Cytoplasmic Kinase Network Mediates Defense Response to Spodoptera litura in Arabidopsis

Plants defend against folivores by responding to folivore-derived elicitors following activation of signaling cascade networks. In Arabidopsis, HAK1, a receptor-like kinase, responds to polysaccharide elicitors (Frα) that are present in oral secretions of Spodoptera litura larvae to upregulate defense genes (e.g., PDF1.2) mediated through downstream cytoplasmic kinase PBL27. Here, we explored whether other protein kinases, including CPKs and CRKs, function with PBL27 in the intracellular signaling network for anti-herbivore responses. We showed that CRK2 and CRK3 were found to interact with PBL27, but CPKs did not. Although transcripts of PDF1.2 were upregulated in leaves of wild-type Arabidopsis plants in response to mechanical damage with Frα, this failed in CRK2- and PBL27-deficient mutant plants, indicating that the CRK2/PBL27 system is predominantly responsible for the Frα-responsive transcription of PDF1.2 in S. litura-damaged plants. In addition to CRK2-phosphorylated ERF13, as shown previously, ethylene signaling in connection to CRK2-phosphorylated PBL27 was predicted to be responsible for transcriptional regulation of a gene for ethylene response factor 13 (ERF13). Taken together, these findings show that CRK2 regulates not only ERF13 phosphorylation but also PBL27-dependent de novo synthesis of ERF13, thus determining active defense traits against S. litura larvae via transcriptional regulation of PDF1.2.


Introduction
In response to herbivory, plants activate signaling cascade networks for emergent defense responses that bring about herbivore resistance. Initially, to recognize the herbivore damage, plants perceive elicitors, such as herbivore-associated molecular patterns (HAMPs), secreted by feeding herbivores concomitantly with physical damage, to trigger vigorous defense responses against herbivore pests [1,2].
In addition to the HAK1/PBL27 system, other cytoplasmic kinases should act concomitantly or independently in Arabidopsis during plant damage by S. litura larvae [2]. For instance, calcium-dependent protein kinases (CPK3 and CPK13) have been shown to mediate the phosphorylation of the heat shock factor HsfB2a (Hsf22) in order to upregulate the transcription of PDF1.2 [9]. CPKs constitute a large family of serine/threonine protein kinases in plants and play multi-functional roles in the activation of mitogen-activated protein kinases (MAPKs) [10], nicotinamide adenine dinucleotide phosphate oxidases (NADPH oxidases) [11,12], and transcription factors [9,13] to orchestrate intracellular signaling networks upon herbivore and pathogen attack [14].
Moreover, a member of the CPK-related protein kinases (CRK2) has been shown to phosphorylate tyrosine (Tyr) residues of a subset of transcription factors, including herbivoryresponsive ethylene response factor 13 (ERF13) and RAP2.6 (ERF108) in Arabidopsis, which bind to genomic GCC boxes and activate defense genes including PDF1.2 [15,16]. Likewise, CRK3 plays key roles in Tyr-phosphorylation of WRKY14, which binds to genomic W boxes and activates defense genes [15]. Such Tyr-phosphorylations are responsible for the nuclear localization, DNA-binding, and transactivation of transcription factors, as shown for CjWRKY1, which is involved in the biosynthesis of benzylisoquinoline alkaloids in Coptis japonica [17]. Notably, CRK2 is multifunctional, phosphorylating not only transcription factors but also GARU, gibberellin receptor RING E3 ubiquitin ligase, which promotes ubiquitin-dependent proteasome degradation of gibberellin receptor (GID1) in Arabidopsis [18].
Based on these findings, there is no doubt that the intracellular kinases PBL27, CPKs, and CRKs are responsible for defense responses in Arabidopsis, but whether and how they engage in cross-talk are unknown. Thus, to further understand the functioning of the intracellular signaling network, we explored the polysaccharide elicitor-responsive transcript of PDF1.2 in order to examine its possible regulation through cross-talk between PBL27 and other cytoplasmic protein kinases in response to S. litura attack in Arabidopsis.

Molecular Interaction of PBL27 with Cytoplasmic Kinases
First, to screen CRKs and CPKs that interact with PBL27, we assessed in vitro interaction between the biotinylated recombinant PBL27 protein and FLAG-conjugated cytoplasmic kinase proteins (CRK2, CRK3, CPK3, and CPK13) using the AlphaScreen system. The resultant luminescence intensities showed that PBL27 protein interacted strongly with CRK2 and CRK3 and weakly with CPK3 and CPK13 when compared with Escherichia coli dihydrofolate reductase serving as the control protein ( Figure 1A). Moreover, co-immunoprecipitation assays confirmed in vivo interactions between HA-tagged PBL27 and FLAG-tagged CRK2 and CRK3 in Nicotiana benthamiana leaf cells following their transient expression ( Figure 1B). In contrast, such in vivo interactions were not observed between HA-tagged PBL27 and FLAG-tagged CPK3 or CPK13 ( Figure S1). Therefore, to further study the PBL27-interacting cytoplasmic kinases found here, hereafter, we focused on CRKs.

Central Role of the PBL27/CRK2 System in S. litura Elicitor Response
Next, to further screen cytoplasmic kinases that play a significant role in S. litura polysaccharide elicitor (Frα [3,4])-responsive transcription of the representative defense gene PDF1.2, leaves of Arabidopsis wild-type (WT) and its T-DNA insertion mutant lines of PBL27 (pbl27), CRK2 (crk2), and CRK3 (crk3) were subjected to mechanical damage (MD) with application of Frα. PDF1.2 transcript levels in WT leaves were increased in response to MD + Frα but not MD alone (Figure 2), as shown previously [4]. These responses were not observed in pbl27 or crk2 leaves, but were observed in crk3 leaves, indicating that the S. litura-induced PDF1.2 expression is dependent on PBL27/CRK2. Data marked with an asterisk(s) are significantly different based on a student's t-test (* 0.01 ≤ p < 0.05; ** p < 0.01). ns, not significant. (B) A pair of FLAG-tagged CRK2 or CRK3 (CRK2FLAG or CRK3FLAG) and HA-tagged PBL27 (PBL27HA) were expressed in Nicotiana benthamiana leaf cells. Total proteins extracted from the leaves were immunoprecipitated using anti-FLAG-tag magnetic beads, subjected to SDS-PAGE, and probed with the respective antibodies (αHA or αFLAG) as a primary antibody. Arrowheads indicate the predicted target signals. IP, immunoprecipitation.

Central Role of the PBL27/CRK2 System in S. litura Elicitor Response
Next, to further screen cytoplasmic kinases that play a significant role in S. litura polysaccharide elicitor (Frα [3,4])-responsive transcription of the representative defense gene PDF1.2, leaves of Arabidopsis wild-type (WT) and its T-DNA insertion mutant lines of PBL27 (pbl27), CRK2 (crk2), and CRK3 (crk3) were subjected to mechanical damage (MD) with application of Frα. PDF1.2 transcript levels in WT leaves were increased in response to MD + Frα but not MD alone (Figure 2), as shown previously [4]. These responses were not observed in pbl27 or crk2 leaves, but were observed in crk3 leaves, indicating that the S. litura-induced PDF1.2 expression is dependent on PBL27/CRK2.

Promotion of PDF1.2 Transcription with the PBL27/CRK2/ERF13 System
Regarding the fact that PBL27 is a substrate of CRK2 (see Figure 3), it has been shown that CRK2 also phosphorylates a transcriptional factor, ERF13, leading to activation of the defense gene PDF1.2 in Arabidopsis leaves [15]. Moreover, given that the 5′ flanking region of the PDF1.2 gene (1 kb) (PDF1.2P) contains a potential ERF-binding motif (GCC box [AGCCGCC]) at 311 bp (base pairs) upstream of the start codon, it was predicted that ERF13 serves as potent activator of PDF1.2P. In fact, when ERF13 was coexpressed with a firefly luciferase (Fluc) reporter gene under the control of PDF1.2P (PDF1.2P: Fluc) in protoplasts prepared from Arabidopsis WT leaves, the levels of Fluc activity produced due to the transformed reporter construct was dramatically increased compared to the level in protoplasts expressing PDF1.2P:Fluc alone ( Figure 4A). The Fluc activity levels were not as dramatically increased in protoplasts prepared from pbl27 or crk2 leaves, indicating that PBL27 and CRK2 are responsible for activation of ERF13 ( Figure 4A). However, PDF1.2Ppromoted Fluc activity levels with ERF13 expression were increased when CRK2 was coexpressed, but not when PBL27 was coexpressed, compared to those with ERF13 alone, in WT leaf protoplasts ( Figure 4B). We therefore hypothesized that CRK2 is directly committed to ERF13 activation but PBL27 is not.

Promotion of PDF1.2 Transcription with the PBL27/CRK2/ERF13 System
Regarding the fact that PBL27 is a substrate of CRK2 (see Figure 3), it has been shown that CRK2 also phosphorylates a transcriptional factor, ERF13, leading to activation of the defense gene PDF1.2 in Arabidopsis leaves [15]. Moreover, given that the 5 flanking region of the PDF1.2 gene (1 kb) (PDF1.2P) contains a potential ERF-binding motif (GCC box [AGCCGCC]) at 311 bp (base pairs) upstream of the start codon, it was predicted that ERF13 serves as potent activator of PDF1.2P. In fact, when ERF13 was coexpressed with a firefly luciferase (Fluc) reporter gene under the control of PDF1.2P (PDF1.2P: Fluc) in protoplasts prepared from Arabidopsis WT leaves, the levels of Fluc activity produced due to the transformed reporter construct was dramatically increased compared to the level in protoplasts expressing PDF1.2P: Fluc alone ( Figure 4A). The Fluc activity levels were not as dramatically increased in protoplasts prepared from pbl27 or crk2 leaves, indicating that PBL27 and CRK2 are responsible for activation of ERF13 ( Figure 4A). However, PDF1.2Ppromoted Fluc activity levels with ERF13 expression were increased when CRK2 was coexpressed, but not when PBL27 was coexpressed, compared to those with ERF13 alone, in WT leaf protoplasts ( Figure 4B). We therefore hypothesized that CRK2 is directly committed to ERF13 activation but PBL27 is not.

Ethylene Signaling for Transcriptional Activation of ERF13
Based on the findings regarding a possible indirect involvement of PBL27 in the transcriptional regulation of PDF1.2 ( Figure 4B), we next focused on transcriptional regulation of ERF13. First of all, we assessed whether the ERF13 transcript level was responsive to Frα in a PBL27-dependent manner. For this, leaves of Arabidopsis WT and pbl27 mutant plants were subjected to MD with application of Frα. Increased ERF13 transcript level was elicited in response to MD + Frα in WT leaves but less in pbl27 mutant leaves ( Figure 5A), indicating that ERF13 transcription was responsive to Frα in a PBL27-dependent manner. Moreover, given the fact that PBL27 has been shown to be involved in de novo ethylene biosynthesis in Arabidopsis in response to Frα [4], we next assessed whether ethylene signaling was involved in the regulation of ERF13 transcription. For this purpose, leaves of WT Arabidopsis plants were treated with ethephon, a chemical replacement for ethylene treatment [19]. The transcript level of ERF13 was upregulated by treatment with ethephon, compared to that in untreated leaves ( Figure 5B), indicating that ERF13 transcription was responsive to ethylene.

Ethylene Signaling for Transcriptional Activation of ERF13
Based on the findings regarding a possible indirect involvement of PBL27 in scriptional regulation of PDF1.2 ( Figure 4B), we next focused on transcriptional r of ERF13. First of all, we assessed whether the ERF13 transcript level was resp Frα in a PBL27-dependent manner. For this, leaves of Arabidopsis WT and pbl2 plants were subjected to MD with application of Frα. Increased ERF13 transcript elicited in response to MD + Frα in WT leaves but less in pbl27 mutant leaves (Fi indicating that ERF13 transcription was responsive to Frα in a PBL27-dependent Moreover, given the fact that PBL27 has been shown to be involved in de novo biosynthesis in Arabidopsis in response to Frα [4], we next assessed whether signaling was involved in the regulation of ERF13 transcription. For this purpo of WT Arabidopsis plants were treated with ethephon, a chemical replacemen ylene treatment [19]. The transcript level of ERF13 was upregulated by treatm ethephon, compared to that in untreated leaves ( Figure 5B), indicating that ER scription was responsive to ethylene.

Discussion
In Arabidopsis, CRK2 is multi-functional, controlling an array of regulatory m

Discussion
In Arabidopsis, CRK2 is multi-functional, controlling an array of regulatory molecules, including transcriptional factors involved in JA signaling [15,16], as well as GARU [18], in various signaling cascades. In addition to these previous findings, here we provided new insight into the complex function of CRK2, which coordinates with PBL27 for resultant transcriptional activation of PDF1.2 in response to a polysaccharide elicitor (Frα) during S. litura attack (summarized in Figure 6). PBL27 is a member of receptor-like cytoplasmic kinases [20], which act as a major class of signal transmitting proteins to serve for cellular responses to elicitors such as HAMPs [4] and microbe-associated molecular patterns (MAMPs) [5,6]. Therefore, the CRK2/PBL27 complex may commonly function in HAMP and MAMP responses. Notably, following phosphorylation of PBL27, ethylene signaling may serve a major intermediate signaling with de novo synthesis of ERF ( Figure 5). In connection to this fact, it has been shown that PBL27 regulates the MAPK kinase kinase 5 (MAPKKK5), in the MAPK cascade [5], and that pathogen-responsive MAPKs (MPK3 and MPK6) regulate ethylene production [21]. Moreover, the 1-amino-cyclopropane-1-carboxylic acid synthase (ACS) is one of the rate-limiting enzymes for ethylene production, and ACS isomers (ACS2 and ACS6) have been shown to serve as substrates of MPK3 and MPK6 [22,23]. In the sequence of reactions in such signaling pathways, phosphorylation of ACS2/ACS6 by MAPKs is certainly required to stabilize the ACS protein and its activation, leading to de novo ethylene synthesis in Arabidopsis during biotic and abiotic stress responses [22,23]. Collectively, these facts show that it is indeed conceivable that the PBL27-mediated activation of ethylene-signaling controls ethylene-responsive transcription of ERF13. In other words, CRK2 is dual-functional by modulating ERF13 protein function directly and ERF13 transcriptional activity indirectly, eventually leading to transcriptional activation of PDF1.2 for anti-herbivore defense ( Figure 6). However, the molecular mechanism by which the phosphorylation of ERF13 by the complex of CRK2 and PBL27 activates ERF13 transcription remains unclear. To reveal how protein phosphorylation exerts significant Notably, following phosphorylation of PBL27, ethylene signaling may serve a major intermediate signaling with de novo synthesis of ERF ( Figure 5). In connection to this fact, it has been shown that PBL27 regulates the MAPK kinase kinase 5 (MAPKKK5), in the MAPK cascade [5], and that pathogen-responsive MAPKs (MPK3 and MPK6) regulate ethylene production [21]. Moreover, the 1-amino-cyclopropane-1-carboxylic acid synthase (ACS) is one of the rate-limiting enzymes for ethylene production, and ACS isomers (ACS2 and ACS6) have been shown to serve as substrates of MPK3 and MPK6 [22,23]. In the sequence of reactions in such signaling pathways, phosphorylation of ACS2/ACS6 by MAPKs is certainly required to stabilize the ACS protein and its activation, leading to de novo ethylene synthesis in Arabidopsis during biotic and abiotic stress responses [22,23]. Collectively, these facts show that it is indeed conceivable that the PBL27-mediated activation of ethylenesignaling controls ethylene-responsive transcription of ERF13. In other words, CRK2 is dualfunctional by modulating ERF13 protein function directly and ERF13 transcriptional activity indirectly, eventually leading to transcriptional activation of PDF1.2 for anti-herbivore defense ( Figure 6). However, the molecular mechanism by which the phosphorylation of ERF13 by the complex of CRK2 and PBL27 activates ERF13 transcription remains unclear. To reveal how protein phosphorylation exerts significant effects on the specific transcription machinery, further analysis of the interaction between the complex and the ERF13 promoter using electrophoretic mobility shift assays, etc., will be required.
It should be noted that transient expression of ERF13 in protoplasts prepared from the pbl27 mutant resulted in reduced activation levels of PDF1.2P compared to that in WT protoplasts ( Figure 4A). Moreover, given that PBL27 was not directly involved in ERF13 transactivation ( Figure 4B), PBL27 might contribute to not only MAPK/ethylenedependent regulation of the ERF13 transcript level but also to transactivation of ERF13 indirectly. PBL27 has been shown to phosphorylate not only MAPKKK5, as described [5], but also slow-type (S-type) anion channels [24]. Alternatively, for the transactivation of ERF13 by PBL27, additional enhancer molecule(s) may be required.
Unlike CRK2, CRK3 is not likely to interact strongly with PBL27 ( Figure 1) and to be aggressively involved in the Frα-mediated defense response (Figure 2). This possibility is in accord with the finding that ABA-responsive WRKY14, a CRK3 substrate [15], does not control PDF1.2 transcription ( Figure S2). However, given the fact that CRK3 is responsible for transcriptional regulation of PDF1.2 during S. litura attack [15], herbivore danger signals other than Frα, e.g., oral bacteria in S. litura larvae, may be more responsible for mediating the effects of CRK3 during herbivory. This is in accord with the fact that ABA signaling is enhanced by oral bacteria such as Staphylococcus epidermidis [25]. Alternatively, since WRKYs also play a central role in the environmental stress response towards, e.g., draught and heat stresses [26], CRK3 may be involved in responses to not only herbivory but also environmental stresses.
Unlike CRKs, CPK3 and CPK13 might not be predominantly involved in Frα response during S. litura attack, as they did not interact with PBL27 ( Figure S1). Alternatively, since calcium influx mediated via CNGC19, a calcium-permeable channel [27], would be able to activate those CPKs [28], this calcium-dependent signaling may work for signal transduction in a manner independent of the Frα response via the CRK/PBL27 system. Namely, the HAMP-mediated signal network may be sophisticatedly constructed by both the independent actions and cross-talks of multiple protein kinases in plants in response to herbivory.

Plants and Elicitor
Arabidopsis thaliana (Arabidopsis) ecotypes Col-0 and its T-DNA insertion mutant lines (pbl27 [GK_958D06], crk2 [SALK_090938C], crk3 [SALK_128719C]) were grown in soil in climate-controlled rooms at 22 ± 1 • C with a photoperiod of 12 h (80 µE m -2 s -1 ). Likewise, the potted Nicotiana benthamiana plants were grown at 24 ± 1 • C with a photoperiod of 16 h (80 µE m -2 s -1 ). The individual plants were grown in single plastic pots. The potted Arabidopsis and N. benthamiana plants were grown for 4 weeks and 6 weeks, respectively, and were used for subsequent analyses.
Eggs of Spodoptera litura (Fabricius) were obtained from Sumika Technoservice Co. Ltd. (Takarazuka, Japan). They were incubated in a climate-controlled room at 24 ± 1 • C with a photoperiod of 16 h. The hatched larvae were reared on artificial diet (Insecta LFS, Nihon Nosan Kogyo Ltd., Tokyo, Japan) in a plastic container (0.9 L) with a mesh-covered lid. Feces in the plastic case were removed and a piece of artificial diet was added 3 times a week. OS was collected from third or fourth instar larvae of S. litura (about a week after hatching) using a glass capillary tube (Hirschmann Laborgeräte GmbH and Co. KG, Eberstadt, Germany). Briefly, the collected OS was stored at −20 • C until use. OS was passed through a column (1.5 cm × 80 cm) packed with Bio-Gel P-2 resin (Bio-Rad, Hercules, CA, USA) to collect FrA. FrA was subsequently passed through a column (2.0 cm × 45 cm) packed with Bio-Gel P-10 resin (Bio-Rad) to collect Frα. Frα was lyophilized and then dissolved with 750 µL of 10 mM MES buffer (pH 6.0) for assays (2-fold concentrated), according to the method described previously [4].
Frα was diluted 5 fold with 10 mM MES buffer (pH 6.0). MD was performed with stainless steel needles on 3 leaves of an individual Arabidopsis plant. Approximately 30 MD spots were made per leaf. The Frα was immediately applied on an MD spot (approximately 1 µL per spot). Treatment of MD leaves with MES buffer served as a control. Arabidopsis plants were placed in an air-tight container and sprayed with 1mL of 10 mM ethephon solution (Tokyo Chemical Industry Co., Ltd., Tokyo, Japan) dissolved in 50 mM phosphate buffer (pH 7.0) and incubated for up to 8 h.

Primers
Primers used in this study are listed in Table S1.

Cell-Free Protein Synthesis, Immunoblotting, and AlphaScreen System
The full-length open reading frames (ORFs) of PBL27, CRK2, CRK3, CPK3, and CPK13 were cloned into the Gateway (GW) destination vector pEU-6His-bls-GW (bls; biotin ligation site) or pEU-GW-FALG using the Gateway cloning system (Thermo Fisher Scientific, Waltham, MA, USA). Cell-free protein synthesis and AlphaScreen-based protein-protein interaction assays were carried out according to the methods described previously [29]. For evaluation of the quality of the proteins used, total proteins were subjected to 10% SDS-PAGE and immunoblotted with anti-biotin HRP-linked antibody (Cell Signaling Technology, Beverly, MA, USA) or monoclonal anti-FLAG M2-peroxidase antibody produced by mouse clone M2 (Sigma-Aldrich, St. Louis, MO, USA) ( Figure S3). The membranes were soaked with Immobilon Western Chemiluminescent HRP Substrate (Merck Millipore Ltd., Darmstadt, Germany), and the signals were detected with an ImageQuant LAS-4000 imaging system (GE Healthcare, Buckinghamshire, UK).

RNA Isolation, cDNA Synthesis and Quantitative Polymerase Chain Reaction (qPCR)
Approximately 100 mg of leaf tissues were homogenized in liquid nitrogen, and total RNA was isolated and purified using TRI reagent (Molecular Research Center, Inc., Cincinnati, OH, USA) following the manufacturer's protocol. Single-stranded cDNA was synthesized using ReverTra Ace qPCR RT Master Mix with gDNA Remover (Toyobo, Osaka, Japan), and 0.5 µg of the total RNA was incubated, first, at 37 • C for 5 min for the DNase reaction, and then at 37 • C for 15 min for the RT reaction. Real-time PCR was performed using a CFX Connect real-time PCR detection system (Bio-Rad) with THUNDERBIRD SYBR qPCR Mix (Toyobo) and gene-specific primers (Table S1). The following protocol was used: an initial polymerase activation of 60 s at 95 • C, followed by 45 cycles of 15 s at 95 • C and then 30 s at 60 • C. Then a melting curve analysis preset by the instrument was performed. Relative transcript abundances were determined after normalization of raw signals with the abundance of the housekeeping transcript of the Arabidopsis ACT8 gene (at1g49240).

LUC Assay
The LUC assay was performed as previously described [32]. Fluc activity produced due to the transformed reporter construct was expressed as the value normalized by the Rluc activity produced due to the co-transfected reference vector. Replicate analyses were conducted with 3 independent samples.

Statistics and Reproducibility
We performed Student's t-test for pairwise analysis and one-way ANOVA with Holm's sequential Bonferroni post hoc test using the program (http://astatsa.com/OneWay_ Anova_with_TukeyHSD/ (accessed in 1 April 2023)) for comparing multiple samples. The sample sizes and number of replicates for all of the sets of assays and analyses are indicated in the legends of the corresponding figures.
Supplementary Materials: The following supporting information can be downloaded at: https:// www.mdpi.com/article/10.3390/plants12091747/s1. Figure S1: Interactions of PBL27 and CPKs. A pair of FLAG-tagged CPK3 or CPK13 (CPK3-FLAG or CPK13-FLAG) and HA-tagged PBL27 (PBL27-HA) were expressed in Nicotiana benthamiana leaf cells. Total proteins extracted from the leaves were immunoprecipitated using anti-FLAG-tag magnetic beads, subjected to SDS-PAGE, and probed with anti-HA or anti-FLAG antibody as a primary antibody. Arrowheads indicate the predicted target signals. Figure S2: Transient activation of a firefly luciferase reporter gene under the control of PDF1.2 promoter according to coexpression with or without (-) ERF13 or WRKY14 in arabidopsis wild-type leaf protoplasts. Data represent the mean and standard error (n = 4). Data marked with asterisks are significantly different from those obtained without ERF13 or WRKY14 (-), based on an ANOVA with Holm's sequential Bonferroni post-hoc test (**, P < 0.01). Figure S3: Recombinant proteins used for AlphaScreen. Immunoblotting of proteins for biotinylated (Bio)-dihydrofolate reductase and PBL27 (Bio-DR and Bio-PBL27, respectively) as well as FLAG-tagged CRK2, CRK3, CPK3 and CPK13 (FLAG-CRK2, FLAG-CRK3, FLAG-CPK3 and FLAG-CPK13, respectively) were synthesized using a cell-free system. Total proteins were subjected to 10% SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblotted with the respective antibodies (α-Biotin and α-FLAG). Table S1