Silencing of the Chitin Synthase Gene Is Lethal to the Asian Citrus Psyllid, Diaphorina citri

Chitin synthase is a critical enzyme that catalyzes N-acetylglucosamine to form chitin, which plays an important role in the growth and development of insects. In this study, we identified a chitin synthase gene (CHS) with a complete open reading frame (ORF) of 3180 bp from the genome database of Diaphorina citri, encoding a protein of 1059 amino acid residues with the appropriate signature motifs (EDR and QRRRW). Reverse transcription-quantitative PCR (RT-qPCR) analysis suggested that D. citri CHS (DcCHS) was expressed throughout all developmental stages and all tissues. DcCHS had the highest expression level in the integument and fifth-instar nymph stage. Furthermore, the effects of diflubenzuron (DFB) on D. citri mortality and DcCHS expression level were investigated using fifth-instar nymph through leaf dip bioassay, and the results revealed that the nymph exposed to DFB had the highest mortality compared with control group (Triton-100). Silencing of DcCHS by RNA interference resulted in malformed phenotypes and increased mortality with decreased molting rate. In addition, transmission electron microscopy (TEM) and fluorescence in situ hybridization (FISH) also revealed corresponding ultrastructural defects. Our results suggest that DcCHS might play an important role in the development of D. citri and can be used as a potential target for psyllid control.


Introduction
The Asian citrus psyllid (ACP), Diaphorina citri Kuwayama (Hemiptera: Liviidae), is a notorious pest across Asia, USA, and Brazil, causing severe economic losses in the citrus industry [1]. However, the greatest threat of ACP arises from the transmission of "Candidatus Liberibacter asiaticus (CLas)", which causes citrus greening disease, also called huanglongbing (HLB) [2]. Up to this date, psyllid control plays a leading role to prevent HLB from spreading. At present, the application of insecticides is the most widely followed option for reducing ACP populations. However, the improper use of insecticide will lead to pest resistance, human poisoning, and environmental pollution [3,4]. Therefore, there is a great need to find environmentally friendly methods to control the citrus psyllid.
During the growth and development of insects, periodic molting, the process of shedding and replacing the rigid insect exoskeleton is required. During this process, the degraded old cuticle is shed and replaced with a newly synthesized cuticle. Insects are covered by this cuticle, which is a composite structure consisting of chitin filaments embedded in a protein matrix. The insect cuticle undertakes various functional roles, including protection, support, movement, and as a shield against environmental stress [5]. Chitin, a polymer of N-acetylglucosamine, is an essential component of the

Analysis of the cDNA and Protein Sequences of DcCHS
The cDNA sequence of DcCHS (XP_017303059) contains an ORF of 3180 bp encoding a protein of 1059 amino acid residues with a predicted MW of 129.9 kDa and pI of 5.02 ( Figure 1A). Gene structure analysis showed that DcCHS contains 19 exons and 18 introns ( Figure 1B). In terms of protein structure, a total of 14 transmembrane helices, two low-complexity regions, and a coiled-coil region were identified ( Figure 1C). A BLASTP search of the NCBI databases indicated that the amino acid sequence of DcCHS shared 42.75%, 42.67%, and 42.30% with Acyrthosiphon pisum, Toxoptera citricida, and Aphis glycines, respectively. Based on the amino acid sequences of CHS from different insect species, a phylogenetic tree was generated using MEGA 5.0 to investigate the evolutionary relationship of DcCHS among the selected insect species. The results showed that DcCHS has a close relationship with the CHSs of sap-sucking hemipterans, including A. pisum, T. citricida, and A. glycines (Figure 2). acid sequence of DcCHS shared 42.75%, 42.67%, and 42.30% with Acyrthosiphon pisum, Toxoptera citricida, and Aphis glycines, respectively. Based on the amino acid sequences of CHS from different insect species, a phylogenetic tree was generated using MEGA 5.0 to investigate the evolutionary relationship of DcCHS among the selected insect species. The results showed that DcCHS has a close relationship with the CHSs of sap-sucking hemipterans, including A. pisum, T. citricida, and A. glycines ( Figure 2).

Spatiotemporal Expression Profiles of DcCHS
The expression profiles of DcCHS in different developmental stages and different tissues were investigated by RT-qPCR. The results showed that the DcCHS gene was expressed in all tissues, including midgut, integument, leg, wing, and head. It is notable that DcCHS had high expression in the integument, while it had low expression in the midgut. The expression level of DcCHS in the integument was 44.3 times of that in the midgut, and its expression in the leg was 25.1 times of that in the midgut (Figure 3). The expression of DcCHS decreased from first-instar nymph to third-instar nymph, while it increased from third-instar nymph to fifth-instar nymph, and decreased sharply from fifth-instar nymph stage to adult stage ( Figure 3). The expression level of DcCHS in the fifth-instar nymph was 3.6 times that of the third-instar nymph stage.

Spatiotemporal Expression Profiles of DcCHS
The expression profiles of DcCHS in different developmental stages and different tissues were investigated by RT-qPCR. The results showed that the DcCHS gene was expressed in all tissues, including midgut, integument, leg, wing, and head. It is notable that DcCHS had high expression in the integument, while it had low expression in the midgut. The expression level of DcCHS in the integument was 44.3 times of that in the midgut, and its expression in the leg was 25.1 times of that in the midgut ( Figure 3). The expression of DcCHS decreased from first-instar nymph to third-instar nymph, while it increased from third-instar nymph to fifth-instar nymph, and decreased sharply from fifth-instar nymph stage to adult stage ( Figure 3). The expression level of DcCHS in the fifth-instar nymph was 3.6 times that of the third-instar nymph stage.  Relative mRNA levels of DcCHS as examined using RT-qPCR. Data were normalized using glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and are represented as the means ± standard errors of the means from three independent experiments. Relative expression levels were calculated using the 2 −∆∆Ct method. Statistical analysis was performed using SPSS software. The significant differences are indicated by a different letter, for example, a, b, and c (P < 0.05).

Effect of DFB on D. Citri Survival and DcCHS Expression Level
A leaf-dip bioassay was used to assay the effect of DFB on D. citri survival and DcCHS expression level. After being exposed for 24 h, the cumulative mortality of D. citri had no significant change between DFB treatment group and control (Triton-100 treatment group). However, the cumulative mortality of DFB sharply increased after exposure to DFB for 48 h ( Figure 4B). In addition, D. citri in the DFB treatment group showed an abnormal phenotype after molting and the wing of adult exhibited crimp ( Figure 4A). The relative expression level of DcCHS was significantly upregulated after DFB exposure at 24 h and 48 h ( Figure 4C). Relative mRNA levels of DcCHS as examined using RT-qPCR. Data were normalized using glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and are represented as the means ± standard errors of the means from three independent experiments. Relative expression levels were calculated using the 2 −∆∆Ct method. Statistical analysis was performed using SPSS software. The significant differences are indicated by a different letter, for example, a, b, and c (P < 0.05).

Effect of DFB on D. citri Survival and DcCHS Expression Level
A leaf-dip bioassay was used to assay the effect of DFB on D. citri survival and DcCHS expression level. After being exposed for 24 h, the cumulative mortality of D. citri had no significant change between DFB treatment group and control (Triton-100 treatment group). However, the cumulative mortality of DFB sharply increased after exposure to DFB for 48 h ( Figure 4B). In addition, D. citri in the DFB treatment group showed an abnormal phenotype after molting and the wing of adult exhibited crimp ( Figure 4A). The relative expression level of DcCHS was significantly upregulated after DFB exposure at 24 h and 48 h ( Figure 4C). levels were calculated using the 2 −∆∆Ct method. Statistical analysis was performed using SPSS software. The significant differences are indicated by a different letter, for example, a, b, and c (P < 0.05).

Effect of DFB on D. Citri Survival and DcCHS Expression Level
A leaf-dip bioassay was used to assay the effect of DFB on D. citri survival and DcCHS expression level. After being exposed for 24 h, the cumulative mortality of D. citri had no significant change between DFB treatment group and control (Triton-100 treatment group). However, the cumulative mortality of DFB sharply increased after exposure to DFB for 48 h ( Figure 4B). In addition, D. citri in the DFB treatment group showed an abnormal phenotype after molting and the wing of adult exhibited crimp ( Figure 4A). The relative expression level of DcCHS was significantly upregulated after DFB exposure at 24 h and 48 h ( Figure 4C). . The mean expression level represented for three biological replicates. Relative expression levels were calculated using the 2 −∆∆Ct method. Statistical analysis was performed using SPSS software. The significant differences are indicated by * (P < 0.05) or ** (P < 0.01).

Localization of DcCHS Transcript by FISH
In order to confirm localization of DcCHS transcript in D. citri, FISH was performed using DcCHS RNA probes. The results showed that DcCHS transcript was evenly distributed in the epidermal cells ( Figure 5). The fluorescence signal is the strongest in exocuticle epidermal cells of D. citri, indicating DcCHS is mainly involved in synthesis of chitin in new cuticle. . The mean expression level represented for three biological replicates. Relative expression levels were calculated using the 2 −∆∆Ct method. Statistical analysis was performed using SPSS software. The significant differences are indicated by * (P < 0.05) or ** (P < 0.01).

Localization of DcCHS Transcript by FISH
In order to confirm localization of DcCHS transcript in D. citri, FISH was performed using DcCHS RNA probes. The results showed that DcCHS transcript was evenly distributed in the epidermal cells (

RNAi-Based Silencing of DcCHS and Epidermal Structure Analysis
To determine the effect of DcCHS on D. citri molting, RNAi was performed by ingestion of dsRNA. At 24 h after feeding D. citri with double-stranded DcCHS (dsDcCHS), the expression level of DcCHS was significantly downregulated compared with the controls (double-stranded green fluorescent protein (dsGFP) treatment group) ( Figure 6A). In the dsDcCHS treatment group, many

RNAi-Based Silencing of DcCHS and Epidermal Structure Analysis
To determine the effect of DcCHS on D. citri molting, RNAi was performed by ingestion of dsRNA. At 24 h after feeding D. citri with double-stranded DcCHS (dsDcCHS), the expression level of DcCHS was significantly downregulated compared with the controls (double-stranded green fluorescent protein (dsGFP) treatment group) ( Figure 6A). In the dsDcCHS treatment group, many adults did not complete wing development and presented an abnormal wing phenotype after molting ( Figure 6B). Importantly, the cumulative mortality in the dsDcCHS treatment group was 27% compared to 10% mortality in the group at 48 hpt. The mortality of D. citri increased from 24 hpt to 48 hpt in the treatment group, whereas control group had no significant change ( Figure 7A). In addition, the cumulative molting of D. citri was 53.3% in the treatment group at 48 hpt. However, in the control group, the molting could reach 86.7% ( Figure 7B). These results indicated that RNAi effectively inhibited the relative expression level of DcCHS and resulted in the abnormal D. citri phenotype.   To further analyze the effect of epidermal structure after silencing of DcCHS, TEM observation was conducted at 24 h after RNAi treatment. The results showed that the formation of exocuticle was inhibited compared with the control group, while the structure of endocuticle has no significant change (Figure 8). Insect cuticle is primarily composed of epicuticle and procuticle, and procuticle is comprised of the exocuticle and endocuticle. Chitin is found mainly in exocuticle and endocuticle. These results suggested that knockdown of DcCHS will inhibit the synthesis of chitin and further disrupt the structure of D. citri cuticle.

Discussion
Chitin is a major component of the exoskeleton and the peritrophic matrix of insects. The synthesis of chitin is catalyzed by many enzymes. Among them, chitin synthases (CHSs) play important roles during insect development and metamorphosis [8]. To date, CHS genes have been identified from many insect species, including those in the Lepidoptera, Hemiptera, Hymenoptera, Diptera, and Coleoptera. The number of genes encoding CHS in different fungal species can range from 1 to 20, while in insect genomes characterized so far individual species contain only two CHS genes (CHS-1 and CHS-2) [20]. CHS-A is responsible for chitin synthesis in the cuticle and cuticular lining of the foregut, hindgut, and trachea, whereas CHS-B is dedicated to chitin synthesis in the PM [21]. In this study, only one CHS gene was identified from the genome of D. citri, which was named DcCHS (Figure 1). In a previous report, many hemipterous insects only contain a single CHS gene, including A. glycines, Sogatella furcifera, and A. pisum [18]. We considered that Hemiptera insects lack the PM structure. Terry et al. revealed that the insect PM was lost, leading to the compartmentalization of the digestive process and ultimately increased digestion of polymers during the course of evolution [22]. The insect CHS proteins usually contain 15 transmembrane helices that flank the catalytic domain located on the cytoplasmic side of the plasma membrane [10]. We found that DcCHS contains 14 transmembrane helices (Figure 1). Depending on the number of predicted transmembrane helices, the N-terminus faces either the extracellular space or the cytoplasm. However, the C-terminus region is predicted to face the extracellular space and may be involved in protein-protein interaction or oligomerization [5,23]. In addition, DcCHS has two

Discussion
Chitin is a major component of the exoskeleton and the peritrophic matrix of insects. The synthesis of chitin is catalyzed by many enzymes. Among them, chitin synthases (CHSs) play important roles during insect development and metamorphosis [8]. To date, CHS genes have been identified from many insect species, including those in the Lepidoptera, Hemiptera, Hymenoptera, Diptera, and Coleoptera. The number of genes encoding CHS in different fungal species can range from 1 to 20, while in insect genomes characterized so far individual species contain only two CHS genes (CHS-1 and CHS-2) [20]. CHS-A is responsible for chitin synthesis in the cuticle and cuticular lining of the foregut, hindgut, and trachea, whereas CHS-B is dedicated to chitin synthesis in the PM [21]. In this study, only one CHS gene was identified from the genome of D. citri, which was named DcCHS (Figure 1). In a previous report, many hemipterous insects only contain a single CHS gene, including A. glycines, Sogatella furcifera, and A. pisum [18]. We considered that Hemiptera insects lack the PM structure. Terry et al. revealed that the insect PM was lost, leading to the compartmentalization of the digestive process and ultimately increased digestion of polymers during the course of evolution [22]. The insect CHS proteins usually contain 15 transmembrane helices that flank the catalytic domain located on the cytoplasmic side of the plasma membrane [10]. We found that DcCHS contains 14 transmembrane helices (Figure 1). Depending on the number of predicted transmembrane helices, the N-terminus faces either the extracellular space or the cytoplasm. However, the C-terminus region is predicted to face the extracellular space and may be involved in protein-protein interaction or oligomerization [5,23]. In addition, DcCHS has two conserved domains with chitin synthase signature motifs, i.e., EDR and QRRRW in the catalytic domain, which is essential for the catalytic mechanism [24]. The phylogenetic tree analysis indicated that CHS from D. citri has a close relationship with A. pisum and belongs to the CHS1 group. Interestingly, many studies have proved that the CHS1 gene contains alternative splicing [25,26]. In the present study, the genome analysis of D. citri revealed no splice variants exist. Bansal et al. also found that splice variants of CHS1 do not exist in the A. glycines genome [18]. However, the specific reasons for this apparent loss need to be researched in depth.
The relative expression level of DcCHS was determined in different tissues and different developmental stages. Results suggested that DcCHS had a relatively higher expression in the integument, followed by the leg, but it had low expression in the midgut (Figure 3). Our results are in agreement with the roles of CHS in chitin production in the insect exoskeleton [27]. In insects, chitin functions as a scaffold material, supporting the cuticles of the epidermis [5]. In Sogatella furcifera, CHS1 was also predominantly expressed in the integument [28]. Therefore, we speculated that DcCHS may play a critical role in the process of cuticle formation. Additionally, the phenomenon of low expression of CHS in the midgut was also observed in Plutella xylostella and Nilaparvata lugens [6,29]. At different developmental stages, DcCHS had a higher expression in the fifth-instar nymph stage (Figure 3). The fifth-instar nymph stage is a critical period that involves progressing from nymph stage into adult stage [30]. During molting period, the synthesis of chitin is required to maintain rigid structure of new cuticle in D. citri.
Chitin is synthesized by insects and fungi but not by vertebrates, so chitin synthase presents a novel target for pest control. In recent years, the exploration of inhibitors of chitin synthesis has received extensive attention [17]. DFB is an insect growth regulator acting on chitin synthesis, which was discovered in the 1970s [31]. It was used as a potential insecticide for pest control in forestry and agriculture [32]. In a previous research, Tiwari et al. revealed that DFB could effectively suppress D. citri adult emergence [4]. However, the specific molecular mechanisms are unclear. In this study, we found that DFB can increase the expression of DcCHS and lead to higher mortality of D. citri ( Figure 4). In many insect species, DFB has been found to elevate CHS expression level. Zhang et al. revealed a significant increase of CHS1 mRNA level in Anopheles quadrimaculatus larvae exposed to DFB at 100 and 500 µg/L [33]. In T. citricida, the mRNA expression levels of TCiCHS were significantly increased upon the exposure of nymphs to both low and high DFB concentrations [19]. At 48 h post DFB treatment (hpt), the cumulative mortality in the treatment group was significantly greater than the control group, whereas it showed no obvious change at 24 hpt. Therefore, we speculated that DFB can reduce the chitin content by inhibition of chitin synthase activity. The increasing DcCHS expression levels may also indicate the existence of a feedback regulatory mechanism that compensates for the low enzyme content.
RNA interference (RNAi) has already proven its usefulness in functional genomics research on insects, but it also has considerable potential for the control of pest insects [34]. When monitoring RNAi responses using different delivery methods, variable efficiency is very common in different insect species, e.g., the physiological pH of hemolymph significantly affected the efficiency of RNAi in Locusta migratoria [35]. In this study, we performed RNAi experiments through the feeding of dsRNA. The results showed that DcCHS was silenced effectively ( Figure 5). In recent years, RNAi combined with RT-qPCR has been widely used to research the functions of target genes. Yu et al. revealed that silencing of transformer-2 gene influenced female reproduction and offspring sex in D. citri [36]. Kishk et al. used RNAi to silence genes implicated in pesticide resistance in order to increase susceptibility, and the results suggested that the treatments with dsRNA caused concentration-dependent nymph mortality [37]. In addition, we found that D. citri showed increased cumulative mortality and abnormal phenotypes after silencing of DcCHS ( Figure 6). In this regard, many reports on RNAi mediated knockdown of insect CHS genes resulting in lethal phenotypes are encouraging [15,38,39]. Chitin is the main component of exocuticle and endocuticle [40]. We found that the formation of exocuticle was inhibited after knockdown of DcCHS, while the structure of endocuticle had no significant change, indicating the decrease of chitin content will influence the structure of cuticle. These results further indicated that DcCHS could be used as a new target for control of D. citri.
D. citri nymphs were classified to different stages according to their morphological features and collected using an aspirator. D. citri adults were divided into three groups, and then each group was dissected to obtain the midgut, head, leg, wing, and integument. The collected tissues were cleaned with DEPC water and stored at −80 • C until use. Each experiment was conducted in three biological replicates.

RNA Isolation and cDNA Synthesis
To obtain the cDNA template for spatiotemporal expression analysis of DcCHS, total RNA was isolated from different tissues of adult insects (head, midgut, leg, wing, and integument) and at different developmental stages of the nymph (first-instar, second-instar, third-instar, fourth-instar, and fifth-instar nymphs) using a RNA extraction kit (TaKaRa Biotechnology Co. Ltd., Dalian, China). The integrity of total RNA was confirmed using standard agarose gel electrophoresis with ethidium bromide staining. RNA quantification was performed using a NanoDrop 2000 spectrophotometer (Thermo Fisher Scientific, New York, NY, USA). The purity of all RNA samples was assessed at an absorbance ratio of A 260/230 and A 260/280 . Total RNA was reverse-transcribed in a 20 µL reaction system using a cDNA synthesis master mix kit according to the manufacturer's instructions (Simgen, Hangzhou, Zhejiang, China). In brief, 2.0 µL of 5 × gRNA buffer and 1 µg of total RNA were mixed, then RNase-free water was added to reach 10 µL, which was then incubated at 42 • C for 3 min. Afterward, 4 µL of 5 × RT buffer, 2 µL of RT enzyme mix, and 4 µL RT primer mix were added to the tube. The mixture was incubated at 42 • C for 15 min and then incubated at 95 • C for 3 min. The cDNA was stored at −20 • C for later use.

Identification of DcCHS and Bioinformatics Analysis
To identify chitin synthase genes in D. citri, sequences of Nilaparvata lugens CHS (NlCHS: AEL88648.1) and A. pisum CHS (ApCHS: XP_003247517.1) were used as query in a TBLASTN search of genome database of D. citri. The cDNA and deduced amino acid sequence of DcCHS were analyzed by using DNASTAR. The open reading frame (ORF) was identified according to the ORF finder tool (https://www.ncbi.nlm.nih.gov/orffinder/) at the National Center for Biotechnology Information (NCBI). The molecular weight (MW) and isogenic point (pI) of DcCHS were calculated using ExPASy (http://web.expasy.org/compute_pi). The signal peptide of DcCHS was predicted using SignalP 4.1 Server (http://www.cbs.dtu.dk/services/SignalP). The functional domain was predicted by using SMART software (http://smart.embl-heidelberg.de/). The membrane-spanning domain was predicted by TMHMM Server v. 2.0. The phylogenetic tree was constructed with MEGA 7.0 software using the neighbor-joining method with 1000-fold bootstrap resampling. Protein sequences from different species were downloaded from GenBank (http://www.ncbi.nlm.nih.gov/) and used in phylogenetic analysis (Table S1).

RT-qPCR Analysis of DcCHS Expression Levels
RT-qPCR was conducted to confirm the relative expression levels of DcCHS in various tissues and developmental phases. The primers were designed using Primer Premier 5.0 software (Premier Biosoft, www.premierbiosoft.com) ( Table 1). The 20 µL of reaction mixture for the RT-qPCR contained 10 µL of SYBR II, 8 µL of ddH 2 O, 0.5 µL of forward primer, 0.5 µL of reverse primer, and 1.0 µL of cDNA template. The thermal cycling profile consisted of an initial denaturation at 95 • C for 60 s, and 40 cycles of 95 • C for 10 s, 60 • C for 10 s, and 72 • C for 10 s. The reactions were performed with a LightCycle ® 96 PCR Detection System (Roche, Basel, Switzerland). Relative expression levels were calculated by using the 2 −∆∆Ct method. There were three biological replicates and three technique replicates for each sample. The reference gene chosen for analysis of DcCHS in different tissues and different developmental phases was glyceraldehyde-3-phosphate dehydrogenase (GAPDH). This gene was cited as a reference in previous studies involving expression analyses in D. citri [41]. All ANOVAs were followed by Fisher's protected least significant difference (LSD) tests.

Leaf-Dip Bioassay
To determine whether DFB can affect the expression of DcCHS and increase the mortality of D. citri, we used a leaf-dip bioassay according to a previous protocol with some modifications [32]. In brief, about 0.05 g of DFB (LKT Laboratories Inc., Saint Paul, MN, USA) was added into 10 mL acetone and dissolved completely as a stock solution (5000 mg/L). The stock solution was diluted into a low concentration (300 mg/L) using ddH 2 O, and 50 µL of Triton-100 (0.1%) was added. Detached tender leaves of Murraya koenigii were dipped into the DFB working solution for 5 min and air-dried for 1 h, after which 40 fifth-instar D. citri nymphs were transferred to each leaf. Leaves treated with ddH 2 O containing 0.1% Triton-100 were used as a control. The number of deaths and molts were counted at 24 h and 48 h after DFB exposure. In addition, the surviving D. citri were kept at −80 • C for RNA isolation. The relative expression levels of DcCHS were analyzed by RT-qPCR as described above. All experiments were performed using three biological replicates.

dsRNA Synthesis and DcCHS RNAi Analysis
The primers for DcCHS were designed to synthesize dsRNA using the T7 RioMAX Express RNAi System (Promega, San Luis Obispo, CA, USA) based on the manufacturer's instructions. GFP dsRNA was used as a control. The dsRNA delivery was performed by using an artificial diet according to a previous method [42]. In brief, 30 newly emerged fifth-instar D. citri nymphs were used in dsRNA treatment. All nymphs were allowed to feed on an aliquot of the artificial diet (150 µL) placed between two layers of stretched Parafilm. The artificial diet consisting of 20% (w:v) sucrose was mixed with dsDcCHS at a final concentration of 150 ng/µL. After 24 h, all live insects were collected to isolate total RNA and synthesize cDNA. The effect of dsDcCHS on gene expression was evaluated by RT-qPCR. A total of three biological replicates were used for each experiment.

Fluorescence In Situ Hybridization (FISH) Analysis
FISH was performed to confirm the specific distribution of DcCHS transcript in D. citri. The RNA probes of DcCHS (5 -Cy3-CGUAAGUCCUUCAAAUCGCUCGUAAUUCGACUCUG-3 ) were synthesized by Rochen Biotechnology (Rochen, Shanghai, China). FISH was conducted according to previous protocol with some modification [43]. In brief, the dissected integument samples were fixed in 4% paraformaldehyde for about 8 h at 4 • C and then washed using PBST (PBS+Triton X-100) for three times (5 min each), treated with proteinase K (50 µg/mL in PBST). The fixed tissues were prehybridized in hybridization buffer at 37 • C for 1 h and then hybridized in the same hybridization buffer containing 10 µg/mL RNA probes overnight at 37 • C. After hybridization, the samples were washed using 2 × SSC at 37 • C for 10 min, 1 × SSC at 37 • C for 5 min, and 0.5 × SSC at 37 • C for 10 min to remove remaining hybridization buffer, and then moved to a fresh microscope slide containing 30 µL of new hybridization buffer supplemented with DAPI and kept with a liquid blocker. At last, the samples were visualized under an Olympus fluorescence microscope equipped with Cy3 filter set.

Transmission Election Microscopy (TEM) Analysis
To investigate the transformation of epidermal structure after silencing of DcCHS, TEM was used following a previous report [21]. Abdominal integument of a hatched adult was dissected and fixed in 2.5% glutaraldehyde of PBS at 4 • C overnight and then fixed in 1% osmic acid at 4 • C for 3 h. After fixation, all samples were washed three times using 0.1 M PBS. The fixed integuments were dehydrated through incubation in a graded series of ethanol washes (50%, 70%%, 80%, 85%, 90%, 95%, and 100%, v/v) for 15 min each and then further dehydrated twice using 100% ethanol for 10 min each. The dehydrated samples were consecutively soaked by penetrant 1 (2:1 mixture of acetone and epoxy resin), penetrant 2 (1:1 mixture of acetone and epoxy resin), and penetrant 3 (epoxy resin) at 37 • C for 12 h. Finally, the samples were embedded at 60 • C for 48 h. The ultrathin (100 nm) sections were cut with a Leica microtome (Leica, Wetzlar, Germany). The sections were stained with 3% uranyl acetate and alkaline lead citrate and observed using TEM with a mode (Tecnai G2 20 S-TWIN, EDX: GENESIS 2000) at an accelerating voltage of 200 kV.

Conclusions
In conclusion, the cDNA sequence of DcCHS was identified from the genome database of D. citri. Spatiotemporal expression analysis suggested that DcCHS was highly expressed in the integument and fifth-instar nymph stage. In addition, DcCHS was upregulated and the cumulative mortality of D. citri increased after exposure to DFB, an inhibitor of chitin synthesis. Furthermore, RNAi-based gene silencing inhibited the expression of DcCHS and influenced the structure of cuticle, resulting in malformed phenotypes. Taken together, these results indicated DcCHS as a new target for control of D. citri.