Multilocus Sequence Analysis and Detection of Copper Ion Resistance of Xanthomonas phaseoli pv. manihotis Causing Bacterial Blight in Cassava
Key Laboratory of Integrated Pest Management on Tropical Crops, Ministry of Agriculture and Rural Affairs, Environment and Plant Protection Institute, Chinese Academy of Tropical Agricultural Sciences, Haikou 571101, China
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Author to whom correspondence should be addressed.
Curr. Issues Mol. Biol. 2023, 45(7), 5389-5402; https://doi.org/10.3390/cimb45070342
Submission received: 3 June 2023
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Revised: 24 June 2023
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Accepted: 26 June 2023
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Published: 28 June 2023
(This article belongs to the Collection Feature Papers in Current Issues in Molecular Biology)
Abstract
:Cassava (Manihot esculenta Crantz) is an important tropical tuber crop around the world. Cassava bacterial blight, caused by Xanthomonas phaseoli pv. manihotis, is a key disease that influences cassava production worldwide. Between 2008 and 2020, 50 X. phaseoli pv. manihotis strains were isolated from diseased plant samples or acquired from China, Uganda, Cambodia, Colombia, Malaysia, and Micronesia. Using multilocus sequence analysis, the genetic diversity of X. phaseoli pv. manihotis strains was evaluated. A neighbor-joining phylogenetic dendrogram was constructed based on partial sequences of five housekeeping genes (atpD-dnaK-gyrB-efp-rpoD). The strains clustered into three groups whose clusters were consistent with atpD and RpoD gene sequences. Group I contained 46 strains from China, Uganda, Cambodia, and Micronesia, and the other two groups were comprised of strains from Colombia and Malaysia, respectively. The resistance of all these strains to copper ion (Cu2+) was determined, the minimal inhibitory concentration was between 1.3 and 1.7 mM, and there was no significant difference between strains from different geographic region. During genome annotation of the X. phaseoli pv. manihotis strain CHN01, homologous gene clusters of copLAB and xmeRSA were identified. The predicted amino acid sequences of two gene clusters were highly homologous with the copper-resistant protein from Xanthomonas strains. CopLAB and xmeRSA were amplified from all these strains, suggesting that the regulation of copper resistance is associated with two distinct metabolic pathways. CopLAB and xmeRSA were highly conserved among strains from different geographic regions, possibly associated with other conserved function.
1. Introduction
Cassava (Manihot esculenta Crantz) is an important tropical tuber crop widely cultivated in Africa, Latin America, and Asia. It is the third-largest source of calories for more than one billion people in the tropics. In many developing countries, cassava is a common economic crop. In 2021, the total harvest area of cassava was 296.52 thousand km2, and the yield was 314.81 billion kg [1].
Cassava was first introduced in Guangdong province of China around the 1820s. Now, cassava is widely cultivated in southern China, and experimental introduction was successfully finished in Henan, Shandong, and other northern provinces. Guangxi province currently accounts for the largest cultivation area of cassava in China, followed by Guangdong, Hainan, and Yunnan provinces. In 2021, the cultivation area was 3027.80 km2, and the dry chip yield was 4.95 billion kg [1]. In China, most of the cassava yield is used for the production of starch, ethanol, and many other products, and it plays a significant role in local industry. However, China is not self-sufficient in cassava production and became the largest importer of cassava from 2005.
Cassava bacterial blight (CBB) caused by Xanthomonas phaseoli pv. Manihotis (previously also known as Xanthomonas campestris pv. manihotis or Xanthomonas axonopodis pv. manihotis) is a disease that impacts cassava production worldwide. CBB was first reported in 1912 by Bondar in Brazil and has now spread to 48 main cassava-planting countries located in tropical and part subtropical regions [2]. It is identified by the presence of angular, water-soaked leaf lesions, blight, partial or total wilting of the branches, dieback, and necrosis of some vascular strands of the stems. Diseased plants show lowered growth potential or even death, usually leading to 12% to 100% yield losses [3,4]. In 1980, CBB was first identified in China in a cassava nursery located in Danzhou, Hainan and then detected in Guangdong and Guangxi provinces [5]. Recently, a comprehensive disease survey showed that CBB is popular in the major cassava-planting areas in China and has become the most destructive disease, the main cassava cultivars being susceptible [6].
The most appropriate and realistic approach for controlling crop disease is through host resistance, so genetic variation is very important for understanding the breakdown of resistance to the pathogen. Multilocus sequence analysis (MLSA), a joint analysis of multiple conserved genetic loci, is a commonly used technique for species definition in bacteriology, including reevaluation of species, pathogen identification, classification, and phylogenetic analysis [7,8,9]. The housekeeping genes atpD (F0F1-ATP synthase β subunit), dnaK (molecular chaperone), glnA (glutamine synthase), gyrB (DNA gyrase β subunit), efp (elongation factor P), rpoD (RNA polymerase sigma-70), abc (ATP-binding cassette), and fyuA (TonB-dependent receptor) have been frequently used in MLSA-based phylogenetic analyses. Ntambo et al. (2019) amplified and sequenced five housekeeping genes—gyrB, glnA, rpoD, atpD, and abc—in 14 Xanthomonas albilineans samples collected in China. MLSA-based phylogenetic analysis showed these samples and 13 other strains (not from China) were distributed in two distinct clades [10]. The population structure of 50 Xanthomonas campestris pv. Campestris (Xcc) strains isolated from infected cabbage was examined by MLSA of four genes—atpD, fyuA, gyrB, and rpoD—to generate 12 allelic profiles. Similar diversity of these 50 Xcc strains was observed using repetitive-DNA-sequence-based PCR (rep-PCR) simultaneously, and 31 strains showed the same allelic profiles [11].
Restrepo et al. (2000) assessed the genetic diversity of 238 X. phaseoli pv. manihotis strains from Colombia. Based on restriction fragment length polymorphism, amplified fragment length polymorphism and rep-PCR data, these strains were clustered into 17, 18 and 4 groups, respectively [12]. The draft genomes of 65 X. phaseoli pv. manihotis strains from 11 countries were obtained using Illumina deep-sequencing technology, and the identified single-nucleotide polymorphisms (SNPs) were concatenated, aligned, and used to build a phylogenetic tree based on a neighbor-joining analysis, which showed that most strains clustered by geographic origin [13]. The population structure of X. phaseoli pv. manihotis from other countries has also been studied [14,15,16]. However, phylogenetic analyses on X. phaseoli pv. manihotis strains of China remain limited.
Copper-based bactericides are effective against plant bacterial diseases and are extensively used in the field. In China, farmers are recommended to use copper-based bactericides for CBB. The inhibitory effect of two kinds of frequently used bactericides, 20% thiadiazole copper SC and 77% copper hydroxide WP, was appraised, and the lowest effective concentration was 500 and 75 mg/L, respectively [17]. The control effect of several kinds of copper hydroxide formulation was lower than 50% in cassava plantations located in Guangxi and Hainan provinces (unpublished).
Usually, continuous and widespread application has favored the spread of copper-resistance genes among pathogenic bacterial strains [18,19]. CopAB, copLAB, ORF1-4 and other homologous genes are a copper-resistance gene cluster in Xanthomonads [20,21,22,23]. Ryan et al. (2007) isolated a novel gene cluster: xmeRSA from Xanthomonas campestris strain IG-8. Further research indicates that xmeRSA is a homologue of the multidrug efflux system of Stenotrophomonas maltophilia and required for a copper-resistant phenotype [24]. Whether Cu2+ resistance has likewise begun to emerge in the X. phaseoli pv. manihotis population and which copper resistance genes plays the important role is worth investigating.
Planting resistant varieties and spraying copper-based bactericides are common methods to control bacterial diseases, but the effect is restricted to CBB. Therefore, the present study aimed to assess the genetic diversity and copper ion resistance of X. phaseoli pv. manihotis, sequence the homologous genes of copper-resistance gene clusters, and provide a basis for the cultivation of CBB-resistant cassava varieties and further control research on CBB.
2. Materials and Methods
2.1. Bacterial Strains, Growth Conditions, and Reagents
Forty-eight X. phaseoli pv. manihotis strains were isolated from diseased leaf or stem samples of China, Uganda, Cambodia, Malaysia, and Micronesia. Following Koch’s postulates, pathogenicity was established by Lu et al. (2013) [25]. X. phaseoli pv. manihotis strains GLBY06 and GLBY07 were obtained from Universidad de los Andes and all the strains were conserved at the Environment and Plant Protection Institute (EPPI), CATAS. The details of 50 X. phaseoli pv. manihotis strains are shown in Table 1. These strains were grown on YPGA medium (yeast powder, 5 g; peptone, 5 g; D-glucose, 10 g; deionized water, 1000 mL; agar, 15 g; pH 7.20). Total genomic DNA was prepared by using the procedure of Fargier et al. (2018) [26]. Taq DNA polymerase, PCR buffer (contain MgCl2) and dNTPs were purchased from TIANGEN Co., Ltd. (Beijing, China), Primer synthesis and amplicon sequencing were performed by BGI Co., Ltd. (Shenzhen, China). Anhydrous copper (II) sulfate (CuSO4) was purchased from Sangon Biotech Co., Ltd. (Shanghai, China). A solution of Cu2+ (0.5 M) was created by dissolving anhydrous copper (II) sulfate in ddH2O, filtering through a 0.22 μm filter and storing at 4 °C.
2.2. Clustering Based on Multilocus Sequence Analysis
Using the methodology described by Bella et al. (2019) [27], genomic DNA of fifty X. phaseoli pv. manihotis strains was extracted. The PCR reaction contained a mixture of 1 × PCR buffer, 0.1 mM dNTPs, 0.2 μM each of forward and reverse primers, 50–200 ng genomic DNA, 2.0–3.0 U of Taq DNA polymerase, with sterilized distilled water added to 50 μL. All the PCR amplicon was obtained with the primers listed in Table 2. Using the same primers of efp, both ends of the amplicon were sequenced and merged, then a partial sequence of efp was obtained. Using the primers P-X-atpDF/P-X-atpDR/ATPD-S1/ATPD-S2, P-X-dnaKF/P-X-dnaKR/dnaK-S1/dnaK-S2, X-gyrB1F/X-gyrB1R/gyrB-S1/gyrB-S2, X-gyrB1F/X-gyrB1R/gyrB-S1/gyrB-S2 and X-rpoD1F/X-rpoD1R/rpoD-S1/rpoD-S2 listed in Table 2, the partial sequences of four housekeeping genes—atpD, dnaK, gyrB and rpoD—were also obtained. The same five gene sequences from Xanthomonas axonopodis pv. citrumelo strain F1 (CP002914.1) [28] acted as an outgroup. The phylogenetic tree of X. phaseoli pv. manihotis strains was constructed using the neighbor-joining method (bootstrap = 1000) using MEGAX software (version 11.0.11) [29].
2.3. Copper Tolerance Assays
After autoclaving, YPGA medium was kept in a water bath at 50 °C, and different quantities of CuSO4 solution (0.5 M) were thoroughly mixed with the YPGA medium before pouring the medium into plates. To estimate and narrow down the MIC range of Cu2+ in X. phaseoli pv. manihotis strains, five representative strains from different countries—GLBY06, CGX11, CGD24, UGD1, and KHM04—were used in the first round, and the tested Cu2+ concentrations were 0, 0.4, 0.8, 1.2, 1.6, 2.0, and 2.4 mM. In the second round, the tested concentrations ranged from 1.2 to 2.0 mM with 0.1 mM increments. All strains were cultured on YPGA medium for 48 h, suspended in sterile water at OD600 = 0.5 and streaked on YPGA medium containing CuSO4; medium without copper served as the control. The growth of strains was assessed after 72 h of incubation at 28 °C. The experiments were repeated three times. The minimum Cu2+ concentration at which a strain failed to grow was determined to be the MIC. On the basis of the results of Cu2+ resistance detection on YPGA, six representative strains—CHN03, UGD1, MLXY1825, MK1825, KHM01, and GLBY06—were selected. A 0.1 mL (OD600 = 0.5) suspension was prepared and added to 49.9 mL of YPG broth containing different amounts of CuSO4, incubated (at 28 °C, 180 rpm), and the OD600 value was measured at 48 h, 60 h, and 72 h to reconfirm the MIC.
2.4. Analysis of Copper-Resistance-Related Genes
Based on X. phaseoli pv. manihotis strain CHN01 (CP083575.1) genome annotations [4], the encoded amino acid sequences of copAB (AE008923), copLAB (AY536748 and HM362782), ORF1-4 (L19222.1) and xmeRSA (AY359472.5) were obtained from the GenBank database, and two homologous gene clusters of copLAB and xmeRSA were anchored. The structure and encoded functional proteins of copLAB and xmeRSA were analyzed, and other copper-resistance-related genes were also screened.
The primers X-LABF/X-LABR and X-RSAF/X-RSAR (Table 2) were designed to amplify the sequences of copLAB and xmeRSA from X. phaseoli pv. manihotis strains in this study. Using the primers X-LABF/X-LABR/copLAB-S1/copLAB-S2/copLAB-S3/copLAB-S4/copLAB-S5, and X-RSAF/X-RSAR/xmeRSA-S1/xmeRSA-S2/xmeRSA-S3/xmeRSA-S4/xmeRSA-S5, listed in Table 2, the amplicon sequences of copLAB and xmeRSA were obtained.
3. Results
3.1. Clustering Based on Multilocus Sequence Analysis
The five housekeeping genes atpD, dnaK, gyrB, efp, and rpoD were successfully amplified from 50 X. phaseoli pv. manihotis strains (Table 1), with a partial sequence length of 868, 1034, 904, 445 and 959 nucleotides, respectively (Table 2). These five sequences were concatenated in the order atpD–dnaK–gyrB–efp–rpoD, and the total length was 4210 nucleotides (Supplementary File S1). In the neighbor-joining phylogenetic tree, the 50 strains were clustered into three groups (Figure 1). Group I contained 46 strains from China, Uganda, Cambodia, and Micronesia. Group II contained two strains from Colombia, and Group III contained the remaining two strains from Malaysia.
The five sequenced genes were highly conserved among strains from different geographic regions. DnaK, gyrB and efp had the same sequence in all strains, whereas a few polymorphisms were observed in atpD and rpoD. One point mutation occurred at position 361 of the trimmed atpD sequence: A in Groups I and II and C in Group III. Similarly, for rpoD, there was only one nucleotide polymorphism observed between the Group II strains and strains in the other two groups; this mutation was located at position 609 with an A-to-T transversion in the two Group II strains.
3.2. Copper Resistance
In the first round, five representative strains were tested to narrow down the Cu2+ resistance threshold. The strains grew on solid medium plates or broth culture containing >1.2 mM of Cu2+. Only one strain, GLBY06, could grow with 1.6 mM of Cu2+. On solid medium, the thickness and size of the colony reduced with increasing Cu2+ concentration.
After the second round, the minimal inhibitory concentration (MIC) was determined as the lowest Cu2+ concentration at which no growth was observed in plate culture. Six strains—CHN03, UGD1, MLXY1825, MK1825, KHM01, and GLBY06—from different groups and areas were also tested in YPG broth medium, and similar observations were made. The MIC of the 50 X. phaseoli pv. manihotis strains ranged from 1.3 to 1.7 mM (Table 1). Strains CHN22, CGD31, CGX04, and GLBY06 had the highest MIC value of 1.7 mM, whereas CJX05, CHN02, CGX01, and MLXY1827 had the lowest MIC value of 1.3 mM. The copper-resistance levels of the X. phaseoli pv. manihotis strains did not differ significantly according to geographic region.
In total, 39 X. phaseoli pv. manihotis strains had been isolated from diseased samples collected in China. The MIC of copper was 1.3 mM for three strains (CJX05, CHN02 and CGX01), 1.4 mM for 10 strains (CJX01, CJX07, CHN11, CHN21, CGD24, CGD55, CGX18, CGX23, CGX29 and CGX71), 1.5 mM for 12 strains (CHN09, CHN16, CHN17, CGD11, CGD17, CGD43, CGD56, CGX07, CGX15, CGX33, CGX36 and CGX69), 1.6 mM for 11 strains (CHN03, CHN27, CHN31, CGD12, CGD19, CGD25, CGD37, CGD50, CGX11, CGX13 and CGX44), and 1.7 mM for the other three strains (CHN22, CGD31, CGX04), with an average MIC of 1.5 mM.
3.3. Copper-Resistance-Related Genes
The homologous gene clusters of copLAB and xmeRSA of X. phaseoli pv. manihotis strain CHN01 were identified at two different loci, and no other identifiable copper-resistance-related gene was detected at these two loci. Thirteen other copper-related genes were also screened, including those encoding copper-binding protein, CopD family protein, copper homeostasis protein CutC, and copper-type cytochrome.
The full-length copLAB gene cluster was 3459 nucleotides, comprising three genes, copL, copA, and copB, each with the same coding direction (Figure 2a). According to the genome annotation, the distance between the stop codon of copL and the start codon of copA was 88 nucleotides, and the stop codon of copA overlapped with the start codon of copB. No putative ribosome-binding site (core sequence AGGA; www.ics.uci.edu/~kibler/pubs/TR03 accessed on 2 June 2023) was found at the end of copL and copA or at the adjacent sequence upstream of the coding region of copL. Two putative ribosome-binding sites were identified at the beginning of the copB coding region (Figure 2c). The first putative site was located upstream of alternative ATG start codons; however, it was located at a distance of 84 nucleotides from annotated start codons, which suggests that another putative start codon should be considered. copL encodes a predicted 152-amino acid metal-binding regulatory protein, copA encodes a predicted 601-amino acid multicopper oxidase, and copB encodes a predicted 369-amino acid copper resistance protein. The deduced amino acid sequences of copL, copA, and copB exhibited 100% (124/124) identity with that of copL from Xanthomonas axonopodis pv. vesicatoria, 96% (572/594) identity with that of copA and 86% (317/369) identity with that of copB from X. axonopodis pv. citri [20,21].
The full-length sequence of the xmeRSA gene cluster was 3444 nucleotides, comprising three genes xmeR, xmeS, and xmeA, and the coding direction of xmeA was inverse to that of the other two genes (Figure 2b). The annotation results indicated that the distance between the two start codons of xmeS and xmeA was 160 nucleotides, and the stop codon of xmeS overlapped with the start codon of xmeR. No putative ribosome-binding site was identified in the adjacent upstream sequence of the coding region of xmeS and xmeA or at the end of xmeS. Two putative ribosome-binding sites were identified at the beginning of the xmeR coding region, with the second site located upstream of alternative ATG start codons. The distance from the alternative ATG start codons to the annotated start codons was 243 nucleotides (Figure 2d), suggesting that another putative start codon should be considered. xmeR encodes a predicted 227-amino acid transcriptional regulatory protein that exhibits 100% (227/227) identity with the DNA-binding transcriptional regulator BaeR of Xanthomonas citri (WP_017157623.1) [32]. XmeS encodes a predicted 459-amino acid protein that exhibits 100% (459/459) identity with sensor histidine kinase efflux regulator BaeS of Xanthomonas phaseoli (WP_017157622.1). XmeA encodes a predicted 407-amino acid protein that exhibits 100% (407/407) identity with the multidrug efflux RND transporter periplasmic adaptor subunit AcrA of Xanthomonas phaseoli (WP_017157621.1). The predicted amino acid sequences of xmeR, xmeS, and xmeA also showed 67% (151/227), 57% (260/455), and 61% (115/189) identity with xmeR, xmeS, and xmeA of Xanthomonas campestris strain IG-8 (AY359472.5), respectively, which are also associated with the copper resistance [24].
3.4. Two Gene Clusters Were Highly Conserved
CopLAB and xmeRSA play an important role in the copper-resistant Xanthomonads strains, so these two gene clusters were chosen as the target for further analysis. copLAB and xmeRSA were also successfully amplified from 50 X. phaseoli pv. manihotis strains. Polymorphisms in the two gene clusters comprised the few differences among the determined sequences. For copLAB, only one point substitution at position 963 with a G-to-A transversion in the coding region of copA but no amino acid transversion, was observed in strain CGD17. The other 49 strains had the same copLAB sequence as strain CHN01 (Supplementary File S2).
The sequence of xmeRSA in the seven strains CHN02, CHN09, CHN17, CHN21, CGD37, CGX04, and CGX69 exhibited 100% identity with that in strain CHN01. Two point substitutions were observed in strain CGD50: a C-to-A transversion at position 1160 in the coding region of xmeA, leading to an amino acid change from glycine to valine and an A to G transversion at position 1015 in the coding region of xmeS, leading to amino acid change from threonine to alanine. The remaining 42 strains showed the same single point substitution: an A-to-G transversion at position 1015 in the coding region of xmeS (Supplementary File S3).
4. Discussion
CBB frequently causes severe losses in cassava plantations in China and has become the most damaging disease of cassava. Remarkably, copper-based bactericides have failed to control this disease, and the main cassava cultivars are susceptible. The genetic diversity and emergent copper-ion resistance of X. phaseoli pv. manihotis are major obstacles to the field management of CBB in China. As such, the genetic diversity and copper resistance of X. phaseoli pv. manihotis population was studied. Fifty strains were used in this study, thirty-nine strains originating from four provinces of China respectively, and eleven strains from five other countries.
The genetic diversity of 50 X. phaseoli pv. manihotis strains from different geographic regions was assessed by sequencing the five housekeeping genes atpD, dnaK, gyrB, efp, and rpoD. All the strains showed low genetic diversity and a certain degree of correlation with the geographical origin. This is similar to the genetic diversity of X. phaseoli pv. manihotis strains assessed on the basis of concatenated SNPs [13]. In the present study, the strains from the Asian mainland (China and Cambodia), Africa (Uganda), and Central Pacific Region (Micronesia) clustered into the same group. Unlike Uganda or Micronesia, Malaysia is located in the Asian continent, but the only two strains from Malaysia clustered into a separate group (Group III).
The partial sequences of dnaK, gyrB, and efp genes were highly conserved, and no nucleotide substitutions were found among these strains. In fact, a phylogenetic analysis using the concatenated sequence of the two genes atpD and rpoD would produce the same clustering groups. The gyrB sequences were highly conserved, with the same sequence from 60 X. arboricola pv. juglandis isolates from China [33]. The genetic diversity analysis of 59 X. arboricola pv. juglandis isolates from Serbia also showed that this gene was not a good choice to assess genetic diversity. Our results showed only one nucleotide polymorphism observed among different group strains, implying that all these five genes were unsuitable for population structure analysis of X. phaseoli pv. manihotis.
The pressure imposed by the continuous application of copper-based bactericides drives the selection of copper-resistant strains and favors a gradual increase in the frequency of resistant pathogens within the bacterial population. Garde et al. (1991) collected and studied many Xanthomonas campestris pv. vesicatoria strains from Florida, New Mexico, Oklahoma and California, USA, and found that copper-resistant strains had emerged in the environment and the number had increased owing to the heavy use of copper-based bactericidal sprays [34]. In Australia, copper-based bactericides are the only products available to pepper producers to combat bacterial spot, and the number and proportion of copper-resistant X. campestris pv. vesicatoria strains have increased with the increasing application frequency. In Queensland, only one X. campestris pv. vesicatoria strain (of 12) collected before 1987 could tolerate 1.0 mM Cu2+. In contrast, approximately one in four strains (75 total) collected between 1999 and 2000 tolerated more than 1.0 mM Cu2+, and the MIC for all four strains isolated in 2015 was 1.5 or 2.0 mM Cu2+ [35,36]. In Hubei, China, where walnut bacterial blight caused by X. arboricola pv. juglandis was common, the high ratio of copper-resistant isolates was also associated with the heavy use of copper-based bactericides. Two isolates from Danjiangkou, where copper compounds had been frequently applied for more than 10 years, were extremely highly resistant to Cu2+ (270 µg/mL) [33].
Copper-resistant Xanthomonas strains have been found worldwide. In a previous study, 87 of 98 Xanthomonas strains causing tomato bacterial spot collected in Ontario, Canada were reported to grow on mannitol–glutamate–yeast extract (MGY) medium containing 1.0 mmol per liter of Cu2+ or higher [37]. Using a Cu2+ concentration of 125 µg/mL (0.5 mM) as the threshold dose, Fu et al. (2021) categorized X. arboricola pv. juglandis isolates into resistant and sensitive groups [33]. Previous studies have reported that only some of the studied strains of plant pathogenic bacteria were copper-resistant. However, in the present study, the MIC of all the fifty X. phaseoli pv. manihotis strains was 1.3 to 1.7 mM, indicating moderate levels of copper resistance. These findings explain why copper-based bactericides were ineffective in CBB control. Notably, there was no evident relationship between the level of copper resistance and genetic diversity based on MLSA.
In China, copper compounds were only occasionally used to control CBB in the field. In this paper, we found all the strains could tolerate 1.3 mM Cu2+. To our knowledge, there are almost no records of the use of copper-based bactericides in Uganda, Cambodia, and other countries included in this study. Thus, it remains unknown why all the X. phaseoli pv. manihotis strains exhibit resistance to Cu2+.
Via conjugation, plasmid-borne copper-resistance gene clusters may be horizontally transferred to different Xanthomonas strains [19]. CopLAB, a typical copper-resistance gene cluster, is often encoded by plasmid and is present in many copper-resistant Xanthomonas species isolated from different parts of the world. Xanthomonas strain IG-8 isolated from soil collected in Hebei province (China) was heavily contaminated with glyphosates and several kinds of heavy metals. XmeRSA genes play a major role in the copper-, arsenic-, and cadmium-resistant phenotype, and bioinformatics analysis suggests that these genes were acquired by horizontal gene transfer [24]. The genome annotation of X. phaseoli pv. manihotis strain CHN01 confirmed that copLAB and xmeRSA were encoded in the chromosome. The predicted amino acid sequences of these two gene clusters from 50 X. phaseoli pv. manihotis strains showed high homology, indicating that these two gene clusters were also acquired from other Xanthomonas strains. According to the genome annotation of X. axonopodis pv. citri strain 306, the stop codon of copA overlaps with the start codon of copB [20]. The same overlaps happened on the copA and xmeS from X. phaseoli pv. manihotis strains in this paper, while the coding direction of xmeS was inverse to the homologous gene of Xanthomonas strain IG-8 [24].
CopA and copB encode multicopper oxidase and copper-resistance proteisn, whereas copL encodes a copper-binding protein to regulate the expression of copA and copB. The xmeRSA from X. phaseoli pv. manihotis strains is homologous to xmeRSA from Xanthomonas strain IG-8, which encodes a multidrug efflux system and plays a key role in the multiresistant phenotype. In the present study, all 50 X. phaseoli pv. manihotis strains showed moderate levels of copper resistance and carried two different copper-resistance-related gene clusters, suggesting that the regulation of copper resistance is associated with two distinct metabolic pathways.
Some copper-resistance genes are also required for full virulence of Xanthomonas strains. A copA mutation of X. campestris pv. campestris strain Xc17 resulted in a significant decrease in copper tolerance and virulence on cabbage [38]. Xanthomonas gardneri strain Xv10 isolated from diseased tomato leaves was collected in the Inner Mongolia province of China, and the virulence on tomato and level of copper resistance declined with copB deletion [39]. The X. phaseoli pv. manihotis strains used in the present study were resistant to Cu2+ without high selective pressure in the field, suggesting that copLAB and xmeRSA also have another conserved function. The functions of copLAB and xmeRSA need to be further investigated in future studies.
5. Conclusions
Fifty X. phaseoli pv. manihotis strains were collected from China, Uganda, Cambodia, Colombia, Malaysia, and Micronesia. Using multilocus sequence analysis of five housekeeping genes (atpD–dnaK–gyrB–efp–rpoD), the strains clustered into three groups. The largest was group I, comprising 46 strains from China, Uganda, Cambodia, and Micronesia, while the other two groups comprised four strains from Colombia and Malaysia separately. Without the pressure imposed by the continuous application of copper-based bactericides, all the strains were resistant to copper, and the copper-resistance levels of the X. phaseoli pv. manihotis strains did not differ significantly according to geographic region. Copper-based bactericides are not a good choice for CBB, while ethylicin and 2-amino-5-sulfydryl-1,3,4-thiadiazole zinc were effective [40]. Two conservative copper-resistance-related gene clusters, copLAB and xmeRSA, were amplified from all strains, suggesting they also have another conserved function. In addition, the structural composition of two gene clusters was analyzed.
Supplementary Materials
The following supporting information can be downloaded at https://www.mdpi.com/article/10.3390/cimb45070342/s1. Supplementary File S1: Partial sequence of atpD-dnaK-gyrB-efp-rpoD; Supplementary File S2: Sequence of copLAB; Supplementary File S3: Sequence of xmeRSA.
Author Contributions
Conceptualization, T.S. and G.H.; writing—review and editing, T.S.; methodology, C.L.; formal analysis, G.W.; funding acquisition, T.S. and G.H. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the Hainan Provincial Natural Science Foundation of China, grant 2019RC274 and the earmarked fund for CARS-11.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
Not applicable.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
Clustering of 50 Xanthomonas phaseoli pv. manihotis strains on the basis of multilocus sequence analysis (atpD-dnaK-gyrB-efp-rpoD concatenated). The phylogenetic tree was constructed using the neighbor-joining method (bootstrap = 1000) using MEGA software (version 11.0.11). Xac F1 (National Center for Biotechnology Information Reference Sequence: CP002914.1), one of the Xanthomonas axonopodis pv. citrumelo type strains, was used as the outgroup.
Figure 1.
Clustering of 50 Xanthomonas phaseoli pv. manihotis strains on the basis of multilocus sequence analysis (atpD-dnaK-gyrB-efp-rpoD concatenated). The phylogenetic tree was constructed using the neighbor-joining method (bootstrap = 1000) using MEGA software (version 11.0.11). Xac F1 (National Center for Biotechnology Information Reference Sequence: CP002914.1), one of the Xanthomonas axonopodis pv. citrumelo type strains, was used as the outgroup.
Figure 2.
Organization of the gene clusters (a) copLAB and (b) xmeRSA and intergenic region (c) between copA and copB and (d) between xmeS and xmeR. The copA/xmeS stop codon is shown in blue and italics, and the copB/xmeR start codon is shown in bold and underlined letters. Putative ATG start codons for copB/xmeA are shown in bold, and the start codon of copB/xmeR suggested in this study is shown in red. Putative ribosome-binding sites are shown in double-underlined letters.
Figure 2.
Organization of the gene clusters (a) copLAB and (b) xmeRSA and intergenic region (c) between copA and copB and (d) between xmeS and xmeR. The copA/xmeS stop codon is shown in blue and italics, and the copB/xmeR start codon is shown in bold and underlined letters. Putative ATG start codons for copB/xmeA are shown in bold, and the start codon of copB/xmeR suggested in this study is shown in red. Putative ribosome-binding sites are shown in double-underlined letters.
Table 1.
Xanthomonas phaseoli pv. manihotis strains used in this study.
| NO. | Strain | Year of Samples Collected | Source | MIC a (mM) |
|---|---|---|---|---|
| 1 | CJX01 | 2013 | Dongxiang, Jiangxi, China | 1.4 |
| 2 | CJX05 | 2015 | Dongxiang, Jiangxi, China | 1.3 |
| 3 | CJX07 | 2020 | Fuzhou, Jiangxi, China | 1.4 |
| 4 | CHN02 | 2009 | Danzhou, Hainan, China | 1.3 |
| 5 | CHN03 | 2009 | Qionghai, Hainan, China | 1.6 |
| 6 | CHN09 | 2009 | Wenchang, Hainan, China | 1.5 |
| 7 | CHN11 | 2015 | Qiongzhong, Hainan, China | 1.4 |
| 8 | CHN16 | 2017 | Haikou, Hainan, China | 1.5 |
| 9 | CHN17 | 2017 | Danzhou, Hainan, China | 1.5 |
| 10 | CHN21 | 2017 | Chengmai, Hainan, China | 1.4 |
| 11 | CHN22 | 2017 | Wenchang, Hainan, China | 1.7 |
| 12 | CHN27 | 2018 | Danzhou, Hainan, China | 1.6 |
| 13 | CHN31 | 2019 | Chengmai, Hainan, China | 1.6 |
| 14 | CGD11 | 2008 | Suixi, Guangdong, China | 1.5 |
| 15 | CGD12 | 2009 | Yangjiang, Guangdong, China | 1.6 |
| 16 | CGD17 | 2009 | Kaiping, Guangdong, China | 1.5 |
| 17 | CGD19 | 2012 | Zhanjiang, Guangdong, China | 1.6 |
| 18 | CGD24 | 2013 | Yunfu, Guangdong, China | 1.4 |
| 19 | CGD25 | 2015 | Guangzhou, Guangdong, China | 1.6 |
| 20 | CGD31 | 2016 | Leizhou, Guangdong, China | 1.7 |
| 21 | CGD37 | 2016 | Suixi, Guangdong, China | 1.6 |
| 22 | CGD43 | 2017 | Yunfu, Guangdong, China | 1.5 |
| 23 | CGD50 | 2017 | Jiangmen, Guangdong, China | 1.6 |
| 24 | CGD55 | 2019 | Kaiping, Guangdong, China | 1.4 |
| 25 | CGD56 | 2020 | Leizhou, Guangdong, China | 1.5 |
| 26 | CGX01 | 2008 | Wuming, Guangxi, China | 1.3 |
| 27 | CGX04 | 2008 | Hepu, Guangxi, China | 1.7 |
| 28 | CGX07 | 2009 | Dongxing, Guangxi, China | 1.5 |
| 29 | CGX11 | 2010 | Beihai, Guangxi, China | 1.6 |
| 30 | CGX13 | 2015 | Pingnan, Guangxi, China | 1.6 |
| 31 | CGX15 | 2015 | Guiping, Guangxi, China | 1.5 |
| 32 | CGX18 | 2016 | Nanning, Guangxi, China | 1.4 |
| 33 | CGX23 | 2016 | Beihai, Guangxi, China | 1.4 |
| 34 | CGX29 | 2017 | Wuxuan, Guangxi, China | 1.4 |
| 35 | CGX33 | 2017 | Hepu, Guangxi, China | 1.5 |
| 36 | CGX36 | 2018 | Nanning, Guangxi, China | 1.5 |
| 37 | CGX44 | 2019 | Longan, Guangxi, China | 1.6 |
| 38 | CGX69 | 2020 | Pingnan, Guangxi, China | 1.5 |
| 39 | CGX71 | 2020 | Guiping, Guangxi, China | 1.4 |
| 40 | UGD1 | 2014 | Kiryandongo, Uganda | 1.4 |
| 41 | UGD2 | 2014 | Masindi, Uganda | 1.5 |
| 42 | UGD3 | 2015 | Hoima, Uganda | 1.6 |
| 43 | KHM01 | 2016 | Kratié, Cambodia | 1.4 |
| 44 | KHM03 | 2017 | Kratié, Cambodia | 1.6 |
| 45 | KHM04 | 2018 | Stung Treng, Cambodia | 1.4 |
| 46 | MLXY1825 | 2018 | Sabah, Malaysia | 1.4 |
| 47 | MLXY1827 | 2018 | Sabah, Malaysia | 1.3 |
| 48 | MK1825 | 2018 | Micronesia | 1.5 |
| 49 | GLBY06 | 2013 | Colombia | 1.7 |
| 50 | GLBY07 | 2013 | Colombia | 1.4 |
a MIC, minimal inhibitory concentration.
Table 2.
Primers used in this study.
| Gene/Gene Cluster | Coding Protein | Primer Name | Sequence (5′–3′) b | Size of Amplicon | Reference |
|---|---|---|---|---|---|
| atpD | ATP synthase β-chain | P-X-atpDF | GGGCAAGATCGTTCAGAT | 868 nt | Fischer-Le Saux et al. (2015) [30]. |
| P-X-atpDR | GCTCTTGGTCGAGGTGAT | ||||
| ATPD-S1 | CTGGAAACCGGCATCAAGGTC | This study | |||
| ATPD-S2 | CGTGGTAGAAGTCGTTGCCCT | ||||
| dnaK | Molecular chaperone DnaK (HSP70) | P-X-dnaKF | GGTATTGACCTCGGCACCAC | 1034 nt | Fischer-Le et al. (2015) [30]. |
| P-X-dnaKR | ACCTTCGGCATACGGGTCT | ||||
| dnaK-S1 | ACTTCAACGACAGCCAG | This study | |||
| dnaK-S2 | TACTCGATGACGCGGTTGT | ||||
| gyrB | DNA topoisomerase β-subunit | X-gyrB1F | ACGAGTACAACCCGGACAA | 904 nt | Fischer-Le et al. (2015) [30]. |
| X-gyrB1R | CCCATCAAGGTGCTGAAGAT | ||||
| gyrB-S1 | TTGTTGATGCTGTTCACCA | This study | |||
| gyrB-S2 | CTCTTGTTGCCGCGCACGATCT | ||||
| efp | elongation factor P | X-efp1F | TCATCACCGAGACCGAAT | 445 nt | Hamza et al. (2012) [31]. |
| X-efp1R | TCCTGGTTGACGAACAG | ||||
| rpoD | RNA polymerase sigma factor | X-rpoD1F | TGGTCAACGGCATCAAGGA | 959 nt | This study |
| X-rpoD1R | CAACGCCTTGGCCTCTATCT | ||||
| rpoD-S1 | TCAAGGACCAGATCATCTCC | ||||
| rpoD-S2 | TCGATCATGTGCACCGGGATAC | ||||
| copLAB | metal-binding regulatory protein, multicopper oxidase and copper resistance protein | X-LABF X-LABR | ATGCTATGCTCGCTGCACCT | 3459 nt | This study |
| TCAAAACCACACGCGTACAC | |||||
| copLAB-S1 | AGGAGATGTCATGTCGTTCGAT | ||||
| copLAB-S2 | AGCCACGACAACTACGCACA | ||||
| copLAB-S3 | GCAACCCGCTGATCGACAT | ||||
| copLAB-S4 | TACGCAAGCACACCATCGACAT | ||||
| copLAB-S5 | AACGACACGACGGACGCACCGAAT | ||||
| xmeRSA | transcriptional regulatory protein, sensor histidine kinase efflux regulator and multidrug efflux RND transporter periplasmic adaptor subunit | X-RSAF X-RSAR | ATTCCTCAGTCGGCCTTGG | 3444 nt | This study |
| TCACGGCTCAAACCGATACC | |||||
| xmeRSA-S1 | CAGAGCGAGGTGCTGGCCAC | ||||
| xmeRSA-S2 | TGTAGTCGAGATTGATGCGC | ||||
| xmeRSA-S3 | TTACCGCGCTTCGCATCACCTC | ||||
| xmeRSA-S4 | CAAGCGCTGGAGCACAACGAA | ||||
| xmeRSA-S5 | ATGTGCTGATCGTCGAGGA |
b The nucleotides and sequences in bold were revised or designed according to the published sequences of X. phaseoli pv. manihotis strain (CP083575.1) from the GenBank database.
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Shi, T.; Li, C.; Wang, G.; Huang, G. Multilocus Sequence Analysis and Detection of Copper Ion Resistance of Xanthomonas phaseoli pv. manihotis Causing Bacterial Blight in Cassava. Curr. Issues Mol. Biol. 2023, 45, 5389-5402. https://doi.org/10.3390/cimb45070342
AMA Style
Shi T, Li C, Wang G, Huang G. Multilocus Sequence Analysis and Detection of Copper Ion Resistance of Xanthomonas phaseoli pv. manihotis Causing Bacterial Blight in Cassava. Current Issues in Molecular Biology. 2023; 45(7):5389-5402. https://doi.org/10.3390/cimb45070342
Chicago/Turabian StyleShi, Tao, Chaoping Li, Guofen Wang, and Guixiu Huang. 2023. "Multilocus Sequence Analysis and Detection of Copper Ion Resistance of Xanthomonas phaseoli pv. manihotis Causing Bacterial Blight in Cassava" Current Issues in Molecular Biology 45, no. 7: 5389-5402. https://doi.org/10.3390/cimb45070342
