Abstract
Broad-spectrum resistance has great values for crop breeding. However, its mechanisms are largely unknown. Here, we report the cloning of a maize NLR gene, RppK, for resistance against southern corn rust (SCR) and its cognate Avr gene, AvrRppK, from Puccinia polysora (the causal pathogen of SCR). The AvrRppK gene has no sequence variation in all examined isolates. It has high expression level during infection and can suppress pattern-triggered immunity (PTI). Further, the introgression of RppK into maize inbred lines and hybrids enhances resistance against multiple isolates of P. polysora, thereby increasing yield in the presence of SCR. Together, we show that RppK is involved in resistance against multiple P. polysora isolates and it can recognize AvrRppK, which is broadly distributed and conserved in P. polysora isolates.
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Introduction
Maize (Zea mays L) is one of the crops with the highest production and a major source of calories and proteins for livestock and humans worldwide. However, the grain yield and quality of maize are seriously reduced by many diseases around the world. The most efficient way to control these diseases is to develop maize lines carrying resistance genes. The identification and cloning of resistance genes are critical steps toward that goal. However, only sixteen resistance genes (Hm1, Htn1, Ht2, Ht3, Rp1-D21, RppC, RabGD1α, ZmABP1, ZmAuxRP1, ZmCCoAOMT2, ZmCCT, ZmFBL41, ZmMM1, ZmREM1.3, ZmTrxh, ZmWAK) have been cloned from maize1,2,3,4,5,6,7,8,9,10,11,12,13,14,15, and very few of them have been proven to have breeding value.
Plant innate immunity consists of pattern-triggered immunity (PTI) and effector-triggered immunity (ETI)16. PTI is triggered by the recognition of microbial components by cell surface-localized pattern-recognition receptors (PRRs), while ETI is activated by the recognition of microbial effector proteins directly or indirectly by intracellular nucleotide-binding leucine-rich repeat receptors (NLRs)16. ETI activates more rapid and stronger immunity than PTI17,18, although they share similar downstream cellular responses19,20. Therefore, the deployment of NLR genes in crop cultivars has been the major approach for improving disease resistance in crop breeding21. Unfortunately, the resistance conferred by NLR genes is often not durable in the field because of changes in pathogen races. Pathogen races without corresponding effector genes (known as avirulence, Avr, genes) accumulate quickly, and pathogen races may evolve through the mutation or deletion of the corresponding Avr gene, resulting in the breakdown of resistance conferred by NLR genes16,21,22. For example, the Ug99 race group of Puccinia graminis f. sp. tritici has successfully broken through the resistance of wheat cultivars conferred by the Sr31, Sr24, Sr36, and SrTmp resistance genes23,24,25,26. To achieve broad-spectrum resistance, the pyramiding of multiple NLR genes has been applied in breeding22. For example, the pyramiding of yellow rust resistance genes (Yr5 and Yr15 or Yr64 and Yr15) in wheat resulted in broad-spectrum resistance against all tested stripe rust races27,28. Another way to obtain broad-spectrum resistance is to deploy NLR genes recognizing core effectors, which are widely distributed in most races of a particular pathogen and are required for their virulence in crops21. Although much work has been performed to achieve that goal29,30, no core effector gene-NLR gene pairs have been identified in major pathogens and crops. Therefore, no direct evidence has been presented to prove that this strategy is practicable.
Owing to changes in climate and cropping practices, southern corn rust (SCR) caused by Puccinia polysora UnderW. has become a major maize disease in the USA, Canada, Brazil, and China31,32,33,34,35. Under favorable conditions, SCR can cause yield losses of more than 50%, which seriously threatens maize production and food security31,32,35,36,37,38. Similar to other rust fungi, P. polysora behaves as an obligate biotroph that only extracts nutrients from living cells. Although eleven maize dominant resistance genes (Rpp1 to Rpp11) and eight maize major resistance QTLs (RppC, RppCML470, RppD, RppM, RppP25, RppQ, RppS, and RppS313) against P. polysora have been reported, only RppC was cloned14,31,33,37,39,40,41,42,43,44.
In this work, we clone a maize CC-NB-LRR gene, RppK, involved in resistance against P. polysora by map-based cloning, and its cognate Avr gene, AvrRppK, from P. polysora. AvrRppK is highly conserved in all tested P. polysora isolates and can suppress chitin-induced PTI. Furthermore, the RppK gene has great value for breeding because maize inbred lines or hybrids introgressed with the RppK gene exhibit stronger resistance against P. polysora and higher yields than those without the RppK gene in the presence of P. polysora.
Results
Map-based cloning of RppK
K22 is a maize inbred line with durable and complete resistance against SCR in China over the last 30 years (Fig. 1a and Supplementary Fig. 1a). To study the genetic mechanism underlying its resistance against SCR, K22 was crossed with the susceptible inbred line DAN340 to generate a K22 × DAN340 F6:7 population45,46, and the disease phenotypes of these plants were evaluated, based on the SCR disease scale (Supplementary Fig. 1b, c). QTL analysis identified one major QTL, RppK, on the short arm of chromosome 10 that accounted for 68% of the phenotypic variation in resistance against SCR (Fig. 1b and Supplementary Table 1). To fine-map RppK, we genotyped and evaluated the SCR resistance of 402 recombinant lines isolated from 3392 HIF (heterogeneous inbred family)-derived F2 populations47. RppK was mapped to an interval of ~18.3 kb delimited by the markers SNP20 and SNP5 based on the B73 RefGen_v4 genomic sequence (Fig. 1c, d and Supplementary Fig. 2).
The RppK-linked molecular markers RUST7-5 and RUST9-4 were then used to screen BAC libraries of K22 and DAN340. The sequencing and annotation of five BAC clones from K22 revealed that the candidate region between markers SNP20 and SNP5 in K22 spanned 29.8 kb and contained three genes (R1, R2, and R3) (Supplementary Fig. 3). The three candidate genes belong to the CC-NLR gene family with more than 96% nucleotide identity with each other (Supplementary Figs. 4 and 5). In contrast, the candidate region in the susceptible inbred line DAN340 was 20.2 kb and harbors only one CC-NLR gene; and, this gene was named as DAN340 R gene homologous to R3, or DR3 (Supplementary Figs. 4 and 5). Based on the DNA sequences of the candidate regions in K22 and DAN340, we developed more markers to genotype recombinant plants. The candidate region for the RppK region was ultimately delimited between markers RRD103 and RRD111, which encompassed only the R2 and R3 genes (Fig. 1d, e). We subsequently sequenced the DR3 and R3 genes in 21 recombinant plants and found that 11 of them showed recombination between DR3 and the R1, R2 or R3 gene (Supplementary Fig. 6). Among the 11 recombinant lines, five lines (4H1074, 4H1505, 4H1083, 4H1028 and 4H1213) carrying the R3 gene showed resistance to SCR, whereas the other six lines, containing either no R3 gene (5H2661, 4H1285 and 4H1169) or only a partial R3 gene (4H1652, 4H1474 and 4H943), exhibited a susceptible response to SCR (Supplementary Fig. 6). These results indicated that R3 gene is responsible for RppK resistant against SCR. To determine whether R2 or R3 contributed to SCR resistance, we cloned genomic DNA fragments of 12.6 and 11.4 kb for R2 and R3, respectively, from K22; these fragments contained whole genes with their native promoter and terminator sequences (Fig. 1f and Supplementary Fig. 7a). The two fragments were then transformed into the susceptible inbred line KN5585. Two independent T1 families of R2 or R3 gene transgenic plants were tested for resistance to natural infection by P. polysora in the field in Hainan over three years (2017, 2019 and 2020). R2 transgenic plants showed similar SCR susceptibility to the nontransgenic plants (Supplementary Fig. 7b, c), whereas all R3 transgenic plants from two independent families showed stronger resistance to SCR than the nontransgenic plants (Fig. 1g, h and Supplementary Fig. 8). In order to confirm the resistance function of R3 gene, R3 transgenic plants and nontransgenic plants were inoculated with five different isolates of P. polysora in growth room (Supplementary Fig. 9a). Moreover, R3 transgenic plants were more resistant to all five P. polysora isolates than the nontransgenic control plants (Supplementary Fig. 9b–f). We conclude that R3 is the QTL encoding resistance gene against SCR, and was renamed as RppK.
RppK presents great values for maize breeding
To explore natural RppK variation in maize accessions, we used four RppK-related molecular markers (R8.65, R8.63, Del13K and R8.61) (Supplementary Fig. 10a, b) to screen ~500 diverse maize inbred lines from an association mapping panel48 and found that only 17 of them contained the RppK gene (Supplementary Fig. 10, Supplementary Table 2 and Supplementary Data 1). Also, we screened 168 teosinte lines and 288 landrace lines using the functional marker R8.63, which did not amplify related sequences (Supplementary Data 2 and 3). Further, we checked 74 commercial maize hybrid lines and found that only five of them contained the RppK gene (Supplementary Fig. 11 and Supplementary Data 4). The low frequency of the RppK gene in the current maize collections indicates that the allele has not broadly spread in maize lines, which highlights the potential value of the RppK gene in improving SCR resistance in maize breeding. Therefore, we introgressed the RppK allele into ten elite inbred lines via backcrossing and evaluated their SCR resistance in Hainan, China. The plants harboring the RppK gene were significantly more resistant to SCR than the plants without RppK (Supplementary Fig. 12). To evaluate the breeding value of RppK in hybrids, we performed repeated backcrossing and molecular marker-assisted selection to introduce the RppK gene into the two parental lines of the maize hybrid JK968 (Jing724 × Jing92), which has been planted seven million hectares in China over the past decade49. In the field, the JK968 hybrid lines carrying RppK were more resistant to SCR than the original JK968 hybrid (Fig. 2a–d). As a result, the grain yields of the JK968 lines carrying RppK were 11.9% (with one RppK allele, JK968a) and 17.1% (with two RppK alleles, JK968b) higher than that of the original JK968 hybrid without RppK in the presence of SCR without significant changes in major agronomic traits (Fig. 2c–f and Supplementary Fig. 13). We also improved the SCR resistance of four other hybrid lines with different genetic backgrounds by using the same strategy and got similar results (Supplementary Figs. 14 and 15). Moreover, we generated four additional hybrids by crossing transgenic KN5585RppK lines with four maize inbred lines (B73, Mo17, IL1, and IL2). Consistent with the previous results, the RppK gene enhanced maize resistance against SCR and increased the grain yield by 4.51% to 15.6% under different SCR disease conditions with no yield penalty in the absence of SCR (Supplementary Figs. 14–16). These results indicate the high breeding value of RppK in maize.
The RppS gene is an allele of RppK
There are eight other SCR resistance QTLs mapped to the same region as RppK on the short arm of chromosome 1033,37,40,41,42,43,44. We obtained resistant donor lines for five of those QTLs (CML470, CML496, P25, QI319, and SCML205) and analyzed their genetic relationships with RppK. By genotyping these lines using four markers (Del13K, R8.65, R8.63, and R8.61), we discovered that only SCML205, which carried the RppS locus, showed the same genotype as K22 (Supplementary Table 3). Furthermore, sequencing analysis revealed that SCML205 carried a RppK genomic DNA sequence almost identical to the RppK gene from K22, with only a 2 bp-indel difference in the second intron region between the two alleles (Supplementary Fig. 17). Therefore, the RppS locus from SCML205 is likely to be identical to RppK in K22.
Cloning of AvrRppK from P. polysora
In order to identify AvrRppK, we used PacBio sequencing to obtain the full-length mRNA sequences of P. polysora isolated from germinated urediospores. Through extensive bioinformatic analysis50,51, we identified 965 P. polysora genes (PPGs) predicted to encode secretory proteins, and successfully cloned 338 of them with a cysteine content greater than 1.8% (Supplementary Fig. 18).
The recognition of an Avr protein by the corresponding R protein typically activates the hypersensitive response (HR), which is a rapid cell-death phenotype. A powerful tool for Avr gene identification has been developed based on transient protoplast expression of the LUC reporter gene, whose expression level is used as an indicator of cell viability52,53. To identify the interactor of the RppK gene, we coexpressed the 338 cloned PPGΔSPs (PPG genes without signal peptide region) with the LUC gene in the protoplasts of transgenic RppK plants and nontransgenic control plants. Rp1-D21, an HR-activating NLR gene54, was used as a positive control (Fig. 3a). Only PPG1259ΔSP induced a strong HR in the protoplasts of transgenic RppK plants and no HR in those of nontransgenic control plants (Fig. 3b and Supplementary Fig. 19). Further, we deployed the transient expression system in Nicotiana benthamiana. The RppK genomic DNA clone was coexpressed with the PPG1259ΔSP gene in N. benthamiana. We observed a clear HR when the RppK and PPG1259ΔSP clones were coinfiltrated (Fig. 3c). In contrast, no HR was triggered by the infiltration of RppK genomic DNA or PPG1259ΔSP with an empty vector (EV) (Fig. 3c and Supplementary Fig. 20). This indicated that RppK induced the HR in a PPG1259-dependent manner. Moreover, we generated recombinant constructs encoding GST-PPG1259ΔSP and GST-PPG348ΔSP for the protein infiltration assay. PPG348ΔSP was used as a negative control because it did not induce cell death in maize protoplasts with or without RppK. These two constructs were expressed in Escherichia coli, and the purified recombinant proteins were digested with 3 C PPase to cleave the GST tag (Supplementary Fig. 21). The purified PPG1259ΔSP and PPG348ΔSP proteins were then infiltrated into the leaves of transgenic RppK plants and nontransgenic control plants. One day after infiltration, a clear HR was observed in the PPG1259ΔSP-infiltrated leaves of transgenic RppK plants but not in the PPG1259ΔSP-infiltrated leaves of nontransgenic control plants (Fig. 3d). As expected, no HR was observed in the PPG348ΔSP-infiltrated leaves of either transgenic RppK plants or nontransgenic control plants (Fig. 3d). So, we conclude that the interaction between PPG1259 encoded AvrRppK protein and RppK could trigger ETI.
We also coexpressed the RppS genomic DNA clone with the AvrRppKΔSP gene in N. benthamiana. A clear HR was observed when the RppS and AvrRppKΔSP clones were coinfiltrated and no HR was triggered in the controls (Supplementary Fig. 22). It indicates that RppS might recognize AvrRppK to trigger ETI.
AvrRppK of P. polysora suppresses plant resistance
AvrRppK encodes a 96-aa protein with a predicted secretion signal peptide at the N-terminus but lacks any other known structural domain. BLASTP and BLASTN analysis identified no proteins or genes with similarity to AvrRppK. Therefore, AvrRppK might only exist in P. polysora. By using single-cell sequencing technology55, we sequenced and annotated part of the genome of a P. polysora strain isolated from Wuhan and identified one contig (8.2 kb) containing the AvrRppK gene, which was flanked by a large number of repeat sequences (Supplementary Fig. 23).
To evaluate the variation in AvrRppK in natural P. polysora isolates, we designed gene-specific molecular markers to examine the genotypes of more than 100 P. polysora isolates collected from corn fields in Hainan, Guangxi and Hubei provinces in China. AvrRppK gene sequences with the same size were successfully amplified from the isolates. Furthermore, we sequenced the AvrRppK coding sequences amplified from 20 isolates from Hainan, 11 isolates from Guangxi, 6 isolates from Hubei and mixed P. polysora spores from the field. Interestingly, their coding sequences of AvrRppK from all isolates were identical to the AvrRppK coding DNA sequence of the Wuhan isolate (Fig. 4a). Therefore, the AvrRppK gene was highly conserved in P. polysora.
RT-qPCR assays showed that AvrRppK was expressed at high levels relative to the P. polysora Actin gene at 1, 3, 5, 7, and 9 days after inoculation (Fig. 4b). To determine whether AvrRppK can enhance disease development, we generated transgenic maize plants overexpressing AvrRppK∆SP driven by ZmUbi promoter and RT-qPCR results confirmed the expression of AvrRppK∆SP in two independent lines (Fig. 4c). After challenged with P. polysora, AvrRppK∆SP transgenic-positive plants in two independent lines showed more susceptible response to SCR than transgenic-negative plants (Fig. 4d, e) and more P. polysora biomass was accumulated in AvrRppK∆SP transgenic-positive plants than in transgenic-negative plants (Fig. 4f). It indicates that expression of AvrRppK can enhance the development of SCR.
In order to test whether AvrRppK can suppress ETI, we coexpressed AvrRppK∆SP with Rp1-D21 in N. benthamiana, and clear HR was observed, similar as overexpression of Rp1-D21 alone (Supplementary Fig. 24), which indicates AvrRppK cannot suppress Rp1-D21-mediated ETI. Further, we tried to test whether AvrRppK could suppress PTI. Transgenic plants overexpressing AvrRppK∆SP were treated with chitin and two typical PTI responses (MAP kinase signaling and ROS accumulation) were examined. As the results shown, the chitin-triggered MAP activation was suppressed in AvrRppK∆SP transgenic-positive plants, compared with that in transgenic-negative plants (Fig. 4g and Supplementary Fig. 25a). Also, the chitin-triggered ROS accumulation in AvrRppK∆SP transgenic-positive plants was weaker than that in transgenic-negative plants (Fig. 4h and Supplementary Fig. 25b). All of these results indicate that AvrRppK can significantly suppress chitin-triggered PTI.
Discussion
The ideal disease resistance in crops would be durable, broad-spectrum resistance, and with no fitness tradeoffs. Here, we reported the cloning of a maize NLR gene, RppK, for resistance against southern corn rust (SCR), and its cognate Avr gene, AvrRppK, from P. polysora (the causal pathogen of SCR). The introgression of the RppK gene into different maize inbred lines and hybrid lines significantly enhanced resistance against multiple P. polysora isolates and increased yield in the present of P. polysora.
Effector proteins are major virulence factors of biotrophic and hemibiotrophic pathogens that suppress plant immunity16,56. In resistant plants, NLR proteins detect effector proteins and trigger ETI57. However, effector proteins are subject to rapid evolution through deletions or mutations21,58. Consequently, resistant plants may regain susceptibility to pathogens. For example, the disruption of the AvrSr35 gene by a MITE insertion in Puccinia graminis f. sp. tritici prevents recognition by the wheat NLR gene Sr3559. However, the core effectors of pathogens are highly conserved and widely distributed in particular pathogens, and the mutation of a core effector significantly suppresses pathogen virulence58. Three core effectors in Ustilago maydis, Cce1, Pep1 and Vp1, are highly conserved in smut fungi and are required for their virulence60,61. In the present study, the coding sequences of AvrRppK were found to be identical in all tested P. polysora isolates (Fig. 4a), and AvrRppK was highly expressed during infection (Fig. 4b). Overexpression of AvrRppK in maize significantly suppressed maize resistance against SCR and reduced chitin-mediated PTI (Fig. 4d–h and Supplementary Fig. 25). All of this evidence indicated that AvrRppK might function as an effector. However, it should be noted that we didn’t provide genetic evidences to support its role as a core effector.
Since core effectors are highly conserved in specific pathogens, it has been proposed that the deployment of NLR genes corresponding to core effectors is a promising strategy for achieving broad-spectrum resistance21. Although many core effectors have been identified by comparing the genomic DNA sequences of different strains of a specific pathogen58,62,63, no NLR genes recognizing these core effectors have been identified. Here, we cloned a maize NLR gene, RppK. The introgression of RppK into multiple elite maize inbred lines and hybrids significantly enhanced resistance against P. polysora and increased yields in the present of P. polysora (Fig. 2 and Supplementary Figs. 12–15). The improved maize lines were planted in different locations and were challenged with different P. polysora isolates, and the results showed that RppK functioned well in all tested locations (Supplementary Figs. 12 and 14–16). These results indicate that the deployment of a single NLR gene is sufficient to activate resistance against multiple P. polysora isolates.
Although the introgression of resistance genes into crops normally causes fitness tradeoffs64, no yield loss in the absence of P. polysora was observed in any of the tested maize hybrid lines after the introgression of the RppK gene (Fig. 2c, d, f and Supplementary Figs. 13–15). Furthermore, several important agricultural traits were unaffected by the introgression of the RppK gene (Supplementary Figs. 13 and 14). All of these results confirmed that the RppK gene presents great values in maize breeding.
In the 500 inbred lines, only seventeen inbred lines contains RppK gene (Supplementary Data 1). Six of them belong to non-stiff stalk (NSS) group; eight of them belong to tropical-subtropical (TST) subgroup; and three of them belong to mixed subgroup (Supplementary Table 4)48. Also, eleven of the seventeen lines were originated from China, and six of them were originated from CIMMYT, Mexico (Supplementary Table 4)48. Further, only five of 74 commercial maize hybrids in China contain RppK gene (Supplementary Fig. 11 and Supplementary Data 4). Based on the information on https://chinaseed114.com, they were released to the market during the last 12 years. So, RppK gene is a rare allele and it has not been widely spread in maize inbred lines, which partially explain why RppK gene has been durable for more than 30 years in China.
Effectors as the major virulence weapons of pathogens and NLR proteins as the major components of the plant immune system are subjected to evolutionary pressure65, which consequently results in high variation in effectors and NLR proteins16,21. Core effectors are widely distributed in a particular pathogen21,58. It indicates that pathogens cannot afford to lose them58. To evade the recognition by host resistance proteins, some core effectors show polymorphism in different isolates. Multiple Avramr1 homologs were identified from different P. infestans isolate and they are recognized by different Rpi-amr1 alleles66. In order to explain why core effectors are not deleted in the arm-race, more studies on NLR proteins and core effectors should be conducted in future.
Methods
Plant materials
The resistant inbred line K22, derived from K11 × Ye478 cross, is an elite subtropical line and has been used for breeding program in China for ~30 years67. The susceptible donor DAN340, with good agronomic traits, is one of the main inbred lines from the Luda Red Cob group in China.
The F6:7 RIL population of 192 lines was generated by crossing K22 with DAN340, followed by subsequent self-pollination45,46. The K22 × DAN340 (KD) RILs and their parental lines were planted at Sanya (109.2 °N, 18.3 °E), Hainan Province, China in 2011, 2012, and 2013 and at Xinxiang (113.9 °N, 35.3 °E), Henan Province, China in 2014. Two repeats were planted at each location in 2011, 2013 and 2014, and one repeat was planted in 2012. KD RILs and their parental lines were planted in a randomized complete block design.
The association mapping panel (AMP) containing 500 diverse maize inbred lines has been reported previously48. The AMP lines were planted from 2011 to 2016 at three locations with a randomized complete block design. The panel lines were planted with one repeat in 2011, 2012, 2015, and 2016 and three repeats in 2013 at Sanya in Hainan Province. The lines from the same panel were planted with two repeats in two trials (i.e., Nanning (108.4 °N, 22.8 °E) in China in 2011, 2012, and Xinxiang in 2014). All lines were grown in 3.0 m row spaced 0.67 m apart with a planting density of 45,000 plants ha−1.
Disease scoring in the field
The conditions with warm temperature and high humidity in Hainan Province were favorable for SCR development. The mapping lines of RIL populations were naturally infected along with DAN340 and BY815 as the susceptible control and K22 as the resistance control. The SCR phenotype was scored at the third or fourth weeks after pollination. Using the following one-nine-point scale: “1”, no disease symptom or only hypersensitivity response; “2”, 5–10% leaf area infected; “3”, 15–20% leaf area infected; “4”, 30–40% leaf area infected; “5”, 50% leaf area infected; “6”, 60% leaf area infected; “7”, 70% leaf area infected; “8”, 80–90% leaf area infected; and “9”, the whole leaf infected and dead (Supplementary Fig. 1b). The best linear unbiased predictor (BLUP) values for each RIL and AMP lines were calculated according to the methods with minor modification46. The BLUP values of KD RIL were used for QTL mapping by composite interval method68.
Inoculation in greenhouse
Maize plants were planted in the Greenhouse at Huazhong Agricultural University. The inoculation with P. polysora urediospores was followed by the leaf method with minor modifications69. Urediospores of P. polysoda were collected from susceptible lines in Nanbing Farm, Hainan Province. The spores were brushed down from susceptible leaves with brush pens into 20 ml distilled water with one drop of Tween-20. The spores were completely suspended and adjusted to a final concentration of 5 × 105 spores/ml. The fully extended leaves of B73, transgenic-positive and negative plants at the 6-leaf stage were painted with spore suspension. The temperature in the greenhouse was set from 25 to 30 °C. All lines were covered with non-permeable plastic films on the top to keep high humidity. The disease symptom with pinpoint spots was observable at one week after inoculation. The experiment was repeated at least three times with similar results.
BAC library screening and sequence analysis
The BAC library of resistant line K22 was constructed at The Genome Resource Laboratory at Huazhong Agricultural University. Etiolated seedlings, grown in the dark for 2–3 weeks, were collected and frozen in liquid nitrogen. The BAC library was constructed using the standard protocols70. A total of 120960 clones were obtained and were saved individually in 315 384-well-plates with an average insertion size of 150 kb. Five positive BAC clones carrying RppK gene were identified by using PCR primers, RUST7-5 and RUST9-4 and were further confirmed with PCR amplification by primers, RRD39, RRD44, RUST8-2, RRD15, and RRD64, followed by sequencing of the PCR fragments. DNA of the five positive BAC clones were extracted using Large-Construct Kit (QIAGEN, Cat No. 12462) and was used for construction of a 20 kb insertion library for PacBio RSII. SMRT sequencing was performed in one SMRT Cell on a PacBio RSII instrument. After filtering the adaptor and low-quality reads in the raw sequencing reads, the clean data were assembled using SMRT analysis software. The contiguous sequence of about 230 kb for the genomic fragment was obtained from those BAC clones. The sequence of the target region containing three NLR genes, R1, R2 and R3, were confirmed again by Sanger sequencing.
The BAC library screening and BAC clone sequencing of inbred line 1145 was performed similarly to that of K22. Two positive BAC clones covering the candidate region were identified and sequenced. The sequence results showed that the candidate region in line 1145 is 117 kb.
The BAC library of maize inbred line DAN340 was constructed from young ear tissue70. To optimize cost and efficiency without sacrificing time and coverage, we combined BAC clones to make superpools and after the genomic DNA fragment by partial digestion inserted them into pIndigoBAC536-S vector. Those superpools were constructed in two dimensions for each plate in multiple copied and positive clones were identified using primers: RUST7-5 and RUST9-4. The positive superpools were diluted and spread onto culture for screening of positive clones using the same primers. One positive BAC clone was identified by utilization of this strategy and was amplified by polymorphism markers to deduce the covered length. This single BAC clone from inbred line DAN340 was sequenced by Pacific Biosciences single-molecule sequencing as described above and was found to contain a 102 kb genomic fragment insertion.
The repetitive elements in the genomic sequences of candidate region were analyzed by using RepeatMasker Web Server (www.repeatmasker.org/). Gene annotation were analyzed by using the coding sequences of the B73 reference genome (AGPv2, FGS 5b71) with GMAP package (version 2015-09-2972). The gene finding programs including GENSCAN and Fgenesh were also used73,74. Those results were combined together manually. The sequence comparison between homology regions of RppK locus was done by using BLASTN suite from the National Center for Biotechnology Information. The graphical display of alignment was drawn with genoPlotR package (version 0.8.2)75.
Breakpoint detection in recombinant families
To confirm the breakpoints in recombinant lines between RRD103 and RRD111, they were first genotyped with primers R8.63 and R8.61 to confirm the allele on the R3 promoter and then tested for the presence of the R1 and R2 genes using primer R8.65. The results were verified by sequencing PCR products as follows: presence of both R1 and R2 genes, double peaks at the nucleotides 662, 676 and 694 (relative to ATG of R2 gene) in sequencing chromatogram; presence of only R1 gene, single peaks at those sites and “ACA” haplotype; presence of only R2 gene, single peaks at those sites but “TGG” haplotype (Supplementary Fig. 10b, c). Based on the result of R8.63, R8.61 and R8.65, the recombination model of families was constructed. Furthermore, the R8.53 PCR products of recombination families were sequenced and were aligned with R1, R2, R3, and DR3 of BAC sequences. For those families in which no breakpoint in R8.53 region was identified, they were sequenced again with R8.65F/R8.64F or R8.63R/R8.64F based on the model. Those families in which the breakpoint occurred in the last intron of NLR genes, they were not used for future analysis.
Transgenic maize generation and functional validation
R2 and R3 genomic fragments from BAC clones were subcloned into vector pZZ01523 and the positive clones were confirmed by sequencing. The transgenic construct (pMA138) contained the genomic sequence of R3 gene (11443 bp) including 3086 bp promoter and 2378 bp downstream regions (Fig. 1f). The transgenic construct (pMA115) contained the genomic sequence of R2 gene (12611 bp) including 4703 bp promoter and 4464 bp downstream region (Supplementary Fig. 7a). Both pMA138 and pMA115 were transferred into KN5585, a SCR susceptible maize inbred lines, by the gene transformation platform of China National Seed Group. All the positive genomic transformation plants were self-crossed or backcrossed to KN5585. Transgenic plants were grown in Transgenic Experimental Farm of Beijing Academy of Agriculture and Forestry at Sanya, Hainan Province. Those plants including transgenic-positive plants and transgenic-negative plants were identified in each generation with R2- and R3-specific primers and were infected under natural inoculation. The procedures for SCR testing including the investigation time and standard of disease scores were the same as those used for RILs. The progeny-test assay was done in different genetic background populations. Statistically significant difference between transgenic and nontransgenic subgroups was determined by Student’s t-test with P-value < 0.05.
PPG1259 CDS region without the signal peptide (PPG1259∆SP) driven by ZmUbiquitin promoter was cloned into pZZ01523. The positive clone was confirmed by sequencing and was transferred into KN5585 by the gene transformation platform of Weimi Biotechnology Co., Ltd.
Cell-death assay in maize protoplasts
Maize protoplasts were isolated from 10 days old plants for transformation using PEG-calcium transfection of plasmid DNA and protoplast culture76. Constructs expressing candidate genes were co-transfected with the plasmid containing firefly Luciferase (Luc) gene into maize protoplasts as described before77. The concentrations of each plasmid and each protoplast sample were kept at the same level for all repeats and experiments. For each construct, three technical repeats were used. At 24 h after transformation, the protoplast viability was checked under fluorescence microscope (Leica). Luciferase activity was measured and quantified using a luciferase assay system (Promega). All of those experiment was repeated three times. Data were analyzed by GraphPad Prism 8 software. The experiment was repeated at least three times with similar results.
RT-qPCR assay
Maize inbred line B73 at five-leaf stage was inoculated with P. polysora urediospores under high-humidity conditions. mRNA was isolated from leaf samples collected at different time points after inoculation by using Trizol (Invitrogen). Moreover, RT-qPCR was done by using SYBR premix (TaKaRa) on real-time PCR (CFX96 Real-Time System, Bio-Rad). All of the experiments were done at least three times. Primers for detecting the expression levels of AvrRppK are listed in Supplementary Data 5. For each assay, the experiment was repeated at least three times with similar results.
Single-cell DNA whole-genome sequence of P. polysora
For the single-cell DNA whole-genome sequencing, more than one hundred urediospores from a single uredium of P. polysora were picked up by needles under microscope. DNA from those spores were isolated by using the QIAGEN REPLI-g Single-Cell Kit and DNA amplification was done by MDA following the standard protocol55. The whole-genome amplification products were submitted for detection and sequencing.
Identification of effector candidate genes in P. polysora
P. polysora urediospores collected from inoculated leaves in greenhouse were evenly dispersed on the surface of sterile water and kept at room temperature for 24 h. Then the mycelia were collected and washed three time by sterile water. RNA was isolated from the collected mycelia by Trizol (Invitrogen) and was submitted for Pacbio sequencing (Shanghai Personal Biotechnology Co., Ltd). The sequence results were analyzed by SMRT analysis (V2.3) and 53296 full-length sequences were identified50. The full-length transcripts were transcribed by Transdecoder v4.1.0 and signal peptide in ORF were analyzed by SignaIP-4.051. The analysis identified 965 secretory proteins and 338 of them were successfully cloned.
Transient expression in N. benthamiana
For transient expression assay in N. benthamiana, constructs were transformed by electroporation into the Agrobacterium strain GV3101 and positive Agrobacterium transformants were identified by PCR using primers specific to each construct. Agrobacteria were inoculated into LB medium and grown overnight at 28 °C with shaking. Agrobacterium cultures were collected by centrifugation at 4602 × g for 10 min and the bacterial pellet were resuspended in the infiltration buffer (10 mM MES, 10 mM MgCl2 and 200 µM acetosyringone) and adjusted to OD600 of 0.5 before infiltration into the leaves of 30-day old N. benthamiana. Leaves of N. benthamiana for transient expression. HA tagged proteins were detected by western blot using anti-HA antibody (Abcom, Cat#49969, dilution 1:1000). The experiment was repeated at least three times with similar results.
Expression and purification of recombinant proteins in E. coli
For expression and purification of GST recombinant proteins in E. coli, the coding DNA sequences of PPG1259 and PPG348 without the signal peptide were cloned into the GST expression vector pGEX-4T-1. The recombinant constructs were transformed into home-made E. coli BL21 competent cells. The expression of recombinant proteins in E. coli was induced by adding isopropyl-b-D thiogalactopyranoside (IPTG) and the purification of proteins was performed according to the manufacturer’s manual. The purified proteins were digested by 3C PPase to cleave the GST tag.
For the protein infiltration assay, two-week old seedlings of RppK-positive transgenic and negative transgenic plants from the same transgenic line were used. Purified PPG1259ΔSP and PPG348ΔSP proteins were diluted to 0.2 mg/ml in 1× PBS buffer and infiltrated into the first leaf of RppK-positive and negative transgenic plants using 1 ml syringe. The hypersensitive response (HR) was evaluated at 24 h after infiltration. The experiment was repeated at least three times with similar results.
ROS detection assay and MAPK kinase activity assay
For ROS detection assay, two independent PPG1259ΔSP transgenic lines at three-leaf stage were tested in this assay. Leaf discs were taken by using a 4 mm diameter punch. All discs were put in 1% DMSO for overnight, then 1% DMSO was replaced by 2× L-012 in 0.005% Silwet L-77 and disc samples were treated for 1 h. Two kinds of 2× HRP buffer were prepared; one was for the treatment buffer containing 50 mg/ml chitin and the other was for the mock control without chitin. Next, eight cells were treated with treatment buffer and the others were treated with the mock buffer. A microplate detector was used to collect light signals, which reflected ROS production. The signal was read every one minute for one hour and the data were analyzed to display the changes of ROS production over time. The experiment was repeated at least three times with similar results. Moreover, statistical tests were done by two-tailed Student’s test with P < 0.05.
For chitin-induced MAPK kinase activity assay, two independent PPG1259ΔSP transgenic lines at six-leaf stage were tested in this assay. The fully extended leaves were treated with 50 mg/ml chitin for 0, 5, 15, or 30 min. Then leaf samples were grounded for protein extraction. Equal amount of proteins was loaded onto a 12% SDS-PAGE gel for western blot. MAPK kinase activity was examined by using anti-phospho-p44/42 antibody (Cell Signaling Technology, 9101S, dilution 1: 1000) and the loading actin control was examined by using anti-Actin antibody (ABclonal, AC009, dilution 1: 5,000). Relative MAP kinase activity was normalized to the level of Actin protein. The experiment was repeated at least three times with similar results. Statistical tests were done by two-tailed Student’s t-test with P value < 0.05.
Molecular breeding of RppK
The cultivar K22 carrying RppK was crossed with two parental inbred lines of JK968 (Jing724 × Jing92), an elite hybrid widely planted in China, and backcrossed four time with recurrent parents to generate the BC4F1 plants, which self-crossed two time to generate the BC4F3 lines. Molecular markers were used to maintain the K22-derived RppK locus. Two pairs of near isogenic lines (NILs): Jing724RppK and Jing724, Jing92RppK and Jing92 were selected from the BC4F3 progenies. Selected Jing724RppK and Jing92RppK carrying the RppK locus were genotyped with Genotyping-by-Sequencing and found to contain 97.4% and 96.9% of their respective recurrent parent genome. The Jing724RppK and Jing92RppK lines were crossed to generate the improved hybrid JK968a (Jing724 × Jing92RppK) and JK968b (Jing724RppK × Jing92RppK). The improved IL4RppK line was selected with similar molecular assisted selection. The inbred line IL3 was crossed with IL4 or improved IL4RppK to generate the original Hybrid2wt or the improved Hybrid2RppK (IL3 × IL4RppK). The inbred lines: Jing72464, JingMC01 and Jing88 were respectively crossed with inbred line Jing2416 and Jing2416K (with the same RppK locus as K22), respectively, to generate paired hybrids: MC121wt and MC121RppK, JNK728wt and JNK728RppK, JNK828wt and JNK828RppK.
To test the performance of hybrids in the field, we planted those hybrids in fields for yield tests under two conditions: a) none-SCR condition: fields in Tongzhou (116.6 °N, 39.9 °E), Changping (116.2 °N, 40.2 °E) and Huanggang (114.9 °N, 30.5 °E), China, in 2020; b) SCR condition: natural SCR nursery fields in Bozhou (115.8 °N, 33.9 °E) and Yongcheng (116.4 °N, 33.9 °E), China in 2020. Field trials of hybrids JK968 and JK968a were conducted in three locations: Bozhou, Tongzhou and Changping. Field trials for hybrids MC121wt and MC121RppK, JNK728wt and JNKRppK, JNK828wt and JNK828RppK were done in two locations: Bozhou and Tongzhou. Each line was planted in nine subplots and each subplot contains two rows. Each row was 5 m long and spaced 60 cm with 19 plants. Field trials of hybrids JK968 and JK968b, Hybrid2wt and Hybrid2RppK were conducted in two locations: Yongcheng and Huanggang. Each line was planted in sixteen subplots and each subplot contains one row. Each row was 3 m long and spaced 50 cm with 11 plants. The agronomic traits (flowering time, plant height and ear height) of each line were investigated. All ears were harvested and dried to uniform moisture for scoring ear and grain traits. Yield-related traits (ear length, ear diameter, ear weight and kernel weight per plant) in a subplot were calculated. Statistically significant difference between wild-type lines and improved lines was evaluated by two-tailed Student’s t-test with P-value < 0.05.
The transgenic-positive line KN5585RppK and negative line KN5585Wt were crossed with four inbred lines (B73, Mo17, IL1, and IL2) to generate F1 hybrids. Those hybrids were planted in Sanya, China in 2019 to test the yield performance. Each hybrid line was planted eight rows and each row was set as one subplot. The SCR score and yield-relative traits were investigated. Statistically significant difference between hybrid line without RppK gene and improved hybrid lines with RppK gene was evaluated by two-tailed Student’s t-test with P value < 0.05.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
The RppK locus genomic DNA sequences from K22, DAN340, and 1145 are available at NCBI under accessions MZ322317, MZ322318, MZ312612, respectively. The RNA-seq data generated by PacBio sequencing is available at NCBI under the BioProject ID PRJNA732947; the P. polysora genomic DNA sequence data generated by single cell is available under the BioProject ID PRJNA732557. Source data are provided with this paper.
References
Johal, G. S. & Briggs, S. P. Reductase activity encoded by the HM1 disease resistance gene in maize. Science 258, 985–7 (1992).
Hurni, S. et al. The maize disease resistance gene Htn1 against northern corn leaf blight encodes a wall-associated receptor-like kinase. Proc. Natl Acad. Sci. USA 112, 8780–5 (2015).
Yang, P. et al. Alleles of a wall-associated kinase gene account for three of the major northern corn leaf blight resistance loci in maize. Plant J. 106, 526–535 (2021).
Collins, N. et al. Molecular characterization of the maize Rp1-D rust resistance haplotype and its mutants. Plant Cell 11, 1365–76 (1999).
Liu, Q. et al. A helitron-induced RabGDIalpha variant causes quantitative recessive resistance to maize rough dwarf disease. Nat. Commun. 11, 495 (2020).
Leng, P. et al. Auxin binding protein 1 reinforces resistance to sugarcane mosaic virus in maize. Mol. Plant 10, 1357–1360 (2017).
Ye, J. et al. The auxin-regulated protein ZmAuxRP1 coordinates the balance between root growth and stalk rot disease resistance in maize. Mol. Plant 12, 360–373 (2019).
Yang, Q. et al. A gene encoding maize caffeoyl-CoA O-methyltransferase confers quantitative resistance to multiple pathogens. Nat. Genet. 49, 1364–1372 (2017).
Wang, C. et al. A transposon-directed epigenetic change in ZmCCT underlies quantitative resistance to gibberella stalk rot in maize. N. Phytol. 215, 1503–1515 (2017).
Li, N. et al. Natural variation in ZmFBL41 confers banded leaf and sheath blight resistance in maize. Nat. Genet. 51, 1540–1548 (2019).
Wang, H. et al. A teosinte-derived allele of a MYB transcription repressor confers multiple disease resistance in maize. Mol. Plant 14, 1846–1863 (2021).
Liu, Q. et al. An atypical thioredoxin imparts early resistance to sugarcane mosaic virus in maize. Mol. Plant 10, 483–497 (2017).
Zuo, W. et al. A maize wall-associated kinase confers quantitative resistance to head smut. Nat. Genet. 47, 151–7 (2015).
Deng, C. et al. The RppC-AvrRppC NLR-effector interaction mediates the resistance to southern corn rust in maize. Mol. Plant 15, 904–912 (2022).
Wang, S. et al. Comparative proteomics combined with analyses of transgenic plants reveal ZmREM1.3 mediates maize resistance to southern corn rust. Plant Biotechnol. J. 17, 2153–2168 (2019).
Jones, J. D. & Dangl, J. L. The plant immune system. Nature 444, 323–9 (2006).
Yuan, M. et al. PTI-ETI crosstalk: an integrative view of plant immunity. Curr. Opin. Plant Biol. 62, 102030 (2021).
Mine, A. et al. The defense phytohormone signaling network enables rapid, high-amplitude transcriptional reprogramming during effector-triggered immunity. Plant Cell 30, 1199–1219 (2018).
Yuan, M. et al. Pattern-recognition receptors are required for NLR-mediated plant immunity. Nature 592, 105–109 (2021).
Peng, Y. et al. Convergent and divergent signaling in PAMP-triggered immunity and effector-triggered immunity. Mol. Plant Microbe Interact. 31, 403–409 (2018).
Dangl, J. et al. Pivoting the plant immune system from dissection to deployment. Science 341, 746–51 (2013).
Li, W. et al. Exploiting broad-spectrum disease resistance in crops: from molecular dissection to breeding. Annu. Rev. Plant Biol. 71, 575–603 (2020).
Pretorius, Z. et al. Detection of virulence to wheat stem rust resistance gene Sr31 in Puccinia graminis f. sp. tritici in Uganda. Plant Dis. 84, 203–203 (2000).
Jin, Y. et al. Detection of virulence to resistance gene Sr24 within race TTKS of Puccinia graminis f. sp. tritici. Plant Dis. 92, 923–926 (2008).
Jin, Y. et al. Detection of virulence to resistance gene Sr36 within the TTKS race lineage of Puccinia graminis f. sp. tritici. Plant Dis. 93, 367–370 (2009).
Patpour, M. et al. First report of the Ug99 race group of wheat stem rust, Puccinia graminis f. sp. tritici, in Egypt in 2014. Plant Dis. 100, 863–863 (2016).
Klymiuk, V. et al. Cloning of the wheat Yr15 resistance gene sheds light on the plant tandem kinase-pseudokinase family. Nat. Commun. 9, 3735 (2018).
Qie, Y. et al. Development, validation, and reselection of wheat lines with pyramided genes Yr64 and Yr15 linked on the short arm of chromosome 1B for resistance to stripe rust. Plant Dis. 103, 51–58 (2019).
Vleeshouwers, V. et al. Understanding and exploiting late blight resistance in the age of effectors. Annu. Rev. Phytopathol. 49, 507–31 (2011).
Bart, R. et al. High-throughput genomic sequencing of cassava bacterial blight strains identifies conserved effectors to target for durable resistance. Proc. Natl Acad. Sci. USA 109, E1972–E1979 (2012).
Balint-Kurti, P. J. & Johal, G. S. In Handbook of Maize: its biology (eds. Bennetzen, J. L. & Hake, S. C.) 229–250 (Springer New York, 2009).
Mueller, D. et al. Corn yield loss estimates due to diseases in the United States and Ontario, Canada from 2012 to 2015. Plant Health Prog. 17, 211–222 (2016).
Wang, S. et al. Identification and fine mapping of RppM, a southern corn rust resistance gene in maize. Front. Plant Sci. 11, 1057 (2020).
Mueller, D. et al. Corn yield loss estimates due to diseases in the United States and Ontario, Canada, from 2016 to 2019. Plant Health Prog. 21, 238–247 (2020).
Sun, Q. et al. Southern corn rust caused by Puccinia polysora Underw: a review. Phytopathol. Res. 3, 25 (2021).
Stanton, W. R. & Cammack, R. H. Resistance to the maize rust, Puccinia polysora Underw. Nature 172, 2 (1953).
Zhou, C. et al. Characterization and fine mapping of RppQ, a resistance gene to southern corn rust in maize. Mol. Genet. Genomics 278, 723–8 (2007).
Sun, G. et al. Quantitative resistance loci to southern rust mapped in a temperate maize diversity panel. Phytopathology 112, 579–587 (2022).
Brewbaker, J. et al. General resistance in maize to southern rust (Puccinia polysora Underw.). Crop Sci. 51, 1393–1409 (2011).
Zhao, P. et al. Fine mapping of RppP25, a southern rust resistance gene in maize. J. Integr. Plant Biol. 55, 462–472 (2013).
Zhang, Y. et al. Mapping of southern corn rust-resistant genes in the W2D inbred line of maize (Zea mays L.). Mol. Breed. 25, 433–439 (2010).
Yao, G. et al. Mapping the maize southern rust resistance gene in inbred line CML470. J. Plant Gene Res. 14, 518–522 (2013).
Wu, X. et al. Geographic and genetic identification of RppS, a novel locus conferring broad resistance to southern corn rust disease in China. Euphytica 205, 17–23 (2015).
Lv, M. et al. Identification and fine-mapping of RppCML496, a major QTL for resistance to Puccinia polysora in maize. Plant Genome 14, e20062 (2020).
Pan, Q. et al. Genome-wide recombination dynamics are associated with phenotypic variation in maize. N. Phytol. 210, 1083–94 (2016).
Xiao, Y. et al. Genome-wide dissection of the maize ear genetic architecture using multiple populations. N. Phytol. 210, 1095–106 (2016).
Liu, N. et al. Intraspecific variation of residual heterozygosity and its utility for quantitative genetic studies in maize. BMC Plant Biol. 18, 66 (2018).
Yang, X. et al. Characterization of a global germplasm collection and its potential utilization for analysis of complex quantitative traits in maize. Mol. Breed. 28, 511–526 (2011).
Cai, W. et al. Research on new model of new varieties cooperated by science and enterprise cooperation based on the analysis of Jingke 968 corn variety R&D consorium. Till. Culti. 40, 3 (2020).
Gordon, S. et al. Widespread polycistronic transcripts in fungi revealed by single-molecule mRNA sequencing. PLoS ONE 10, e0132628 (2015).
Petersen, T. et al. SignalP 4.0: discriminating signal peptides from transmembrane regions. Nat. Methods 8, 785–6 (2011).
Lu, X. et al. Allelic barley MLA immune receptors recognize sequence-unrelated avirulence effectors of the powdery mildew pathogen. Proc. Natl Acad. Sci. USA 113, E6486–E6495 (2016).
Yoshida, K. et al. Association genetics reveals three novel avirulence genes from the rice blast fungal pathogen Magnaporthe oryzae. Plant Cell 21, 1573–1591 (2009).
Wang, G. F. & Balint-Kurti, P. J. Cytoplasmic and nuclear localizations are important for the hypersensitive response conferred by maize autoactive Rp1-D21 protein. Mol. Plant Microbe Interact. 28, 1023–31 (2015).
Li, X. et al. Dissecting meiotic recombination based on tetrad analysis by single-microspore sequencing in maize. Nat. Commun. 6, 6648 (2015).
Bialas, A. et al. Lessons in effector and NLR biology of plant-microbe systems. Mol. Plant Microbe Interact. 31, 34–45 (2018).
Zhou, J. M. & Zhang, Y. Plant immunity: danger perception and signaling. Cell 181, 978–989 (2020).
Chepsergon, J. et al. “Core” RxLR effectors in phytopathogenic oomycetes: A promising way to breeding for durable resistance in plants? Virulence 12, 1921–1935 (2021).
Salcedo, A. et al. Variation in the AvrSr35 gene determines Sr35 resistance against wheat stem rust race Ug99. Science 358, 1604–1606 (2017).
Hemetsberger, C. et al. The fungal core effector Pep1 is conserved across smuts of dicots and monocots. N. Phytologist 206, 1116–1126 (2015).
Seitner, D. et al. The core effector Cce1 is required for early infection of maize by Ustilago maydis. Mol. Plant Pathol. 19, 2277–2287 (2018).
Rojas-Estevez, P. et al. Effector repertoire of Phytophthora betacei: in search of possible virulence factors responsible for its host specificity. Front. Genet. 11, 579 (2020).
Fan, J. et al. A core effector UV_1261 promotes Ustilaginoidea virens infection via spatiotemporally suppressing plant defense. Phytopathol. Res. 1, 11 (2019).
Karasov, T. et al. Mechanisms to mitigate the trade-off between growth and defense. Plant Cell 29, 666–680 (2017).
Wang, Y. et al. Evasion of plant immunity by microbial pathogens. Nat. Rev. Microbiol. 20, 449–464 (2022).
Witek, K. et al. A complex resistance locus in Solanum americanum recognizes a conserved Phytophthora effector. Nat. Plants 7, 198–208 (2021).
Li, F. et al. The breeding of maize inbred line K22 and the analysis on the combine ability. J. Gansu Agric. Univ. 39, 4 (2004).
Zeng, Z. B. Precision mapping of quantitative trait loci. Genetics 136, 1457–68 (1994).
Chen, C. et al. Molecular tagging and genetic mapping of the disease resistance gene RppQ to southern corn rust. Theor. Appl. Genet. 108, 945–50 (2004).
Luo, M. & Wing, R. A. An improved method for plant BAC library construction. in Plant functional genomics (ed. Grotewold, E.) 3–19 (Humana Press, 2003).
Schnable, P. et al. The B73 maize genome: complexity, diversity, and dynamics. Science 326, 1112–5 (2009).
Wu, T. D. & Watanabe, C. K. GMAP: a genomic mapping and alignment program for mRNA and EST sequences. Bioinformatics 21, 1859–75 (2005).
Burge, C. & Karlin, S. Prediction of complete gene structures in human genomic DNA. J. Mol. Biol. 268, 78–94 (1997).
Solovyev, V. et al. Automatic annotation of eukaryotic genes, pseudogenes and promoters. Genome Biol. 7, S10 1–12 (2006).
Guy, L. et al. genoPlotR: comparative gene and genome visualization in R. Bioinformatics 26, 2334–5 (2010).
Du, Y. et al. Unbranched3 expression and inflorescence development is mediated by Unbranched2 and the distal enhancer, KRN4, in maize. PLoS Genet. 16, e1008764 (2020).
Yoo, S. et al. Arabidopsis mesophyll protoplasts: a versatile cell system for transient gene expression analysis. Nat. Protoc. 2, 1565–72 (2007).
Acknowledgements
We thank Dr. Mingling Xu at China Agricultural University, Dr. Zhixiang Chen at Purdue University, Dr. Jeffery L. Dangl at University of North Carolina, Dr. Hanhui Kuang at Huazhong Agricultural University, and Dr. Xuewei Chen at Sichuan Agricultural University for critical reading and comments. This work was supported by The National Key Research and Development Program of China (2016YFD0101002, Z.L.), the National Natural Science Foundation of China (31571676, Z.L.; 31761143008, Z.L.; 32072007, Z.L; and 31161140347, J.Y.).
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Contributions
G.C., H.W., and J.D. cloned RppK gene by map-based strategy and did disease evaluation. B.Z. did P. polysora avr gene screening, identified AvrRppK gene and examined the function of AvrRppK in suppressing PTI. B.Z., J.W., and H.Z. did protoplast assays. Q.P. sequenced AvrRppC gene in different P. polysora isolates and checked RppK genotypes in different hybrid lines. Junshi Huang, Jiabao Hou, Junfei Dong, J.Q., and F.Z. cloned genes encoding P. polysora secretory proteins. Q.Y. identified and cloned RppK gene transcripts and cloned RppS gene. G.C., H.W., and H.M. did bioinformatic analysis. W.L. did maize breeding and field management. C.D. did genotype analysis. G.T. and B.L. repeated the function of AvrRppK gene. X.L. generated maize transgenic plants. G.C., R.Z., and J.Z. evaluated the agricultural traits of hybrids. G.C. J.Y., and Z.L. wrote the manuscript. J.Y. and Z.L. directed the project.
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Patents with application No. PCT/US20 19/032497 (Methods of identifying, selecting, and producing southern corn rust resistance crops; Inventors: J.Y.; B.L.; G.T.; G.C.; J.D.; Z.L.; H.W.; Q.Y.) and WO 2019/236257 (Plant pathogen effector and disease resistance gene identification; Inventors: Z.L.; B.Z.; J.W.; Junshi Huang; H.W.; H.M.) are pending. Other authors claim no competing interests.
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Chen, G., Zhang, B., Ding, J. et al. Cloning southern corn rust resistant gene RppK and its cognate gene AvrRppK from Puccinia polysora. Nat Commun 13, 4392 (2022). https://doi.org/10.1038/s41467-022-32026-4
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DOI: https://doi.org/10.1038/s41467-022-32026-4
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