Identification of the Capsicum baccatum NLR Protein CbAR9 Conferring Disease Resistance to Anthracnose

Anthracnose is caused by Colletotrichum species and is one of the most virulent fungal diseases affecting chili pepper (Capsicum) yield globally. However, the noble genes conferring resistance to Colletotrichum species remain largely elusive. In this study, we identified CbAR9 as the causal locus underlying the large effect quantitative trait locus CcR9 from the anthracnose-resistant chili pepper variety PBC80. CbAR9 encodes a nucleotide-binding and leucine-rich repeat (NLR) protein related to defense-associated NLRs in several other plant species. CbAR9 transcript levels were induced dramatically after Colletotrichum capsici infection. To explore the biological function, we generated transgenic Nicotiana benthamiana lines overexpressing CbAR9, which showed enhanced resistance to C. capsici relative to wild-type plants. Transcript levels of pathogenesis-related (PR) genes increased markedly in CbAR9-overexpressing N. benthamiana plants. Moreover, resistance to anthracnose and transcript levels of PR1 and PR2 were markedly reduced in CbAR9-silenced chili pepper fruits after C. capsici infection. Our results revealed that CbAR9 contributes to innate immunity against C. capsici.


Introduction
Chili pepper (Capsicum) is an economically important crop providing food, spices, and medicinals [1][2][3]. Pepper is a member of the Solanaceae family, which also includes potato (Solanum tuberosum), tomato (Solanum lycopersicum), tobacco (Nicotiana sp.), and petunia (Petunia × atkinsiana) [4]. Members of the Solanaceae have similar numbers of chromosomes (n = 12), although their genome sizes can vary largely [5]. Indeed, the genomes of pepper species are typically larger, being about four times that of tomato, due to a greater fraction of repetitive sequences [6]. Of the approximately 40 species in the Capsicum genus [7], the only domesticated ones are bell pepper (C. annuum), cayenne pepper (C. frutescens), habanero pepper (C. chinense), locoto pepper (C. baccatum), and rocoto pepper (C. pubescens) [8]. Of those, C. chinense and C. baccatum harbor valuable genes for plant breeding [9]. In 1998, the World Vegetable Center identified three anthracnoseresistant varieties in these species-C. chinense variety 'PBC932' and C. baccatum varieties 'PBC80' and 'PBC81' [10]-paving the way for botanists to introduce anthracnose resistance into other varieties using conventional breeding and embryo rescue [11]. In particular, the C. baccatum resistant variety PBC80 showed broad-spectrum resistance (BSR), conferring resistance to at least two pathogenic species or to the majority of races/strains of the Int. J. Mol. Sci. 2021, 22, 12612 2 of 11 same pathogen [12], as well as to the three main Colletotrichum species causing pepper anthracnose: C. acutatum, C. capsici, and C. gloeosporioides [13][14][15]. The resistance genes originating from variety PBC80 have therefore been the focus of much attention toward their identification and characterization.
Plants and animals alike use nucleotide-binding and leucine-rich repeat (NLR) proteins to respond to invading pathogens through the activation of innate immunity [16][17][18]. The NLR family is one of the most variable gene families in plant genomes [19], and plant NLRs play various roles such as sensors, helpers, and executors in response to pathogen infection [20]. Plant NLRs are divided into three main groups based on the accompanying functional domains at their N termini: Toll/interleukin-1 receptor (TIR) domain, coiled-coil (CC) domain, and resistance to powdery mildew 8 (RPW8)-type CC (CC R ) domain [21]. Plant NLRs also contain a central nucleotide-binding site (NBS) and C-terminal leucine-rich repeats (LRRs) [22].
Plants possess two major innate immunity systems: pathogen-associated molecular pattern (PAMP)-triggered immunity (PTI) and effector-triggered immunity (ETI) [23]. PTI signaling is initiated by the recognition of PAMPs by pattern recognition receptors (PRRs) residing in the plasma membrane, and it results in transcriptional reprograming and generation of defense components that increase resistance to a wide range of pathogens [24]. To overcome this defense mechanism, pathogens produce effectors required for inhibition of PTI and activation of effector-triggered susceptibility (ETS) [25]. Counteracting pathogen effector strategy, plants activate ETI through perception of effectors by NLRs, a wellcharacterized representative intracellular resistance (R) protein that recognizes specific pathogen effectors [26][27][28]. NLR-mediated ETI leads to a hypersensitive response (HR), which is characterized by a burst of reactive oxygen species and programmed cell death associated with disease resistance at the infected site [29][30][31]. HR also induces a secondary resistance response known as systemic acquired resistance (SAR), which confers longlasting protection against a broad spectrum of pathogens throughout the infected plant [32].
Some of the sensor NLR (sNLR) receptors, such as RRS1 and RGA5, contain an integrated decoy domain that binds directly to effector [33]. However, since most characterized plant NLRs contain no integrated decoy domain [34], sNLR receptors have been proposed to interact with effectors indirectly through either an accessory protein, as in the guard model hypothesis, or via a structural mimic as in the decoy model [35][36][37]. Moreover, a subset of activated sNLRs also requires a helper NLR (hNLR) to transduce the ETI signal to downstream signaling components, with hNLRs in fact having been recently proposed to act as signaling hubs for a diverse array of sNLRs [33,38,39]. However, the noble NLR genes conferring resistance to Colletotrichum species remain largely elusive.
Pepper production is currently under threat by anthracnose disease, which is caused by Colletotrichum species and can result in losses of up to 80% of the harvest [40]. Therefore, identifying genes conferring resistance to Colletotrichum species is a high-priority goal for pepper breeding. Previous genomic studies showed that the NLR gene family is highly expanded and diversified in chili pepper [6,41]. Moreover, we previously mapped quantitative trait loci (QTLs) for resistance against C. capsici on chromosome 9, and for resistance to C. acutatum on chromosome 12, using composite interval mapping (CIM) [42]. Recently, we identified CbCN conferring resistance to C. acutatum from QTL located on chromosome 12 [43]. However, the noble genes involved in innate immunity against C. capsici remain to elucidated.
We previously showed that the major CcR9 QTL for resistance against C. capsici maps between the markers HpmsE143 and EtgaMccg10 on chromosome 9; CcR9 alone explained >50% of the standing phenotypic variance for several anthracnose resistance-associated parameters [42]. Since NLR proteins play critical roles in innate immunity, here, we identified the NLR gene CbAR9 from PBC80 as responsible for the QTL on chromosome 9. Molecular and genetic studies revealed that CbAR9 confers resistance to C. capsici in chili pepper.

CbAR9 Encoding a Typical NLR Protein Is Identified from the CcR9 QTL of C. baccatum PBC80
To identify candidate genes associated with anthracnose resistance, we analyzed the CcR9 mapping interval in the C. baccatum genome and identified the expressed NLR genes ( Figure 1A) Figure 1B). To know genetic divergence, we performed phylogenic analysis based on amino acid sequence of the candidate genes (Table S1). As a result, phylogenic tree showed that CbAR9 (CB.CBv1.2.scaffold1468.5) is remarkable different to the other candidate proteins ( Figure S1).

CbAR9 Encoding a Typical NLR Protein Is Identified from the CcR9 QTL of C. baccatum PBC80
To identify candidate genes associated with anthracnose resistance, we analyzed the CcR9 mapping interval in the C. baccatum genome and identified the expressed NLR genes ( Figure 1A). The four genes such as CB.CBv1.2.scaffold1468.5/1022.13/778.14/778. 16 Figure 1B). To know genetic divergence, we performed phylogenic analysis based on amino acid sequence of the candidate genes (Table S1). As a result, phylogenic tree showed that CbAR9 (CB.CBv1.2.scaf-fold1468.5) is remarkable different to the other candidate proteins ( Figure S1).     Figure 2A). Using CbAR9 as a query, we identified two NLR proteins: one in bell pepper (CaNLR, XP_016566298) and one in habanero pepper (CcNLR, PHU21239) that were over 98% identical to CbAR9 ( Figure 2A). In addition, we searched for NLR proteins with the same domain arrangement as CbAR9 in other plant species using SmartBLAST, yielding NLR proteins from soybean (Glycine max) and Arabidopsis (Arabidopsis thaliana) that are highly similar with CbAR9 over the length of the NLR domains ( Figure S2). Phylogenic analysis indicated that CbAR9 clusters with other pepper NLR proteins, followed by Solanaceae proteins, which will be informative for pepper breeding using CbAR9 based on sequence similarity ( Figure 2B).
CbAR9 as a query, we identified two NLR proteins: one in bell pepper (CaNLR, XP_016566298) and one in habanero pepper (CcNLR, PHU21239) that were over 98% identical to CbAR9 (Figure 2A). In addition, we searched for NLR proteins with the same domain arrangement as CbAR9 in other plant species using SmartBLAST, yielding NLR proteins from soybean (Glycine max) and Arabidopsis (Arabidopsis thaliana) that are highly similar with CbAR9 over the length of the NLR domains ( Figure S2). Phylogenic analysis indicated that CbAR9 clusters with other pepper NLR proteins, followed by Solanaceae proteins, which will be informative for pepper breeding using CbAR9 based on sequence similarity ( Figure 2B).  13 and CbAR9 in PBC80 after C. capsici inoculation for 48 h, as determined by RT-qPCR. Actin served as internal reference. Data are shown as means ± SD. Asterisks indicate statistically significant differences from controls (** p < 0.01). (D) Relative CbAR9 transcript levels in An-S and PBC80 after C. capsici infection for the indicated times, as determined by RT-qPCR. Actin served as the internal reference. Data are shown as means ± SDs. Asterisks indicate statistically significant differences from controls (* p < 0.05 and ** p < 0.01). The experiments were repeated at least three times, with similar results.
Since NLR genes related to innate immunity are commonly induced by pathogen infection [44], we measured transcription levels of the four candidate genes encoding a typical NLR in response to anthracnose disease by infecting plants with C. capsici. Indeed, CbAR9 expression was dramatically induced in PBC80 48 h after C. capsici inoculation. In order to monitor the expression pattern of CbAR9 in detail, the chili pepper variety An-S and PBC80 were inoculated with C. capsici. CbAR9 transcript levels rose to higher levels in the resistant variety PBC80 than in the susceptible variety An-S by C. capsici. ( Figure  2D). Therefore, we focused primarily on CbAR9 among the candidate genes.

Overexpression of CbAR9 Enhances Resistance to C. capsici Infection
To elucidate the biological function of CbAR9 in plants, we generated transgenic Nicotiana benthamiana plants constitutively expressing CbAR9 (CbAR9 OX ). We validated the presence and expression of the transgene by RT-qPCR analysis ( Figure S3A). Since activation of innate immunity system effects plant growth and development, overexpression of immune genes frequently causes a constitutive immunity phenotype. However, CbAR9 OX did not show any visible growth phenotypes ( Figure S3B). When we examined whether  13 and CbAR9 in PBC80 after C. capsici inoculation for 48 h, as determined by RT-qPCR. Actin served as internal reference. Data are shown as means ± SD. Asterisks indicate statistically significant differences from controls (** p < 0.01). (D) Relative CbAR9 transcript levels in An-S and PBC80 after C. capsici infection for the indicated times, as determined by RT-qPCR. Actin served as the internal reference. Data are shown as means ± SDs. Asterisks indicate statistically significant differences from controls (* p < 0.05 and ** p < 0.01). The experiments were repeated at least three times, with similar results.
Since NLR genes related to innate immunity are commonly induced by pathogen infection [44], we measured transcription levels of the four candidate genes encoding a typical NLR in response to anthracnose disease by infecting plants with C. capsici. Indeed, CbAR9 expression was dramatically induced in PBC80 48 h after C. capsici inoculation. In order to monitor the expression pattern of CbAR9 in detail, the chili pepper variety An-S and PBC80 were inoculated with C. capsici. CbAR9 transcript levels rose to higher levels in the resistant variety PBC80 than in the susceptible variety An-S by C. capsici. (Figure 2D). Therefore, we focused primarily on CbAR9 among the candidate genes.

Overexpression of CbAR9 Enhances Resistance to C. capsici Infection
To elucidate the biological function of CbAR9 in plants, we generated transgenic Nicotiana benthamiana plants constitutively expressing CbAR9 (CbAR9 OX ). We validated the presence and expression of the transgene by RT-qPCR analysis ( Figure S3A). Since activation of innate immunity system effects plant growth and development, overexpression of immune genes frequently causes a constitutive immunity phenotype. However, CbAR9 OX did not show any visible growth phenotypes ( Figure S3B). When we examined whether CbAR9 modulates disease resistance to anthracnose, surprisingly, CbAR9 OX plants exhibited strong resistance to anthracnose caused by C. capsici compared with the wild-type plant ( Figure 3A). Quantitative analysis also showed CbAR9 OX plants developed smaller lesions compared to wild-type plants after C. capsici infection ( Figure 3B). To monitor the expression of innate immunity-related genes, we performed RT-qPCR 6 days after C. capsici infection in wild-type and CbAR9 OX plants. We observed strong induction (20-to 50-fold relative to the wild type) of the expression of PR genes such as NbPR1, NbPR2, and NbPR10 in CbAR9 OX ( Figure 3C). However, expression levels of them did not change dramatically in CbAR9 OX compared with wild-type plant after mock treatment ( Figure 3C).
CbAR9 modulates disease resistance to anthracnose, surprisingly, CbAR9 OX plants exhibited strong resistance to anthracnose caused by C. capsici compared with the wild-type plant ( Figure 3A). Quantitative analysis also showed CbAR9 OX plants developed smaller lesions compared to wild-type plants after C. capsici infection ( Figure 3B). To monitor the expression of innate immunity-related genes, we performed RT-qPCR 6 days after C. capsici infection in wild-type and CbAR9 OX plants. We observed strong induction (20-to 50fold relative to the wild type) of the expression of PR genes such as NbPR1, NbPR2, and NbPR10 in CbAR9 OX ( Figure 3C). However, expression levels of them did not change dramatically in CbAR9 OX compared with wild-type plant after mock treatment ( Figure 3C).

CbAR9-Silenced Pepper Plants Are More Susceptible to C.capsici and C. acutatum Infection
To further explore the role of CbAR9 in resistance against C. capsici, we infected the fruits of CbAR9-silenced chili pepper plants with C. capsici for 6 days before scoring the progression of the disease. Accordingly, we silenced CbAR9 in chili pepper fruits by VIGS, which we confirmed by RT-qPCR analysis of silenced chili pepper fruits ( Figure 4A). As a result, we found that CbAR9-silenced pepper fruits exhibited much greater susceptibility to C. capsici infection ( Figure 4B). A quantitative analysis of lesion size caused by C. capsici showed an over 5-fold increase in CbAR9-silenced pepper fruits compared to wild-type fruits ( Figure 4C).
Since overexpression of CbAR9 resulted in higher transcript levels for PR genes after C. capsici inoculation, we determined the effect of CbAR9 silencing on PR gene expression in chili pepper by RT-qPCR on CbAR9-silenced chili pepper fruits inoculated with C. capsici. Silencing of CbAR9 reduced PR1 and PR2 transcript levels in response to C. capsici infection ( Figure 4D).  4-week-old CbAR9 OX and wild-type plants were inoculated with C. capsici. Images were captured after 6 days (A), and the progression of the disease was quantified using the image-based plant disease phenotyping method (B). Scale bars: 1 cm. Data are shown as means ± SD. Asterisks indicate statistical difference from controls (* p < 0.05). (C) Relative NbPR transcript levels in CbAR9 OX N. benthamiana plants after C. capsici inoculation, as determined by RT-qPCR. NbActin served as internal reference. Data are shown as means ± SD. Asterisks indicate statistically significant differences from controls (* p < 0.05 and ** p < 0.01). The experiments were repeated at least three times, with similar results.

CbAR9-Silenced Pepper Plants Are More Susceptible to C. capsici and C. acutatum Infection
To further explore the role of CbAR9 in resistance against C. capsici, we infected the fruits of CbAR9-silenced chili pepper plants with C. capsici for 6 days before scoring the progression of the disease. Accordingly, we silenced CbAR9 in chili pepper fruits by VIGS, which we confirmed by RT-qPCR analysis of silenced chili pepper fruits ( Figure 4A). As a result, we found that CbAR9-silenced pepper fruits exhibited much greater susceptibility to C. capsici infection ( Figure 4B). A quantitative analysis of lesion size caused by C. capsici showed an over 5-fold increase in CbAR9-silenced pepper fruits compared to wild-type fruits ( Figure 4C). Relative CbAR9 transcript levels were determined by RT-qPCR with Actin as an internal reference. Data are shown as means ± SD. Asterisks indicate statistically significant differences from controls (** p < 0.01). The experiments were repeated at least three times, with similar results. (B,C) Anthracnose disease resistance assays with wild-type and VIGS-mediated CbAR9-silenced chili pepper fruits after C. capsici infection. CbAR9silenced and wild-type chili pepper fruits were inoculated with C. capsici. Images were taken 6 days later, and the extent of the disease area was quantified using the image-based plant disease phenotyping method. Data are shown as means ± SD. Asterisks indicate statistically significant differences from controls (* p < 0.05). (D) Relative PR1 and PR2 transcript levels in CbAR9-silenced and wildtype chili pepper fruits after C. capsici infection. Actin served as the internal reference. Data are shown as means ± SD. Asterisks indicate statistically significant differences from controls (** p < 0.01). The experiments were repeated at least three times, with similar results.

Discussion
Chili pepper is a crop with crucial economic importance worldwide, but it can also be susceptible to anthracnose caused by Colletotrichum. Thus, the identification of gene(s) associated with innate immunity against Colletotrichum species is important for pepper plant breeding. Previous genomic analyses suggested that the NLR protein family is a central regulator of anthracnose resistance in chili pepper [6,41]. However, whether, which, and how NLR proteins mediate anthracnose resistance is largely unknown. Since variety PBC80 exhibits BSR to a range of Colletotrichum species such as C. acutatum, C. capsici, and C. gloeosporioides [15], we attempted to identify NLR genes contributing to innate immunity involved in anthracnose resistance in the PBC80 background ( Figure 1A). Accordingly, we describe here CbAR9, which encodes a typical NLR protein, as the likely candidate gene underlying the previously mapped main-effect QTL CcR9 ( Figure 1B). Sequence alignment and phylogenic analysis showed that CbAR9 is highly similar to Relative CbAR9 transcript levels were determined by RT-qPCR with Actin as an internal reference. Data are shown as means ± SD. Asterisks indicate statistically significant differences from controls (** p < 0.01). The experiments were repeated at least three times, with similar results. (B,C) Anthracnose disease resistance assays with wild-type and VIGS-mediated CbAR9-silenced chili pepper fruits after C. capsici infection. CbAR9-silenced and wild-type chili pepper fruits were inoculated with C. capsici. Images were taken 6 days later, and the extent of the disease area was quantified using the image-based plant disease phenotyping method. Data are shown as means ± SD. Asterisks indicate statistically significant differences from controls (** p < 0.01). (D) Relative PR1 and PR2 transcript levels in CbAR9-silenced and wild-type chili pepper fruits after C. capsici infection. Actin served as the internal reference. Data are shown as means ± SD. Asterisks indicate statistically significant differences from controls (** p < 0.01). The experiments were repeated at least three times, with similar results.
Since overexpression of CbAR9 resulted in higher transcript levels for PR genes after C. capsici inoculation, we determined the effect of CbAR9 silencing on PR gene expression in chili pepper by RT-qPCR on CbAR9-silenced chili pepper fruits inoculated with C. capsici. Silencing of CbAR9 reduced PR1 and PR2 transcript levels in response to C. capsici infection ( Figure 4D).

Discussion
Chili pepper is a crop with crucial economic importance worldwide, but it can also be susceptible to anthracnose caused by Colletotrichum. Thus, the identification of gene(s) associated with innate immunity against Colletotrichum species is important for pepper plant breeding. Previous genomic analyses suggested that the NLR protein family is a central regulator of anthracnose resistance in chili pepper [6,41]. However, whether, which, and how NLR proteins mediate anthracnose resistance is largely unknown. Since variety PBC80 exhibits BSR to a range of Colletotrichum species such as C. acutatum, C. capsici, and C. gloeosporioides [15], we attempted to identify NLR genes contributing to innate immunity involved in anthracnose resistance in the PBC80 background ( Figure 1A). Accordingly, we describe here CbAR9, which encodes a typical NLR protein, as the likely candidate gene underlying the previously mapped main-effect QTL CcR9 ( Figure 1B). Sequence alignment and phylogenic analysis showed that CbAR9 is highly similar to homologous proteins associated with disease resistance in various plant species (Figure 2A,B). This observation suggests that CbAR9 may be conserved across pathogen-response signaling pathways, which will be useful for plant breeding of other members of the Solanaceae family.
Genes upregulated by a specific pathogen are often expected to associate with innate immunity against the same pathogen [44][45][46]. Upregulation of CbAR9 transcript levels by C. capsici infection prompted us to speculate that CbAR9 plays a role in anthracnose resistance ( Figure 2C). To elucidate the function of CbAR9, we also generated and analyzed N. benthamiana plants overexpressing CbAR9 ( Figure S3A). Surprisingly, despite the absence of a constitutive immunity phenotype ( Figure S3B), CbAR9 OX plants exhibited enhanced disease resistance to C. capsici compared to wild-type plants ( Figure 3A,B). This result suggested that CbAR9 is activated by pathogen infection, and it provides evidence that CbAR9 is involved in ETI signaling pathway triggered by the recognition of pathogen effectors. However, whether CbAR9 acts as sNLR or hNLR must be clarified in future studies.
Since the activation of NLR proteins commonly leads to significant transcriptional reprogramming [47], we monitored the expression of genes related to innate immunity. RT-qPCR analysis showed that PR genes are dramatically induced in CbAR9 OX plants. As a complementary analysis, we also silenced CbAR9 by VIGS ( Figure 4A). CbAR9-silenced chili pepper fruits showed increased susceptibility to C. capsici infection ( Figure 4B,C), and PR1 and PR2 transcript levels decreased significantly compared to wild-type plants ( Figure 4D). These results showed that CbAR9 is involved in disease response to C. capsici.
Surprisingly, although CbAR9 is 98% identical to the two homologous proteins of other Capsicum species lacking a resistance to C. capsici (Figure 2A), it dramatically increased the innate immunity against C. capsici (Figures 3 and 4). These results imply that the 11 amino acid difference of CbAR9 may be an important site for CbAR9 activation (Figure 2A). A recent study showed that Arabidopsis RRS1/RPS4 NLR protein immune receptor complex is regulated by phosphorylation [48]. Therefore, Ser 216 and Thr 607 on CbAR9 especially need to be tested in future. Investigating and understanding the basis of genetic resistance to relatively understudied pathogen species such as Colletotrichum is important. The effectors from Colletotrichum species and their dedicated NLR receptors in chili pepper remain unknown. Thus, the identification and a deeper understanding of NLR genes from variety PBC80, which exhibits disease resistance to Colletotrichum species, are important for plant breeding. Our findings will offer new options for pepper plant breeding.

Conclusions
Here, we identified CbAR9 encoding nucleotide-binding and leucine-rich repeat protein as the causal locus underlying the large effect quantitative trait locus CcR9 from the anthracnose-resistant chili pepper (C. baccatum) variety PBC80. Interestingly, despite the absence of a constitutive immunity phenotype, the anthracnose resistance and transcript levels of PR genes were significantly increased in CbAR9-expressing transgenic N. benthamiana lines after C. capsici inoculation. Conversely, resistance to anthracnose and transcript levels of PR genes were markedly reduced in CbAR9-silenced chili pepper fruits after C. capsici infection. Taken together, we revealed that CbAR9 which is located on CcR9 locus of PBC80 contributes to innate immunity against C. capsici and regulates gene expression involved in disease response.
The C. baccatum resistant variety PBC80 contains the noble genes conferring disease resistance and BSR to Colletotrichum species, and they are proposed as a vital biotechnological target for introducing anthracnose resistance. Therefore, identification of CbAR9, a positive regulator of innate immunity to anthracnose without a constitutive immune phenotype, may offer new possibilities for crop improvement. Moreover, further elucidation of CbAR9 will explain plant defense mechanism against Colletotrichum species and the role of NLR related to its presence in pepper.

Plant Material and Growth Conditions
Seeds of chili pepper (Capsicum baccatum) variety 'PBC80' and Nicotiana benthamiana (N. benthamiana) were surface sterilized in 70% ethanol for 1 min, followed by 5% sodium hypochlorite for 3 min, and then washed thoroughly with sterilized distilled water. Clean seeds were then sown on half-strength Murashige and Skoog (MS) medium and placed in a chamber with a programmed photoperiod at 28 • C. Depending on the experiment, aseptic seedlings were kept in a growth chamber or transplanted into pots containing soil in a greenhouse under a programmed 16-h light/8-h dark photoperiod at 28 • C. The humidity was adjusted to 50%.

Cloning of CbAR9 and Web-Based Analysis
The full-length cDNA of CbAR9 (PHT39462) was amplified by PCR with the primers listed in Table S2 from first-strand cDNA prepared from total RNA extracted from variety PBC80. The CbAR9 cDNA was inserted into the pENTR entry vector using Gateway BP Clonase II enzyme (Invitrogen, Waltham, MA, USA), and then recombined into destination vectors [49] using Gateway LR Clonase II enzyme (Invitrogen, Waltham, MA, USA) as per the manufacturer's instructions. For subcellular localization and generation of transgenic plants, the CbAR9 cDNA was recombined into the pEarleyGate101 and the pEarleyGate201 vectors, respectively.

Total RNA Extraction and RT-qPCR Analysis
Total RNA was extracted using TRIzol reagent (Invitrogen, Waltham, MA, USA). First-strand cDNA synthesis was initiated from 2 µg of total RNA using Superscript III reverse transcriptase (Invitrogen, Waltham, MA, USA) according to the manufacturer's instructions. RT-qPCR was performed using gene-specific primers (Table S1) on a MyiQ Real-Time PCR System (Bio-Rad, Hercules, CA, USA) using SYBR Green Master Mix (Bio-Rad, Hercules, CA, USA) under the following conditions: 40 cycles of denaturation at 95 • C for 10 s, annealing at 58 • C for 15 s, and extension at 72 • C for 30 s. Relative transcript levels were quantified using the comparative Ct method, with Actin as an internal reference. All experiments were independently conducted at least three times.

N. benthamiana Transformation
To generate transgenic plants overexpressing CbAR9, the pEarleyGate201-CbAR9 construct was introduced into Agrobacterium strain LBA4404 by electroporation. Positive colonies harboring the construct were selected based on resistance to appropriate antibiotics and grown in YEP medium. Agrobacterium-mediated leaf disk transformation was performed as previously described [50]. Transgenic N. benthamiana lines were selected on MS plates containing antibiotic and propagated to obtain homozygous T 3 lines. All transgenic lines were verified by RT-qPCR, and two T 3 lines were chosen for detailed analyses.

Anthracnose Disease Resistance Assay
To test whether CbAR9 modulates disease resistance to anthracnose, we infected CbAR9 OX plants with C. capsici and followed the progression of the disease. Previously reported CbCN OX plant lines conferring disease resistance to C. acutatum were used as the control [43]. C. capsici was cultured on potato dextrose agar (PDA) medium for 3 to 7 days with a programmed 12-h light/12-h dark photoperiod at 28 • C. Conidial suspensions were collected in 3 mL of sterile distilled water using a scalpel and filtered through two layers of cheesecloth. Their density was adjusted to 1 × 10 6 conidia/mL by adding sterile distilled water and counting with a hemacytometer. Anthracnose disease resistance was assayed using the pinning method with a toothpick for N. benthamiana leaves and by microinjection for chili pepper fruits, as previously described [51]. The inoculated plant tissues were incubated at 28 • C for 6 days. For a more quantitative analysis, the extent of lesion areas was measured using an image-based plant disease phenotyping method [52]. All experiments were performed in triplicate. Consistent results were obtained, and representative data from one replicate are shown.

Virus-Induced Gene Silencing (VIGS) of CbAR9 in Chili Pepper
Transcription levels of CbAR9 were silenced using virus-induced gene silencing (VIGS). Previously reported construct of VIGS for CbCN silencing was also used as the control [43]. VIGS was performed as previously described [53] with slight modifications. Briefly, the target sequence of CbAR9 for VIGS was amplified by PCR using specific primers (Table  S1) and inserted into the pTRV2 vector. The pTRV1 and pTRV2-CbAR9 constructs were transformed into Agrobacterium strain GV3101 by electroporation. Positive colonies harboring the constructs were selected based on resistance to appropriate antibiotics and grown overnight at 28 • C in YEP medium. The cultures were harvested by quick centrifugation and resuspended in MMA buffer (10 mM MES, 10 mM MgCl 2 , and 200 µM acetosyringone) to a final OD 600 of 0.7. Cell suspensions harboring pTRV1 and pTRV2-CbAR9 were mixed in a 1:1 (v/v) ratio and infiltrated into chili pepper fruits. The inoculated fruits were placed in the dark at 20 • C in 50% relative humidity for 48 h. The plants were then moved to the growth chamber under a 16-h light/8-h dark photoperiod at 28 • C and incubated for 6 days.

Statistical Analysis
All experiments were independently conducted at least three times, and the data were analyzed by t-test using GraphPad Prism 8.0 software, and asterisks denote significant differences (* p < 0.05, ** p < 0.01).