio than P700-chlorophyll a-protein complexes, indicating the specific binding of chlorophyll to apoproteins in our systems. 7-Hydroxymethyl chlorophyll, an intermediate molecule from chlorophyll b to chlorophyll a, did not become assembled with any apoproteins. These results indicate that chlorophyll b is released from light-harvesting chlorophyll a/b-protein complexes of photosystem II and converted to chlorophyll a via 7-hydroxymethyl chlorophyll in the lipid bilayer and is then used for the formation of core complexes of photosystems. These mechanisms provide the fast, fine regulation of the photosynthetic apparatus during construction of photosystems.     

Biogenesis of chlorophyll-binding proteins under iron stress in Synechocystis sp. PCC 6803

The biogenesis of chlorophyll-binding proteins under iron stress has been investigated in vivo in a chlN deletion mutant of Synechocystis sp. PCC 6803. The chlN gene encodes one subunit of the light-independent protochlorophyllide reductase. The mutant is unable to synthesis chlorophyll in darkness, causing chlorophyll biosynthesis to become light dependent. When the mutant was propagated in darkness, essentially no chlorophyll and photosystems were detected. Upon return of the chlN deletion mutant to light, 77 K fluorescence emission spectra and oxygen evolution of greening cells under iron-sufficient or -deficient conditions were measured. The gradual blue shift of the photosystem I (PS I) peak upon greening under iron stress suggested the structural alteration of newly synthesized PS I. Furthermore, the rate of biogenesis of PS II was delayed under iron stress, which might be due to the presence of IsiA.     

15N-labeling to determine chlorophyll synthesis and degradation in Synechocystis sp. PCC 6803 strains lacking one or both photosystems

Rates of chlorophyll synthesis and degradation were analyzed in Synechocystis sp. PCC 6803 wild type and mutants lacking one or both photosystems by labeling cells with ((15)NH(4))(2)SO(4) and Na(15)NO(3). Pigments extracted from cells were separated by HPLC and incorporation of the (15)N label into porphyrins was subsequently examined by MALDI-TOF mass spectrometry. The life time (tau) of chlorophyll in wild-type Synechocystis grown at a light intensity of 100 micromol photons m(-2) s(-1) was determined to be about 300 h, much longer than the cell doubling time of about 14 h. Slow chlorophyll degradation (tau approximately 200-400 h) was also observed in Photosystem I-less and in Photosystem II-less Synechocystis mutants, whereas in a mutant lacking both Photosystem I and Photosystem II chlorophyll degradation was accelerated 4-5 fold (tau approximately 50 h). Chlorophyllide and pheophorbide were identified as intermediates of chlorophyll degradation in the Photosystem I-less/Photosystem II-less mutant. In comparison with the wild type, the chlorophyll synthesis rate was five-fold slower in the Photosystem I-less strain and about eight-fold slower in the strain lacking both photosystems, resulting in different chlorophyll levels in the various mutants. The results presented in this paper demonstrate the presence of a regulation that adjusts the rate of chlorophyll synthesis according to the needs of chlorophyll-binding polypeptides associated with the photosystems.     

Photoacoustic studies on the dependence of state transitions on grana stacking

Photoacoustic detection of oxygen evolution and Emerson enhancement in state 1 and state 2 were compared in a tobacco wild type and mutant (Su/su) deficient in chlorophyll. The mutant shows smaller changes in the distribution of excitation energy between the two photosystems than the wild type. Analysis of Emerson enhancement saturation curves indicates that in the mutant which is deficient in grana partitions and shows less stacking, state 1-state 2 transitions reflect changes in the yield of energy transfer from PS II to PS I (spillover). On the other hand, the wild type containing large grana shows changes in absorption cross-sections of the two photosystems upon state transitions. NaF, a specific phosphatase inhibitor, blocks the transition to state 1, indicating that LHC II phosphorylation has a role in excitation energy regulation in both the mutant as well as the wild type. It is demonstrated that N-ethylmaleimide, a specific sulfhydryl reagent, blocks the transition to state 2, suggesting that a disulfide-sulfhydryl redox couple activates the LHC II kinase in vivo.Abbreviations LHC II light harvesting chlorophyll a/b pigment protein complex of PS II - LHC II-P phosphorylated complex - NEM N-ethylmaleimide     

Effects of chlorophyll availability on phycobilisomes in Synechocystis sp. PCC 6803

Inactivation of the chlL gene in Synechocystis sp. PCC 6803 resulted in negligible chlorophyll content when the mutant was grown in darkness. Upon phycocyanin excitation at 580 nm, the 77K fluorescence spectrum of dark-grown cells showed three peaks at 648 nm, 665 nm, and 685 nm, this last being the largest. This reflects the functional presence of major components of phycobilisomes, including phycocyanin, allophycocyanin, and the terminal emitter, and efficient energy transfer between these components. As expected, no fluorescence emission peaks corresponding to chlorophyll in the photosystems were observed. Intact phycobilisomes could be isolated from the dark-grown chlL-deletion mutant. However, the phycobilisomes had a lower efficiency of energy transfer than did those isolated from the light-grown mutant, probably because of a decreased phycobilisome stability in the absence of chlorophyll. Exposing the dark-grown chlL-deletion mutant to light triggered the biosynthesis of chlorophyll. For the first 6 h in the light, upon phycocyanin excitation at 580 nm, the 77K fluorescence emission spectrum of greening cells was identical to that of dark-grown cells that lacked significant amounts of chlorophyll. With increased chlorophyll synthesis, gradual energy transfer from phycobilisomes to the two photosystems can be demonstrated.     

Biogenesis of chlorophyll-binding proteins under iron stress in <Emphasis Type="Italic">Synechocystis</Emphasis> sp. PCC 6803

The biogenesis of chlorophyll-binding proteins under iron stress has been investigated in vivo in a chlN deletion mutant of Synechocystis sp. PCC 6803. The chlN gene encodes one subunit of the light-independent protochlorophyllide reductase. The mutant is unable to synthesize chlorophyll in darkness, causing chlorophyll biosynthesis to become light dependent. When the mutant was propagated in darkness, essentially no chlorophyll and photosystems were detected. Upon return of the chlN deletion mutant to light, 77 K fluorescence emission spectra and oxygen evolution of greening cells under iron-sufficient or-deficient conditions were measured. The gradual blue shift of the photosystem I (PS I) peak upon greening under iron stress suggested the structural alteration of newly synthesized PS I. Furthermore, the rate of biogenesis of PS II was delayed under iron stress, which might be due to the presence of IsiA.     

The redox state of the plastoquinone pool directly modulates minimum chlorophyll fluorescence yield in Chlamydomonas reinhardtii

The effect of the plastoquionone (PQ) pool oxidation state on minimum chlorophyll fluorescence was studied in the green alga Chlamydomonas reinhardtii. In wild type and a mutant strain that lacks both photosystems but retains light harvesting complexes, oxygen depletion induced a rise in minimum chlorophyll fluorescence. An increase in minimum fluorescence yield is also observed when the PQ pool becomes reduced in the presence of oxygen and after application of an ionophore that collapses the transmembrane proton gradient. Together these results indicate that minimum chlorophyll fluorescence is modulated by the PQ oxidation state.     

A novel prenyltransferase for a small GTP-binding protein having a C-terminal Cys-Ala-Cys structure

smg p25A/rab3A p25 is a member of the small GTP-binding protein superfamily which is implicated in intracellular vesicle transport. smg p25A has a cDNA-predicted C-terminal structure of Cys-Ala-Cys. The protein purified from bovine brain membranes is geranylgeranylated at both the two cysteine residues and carboxyl-methylated at the C-terminal cysteine residue. Two types of prenyltransferase for small GTP-binding proteins have thus far been reported: ras p21 farnesyltransferase (ras p21 FT) and rhoA p21 geranylgeranyltransferase (rhoA p21 GGT). Neither of them geranylgeranylated smg p25A having a C-terminal Cys-Ala-Cys structure. In this paper, a smg p25A GGT was partially purified from bovine brain cytosol and separated from the ras p21 FT and rhoA p21 GGT by column chromatographies. smg p25A GGT transferred the geranylgeranyl moiety from geranylgeranyl pyrophosphate to both the two cysteine residues in the C-terminal Cys-Ala-Cys structure of smg p25A. smg p25A GGT did not use farnesyl pyrophosphate as a substrate and was also inactive on c-Ha-ras p21 and rhoA p21 with either farnesyl pyrophosphate or geranylgeranyl pyrophosphate as a substrate. These results indicate that there are at least three types of prenyltransferase for small GTP-binding proteins in mammalian tissues.     

N-labeling to determine chlorophyll synthesis and degradation in Synechocystis sp. PCC 6803 strains lacking one or both photosystems

Rates of chlorophyll synthesis and degradation were analyzed in Synechocystis sp. PCC 6803 wild type and mutants lacking one or both photosystems by labeling cells with (¹⁵NH₄)₂SO₄ and Na¹⁵NO₃. Pigments extracted from cells were separated by HPLC and incorporation of the ¹⁵N label into porphyrins was subsequently examined by MALDI-TOF mass spectrometry. The life time (τ) of chlorophyll in wild-type Synechocystis grown at a light intensity of 100 μmol photons m⁻² s⁻¹ was determined to be about 300 h, much longer than the cell doubling time of about 14 h. Slow chlorophyll degradation (τ ∼200-400 h) was also observed in Photosystem I-less and in Photosystem II-less Synechocystis mutants, whereas in a mutant lacking both Photosystem I and Photosystem II chlorophyll degradation was accelerated 4-5 fold (τ ∼50 h). Chlorophyllide and pheophorbide were identified as intermediates of chlorophyll degradation in the Photosystem I-less/Photosystem II-less mutant. In comparison with the wild type, the chlorophyll synthesis rate was five-fold slower in the Photosystem I-less strain and about eight-fold slower in the strain lacking both photosystems, resulting in different chlorophyll levels in the various mutants. The results presented in this paper demonstrate the presence of a regulation that adjusts the rate of chlorophyll synthesis according to the needs of chlorophyll-binding polypeptides associated with the photosystems.     

Increase in the rate of photosynthetic linear electron transport in cyanobacteruim <Emphasis Type="Italic">Synechocystis</Emphasis> sp. PCC 6803 lacking phycobilisomes

Compensating changes in the pigment apparatus of photosynthesis that resulted from a complete loss of phycobilisomes (PBS) were investigated in the cells of a PAL mutant of cyanobacterium Synechocystis sp. PCC 6803. The ratio PBS/chlorophyll calculated on the basis of the intensity of bands in the action spectra of photosynthetic activity of two photosystems in the wild strain was 1: 70 for PSII and 1: 300 for PSI. Taking into consideration the number of chlorophyll molecules per reaction center in each photosystem, these ratios could be interpreted as association of PBS with dimers of PSII and trimers of PSI as well as greater dependence of PSII as compared with PSI on light absorption by PBS. The ratio PSI/PSII determined by photochemical cross-section of the reactions of two photosystems was 3.5: 1.0 for wild strain of Synechocystis sp. PCC 6803 and 0.7: 1.0 for the PAL mutant. A fivefold increase in the relative content of PSII in pigment apparatus corresponds to a 5-fold increase in the intensity of bands at 685 and 695 nm as related to the band of PSI at 726 nm recorded in low-temperature fluorescence spectrum of the PAL mutant. Inhibition of PSII with diuron resulted in a pronounced stimulation of chlorophyll fluorescence in the PAL mutant as compared to the wild strain of Synechocystis sp. PCC 6803; these data suggested an activation of electron transfer between PSII and PSI in the mutant cells. Thus, the lack of PBS in the mutant strain of Synechocystis sp. PCC 6803 was compensated for by the higher relative content of PSII in the pigment apparatus of photosynthesis and by a rise in the rate of linear electron transport.     

Digeranyl bisphosphonate inhibits geranylgeranyl pyrophosphate synthase

A primary cellular target of the clinical nitrogenous bisphosphonates is the isoprenoid biosynthetic pathway. Specifically these drugs inhibit the enzyme farnesyl pyrophosphate synthase and deplete cells of larger isoprenoids. Inhibition of this enzyme results in impaired processing of both farnesylated and geranylgeranylated proteins. We recently showed that isoprenoid-containing bisphosphonates such as digeranyl bisphosphonate inhibit protein geranylgeranylation and not farnesylation. Here, we show that this impairment results from potent and specific inhibition of geranylgeranyl pyrophosphate synthase, which leads to enhanced depletion of intracellular geranylgeranyl pyrophosphate relative to the nitrogenous bisphosphonate zoledronate.     

The carotenoid-deficient mutant, C-6E, of Scenedesmus obliquus is blocked at the site of phytoene synthase

In contrast to the wild type strain of Scenedesmus , mutant C-6E synthesized only trace amounts of the carotenoids violaxanthin and lutein during prolonged heterotrophic growth. All other carotenoids and carotenoid precursors, such as phytoene, were undetectable. Additionally, only reduced levels of chlorophyll a and no chlorophyll b were formed. To evaluate the potential site of inhibition in the pathway for carotenoid biosynthesis the enzymatic activities of geranylgeranyl pyrophosphate synthase and phytoene synthase were assayed in cell-free extracts. Both enzymes were highly active in extracts of the wild type but only geranylgeranyl pyrophosphate synthase was active in comparable extracts from mutant C-6E . This observation strongly indicates that the phenotype of C-6E results from either a mutation of the phytoene synthase structural gene or of a regulatory gene involved in expression of this enzyme. Other phenotypic effects on composition and structure of the photosynthetic apparatus are discussed as a secondary consequence of the carotenoid deficiency in the thylakoid membranes.     

The development of structure and function in chloroplasts of greening mutants of Scenedesmus II. Development of the photosynthetic apparatus

Mutant C-2A' of Scenedesmus obliquus formed only traces of chlorophylland showed no detectable photosynthesis when grown heterotrophically.When transferred to light this mutant developed chlorophylland its photosynthetic capacity was established. Following ashort initial lag phase, both photosynthetic capacity and totallight absorption of the cells reached saturation more rapidlythan did the rate of chlorophyll synthesis. Consequently, thequantum requirement of photosynthesis showed a rapid declineduring the initial 6 hr of greening, to a best value of 8. Subsequently,a slow increase occurred as additional chlorophyll was synthesized.Behavior parallel to that of the quantum requirement was alsonoted for the relative fluorescence yield and for the onsetof the 520 nm light-induced absorbance change. Of the two photosystems,PS-I seemed to develop more rapidly than did PS-II. The appearanceof PS-II activity appeared to accompany linkage of the two photosystems,as revealed by analysis of the variable-yield fluorescence andthe kinetics of the 520 nm light-induced absorbance change.During the phase of greening at which photosynthetic capacitydeveloped its maximum quantum efficiency, no significant changesin type or content of the various chloroplast cytochromes weredetected. Analysis of the ratio of chlorophyll/plastoquinone,however, showed that changes in this value followed more closelythe observed increase in the quantum efficiency of photosynthesisand the other parameters of photosynthesis examined. (Received May 19, 1972; )     

Crystal structure of type-III geranylgeranyl pyrophosphate synthase from Saccharomyces cerevisiae and the mechanism of product chain length determination

Geranylgeranyl pyrophosphate synthase (GGPPs) catalyzes a condensation reaction of farnesyl pyrophosphate with isopentenyl pyrophosphate to generate C(20) geranylgeranyl pyrophosphate, which is a precursor for carotenoids, chlorophylls, geranylgeranylated proteins, and archaeal ether-linked lipid. For short-chain trans-prenyltransferases that synthesize C(10)-C(25) products, bulky amino acid residues generally occupy the fourth or fifth position upstream from the first DDXXD motif to block further elongation of the final products. However, the short-chain type-III GGPPs in eukaryotes lack any large amino acid at these positions. In this study, the first structure of type-III GGPPs from Saccharomyces cerevisiae has been determined to 1.98 A resolution. The structure is composed entirely of 15 alpha-helices joined by connecting loops and is arranged with alpha-helices around a large central cavity. Distinct from other known structures of trans-prenyltransferases, the N-terminal 17 amino acids (9-amino acid helix A and the following loop) of this GGPPs protrude from the helix core into the other subunit and contribute to the tight dimer formation. Deletion of the first 9 or 17 amino acids caused the dissociation of dimer into monomer, and the Delta(1-17) mutant showed abolished enzyme activity. In each subunit, an elongated hydrophobic crevice surrounded by D, F, G, H, and I alpha-helices contains two DDXXD motifs at the top for substrate binding with one Mg(2+) coordinated by Asp(75), Asp(79), and four water molecules. It is sealed at the bottom with three large residues of Tyr(107), Phe(108), and His(139). Compared with the major product C(30) synthesized by mutant H139A, the products generated by mutant Y107A and F108A are predominantly C(40) and C(30), respectively, suggesting the most important role of Tyr(107) in determining the product chain length.     

Fluorescence,chlorophyll shape and number of photosystem reaction centers I and II in chlorotica mutants of Pisum sativum L

The fluorescent and absorbing properties of chloroplasts and pigment-protein complexes isolated by gel electrophoresis from pea leaves of the cultivar Torsdag and the mutants chlorotica 2004 and 2014 were studied. From the absorption and fluorescence spectra of chlorophylls and their 2nd derivatives, the range of their changes in the native state at 23 degrees C and specific maxima of fluorescence and the forms of chlorophyll of individual complexes at -196 degrees C were found. It was found that in mutant chlorotica 2004 the intensity of fluorescence of long-wave band at 745 nm (23 degrees C) and the maximum--at 728 nm (-196 degrees C) belonging to the light-harvesting complex I increased. Nevertheless, the accumulation of the chlorophyll forms in this mutant at 690, 697 and 708 nm, which make an antenna of reaction centers of photosystem (PS) I decreased. No spectral differences from the spectrum of the wild type were found in mutant chlorotica 2014, except for a weakening of interaction between the complexes of PS I and PS II. It was shown by gel electrophoresis that both mutants were capable of synthesizing any chlorophyll-protein complexes. However, the analysis of the photochemical activity of reaction centers of PS I and PS II as well as calculations of the value of the photosynthetic unit and the number of reaction centers of the photosystems enabled us to conclude that the quantity of the reaction centers of PS I in the mutant chlorotica 2004 was 1.7 times lower due to disturbance of mutations in biosynthesis or the formation of the chlorophyll a-protein complex of PS I. No primary effect of mutation of chlorotica 2014 was established. Proportional changes of all parameters in this mutant gave us the ground to consider them as secondary ones, which are caused by a decrease in chlorophyll content by half.     

Structural-functional organization of chloroplasts in leaves of xantha-702 mutant of Gossypium hirsutum L

For cotton mutant xantha (Gossypium hirsutum L.), it has been established that synthesis of 5-aminolevulinic acid was blocked in the light. In the light this mutant accumulates chlorophyll by 30 times lower as compared to the parent type. In mutant xantha, a very few pigment-protein complexes of PS-I and PS-II are formed in chloroplasts, and formation of membrane system in these is blocked at the early stages, in most cases, at the stage of bubbles and single short thylakoids. Functional activity of reaction centers of PS-I and PS-II is close to zero. Only light-harvesting chlorophyll-a/b protein complexes of the two photosystems are formed in mutant xantha plastid membranes with maximum chlorophyll fluorescence at 728 and 681 nm, respectively. It has been concluded that in mutant xantha genetic block of 5-aminolevulinic acid biosynthesis in the light disturbs the formation and functioning of the complexes of reaction centers of PS-I and PS-II, hindering the development of the whole membrane system in chloroplasts, causing a sharp decrease in productivity.