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RPW8/HR repeats control NLR activation in Arabidopsis thaliana

Abstract

In many plant species, conflicts between divergent elements of the immune system, especially nucleotide-binding oligomerization domain-like receptors (NLR), can lead to hybrid necrosis. Here, we report deleterious allele-specific interactions between an NLR and a non-NLR gene cluster, resulting in not one, but multiple hybrid necrosis cases in Arabidopsis thaliana. The NLR cluster is RESISTANCE TO PERONOSPORA PARASITICA 7 (RPP7), which can confer strain-specific resistance to oomycetes. The non-NLR cluster is RESISTANCE TO POWDERY MILDEW 8 (RPW8) / HOMOLOG OF RPW8 (HR), which can confer broad-spectrum resistance to both fungi and oomycetes. RPW8/HR proteins contain at the N-terminus a potential transmembrane domain, followed by a specific coiled-coil (CC) domain that is similar to a domain found in pore-forming toxins MLKL and HET-S from mammals and fungi. C-terminal to the CC domain is a variable number of 21- or 14-amino acid repeats, reminiscent of regulatory 21-amino acid repeats in fungal HET-S. The number of repeats in different RPW8/HR proteins along with the sequence of a short C-terminal tail predicts their ability to activate immunity in combination with specific RPP7 partners. Whether a larger or smaller number of repeats is more dangerous depends on the specific RPW8/HR autoimmune risk variant.

Author summary

In many plant species, conflicts between divergent elements of the immune system can cause hybrids to express autoimmunity, a generally deleterious syndrome known as hybrid necrosis. We are investigating multiple hybrid necrosis cases in Arabidopsis thaliana that are caused by allele-specific interactions between different variants at two unlinked resistance (R) gene clusters, RESISTANCE TO PERONOSPORA PARASITICA 7 (RPP7) and RESISTANCE TO POWDERY MILDEW 8 (RPW8)/HOMOLOG OF RPW8 (HR). The RPP7 locus encodes intracellular nucleotide binding site-leucine rich repeat (NLR) immune receptors that can confer strain-specific resistance to oomycetes, while the RPW8/HR locus encodes atypical resistance proteins, of which some can confer broad-spectrum resistance to filamentous pathogens. There is extensive structural variation in the RPW8/HR cluster, both at the level of gene copy number and at the level of C-terminal, 21- or 14-amino acid long RPW8/HR repeats. We demonstrate that the number of RPW8/HR repeats and the short C-terminal tail correlate, in an allele-specific manner, with the severity of hybrid necrosis when these alleles are combined with RPP7 variants. We discuss these findings in light of sequence similarity between RPW8/HR and pore-forming toxins MLKL and HET-S from mammals and fungi.

Introduction

The combination of divergent parental genomes in hybrids can produce new phenotypes not seen in either parent. At one end of the spectrum is hybrid vigor, with progeny being superior to the parents, while at the other end there is hybrid weakness, with progeny being inferior to the parents, and in the most extreme cases being sterile or unable to survive.

In plants, a particularly conspicuous set of hybrid incompatibilities is associated with autoimmunity, often with substantial negative effects on hybrid fitness [13]. Studies of hybrid autoimmunity in several species, often expressed as hybrid necrosis, have revealed that the underlying genetics tends to be simple, with often only one or two major-effect loci. Where known, at least one of the causal loci encodes an immune protein, often an intracellular nucleotide binding site-leucine-rich repeat (NLR) protein [413]. The gene family encoding NLR immune receptors is the most variable gene family in plants, both in terms of inter- and intraspecific variation [1417]. Many NLR proteins function as major disease resistance (R) proteins, with the extravagant variation at these loci being due to a combination of maintenance of very old alleles by long-term balancing selection and rapid evolution driven by strong diversifying selection [1820]. The emergence of new variants is favored by many NLR genes being organized in tandem clusters, which can spawn new alleles as well as copy number variation by illegitimate recombination, and by the presence of leucine-rich repeats in NLR genes, which can lead to expansion and contraction of coding sequences [2123]. Cluster expansion has been linked to diversification and adaptation in a range of systems [2426]. Several complex plant NLR loci provide excellent examples of cluster rearrangement increasing pathogen recognition specificities [19]. Substantial efforts have been devoted to decomposing the complexity of the plant immune system and interactions between its components.

While many plant disease R genes are members of the NLR family, some feature different molecular architectures. One of these is RESISTANCE TO POWDERY MILDEW 8 (RPW8) in Arabidopsis thaliana, which was initially identified based on an allele that confers resistance to multiple powdery mildew isolates [27] and later shown also to provide resistance to oomycetes [28,29]. The namesake RPW8 gene is located in a gene cluster of variable size and composition that includes multiple RPW8-like genes as well as HOMOLOG OF RPW8 (HR) genes [27,30,31]. The reference accession Col-0, which is susceptible to powdery mildew, has four HR genes, but no RPW8 gene, whereas the resistant accession Ms-0 carries RPW8.1 and RPW8.2 along with three HR genes [27]. Several RPW8 proteins from A. thaliana and Brassica spp. become localized to the extra-haustorial membrane upon powdery mildew infection, highlighting their potential function at the host-microbe interface [29,32,33]. NLRs are distinguished by N-terminal Toll/interleukin-1 receptor (TIR) or coiled-coil (CC) domains, which, when overexpressed alone, can often activate immune signaling [34,35]. A subset of CC-NLRs (CNLs) has a diagnostic type of coiled-coil domain, termed CCR to indicate that this domain is being shared with RPW8/HR proteins. The latter have an N-terminal extension that might be a transmembrane domain as well as C-terminal repeats of unknown activity [36,37]. It has been noted that the CCR domain is similar to a portion of the animal mixed-lineage kinase domain-like (MLKL) protein that forms a multi-helix bundle [38] as well as the HeLo and HELL domains of fungi, which also form multi-helix bundles [3941]. Many fungal HeLo domain proteins have a prion-forming domain that consists of C-terminal 21-amino acid repeats. This domain can form amyloids and thereby affect oligomerization and activity of these proteins [3943].

We have previously reported hybrid necrosis due to incompatible alleles at the RPW8/HR locus and at the complex RECOGNITION OF PERONOSPORA PARASITICA 7 (RPP7) locus, which encodes a canonical CNL and which has alleles that provide race-specific resistance to the oomycete Hyaloperonospora arabidopsidis [44,45]. Here, we investigate in detail three independent cases of incompatible RPW8/HR and RPP7-like alleles, and show that two are caused by members of the fast-evolving RPW8.1/HR4 clade. We describe how variation in the number of C-terminal repeats and the short C-terminal tail predict the degree of incompatibility between two common RPW8.1/HR4 alleles and corresponding RPP7-like alleles.

Results

Distinct pairs of RPP7 and RPW8/HR alleles cause hybrid necrosis

In a systematic intercrossing and genetic mapping program among 80 A. thaliana accessions, a series of genomic regions involved in hybrid incompatibility were identified [10]. The underlying genes were termed DANGEROUS MIX (DM) loci. One instance, between the DM6 and DM7 regions, stood out because it is responsible for two phenotypically distinct hybrid necrosis cases (Fig 1A) [10]. Strong candidates, as previously inferred from a combination of mapping, gene knockdown and transformation with genomic constructs, suggested that DM6 corresponds to the RPP7 cluster, and DM7 to the RPW8/HR cluster. We recently found an additional case of incompatibility between the DM6 and DM7 regions, with a third distinctive phenotype (Figs 1A and 2A). In addition to phenotypic differences between the three DM6DM7 F1 hybrids, test crosses confirmed that each case was caused by different combinations of DM6 and DM7 alleles, as only certain combinations resulted in hybrid necrosis (Fig 1B).

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Fig 1. DM6DM7 hybrid necrosis cases.

(A) Morphological variation in three independent DM6DM7 hybrid necrosis cases. (B) Red lines indicate necrosis in F1 hybrids, grey indicates normal progeny. (C, D) Variation in morphology in two DM6DM7 cases sharing the same DM6 allele in Lerik1-3. (C) Entire rosettes of four-week-old plants. (D) Abaxial sides of eighth leaves of six-week-old plants. Inset shows Trypan Blue stained leaf of Lerik1-3 x Fei-0 F1. (E) Summary phenotypes in crosses of Lerik1-3 to 80 other accessions. Red is strong necrosis in F1, and yellow is mild necrosis in F1 or necrosis only observable in F2. Scale bars indicate 1 cm.

https://doi.org/10.1371/journal.pgen.1008313.g001

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Fig 2. Mapping of two DM6 (RPP7 cluster)–DM7 (RPW8/HR cluster) hybrid necrosis cases.

(A) QTL analyses. The QTL on chromosome 1 includes RPP7 from Lerik1-3 and ICE79 (21.37–22.07 and 21.50–21.98 Mb), and the QTL on chromosome 3 RPW8/HR from ICE106/ICE107 and Don-0 (18.59–19.09 Mb, 18.61–19.06 Mb). The horizontal lines indicate 0.05 significance thresholds established after 1,000 permutations. (B) Heat map for two-dimensional, two-QTL model genome scans. Upper left triangles indicate epistasis scores (LODi) and lower right triangles joint two-locus scores (LODf). Scales for LODi on left and for LODf on right. (C) Manhattan plot for a GWAS of necrosis in hybrid progeny of Lerik1-3 crossed to 80 other accessions (see S2 Table). The hit in the RPW8/HR region (red arrow) stands out, but it is possible that some of the other hits that pass the significance threshold (Bonferroni correction, 5% familywise error) identify modifiers of the DM6DM7 interaction.

https://doi.org/10.1371/journal.pgen.1008313.g002

To corroborate the evidence from mapping experiments that DM6 alleles of Mrk-0 and ICE79 were RPP7 homologs, we designed ten artificial microRNAs (amiRNAs) based on sequences from the Col-0 reference accession. AmiRNAs targeting a subclade of five RPP7 homologs that make up the second half of the RPP7 cluster in Col-0, suppressed hybrid necrosis in all three crosses, Mrk-0 x KZ10, Lerik1-3 x Fei-0 and ICE79 x Don-0 (S1 Fig and S1 Table). These rescue experiments, together with the above-mentioned test crosses, indicate that specific RPP7 homologs in Mrk-0, Lerik1-3 and ICE79 correspond to different DM6 alleles that cause hybrid necrosis in combination with specific DM7 alleles from other accessions.

A common set of RPW8/HR haplotypes affecting hybrid performances in F1 and F2 progeny

In the mentioned set of diallelic F1 crosses among 80 accessions [10], we noted that the DM6 carrier Lerik1-3 was incompatible with several other accessions, suggesting that these have DM7 (RPW8/HR) hybrid necrosis risk alleles that are similar to the one in Fei-0. Crosses with TueScha-9 and TueWa1-2 produced hybrids that looked very similar to Lerik1-3 x Fei-0 progeny, with localized spots of cell death spreading across the leaf lamina along with leaf crinkling and dwarfism (Fig 1D and S2 Fig). Similar spots of cell death and leaf crinkling were observed in crosses of Lerik1-3 to ICE106 and ICE107, although these were not as dwarfed (Fig 1C and 1D and S2 Fig).

Hybrid necrosis often becomes more severe when the causal loci are homozygous [5,7,10,12]. To explore whether Lerik1-3 might cause milder forms of hybrid necrosis that are missed in the F1 generation, we surveyed several F2 populations involving Lerik1-3. Six segregated necrotic plants with very similar phenotypes (Fig 1D and 1E and S2 Fig). This makes all together for 11 incompatible accessions, which are spread over much of Eurasia (Fig 1E).

The F2 segregation ratios suggested that the effects of the DM7 allele from ICE106/ICE107 are intermediate between those of the Fei-0/TueWa1-2/TueScha-9 alleles and the Cdm-0/Nie-0 alleles (Table 1). Alternatively, the hybrid phenotypes might be affected by background modifiers, such that identical DM7 alleles produce a different range of phenotypes in combination with DM6Lerik1-3.

Because the phenotypic variation among hybrid necrosis cases involving Lerik1-3 could involve loci other than DM6 and DM7, we carried out linkage mapping with Lerik1-3 x ICE106 and Lerik1-3 x ICE107 crosses. We combined genotyping information from Lerik1-3 x ICE106 and Lerik1-3 x ICE107 F2 and F3 individuals for mapping, because the genomes of ICE106 and ICE107, which come from closeby collection sites, are very similar and because the two crosses produce very similar F1 hybrid phenotypes, suggesting that the responsible alleles are likely to be identical. We used F3 populations to better distinguish different phenotypic classes, since we did not know the number of causal genes nor their genetic behavior. QTL analysis confirmed that the DM6 and DM7 genomic regions are linked to hybrid necrosis in these crosses (Fig 2A and 2B).

To narrow down the DM7 mapping interval, we took advantage of having 11 accessions that produced hybrid necrosis in combination with Lerik1-3, and 69 accessions (including Lerik1-3 itself) that did not. We performed GWAS with Lerik1-3-dependent hybrid necrosis as a binary trait [46]. The by far most strongly associated marker was immediately downstream of HR4, the last member of the RPW8/HR cluster in Col-0 (Fig 2C and S2 Table). An amiRNA matching HR4 sequences from Col-0 fully rescued both the strong necrosis in Lerik1-3 x Fei-0 and the weaker necrosis in Lerik1-3 x ICE106 (Fig 3A and S3 Table). We confirmed the causality of another member of the RPW8/HR cluster in the KZ10 x Mrk-0 case with a CRISPR/Cas9-induced mutation of RPW8.1KZ10 (Fig 3B and S3 Fig).

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Fig 3. Confirmation of causal genes in RPW8/HR cluster.

(A) Rescue of hybrid necrosis in Lerik1-3 x Fei-0 F1 plants with an amiRNA against HR4. Fei-0 parents were T1 transformants. PCR genotyping of numbered plants from left shown on the right. Only plant 1, which does not carry the amiRNA, is necrotic and dwarfed. (B) Rescue of hybrid necrosis in Mrk-0 x KZ10 F1 plants by CRISPR/Cas9-targeted mutagenesis on RPW8.1KZ10. (C) Recapitulation of hybrid necrosis in Lerik1-3 T1 plants transformed with indicated genomic fragments from Fei-0 and ICE106. Representative phenotypes on right. Numbers of T1 plants examined given on top. (D) Summary of rescue and recapitulation experiments. Asterisks refer to published experiments [10]. Scale bars indicate 1 cm.

https://doi.org/10.1371/journal.pgen.1008313.g003

In Col-0, but not in all A. thaliana accessions, resistance to H. arabidopsidis Hiks1 maps to the RPP7 cluster [47,48]. The RPP7-like hybrid necrosis risk allele carrier Lerik1-3 was resistant to Hiks1 as well, but Fei-0 and ICE106 were not. Resistance was inherited in a dominant manner (S4 Fig and S4 Table). We further used seven different amiRNAs against RPP7 homologs, three of which had suppressed hybrid necrosis in combination with HR4Fei-0 (S1 Table), to test whether RPP7 homologs underlie Hiks1 resistance in Lerik1-3. That none of the amiRNAs reduced Hiks1 resistance indicates minimally that there is no simple correspondence between the RPP7-like hybrid necrosis risk allele and the Hiks1 resistance gene. We also asked whether HR4 is required for RPP7-mediated Hiks1 resistance in Col-0. Two independent hr4 CRISPR/Cas9 knockout lines in Col-0 (S3 Fig) remained completely resistant to Hiks1 (S4 Fig and S4 Table), indicating that HR4 in Col-0 is dispensable for RPP7-mediated resistance to Hiks1.

Structural variation of the RPW8/HR cluster

For reasons of convenience, we assembled the RPW8/HR cluster from TueWa1-2 instead of Fei-0; accession TueWa1-2 interacted with RPP7-like gene from Lerik1-3 in the same manner as Fei-0; the strong necrosis in Lerik1-3 x TueWa1-2 was rescued with the same amiRNA as in Lerik1-3 x Fei-0 (S3 Table), and TueWa1-2 had an HR4 allele that was identical in sequence to HR4Fei-0. We found that the RPW8/HR cluster from TueWa1-2 had at least 13 RPW8/HR-like genes, several of which were very similar to each other (Fig 4A). For example, there were at least four copies of RPW8.3-like genes with 93 to 99.8% sequence similarity, and two identical RPW8.1 genes, named RPW8.1a, followed by distinct RPW8/HR copies.

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Fig 4. Structural variation of the RPW8/HR cluster.

(A) The RPW8/HR cluster in different accessions. The extreme degree of recent duplications in TueWa1-2, with the same HR4 hybrid necrosis risk allele as Fei-0, did not allow for closure of the assembly from PCR products; assembly gaps are indicated. Color coding of HR4 alleles according to Fig 6. HR4 and RPW8.1 form a distinct clade from other RPW8s. Tagging SNPs found in GWAS marked in TueWa1-2 RPW8/HR cluster as black vertical lines. (B) Maximum likelihood tree of RPW8/HR genes from three A. thaliana accessions and the A. lyrata and B. rapa reference genomes. Branch lengths in nucleotide substitutions are indicated. Bootstrap values (out of 100) are indicated on each branch.

https://doi.org/10.1371/journal.pgen.1008313.g004

Recapitulation experiments had identified HR4Fei-0 (identical to HR4TueWa1-2 and HR4TueScha-9) and HR4ICE106 as causal for hybrid necrosis (Fig 3C and 3D). We analyzed the phylogenetic relationship of the RPW8/HR genes in TueWa1-2 with the ones from published RPW8/HR clusters in A. thaliana, in A. lyrata and in Brassica spp. [10,30,31,49]. In A. thaliana, RPW8/HR genes seem to have undergone at least three duplication events, with the first one generating a new A. thaliana specific clade, which gave rise to independent RPW8.1/HR4 and RPW8.2/RPW8.3 duplications.

The RPW8/HR cluster of TueWa1-2 consists of RPW8/HR members from both the ancestral and the two A. thaliana specific clades, an arrangement that has not been observed before. Using species-wide data [50], we found that accessions carrying Col-0-like HR4 alleles have simple cluster configurations, while accessions with HR4 genes resembling hybrid necrosis alleles have more complex configurations (Fig 4A). The tagging SNPs found in GWAS (Fig 4A and S2 Table) were mostly found to be associated with the complex clusters, suggesting that the tagging SNPs are linked to structural variation in the distal region of the RPW8/HR cluster (Fig 4B).

Causality of RPW8/HR C-terminal repeats

To further narrow down the mutations that cause autoimmunity, we compared RPW8.1KZ10 and HR4Fei-0 with other RPW8/HR alleles from the global A. thaliana collection [50]. Some RPW8.1 alleles have intragenic duplications of a sequence encoding a 21-amino acid repeat (QWDDIKEIKAKISEMDTKLA[D/E]) at the C-terminal end of the protein [31]. In HR4, there is a related 14-amino acid repeat (IQV[H/D]QW[T/I]DIKEMKA). Both RPW8.1 and HR4 repeats are predicted to fold into extended alpha-helices, but only RPW8.1 repeats appear to have the potential to form coiled coils [51].

The number of repeats varies in both RPW8.1 and HR4 between hybrid necrosis risk and non-risk alleles. To experimentally test the effect of repeat number variation and other polymorphisms, we generated a series of derivatives in which we altered the number of repeats and swapped different portions of the coding sequences between the RPW8.1KZ10 risk and RPW8.1Ms-0 non-risk alleles, and between the HR4Fei-0 and HR4ICE106 risk and the HR4Col-0 non-risk alleles (Fig 5A).

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Fig 5. Necrosis-inducing activity of RPW8.1 and HR4 chimeras.

N-terminal portions indicated with the initial of the accession in italics (“K”, “M”, etc.), complete repeats indicated with regular capital letters (“A”, “B”, etc.), the partial repeat in KZ10 with a lowercase letter (“c”), and the C-terminal tails with Greek letters (“α”, “β”, etc.). Non-repeat portions are semi-transparent. Repeats with identical amino acid sequences have the same letter designation. Numbers indicate amino acid positions. Constructs on the left, and distribution across phenotypic classes in T1 transformants on the right, with n given on top of each column. Natural alleles labeled in color and bold. RPW8/HR repeats indicated as light grey boxes. (A) RPW8.1 chimeras, driven by the RPW8.1KZ10 promoter, were introduced into Mrk-0, which carries the corresponding incompatible RPP7-like allele. (B) HR4 chimeras, driven by the HR4Fei-0 promoter, were introduced into Lerik1-3, which carries the corresponding incompatible RPP7-like allele. Scale bars indicate 1 cm.

https://doi.org/10.1371/journal.pgen.1008313.g005

A 1.4 kb promoter fragment of RPW8.1KZ10 and a 1.2 kb promoter fragment of HR4Fei-0 in combination with coding sequences of risk alleles were sufficient to induce hybrid necrosis (Figs 3C, 5A and 5B). To simplify discussion of the chimeras, the N-terminal portion was labeled with the initial of the accession in italics (“M”, “K”, etc.), complete repeats were labeled with different capital letters to distinguish sequence variants (“A”, “B”, etc.), the partial repeat in KZ10 with a lowercase letter (“c”), and the C-terminal tails with Greek letters (“α”, “β”, etc.).

In RPW8.1KZ10, there are two complete repeats and one partial repeat, while RPW8.1Ms-0 has only one repeat (Fig 5A). Modifying the number of repeats in RPW8.1 affected the frequency and severity of necrosis in T1 plants in a Mrk-0 background, which carries the interacting RPP7-like allele, dramatically. Deletion of the first full repeat in RPW8.1KZ10 (“K-Bcβ”, with the KZ10 configuration being “K-BBcβ”) substantially reduced the number of plants that died in the first three weeks of growth. The additional deletion of the partial repeat (“K-Bβ”) reduced death and necrosis even further (Fig 5A). That K-Bβ still produces some necrosis, even though its repeat structure is the same as in the inactive K-Aα suggests that the polymorphism in the C-terminal tail makes some contribution to necrosis activity. It is less likely that the polymorphism in the repeats play a role, as there is only a very conservative aspartate-glutamate difference between A and B repeats.

In contrast to repeat shortening, the extension of the partial repeat (“K-BBBβ”) or addition of a full repeat (“K-BBBcβ”) increased the necrosis-inducing activity of RPW8.1KZ10, such that almost all T1 plants died without making any true leaves. However, it appears that not all repeats function equally, as removal of the partial repeat slightly increased necrosis-inducing activity (“K-BBβ”). Polymorphisms in the N-terminal non-repeat region seemed to contribute to necrosis, as swaps of the N-terminal Ms-0 fragment (“M-BBcβ” or “M-BBBβ”) induced weaker phenotypes than the corresponding variants with the N-terminal fragment from KZ10. Nevertheless, we note that the normal KZ10 repeat configuration was sufficient to impart substantial necrosis-inducing activity on a chimera in which the N-terminal half was from Ms-0, which is distinguished from KZ10 by nine nonsynonymous substitutions outside the repeats.

Compared to the RPW8.1 situation, the relationship between HR4 repeat length and necrosis-inducing activity is more complex. The natural alleles suggested a negative correlation of repeat number with necrosis-inducing activity when crossed to Lerik1-3, since the non-risk HR4 allele from Col-0 has five full repeats, while weaker risk alleles such as the one from ICE106 have two, and the strong risk allele from Fei-0 has only one (Fig 5B). Addition of a full repeat to HR4Fei-0 (“F-RTδ”, with the original Fei-0 configuration being “F-Tδ”) reduced its activity to a level similar to that of HR4ICE106 (“I-RTδ”). Deletion of a full repeat from HR4ICE106 (“I-Tδ”) modestly increased HR4 activity (Fig 5B). Together, the chimera analyses indicated that the quantitative differences between crosses of Fei-0 and ICE106 to Lerik1-3 (Fig 1 and S2 Fig) are predominantly due to variation in HR4 repeat number. This is further supported by the necrosis-inducing activity of a chimera in which the repeats in the Col-0 non-risk allele were replaced with those from HR4Fei-0 (“C-Tδ”, with the original Col-0 configuration being “C-QQRSRγ”) (Fig 5B and S5 Fig). However, repeat number alone is not the only determinant of necrosis-inducing activity of HR4 in combination with RPP7-likeLerik1-3. Adding another repeat to the “F-RTδ” chimera, resulting in “F-RRTδ”, increased the activity of HR4Fei-0 again, perhaps suggesting that there is an optimal length for HR4 to interact with the cognate RPP7.

Unlike RPW8.1, the C-terminal tails of HR4 proteins beyond the RPW8/HR repeats (fragments “γ” and “δ”) differ in length between hybrid necrosis-risk and non-risk variants (Fig 5B). Swapping only these two fragments affected HR4 activity substantially, and converted two chimeras with weak necrosis-inducing activity (“F-QQRSRγ” to “F-QQRSRδ” and “F-QQSRγ” to “F-QQSRδ”) into chimeras with activity resembling that of HR4ICE106 (which is “I-RTδ”).

Taken together, the swap experiments led us to conclude that naturally occurring variation in the configuration of RPW8/HR repeats play a major role in quantitatively modulating the severity of autoimmune phenotypes when these RPW8/HR variants are combined with RPP7 alleles from Mrk-0 and Lerik1-3. At least in the case of HR4, we could show directly that the short C-terminal tail also affects the hybrid phenotype, while for RPW8.1 this seems likely as well, given that the repeats between different alleles differ less from each other than the tails.

Prediction of RPP7-dependent hybrid performance using RPW8.1/HR4 haplotypes

To obtain a better picture of RPW8.1/HR4 variation, we remapped the raw reads from the 1001 Genomes project to the longest RPW8.1 and HR4 alleles, RPW8.1KZ10 and HR4Col-0, as references (S5 and S6 Tables). The results suggested that HR4-carrying accessions are more rare than those carrying RPW8.1 alleles (285 vs. 903 out of 1,221 accessions). The short, necrosis-linked, HR4 risk alleles (Fig 6A) were predicted to be as frequent as the long non-risk variants (Fig 6A and 6B and S5 Table), whereas for RPW8.1, only seven accessions were predicted to have the long RPW8.1KZ10-type risk variant (Fig 6A and S6 Table).

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Fig 6. Sequence variation of a large collection of RPW8.1 and HR4 alleles.

(A) Repeat polymorphisms in RPW8.1 and HR4 proteins (grey background). N-terminal regions and tails are semi-transparent. (B) Distribution of HR4 types across 113 Sanger sequenced alleles (see S5 Table). (C) Distribution of HR4 allele types in Eurasia and North America. (D) Haplotype network of HR4 alleles, with a 1-bp minimum difference. (E) F1 progeny of Mrk-0 crossed to accessions with different RPW8.1 alleles. Short RPW8.1 variants do not induce hybrid necrosis. (F) F1 progeny of Lerik1-3 crossed to accessions with different HR4 alleles. The shortest HR4 alleles (red) cause strong hybrid necrosis, the second shortest HR4 alleles (yellow) cause mild hybrid necrosis. (G) Rosette growth of F1 progeny from Lerik1-3 and accessions carrying different HR4 alleles. The shortest HR4 allele causes a strong growth reduction, while the second-shortest HR4 allele has a milder effect. Scale bars indicate 1 cm.

https://doi.org/10.1371/journal.pgen.1008313.g006

To confirm the short read-based length predictions, RPW8.1 was PCR amplified from 28 accessions and HR4 from 113 accessions (Fig 6A–6D and S5 and S6 Tables). This not only confirmed that the Illumina predictions were accurate, but also revealed new variants with different arrangements of HR4 repeats, although none were as short as HR4Fei-0 or HR4ICE106 (Fig 6A and 6B). The short necrosis-risk HR4 variants are found across much of the global range of A. thaliana (Fig 6C), whereas the much rarer necrosis-risk RPW8.1KZ10-like variant was exclusive to Central Asia. We also observed that sequences of the two short HR4 types were more conserved than the longer ones, with each short type belonging to a single haplotype, while the long necrosis-risk HR4 alleles belonged to multiple haplotypes (Fig 6D).

The extensive information on RPW8.1/HR4 haplotypes allowed us to use test crosses to determine whether interaction with either causal RPP7-like genes from Mrk-0 or Lerik1-3 is predictable from sequence, specifically from repeat number (Fig 6E and 6F). As expected, accessions with the longest, Type 1, RPW8.1KZ10-like alleles (Fig 6E, pink) produced necrotic hybrid progeny when crossed to Mrk-0, whereas accessions carrying the two shorter Type 2 and 3 alleles did not (Fig 6E and S7 Table). The situation was similar for HR4; all but two of the tested accessions with the shortest HR4Fei-0-like alleles (Fig 6F, red) produced strongly necrotic progeny when crossed to Lerik1-3, while accessions carrying the second shortest HR4ICE106-like alleles (Fig 6F and S8 Table) produced more mildly affected progeny. Hybrid progeny of Lerik1-3 and accessions carrying other HR4 alleles did not show any signs of necrosis (Fig 6F). Necrosis was correlated with reduction in overall size of plants, which in turn correlated with RPW8.1/HR4 repeat length (Fig 6F and S9 Table). Finally, HR4Fei-0-like alleles in two accessions caused a mild phenotype similar to HR4ICE106, suggesting the presence of genetic modifiers that partially suppress autoimmune symptoms.

Discussion

The RPW8/HR cluster is remarkably variable in terms of copy number, reminiscent of many multi-gene clusters carrying NLR-type R genes [16]. While the first three genes in the cluster, HR1, HR2 and HR3, are generally well conserved, there is tremendous variation in the number of the other genes in the cluster, including RPW8.1/HR4. Nevertheless, that the HR4 hybrid necrosis-risk allele is not rare and widely distributed, accounting for half of all HR4 carriers (Fig 6B and 6C), suggests that it might provide adaptive benefits, as postulated before for ACD6 hybrid necrosis-risk alleles [12].

The N-terminal portion of RPW8 and HR proteins can be homology modeled on a multi-helix bundle in the animal MLKL protein [38], which in turn shares structural similarity with fungal HeLo and HELL domain proteins [41]. In both cases, the N-terminal portions can insert into membranes (with somewhat different mechanisms proposed for the two proteins), thereby disrupting membrane integrity and triggering cell death [40,5254]. For both proteins, insertion is regulated by sequences immediately C-terminal to the multi-helix bundle [40,5256]. It is tempting to speculate that the RPW8/HR repeats and the C-terminal tail, which together make up the C-terminal portions of the proteins, similarly regulate activity of RPW8.1 and HR4. In agreement, our chimera studies, where we exchanged and varied the number of RPW8/HR repeats and swapped the C-terminal tail, indeed point to the C-terminal portion of RPW8/HR proteins having a regulatory role. A positive regulator of RPW8-mediated disease resistance, a 14-3-3 protein, interacts specifically with the C-terminal portion of RPW8.2, consistent with this part of the protein controlling RPW8/HR activity [57]. Perhaps even more intriguing is the fact that in many fungal HeLo domains this C-terminal region is a prion-forming domain composed of 21-amino acid repeats. RPW8.1 also has 21-amino acid repeats, while HR4 has 14-amino acid repeats, but in both cases these were not interrupted by a spacer, as in the fungal proteins. In fungal HET-S and related proteins, the repeats exert regulatory function by forming amyloids and thereby causing the proteins to oligomerize [3943]. While it remains to be investigated whether the RPW8/HR repeats and the C-terminal tail function in a similar manner, their potential regulatory function makes them a possible target for pathogen effectors. In such a scenario, at least some RPP7 proteins might act as guards for RPW8/HR proteins and sense their modification by pathogen effectors [16,58].

Can we conclude from the MLKL homology that RPW8 and HR proteins form similar pores as MLKL? Unfortunately, this is not immediately obvious, as a different mechanism has been suggested for fungal proteins with HeLo and HELL domains [3941]. For MLKL, it has been suggested that the multi-helix bundle directly inserts into the membrane, whereas for the fungal protein, it has been proposed that the multi-helix bundle regulates the ability of an N-terminal transmembrane domain to insert into the membrane. An N-terminal transmembrane domain has been predicted for RPW8 [27], but although RPW8 proteins can be membrane associated [33,59], the insertion of this domain into the membrane has not been directly demonstrated.

We have shown that differences in protein structure, rather than expression patterns or levels, are key to the genetic interaction between RPW8/HR and RPP7. While we do not know whether the proteins interact directly, allele-specific genetic interactions are often an indicator of direct interaction between the gene products [60]. Moreover, reminiscent of RPW8/HR and RPP7 interaction, the activity of the fungal HeLo domain protein HET-S is regulated by an NLR protein [42].

Finally, we would like to emphasize that our observations do not necessarily imply that RPP7 and RPW8/HR genes are obligatory partners. First, we found that HR4 is not required for RPP7-dependent Hpa Hiks1 resistance in Col-0. Second, previous genetic studies have revealed both overlap and differences in the downstream signaling requirements of RPP7 and RPW8/HR genes [44,61].

In conclusion, we have described in detail an intriguing case of hybrid necrosis in A. thaliana, where three different pairs of alleles at a conventional complex NLR resistance gene cluster, RPP7, and alleles at another complex, but non-NLR resistance gene cluster, RPW8/HR, interact to trigger autoimmunity in the absence of pathogens. Our findings suggest that within the immune system, conflict does not occur randomly, but that certain pairs of loci are more likely to misbehave than others. Finally, that genes of the RPW8/HR cluster can confer broad-spectrum disease resistance, while at least one RPP7 member can confer race-specific resistance, provides yet another link between different arms of the plant immune system [62].

Materials and methods

Plant material

Stock numbers of accessions used are listed in Supplementary Material. All plants were stratified in the dark at 4°C for 4–6 days prior to planting on soil. Late flowering accessions were vernalized for six weeks under short day conditions (8 h light) at 4°C as seedlings. All plants were grown in long days (16 h light) at 16°C or 23°C at 65% relative humidity under Cool White fluorescent light of 125 to 175 μmol m-2 s-1. Transgenic seeds were selected either with 1% BASTA (Sigma-Aldrich), or by mCherry fluorescence. Constructs are listed in S10 Table.

RAPA phenotyping

Images were acquired daily in top view using two cameras per tray. Cameras were equipped with OmniVision OV5647 sensors with a resolution of 5 megapixels. Each camera was attached to a Raspberry Pi computer (Revision 1.2, Raspberry Pi Foundation, UK) [63]. Images of individual plants were extracted using a predefined mask for each plant. Segmentation of plant leaves and background was then performed by removing the background voxels then a GrabCut-based automatic postprocessing was applied [64]. Lastly, unsatisfactory segmentations were manually corrected. The leaf area of each plant was then calculated based on the segmented plant images.

Histology

Cotyledons from 18 day-old seedlings were collected and 1 ml of lactophenol Trypan Blue solution (20 mg Trypan Blue, 10 g phenol, 10 ml lactic acid, 10 ml glycerol and 10 ml water) diluted 1: 2 in 96% ethanol was added for 1 hour at 70°C. Trypan Blue was removed, followed by the addition of 1 ml 2.5g/ml chloral hydrate and an overnight incubation. The following day, the de-stained cotyledons were transferred to 50% glycerol and mounted on slides.

Pathology

The Hyaloperonospora arabidopsidis isolate Hiks1 was maintained by weekly subculturing on susceptible Ws-0 eds1-1 plants [47]. To assay resistance of susceptibility, 12- to 13-day old seedlings were inoculated with 5 x 104 spores/ml. Sporangiophores were counted 5 days after infection.

Constructs and transgenic lines

Genomic fragments were PCR amplified, cloned into pGEM®-T Easy (Promega, Madison, WI, USA), and either directly transferred to binary vector pMLBart or Gateway vectors pJLBlue and pFK210. amiRNAs [65] against members of the RPP7 and RPW8/HR clusters were designed using the WMD3 online tool (http://wmd3.weigelworld.org/), and placed under the CaMV 35S promoter in the binary vector pFK210 derived from pGreen [66]. amiRNA constructs were introduced into plants using Agrobacterium-mediated transformation [67]. T1 transformants were selected on BASTA, and crossed to incompatible accessions. For the chimeras, promoters and 5’ coding sequences were PCR amplified from genomic DNA, repeat and tail sequences were synthesized using Invitrogen’s GeneArt gene synthesis service, all were cloned into pBlueScript. The three parts, promoter, 5’ and 3’ coding sequences, were assembled using Greengate cloning [68] in the backbone vector pMCY2 [69]. Quality control was done by Sanger sequencing. Transgenic T1 plants were selected based on mCherry seed fluorescence. For CRISPR/Cas9 constructs, sgRNAs targeting HR4 or RPW8.1 were designed on the Chopchop website (http://chopchop.cbu.uib.no/), and assembled using a Greengate reaction into supervector pRW006 (pEF005-sgRNA-shuffle-in [70] Addgene plasmid #104441). mCherry positive T2 transformants were screened for CRISPR/Cas9-induced mutations by Illumina MiSeq based sequencing of barcoded 250-bp amplicons. Non-transgenic homozygous T3 lines were selected based on absence of fluorescence in seed coats.

Genotyping-by-sequencing and QTL mapping

Genomic DNA was isolated from Lerik1-3 x ICE106/ICE107 F2 and F3 individuals and from ICE79 x Don-0 F2 individuals using a Biosprint 96 instrument and the BioSprint 96 DNA Plant Kit (Qiagen, Hilden, Germany). The individuals represented all classes of segregating phenotypes. Genotyping-by-Sequencing (GBS) using RAD-seq was used to genotype individuals in the mapping populations with KpnI tags [71]. Briefly, libraries were single-end sequenced on a HiSeq 3000 instrument (Illumina, San Diego, USA) with 150 bp reads. Reads were processed with SHORE [72] and mapped to the A. thaliana Col-0 reference genome. QTL was performed using R/qtl with the information from 330 individuals and 2,989 markers for the Lerik1-3 x ICE106/107 populations, and 304 individuals and 2,207 markers for the ICE79 x Don-0 population. The severity of the hybrid phenotype was scored as a quantitative trait.

GWAS

Lerik1-3-dependent hybrid necrosis in F1 progeny from crosses with 80 accessions [10] was scored as 1 or 0. The binary trait with accession information was submitted to the easyGWAS platform [46], using the FaSTLMM algorithm. A -log10(p-value) was calculated for every SNP along the five A. thaliana chromosomes.

RPP7 phylogeny

The NB domain was predicted using SMART (http://smart.embl-heidelberg.de/). NB amino acid sequences were aligned using MUSCLE (70). A maximum-likelihood tree was generated using the BLOSUM62 model in RaxML (71). Topological robustness was assessed by bootstrapping 1,000 replicates.

RPW8.1/HR4 length prediction

Short reads from the 1001 Genomes project (http://1001genomes.org) were mapped using SHORE [72] with 5 mismatches allowed per read. Sequences of the RPW8/HR clusters from Col-0 and KZ10 were provided as references and the covered region for RPW8.1KZ10 and HR4Col-0 was retrieved.

RPW8.1/HR4 sequence analysis

Overlapping fragments covering the HR4/RPW8.1 genomic region were PCR amplified from different A. thaliana accessions (oligonucleotides in S11 Table). Fragments were cloned and Sanger sequenced. A maximum-likelihood tree of coding portions of exons and introns was computed using RaxML [73] and visualized with Figtree.

Population genetic analysis

The geographical distribution of the 113 accessions carrying different HR4 alleles was plotted using R (version 0.99.903). Packages maps, mapdata, mapplots and scales were used. A haplotype network was built using a cDNA alignment of 113 HR4 alleles from different accessions. The R packages used were ape (dist.dna function) and pegas (haploNet function).

Oligonucleotides

See S11 Table.

Supporting information

S1 Fig. Role of the RPP7 cluster in DM6–DM7 dependent hybrid necrosis.

Related to Fig 1. (A) RPP7 cluster in the Col-0 reference genome. The left portion of the cluster consists of three NLR genes, At1g58390, At1g58400 and At1g58410 (green arrows). The right portion includes five NLR genes, At1g58602, At1g58807, At1g58848, At1g59124 and At1g59218 (brown arrows). Twenty-two non-NLR genes in this region are not shown. (B) Maximum-likelihood tree of NLR genes in the RPP7 cluster based on the NB domain. At1g59124 and At1g58807 sequences are identical, as are At1g59218 and At1g58848. Same colors as in (A). Bootstrap values (out of 100) are indicated on each branch. (C) Representative rescue experiment using an amiRNA construct targeting RPP7 homologs (see S1 Table). ICE79 was transformed with the amiRNA construct EK21 and T1 plants were crossed to Don-0, resulting in rescued and non-rescued plants segregating in the F1 progeny. Parental genotypes were confirmed with CAPS markers, shown below. Five-week old plants grown in 16°C are shown.

https://doi.org/10.1371/journal.pgen.1008313.s001

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S2 Fig. Phenotypic variation in Lerik1-3 F1 hybrids.

Related to Fig 1. Major differences were observed in rosette size of F1 hybrids (A) and spotted cell death on the abaxial side of leaves (B). Scale bar represents 1cm (A) and 1mm (B). Plants were five weeks old.

https://doi.org/10.1371/journal.pgen.1008313.s002

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S3 Fig. HR4 and RPW8.1 CRISPR/Cas9 knockout lines.

Related to Fig 3 and S4 Fig. (A) Two alleles of HR4 in Col-0 with a 1-bp insertion (#8/18) or a 19-bp deletion (#8/6) were identified by amplicon sequencing. (B) An allele of RPW8.1 in KZ10 with a 1-bp insertion was recovered. The stop codons are marked with an asterisk and the first amino acid after a frameshifting event is in bold.

https://doi.org/10.1371/journal.pgen.1008313.s003

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S4 Fig. Resistance and susceptibility to H. arabidopsidis isolate Hiks1.

(A) Trypan Blue stained cotyledons 5 days after infection. Lerik1-3 is resistant, while Fei-0 and ICE106 are fully susceptible. The F1 hybrids Lerik1-3 x Fei-0 and Lerik1-3 x ICE106 appear to be less resistant than Lerik1-3. Ws-0 eds1-1 is a positive infection control. (B) Two different hr4 loss-of-function alleles (see S3 Fig) are as resistant as Col-0 wild-type plants. eds1-1 and rpp7-15 are positive infection controls.

https://doi.org/10.1371/journal.pgen.1008313.s004

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S5 Fig. Hybrid necrosis by introduction of chimeras.

Related to Fig 5. Effects of chimeric HR4 transgenes introduced into Lerik1-3, with negative and positive controls shown to the left and right. Scale bar represents 1cm. Five week-old plants are shown.

https://doi.org/10.1371/journal.pgen.1008313.s005

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S6 Fig. Predicted lengths of HR4 and RPW8.1 coding sequences from remapping of short reads from the 1001 Genomes project.

Related to Fig 6. (A) HR4 type assignments based on information from Sanger sequencing. (B) RPW8.1 type based on information from Sanger sequencing.

https://doi.org/10.1371/journal.pgen.1008313.s006

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S1 Table. Rescue of hybrid necrosis by amiRNAs against RPP7 homologs.

Related to Fig 1. AmiRNAs were designed based on NLR sequences of the RPP7 cluster in Col-0 (Table S1) using WMD3 (http://wmd3.weigelworld.org/). Constructs were introduced into Mrk-0, Lerik1-3 or ICE79, and T1 lines were crossed to incompatible parents. Hybrid necrosis was scored at 16°C. Examples of F1 plants are shown in S1 Fig.

https://doi.org/10.1371/journal.pgen.1008313.s007

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S2 Table. GWAS hits on chromosome 3 from Lerik1-3 x 80 accessions panel and tagging SNPs present in accessions carrying different HR4 types.

Related to Fig 2. Location of HR4 (At3g50480) is 18,733,287 to 18,734,180 bp on chromosome 3 of the reference Col-0 genome. The next protein-coding gene is At3g50500 (18,741,805 to 18,743,904 bp), with At3g50490 (18,738,630 to 18,739,261 bp) encoding a transposable element (see Fig 4A). SNPs in bold italics differ from the Col-0 reference.

https://doi.org/10.1371/journal.pgen.1008313.s008

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S3 Table. Rescue effects of amiRNAs targeting RPW8 homologs.

Related to Figs 1 and 3. AmiRNAs were designed based on sequence information of RPW8/HR clusters from Col-0, Ms-0 and KZ10. Constructs were introduced into Fei-0 or ICE106, and T1 lines were crossed to the incompatible accession Lerik1-3. Hybrid necrosis was scored at 16°C. Parental genotypes and the presence of amiRNA constructs were confirmed by PCR genotyping (see Fig 3A).

https://doi.org/10.1371/journal.pgen.1008313.s009

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S4 Table. Resistance to the H. arabidopsidis isolate Hiks1.

Related to S4 Fig. *strong resistance: no conidiophores; weak resistance: 1–5 conidiophores/cotyledon, with some sporulation; very weak resistance: 6–19 conidiophores/cotyledon, with low to medium sporulation; no resistance: >20 conidiophores/cotyledon, heavy sporulation. See S1 Table for amiRNA key.

https://doi.org/10.1371/journal.pgen.1008313.s010

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S5 Table. Accessions for HR4 survey.

Related to Fig 6. Covered region indicates the length of HR4Col-0 (894 bp) covered by reads from the 1001 Genomes Project (http://1001genomes.org), allowing for five mismatches. HR4 types are categorized according to the number of RPW8/HR repeats, and the haplotype is based on the entire HR4 coding sequence.

https://doi.org/10.1371/journal.pgen.1008313.s011

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S6 Table. Accessions for RPW8.1 survey.

Related to Fig 6.

https://doi.org/10.1371/journal.pgen.1008313.s012

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S7 Table. Hybrid necrosis in F1 plants of Mrk-0 F1 crossed to other accessions.

Related to Fig 6. Strong hybrid necrosis equals what is observed in KZ10 x Mrk-0 hybrids.

https://doi.org/10.1371/journal.pgen.1008313.s013

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S8 Table. Hybrid necrosis in F1 plants of Lerik1-3 crossed to other accessions.

Related to Fig 6. Strong hybrid necrosis equals what is observed in Lerik1-3 x Fei-0 F1 hybrids.

https://doi.org/10.1371/journal.pgen.1008313.s014

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S9 Table. Accessions and hybrids in which growth was analyzed with the automated phenotyping platform RAPA.

Related to Fig 6.

https://doi.org/10.1371/journal.pgen.1008313.s015

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S11 Table. Oligonucleotides used for amplifying RPW8.1/HR4 genomic fragments and swap constructs.

Related to Figs 3 and 5.

https://doi.org/10.1371/journal.pgen.1008313.s017

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Acknowledgments

We thank Jane Parker for the H. arabidopsidis Hiks1 isolate, Katrin Fritschi and Camilla Kleinhempel for technical support, and Gautam Shirsekar for help with the pathology assays and discussions.

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