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Article

Dual-Located WHIRLY1 Interacting with LHCA1 Alters Photochemical Activities of Photosystem I and Is Involved in Light Adaptation in Arabidopsis

Center for Molecular Cell and Systems Biology, Fujian Provincial Key Laboratory of Haixia Applied Plant Systems Biology, College of Life Sciences, Fujian Agriculture and Forestry University, Fuzhou 350002, China
*
Author to whom correspondence should be addressed.
Int. J. Mol. Sci. 2017, 18(11), 2352; https://doi.org/10.3390/ijms18112352
Submission received: 9 October 2017 / Revised: 27 October 2017 / Accepted: 2 November 2017 / Published: 7 November 2017
(This article belongs to the Section Molecular Plant Sciences)

Abstract

:
Plastid-nucleus-located WHIRLY1 protein plays a role in regulating leaf senescence and is believed to associate with the increase of reactive oxygen species delivered from redox state of the photosynthetic electron transport chain. In order to make sure whether WHIRLY1 plays a role in photosynthesis, in this study, the performances of photosynthesis were detected in Arabidopsis whirly1 knockout (kowhy1) and plastid localized WHIRLY1 overexpression (oepWHY1) plants. Loss of WHIRLY1 leads to a higher photochemical quantum yield of photosystem I Y(I) and electron transport rate (ETR) and a lower non-photochemical quenching (NPQ) involved in the thermal dissipation of excitation energy of chlorophyll fluorescence than the wild type. Further analyses showed that WHIRLY1 interacts with Light-harvesting protein complex I (LHCA1) and affects the expression of genes encoding photosystem I (PSI) and light harvest complexes (LHCI). Moreover, loss of WHIRLY1 decreases chloroplast NAD(P)H dehydrogenase-like complex (NDH) activity and the accumulation of NDH supercomplex. Several genes encoding the PSI-NDH complexes are also up-regulated in kowhy1 and the whirly1whirly3 double mutant (ko1/3) but steady in oepWHY1 plants. However, under high light conditions (800 μmol m−2 s−1), both kowhy1 and ko1/3 plants show lower ETR than wild-type which are contrary to that under normal light condition. Moreover, the expression of several PSI-NDH encoding genes and ERF109 which is related to jasmonate (JA) response varied in kowhy1 under different light conditions. These results indicate that WHIRLY1 is involved in the alteration of ETR by affecting the activities of PSI and supercomplex formation of PSI with LHCI or NDH and may acting as a communicator between the plastids and the nucleus.

Graphical Abstract

1. Introduction

Chloroplasts serve as sensors of environmental conditions and guide plants toward proper adaption [1]. They can remodel the photosynthetic apparatus and maximize photosynthetic efficiency under various environmental conditions [2,3]. Photosynthetic light reactions are essential to the retrograde plastid-to-nucleus signaling which contributes to the coordination of chloroplast function by regulating nuclear gene expression [4,5,6]. Although novel possible plastidial signals including the transcription factor WHIRLY1 (WHY1) were proposed [7,8,9], the association of WHY1 and retrograde plastid-to-nucleus signaling remains elusive.
WHY1 is a plastids-nucleus bi-located protein and belongs to a small family of single-stranded DNA (ssDNA) binding proteins [10,11]. In monocotyledonous plants, the WHIRLY family contains two members, whereas in dicotyledonous plants, they have three members [12]. In Arabidopsis, WHY1 and WHY3 were discovered in the proteome of transcriptionally active chromosome (TAC), which is the transcriptionally active fraction of nucleoids [13]. Most of the double knockout mutants lacking both WHY1 and WHY3 (why1why3, ko1/3) had no difference in phenotype with the wild-type [14,15]. In contrast, the why1why3polIb-1 triple mutant that is defective in WHY1 and WHY3 as well as the chloroplast DNA polymerase 1B (Pol1B) exhibited a more extreme yellow-variegated phenotype [16]. The why1why3polIb-1 mutants showed lower photosynthetic electron transport efficiencies and higher accumulation of reactive oxygen species compared to wild-type plants [16]. The higher level of oxidation observed in this mutant was linked to chloroplast to nucleus signaling and enhanced the adaptation to oxidative stress [16]. WHY3 protein was identified as a redox-affected protein in chloroplasts, while WHY1 protein was indicated as a thioredoxin target [8]. Moreover, WHY1 was proposed to link the operation of the photosynthetic electron transport chain to gene expression due to its location that is at the boundary between thylakoids and nucleoids [8]. Therefore, WHY1 is important in the perception of redox functions within the electron transport system which is closely linked to photosynthesis [8].
Recently, a new research showed that young leaves of WHY1 RNAi knockdown mutants (W1-1, W1-7, W1-9) had lower CO2 assimilation rates and epoxidation state (EPS) than that in wild-type barley under high light condition [17]. However, CO2 assimilation rates in senescent leaves of WHY1 RNAi mutants were higher than in wild-type while EPS was similar in both genotypes [17]. Furthermore, the VAZ (violaxanthin, antheraxanthin, zeaxanthin) pool was elevated in both young and senescent leaves of WHY1 RNAi knockdown mutants [17]. Hence, WHY1 should be associated with photosynthesis and the metabolism during both chloroplast development and senescence progress. The slowing down of light-dependent senescence processes but not of dark-induced senescence in WHY1-defcient barley plants indicates that WHY1 is involved in sensing and signaling of light intensity [17]. Moreover, transcriptome analyses showed that WHY1 was significantly enriched in light-regulated gene cluster and plastid-regulated gene cluster, implying that WHY1 has a role in integration of light and plastid signaling [18]. In addition, WHY1 in barely were assumed to connect the plastid and nuclear genes encoding photosynthetic proteins during abiotic stress [19]. However, the detail role of WHY1 in both pathways remains unknown.
Performances of photosynthesis such as optimization of electron transport, carbon assimilation, and assimilate production are important at all stages of leaf development, especially during senescence when chloroplasts are dismantled and photosynthetic proteins are recycled for vegetative or reproductive development and in particular for grain filling [20]. Therefore, photosynthesis and leaf senescence are determinants of plant productivity [20]. In this report, roles of WHY1 on photosynthesis have been investigated using Arabidopsis WHY1 knock out and overexpression plants [21]. The effects of WHY1 on photosynthetic performances and photosystem I encoding genes were determined at early senescence stage. Then we further searched for the WHY1 interacting protein in chloroplast and analyzed the function and structure of the NDH complex which formed a supercomplex with PSI in WHY1 mutants. Moreover, to determine whether WHY1 is involved in light adaption via regulating photosynthesis, we tested the photosynthesis parameters and PSI-LHCI, NDH gene expression in kowhy1 and ko1/3 mutants under high light conditions. Our results suggest that WHY1 is involved in regulating the photosynthesis process during senescence and stress.

2. Results

2.1. Changes of Photosynthetic Performance in WHY1 Mutants

The function of the photosynthetic machinery can be probed by chlorophyll (chl) fluorescence emission by photosystem II (PSII) and light absorption by P700 reaction center chl a of photosystem I (PSI) [22]. To determine whether photosynthetic performance at leaf early senescence stage is affected by WHY1 in Arabidopsis, photosynthetic parameters in WHY1 mutants were measured. The photochemical quantum yield of photosystem I Y(I) and photosystem II Y(II) was measured in fully expanded rosette leaves of different WHY1 mutants at the seventh week by using a Dual PAM (Pulse-amplitude modulation) Measuring System (Walz, Effeltrich, Germany). Photosynthetic parameters in Light-harvesting complex a 1 knock out mutant (lhca1) that is defective in state transitions in photosynthesis were also measured [23]. The leaves were exposed to 125 μmol m−2 s−1 of actinic irradiance after dark adaptation for 15 min and transient 10,000 μmol m−2 s−1 of irradiance of the saturating pulses for 21 s. Y(I) is defined by the fraction of overall P700 that is reduced in a given state and is not limited by acceptor [24]. Y(II) is the efficiency of excitation capture by open PSII reaction centers. As showed in Figure 1A, Y(I) was higher in kowhy1 plants than in wild-type, and in agreement, the Y(I) in the heterozygous line (WT/why1) created by back-crossing kowhy1 with wild-type also slightly decreased but was still significantly higher than wild-type (Figure 1A), whereas Y(I) in oepWHY1 plants that overexpressed WHY1 in chloroplast were only about 60% of that in WT. Interestingly, the lhca1 mutant line showed the same yield of Y(I) as the WT/why1 heterozygous line (Figure 1). In addition, photosystem II yield was similar in wild-type and those WHY1 mutants (Figure 1B). Therefore, loss of WHY1 seems to increase photosystem I quantum yield but not photosystem II quantum yield.
We also determined the nonphotochemical quenching of photosystem II fluorescence (NPQ) and the chloroplast electron transport rate (ETR) in WHY1 and lhca1 mutants. As showed in Figure 1D, though NPQ displayed a slight increase in the overexpression plastid-localized WHY1 (oepWHY1) plants, it was clearly reduced in WHY1 heterozygous knockout line (WT/why1) and homozygous line (kowhy1), and the latter showed a lower level (Figure 1D). In addition, NPQ was also lower in lhca1 mutant compared to wild-type plants. Therefore, loss of WHY1 led to less excessive excitation energy production. The ETR in kowhy1 mutants showed an increase of 35% than in wild-type, whereas the ETR was slightly decreased in oepWHY1 plants (Figure 1C). Moreover, the heterozygous line (WT/why1) and lhca1 mutant exhibited an intermediate ETR value between wild-type and the kowhy1 mutant (Figure 1C). These results suggest that WHY1 acts as a repressor in electron transport progress.

2.2. WHY1 Affects the Expression of PSI-LHCI Encoding Genes

Previous transcriptome analyses showed that WHY1 was significantly enriched in light-regulated gene cluster and plastid-regulated gene cluster [18]. Our previous microarray data analyses also showed that photosystem I related gene expression was significally up- or down-regulated in the inducible expression of WHY1 or knockout of WHY1 plants (Lin et al., 2017 manuscript). We wondered if WHY1 regulates the function and activity of photosystem I at transcriptional level. Therefore, we examined the expression of genes encoding reaction center and LHCI complex [25] under different WHY1 mutant plants at 6th week by qRT-PCR when leaf senescence is initiated (Figure 2). LHCA2 and LHCA4, both of which have been reported to be associated with the core in the absence of their “dimeric partners” [26], were up-regulated 2–4-fold in the absence of WHY1 mutant (kowhy1), while genes encoding PSI core complex were not affected. Moreover, expression of LHCA6, PsaK and PsaO were significantly increased in WHY1 and WHY3 double mutant (ko1/3). In contrast, in the overexpression plastid-localized WHY1 (oepWHY1) plants, which accumulated WHY1 only in plastids, did not alter the transcription levels of PSI or LHCI encoding genes. Interestingly, a large number of genes encoding the PSI core complex were up-regulated in both the nucleus and plastids overexpressed WHY1 plants (oepnWHY1) (Figure 2B), whereas the transcription level of LHCA1-6 was steady (Figure 2A). Since most of the PSI core subunit are critical to maintain the formation and functions of PSI [27], these results indicate that WHY1 is involved in regulating the expression of PSI encoding genes, but may not be a direct upstream regulator on plastid transcriptional level.

2.3. WHY1 Interacts with LHCA1 In Vitro and In Vivo

In order to know whether pWHY1 affects the function and activity of photosystem I on protein level, we searched for the WHY1 interacting protein library [28]. Interestingly, LHCA1, which has a molecular weight of 22 kDa, was identified as one of the putative interaction partners (Figure 3A). LHCA1 is one of the four subunits of the peripheral light-harvesting complex (LHCI) in photosystem I (PSI) [29]. The interaction between LHCA1 and WHY1 was confirmed by fresh retransformation of yeast two hybrid (Figure 3A).
Next, we conducted a co-immunoprecipitation assay using the three-solubilized thylakoid membrane fractions (Figure S1) as inputs and the antibody against HA-tag as the binding partner. Immunoblotting using antibodies against LHCA1, LHCA2, LHCA3, LHCA4, and the photosystem II LHCB1, respectively, showed that these proteins were all present in the Fraction 3, whereas only LHCA1 was detectable in that of the co-IP samples, indicating a direct interaction between WHY1 and LHCA1. No interactions between WHY1 and the others LHCAs were discovered (Figure 3B). Here, the photosystem II protein LHCB1 was used as a separation control and it gave signals in both Fraction 2 and 1 in the input gel. A weak signal of LHCB1 in the lane of Fraction 3 of the same gel might hint a slight contamination of photosystem II. Similarly, the appearance of a weak signal of LHCA3 and an even-weaker signal of LHCA4 in the lane of Fraction 2 of the input gel probably arose from cross-contamination during sucrose gradient ultracentrifugation that were normally difficult to be avoided [26].
Further, a bimolecular fluorescence complementation (BiFC) assay was performed in onion epidermal cells to investigate the interaction between WHY1 and LHCA1 in vivo. WHY1 and LHCA1 were fused to YN vector pHA-GFPn173c or YC vector pcMYC-GFPc155c. As shown in Figure 3C, co-expression of WHY1-HA-GFPn173c and LHCA1-MYC-GFPc155c reconstituted a functional GFP in onion epidermal cells, and co-expression of WHY1-MYC-GFPc155c and LHCA1-HA-GFPn173c also reconstituted a functional GFP in onion epidermal cells. The co-expression of LHCA4 and WHY1 served as a negative control, which did not show the fluorescent signals (Figure 3C). The expression of LHCA4 and WHY1 in onion epidermal cells was detected by immunodetection (Figure S2). Fusions of WHY1 or LHCA1 to the full length GFP confirmed their plastid localization (Figure 3C). These results suggest that WHY1 interacts with LHCA1 both in vitro and in vivo. We here confirmed the interaction of WHY1 and LHCA1 is a part of the photosynthetic apparatus, implying that WHY1 might be involved in the photosynthetic apparatus complex formation on the protein level. However, native LHCA1 forms functional dimer with LHCA4 [30], which per se did not interact with WHY1 in these assays (Figure 3). Taken together, these results suggest that WHY1 interacts with LHCA1 in vitro and in vivo. Considering the roles of LHCA1 in photosynthesis and the similarity of photosynthesis parameters in WHY1 mutants and lhca1, the interaction of WHY1 and LHCA1 may have a function in regulating photosynthetic activity.

2.4. WHY1 Affects the Expression of Plastid NDH Genes

The ETR and Y(I) was increased, but Y(II) was steady in kowhy1 mutant, suggesting that the up-regulation of cyclic electron flow around PSI in kowhy1 mutant led to the increase of PS I activity [24]. NDH is a large multi-protein complex containing more than 30 subunits which are encoded by both nucleus and organelle genomes. It has a key function in one of the CET (cyclic electron transport around photosystem I) pathways [31]. We then examined whether NDH subunits of membrane subcomplex and subcomplex A encoded by organelle genomes were affected by WHY1. qPCR analysis showed that the expression level of NDHA, NDHB, NDHC, NDHE, NDHG, and NDHJ were increased by more than 1.5-fold in the oepnWHY1 mutant, while the transcripts of NDHD, NDHF, NDHH, and NDHI were almost invariable (Figure 4). The expression of these genes was steady in both oepWHY1 and ko1/3 mutants while the expression of NDHE was slightly increased in kowhy1 mutant (Figure 4). These results raise the possibility that WHY1 may affect the activity or the formation of the NDH complex by regulating NDH gene expression.

2.5. NDH Activity and the Accumulation of NDH18 Were Changed in WHY1 Mutants

To further examine the effect of WHY1 on NDH activity, in vivo measurement of NDH activity was applied in lhca1, kowhy1, lhca1why1, ndho, and oepWHY1 mutants and wild-type plants. ndho mutant lacked the peptides encoded by the nuclear gene NDHO (At1g74880) [32]. A post illumination rise in chlorophyll fluorescence of five-week-old rosette leaves was determined by using a PAM chlorophyll fluorometer. After illumination for 5 min with actinic light (ACT; 200 μmol m−2 s−1), transient increases in chlorophyll fluorescence in dark were recorded as an indicator of NDH activity (Figure 5A, see Section 4). As showed in Figure 5, absence of NDHO leads to a loss of NDH activity. Moreover, NDH activities were declined in lhca1, kowhy1, and lhca1why1 mutants, but increased in oepWHY1 line compared to wild-type (Figure 5A,B). These results suggest that WHY1 and LHCA1 can affect NDH activity.
We next examined the association of WHY1 with NDH-PSI super complex. The blue-native polyacrylamide gel electrophoresis (BN-PAGE) of thylakoid membrane protein from PWHY1-HA in lhca1 background (lhca1/PWHY1-HA), kowhy1, oepWHY1-HA, and PWHY1-HA mutants were conducted using the NDH18 protein (a NAD(P)H dehydrogenase) as a representation to detect the NDH-PSI supercomplex [33,34]. Surprisingly, the PSI+LHCI complex protein was declined in kowhy1 and lhca1 mutants (Figure 5C) and was only detected in PWHY1-HA line. By 2D gel, the result further showed that NDH protein accumulation was decreased in kowhy1 mutant and the monomeric NDH was increased in lhca1 mutant, and LHCA4 protein was disappeared in the lhca1 mutant (Figure 5D,E). This indicated that loss of WHY1 blocked NDH18 accumulation while loss of LHCA1 and LHCA4 enhanced NDH18 and monomeric NDH accumulation. It might suggest that both WHY1 and LHCA1 affect the composition of NDH-PSI super complex and the super complex structure, but WHY1 or LHCA1 does not affect the same subunit of NDH-PSI.

2.6. WHIRLY Proteins Alter the Photosynthetic Performances after High Light Treatment

Cyclic electron flow around photosystem I (PSI) seems to prevent photoinhibition of photosystem I [35]. As reported in previous studies, WHY1 was involved in the alteration of ETR as well as gene expression, activity and formation of the NDH complex which both are related to cyclic electron transport. To further investigate the effects of WHY1 in photoinhibition, kowhy1, ko1/3, and wild-type plants grown for four weeks under normal light condition were transferred for 1, 2, 3, and 4 h to high light conditions (800 μmol m−2 s−1). Image-PAM was used to determine the chlorophyll fluorescence parameters. Under normal light conditions (80 μmol m−2 s−1), photochemical quenching (qP), quantum efficiency of PSII (ΦPSII) and maximum efficiency of PSII (Fv/Fm) were similar in wild-type plants and the mutants (kowhy1 and ko1/3) (Figure S3). The non-photochemical quenching (qN and NPQ) were lower in kowhy1 and ko1/3 mutants compared to wild-type while the electron transport rate (ETR) was higher in these mutants (Figure 6 and Figure S3). Hence, the photosynthetic parameters were similar in both young and senescent leaves of kowhy1 mutant (Figure 1 and Figure 6).
Under high light conditions, qP and ΦPSII were similarly decreased in all lines while NPQ and qN were increased. Therefore, the linear electron transport of photosynthesis was inhibited and the more excessive excitation energy was produced in all plants under high light conditions [36]. qP and ΦPSII were similar in kowhy1, ko1/3, and wild-type plants. Interestingly, NPQ and qN were also similar in kowhy1 and ko1/3 mutants compared to wild-type after high light treatment, while they were lower in kowhy1 and ko1/3 mutants compared to wild-type under normal light conditions. However, the ETR in kowhy1 and ko1/3 plants were lower than wild-type after 2 or 3 h high light treatments respectively (Figure 6), implying that electron transport of photosynthesis, especially the cyclic electron transport of Photosystem I, was inhibited in WHY mutants under high light conditions. Therefore, WHY1 may be involved in light adaption by regulating the electron transportation of photosynthesis.

2.7. WHIRLY Proteins Affect the Expression of Photosynthesis Related Genes under High Light Condition

To further confirm the role of WHY1 in electron transport after high light treatment, we examined the expression of numerous genes encoding LHCI complex, PSI core complex, and NDH complex by qPCR. Under normal light condition, there were little differences in the expression levels of PSI-related genes between kowhy1 and wild-type, while PsaA was down-regulated in ko1/3 mutant (Figure 7). However, after high light treatment, the expression level of PsaA was higher in kowhy1 than in wild-type, while they were similar in ko1/3 and wild-type plants. Transcription level of PsaC was increased only in ko1/3 line, which may imply a relationship in function between WHY1 and WHY3. PsaA and PsaB can form hydrophobic interaction site of the PSI core for efficient docking of the electron transfer donors [37]. NDHB, which has been reported to have a relation with CET in cyanobacterium [38], was up-regulated in kowhy1 and ko1/3 mutants (Figure 7). The rates of PSI cyclic electron transport in ndhb mutant of Cyanobacterium Synechocystis were decreased after dark treatment but increased after exposure to high light, compared to the wild-type [38]. WRKY22 and BCH2 (BETA CAROTENOID HYDROXYLASE 2), which were repressed and induced by high light, were used as the negative and positive control, respectively [39,40]. The expression levels of WRKY22 and BCH2 in kowhy1 and ko1/3 mutants were similar to wild-type under high light.
Further, mutation of WHY1 led to the increased expression level of ERF109 and ERF13 compared to wild-type plants in response to high light treatment (Figure 7). ERF13 is a CE1 (coupling element 1) binding protein and confers ABA hypersensitivity in Arabidopsis [41]. ERF109 (RRTF) was induced by singlet oxygen and increased in response to JA [42,43]. ERF109 enhances the defense responses to high light (HL) stress in young leaves, while it induces senescence and chlorosis in older leaves [44]. Moreover, the expression of Calcineurin B-Like-Interacting Protein Kinase14 (CIPK14, also named SR1) and WHY1 targeted genes included PRXCB and MYB38 were also detected [21,28]. The transcription level of SR1 that interacts with and phosphorylates WHY1 to increase its accumulation in the nucleus was similar in kowhy1, ko1/3, and wild-type plants under high light conditions. Previous studies showed PRXCB is a peroxidase regulated by light [45] and MBY38 functions as a positive element in blue light signaling [46]. Their expression level was steady in WHY mutants and wild-type plants under high light conditions. Collectively, these findings suggest that WHY1 may affect PSI-NDH complex formation and is involved in the plant hormone response pathways during light adaptation.

3. Discussion

In chloroplasts, WHY1 were found to associate with nucleoids [14,15,47], but only a minor part of WHY1 colocalizes with cp nucleoids that was showed by high-resolution imaging [48]. The elusive and complex localization of WHIRLY may represent its multifunctionality. WHY1 is located at the boundary between thylakoids and nucleoids, where are attractive to a protein that may link the operation of the photosynthetic electron transport chain to gene expression [8]. In addition, HvWHY1 RNAi mutants have delayed senescence phenotype under high light irradiation while that was not observed under normal light and dark. Therefore, WHY1 was proposed to closely associate with the components of thylakoid electron chain and is related to photosynthesis and the perception of light intensity [8]. However, the relationship of WHY1 and photosynthesis as well as light is not yet clear. The results of this study showed photosynthetic performance was affected in WHY1 knock out mutant under different light conditions. Furthermore, WHY1 were found to interact with LHCA1 in chloroplasts and affect the expression of photosystem I-LHCI and NDH encoding genes, which were consistent with the alternation of NDH activity and structure in kowhy1 mutant.
In this study, higher Y(I) in kowhy1 mutant demonstrated an elevated redox rate of P700 caused by the lack of WHY1 at an early stage of leaf senescence (Figure 1). The lower NPQ and higher ETR implied that a proton gradient across the thylakoid membrane formed was affected in the kowhy1 mutant [36]. However, the similar photochemical quantum yield of photosystem II Y(II) in WHY1 mutants and wild-type plants showed linear electron transport of photosynthesis, which is related to photosystem II activity may not be affected by WHY1 [49]. The lower NPQ in kowhy1 plants may be a mechanism to up-regulate photosynthetic electron transport [50]. Under high light conditions, in accordance with barley, the ETR in Arabidopsis kowhy1 and ko1/3 mutants was lower than in wild-type (Figure 6), while the NPQ were similar in kowhy1, ko1/3 and wild-type plants. It is possible that self-protective machinery of kowhy1 and ko1/3 mutants, by dissipating the excessive excitation energy harmlessly as heat, is also operating under short-time high radiation instead of lowering NPQ to rescue the ETR inhibited in kowhy1 and ko1/3. Therefore, WHY1 in chloroplasts may have a positive role in photosynthetic electron transport.
Mutants analysis of photosystem I subunits showed that deficiencies in photosynthesis promote the induction of leaf senescence [3]. Interestingly, overexpression of WHY1 in chloroplasts accelerated leaf senescence (Lin et al., 2017, unpublished data). Unexpectedly, overexpressing plastid-localized WHY1 (pWHY1) does not alter the expression level of genes encoding the PSI core complex and PSI external antenna, and that of plastid genes encoding the NDH complex. However, WHY1 is able to physically interact with LHCA1 (Figure 2), which belongs to the light harvesting complex of photosystem I [30]. It is just consistent with the phenomena that the WHIRLY protein was not detected in all cp nucleoids and punctate immunofluorescence signals were also observed in extra-nucleoid (stroma) regions in the zygote of C. reinhardtii, K. flaccidum, and M. Polymorpha plants [48]. LHCA1 was located closely to PsaG of the core complex and proposed serving as an anchor for the binding of the whole LHCI to one side of the PSI core complex [29,30]. Specific location of each LHCA protein within the PSI-LHCI super complex is important to excitation energy trapping [51]. A previous study showed that an Arabidopsis thaliana Phloem Intercalated with Xylem-like 1 (AtPXL1) protein interacts with and phosphorylates LHCA1 in the regulation of signal transduction pathways under temperature fluctuations [52]. Thereby, we hypothesize that the interaction of WHY1 and LHCA1 may have effects on the structure and function of the photosynthetic apparatus and is involved in the signal transduction between chloroplasts and nucleus during leaf development and responds to various stresses. Alternatively, WHY1 in chloroplast may have a protective effect on photosystem I that was similar to the function of PsaG, which changes the conformation of PSI and thereby allows higher electron transfer under high light or other photoinhibitory conditions [53].
In addition, overexpression of WHY1 in both nucleus and plastid improved the transcription level of a number of genes encoding PSI core subunits which are essential to the formation of super complexes of PSI [27,37] (Figure 1B) and multiple NDH genes encoded by the plastid genome (Figure 4). However, the expression of those genes was not affected by overexpression of pWHY1 in plastids. Hence, WHY1 might not regulate the NDH-PSI super complex genes directly in transcriptional level, but have a role in the formation of NDH-PSI super complex. The formation of the NDH-PSI super complex is necessary for the stability of NDH, especially under high-light conditions [34]. NDH complexes contain homologs of the subunits of mitochondria complex I and eubacterial NADH dehydrogenase and are also equipped with different “catalytic” domains, suggesting that they probably utilize different substrates as electron donors [34]. Loss of WHY1 and LHCA1 leads to the decline of NDH activity (Figure 5A) and inhibit NDH-PSI supercomplex accumulation (Figure 5D,E). Therefore, WHY1 protein located in chloroplasts and interaction with LHCA1 may facilitate the stability of the NDH-PSI supercomplex. Moreover, WHY1 protein may act as a coordinator between chloroplasts and nucleus and affect the NDH-dependent cyclic electron transport around photosystem I in a manner depending on hormone signal response since the expression of several hormone-related genes was varied in WHY1 mutated plants (Figure 7) [17].

4. Materials and Methods

4.1. Plant Materials and Growth Conditions

All plants used in this study were Arabidopsis thaliana (L.) Heynold ecotype Columbia 0 background. The WHY1 knock-out line (kowhy1) that has a T-DNA insertion in exon1 (SALK_023713) and the LHCA1 knock-out line that T-DNA inserted in the first exon (lhca1, SAIL_870_E09) were received from NASC (Nottingham, UK). The homozygous line was selected by PCR using the primers provided by the Salk Institute (http://signal.salk.edu/) [54]. WHY1 lines including oepnWHY1, oepWHY1, Pwhy1 were prepared from the former work [21]. The WT/why1 line was the kowhy1 line crossing with wild-type plants and the double why1lhca1 mutant was the kowhy1 line crossing with the lhca1 line, and they were identified by qRT-PCR. Seeds of WHY1 and WHY3 double mutant (ko1/3) were kindly provided by Prof. Normand Brisson, Department of Biochemistry, Montreal University, Montreal, Canada. Seeds of these mutants and wild-type were grown in a growth chamber at 23 °C with 13 h light condition (100 μmol m−2 s−1). For high light treatment, seeds of kowhy1, ko1/3 and wild-type were grown for 4 weeks at 23 °C with 13 h light condition (80 μmol m−2 s−1) and then transferred to high light conditions (800 μmol m−2 s−1) for 1, 2, 3, and 4 h.

4.2. Analysis of Photosynthetic Parameters

Seven-week-old Arabidopsis wild-type plants and the T-DNA insertion mutant of At-WHY1 were grown in a controlled growth chamber at a photon irradiance of 100 μmol m−2 s−1. A Dual PAM 100 measuring system (Walz, Effeltrich, Germany) with a Dual-DR and a Dual-E measuring head was used for simultaneous measurement of chlorophyll fluorescence and P700 oxidation. Two leaves of each plant and five plants of each line were used for the measurements. According to the method described in http://www.walz.com/products/chl_p700/dual-pam-100/applications.html, experiments were carried out by using the automated Induction and Recovery Curve routine provided by the Dual-PAM software, with repetitive application of saturation pulses (SP) for assessment of fluorescence and P700 parameters, from which the quantum yields of PS I and PS II were derived by the software. The measuring mode was set up for P700 and fluorescence analyses mode is SP analysis, induction curve was recorded, light intensity 125 μmol m−2 s−1, total collection time 6 min, SP duration time is 5 min. The max data of Y(I), Y(II), and Y(NPQ) were used deduced form the data collected. Initial parameters of Photosystem II fluorescence including dark fluorescence yield (F0) and maximal fluorescence yield (Fm) in plants were measured after dark adaptation for 15 min The calculation of quantum yields of Photosystem I Y(I), Photosystem II Y(II) and non-photochemical quenching of photosystem II fluorescence (NPQ) were performed with equations [55,56]. Electron transport rates (ETR) were calculated and recorded by the Dual-PAM software [57,58].
For high light treatment, plants were transferred from normal light condition (80 μmol m−2 s−1) to high light conditions (800 μmol m−2 s−1) for 1, 2, 3, and 4 h. The chlorophyll fluorescence parameters in high light treatment were measured using IMAGING-PAM MAXI (Heinz Walz GmbH, Effeltrich, Germany) after dark-adaptation for 15 min as described by Shao [59]. Fully expanded leaves were selected for measurement and were placed onto a block with wet blotting paper. An area of interest with a diameter of 1 cm was selected in the middle of the whole leaf to record chlorophyll fluorescence parameters. Data of the maximum quantum yield of PSII (Fv/Fm) that represents the maximum quantum yield of PSII, the quantum yield of PSII (ΦPSII), photochemical fluorescence quenching coefficients in PSII (qP) that is a measure of the overall openness of the reaction center, non-photochemical quenching (NPQ and qN), and ETR were exported from IMAGING-PAM software. Photochemical (qP) and no-photochemical quenching (NPQ, qN) are protective mechanisms to photosynthetic machinery via balancing light utilization [24].

4.3. Quantitative Real-Time PCR

Total RNA was isolated according to the manufacturer’s protocol of TransZol UP (TransGen Biotech, Beijing, China). First-strand cDNA was generated from 1μg of total RNA using TranScript one-step gDNA removal and cDNA synthesis supermix kit (AT311, TRANSGEN), following the instruction. qPCR was performed to analyze the expression of genes in the CFX96 machine (Bio-Rad Company, Hercules, CA, USA) in a whole volume of 15 μL, including 2 μL of 2× UltraSYBR Mixture (cw0956c, CoWin Biosciences, Beijing, China), 0.5 μL of each gene-specific primer (10 μm). To determine the relative expression rate, data were normalized to the expression level of wild-type or in five-week-old plants (which were set to 1) after normalized to the internal GAPC2 gene control. Three technical replicates of three biological replicates and the determination of a melting curve of the amplified PCR products were carried out. Primers used for qPCR were listed in Table S1 (In Supplementary).

4.4. Yeast Two-Hybrid System Screen and Confirmation

The activation domain of the full length WHY1 cDNA was deleted, and the truncated cDNA was cloned into the bait pGBKT7 vector, and screened the cDNA expression library that was prepared from five-week-old rosette leaves of Arabidopsis according to the method described by Miao and Zentgraf [60]. The two-hybrid assays were performed as described in Clontech’s Matchmaker GAL4 Two-Hybrid System 3 manual. WHY1 and LHCA1 with full-length cDNA sequences were cloned into prey vectors. The truncated version of WHY1 lacking the activated domain and full-length cDNA sequences encoding LHCA1 were inserted in the bait construct, respectively. These recombinant plasmids were introduced into yeast strain Y187 containing LacZ gene. X-gal agarose overlay assay were performed according to the protocol (http://biochemistry.ucsf.edu/~herskowitz/protocols.html) using o-nitrophenyl β-galactopyranoside as substrate.

4.5. Immunological Analyses

Proteins were extracted from rosette leaves according to Miao et al. [61]. Equal amounts of proteins (8–25 μg) determined according to Bradford method [62] were subjected to SDS-PAGE on 14% (w/v) polyacrylamide gels [63], and separated proteins were transferred to nitrocellulose by semi-dry electroblotting [61]. After incubation with the primary antibody and secondary antiserum in turn, immunoreactions were detected with a chemiluminescent substrate (GE Healthcare, Chalfont St. Giles, Buckinghamshire, UK). Primary antibodies directed toward the HA-tag oligopeptides (Sigma, Munich, Germany) and the 14kD histone H2B (Cell Signaling, Munich, Germany), all other antibodies were purchased from Agrisera, Sweden. GFP specific antibody was purchased from Roche Diagnostics GmbH Germany (Mannheim, Germany).

4.6. Coimmunoprecipitation of Photosystem I Complex Proteins

A crude fraction of chloroplasts was prepared from the seventh leaves of 5-week-old Arabidopsis plants referred to the method of Poulsen [64]. Plastids were osmotically lysed and fractions were obtained after centrifugation at 20,000× g for 10 min. Thylakoids employed for isolation of super molecular complexes were prepared and stored at −80 °C in buffer with 50% (v/v) glycerol [65,66]. After solubilization of thylakoids by 0.02% or 0.5% (w/v) dodecyl-α-d-maltoside [67,68], complexes were separated on continuous 0.2–1.0 M sucrose density gradients containing 0.02% or 0.5% dodecyl-α-d-maltoside and 10 mM Hepes by centrifugation in a Beckman (Indianapolis, IN, USA) Ti 41.14 rotor for 24 h at 200,000× g at 4 °C.
The photosystem I containing thylakoid membrane fractions were incubated with the HA-tag peptide antibody at 4 °C for one hour on a rotating wheel. After the addition of protein A beads, the mixture was incubated likewise for one hour and then centrifuged at 7000 rpm for 20 s. Protein A beads were washed three times with buffer (50 mM Tris-HCl including 0.1% nonidet P-40, pH 8.0) and then resuspended in SDS-PAGE loading buffer.

4.7. Bimolecular Fluorescence Complementation Assay (BiFC)

The plasmid of the full length AtWHY1 sequence fused to GFP was available [69]. The full-length AtLHCA1 coding sequence was amplified by PCR from NASC cDNA clone U12182 and was cloned in frame in front of the GFP coding sequence using the binary gateway vector pBatTL-B.GFP2 containing a double 35S promoter. The full length AtWHY1 and AtLHCA1 cDNA were cloned to pHA-GFPn173c vector and pcMYC-GFPc155c vector via XbaI/KpnI, respectively [60]. Both appropriate plasmids were introduced to onion epidermal cells with the biolistic bombardment method [69]. GFP-dependent fluorescence was observed using an epifluorescence microscope (Axiophot, Zeiss, Jena, Germany) and a Leica SP8 confocal laser scanning microscope (Leica, Heidelberg, Germany). For immunological analysis of proteins, 200 mg of onion epidermal tissue were extracted 24–48 h after transformation.

4.8. In Vivo Measurements of NDH Activity

NDH activity of five-week-old rosette leaves from different mutants and WT were measured using a PAM chlorophyll fluorometer according to Peng (2009) [33]. The plants were illuminated for 5 min with actinic light (ACT; 200 μmol m−2 s−1). After illumination, the fluorescence rise of the F0 level due to electron donation to PQ via NDH in dark after switching off the actinic light is taken as a measure of the NDH activity, which was monitored as the subsequent transient increase in chlorophyll fluorescence [33,70,71,72]. The transient increase in chlorophyll fluorescence in mutants was quantified by comparing the peak area with that of WT during 1 min. The peak area of WT was set as 1.

4.9. Separation of Photosynthetic Complexes by Blue-Native Polyacrylamide Gel Electrophoresis (BN-PAGE)

Leaf samples were immediately frozen by liquid nitrogen after harvest. Thylakoid membranes were isolated at 4 °C according to Li et al. (2010), and BN-PAGE and 2D SDS-PAGE were performed as previously described [73]. An equal amount of supernatant equivalent to 10 μg of Chls was subjected to BN-PAGE with a 4–20% gradient gel. Electrophoresis was carried out for 3 h at 30 mA at 4 °C.

Supplementary Materials

Supplementary materials can be found at www.mdpi.com/1422-0067/18/11/2352/s1.

Acknowledgments

We acknowledge Karin Krupinska for the discussion of plastid biology and Wolfgang Bilger (University of Kiel) on the Dual-PAM-100-Measuring system. We acknowledge Toshiharu Shikanai (Kyoto University) for providing the antibody against NDH18 protein. Ziwei Zhao and Carlotta Ober-Blöbaum (University of Kiel) crossed lhca1 with kowhy1 and screened the double mutants. This work was supported by a grant of the German Research Foundation (MI1392/1-1) and a grant from NSFC (31470383).

Author Contributions

Ying Miao designed the research; Ying Miao performed yeast two hybridization, BiFC and CoIP; Wenfang Lin performed the protein blue native gel and protein immuno-detection; Dongmei Huang and Ban Deng performed qPCR and photosystem performance analysis; Yujun Ren helped to analyze the data; Dongmei Huang and Ying Miao analyzed data and wrote the paper.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Pfannschmidt, T.; Nilsson, A.; Allen, J.F. Photosynthetic control of chloroplast gene expression. Nature 1999, 397, 625–628. [Google Scholar]
  2. Moseley, J.L.; Allinger, T.; Herzog, S.; Hoerth, P.; Wehinger, E.; Merchant, S.; Hippler, M. Adaptation to Fe-deficiency requires remodeling of the photosynthetic apparatus. EMBO J. 2002, 21, 6709–6720. [Google Scholar] [CrossRef] [PubMed]
  3. Wang, J.; Leister, D.; Bolle, C. Photosynthetic lesions can trigger accelerated senescence in Arabidopsis thaliana. J. Exp. Bot. 2015, 66, 6891–6903. [Google Scholar] [CrossRef] [PubMed]
  4. Chi, W.; Sun, X.; Zhang, L. Intracellular signaling from plastid to nucleus. Annu. Rev. Plant Biol. 2013, 64, 559–582. [Google Scholar] [CrossRef] [PubMed]
  5. Larkin, R.M.; Ruckle, M.E. Integration of light and plastid signals. Curr. Opin. Plant Biol. 2008, 11, 593–599. [Google Scholar] [CrossRef] [PubMed]
  6. Gollan, P.J.; Tikkanen, M.; Aro, E.M. Photosynthetic light reactions: Integral to chloroplast retrograde signalling. Curr. Opin. Plant Biol. 2015, 27, 180–191. [Google Scholar] [CrossRef] [PubMed]
  7. De Barajas-López, J.D.; Blanco, N.E.; Strand, Å. Plastid-to-nucleus communication, signals controlling the running of the plant cell. Biochim. Biophys. Acta 2013, 1833, 425–437. [Google Scholar] [CrossRef] [PubMed]
  8. Foyer, C.H.; Karpinska, B.; Krupinska, K. The functions of WHIRLY1 and REDOX-RESPONSIVE TRANSCRIPTION FACTOR 1 in cross tolerance responses in plants: A hypothesis. Philos. Trans. R. Soc. Lond. B Biol. Sci. 2014, 369, 20130226. [Google Scholar] [CrossRef] [PubMed]
  9. Pfannschmidt, T. Plastidial retrograde signalling—A true “plastid factor” or just metabolite signatures? Trends Plant Sci. 2010, 15, 427–435. [Google Scholar] [CrossRef] [PubMed]
  10. Grabowski, E.; Miao, Y.; Mulisch, M.; Krupinska, K. Single-stranded DNA-binding protein Whirly1 in barley leaves is located in plastids and the nucleus of the same cell. Plant Physiol. 2008, 147, 1800–1804. [Google Scholar] [CrossRef] [PubMed]
  11. Krupinska, K.; Haussuhl, K.; Schafer, A.; van der Kooij, T.A.; Leckband, G.; Lorz, H.; Falk, J. A novel nucleus-targeted protein is expressed in barley leaves during senescence and pathogen infection. Plant Physiol. 2002, 130, 1172–1180. [Google Scholar] [CrossRef] [PubMed]
  12. Desveaux, D.; Maréchal, A.; Brisson, N. Whirly transcription factors: Defense gene regulation and beyond. Trends Plant Sci. 2005, 10, 95–102. [Google Scholar] [CrossRef] [PubMed]
  13. Pfalz, J.; Liere, K.; Kandlbinder, A.; Dietz, K.J.; Oelmuller, R. pTAC2, -6, and -12 are components of the transcriptionally active plastid chromosome that are required for plastid gene expression. Plant Cell 2006, 18, 176–197. [Google Scholar] [CrossRef] [PubMed]
  14. Marechal, A.; Parent, J.S.; Veronneau-Lafortune, F.; Joyeux, A.; Lang, B.F.; Brisson, N. Whirly proteins maintain plastid genome stability in Arabidopsis. Proc. Natl. Acad. Sci. USA 2009, 106, 14693–14698. [Google Scholar] [CrossRef] [PubMed]
  15. Cappadocia, L.; Marechal, A.; Parent, J.S.; Lepage, E.; Sygusch, J.; Brisson, N. Crystal structures of DNA-Whirly complexes and their role in Arabidopsis organelle genome repair. Plant Cell 2010, 22, 1849–1867. [Google Scholar] [CrossRef] [PubMed]
  16. Lepage, E.; Zampini, E.; Brisson, N. Plastid genome instability leads to reactive oxygen species production and plastid-to-nucleus retrograde signaling in Arabidopsis. Plant Physiol. 2013, 163, 867–881. [Google Scholar] [CrossRef] [PubMed]
  17. Kucharewicz, W.; Distelfeld, A.; Bilger, W.; Muller, M.; Munne-Bosch, S.; Hensel, G.; Krupinska, K. Acceleration of leaf senescence is slowed down in transgenic barley plants deficient in the DNA/RNA-binding protein WHIRLY1. J. Exp. Bot. 2017, 68, 983–996. [Google Scholar] [CrossRef] [PubMed]
  18. Ruckle, M.E.; Burgoon, L.D.; Lawrence, L.A.; Sinkler, C.A.; Larkin, R.M. Plastids are major regulators of light signaling in Arabidopsis. Plant Physiol. 2012, 159, 366–390. [Google Scholar] [CrossRef] [PubMed]
  19. Comadira, G.; Rasool, B.; Kaprinska, B.; Garcia, B.M. WHIRLY1 Functions in the Control of Responses to Nitrogen Deficiency but Not Aphid Infestation in Barley. Plant Physiol. 2015, 168, 1140–1151. [Google Scholar] [CrossRef] [PubMed]
  20. Gregersen, P.L.; Foyer, C.H.; Krupinska, K. Photosynthesis and Leaf Senescence as Determinants of Plant Productivity. In Biotechnological Approaches to Barley Improvement; Kumlehn, J., Stein, N., Eds.; Springer: Berlin/Heidelberg, Germany, 2014; pp. 113–138. [Google Scholar]
  21. Miao, Y.; Jiang, J.; Ren, Y.; Zhao, Z. The single-stranded DNA binding protein WHIRLY1 represses WRKY53 expression and delays leaf senescence in a developmental stage-dependent manner in Arabidopsis thaliana. Plant Physiol. 2013, 163, 746–756. [Google Scholar] [CrossRef] [PubMed]
  22. Tikkanen, M.; Rantala, S.; Grieco, M.; Aro, E.M. Comparative analysis of mutant plants impaired in the main regulatory mechanisms of photosynthetic light reactions—From biophysical measurements to molecular mechanisms. Plant Physiol. Biochem. 2017, 112, 290–301. [Google Scholar] [CrossRef] [PubMed]
  23. Benson, S.L.; Maheswaran, P.; Ware, M.A.; Hunter, C.N.; Horton, P.; Jansson, S.; Ruban, A.V.; Johnson, M.P. An intact light harvesting complex I antenna system is required for complete state transitions in Arabidopsis. Nat. Plants 2015, 1, 15176. [Google Scholar] [CrossRef] [PubMed]
  24. Tongra, T.; Bharti, S.; Jajoo, A. Cyclic electron flow around photosystem I is enhanced at low pH. Plant Physiol. Biochem. 2014, 83, 194–199. [Google Scholar] [CrossRef] [PubMed]
  25. Croce, R.; Morosinotto, T.; Castelletti, S.; Breton, J.; Bassi, R. The Lhca antenna complexes of higher plants photosystem I. Biochim. Biophys. Acta 2002, 1556, 29–40. [Google Scholar] [CrossRef]
  26. Wientjes, E.; Oostergetel, G.T.; Jansson, S.; Boekema, E.J.; Croce, R. The role of Lhca complexes in the supramolecular organization of higher plant photosystem I. J. Biol. Chem. 2009, 284, 7803–7810. [Google Scholar] [CrossRef] [PubMed]
  27. Busch, A.; Hippler, M. The structure and function of eukaryotic photosystem I. Biochim. Biophys. Acta 2011, 1807, 864–877. [Google Scholar] [CrossRef] [PubMed]
  28. Ren, Y.; Li, Y.; Jiang, Y.; Wu, B.; Miao, Y. Phosphorylation of WHIRLY1 by CIPK14 Shifts Its Localization and Dual Functions in Arabidopsis. Mol. Plant 2017, 10, 749–763. [Google Scholar] [CrossRef] [PubMed]
  29. Amunts, A.; Drory, O.; Nelson, N. The structure of a plant photosystem I supercomplex at 3.4 A resolution. Nature 2007, 447, 58–63. [Google Scholar] [CrossRef] [PubMed]
  30. Jensen, P.E.; Bassi, R.; Boekema, E.J.; Dekker, J.P.; Jansson, S.; Leister, D.; Robinson, C.; Scheller, H.V. Structure, function and regulation of plant photosystem I. Biochim. Biophys. Acta 2007, 1767, 335–352. [Google Scholar] [CrossRef] [PubMed]
  31. Kouril, R.; Strouhal, O.; Nosek, L.; Lenobel, R.; Chamrad, I.; Boekema, E.J.; Sebela, M.; Ilik, P. Structural characterization of a plant photosystem I and NAD(P)H dehydrogenase supercomplex. Plant J. 2014, 77, 568–576. [Google Scholar] [CrossRef] [PubMed]
  32. Rumeau, D.; Becuwe-Linka, N.; Beyly, A.; Louwagie, M.; Garin, J.; Peltier, G. New subunits NDH-M, -N, and -O, encoded by nuclear genes, are essential for plastid NDH complex functioning in higher plants. Plant Cell 2005, 17, 219–232. [Google Scholar] [CrossRef] [PubMed]
  33. Peng, L.; Fukao, Y.; Fujiwara, M.; Takami, T.; Shikanai, T. Efficient operation of NAD(P)H dehydrogenase requires supercomplex formation with photosystem I via minor LHCI in Arabidopsis. Plant Cell 2009, 21, 3623–3640. [Google Scholar] [CrossRef] [PubMed]
  34. Peng, L.; Shikanai, T. Supercomplex formation with photosystem I is required for the stabilization of the chloroplast NADH dehydrogenase-like complex in Arabidopsis. Plant Physiol. 2011, 155, 1629–1639. [Google Scholar] [CrossRef] [PubMed]
  35. Roach, T.; Krieger-Liszkay, A. Regulation of photosynthetic electron transport and photoinhibition. Curr. Protein Pept. Sci. 2014, 15, 351–362. [Google Scholar] [CrossRef] [PubMed]
  36. Chuang-Dao, J.; Hul-Yuan, G.; Qi, Z.; Lei, S. Effects of Iron Deficiency on Photosynthesis and Photosystem II Function in Soybean Leaf. J. Plant Physiol. Mol. Biol. 2007, 1, 53–60. [Google Scholar]
  37. Scheller, H.V.; Jensen, P.E.; Haldrup, A.; Lunde, C.; Knoetzel, J. Role of subunits in eukaryotic Photosystem I. Biochim. Biophys. Acta 2001, 1507, 41–60. [Google Scholar] [CrossRef]
  38. Thomas, D.J.; Thomas, J.; Youderian, P.A.; Herbert, S.K. Photoinhibition and light-induced cyclic electron transport in ndhB- and psaE- mutants of Synechocystis sp. PCC 6803. Plant Cell Physiol. 2001, 42, 803–812. [Google Scholar] [CrossRef] [PubMed]
  39. Rossel, J.B.; Wilson, I.W.; Pogson, B.J. Global changes in gene expression in response to high light in Arabidopsis. Plant Physiol. 2002, 130, 1109–1120. [Google Scholar] [CrossRef] [PubMed]
  40. Zhou, X.; Jiang, Y.; Yu, D. WRKY22 transcription factor mediates dark-induced leaf senescence in Arabidopsis. Mol. Cells 2011, 31, 303–313. [Google Scholar] [CrossRef] [PubMed]
  41. Lee, S.J.; Park, J.H.; Lee, M.H.; Yu, J.H.; Kim, S.Y. Isolation and functional characterization of CE1 binding proteins. BMC Plant Biol. 2010, 10, 277. [Google Scholar] [CrossRef] [PubMed]
  42. Gonzalez-Perez, S.; Gutierrez, J.; Garcia-Garcia, F.; Osuna, D.; Dopazo, J.; Lorenzo, O.; Revuelta, J.L.; Arellano, J.B. Early transcriptional defense responses in Arabidopsis cell suspension culture under high-light conditions. Plant Physiol. 2011, 156, 1439–1456. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  43. Wang, Z.; Cao, G.; Wang, X.; Miao, J.; Liu, X.; Chen, Z.; Qu, L.J.; Gu, H. Identification and characterization of COI1-dependent transcription factor genes involved in JA-mediated response to wounding in Arabidopsis plants. Plant Cell Rep. 2008, 27, 125–135. [Google Scholar] [CrossRef] [PubMed]
  44. Matsuo, M.; Oelmuller, R. REDOX RESPONSIVE TRANSCRIPTION FACTOR1 is involved in age-dependent and systemic stress signaling. Plant Signal. Behav. 2015, 10, e1051279. [Google Scholar] [CrossRef] [PubMed]
  45. Passardi, F.; Tognolli, M.; De Meyer, M.; Penel, C.; Dunand, C. Two cell wall associated peroxidases from Arabidopsis influence root elongation. Planta 2006, 223, 965–974. [Google Scholar] [CrossRef] [PubMed]
  46. Hong, S.H.; Kim, H.J.; Ryu, J.S.; Choi, H.; Jeong, S.; Shin, J.; Choi, G.; Nam, H.G. CRY1 inhibits COP1-mediated degradation of BIT1, a MYB transcription factor, to activate blue light-dependent gene expression in Arabidopsis. Plant J. 2008, 55, 361–371. [Google Scholar] [CrossRef] [PubMed]
  47. Cappadocia, L.; Parent, J.S.; Sygusch, J.; Brisson, N. A family portrait: Structural comparison of the Whirly proteins from Arabidopsis thaliana and Solanum tuberosum. Acta Crystallogr. Sect. F Struct. Biol. Cryst. Commun. 2013, 69, 1207–1211. [Google Scholar] [CrossRef] [PubMed]
  48. Kobayashi, Y.; Takusagawa, M.; Harada, N.; Fukao, Y.; Yamaoka, S.; Kohchi, T.; Hori, K.; Ohta, H.; Shikanai, T.; Nishimura, Y. Eukaryotic Components Remodeled Chloroplast Nucleoid Organization during the Green Plant Evolution. Genome Biol. Evol. 2015, 8, 1–16. [Google Scholar] [CrossRef] [PubMed]
  49. Bertamini, M.; Muthuchelian, K.; Nedunchezhian, N. Iron deficiency induced changes on the donor side of PS II in field grown grapevine (Vitis vinifera L. cv. Pinot noir) leaves. Plant Sci. 2002, 162, 599–605. [Google Scholar] [CrossRef]
  50. Cui, Y.; Tian, Z.; Zhang, X.; Muhammad, A.; Han, H.; Jiang, D.; Cao, W.; Dai, T. Effect of water deficit during vegetative growth periods on post-anthesis photosynthetic capacity and grain yield in winter wheat (Triticum aestivum L.). Acta Physiol. Plant. 2015, 37, 196. [Google Scholar] [CrossRef]
  51. Ihalainen, J.A.; Klimmek, F.; Ganeteg, U.; van Stokkum, I.H.; van Grondelle, R.; Jansson, S.; Dekker, J.P. Excitation energy trapping in photosystem I complexes depleted in Lhca1 and Lhca4. FEBS Lett. 2005, 579, 4787–4791. [Google Scholar] [CrossRef] [PubMed]
  52. Jung, C.G.; Hwang, S.G.; Park, Y.C.; Park, H.M.; Kim, D.S.; Park, D.H.; Jang, C.S. Molecular characterization of the cold- and heat-induced Arabidopsis PXL1 gene and its potential role in transduction pathways under temperature fluctuations. J. Plant Physiol. 2015, 176, 138–146. [Google Scholar] [CrossRef] [PubMed]
  53. Jensen, P.E.; Rosgaard, L.; Knoetzel, J.; Scheller, H.V. Photosystem I activity is increased in the absence of the PSI-G subunit. J. Biol. Chem. 2002, 277, 2798–2803. [Google Scholar] [CrossRef] [PubMed]
  54. Alonso, J.M.; Stepanova, A.N.; Leisse, T.J.; Kim, C.J.; Chen, H.; Shinn, P.; Stevenson, D.K.; Zimmerman, J.; Barajas, P.; Cheuk, R.; et al. Genome-wide insertional mutagenesis of Arabidopsis thaliana. Science 2003, 301, 653–657. [Google Scholar] [CrossRef] [PubMed]
  55. Klughammer, C.; Schreiber, U. Saturation pulse method for assessment of energy conversion in PS I. PAM Appl. Notes 2008, 1, 11–14. [Google Scholar]
  56. Maxwell, K.; Johnson, G.N. Chlorophyll fluorescence—A practical guide. J. Exp. Bot. 2000, 51, 659–668. [Google Scholar] [CrossRef] [PubMed]
  57. Suzuki, K.; Ohmori, Y.; Ratel, E. High root temperature blocks both linear and cyclic electron transport in the dark during chilling of the leaves of rice seedlings. Plant Cell Physiol. 2011, 52, 1697–1707. [Google Scholar] [CrossRef] [PubMed]
  58. Wang, S.; Chen, F.; Mu, S.; Zhang, D.; Pan, X.; Lee, D.J. Simultaneous analysis of photosystem responses of Microcystis aeruginoga under chromium stress. Ecotoxicol. Environ. Saf. 2013, 88, 163–168. [Google Scholar] [CrossRef] [PubMed]
  59. Shao, L.; Shu, Z.; Peng, C.-L.; Lin, Z.-F.; Yang, C.-W.; Gu, Q. Enhanced sensitivity of Arabidopsis anthocyanin mutants to photooxidation: A study with fluorescence imaging. Funct. Plant Biol. 2008, 35, 714–724. [Google Scholar] [CrossRef]
  60. Miao, Y.; Zentgraf, U. The antagonist function of Arabidopsis WRKY53 and ESR/ESP in leaf senescence is modulated by the jasmonic and salicylic acid equilibrium. Plant Cell 2007, 19, 819–830. [Google Scholar] [CrossRef] [PubMed]
  61. Miao, Y.; Zentgraf, U. A HECT E3 ubiquitin ligase negatively regulates Arabidopsis leaf senescence through degradation of the transcription factor WRKY53. Plant J. 2010, 63, 179–188. [Google Scholar] [CrossRef] [PubMed]
  62. 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. [Google Scholar] [CrossRef]
  63. Fling, S.P.; Gregerson, D.S. Peptide and protein molecular weight determination by electrophoresis using a high-molarity tris buffer system without urea. Anal. Biochem. 1986, 155, 83–88. [Google Scholar] [CrossRef]
  64. Poulsen, C. The barley chloroplast genome: Physical structure and transcriptional activity in vivo. Carlsberg Res. Commun. 1983, 48, 57–80. [Google Scholar] [CrossRef]
  65. Caffarri, S.; Croce, R.; Breton, J.; Bassi, R. The major antenna complex of photosystem II has a xanthophyll binding site not involved in light harvesting. J. Biol. Chem. 2001, 276, 35924–35933. [Google Scholar] [CrossRef] [PubMed]
  66. Eshaghi, S.; Andersson, B.; Barber, J. Isolation of a highly active PSII-LHCII supercomplex from thylakoid membranes by a direct method. FEBS Lett. 1999, 446, 23–26. [Google Scholar] [CrossRef]
  67. Bassi, R.; Simpson, D. Chlorophyll-protein complexes of barley photosystem I. Eur. J. Biochem. 1987, 163, 221–230. [Google Scholar] [CrossRef] [PubMed]
  68. Gruissem, W.; Greenberg, B.M.; Zurawski, G.; Hallick, R.B. Chloroplast gene expression and promoter identification in chloroplast extracts. Methods Enzymol. 1986, 118, 253–270. [Google Scholar] [PubMed]
  69. Krause, K.; Kilbienski, I.; Mulisch, M.; Rödiger, A.; Schäfer, A.; Krupinska, K. DNA-binding proteins of the Whirly family in Arabidopsis thaliana are targeted to the organelles. FEBS Lett. 2005, 579, 3707–3712. [Google Scholar] [CrossRef] [PubMed]
  70. Bilger, W.; Heber, U.; Schreiber, U. Kinetic Relationship between Energy-Dependent Fluorescence Quenching, Light Scattering, Chlorophyll Luminescence and Proton Pumping in Intact Leaves. Z. Naturforsch. 1988, 43, 877–887. [Google Scholar]
  71. Peng, L.; Fukao, Y.; Fujiwara, M.; Shikanai, T. Multistep assembly of chloroplast NADH dehydrogenase-like subcomplex A requires several nucleus-encoded proteins, including CRR41 and CRR42, in Arabidopsis. Plant Cell 2012, 24, 202–214. [Google Scholar] [CrossRef] [PubMed]
  72. Shikanai, T.; Endo, T.; Hashimoto, T.; Yamada, Y.; Asada, K.; Yokota, A. Directed disruption of the tobacco ndhB gene impairs cyclic electron flow around photosystem I. Proc. Natl. Acad. Sci. USA 1998, 95, 9705–9709. [Google Scholar] [CrossRef] [PubMed]
  73. Li, J.; Pandeya, D.; Nath, K.; Zulfugarov, I.S.; Yoo, S.C.; Zhang, H.; Yoo, J.H.; Cho, S.H.; Koh, H.J.; Kim, D.S.; et al. ZEBRA-NECROSIS, a thylakoid-bound protein, is critical for the photoprotection of developing chloroplasts during early leaf development. Plant J. 2010, 62, 713–725. [Google Scholar] [CrossRef] [PubMed]
Figure 1. Analyses of the photosynthetic performance in leaves of the WHY1, lhca1 mutants and the wild-type plants by a Dual PAM (Pulse-amplitude modulation) device. Dual PAM measurements of photochemical yield of photosystem I Y(I) (A), yield of photosystem II Y(II) (B), electron transport rate (ETR) (C), and photosystem II fluorescence (NPQ) (D), respectively. Data presented are mean ± SE (n = 6–8). Significance analysis was performed by Tukey–Kramer method (p < 0.05) and the data were dividing into different significance groups.
Figure 1. Analyses of the photosynthetic performance in leaves of the WHY1, lhca1 mutants and the wild-type plants by a Dual PAM (Pulse-amplitude modulation) device. Dual PAM measurements of photochemical yield of photosystem I Y(I) (A), yield of photosystem II Y(II) (B), electron transport rate (ETR) (C), and photosystem II fluorescence (NPQ) (D), respectively. Data presented are mean ± SE (n = 6–8). Significance analysis was performed by Tukey–Kramer method (p < 0.05) and the data were dividing into different significance groups.
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Figure 2. Expression of photosystem I (PSI)-light harvest complexes (LHCI) encoded genes in WHY1 mutants and wild-type plants (A) Expression analysis of LHCI complex encoded genes in WHY1 mutants and wild-type plants by qPCR; (B) Expression analysis of PSI core complex encoded genes in WHY1 mutants and wild-type plants. The transcript level in each case was normalized to that of GAPC2 as a reference gene, and the expression level of WT was set as 1. Three biological replications were used to analyze. Asterisk indicate significant differences in gene expression compared to WT (Tukey–Kramer method, * p < 0.05, ** p < 0.01, *** p < 0.001).
Figure 2. Expression of photosystem I (PSI)-light harvest complexes (LHCI) encoded genes in WHY1 mutants and wild-type plants (A) Expression analysis of LHCI complex encoded genes in WHY1 mutants and wild-type plants by qPCR; (B) Expression analysis of PSI core complex encoded genes in WHY1 mutants and wild-type plants. The transcript level in each case was normalized to that of GAPC2 as a reference gene, and the expression level of WT was set as 1. Three biological replications were used to analyze. Asterisk indicate significant differences in gene expression compared to WT (Tukey–Kramer method, * p < 0.05, ** p < 0.01, *** p < 0.001).
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Figure 3. The interaction confirmation of WHY1 and LHCA1. (A) The interaction confirmation of WHY1 and LHCA1 by yeast two hybrid. Yeast two hybrid interaction detection growth selections and X-Gal agarose overlay assay indicate an interaction between WHY1 and LHCA1; (B) CoIP of WHY1 and LHCA1 from photosystem I containing thylakoid membrane complexes. As input to the thylakoid membrane fractions 1, 2, and 3 (see Supplementary Figure S1, 1, free pigments; 2, LHCII and photosystem II complexes; 3, photosystem I complexes) were used. Coimmunoprecipitation (CoIP) was performed with the antibody specific for the HA peptide. Precipitated proteins were separated by SDS-PAGE. Immunoreactions were performed with the antibody specific for LHCA1 (22 kD), followed by incubation with the antibody directed towards LHCA2 (23 kD), LHCA3 (25 kD), LHCA4 (22 kD), and LHCB1 (20 kD) as control; (C) Confirmation of the interaction of WHY1 and LHCA1 by bimolecular fluorescence complementation assays (BiFC). The onion epidermal cells were transiently transformed with the full length WHY1 and the full length LHCA1. Constructs were fused to either c-myc-GFPn173 or HA-GFPc155 and vice versa. The WHY1 and LHCA1 fused to full length GFP and empty vector were used as controls. All constructs were under the control of the 35S promoter. Fluorescence images are shown on the upside and bright field images are shown on the underside, respectively. C1: WHY1-GFPn173 + LHCA1-GFPc155; C2: LHCA1-GFPn173 + WHY1-GFPc155; C3: WHY1-GFP; C4: LHCA1-GFP; C5: WHY1-GFPn173 + LHCA4-GFPc155; C1-2: scale bar 21 μm; C3-5: scale bar 100 μm.
Figure 3. The interaction confirmation of WHY1 and LHCA1. (A) The interaction confirmation of WHY1 and LHCA1 by yeast two hybrid. Yeast two hybrid interaction detection growth selections and X-Gal agarose overlay assay indicate an interaction between WHY1 and LHCA1; (B) CoIP of WHY1 and LHCA1 from photosystem I containing thylakoid membrane complexes. As input to the thylakoid membrane fractions 1, 2, and 3 (see Supplementary Figure S1, 1, free pigments; 2, LHCII and photosystem II complexes; 3, photosystem I complexes) were used. Coimmunoprecipitation (CoIP) was performed with the antibody specific for the HA peptide. Precipitated proteins were separated by SDS-PAGE. Immunoreactions were performed with the antibody specific for LHCA1 (22 kD), followed by incubation with the antibody directed towards LHCA2 (23 kD), LHCA3 (25 kD), LHCA4 (22 kD), and LHCB1 (20 kD) as control; (C) Confirmation of the interaction of WHY1 and LHCA1 by bimolecular fluorescence complementation assays (BiFC). The onion epidermal cells were transiently transformed with the full length WHY1 and the full length LHCA1. Constructs were fused to either c-myc-GFPn173 or HA-GFPc155 and vice versa. The WHY1 and LHCA1 fused to full length GFP and empty vector were used as controls. All constructs were under the control of the 35S promoter. Fluorescence images are shown on the upside and bright field images are shown on the underside, respectively. C1: WHY1-GFPn173 + LHCA1-GFPc155; C2: LHCA1-GFPn173 + WHY1-GFPc155; C3: WHY1-GFP; C4: LHCA1-GFP; C5: WHY1-GFPn173 + LHCA4-GFPc155; C1-2: scale bar 21 μm; C3-5: scale bar 100 μm.
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Figure 4. Expression of NDH-encoded genes in different WHY1 mutants and wild-type plants. (A) Expression analysis of NDH membrane complex encoded genes in WHY1 mutants and wild-type plants by qPCR; (B) Expression analysis of NDH subcomplex-A encoded genes in WHY1 mutants and wild-type plants. The transcript level in each case was normalized to that of GAPC2 as a reference gene, and the expression level of WT was set as 1. Three biological replications were used in the analysis. Asterisk indicate significant differences in gene expression compared to WT (Tukey–Kramer method, * p < 0.05, ** p < 0.01, *** p < 0.001).
Figure 4. Expression of NDH-encoded genes in different WHY1 mutants and wild-type plants. (A) Expression analysis of NDH membrane complex encoded genes in WHY1 mutants and wild-type plants by qPCR; (B) Expression analysis of NDH subcomplex-A encoded genes in WHY1 mutants and wild-type plants. The transcript level in each case was normalized to that of GAPC2 as a reference gene, and the expression level of WT was set as 1. Three biological replications were used in the analysis. Asterisk indicate significant differences in gene expression compared to WT (Tukey–Kramer method, * p < 0.05, ** p < 0.01, *** p < 0.001).
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Figure 5. The stability of NDH-PSI complexes of thylakoid membranes and NDH activities in the different WHY1 and lhca1 mutants. (A) Determination of NDH activity by chlorophyll fluorescence analysis. Five-week-old plants including different WHY1 and lhca1 mutants, why1lhca1 double mutant and wild-type (WT) were illuminated for 5 min with AL (200 μmol m−2 s−1). After illumination, the subsequent transient increase in chlorophyll fluorescence were recorded as an indicator of NDH activity (a.u.; arbitrary units). The fluorescence levels were standardized by the Fm level. Curves shows trace of chlorophyll fluorescence in mutants and WT plants. ndho line was used as positive control; (B) Quantification of NDH activity measured in (A). The transient increase in chlorophyll fluorescence in mutants was quantified by comparing the peak area with that of WT. The peak area of WT was set as 1. Data presented are the mean of ± SE (n = 5–6); (C) Blue Native PAGE of thylakoid membrane, Band I is the NDH-PSI supercomplex detected in PWHY-HA line; (D) 2D SDS-PAGE separation and immunodetection of NDH-PSI supercomplex containing NDH18 protein (I) and monomer NDH18 (II); (E) Immunodetection of thylakoid membrane, the antibody against to HA peptide, LHCA1, LHCA4, NDH18 (provided by Shikanai group, Japan) and PsaA in kowhy1 (a), oepWHY1-HA (b), PWHY1-HA (c), and PWHY1-HA in lhca1 background, lhca1/PWHY1-HA (d).
Figure 5. The stability of NDH-PSI complexes of thylakoid membranes and NDH activities in the different WHY1 and lhca1 mutants. (A) Determination of NDH activity by chlorophyll fluorescence analysis. Five-week-old plants including different WHY1 and lhca1 mutants, why1lhca1 double mutant and wild-type (WT) were illuminated for 5 min with AL (200 μmol m−2 s−1). After illumination, the subsequent transient increase in chlorophyll fluorescence were recorded as an indicator of NDH activity (a.u.; arbitrary units). The fluorescence levels were standardized by the Fm level. Curves shows trace of chlorophyll fluorescence in mutants and WT plants. ndho line was used as positive control; (B) Quantification of NDH activity measured in (A). The transient increase in chlorophyll fluorescence in mutants was quantified by comparing the peak area with that of WT. The peak area of WT was set as 1. Data presented are the mean of ± SE (n = 5–6); (C) Blue Native PAGE of thylakoid membrane, Band I is the NDH-PSI supercomplex detected in PWHY-HA line; (D) 2D SDS-PAGE separation and immunodetection of NDH-PSI supercomplex containing NDH18 protein (I) and monomer NDH18 (II); (E) Immunodetection of thylakoid membrane, the antibody against to HA peptide, LHCA1, LHCA4, NDH18 (provided by Shikanai group, Japan) and PsaA in kowhy1 (a), oepWHY1-HA (b), PWHY1-HA (c), and PWHY1-HA in lhca1 background, lhca1/PWHY1-HA (d).
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Figure 6. Measurement of photosynthetic parameters in WHY mutants and wild-type plants after high light treatment. (A) Electron transport rate (ETR) in WHY mutants and wild-type plants under high light; (B) Non-photochemical quenching (NPQ) in WHY mutants and wild-type plants under high light. Means ± SE of at least 10 independent measurements are shown. Asterisk indicate significant differences compared to WT (* p < 0.05, Student’s t test).
Figure 6. Measurement of photosynthetic parameters in WHY mutants and wild-type plants after high light treatment. (A) Electron transport rate (ETR) in WHY mutants and wild-type plants under high light; (B) Non-photochemical quenching (NPQ) in WHY mutants and wild-type plants under high light. Means ± SE of at least 10 independent measurements are shown. Asterisk indicate significant differences compared to WT (* p < 0.05, Student’s t test).
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Figure 7. Heat map of gene expression in kowhy1 and ko1/3 mutants after high light treatment. Gene expression in kowhy1, ko1/3 mutants after high light treatment was analyzed by qPCR. The transcript level in each case was normalized to that of GAPC2 as a reference gene, and the expression level of WT was set as 1. Three biological replications were used to analyze. Heat map were drawn by Heml software used log2 of expression.
Figure 7. Heat map of gene expression in kowhy1 and ko1/3 mutants after high light treatment. Gene expression in kowhy1, ko1/3 mutants after high light treatment was analyzed by qPCR. The transcript level in each case was normalized to that of GAPC2 as a reference gene, and the expression level of WT was set as 1. Three biological replications were used to analyze. Heat map were drawn by Heml software used log2 of expression.
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MDPI and ACS Style

Huang, D.; Lin, W.; Deng, B.; Ren, Y.; Miao, Y. Dual-Located WHIRLY1 Interacting with LHCA1 Alters Photochemical Activities of Photosystem I and Is Involved in Light Adaptation in Arabidopsis. Int. J. Mol. Sci. 2017, 18, 2352. https://doi.org/10.3390/ijms18112352

AMA Style

Huang D, Lin W, Deng B, Ren Y, Miao Y. Dual-Located WHIRLY1 Interacting with LHCA1 Alters Photochemical Activities of Photosystem I and Is Involved in Light Adaptation in Arabidopsis. International Journal of Molecular Sciences. 2017; 18(11):2352. https://doi.org/10.3390/ijms18112352

Chicago/Turabian Style

Huang, Dongmei, Wenfang Lin, Ban Deng, Yujun Ren, and Ying Miao. 2017. "Dual-Located WHIRLY1 Interacting with LHCA1 Alters Photochemical Activities of Photosystem I and Is Involved in Light Adaptation in Arabidopsis" International Journal of Molecular Sciences 18, no. 11: 2352. https://doi.org/10.3390/ijms18112352

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