Abstract
The green alga Chlorella pyrenoidosa can accumulate lutein and chlorophyll under heterotrophic conditions. We propose that the mitochondrial respiratory electron transport chain (mRET) may be involved in this process. To verify this hypothesis, algal cells were treated with different mRET inhibitors. The biosynthesis of lutein and chlorophyll was found to be significantly stimulated by salicylhydroxamic acid (SHAM), whereas their contents substantially decreased after treatment with antimycin A and sodium azide (NaN3). Proteomic studies revealed profound protein alterations related to the redox and energy states, and a network was proposed: The up-regulation of peroxiredoxin reduces oxidized glutathione (GSSG) to reduced glutathione (GSH); phosphoenolpyruvate carboxykinase (PEPCK) catalyzes the conversion of oxaloacetic acid to phosphoenolpyruvate, and after entering the methylerythritol phosphate (MEP) pathway, 4-hydroxy-3-methylbut-2-en-1yl diphosphate synthase reduces 2-C-methyl-d-erythritol-2,4-cyclodiphosphate (ME-Cpp) to 1-hydroxy-2-methyl-2-(E)-butenyl 4-diphosphate (HMBPP), which is closely related to the synthesis of lutein; and coproporphyrinogen III oxidase and ChlI play important roles in the chlorophyll biosynthetic pathway. These results supported that for the heterotrophic C. pyrenoidosa, the signaling, oriented from mRET, may regulate the nuclear genes encoding the enzymes involved in photosynthetic pigment biosynthesis.
Keywords: mitochondrial respiratory electron transport chain, mitochondrial retrograde regulation, redox state, energy metabolism, proteomics
1. Introduction
Microalgae can utilize organic carbon as a carbon and energy source to grow and reproduce without relying on light, which is known as heterotrophic growth [1]. The advantages of heterotrophic cultivation include high density, high degree of process control, consistent and reproducible biomass yields, and so on; however, not all microalgae can be heterotrophically cultivated. Significant progress in the heterotrophic cultivation of Chlorella has been made in terms of the cultivation modes and yield, and furthermore, commercial successes have been achieved [2]. It was discovered that Chlorella pyrenoidosa not only accumulates up to 150 g/L of biomass under heterotrophic conditions [3], but can also synthesize lutein and chlorophyll [4,5]. Lutein is a member of carotenoids, which represent the most common group of pigments in marine environments. Lutein can preferentially cross the blood–brain barrier and accumulate in brain tissue, thus playing positive roles in neurocognitive functioning [6]. Besides, lutein is also well known to ameliorate cataract, age-related macular degeneration and other optical diseases [7,8,9]. As there is no photosynthesis that occurs during the heterotrophic cultivation, the synthesis of photosynthetic pigments is supposed to be hampered accordingly. Therefore, if the nuclear genes that encode the enzymes involved in photosynthetic pigment biosynthesis and chloroplast formation are not activated by other factors or organelles, the amounts of synthesized chloroplasts and pigments (lutein and chlorophyll) will gradually decrease and disappear as cell division progresses. In recent years, studies have shown that the mitochondria not only act as an energy provider, but also have retrograde regulation of the development of other organelles (such as chloroplasts) in green algae and plants [10,11,12]. The mitochondrial respiratory electron transport chain (mRET) is a key regulator in this process. Several studies have shown that mRET plays a crucial role in the retrograde regulation of the expression of photosynthetic genes, in some microorganisms, under dark conditions. Matsuo and Obokata [11] reported that under heterotrophic conditions, the photosynthetic electron transport (PET) signals and RET signals in Chlamydomonas reinhardtii induced the expression of nuclear photosynthetic genes. Li et al. [12] also reported that the mRET of Chlorella zofingiensis was able to initiate signal transduction and ultimately induced the expression of photosynthesis-related genes, such as those associated with chloroplast formation and pigment biosynthesis. Based on the above information, we hypothesized that the accumulation of photosynthetic pigments in C. pyrenoidosa under heterotrophic conditions may be related to the regulation of mRET. To verify this hypothesis, heterotrophic algal cells were treated with different mRET inhibitors, namely salicylhydroxamic acid (SHAM), antimycin A, and sodium azide (NaN3), and proteomics analysis was conducted. A method coupling two-dimensional electrophoresis (2-DE) with matrix assisted laser desorption-time-of-flight/time-of-flight tandem mass spectrometry (MALDI-TOF/TOF MS/MS) was used in this study. The findings may contribute to the knowledge of proteomics of marine natural products.
2. Results
2.1. Variation in Lutein and Chlorophyll Biosynthesis
In this study, we investigated the role of mRET in the retrograde regulation of lutein and chlorophyll biosynthesis in C. pyrenoidosa under heterotrophic conditions via mitochondrial dysfunction induced by specific inhibitors. The reported action sites of those inhibitors are shown in Figure 1. SHAM inhibited the alternative pathway by inactivating alternative oxidase (AOX) in mRET, while antimycin A blocked the cytochrome oxidase pathway by interrupting the electron transport from cytochrome b to c [13]. NaN3 effectively inactivated the cytochrome oxidase of mRET [14]. Rotenone inhibited the respiratory complex I, and carbonyl cyanide m-chlorophenylhydrazone (CCCP), an oxidative phosphorylation uncoupler, suppressed the ATP synthesis [15]. For each inhibitor, various concentrations were tested at first (rotenone: 0.01–0.1 mM, SHAM: 0.2–2.0 mM, CCCP: 0.01–0.1 mM, antimycin A: 0.05–0.5 mM, and NaN3: 0.01–0.1 mM). After evaluation, the optimal concentrations were determined for each inhibitor (data not shown), and were used for subsequent experiments.
As shown in Table 1, the biomass contents of C. pyrenoidosa significantly decreased after treatment with all inhibitors. With respect to pigments, treatment with antimycin A (0.1 mM) and NaN3 (0.05 mM) induced a sharp decrease in lutein and chlorophyll contents. On the other hand, the accumulation of lutein and chlorophyll was enhanced by the treatment with SHAM (0.5 mM). The effects of CCCP (0.032 mM) and rotenone (0.032 mM) were not so significant compared with those three inhibitors, suggesting that complexes І and V were less involved in the photosynthetic pigment biosynthesis.
Table 1.
Inhibitors | Biomass (%) | Lutein (%) | Chl. a (%) | Chl. b (%) |
---|---|---|---|---|
Antimycin A (0.1 mM) | 59.5 ± 3.2 | 87.7 ± 3.5 | 73.2 ± 2.3 | 73.4 ± 2.5 |
NaN3 (0.05 mM) | 68.9 ± 9.6 | 49.1 ± 1.4 | 38.9 ± 0.9 | 45.2 ± 1.7 |
SHAM (0.5 mM) | 46.1 ± 8.6 | 156.9 ± 7.2 | 121.6 ± 3.6 | 136.1 ± 5.4 |
CCCP (0.032 mM) | 42.7 ± 2.6 | 106.4 ± 3.2 | 104.5 ± 1.8 | 128.6 ± 2.8 |
Rotenone (0.032 mM) | 41.4 ± 3.1 | 107.1 ± 1.6 | 103.1 ± 1.0 | 104.9 ± 0.4 |
The biomass and pigment contents are described as the percentage of the control. Data are expressed as averages ± S.D. of three independent measurements.
2.2. Analysis of Redox and Energy States
Cellular energy and redox states analysis showed that mitochondrial dysfunction caused a decrease in the ATP/ADP ratio (Figure 2A). The ratio of GSH/GSSG (Figure 2B) and NAD+/NADH (Figure 2C) became significantly higher after treating the cells with SHAM (0.5 mM), NaN3 (0.05 mM), and antimycin A (0.1 mM). For CCCP (0.032 mM) and rotenone (0.032 mM), their effects were much less prominent. Taken together, only cells treated with SHAM, NaN3, and antimycin A were further examined in the following proteomic studies.
2.3. SDS-PAGE of Total Proteins
Total soluble proteins from algal cells, that were treated with antimycin A, SHAM and NaN3, were extracted and compared. Figure 3 shows that the protein constitutions between mRET inhibitor-treated and untreated algal cells changed significantly, particularly the bands indicated by the arrows. It can thus be concluded that numerous physiological reactions occurred following mitochondrial dysfunction in dark-grown C. pyrenoidosa.
2.4. 2-DE Analysis and Identification of Differentially Expressed Proteins
Comparative proteomics was employed to examine the variation of protein expression after mitochondrial dysfunction. The extracted proteins were analyzed using 2-DE and the protein expression patterns from the three independent experiments showed high reproducibility. The successfully identified proteins were marked in the gel images, shown in Figure 4A–D. Further, detailed information is provided in Table 2 and Table 3. Compared to the control group, a total of 38 proteins (24 up-regulated and 14 down-regulated) were successfully identified (1.5-fold, P ˂ 0.05) in the SHAM-treated algal cells (Table 2 and Table 3). A total of 36 proteins (16 up-regulated and 20 down-regulated) and 31 proteins (10 up-regulated and 21 down-regulated) were differentially expressed (1.5-fold, P ˂ 0.05) in algal cells treated with antimycin A and NaN3 (Table 2 and Table 3), respectively.
Table 2.
Spot a | Protein Name b | Protein Function and Categorization c | Protein ID d | Species e | MW/pI | Peptides f | Score g |
---|---|---|---|---|---|---|---|
Down-regulated proteins | |||||||
D2 | Autophagy-related protein 3 | Protein transport, Protein fate (folding, modification, destination) | gi|307105862 | Chlorella vulgaris | 35,252.9/4.42 | 1 | 35 |
D3 | Adenylosuccinate synthetase | Purine nucleotide synthesis, Metabolism | gi|307108106 | Chlorella vulgaris | 53,409.7/6.62 | 3 | 64 |
D4 | Hypothetical protein CHLNCDRAFT_144859 | GMP synthase, Metabolism | gi|307108123 | Chlorella vulgaris | 58,172.5/5.6 | 8 | 96 |
D5 | Hypothetical protein CHLNCDRAFT_56182 | Adenylosuccinate synthetase, Metabolism | gi|307106668 | Chlorella vulgaris | 64,272.6/5.81 | 4 | 59 |
D6 | Phosphoserine aminotransferase | L-glutamate synthesis, Metabolism | gi|307109471 | Chlorella vulgaris | 44,960.5/5.60 | 1 | 37 |
D9 | Hypothetical protein CHLNCDRAFT_139931 | Alternative splicing factor SRp20/9G8, Transcription | gi|307103428 | Chlorella vulgaris | 19,849.2/11.52 | 6 | 53 |
D10 | Hypothetical protein CHLNCDRAFT_134964 | SWI-SNF chromatin remodeling complex, Snf 5 subunit, Transcription | gi|307106629 | Chlorella vulgaris | 22,841.5/5.85 | 1 | 27 |
D12 | Nitrite reductase | NO biosynthesis, Cell rescue, defense and virulence | gi|116265919 | Chlorella vulgaris | 22,954.7/9.11 | 1 | 60 |
D14 | Coproporphyrinogen III oxidase | Key enzyme in heme synthesis, Metabolism | gi|71082810 | Candidatus Pelagibacter ubique | 32,383/9.83 | 1 | 68 |
D15 | Hypothetical protein CHLNCDRAFT_30336 | ABC transporter superfamily, lipid transport, Protein with binding function or cofactor requirement | gi|307109169 | Chlorella vulgaris | 65,272.95/8.50 | 1 | 26 |
D17 | Hypothetical protein CHLNCDRAFT_56437 | d-3-phosphoglycerate dehydrogenase, Metabolism | gi|307111670 | Chlorella vulgaris | 63,615.5/6.45 | 1 | 41 |
D19 | Nitrite reductase | NO biosynthesis, Cell rescue, defense and virulence | gi|116265919 | Chlorella vulgaris | 22,954.7/9.11 | 1 | 69 |
D21 | Malate dehydrogenase | Synthesis of oxaloacetate, Energy | gi|307103202 | Chlorella vulgaris | 35,063.6/8.2 | 6 | 104 |
D22 | Hypothetical protein CHLNCDRAFT_57327 | Galactokinase activity, Protein with binding function or cofactor requirement | gi|307109337 | Chlorella vulgaris | 55,429.4/5.97 | 10 | 66 |
D25 | Phytochrome A | G-protein coupled photoreceptor activity, Transcription | P42500 | Glycine max | 125,653.3/6.16 | 14 | 54 |
D30 | Hypothetical protein CHLNCDRAFT_58635 | Chaperonin complex component, TCP-1 eta subunit (CCT7), Protein fate (folding, modification, destination) | gi|307105118 | Chlorella variabilis | 61,530.4/6.25 | 1 | 28 |
D36 | Hypothetical protein CHLNCDRAFT_56384 | UDP-glucose 4-epimerase/UDP-sulfoquinovose synthase, Protein with binding function or cofactor requirement | gi|307103315 | Chlorella variabilis | 39,120.5/6.53 | 1 | 77 |
D37 | Hypothetical protein CHLNCDRAFT_49080 | Phosphoenolpyruvate carboxykinase activity | gi|307104333 | Chlorella variabilis | 49,051.4/5.69 | 6 | 70 |
D39 | Hypothetical protein CHLNCDRAFT_31785 | 14-3-3 family, multifunctional chaperone, Protein with binding function or cofactor requirement | gi|307106152 | Chlorella variabilis | 29,385.8/4.96 | 2 | 77 |
D40 | Hypothetical protein CHLNCDRAFT_34933 | Prolyl-tRNA aminoacylation, Protein with binding function or cofactor requirement | gi|307109063 | Chlorella variabilis | 33,163.8/6.56 | 2 | 83 |
D45 | Hypothetical protein CHLNCDRAFT_14282 | Aconitase/homoaconitase | gi|307110485 | Chlorella variabilis | 11,454.9/5.88 | 3 | 53 |
D46 | Expressed protein | Unknown, Unknown | gi|307104059 | Chlorella variabilis | 19,035.7/7.02 | 1 | 28 |
D50 | Aspartate carbamoyltransferase | Enzyme of the first committed step in pyrimidine synthesis, Protein activity regulation | P49077 | Arabidopsis thaliana | 43,139.3/6.21 | 8 | 55 |
D51 | Hypothetical protein CHLNCDRAFT_35404 | Protein serine/threonine kinase, Protein fate (folding, modification, destination) | gi|307107220 | Chlorella variabilis | 40,979.4/9.01 | 6 | 56 |
D53 | Hypothetical protein CHLNCDRAFT_52952 | Calcium ion binding, Protein with binding function or cofactor requirement | gi|307106250 | Chlorella variabilis | 245,122.6/7.28 | 1 | 27 |
D54 | 14-3-3-like protein | Multifunctional chaperone, posttranslational modification, Protein with binding function or cofactor requirement | P52908 | Chlamydomonas reinhardtii | 29,495.8/4.9 | 1 | 32 |
D60 | Elongation factor 2 (EF-2) | Catalyze GTP dependent ribosomal translocation step during translation elongation, Protein with binding function or cofactor requirement | gi|119167 | Parachlorella kessleri | 94,054.8/5.84 | 17 | 308 |
D65 | Expressed protein | Splicing coactivator, RNA processing, Transcription | gi|307109910 | Chlorella variabilis | 84,395.1/10.28 | 1 | 28 |
D69 | Citrate synthase | Citrate synthesis, located in mitochondria, Energy | gi|307105555 | Chlorella variabilis | 53,533.7/7.24 | 5 | 98 |
D72 | Hypothetical protein CHLNCDRAFT_56456 | Dystonin, growth -arrest-specific protein, cytoskeletone, Subcellular localization | gi|307111694 | Chlorella variabilis | 311,562.1/4.77 | 8 | 66 |
D73 | Ribosomal protein | Large ribosomal subunit, Protein synthesis | gi|307103203 | Chlorella variabilis | 25,401/8.65 | 10 | 138 |
D80 | Hypothetical protein CHLNCDRAFT_138729 | Electron transport, Protein with binding function or cofactor requirement | gi|307104457 | Chlorella variabilis | 62,588.1/9.52 | 11 | 53 |
D82 | OSJNBb0032E06.9 | Ribonuclease H activity, Cell cycle and DNA processing | gi|38344375 | Oryza stiva | 138,142.2/8.96 | 15 | 83 |
D83 | Protein W01F3.3a (mlt-11) | Serine-type endopeptidase inhibitor activity, Development | gi|115534910 | Caenorhabditis elegans | 236,516.9/5.07 | 10 | 84 |
D86 | Fumarate hydratase | Catalyze S-malate synthesis, mitochondria | gi|17549498 | Ralstonia solanacearum GMI1000 | 49,372.3/6.07 | 4 | 127 |
D89 | Ribulose bisphosphate carboxylase small chain 1 | Carbon dioxide fixation, Energy | P00873 | Chlamydomonas reinhardtii | 20,606.4/9.36 | 2 | 66 |
Up-regulated proteins | |||||||
U1 | Chloroplast thioredoxin peroxidase | Peroxidase activity, Cell rescue, defense and virulence | gi|294845922 | Volvox carteri f. nagariensis | 17,421/5.15 | 2 | 193 |
U2 | SMC domain protein | Chromosome structure maintenance, Unknown | gi|296427824 | Heliothis subflexa | 65,238/5.63 | 87 | |
U3 | Peroxiredoxin TSA1 | Oxidoreductase, cell redox homeostasis, Cell rescue, defense and virulence | gi|126132194 | Scheffersomyces stipitis CBS 6054 | 21,761/4.92 | 2 | 82 |
U4 | Magnesium chelatase subunit of protochlorophyllide reductase | Chlorophyll biosynthesis, Protein with binding function or cofactor requirement | gi|254798626 | Parachlorella kessleri | 39,567/5.08 | 6 | 310 |
U5 | 2-Cys peroxiredoxin | Oxidoreductase, cell redox homeostasis, Cell rescue, defense and virulence | gi|327506370 | Dunaliella viridis | 22,235/5.74 | 1 | 51 |
U6 | Hypothetical protein CHLNCDRAFT_48133 | Ornithine carbamoyltransferase, Protein with binding function or cofactor requirement | gi|307109894 | Chlorella variabilis | 38,764.5/6.68 | 9 | 51 |
U7 | Hypothetical protein CHLNCDRAFT_53139 | Antioxidant activity, Cell rescue, defense and virulence | gi|307106076 | Chlorella variabilis | 21,778.9/8.35 | 1 | 40 |
U8 | Hypothetical protein BAL199_15803 | Unknown, Unknown | gi|163792326 | alpha proteobacterium | 42,102.3/5.49 | 12 | 88 |
U9 | Hypothetical protein CHLNCDRAFT_48477 | Membrane transport, Cellular transport, transport facilitation and transport routes | gi|307110872 | Chlorella vulgaris | 31,637.3/9.49 | 1 | 29 |
U10 | tRNA(Ile)-lysidine synthase, chloroplastic | Ligase activity, translation, Transcription | Q32RX0 | Staurastrum punctulatum | 58,797/10.16 | 1 | 29 |
U11 | Penecillin-binding protein 2 | Penicillin binding, Protein with binding function or cofactor requirement | gi|163752395 | Shewanella benthica | 68,820.33/9.54 | 67 | |
U12 | Aldehyde dehydrogenase | Oxidation of aldehyde, Metabolism | gi|285018869 | Xanthomonas albilineans | 54,004.7/6.05 | 64 | |
U13 | Hypothetical protein CHLNCDRAFT_30965 | Structural constitute of ribosome, Protein synthesis | gi|307107744 | Chlorella vulgaris | 21,281.2/10.33 | 8 | 51 |
U14 | Hypothetical protein CHLNCDRAFT_143237 | Dystonin, growth arrest specific protein, Subcelluar location | gi|307109339 | Chlorella vulgaris | 56,981.7/5.56 | 13 | 53 |
U15 | FG-GAP repeat protein | Ligand binding, Unknown | gi|40062562 | Uncultureed marine bacterium 159 | 136,477.9/4.18 | 66 | |
U16 | Expressed protein | Unknown, Unknown | gi|307111048 | Chlorella variabilis | 20,888.8/10.28 | 6 | 57 |
U17 | Hypothetical protein CHLNCDRAFT_59525 | nuclear receptor binding factor-1, Cell rescue, defense and virulence | gi|307111650 | Chlorella variabilis | 34,897.1/5.06 | 68 | |
U18 | Hypothetical protein PEPMIC_01485 | Unknown, Unknown | gi|160947550 | Peptostreptococcus micros | 18,170.3/4.67 | 7 | 83 |
U19 | Hypothetical protein CHLNCDRAFT_58231 | Ribosomal protein L22, Protein synthesis | gi|307105888 | Chlorella vulgaris | 67,650.2/10.05 | 1 | 29 |
U20 | C protein alpha-antigen | Receptor, Protein with binding function or cofactor requirement | gi|307708369 | Streptococcus mitis NCTC 1226 | 34,6246.9/4.98 | 65 | |
U21 | 4-hydroxy-3-methylbut-2-en-1-yl diphosphate synthase | Oxidoreductase, terpenoids biosynthesis, Protein with binding function or cofactor requirement | Q5QYA9 | Idiomarina loihiensis | 40,462/5.68 | 1 | 58 |
U22 | N-(5’-phosphoribosyl)anthranilate isomerase | Tryptophan biosynthesis, Metabolism | gi|307107003 | Chlorella vulgaris | 20,906.8/5.55 | 1 | 31 |
U23 | Hypothetical protein CHLNCDRAFT_37743 | Aldehyde dehydrogenase, Metabolism | gi|307102335 | Chlorella variabilis | 45,285.3/6.11 | 3 | 111 |
U24 | Hypothetical protein OsI_036678 | Calcium ion binding, Protein with binding function or cofactor requirement | gi|125536231 | Oryza sativa | 31,743.5/9.98 | 10 | 93 |
U25 | Chloroplast 30S ribosomal protein S4 | Structural constituent of ribosome, Protein synthesis | P59137 | Catharomnion ciliatum | 23,589.9/10.3 | 1 | 30 |
U26 | Hypothetical protein CHLNCDRAFT_140182 | Transcription initiation factor, Transcription | gi|307103188 | Chlorella variabilis | 63,894.8/5.19 | 13 | 54 |
U27 | Nitrate reductase [NADH] 1 | Catalyze nitrite synthesis, Metabolism | P16081 | Oryza sativa | 101,447.9/6.19 | 1 | 29 |
U28 | Ribulose-1,5-bisphosphate carboxylase/oxygenase large subunit | Carbon fixation, Energy | gi|164455027 | Chlorella variabilis | 52,496.3/5.99 | 1 | 32 |
U29 | Hypothetical protein MGG_08723 | Unknown, Unknown | gi|145601241 | Magnaporthe grisea | 36,967.8/5.69 | 8 | 83 |
U30 | Expressed protein | Large subunit of ribosome, Protein synthesis | gi|307108236 | Chlorella variabilis | 9805.4/11.71 | 4 | 69 |
U31 | Hypothetical protein CHLNCDRAFT_59740 | 3-oxoacyl-(acyl-carrier-protein) synthase, lipid transport, Cellular transport, transport facilitation and transport routes | gi|307104988 | Chlorella variabilis | 32,230.3/6.19 | 1 | 28 |
U32 | Hypothetical protein CHLNCDRAFT_18194 | Unknown, Unknown | gi|307111928 | Chlorella variabilis | 9084.4/4.37 | 1 | 28 |
U33 | Ribulose-1,5-bisphosphate carboxylase/oxygenase large subunit | Carbon fixation, Energy | gi|164455037 | Chlorella variabilis | 52,496.3/6.0 | 18 | 193 |
U34 | Glucose-6-phosphate isomerase | Isomerase, involved in glycolysis, Energy | gi|284434863 | Parachlorella kessleri | 27,035/5.35 | 1 | 48 |
U35 | Hypothetical protein CHLNCDRAFT_143799 | Unknown, Unknown | gi|307108818 | Chlorella variabilis | 43,154.4/9.57 | 1 | 27 |
U36 | Superoxide dismutase | Antioxidant enzyme, Cellular communication/signal transduction mechanism | gi|34558145 | Wolinella succinogenes DSM 1740 | 25,795.1/8.89 | 78 | |
U37 | Hypothetical protein CHLNCDRAFT_138879 | FAP-dependent helicase activity, Transcription | gi|307104244 | Chlorella variabilis | 59,382.6/9.77 | 1 | 27 |
U38 | Glucose -6-phosphate isomerase | Glycolysis enzyme, Energy | gi|307105594 | Chlorella variabilis | 72,048.5/6.41 | 7 | 53 |
U39 | GTP-binding protein | Intracellular protein transport, Cellular communication/signal transduction mechanism | gi|307106020 | Chlorella variabilis | 25,468.9/6.66 | 2 | 66 |
All the down-regulated protein spots were labeled as Dn. The up-regulated protein spots were labeled as Un. Down-regulation means a decreased protein expression when the test group (after inhibitor treatment) was compared to the control group. Up-regulation means an increased protein expression when the test group was compared to the control group. a refers to the number in Figure 4. b protein name from NCBI Nr and Swiss-prot database. c function of hypothetical proteins is described according to the GO (gene ontology) information. d accession number from NCBI Nr database or Swiss-prot database. e species name from NCBI Nr and Swiss-prot database. f number of peptides used for the protein identification, those proteins with no peptides number listed were identified through de novo sequencing and MS-BLAST search against nrdb95 database. g score is defined as −10 × Log (P), where P is the absolute possibility and is closely related the size of database used for searching and automatically calculated by the MASCOT search engine. The minimal threshold value was 25. For the MS-Blast identification, the score meant the HSPs. MW, molecular weight.
Table 3.
Spot a | F.D. h | ||
---|---|---|---|
SHAM | Antimycin A | NaN3 | |
Down-regulated proteins | |||
D2 | −4.95 ± 0.58 | −5.27 ± 2.16 | |
D3 | −6.57 ± 0.59 | ||
D4 | −3.01 ± 0.11 | −2.37 ± 0.22 | −2.29 ± 0.86 |
D5 | −2.22 ± 0.30 | −1.93 ± 0.20 | |
D6 | −2.18 ± 0.11 | ||
D9 | −1.81 ± 0.35 | ||
D10 | −1.77 ± 0.35 | ||
D12 | −2.37 ± 0.74 | −3.12 ± 0.05 | |
D14 | −1.95 ± 0.20 | −1.98 ± 0.43 | −2.29 ± 0.59 |
D15 | −2.27 ± 0.66 | −6.95 ± 2.48 | |
D17 | −2.45 ± 0.98 | −4.46 ± 1.59 | −3.87 ± 0.79 |
D19 | −2.42 ± 0.98 | −2.08 ± 0.25 | |
D21 | −2.26 ± 0.82 | ||
D22 | −1.87 ± 0.26 | −6.32 ± 1.36 | −1.87 ± 0.26 |
D25 | >−100 | >−100 | |
D30 | >−100 | >−100 | |
D36 | −3.03 ± 1.22 | −3.08 ± 0.91 | |
D37 | −3.32 ± 0.65 | −5.66 ± 0.04 | |
D39 | −2.27 ± 0.57 | ||
D40 | >−100 | >−100 | |
D45 | −2.03 ± 0.02 | ||
D46 | −1.77 ± 0.37 | ||
D50 | −1.98 ± 0.14 | ||
D51 | −1.65 ± 0.24 | ||
D53 | −1.89 ± 0.46 | −1.89 ± 0.46 | |
D54 | −1.85 ± 0.33 | ||
D60 | >−100 | ||
D65 | >−100 | ||
D69 | −3.55 ± 0.81 | ||
D72 | −2.54 ± 0.97 | ||
D73 | −4.20 ± 1.37 | ||
D80 | −2.24 ± 0.52 | ||
D82 | −1.89 ± 0.25 | ||
D83 | −1.89 ± 0.30 | ||
D86 | −1.59 ± 0.20 | ||
D89 | −1.76 ± 0.38 | ||
Up-regulated proteins | |||
U1 | 1.65 ± 0.57 | ||
U2 | 1.72 ± 0.48 | ||
U3 | 1.53 ± 0.16 | 1.62 ± 0.08 | |
U4 | 1.60 ± 0.09 | ||
U5 | 1.84 ± 0.37 | ||
U6 | 1.92 ± 0.46 | ||
U7 | 1.85 ± 0.33 | ||
U8 | 1.65 ± 0.57 | 1.59 ± 0.28 | 1.94 ± 0.68 |
U9 | 1.54 ± 0.18 | ||
U10 | 2.13 ± 0.37 | 2.75 ± 0.02 | |
U11 | 1.68 ± 0.30 | ||
U12 | 2.53 ± 0.78 | ||
U13 | 2.56 ± 0.73 | 3.96 ± 2.05 | |
U14 | 2.18 ± 0.10 | ||
U15 | 3.08 ± 1.38 | ||
U16 | 2.66 ± 0.45 | ||
U17 | 2.21 ± 0.25 | ||
U18 | 3.46 ± 0.93 | ||
U19 | 4.38 ± 1.02 | ||
U20 | 4.05 ± 0.09 | ||
U21 | 5.36 ± 0.05 | 3.75 ± 0.01 | 1.53 ± 0.21 |
U22 | 6.89 ± 1.10 | 3.61 ± 0.86 | |
U23 | >100.00 | 5.39 ± 0.69 | |
U24 | >100.00 | ||
U25 | 1.79 ± 0.53 | 1.89 ± 0.39 | |
U26 | 1.77 ± 0.39 | ||
U27 | 1.60 ± 0.05 | ||
U28 | 1.92 ± 0.48 | ||
U29 | 1.92 ± 0.44 | ||
U30 | 2.36 ± 0.71 | ||
U31 | 2.56 ± 0.75 | ||
U32 | 2.16 ± 1.08 | ||
U33 | 3.02 ± 0.08 | ||
U34 | >100 | ||
U35 | 1.75 ± 0.21 | ||
U36 | 1.60 ± 0.03 | ||
U37 | 2.33 ± 0.20 | ||
U38 | >100 | ||
U39 | 3.75 ± 0.01 |
All the down-regulated protein spots were labeled ash Dn. The up-regulated protein spots were labeled as Un. a refers to the number in Figure 4. h fold difference (F.D.) is used to describe the protein expression level variation following inhibitors treatment compared with the control and expressed as mean ± S.D. from three independent experiments. Positive values mean up-regulation and negative values mean down-regulation.
2.5. Functional Categorization
The differentially expressed proteins were then categorized. As no functional classification is available for C. pyrenoidosa, the categorization performed in this study was based on the genome of another member of the same genus, namely C. variabilis. The top candidate with a score higher than the threshold value (P < 0.05) was considered positive. If negative, searching against the NCBI Nr or Swiss-Prot database was also performed. Additionally, de novo sequencing and MS-BLAST searches were also employed as an identification strategy in this study. Those identities together with the pI, molecular weight, reported functions, and fold-change in comparison to the control are listed in Table 2 and Table 3. Among all the identities listed in Table 2 and Table 3, most of the protein orthologues belonged to C. variabilis, while some proteins also belonged to other algae, such as C. vulgaris, Parachlorella kessleri, Chlamydomonas reinhardtii, or plants, such as Arabidopsis thaliana.
According to the identification results, it was found that the protein names of C. variabilis were almost all “hypothetical”. This is because most of the genome annotation of C. variabilis is still in progress. Fortunately, the Gene Ontology (GO) or EuKaryotic Orthologous Groups (KOG) annotations on the majority of the proteins in C. variabilis have been completed and are available online. Therefore, in this study, these GO annotations were used to interpret the function of the identified hypothetical proteins. The functional categorization of abundantly expressed proteins after treatment with three mRET inhibitors was shown in Figure S1.
3. Discussion
The green algae Chlorella can be grown both autotrophically and heterotrophically. Keeping a portion of pigments under the dark condition is a self-adaptive strategy, which may help the algae quickly adapt to the light when the culture is shifted to the phototrophic condition. From the perspective of evolution, this may be regarded as a transition state between eukaryotic microorganisms (100% heterotrophy) and green plants (100% phototrophy). In this study, the dysfunction of mRET led to changes in the contents of lutein and chlorophyll in C. pyrenoidosa under heterotrophic conditions. Lutein and chlorophyll biosynthesis were dramatically stimulated after treatment with SHAM, while their contents considerably decreased after treatment with antimycin A and NaN3. This suggests that mRET participates in the synthesis of photosynthetic pigments, which is consistent with previous reports [11]. Proteomic analysis revealed a large number of differentially expressed proteins after the dysfunction of mRET (Table 2 and Table 3). Among them, some representative proteins were discussed in below to interpret the mechanism. These proteins were divided into four groups based on the functional classification, namely antioxidant proteins, chloroplast proteins, transcription and protein fate-related proteins, and metabolism and energy-related proteins. In each group, the proteins have direct or indirect relation to pigment synthesis.
3.1. Up-Regulation of Antioxidant Proteins
As a result of the excess energy present in the mitochondria, which easily reduces oxygen, mitochondrial reactive oxygen species (mtROS) are often unavoidably produced during the aerobic respiration process, even under normal conditions [16]. Thus, mtROS are even more likely to be produced under abiotic or biotic stress conditions. The study of Tang et al. [17] indicated that mtROS could directly affect the functionality of mRET complexes by oxidizing their iron–sulfur centers, thus aggravating ROS production. Previous studies have confirmed that mRET dysfunction induced by specific inhibitors, such as SHAM and antimycin A, can greatly enhance mtROS production. In response, cells activate multiple defense systems to detoxify these excessive harmful mtROS and protect the cellular organelles [18,19,20]. Our findings corroborated our expectations, particularly in the SHAM treatment. Several antioxidant enzymes, including peroxiredoxin TSA1 (spot U3), 2-Cys peroxiredoxin (spot U5) and hypothetical protein (spot U7), exhibited antioxidant features according to the GO analysis and were all up-regulated. Peroxiredoxin TSA1 (spot U3) and superoxide dismutase (SOD) (spot U36) were also up-regulated in antimycin A- and NaN3-treated cells (Table 3). Peroxiredoxin is an antioxidant protein with an activity site of cysteine that is oxidized by a peroxide substrate. The oxidized peroxiredoxin can be reduced by GSH [21]. Therefore, the proteomic results in this study could explain the changes in redox state following these treatments (NaN3, antimycin A, and SHAM). In addition, the hydroxyl radicals in ROS react directly with DNA components, destroying bases and DNA backbones. Additionally, mtROS, such as H2O2, can also penetrate the mitochondrial membrane and enter into the cytoplasm [22,23]. This results in the further recruitment of GSH molecules to reduce the oxidized antioxidants, such as peroxiredoxin and ascorbate. It is thus reasonable to expect that the ratio of GSH/GSSG would increase. The study of Foyer and Noctor [24] also suggested that GSH is a key arbiter of intracellular redox potential, and ascorbate plays an important role in setting thresholds for cytoplasmic signaling. In addition to being a harmful oxidant, mtROS is also widely believed to participate in mitochondria to nucleus signaling—that is, mitochondrial retrograde regulation [16,18,25,26]. Ho et al. [27] showed that redox homeostasis was disturbed in nicotinamide nucleotide transhydrogenase-deficient cells, resulting in increased mtROS generation and the eventual regulation of the mitochondrial retrograde signaling response. Some researchers have indicated that mtROS, as secondary signaling messengers, lead to the expression of nuclear genes after leaving the mitochondria [18,28]. However, Matsuo and Obokata [11] suggested that mtROS were not responsible for nuclear-located photosynthetic gene expression as a result of increased ROS production following treatment with three inhibiters in Chlamydomonas reinhardtii, although antimycin A and potassium cyanide decreased gene expression, and SHAM increased gene expression. This implies that mtROS might not be the only explanation for the variation in redox state. In addition, chloroplast thioredoxin peroxidase (spot U1) was up-regulated after treatment with SHAM (Table 3). This indicated that messengers from the mitochondria, such as mtROS, interacted with the chloroplast in C. pyrenoidosa and caused a change in the redox state in the chloroplast after the induction of mitochondrial dysfunction by SHAM.
3.2. Variation in Chloroplast Protein Expression Following Mitochondrial Dysfunction
In general, cellular components and organelles are thought not to be isolated and independent, but rather interact and communicate with each other frequently and in a complex manner. Very few studies have focused on cellular organelle communication in green algae, especially in non-model algae. In this study, several chloroplast proteins were found to be up- or down-regulated after inhibitor treatment (Table 2 and Table 3). For example, chloroplast ribosome protein L22 (spot U19) was up-regulated after treatment with SHAM, while chloroplast 30 S ribosome protein S4 (spot U25) was up-regulated in both antimycin A- and NaN3-treated cells.
Ribosome protein L22 was found to be the main component of chloroplast 50S ribosome and is nuclear-encoded in the green alga C. reinhardtii [29]. It could thus be assumed that the retrograde signal from the mitochondria directly or indirectly activated chloroplastic gene expression and protein translation in the chloroplast to adapt to the new cellular environment. This perspective is supported by the observation that chloroplastic tRNA (Ile)-lysidine synthase, which changes amino acids specificity from methionine to isoleucine, was also up-regulated after SHAM treatment. The expression level of other proteins involved in the chlorophyll and lutein biosynthetic pathways in the chloroplast was also altered. Coproporphyrinogen III oxidase catalyzes the biosynthesis of protoporphyrinogen IX, which is converted into protoporphyrin IX; a precursor for chlorophyll and heme biosynthesis in two branch pathways [30,31]. In this study, coproporphyrinogen III oxidase (spot D14, Table 3) in both antimycin A- and NaN3-treated algal cells was down-regulated. This could possibly account for the decrease in chlorophyll content following these two treatments. However, the coproporphyrinogen III oxidase level also significantly decreased after SHAM treatment, which enhanced chlorophyll production markedly. This may be closely related to the up-regulated expression of another enzyme, the magnesium chelatase subunit of protochlorophyllide reductase (ChlI) (spot U4), which is a key enzyme involved in the chlorophyll biosynthesis branch pathway. In contrast, the expression level of ChlI was down-regulated in antimycin A- and NaN3-treated algal cells (Table 3). It is thus reasonable to assume that the up-regulated protochlorophyllide reductase captured more protoporphyrin IX for chlorophyll biosynthesis, even though the pool of protoporphyrinogen IX decreased, due to the down-regulation of coproporphyrinogen III oxidase. This might account for the observation that coproporphyrinogen III oxidase was down-regulated following SHAM treatment, while lutein and chlorophyll biosynthesis increased.
Previous studies have shown that the intermediate of chlorophyll biosynthesis participates in the chloroplast retrograde regulation signaling pathway. Currently, the most studied intermediate is Mg-protoporphyrin IX monomethyl ester, the accumulation of which greatly represses the expression of nuclear photosystem II (Lhcb) mRNA or other chloroplast genes in C. reinhardtii and other organisms [32,33,34,35]. In addition, Mg-chelatase, composed of subunits ChlD, ChlH, and ChlI, also participates in the plastid to nucleus signal transduction pathway in Arabidopsis, with the exception of the function of inserting Mg2+ into the porphyrin ring of Proto IX [36,37]. Mochizuki et al. [36] proposed that ChlH not only serves as chelatase in tetrapyrrole biosynthesis, but functions as a tetrapyrrole sensor in the chloroplast to nucleus signaling pathway. ChlH also possibly participates in the plastid to nucleus signaling pathway by forming ChlH-tetrapyrrole complexes with other cofactors [31,38,39,40].
All previous experiments have only interpreted the negative aspect of the chloroplast retrograde signal transduction pathway whereby it represses nuclear-encoded chloroplastic gene expression. However, the positive aspects of the signaling pathway have not been evaluated. If chlorophyll biosynthesis is improved, the synthesis of more chloroplast proteins (e.g., light-harvesting complex II) would be required to provide sufficient binding locations for these newly synthesized pigments. We thus proposed the hypothesis that the magnesium chelatase subunit also serves as a sensor, or directly participates in the plastid to nucleus signaling transduction pathway, which activates chloroplast genes expression when chlorophyll biosynthesis is enhanced. In fact, another enzyme, 4-hydroxy-3-methylbut-2-en-1yl diphosphate synthase (ispG) (spot U21), was greatly up-regulated after SHAM treatment (Table 3). Furthermore, it is the same group of enzyme as 1-hydroxy-2-methyl-2-(E)-butenyl 4-diphosphate (HMBPP) reductase, which plays rate-determining roles in controlling chloroplastic methylerythritol phosphate (MEP) pathway fluxes towards the biosynthesis of isoprenoids and carotenoids in plants [41,42]. Moreover, the expression level of ispG was also up-regulated to some extent after antimycin A and NaN3 treatment (Table 3).
3.3. Variation in Transcription and Protein Fate-Related Protein Expression
The results in Table 2 and Table 3 show that some transcription and protein fate-related proteins were successfully identified. Among the identified proteins, phytochrome A, 14-3-3-like protein, and TCP-1 eta subunit (CCT7) were the most striking, because of their special functions in plants. Phytochrome A (spot D25) and TCP-1 eta subunit (CCT7) (spot D30) were both down-regulated in NaN3- and antimycin A-treated C. pyrenoidosa, whereas the expression level of these two proteins did not change after treatment with SHAM (Table 3). A 14-3-3-like protein (spot D54) was down-regulated after treatment with antimycin A, while no changes were observed in NaN3- and SHAM-treated cells.
In plants and green algae, adjustments or adaptions to variations in the light irradiation environment are vitally important for growth and development, and this process is accomplished through a network of photoreceptors. Among these photoreceptors, phytochromes, which are able to absorb red and far-red light, are the most thoroughly studied to date [43]. Previous studies showed that phytochrome A was responsible for the regulation of light-inducible photosynthetic genes, such as genes encoding chlorophyll a/b binding proteins, small subunit of ribulose 1,5-bisphosphate carboxylase, pchlide oxidoreductase A, and phytoene synthase [44,45,46]. Chlorophyll a/b-binding proteins primarily associated with chlorophyll and lutein constitute the apoproteins of the light-harvesting complex of photosystem II [47]. In this study, it was observed that the expression level of phytochrome A increased when the algal cells were treated with SHAM. Simultaneously, the content of chlorophyll and lutein also increased. When treated with antimycin A and NaN3, the expression level of phytochrome A decreased, and the contents of chlorophyll and lutein also decreased. It could be concluded that the regulatory process might be related to the expression level of the chlorophyll a/b binding protein encoded by the photosynthetic gene. Phytochromes are typically synthesized under dark conditions, in a red light absorbing form, Pr—which transforms into the biologically active form Pfr after absorbing far-red light [48]. Afterwards, the active Pfr is translocated into the nucleus where it interacts with a series of signaling components and ultimately activates the expression of photomorphogenesis-related genes. Some of these signaling components were reported to be phytochrome-interacting factors (PIFs), which are responsible for the repression of photomorphogenesis in darkness in Arabidopsis [49]. Whereas in the light, phytochromes either promote the degradation of PIFs or inhibit their binding to their target promoters [50,51]. Toledo-Ortiz et al. [48] indicated that the degradation of a high level of cellular PIF following interaction with the bioactive form Pfr was mainly responsible for the rapid accumulation of carotenoids in coordination with increased chlorophyll biosynthesis and chloroplast protein formation. PIFs are a subfamily of basic-helix-loop-helix transcription factors, which have been found in most plants and some green algae, such as C. vulgaris [52]. It is thus reasonable to assume that PIFs are also present in C. pyrenoidosa, even though no related reports exist. Therefore, we speculated that small amounts of phytochrome A were activated through another way in C. pyrenoidosa under dark conditions, and the reaction of Pfr with PIFs allowed small amounts of chlorophyll and carotenoids to be synthesized in C. pyrenoidosa grown in the dark. It is thus sensible that when the level of phytochrome A decreased following treatment with NaN3 and antimycin A, that less chlorophyll and lutein would be synthesized in C. pyrenoidosa. Phytochromes have two major domains: One is an amino-terminal domain carrying a tetrapyrrole chromophore, which is used for absorbing red or far-red light, and the other is a carboxyl-terminal domain used for binding with other signaling components [43]. The currently accepted mechanism for the activation of the phytochrome system is that the conformation of the phytochrome system changes and becomes active for other protein-binding activities after absorbing light. Therefore, if other chaperonins bind with phytochrome and the protein conformation alters appropriately, then phytochrome can also be activated similarly. Mummert et al. [53] reported that chaperonin TCP-1 could be copurified with phytochrome and help refold the inactive phytochrome to the photoactive form. Su and Lagarias [54] also discovered the light-independent phytochrome signaling pathway in an Arabidopsis mutant. In this study, we also found that the expression level of chaperonin TCP-1 and phytochrome A simultaneously decreased after treatment with antimycin A and NaN3. We thus speculated that chaperonin TCP-1 might possibly also facilitate the refolding of phytochrome A in C. pyrenoidosa grown in the dark. However, this requires further verification in future studies. Another chaperonin 14-3-3 protein, which has multifunctional phosphoserine binding sites, participates in many important cellular processes. In higher plants, 14-3-3 proteins are phosphoserine-binding proteins that regulate the activities of a wide array of targets through protein-protein interactions [55]. Kinoshita et al. [56] reported that 14-3-3 interacted with phototropins, another photoreceptor, in a phosphorylation-dependent manner and could be important in phototropin-mediated responses. In our experiment, we also found that a 14-3-3 like protein (Spot D54) was down-regulated 1.8-fold (Table 3) after antimycin A treatment, but not in NaN3-treated cells. Many 14-3-3 protein species have been reported in plants, such as Arabidopsis [57], rice [58], and tomato [59] where they regulate numerous cellular processes via interaction with their target proteins in a phosphorylation-dependent manner. Hong et al. [57] suggested that AtSKIP31 regulates primary root growth under nitrogen deficiency by degrading Arabidopsis 14-3-3s, which are related to cell growth.
3.4. Variation in Metabolism and Energy-Related Protein Expression
The results in Table 2 and Table 3 show that the identified proteins related to metabolism and energy production accounted for a large proportion of the differentially expressed proteins. Among them, d-3-phosphoglycerate dehydrogenase (spot D17), a key enzyme involved in glycolysis, was simultaneously down-regulated after the three treatments (Table 3).
Once the induction of mitochondrial dysfunction by the inhibitors occurs, the TCA cycle and glycolysis process would definitely be influenced. The expression levels of other enzymes related to amino acid biosynthesis or nitrate metabolism also changed, such as phosphoserine aminotransferase, which is involved in serine biosynthesis and was down-regulated in SHAM-treated cells, while N-(5′-phosphoribosyl) anthranilate isomerase, which participates in tryptophan biosynthesis, was up-regulated in SHAM-treated cells. Among the identified proteins, the identification of phosphoenolpyruvate carboxykinase (PEPCK) (spot D37) was most significant in this study. This enzyme was found to be down-regulated in antimycin A- and NaN3-treated cells, but not in SHAM-treated cells (Table 3).
PEPCK, also referred to as ATP-oxaloacetate carboxylase, catalyzes the formation of phosphoenolpyruvate (PEP) [60]. PEP is usually synthesized in the mitochondria and transported into plastids as the precursor for the shikimate pathway, which provides aromatic compounds for plastid development in plants [61]. In plants, the translocation of PEP is vital for plastid development and the biosynthesis of carotenoids and chlorophylls. In addition, carotenoid biosynthesis is widely accepted to occur, via the MEP pathway, in the plastids of plants and green algae, by using pyruvate and glyceraldehyde-3-phosphate as precursors [62]. Huang et al. [63] also reported that the biosynthesis of isopentenyl diphosphate by the MEP pathway was found to be correlated with carotenoid biosynthesis in C. zofingiensis. Pyruvate is directly converted from PEP by pyruvate kinase. In gluconeogenesis, PEPCK catalyzes the reversible decarboxylation of oxaloacetate to PEP and carbon dioxide. The study of Wu et al. [64] showed that the abundance of PEPCK was increased as peach fruits reached the ripening stage, and then gradually declined at the senescence stage, indicating that PEPCK might play an important role in maintaining normal levels of glucose through gluconeogenesis, especially when a large amount of glucose is consumed to provide energy. Thus, if the supply of PEP is deficient, carotenoids and chlorophyll biosynthesis are definitely affected. This suggests that the down-regulation of PEPCK is possibly responsible for the decrease in both lutein and chlorophyll accumulation in antimycin A- and NaN3-treated C. pyrenoidosa. Further analysis is required to reveal the details of this mechanism. An overview of the metabolic pathways of C. pyrenoidosa and the interactions between the identified up- or down-regulated proteins is provided in Figure 5. Mitochondrial dysfunction leads to changes in the intracellular redox state and energy metabolism. Among these changes, up-regulated peroxiredoxin reduces GSSG to GSH, and in the glycolytic pathway, d-3-phosphoglycerate dehydrogenase, which oxidizes glyceraldehyde 3-phosphate to 1,3-diphosphoglyceric acid, is down-regulated. At this moment, the amount of NADH produced is correspondingly reduced, which can explain the increases in the ratios of NAD+/NADH and GSH/GSSG. In addition, in the gluconeogenesis pathway, PEPCK catalyzes the conversion of oxaloacetic acid to PEP. After entering the MEP pathway, ispG reduces 2-C-methyl-d-erythritol-2,4-cyclodiphosphate (ME-cPP) to HMBPP, which is closely related to the synthesis of lutein. And coproporphyrinogen III oxidase and ChlI play important roles in the chlorophyll biosynthetic pathway.
4. Materials and Methods
4.1. Microalga and Culture Conditions
The algal strain C. pyrenoidosa was purchased from Carolina Biological Supply Co., Burlington, NJ, USA. The basic medium was the same as that used in a previous report, and the potassium concentration was 1.25 g/L [4]. The algal cells were inoculated into 250-mL Erlenmeyer flasks containing 100 mL medium at an inoculation volume of 10% (v/v). Heterotrophic cultivation was achieved by culturing the algal cells in a basic medium supplemented with 40 g/L glucose and 8.25 g/L potassium nitrate at 28 °C with orbital shaking at 180 rpm under darkness. For biomass measurement, a 15 mL culture suspension was filtered through a pre-dried Whatman GF/C filter paper (1.6 μm pore size) and washed twice with distilled water. Cells on the filter paper were dried in an oven at 80 °C until constant weight was achieved and the samples were weighted when cooled to room temperature.
4.2. Mitochondrial Dysfunction
Specific inhibitors with different concentrations, including rotenone (0.01~0.1 mM, SHAM (0.2~2.0 mM), carbonyl cyanide m-chlorophenylhydrazone (CCCP) (0.01~0.1 mM), antimycin A (0.05~0.5 mM), and NaN3 (0.01~0.1 mM), were used to induce mitochondrial dysfunction. After 48 h of cultivation, these inhibitors were directly added into the culture. The algal cells were then harvested and used for the subsequent analyses after being continuously cultivated for 36 h.
4.3. Pigment Analysis
The lutein and chlorophyll contents were determined following the report by Baroli [65]. The wet algal cell pellets obtained after centrifugation (3000× g, 5 min) were frozen at −70 °C for at least 1 h. The frozen cell pellets were then lyophilized for 36 h in a freeze dryer. Following lyophilization, the dry cell pellets were ground into a powder in a mortar. The pigments were extracted with acetone until the cell debris became colorless. Then the supernatant containing extracted pigments was filtered through a 0.22 μm PTFE membrane (Millipore, Burlington, MA, USA). Each sample (20 μL) was separated on a Waters Spherisorb 5 μm ODS 4.6 mm × 250 mm analytical column (Waters Corp., Milford, MA, USA). Samples were eluted at a flow rate of 1.0 mL/min with a linear gradient from 100% solvent A [acetonitrile: methanol: 0.1 M Tris-buffer, pH 8.0 (84:2:14, by vol.)] to 100% solvent B [methanol: ethyl acetate (68:32, by vol.)] for 15 min, followed by 10 min of solvent B. Individual pigments were identified by comparing their absorption spectra to those of standards (Sigma-Aldrich, St. Louis, MO, USA). The concentration of each pigment was calculated based on the corresponding standard curve. The contents of lutein and chlorophyll were described as the amount of pigments per dry weight (mg/g dry cell weight).
4.4. Redox and Energy State Evaluation
The extraction and high-performance liquid chromatography (HPLC) analysis of oxidized nicotinamide adenine dinucleotide (NAD+) and reduced nicotinamide adenine dinucleotide (NADH) were conducted based on a previous report [66]. Briefly, the cell pellets were harvested by centrifugation in 20 mL of culture and rinsed with deionized water twice. The cell pellets were then cooled with liquid nitrogen and ground thoroughly in a mortar using a pestle, after which the algal powder was suspended in 10 mL extraction solution containing acetonitrile and 10 mM monopotassium phosphate (KH2PO4), pH 7.4 (3:1, by volume). The mixture was then homogenized at Ultra-Turrax (Janke & Kunkel, Breisgau, Germany) at 12,000 g for 2 min on an ice bath. The supernatant was collected after centrifugation at a speed of 10,000× g at 4 °C for 5 min. The pellets were resuspended in 10 mL extraction solution and homogenized again. The supernatant was then combined with the previously obtained supernatant and thoroughly mixed with chloroform. The supernatant, which contained low molecular weight compounds, was collected and stored at −80 °C.
Nucleotides were analyzed following the method of Ganzera et al. [67]. Nucleotides were separated on a Beckman Spherisorb 5 μm ODS C-18 (4.6 mm × 250 mm) analytical column at a flow rate of 1.0 mL/min. Then, 0.1 M KH2PO4 (pH 6.0) buffer containing 10% methanol was used as the mobile phase to separate the adenosine triphosphate (ATP), adenosine diphosphate (ADP), NAD+, and NADH in the sample. An individual peak was identified by comparing the retention time and spectrum with that of the standards. The concentrations of nucleotides in the samples were calculated based on the calibration curves of the freshly prepared standard solutions.
Reduced glutathione (GSH) and oxidized glutathione (GSSG) were analyzed according to Hissin et al. [68]. GSH reacted with o-phthalaldehyde (OPT) and produced a highly fluorescent compound in pH 8.0 buffer. The fluorescence intensity was proportional to the concentration of GSH in the sample and could be measured at 420 nm after excitation at 350 nm. GSSG, not GSH, could conjugate with OPT at pH 12.0 and produce a fluorescent compound. The concentrations of GSH and GSSG were calculated using a standard curve.
4.5. Protein Extraction
Proteins were extracted from the inhibitor-treated algal cells and the control using a previous method [69]. Briefly, 500 mL of inhibitor-treated or untreated algal cells were harvested by centrifugation (3000× g, 5 min) and rinsed with cold deionized water three times. The cell pellets were disrupted by grinding in a mortar after snap-freezing in liquid nitrogen. The sheared cells were then resuspended in extraction solution containing 50 mM Tris-HCl (pH 8.0), 3 mM dithiothreitol (DTT), 5 mM MgCl2, 10% glycerol, 0.5% polyvinylpyrrolidone (PVP), 5 mM Na2-EDTA, 1 mM phenylmethylsulfonyl fluoride (PMSF), 5 mM benzamidine, and 5 mM aminocaproic acid. The suspension was homogenized for 5 cycles (30 s) at 10,000 g on an ice bath, and the supernatant was collected after centrifugation at 4 °C (10 min, 3000× g). Following this, the supernatant was centrifuged at 4 °C at 20,000× g for 1 h (Beckman Instruments, Inc., Brea, CA, USA). The proteins in the supernatant were precipitated by following the method developed by Wessel et al. [70]. The obtained protein pellets were washed with pure methanol three times and then air-dried. The dry protein pellets were solubilized with lysis buffer containing 7 M urea, 2 M thiourea, 4% CHAPS, 2% immobilized pH gradient (IPG) buffer (3–10 NL), 0.125 pill/mL protein inhibitor cocktail (complete kit, Roche Diagnostics, Risch-Rotkreuz, Switzerland), 1% nuclease mixture (GE Healthcare, Chicago, IL, USA), and 1.0% DTT. The soluble proteins were precipitated by mixing with nine volumes of cold acetone containing 10% (w/v) trichloroacetic acid (TCA) and 0.07% (v/v) 2-mercaptoethanol and maintained at −20 °C overnight. The residual TCA in the protein pellets was removed by thoroughly washing with pre-cooled acetone containing 0.07% 2-mercaptoethanol three times. Residual acetone was removed by air-drying. The protein pellets were resolved with rehydration solution containing 7 M urea, 2 M thiourea, 2% CHAPS, 20 mM DTT, and 0.5% IPG buffer (GE Healthcare). Protein concentration was measured using Coomassie Blue G-250 reagent (Bio-Rad, Richmond, CA, USA) according to the Bradford method [71]. The protein samples were stored at −80 °C prior to one-dimensional or two-dimensional electrophoresis.
4.6. One-Dimensional SDS Gel Electrophoresis and 2-DE
The one-dimensional SDS electrophoresis was performed using a mini VE electrophoresis apparatus (GE Healthcare, USA). Equal quantities of proteins were loaded into each lane and condensed in 4% stacking gel at 80 V for 1 h and then separated in 12% separating gel for 3 h.
2-DE was carried out on Amersham Biosciences IPG-phor isoelectric focusing (IEF) system and Hoefer SE 600 (GE Healthcare, Uppsala, Sweden) electrophoresis units following a previous protocol [72]. Briefly, 150 μg protein prepared in 250 μL rehydration solution was loaded into the 13 cm IPG strip (3–10 NL) by rehydration at 30 V for at least 12 h (20 °C). IEF was performed by following a stepwise voltage increasing procedure: 500 and 1000 V for 1 h, respectively, following which the voltage was gradually increased to 8000 V and maintained at 8000 V for about 10 h, resulting in a total of 64,000 Vh. Prior to the two-dimensional electrophoresis, the IPG strips were firstly equilibrated with buffer containing 50 mM Tris-HCl (pH 8.8), 6 M urea, 30% glycerol, 2% SDS, and 1% DTT for 15 min and then incubated with buffer in which 1% DTT was replaced with 2.5% iodoacetamide under darkness for an additional 15 min. Afterwards, the strips were transferred to the upper layer of the 12.5% SDS-PAGE gel, and two-dimensional electrophoresis was carried out at constant 30 mA for about 4 h.
4.7. Gel Silver-Staining and Image Analysis
After the two-dimensional electrophoresis, the gels were silver-stained using a previously reported method [72]. In brief, the SDS-PAGE gels were fixed overnight in solution containing 10% acetic acid and 40% ethanol and then incubated in solution containing 0.2% sodium thiosulfate, 4.1% sodium acetate, and 30% ethanol at room temperature for 30 min. The gels were stained in 0.1% silver nitrate solution supplemented with 0.02% formaldehyde for 40 min after washing four times with deionized water. The gels were then incubated with developing solution containing 2.5% sodium carbonate and 0.01% formaldehyde for about 10 min. The development was stopped using EDTA solution (1.46%) and the stained gels were washed with water three times.
Image Scanner equipped with software Lab Scan 3.00 (Amersham Bioscience, San Francisco, CA, USA) was used for the image development of silver-stained gels. Prior to scanning, intensity calibration was conducted using an intensity step wedge. The 2-DE images were analyzed using Image Master 2-D Elite software (Amersham Bioscience, USA). Each protein spot was processed by employing the following procedure: Background subtraction, total spot volume normalization, and calculation of spot volume percentage, which was used for comparing the protein expression level. Only those spots that consistently and significantly deviated at least 1.5-fold compared with the control in at least three experiments were selected for the protein identification.
4.8. In-Gel Trypsin Digestion, Mass Spectrometry, and Protein Identification
The spots were excised from the gels and transferred into 0.6 mL centrifuge tubes (AXYGEN, Union City, CA, USA). The gel pieces were then destained by incubation, with solution comprising 1:1 of 30 mM potassium ferricyanide and 100 mM sodium thiosulfate for a few seconds until the dark color disappeared completely. Following this, the gel pieces were washed twice with ultrapure water. The gel chips were equilibrated with 25 mM ammonium bicarbonate (pH 8.0) and then dehydrated with HPLC-grade acetonitrile. The air-dried gel pieces were rehydrated with 2–4 μL trypsin solution [10 μg/mL in 25 mM ammonium bicarbonate (NH4HCO3)] for 30 min on ice and then covered with 20 μL solution containing 25 mM NH4HCO3 and 10% acetonitrile. The mixture was then incubated at 37 °C for 16–18 h. Following centrifugation, the residual peptides in the gel pieces were extracted with solution containing 67% acetonitrile and 2.5% trifluoroacetic acid (TFA). The extracted peptide solution was combined with the previous supernatant and concentrated using a freeze-drier. The samples were then directly applied onto the sample plate and combined with an equal volume of matrix solution (5 mg/mL).
Protocols developed by Ge et al. [73] were used as references. The MALDI-TOF MS and MS/MS spectra were obtained on an ABI 4800 plus MALDI TOF/TOF mass spectrometer (Applied Biosystems, Foster City, CA, USA). The obtained MS and MS/MS data were integrated and interpreted by GPS Explorer software (Applied Biosystems). The combined MS and MS/MS spectra were submitted to the MASCOT search interface (http://www.matrixscience.com/cgi/search_form.pl?FORMVER=2&SEARCH=MIS) (Matrix Science, Ltd., London, UK) using GPS software for database searching. With regards to the search database, the genome database of Chlorella variabilis NC64A submitted by the US DOE Joint Genome Institute [74] was set as the first choice. If the identification results were negative, identification by searching against the NCBI Nr (https://www.ncbi.nlm.nih.gov/) and Swiss-Prot databases (https://www.uniprot.org/uniprot/?query=reviewed:yes) or de novo sequencing combined with sequence-similarity searches were also employed. The searching parameters were set as follows: Peptide and MS/MS ion tolerances: 100 ppm and 0.2 Da modifications: Carbamidomethyl and oxidation, one tolerant missed cleavage. A protein identification with a significant (P < 0.05) MASCOT protein score was considered to be positive. Identifications with a statistically significant (P < 0.05) best ion score based solely on the MS/MS spectra were also accepted as positive. De novo sequencing was carried out on an ABI 4800 plus MALDI TOF/TOF mass spectrometer under the default settings. The peptide sequences were interpreted after filtering out the keratin and trypsin spectra using Mascot Distiller software, with the default settings implemented. The top peptide candidates with the highest score were merged into a single query string, which was submitted to MS-BLAST through the interface at http://genetics.bwh.harvard.edu/msblast/ for searching against the Non-redundant (Nr) database (NRDB95). In sequence similarity searches, the MS-BLAST scoring scheme was used to evaluate the hits. Only high-scoring segment pairs (HSPs) with a score of 62 or above were considered as positive [75].
5. Conclusions
Our study confirmed that mRET had a regulatory effect on the biosynthesis of chlorophyll and lutein in C. pyrenoidosa under heterotrophic conditions, which is associated with changes in the intracellular redox and energy state. Through proteomics analysis, we identified the related proteins that were important and proposed a network of their roles. These results further our understanding of proteomics of marine natural products, providing valuable insights into future exploration of microalgae and other heterotrophic marine organisms for the enhanced pigment production.
Supplementary Materials
The following are available online at http://www.mdpi.com/1660-3397/16/10/354/s1, Figure S1: Functional categorization of identified up- and down-regulated proteins in Chlorella pyrenoidosa after treatment with mitochondrial respiratory electron transport chain (mRET) inhibitors. A: SHAM treatment. B: antimycin A treatment. C: NaN3 treatment. This classification is based on homologies.
Author Contributions
Y.J. conceived and designed the experiments; Z.-h.L. and T.L. performed the experiments; Q.-y.H. coordinated and supervised the experiments; Z.S. analyzed the data and drafted the manuscript.
Funding
This research was funded by National Natural Science Foundation of China (31501493), NSFC-Shandong Joint Fund (U1706209) and Natural Science Foundation of the Tianjin Municipal Education Commission (2017KJ183).
Conflicts of Interest
The authors declare no conflict of interest.
References
- 1.Chen F. High cell density culture of microalgae in heterotrophic growth. Trends Biotechnol. 1996;14:421–426. doi: 10.1016/0167-7799(96)10060-3. [DOI] [Google Scholar]
- 2.Lee Y.K. Commercial production of microalgae in the Asia-pacific rim. J. Appl. Phycol. 1997;9:403–411. doi: 10.1023/A:1007900423275. [DOI] [Google Scholar]
- 3.Qian F.H. Master’s Thesis. East China University of Science and Technology; Shanghai, China: 2007. Study on the Optimization and Primary Scale-up of Chlorella Sequential Heterotrophic/Autotrophic Cultivation Technology for High-Density and High-Quality. [Google Scholar]
- 4.Shi X.M., Chen F., Yuan J.P., Chen H. Heterotrophic production of lutein by selected Chlorella strains. J. Appl. Phycol. 1997;5:445–450. doi: 10.1023/A:1007938215655. [DOI] [Google Scholar]
- 5.Wu Z.Y., Qu C.B., Shi X.M. Biochemical system analysis of lutein production by heterotrophic Chlorella pyrenoidosa in a fermentor. Food Technol. Biotechnol. 2009;47:450–455. [Google Scholar]
- 6.Johnson E.J. Role of lutein and zeaxanthin in visual and cognitive function throughout the lifespan. Nutr. Rev. 2015;72:605–612. doi: 10.1111/nure.12133. [DOI] [PubMed] [Google Scholar]
- 7.Le M., Lin X.M. Effects of lutein and zeaxanthin on aspects of eye health. J. Sci. Food Agric. 2010;90:2–12. doi: 10.1002/jsfa.3785. [DOI] [PubMed] [Google Scholar]
- 8.Sangiovanni J.P., Neuringer M. The putative role of lutein and zeaxanthin as protective agents against age-related macular degeneration: Promise of molecular genetics for guiding mechanistic and translational research in the field. Am. J. Clin. Nutr. 2012;96:1223S–1233S. doi: 10.3945/ajcn.112.038240. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 9.Mewborn C.M., Lindbergh C.A., Robinson T.L., Gogniat M.A., Terry D.P., Jean K.R., Hammond B.R., Renzi-Hammond L.M., Miller L.S. Lutein and Zeaxanthin Are Positively Associated with Visual-Spatial Functioning in Older Adults: An fMRI Study. Nutrients. 2018;10:458. doi: 10.3390/nu10040458. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 10.Yang J., Zhang M., Yu J. Mitochondrial retrograde regulation tuning fork in nuclear genes expressions of higher plants. J. Genet. Genom. 2008;35:65–71. doi: 10.1016/S1673-8527(08)60010-7. [DOI] [PubMed] [Google Scholar]
- 11.Matsuo M., Obokata J. Remote control of photosynthetic genes by the mitochondrial respiratory chain. Plant J. 2006;47:873–882. doi: 10.1111/j.1365-313X.2006.02839.x. [DOI] [PubMed] [Google Scholar]
- 12.Li Y., Huang J., Sandmann G., Chen F. Glucose sensing and the mitochondrial alternative pathway are involved in the regulation of astaxanthin biosynthesis in the dark-grown Chlorella zofingiensis (chlorophyceae) Planta. 2008;228:735–743. doi: 10.1007/s00425-008-0775-4. [DOI] [PubMed] [Google Scholar]
- 13.Padmasree K., Raghavendra A. Response of photosynthetic carbon assimilation in mesophyll protoplasts to restriction on mitochondrial oxidative metabolism: Metabolites related to the redox status and sucrose biosynthesis. Photosynth. Res. 1999;62:231–239. doi: 10.1023/A:1006382518725. [DOI] [Google Scholar]
- 14.Saisho D., Nakazono M., Tsutsumi N., Hirai A. ATP synthesis inhibitors as well as respiratory inhibitors increase steady-state level of alternative oxidase mRNA in Arabidopsis thaliana. J. Plant Physiol. 2001;158:241–245. doi: 10.1078/0176-1617-00193. [DOI] [Google Scholar]
- 15.Li N. Mitochondrial Complex I Inhibitor Rotenone Induces Apoptosis through Enhancing Mitochondrial Reactive Oxygen Species Production. J. Biol. Chem. 2002;278:8516–8525. doi: 10.1074/jbc.M210432200. [DOI] [PubMed] [Google Scholar]
- 16.Rhoads D.M., Vanlerberghe G.C. Plant Mitochondria: From Genome to Function. Springer Dordrecht; Dordrecht, The Netherlands: 2004. pp. 83–106. [Google Scholar]
- 17.Tang X.Q., Luo Y.X., Chen H.Z., Liu D.P. Mitochondria, endothelial cell function, and vascular diseases. Front. Physiol. 2014;5:175. doi: 10.3389/fphys.2014.00175. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 18.Maxwell D.P., Nickels R., McIntosh L. Evidence of mitochondrial involvement in the transduction of signals required for the induction of genes associated with pathogen attack and senescence. Plant J. 2002;29:269–279. doi: 10.1046/j.1365-313X.2002.01216.x. [DOI] [PubMed] [Google Scholar]
- 19.Popov V., Simonian R., Skulachev V., Starkov A. Inhibition of the alternative oxidase stimulates H2O2 production in plant mitochondria. FEBS Lett. 1997;415:87–90. doi: 10.1016/S0014-5793(97)01099-5. [DOI] [PubMed] [Google Scholar]
- 20.Umbach A.L., Fiorani F., Siedow J.N. Characterization of transformed Arabidopsis with altered alternative oxidase levels and analysis of effects on reactive oxygen species in tissue. Plant Physiol. 2005;139:1806–1820. doi: 10.1104/pp.105.070763. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 21.Claiborne A., Yeh J.I., Mallett T.C., Luba J., Crane E.J., Charrier V., Parsonage D. Protein-sulfenic acids: Diverse roles for an unlikely player in enzyme catalysis and redox regulation. Biochemistry. 1999;38:15407–15416. doi: 10.1021/bi992025k. [DOI] [PubMed] [Google Scholar]
- 22.Grene R. The Arabidopsis Book. American Society of Plant Biologists; Rockville, MD, USA: 2002. [Google Scholar]
- 23.Valko M., Leibfritz D., Moncol J., Cronin M.T., Mazur M., Telser J. Free radicals and antioxidants in normal physiological functions and human disease. Int. J. Biochem. Cell Biol. 2007;39:44–84. doi: 10.1016/j.biocel.2006.07.001. [DOI] [PubMed] [Google Scholar]
- 24.Foyer C.H., Noctor G. Redox homeostasis and antioxidant signaling: A metabolic interface between stress perception and physiological responses. Plant Cell Online. 2005;17:1866–1875. doi: 10.1105/tpc.105.033589. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 25.Butow R.A., Avadhani N.G. Mitochondrial signaling: The retrograde response. Mol. Cell. 2004;14:1–15. doi: 10.1016/S1097-2765(04)00179-0. [DOI] [PubMed] [Google Scholar]
- 26.Yao N., Tada Y., Sakamoto M., Nakayashiki H., Park P., Tosa Y., Mayama S. Mitochondrial oxidative burst involved in apoptotic response in oats. Plant J. 2002;30:567–579. doi: 10.1046/j.1365-313X.2002.01314.x. [DOI] [PubMed] [Google Scholar]
- 27.Ho H.Y., Lin Y.T., Lin G., Wu P.R., Cheng M.L. Nicotinamide nucleotide transhydrogenase (NNT) deficiency dysregulates mitochondrial retrograde signaling and impedes proliferation. Redox Biol. 2017;12:916–928. doi: 10.1016/j.redox.2017.04.035. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 28.Gray G., Maxwell D., Villarimo A., McIntosh L. Mitochondria/nuclear signaling of alternative oxidase gene expression occurs through distinct pathways involving organic acids and reactive oxygen species. Plant Cell Rep. 2004;23:497–503. doi: 10.1007/s00299-004-0848-1. [DOI] [PubMed] [Google Scholar]
- 29.Yamaguchi K., Beligni M.V., Prieto S., Haynes P.A., McDonald W.H., Yates J.R., Mayfield S.P. Proteomic Characterization of the Chlamydomonas reinhardtii Chloroplast Ribosome identification of proteins unique to the 70s ribosome. J. Biol. Chem. 2003;278:33774–33785. doi: 10.1074/jbc.M301934200. [DOI] [PubMed] [Google Scholar]
- 30.Rand K., Noll C., Schiebel H.M., Kemken D., Dülcks T., Kalesse M., Heinz D.W., Layer G. The oxygen-independent coproporphyrinogen III oxidase HemN utilizes harderoporphyrinogen as a reaction intermediate during conversion of coproporphyrinogen III to protoporphyrinogen IX. Biol. Chem. 2010;391:55–63. doi: 10.1515/bc.2010.006. [DOI] [PubMed] [Google Scholar]
- 31.Surpin M., Larkin R.M., Chory J. Signal transduction between the chloroplast and the nucleus. Plant Cell Online. 2002;14:S327–S338. doi: 10.1105/tpc.010446. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 32.Johanningmeier U., Howell S.H. Regulation of light-harvesting chlorophyll-binding protein mRNA accumulation in Chlamydomonas reinhardi. Possible involvement of chlorophyll synthesis precursors. J. Biol. Chem. 1984;259:13541–13549. [PubMed] [Google Scholar]
- 33.Oster U., Brunner H., Rüdiger W. The greening process in cress seedlings. V. Possible interference of chlorophyll precursors, accumulated after thujaplicin treatment, with light-regulated expression of Lhc genes. J. Photochem. Photobiol. Biol. 1996;36:255–261. doi: 10.1016/S1011-1344(96)07388-5. [DOI] [Google Scholar]
- 34.Vinti G., Hills A., Campbell S., Bowyer J.R., Mochizuki N., Chory J., López-Juez E. Interactions between hy1 and gun mutants of Arabidopsis, and their implications for plastid/nuclear signalling. Plant J. 2000;24:883–894. doi: 10.1046/j.1365-313x.2000.00936.x. [DOI] [PubMed] [Google Scholar]
- 35.Zavgorodnyaya A., Papenbrock J., Grimm B. Yeast 5-aminolevulinate synthase provides additional chlorophyll precursor in transgenic tobacco. Plant J. 1997;12:169–178. doi: 10.1046/j.1365-313X.1997.12010169.x. [DOI] [PubMed] [Google Scholar]
- 36.Mochizuki N., Brusslan J.A., Larkin R., Nagatani A., Chory J. Arabidopsis genomes uncoupled 5 (GUN5) mutant reveals the involvement of Mg-chelatase H subunit in plastid-to-nucleus signal transduction. Proc. Natl. Acad. Sci. USA. 2001;98:2053–2058. doi: 10.1073/pnas.98.4.2053. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 37.Walker C.J., Willows R.D. Mechanism and regulation of Mg-chelatase. Biochem. J. 1997;327:321–333. doi: 10.1042/bj3270321. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 38.Kropat J., Oster U., Rüdiger W., Beck C.F. Chloroplast signalling in the light induction of nuclear HSP70 genes requires the accumulation of chlorophyll precursors and their accessibility to cytoplasm/nucleus. Plant J. 2000;24:523–531. doi: 10.1046/j.1365-313x.2000.00898.x. [DOI] [PubMed] [Google Scholar]
- 39.La R.N., Rascio N., Oster U., Rüdiger W. Amitrole treatment of etiolated barley seedlings leads to deregulation of tetrapyrrole synthesis and to reduced expression of Lhc and RbcS genes. Planta. 2001;213:101–108. doi: 10.1007/s004250000477. [DOI] [PubMed] [Google Scholar]
- 40.Moller S.G., Kunkel T., Chua N.H. A plastidic ABC protein involved in intercompartmental communication of light signaling. Sci. Signal. 2001;15:90–103. doi: 10.1101/gad.850101. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 41.Estevez J.M., Cantero A., Reindl A., Reichler S., Leon P. 1-deoxy-d-xylulose-5-phosphate synthase, a limiting enzyme for plastidic isoprenoid biosynthesis in plants. J. Biol. Chem. 2001;276:22901–22909. doi: 10.1074/jbc.M100854200. [DOI] [PubMed] [Google Scholar]
- 42.Morris W.L., Ducreux L.J., Hedden P., Millam S., Taylor M.A. Overexpression of a bacterial 1-deoxy-d-xylulose 5-phosphate synthase gene in potato tubers perturbs the isoprenoid metabolic network: Implications for the control of the tuber life cycle. J. Exp. Bot. 2006;57:3007–3018. doi: 10.1093/jxb/erl061. [DOI] [PubMed] [Google Scholar]
- 43.Reed J.W. Phytochromes are Pr-ipatetic kinases. Curr. Opin. Plant Biol. 1999;2:393–397. doi: 10.1016/S1369-5266(99)00011-4. [DOI] [PubMed] [Google Scholar]
- 44.Kuno N., Furuya M. Phytochrome regulation of nuclear gene expression in plants. Semin. Cell Dev. Biol. 2000;11:485–493. doi: 10.1006/scdb.2000.0205. [DOI] [PubMed] [Google Scholar]
- 45.Lintig J., Welsch R., Bonk M., Giuliano G., Batschauer A., Kleinig H. Light-dependent regulation of carotenoid biosynthesis occurs at the level of phytoene synthase expression and is mediated by phytochrome in Sinapis alba and Arabidopsis thaliana seedlings. Plant J. 1997;12:625–634. doi: 10.1046/j.1365-313X.1997.00625.x. [DOI] [PubMed] [Google Scholar]
- 46.Ma L., Li J., Qu L., Hager J., Chen Z., Zhao H., Deng X.W. Light control of Arabidopsis development entails coordinated regulation of genome expression and cellular pathways. Plant Cell Online. 2001;13:2589–2607. doi: 10.1105/tpc.13.12.2589. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 47.Liu R., Xu Y.H., Jiang S.C., Lu K., Lu Y.F., Feng X.J., Wu Z., Liang S., Yu Y.T., Wang X.F., et al. Light-harvesting chlorophyll a/b-binding proteins, positively involved in abscisic acid signalling, require a transcription repressor, wrky40, to balance their function. J. Exp. Bot. 2013;64:5443–5456. doi: 10.1093/jxb/ert307. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 48.Toledoortiz G., Huq E., Rodríguez C.M. Direct regulation of phytoene synthase gene expression and carotenoid biosynthesis by phytochrome-interacting factors. Proc. Natl. Acad. Sci. USA. 2010;107:11626–11631. doi: 10.1073/pnas.0914428107. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 49.Shen H., Zhu L., Castillon A., Majee M., Downie B., Huq E. Light-induced phosphorylation and degradation of the negative regulator phytochrome-interacting factor 1 from Arabidopsis depend upon its direct physical interactions with photoactivated phytochromes. Plant Cell Online. 2008;20:1586–1602. doi: 10.1105/tpc.108.060020. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 50.Leivar P., Monte E. Pifs: Systems integrators in plant development. Plant Cell. 2014;26:56–78. doi: 10.1105/tpc.113.120857. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 51.Park E., Park J., Kim J., Nagatani A., Lagarias J.C., Choi G. Phytochrome B inhibits binding of phytochrome-interacting factors to their target promoters. Plant J. Cell Mol. Biol. 2012;72:537–546. doi: 10.1111/j.1365-313X.2012.05114.x. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 52.Pires N., Dolan L. Origin and Diversification of Basic-Helix-Loop-Helix Proteins in Plants. Mol. Biol. Evol. 2010;27:862–874. doi: 10.1093/molbev/msp288. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 53.Mummert E., Grimm R., Speth V., Eckerskorn C., Schiltz E., Gatenby A.A., Schäfer E. ATCPl-related molecular chaperone from plants refolds phytochrome to its photoreversible form. Nature. 1993;363:644–648. doi: 10.1038/363644a0. [DOI] [PubMed] [Google Scholar]
- 54.Su Y.S., Lagarias J.C. Light-independent phytochrome signaling mediated by dominant GAF domain tyrosine mutants of Arabidopsis phytochromes in transgenic plants. Plant Cell Online. 2007;19:2124–2139. doi: 10.1105/tpc.107.051516. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 55.Mayfield J.D., Folta K.M., Paul A.L., Ferl R.J. The 14-3-3 proteins µ and v influence transition to flowering and early phytochrome response. Plant Physiol. 2007;145:1692–1702. doi: 10.1104/pp.107.108654. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 56.Kinoshita T., Emi T., Tominaga M., Sakamoto K., Shigenaga A., Doi M., Shimazaki K.I. Blue-light-and phosphorylation-dependent binding of a 14-3-3 protein to phototropins in stomatal guard cells of broad bean. Plant Physiol. 2003;133:1453–1463. doi: 10.1104/pp.103.029629. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 57.Hong J.P., Adams E., Yanagawa Y., Matsui M., Shin R. AtSKIP18 and AtSKIP31, F-box subunits of the SCF E3 ubiquitin ligase complex, mediate the degradation of 14-3-3 proteins in Arabidopsis. Biochem. Biophys. Res. Commun. 2017;485:174–180. doi: 10.1016/j.bbrc.2017.02.046. [DOI] [PubMed] [Google Scholar]
- 58.Zhang Z., Zhang Y., Zhao H., Huang F., Zhang Z., Lin W. The important functionality of 14-3-3 isoforms in rice roots revealed by affinity chromatography. J. Proteom. 2017;158:20–30. doi: 10.1016/j.jprot.2017.02.008. [DOI] [PubMed] [Google Scholar]
- 59.Xu H., Zhao X., Guo C., Li K. Spinach 14-3-3 protein interacts with the plasma membrane H(+)-ATPase and nitrate reductase in response to excess nitrate stress. Plant Physiol. Biochem. 2016;106:187–197. doi: 10.1016/j.plaphy.2016.04.043. [DOI] [PubMed] [Google Scholar]
- 60.Delbaere L.T., Sudom A.M., Prasad L., Leduc Y., Goldie H. Structure/function studies of phosphoryl transfer by phosphoenolpyruvate carboxykinase. Biochim. Biophys. Acta-Proteins Proteom. 2004;1697:271–278. doi: 10.1016/j.bbapap.2003.11.030. [DOI] [PubMed] [Google Scholar]
- 61.Streatfield S.J., Weber A., Kinsman E.A., Häusler R.E., Li J., Post B.D., Kaiser W.M., Pyke K.A., Flügge U.I., Chory J. The phosphoenolpyruvate/phosphate translocator is required for phenolic metabolism, palisade cell development, and plastid-dependent nuclear gene expression. Plant Cell Online. 1999;11:1609–1621. doi: 10.1105/tpc.11.9.1609. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 62.Cunningham F.X. Regulation of carotenoid synthesis and accumulation in plants. Pure Appl. Chem. 2002;74:1409–1417. doi: 10.1351/pac200274081409. [DOI] [Google Scholar]
- 63.Huang W., Ye J., Zhang J., Lin Y., He M., Huang J. Transcriptome analysis of chlorella zofingiensis to identify genes and their expressions involved in astaxanthin and triacylglycerol biosynthesis. Algal Res. 2016;17:236–243. doi: 10.1016/j.algal.2016.05.015. [DOI] [Google Scholar]
- 64.Wu X., Jiang L., Yu M., An X., Ma R., Yu Z. Proteomic analysis of changes in mitochondrial protein expression during peach fruit ripening and senescence. J. Proteom. 2016;147:197–211. doi: 10.1016/j.jprot.2016.06.005. [DOI] [PubMed] [Google Scholar]
- 65.Baroli I. Zeaxanthin Accumulation in the Absence of a Functional Xanthophyll Cycle Protects Chlamydomonas reinhardtii from Photooxidative Stress. Plant Cell Online. 2003;15:992–1008. doi: 10.1105/tpc.010405. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 66.Lazzarino G., Amorini A.M., Fazzina G., Vagnozzi R., Signoretti S., Donzelli S., Stasio E.D., Giardina B., Tavazzi B. Single-sample preparation for simultaneous cellular redox and energy state determination. Anal. Biochem. 2003;322:51–59. doi: 10.1016/j.ab.2003.07.013. [DOI] [PubMed] [Google Scholar]
- 67.Ganzera M., Vrabl P., Wörle E., Burgstaller W., Stuppner H. Determination of adenine and pyridine nucleotides in glucose-limited chemostat cultures of Penicillium simplicissimum by one-step ethanol extraction and ion-pairing liquid chromatography. Anal. Biochem. 2006;359:132–140. doi: 10.1016/j.ab.2006.09.012. [DOI] [PubMed] [Google Scholar]
- 68.Hissin P.J., Hilf R. A fluorometric method for determination of oxidized and reduced glutathione in tissues. Anal. Biochem. 1976;74:214–226. doi: 10.1016/0003-2697(76)90326-2. [DOI] [PubMed] [Google Scholar]
- 69.Wang S.B., Hu Q., Sommerfeld M., Chen F. An optimized protocol for isolation of soluble proteins from microalgae for two-dimensional gel electrophoresis analysis. J. Appl. Phycol. 2003;15:485–496. doi: 10.1023/B:JAPH.0000004324.88897.b2. [DOI] [Google Scholar]
- 70.Wessel D., Flügge U.I. A method for the quantitative recovery of protein in dilute solution in the presence of detergents and lipids. Anal. Biochem. 1984;138:141–143. doi: 10.1016/0003-2697(84)90782-6. [DOI] [PubMed] [Google Scholar]
- 71.Bradford M.M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem. 1976;72:248–254. doi: 10.1016/0003-2697(76)90527-3. [DOI] [PubMed] [Google Scholar]
- 72.Wang Y., Cheung Y.H., Yang Z., Chiu J.F., Che C.M., He Q.Y. Proteomic approach to study the cytotoxicity of dioscin (saponin) Proteomics. 2006;6:2422–2432. doi: 10.1002/pmic.200500595. [DOI] [PubMed] [Google Scholar]
- 73.Ge F., Lu X.P., Zeng H.L., He Q.Y., Xiong S., Jin L., He Q.Y. Proteomic and functional analyses reveal a dual molecular mechanism underlying arsenic-induced apoptosis in human multiple myeloma cells. J. Proteome Res. 2009;6:3006–3019. doi: 10.1021/pr9001004. [DOI] [PubMed] [Google Scholar]
- 74.Blanc G., Etten J.L.V. The Chlorella variabilis NC64A genome reveals adaptation to photosymbiosis, coevolution with viruses, and cryptic sex. Plant Cell. 2010;22:2943–2955. doi: 10.1105/tpc.110.076406. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 75.Waridel P., Frank A., Thomas H., Surendranath V., Sunyaev S., Pevzner P., Shevchenko A. Sequence similarity-driven proteomics in organisms with unknown genomes by LC-MS/MS and automated de novo sequencing. Proteomics. 2007;14:2318–2329. doi: 10.1002/pmic.200700003. [DOI] [PubMed] [Google Scholar]
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