Structural Analysis of the Maize Rp1 Complex Reveals Numerous Sites and Unexpected Mechanisms of Local Rearrangement

doi:10.1105/tpc.006338

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Structural Analysis of the Maize Rp1 Complex Reveals Numerous Sites and Unexpected Mechanisms of Local Rearrangement

Wusirika Ramakrishna^a, John Emberton^a, Matthew Ogden^a, Phillip SanMiguel^b and Jeffrey L. Bennetzen¹^,a

^a Department of Biological Sciences, Purdue University, West Lafayette, Indiana 47907
^b Purdue University Genomics Core, Purdue University, West Lafayette, Indiana 47907

¹ To whom correspondence should be addressed. E-mail maize{at}bilbo.bio.purdue.edu; fax 765-496-1496

Abstract

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

Rp1 is a complex disease resistance locus in maize that is exceptionalin both allelic variability and meiotic instability. Genomicsequence analysis of three maize BACs from the Rp1 region ofthe B73 inbred line revealed 4 Rp1 homologs and 18 other gene-homologoussequences, of which at least 16 are truncated. Thirteen of thetruncated genes are found in three clusters, suggesting thatthey arose from multiple illegitimate break repairs at the samesites or from complex repairs of each of these sites with multipleunlinked DNA templates. A 43-kb region that contains an Rp1homolog, six truncated genes, and three Opie retrotransposonswas found to be duplicated in this region. This duplicationis relatively recent, occurring after the insertion of the threeOpie elements. The breakpoints of the duplication are outsideof any genes or identified repeat sequence, suggesting a duplicationmechanism that did not involve unequal recombination. A physicalmap and partial sequencing of the Rp1 complex indicate the presenceof 15 Rp1 homologs in regions of $~$ 250 and 300 kb in the B73 inbredline. Comparison of fully sequenced Rp1-homologous sequencesin the region demonstrates a history of unequal recombinationand diversifying selection within the Leu-rich repeat 2 region,resulting in chimeric gene structures.

INTRODUCTION

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

In plants, a major class of disease resistance genes is involvedin the detection of pathogen presence, leading to the activationof a defense cascade. Most of these resistance genes encodeproteins with a nucleotide binding site and a Leu-rich repeat(LRR) region. The LRR region is believed to be involved directlyin the recognition of the pathogen (Ellis et al., 2000a). Resistancegenes are abundant and highly diverse in plants (Michelmoreand Meyers, 1998; Ellis et al., 2000a; Richter and Ronald, 2000;Dangl and Jones, 2001; Staskawicz, 2001; Staskawicz et al.,2001). Numerous mutational forces act on disease resistancegenes, including point mutations, unequal recombination, geneconversion, and transposon activity, all providing the raw materialon which natural selection may act.

Many disease resistance genes exhibit diversifying selection,in which nonsynonymous substitutions exceed synonymous substitutionswithin an LRR domain or domains. These include resistance genesbelonging to the RGC2 family of lettuce, Cf-4/Cf-9 homologsof tomato, and the Xa21 family of rice (Parniske et al., 1997;Song et al., 1997; Meyers et al., 1998b). Diversifying selectionappears to be particularly strong in the xxLxLxx consensus sequenceof the LRR region, which encodes the part of the protein thatshould be exposed to solvent and involved in ligand binding(Kobe and Deisenhofer, 1995).

Many of the resistance genes in plants are arranged in clusters,including Cf-4/Cf-9, I2, and Pto of tomato, N of flax, RGC2of lettuce, RPP5 of Arabidopsis, and Xa21 of rice (Martin etal., 1994; Parniske et al., 1997; Song et al., 1997; Meyerset al., 1998a; Simons et al., 1998; Noel et al., 1999; Doddset al., 2001). It is probable that the resistance genes withina cluster were generated originally by unequal crossing over.Within these resistance gene clusters, meiotic instability causedby unequal recombination can generate novel alleles with newdisease resistance specificities (Richter et al., 1995).

Transposable elements play an important role in the evolutionof disease resistance genes (Michelmore and Meyers, 1998; Richterand Ronald, 2000), as they do for all other plant genes (Wessleret al., 1995). Two elements of the same family inserted withina resistance gene region provide an opportunity for gene duplicationby unequal crossing over. Insertion of transposons can createinterrupted disease resistance genes, as seen in ArabidopsisRPP5, flax N, maize Hm1, and rice Xa21 homologs (Song et al.,1997; Multani et al., 1998; Noel et al., 1999; Dodds et al.,2001). The insertion of a few amino acids in an L6 allele offlax was caused by the insertion and subsequent excision ofa transposable element (Ellis et al., 1997).

Rp1 is a complex locus in maize that confers resistance to Pucciniasorghi, a fungal rust pathogen. Several Rp1 genes map withina region of $~$ 0.4 centimorgan (cM) near the telomere on the shortarm of chromosome 10 (Saxena and Hooker, 1968). Most Rp1 genesare meiotically unstable (Bennetzen et al., 1988). Unequal recombination,including conversion, is observed frequently in the Rp1 region(Sudupak et al., 1993). Rp1-D and eight paralogs from the Rp1-Dhaplotype have been cloned and sequenced (Collins et al., 1999;Sun et al., 2001). One of the nine Rp1 homologs was truncated.Sequence analysis indicated that maize Rp1 genes undergo diversifyingselection in an LRR region (Sun et al., 2001). Although thesequence relationships of resistance genes in the Rp1 regionhave been investigated, their physical organization has beenestimated only crudely (Sun et al., 2001). In the absence ofthis structural information, it is not possible to describeaccurately the chromosomal rearrangements that gave rise tocurrent Rp1 haplotypes and that continue to generate diversityin this region.

In the present study, we sequenced and analyzed two segmentsthat constitute 195 kb of the maize Rp1 gene region. In addition,we mapped the Rp1 complex to a series of overlapping clonesthat form two contigs of 300 and 450 kb. These studies revealthe genomic organization and suggest some of the molecular eventsthat have contributed to the creation of this complex locus.Many of these modes of regional evolution have been detectedat other genes, including complex resistance loci, but two detectedphenomena are unprecedented in any region of any genome: nearlyexact duplications of 43 kb of DNA that are separated by >300kb, and several clusters of unrelated gene fragments insertedbetween the resistance genes.

RESULTS

TOP
Abstract
INTRODUCTION
RESULTS
DISCUSSION
METHODS
References

Sequence Analysis of Maize Rp1 BACs
To study genomic organization at the Rp1 locus in maize, BACsZm163K15, Zm238E11, and Zm206C17 were selected by their hybridizationto a probe from the 5' end of the Rp1-D gene (Collins et al.,1999). In the first small library that we screened, these werethe only clones that were found, and preliminary restrictionmapping indicated that they did not overlap. These clones wereisolated from a BAC library that was constructed from B73, astandard maize inbred line. These three BACs were sequencedfully by a shotgun approach (Dubcovsky et al., 2001). The finalerror rate was less than one base per 10 kb, and all of thefinished sequence was of high quality (PHRED value of 25 ormore, see www.phrap.org/phrap.docs/phred.html). The maize DNAin BAC Zm163K15 consists of 95,078 bp and has two Rp1-homologousgenes (rp1-1 and rp1-2). This BAC also contains 12 other gene-homologoussequences (of which at least 10 are truncated), 3 full-lengthOpie retroelements (SanMiguel et al., 1996), and 1 PREM-1 retroelement(Turcich and Mascarenhas, 1994) (Figure 1) . The two Rp1 homologsare in direct orientation, $~$ 68 kb apart. BACs Zm206C17 and Zm238E11were found to overlap for most of their length, yielding exactlyidentical sequence for 73,026 bp. The maize DNA in the Zm206C17/Zm238E11contiguous sequence (contig) is 99,156 bp and harbors two Rp1homologs (rp1-3 and rp1-4) plus six other gene-homologous segments(all truncated) and six retrotransposons. The two Rp1 homologsare in the same orientation, $~$ 38 kb apart. In addition, thereare several truncated retroelements on each of these BACs. Identifiedretrotransposon sequences constitute $~$ 70% of Zm206C17/Zm238E11and 45% of Zm163K15.

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Figure 1. Sequence Organization on Two BACs from the rp1 Complex.

The four Rp1 homologs were named rp1-1 through rp1-4. Arrows indicate genes and arrowheads indicate truncated genes, plus their size and proposed direction of transcription. Asterisks indicate simple sequence repeats (SSRs) that contain eight or more tandem repeats. Lines connecting the two BACs indicate the 43-kb duplicated region. Grande, Ji, Opie, and PREM-1 are maize retrotransposons. Miniature inverted repeat transposable elements (MITEs) are indicated by small triangles. The two large arrowheads indicate inverted repeat sequences of 2283 and 2284 bp that are 96% identical to each other (ignoring indels) and separated by 199 bp.

An $~$ 43-kb region (42,366 bp in Zm163K15 and 42,860 bp in Zm206C17/Zm238E11)was duplicated on these two BACs. This duplication containsone Rp1 homolog, six truncated genes, and three Opie retrotransposons.Truncated genes 7 through 12 of Zm163K15 correspond to genes1 through 6 of Zm206C17/Zm238E11. A deletion of 488 bp correspondingto part of the truncated helicase-like transcription factorgene is observed in Zm163K15. Comparison of the duplicated regionidentified insertions/deletions (indels) of 3, 5, 19, and 20bp. Most of the indels (3, 5, and 19 bp) contained perfect shortdirect repeats in one of the 43-kb duplicated segments. In Zm163K15,the 3' boundary of the 43-kb duplication is located $~$ 2 kb downstreamfrom the predicted stop codon of the rp1-2 gene. Ignoring indels,these 43-kb segments are >99% identical. In Zm206C17/Zm238E11,the 5' boundary of this duplication is situated $~$ 1 kb downstreamof the rp1-3 gene and the 3' boundary is situated $~$ 2 kb downstreamof the rp1-4 gene (Figure 1).

Genes and Truncated Genes
Within the Rp1 region sequenced, we identified six loci thatappear to be functional genes. Four of these genes are Rp1 homologs,and they contain uninterrupted reading frames similar to thefunctional Rp1-D gene. Although B73 does not have any knownRp1 gene that provides resistance to any identified race ofP. sorghi, it is possible that an Rp1 homolog in B73 does specifyresistance to some extinct or otherwise unidentified rust pathogenrace. Rp1 homologs from this study show 87 to 100% identitiesover an 800-bp region with maize B73 ESTs (BQ577730, AI947572,BM347712, and BI992969), indicating that some Rp1-homologousgenes in this complex are expressed in this inbred line.

Unlike other complex disease resistance loci, the Rp1 regioncontains two apparently intact genes within the cluster thatplay no obvious role in disease resistance (genes 4 and 5 ofZm163K15; Figure 1). Gene 4 exhibits homology with Arabidopsis(AP002820; E value = 8e-91) and rice hypothetical proteins withno similarity to any ESTs. Gene 5 shows homology with rice unknown(AC087723; E value = 4e-19) and hypothetical proteins with 91and 96% identity with maize ESTs (H89387 and AW424864) overa 440-bp region.

Genes were classified as truncated when the Basic Local AlignmentSearch Tool (BLAST) X program detected homology with only partof a protein entry in the GenBank database (Table 1). The presumedtranslated protein products of most of these truncated genefragments were homologous with protein products encoded by genesin Arabidopsis. This homology was limited only to N-terminal,C-terminal, or central portions of the protein. For instance,the predicted protein product of the truncated gene 3 of Zm163K15is homologous with amino acids 392 through 615 of the 1042 aminoacids specified by a maize calcium ATPase gene (AF09687). Fourof the truncated genes in Zm163K15 exhibited significant ESTmatches. Some of the truncated genes have well-defined intronsand exons supported by hits to ESTs. For example, truncatedgene 12 of Zm163K15 is homologous with exons 2, 3, and 4 plusintrons 2 and 3 of the maize Suc phosphate synthase gene (M97550).Five truncated genes (genes 7 to 11) in Zm163K15 are presentin a cluster of $~$ 5 kb.

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Table 1. Truncated and Apparently Intact Genes in BAC Zm163K15

Physical Order of the Rp1 Genes in Maize Inbred Line B73
A physical map of the rp1 region was made to determine the positionsof the sequenced Rp1 homologs within the genome of B73 maize.Thirty-three maize BACs that hybridized to an Rp1 probe wereidentified from a large insert BAC library of maize inbred lineB73 (www.chori.org/bacpac). The restriction enzymes NotI, MluI,PacI, SwaI, and NcoI were used to generate a physical map basedon overlapping restriction fragments. Gel blot hybridizationanalysis with the Rp1 5' probe and a subclone of the truncatedSuc phosphate synthase–like gene (next to rp1-2 and rp1-4)was used to confirm the physical map. Furthermore, PCR amplificationusing primers that amplify the truncated Suc phosphate synthase–likegene and the truncated ATPase-like gene (present near rp1-1)also was used to confirm the order of the BACs in the Rp1 genecluster. The truncated ATPase-like gene was present in Zm163K15but was absent in Zm206C17/Zm238E11. The truncated Suc phosphatesynthase–like gene was part of the 43-kb duplicated regionand therefore was present on both BACs. Interestingly, neitherof these probes hybridized or amplified fragments from otherregions within the rp1 complex (Figure 2) . Based on the locationsof these fragments, we were able to conclude that the 43-kbduplications (and the included Rp1 homologs) are part of twocontigs within the B73 Rp1 gene cluster. In all, the two BACcontigs covered $~$ 300 and 450 kb. All of the Rp1-homologous sequenceswere mapped to a region of $~$ 250 and 300 kb within these two contigs(Figure 2). Because we do not have any definitive informationconcerning the relative locations of these two contigs (otherthan their adjacent locations on the short arm of chromosome10 by recombinational mapping [Hulbert and Bennetzen, 1991

]),we cannot say which of these two segments should be placed onthe left or the right side of Figure 2, nor can we draw anyconclusions about the distance between them.

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Figure 2. Physical Map of the Rp1 Region in Maize Inbred Line B73.

Each circle represents an Rp1 homolog. Open circles represent the four Rp1 homologs in BACs sequenced in the present study, and those with vertical arrows are part of the 43-kb duplicated region. The truncated Suc phosphate synthase–like and ATPase-like genes are designated by closed and open rectangles, respectively. Physical distances and BACs harboring Rp1 homologs are represented by lines above and below the rp1 complex map.

The number of Rp1 genes in the contigs was determined by hybridizationof NcoI-digested BAC DNAs with the Rp1 5' probe and low-passsequencing of five additional BACs in the region. Our sequenceanalysis of the two segments of the maize genome harboring fourRp1 genes indicated the presence of unique bands hybridizingto three NcoI fragments (6.1, 4.4, and 8.3 kb). The fourth gene(rp1-4) was part of the duplicated 43-kb region, so the NcoIfragment is the same size as the NcoI fragment for rp1-2. Aprevious report by Sun et al. (2001)

suggested that the numberof NcoI hybridizing fragments corresponds to the number of Rp1homologs. However, our data demonstrate that some Rp1 homologscan be on NcoI fragments of the same size, as seen here forrp1-2 and rp1-4. In addition, more than one hybridizing bandper gene would be observed if there were an NcoI restrictionsite in the 5' region of any Rp1 gene covered by the probe.As a result of the complex nature of the Rp1 locus, with multipleresistance genes in close vicinity and multiple duplicationsinvolving large genomic segments, low-pass sequencing of BACsZ486N13, Z526K02, Z337N17, Z418K17, and Z438O20 was performedto confirm the physical map. Based on sequencing and NcoI fragmentsharboring Rp1 homologs, we identified 15 Rp1 homologs in theRp1 region (Figure 2).

Analysis of the Rp1 Homologs
The four Rp1 homologs sequenced in this study were comparedwith the Rp1-D gene that had been cloned and sequenced (Collinset al., 1999) and with each other. Rp1-D is the only sequencedRp1 homolog that is known to provide disease resistance. Thenucleotide sequence identities range from 90.8% (between rp1-1and rp1-3) to 99.9% (between rp1-2 and rp1-4), correspondingto 351 and 1 nucleotide differences, respectively. rp1-1 wassimilar to rp1-3 in the N-terminal region of the gene, whereasrp1-2 and rp1-4 were most similar to Rp1-D (Figure 3) in thisregion. For these analyses, it is useful to evaluate severaldifferent domains in the putative RP1 proteins separately. Inparticular, three domains in the LRR region exhibit differentrepeat patterns: the LRR1 region (LRRs 1 to 11), domain C (LRRs12 to 14), and the LRR2 region (LRRs 15 to 27) (Collins et al.,1999). In the first LRR domain, the LRR1 region, there is anapparent recombination breakpoint at which rp1-3 becomes similarto Rp1-D, rp1-2, and rp1-4 after a region in which there isa 3-bp deletion in rp1-3 and a 15-bp deletion in rp1-2 and rp1-4compared with Rp1-D. There are several such regions downstreamof the LRR1 region that give rise to a mosaic gene pattern.Nine adjacent amino acids were missing in rp1-2, rp1-3, andrp1-4 compared with Rp1-D and rp1-1 after the 13th amino acidof the fourth LRR unit. In another region downstream of LRR1,rp1-2, rp1-3, and rp1-4 had five more amino acids than Rp1-Dand rp1-1 in the seventh LRR unit. In the LRR2 region, the numberof amino acids was identical in all five Rp1 homologs.

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Figure 3. Mosaic Gene Structure of the Rp1 Homologs.

N-term indicates the N-terminal nucleotide binding site region (domain A), LRR1 indicates Leu-rich repeat region 1 (domain B), and LRR2 indicates Leu-rich repeat region 2 (domain D). Domain C is the region between LRR1 and LRR2. Domain E is the region between LRR2 and the end of the gene (stop codon). Recombination breakpoints are located in the LRR regions, creating chimeric gene structures. Gray and black boxes represent the highest similarity to Rp1-D and rp1-2/rp1-4, respectively. Hatched boxes represent regions that are unique to the specific Rp1 homologs.

Diversifying Selection
Like other plant disease resistance genes, Rp1 homologs havebeen shown to be under divergent or diversifying selection,especially in the LRR2 region (Sun et al., 2001

). Sliding-windowanalysis (Proutski and Holmes, 1998

) was performed with a windowsize of 150 bp to identify specific regions of the Rp1 homologsthat are subject to diversifying selection. Our analysis showsthat specific regions corresponding to the C domain and theLRR2 region are subject to diversifying selection (Figure 4) .Varying degrees of selection were observed in different comparisons.For instance, comparison of rp1-1 with Rp1-D showed maximaldiversifying selection in the C domain, which was found to bestatistically significant (P < 0.05), even at this smallwindow size. Purifying selection was observed throughout thenucleotide binding site and LRR1 regions for most of the pairwisecomparisons. From these results, it appears that sliding windowanalysis is a particularly powerful tool for the identificationof selected domains, with more discrimination power than a simplenonsynonymous substitution/synonymous substitution ratio forthe entire LRR region.

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Figure 4. Sliding-Window Analysis Showing Diversifying and Purifying Selection across the Rp1 Homologs.

Each data point represents a window size of 150 bp. Nonsynonymous substitution/synonymous substitution (Ka/Ks) values >1, $~$ 1, and <1 indicate diversifying, neutral, and purifying selection, respectively. Abbreviations are as in Figure 3.

Assessment of Retrotransposon Insertion and Regional Duplication Dates
The insertion dates of full-length retrotransposons can be estimatedfrom the divergence of their long terminal repeats (SanMiguelet al., 1998

). In addition, we can use sequence divergence withinthe 43-kb duplicated segments to approximate when this duplicationoccurred. The number of substitutions per site was estimatedusing the Kimura two-parameter method, which corrects for multiplehits and takes into account transition and transversion substitutionrates (Kimura, 1980

). The synonymous substitution rate for theadh1 and adh2 genes of grasses (6.5 x 10^-9 substitutions peryear per site) was used to estimate the insertion and divergencedates of the retrotransposons. The Opie retroelements (Opie-B,Opie-C, and Opie-D) that are part of the duplicated 43-kb segmentwere estimated to have inserted within the last 1.5 millionyears (Table 2). The Grande element in Zm238E11 seems to bethe most recent insertion, because its long terminal repeatsare still identical. All of the other retrotransposons in thetwo BACs were inserted <1.5 million years ago. Comparisonof the Opie elements within the 43-kb duplicated regions ofZm163K15 and Zm238E11 indicated that they began to diverge fromeach other within the last 0.2 million years (Table 2), consistentwith the divergence time predicted by the one-nucleotide differencebetween rp1-2 and rp1-4. Based on these results, we concludethat the duplication of the 43-kb maize segment occurred withinthe last 0.2 million years, long after the insertion of thethree retrotransposons in this duplicated region.

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Table 2. Predicted Retrotransposon Insertion and Divergence Times

	DISCUSSION

TOP Abstract INTRODUCTION RESULTS DISCUSSION METHODS References

Rp1 is a complex disease resistance locus that shows meioticinstability as a result of unequal crossing over (Bennetzenet al., 1988

; Sudupak et al., 1993

; Richter et al., 1995

; Collinset al., 1999

). We studied the sequence organization and evolutionof this region by sequencing three BACs covering $~$ 195 kb of theRp1 region from maize line B73, an inbred line with no knownRp1 resistance specificity. Several interesting features wererevealed that indicate the dynamic nature of this locus. Theduplication of a 43-kb segment shared by the two BACs was identified.From our physical map, we conclude that these duplicated segmentsare separated by at least 300 kb. Although unequal recombinationcan create adjacent direct duplications of a very large size,from a few base pairs to hundreds of kilobases, there is noknown single-step mechanism that can generate duplications ofmore than a few base pairs that are several kilobases apart.The boundaries of this 43-kb duplication are located outsideof the Rp1 homologs. Therefore, the duplication of the 43-kbsegment probably did not involve unequal recombination sitedwithin Rp1 homologs. However, the instability of this regionmakes it likely that the current state of the region is theproduct of numerous rearrangement events. Regardless, at leasttwo of these rearrangements must have had boundaries outsideof the Rp1 homologs to generate the current B73 Rp1 region.

Comparison of the 43-kb duplicated segments revealed the presenceof several indels. The presence of direct tandem repeats suggeststhat replication slippage, illegitimate recombination, and/ortransposable element excision were responsible for these indels.The small number of differences within the 43-kb region indicatesthat this duplication occurred very recently, within the last200,000 years. Recombinational studies and investigations oflocus instability (Bennetzen et al., 1988; Sudupak et al., 1993;Richter et al., 1995; Sun et al., 2001) all have suggested thatunequal recombination and/or other rearrangements in the Rp1region can occur at rates of up to a few tenths of a percentper meiosis in some alleles or allelic combinations, so recentrearrangements are expected.

Several truncated gene fragments were detected next to the Rp1homologs in the two BACs. Such truncated genes have been reportedin a few disease resistance gene clusters in plants and alsoin duplicated segments of the human genome (Parniske et al.,1997; Meyers et al., 1998a; Noel et al., 1999; Holub, 2001;Emanuel and Shaikh, 2001). For instance, the Cf-4/Cf-9 clustercontains several copies of one truncated gene that is similarto plant lipoxygenases, whereas the Dm region of lettuce hasthree gene fragments that have homology with a few hundred basepairs of a cyclin gene (Parniske et al., 1997; Meyers et al.,1998a). In addition, eight truncated copies of a Ser/Thr proteinkinase gene and a 5S rRNA gene were observed in the ArabidopsisRPP5 locus (Noel et al., 1999). In humans, segmental duplicationsinvolved in genomic disorders sometimes contain truncated genes(Emanuel and Shaikh, 2001). In the B73 Rp1 region, we foundnumerous truncated genes, often arranged in clusters. Truncatedgenes are relatively rare in plants, and no clustering of suchgenes has been reported to date. We believe that the accumulationof these elements in the Rp1 complex that we have discoveredmay be an outcome of the general instability of this region.

Double-stranded breaks are critical lesions in genomes thatcan be repaired by illegitimate or homologous recombination.In large genomes, such as that of tobacco, 40% of observed deletionsin one study were accompanied by the insertion of filler sequences,whereas no large deletions or insertions were observed duringdouble-stranded break repair in Arabidopsis (Kirik et al., 2000).Filler DNA was associated in maize with spontaneous wx and bz1deletion alleles (Ralston et al., 1988; Wessler et al., 1990)and at the breakpoints of several spontaneous Ac deletion derivatives(Yan et al., 1999). The presence of discontinuous stretchesof sequences in maize r-r alleles also was attributed to thisgap-repair mechanism (Walker et al., 1995). In the illegitimaterecombination process of gap repair, short stretches of heterologousDNA with very little sequence homology with the gap boundaries(often not more than 1 or 2 bp) can serve as a template to fillthe gap between two broken ends. Although these fragments oftenconsist of genomic DNA, long interspersed nuclear element DNAsand genic cDNA fragments have been inserted at the sites ofDNA breaks in yeast and mammals (Moore and Haber, 1996; Tenget al., 1996). Hence, double-stranded break repair offers amechanism for spreading sequences into new chromosomal locations.In general, though, it is rare for a filler sequence to containan uninterrupted open reading frame over its entire length (Salomonand Puchta, 1998). In the B73 Rp1 region of maize, we do notknow whether genes 4 and 5 of BAC Zm163K15 are genes that havebeen intrinsic to this region for many millions of years orwhether they represent unusually large filler sequences.

The numerous truncated genes in the maize Rp1 region suggestthat a high frequency of DNA breakage occurs in this regionand that the truncated loci have been acquired as fillers indouble-stranded break repair. The fact that the truncated genesare clustered also implies that the breaks must occur frequentlyat the same locations or that nu-merous fillers were neededto deal with the gaps that were created. The appearance of raretruncated genes at other complex resistance loci, although atlower abundances, sug-gests that double-stranded breaks maybe unusually frequent in all complex resistance loci but justmore so in the highly unstable Rp1 locus.

Genomic regions that exhibit high levels of recombination areusually gene rich in eukaryotes (Gill et al., 1996; Farris etal., 2000; Fu et al., 2001). The maize Rp1 complex varies tremendouslyin recombinational "size" from experiment to experiment, dependingon the haplotypes that are paired. In a standard case, the mostdistal Rp1 resistance determinants are $~$ 0.4 cM apart (Saxenaand Hooker, 1968). In our studies, the most distant Rp1 homologsare at least 550 kb apart, amounting to >1.3 Mb/cM. This findingsuggests somewhat less recombination in the Rp1 area than thepredicted average number for a maize genome that is $~$ 2400 Mbin size and has a genetic map of $~$ 2500 cM (Arumuganathan andEarle, 1991). However, in a previous study, markers ksu3/4 andksu16 (bnl3.04), which are separated by $~$ 4 cM and which flankthe Rp1 region (Hulbert and Bennetzen, 1991; Hong et al., 1993),were estimated to be $~$ 650 kb apart based on fluorescence in situhybridization (Jiang et al., 1996). That study suggested a recombinationrate of $~$ 160 kb per cM, approximate sevenfold higher than average.These results reconfirm earlier observations that the Rp1 regioncan be a hot spot for meiotic recombination in some homozygotesor allelic combinations but may be relatively deficient in recombinationin other haplotype combinations. The low recombination ratesin some combinations may be caused by dissimilar sizes and compositionsof the regions between these highly divergent alleles, by inversionsin some or all of the Rp1 paralogs present, or by a physicallyshort distance between the Rp1 homologs that actually providea scorable trait (race-specific disease resistance).

Unequal recombination can be localized within genes and is oftensited in the repeats in the LRR region, as observed in mutantsat the M locus in flax and in RPP5 in Arabidopsis (Andersonet al., 1997; Noel et al., 1999). However, in haplotypes ofthe Cf-4/Cf-9 region, unequal recombination within the complexwas sited primarily at a specific location that was not withina resistance gene (Parniske et al., 1997; Parniske and Jones,1999). The breakpoints in novel RGC2 haplotypes were betweenrather than within RGC2 genes (Chin et al., 2001). In the Rp1homologs studied by Sun et al. (2001), all but two of the detectedunequal recombination events were resolved within the Rp1 homologsthemselves. However, each of these unequal recombination eventswas identified because it altered a resistance phenotype, anoutcome that may be most likely to occur if recombination issited within a resistance gene. Future studies of "unselected"recombination or rearrangement events (perhaps like the 43-kbduplication seen in this study) may provide a less biased indicationof how often resistance genes are the sites of unequal recombinationevents.

Unequal or equal recombination within the LRR repeats can expandor contract LRR repeat numbers and make chimeric repeats, therebypotentially altering the recognition specificity of the gene(Ellis et al., 2000b). Hence, recombination at intragenic locationsshould provide outcomes that are most likely to be selectivelyadvantageous. Alternatively, a specific mechanism to site recombinationevents within particular regions of resistance/recognition genesmight evolve to promote resistance gene diversification (Bennetzenand Hulbert, 1992). In the Rp1 region, our data indicate thatnumerous equal or unequal recombination events have boundarieslocated within the LRR domains, particularly in LRR2. This findingsuggests that this area is actively selected for diverse sequences.

Diversifying selection in the LRR regions allows plant diseaseresistance genes to keep up with rapidly evolving pathogen populations.In general, the N-terminal nucleotide binding site region showspurifying selection as expected as a result of its proposedrole as an obligatory effector domain involved in signal transduction(Baker et al., 1997). The LRR regions participate in directrecognition of pathogen-derived avirulence factors, so theirpotential for variation is highly important. In this study,we show that sliding-window analysis can provide a particularlyprecise indication of the sites in resistance genes that areunder diversifying or purifying selection.

Transposons are important players in the evolution of all plantgenes and all aspects of genome structure (Wessler et al., 1995;Bennetzen, 2000). In some cases, resistance gene inactivationand diversification have been caused by transposable elements.For instance, an insertion in maize Hm1 was responsible forthe breakdown of fungal resistance in many commercial breedingpopulations (Multani et al., 1998). Insertion of the transposableelements Retrofit and Truncator resulted in truncated open readingframes of rice Xa21 gene family members (Song et al., 1997).It is not known whether the retrotransposons or other transposableelements in the vicinity of the B73 rp1 cluster have any effecton Rp1 gene function or evolution.

The regions sequenced are unusual in their deficiency of miniatureinverted repeat transposable elements (Bureau and Wessler, 1994).These elements are abundant throughout plant genomes, especiallyin genic areas (Wessler et al., 1995; Tikhonov et al., 1999;Jiang and Wessler, 2001). It is not clear why there are onlytwo miniature inverted repeat transposable elements in thisregion compared with the average of three or more per gene thatwe observed in other regions of the maize genome (Tikhonov etal., 1999). The Zm206C17/Zm238E11 BAC contig and BAC Zm163K15exhibit retrotransposon contents of 70 and 45%, respectively,similar to the retrotransposon contents reported in the maizeadh1 region (74%) (Tikhonov et al., 1999) and for the entiremaize genome (50 to 75%) (SanMiguel and Bennetzen, 1998; Meyerset al., 2001). Hence, the meiotic instability of the Rp1 regiondoes not seem to have removed most repetitive DNAs. Future studiescan use retrotransposons as tools to date the history of changesin different rp1 haplotypes and also can investigate the degreeto which these abundant elements may have altered Rp1 regionstructure and gene function.

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BAC Selection, Restriction Map, and Sequencing
An Rp1 5' probe, as described by Sun et al. (2001) (kindly providedby Scot Hulbert, Kansas State University, Manhattan, KS), wasused to screen a maize (Zea mays) B73 BAC library (Genome Systems,St. Louis, MO). Restriction maps of BACs Zm163K15, Zm206C17,and Zm238E11 were constructed to experimentally validate sequenceassembly. BACs were digested with the restriction enzymes AscI,NotI, PacI, PmeI, and SwaI. Restriction fragments were separatedby field inversion gel electrophoresis on 1% agarose gels, transferredto nylon membranes, and hybridized with the Rp1 5' probe.

Shotgun libraries for BACs Zm163K15, Zm206C17, and Zm238E11,sequencing, and analysis were as described by Dubcovsky et al.(2001). For finishing the sequences of the BACs, gaps were closedby a combination of different approaches, including the useof different sequence chemistries, use of the thermofidelaseenzyme, PCR amplification of gaps, shotgun sequencing of transposon-insertedsubclones that flank a gap, and direct sequencing of BAC template.When gaps were caused by repetitive regions, subclones thateither started or ended in unique regions with the remainingportion in the repetitive region were assembled separately andinserted into the main assembly.

Construction of a Physical Map
A large insert B73 maize BAC library (www.chori.org/bacpac)was screened with the Rp1 5' probe. A total of 33 positive BACswere identified, and these clones were mapped using differentcombinations of MluI, NcoI, NotI, and SwaI. Fragments were size-fractionatedby field inversion gel electrophoresis. The DNAs in the gelswere transferred to nylon membranes and hybridized with theRp1 5' probe and a probe that contained a truncated Suc phosphatesynthase–like gene identified in the region by sequenceanalysis. Fragments observed on the agarose gel were comparedbetween BACs to identify common fragments. This map also wascompared with the maize genome physical map that is in preparationat the Arizona Genomics Institute (www.genome.arizona.edu/fpc/maize/).

Sequence Analysis
Annotation and sequence analysis were performed as describedpreviously (Dubcovsky et al., 2001). FGENESH (http://www.softberry.com/berry.phtml)with the monocot training set was used for gene prediction,in addition to GENSCAN (http://genes.mit.edu/GENSCAN.html) andGeneMark.hmm (http://opal.biology.gatech.edu/GeneMark/eukhmm.cgi).The criteria used to define a gene were as follows: (1) a matchto a sequence in a protein database using BLASTX (Altschul etal., 1997); (2) a match to ESTs or cDNAs; or (3) predictionas a gene by two or more gene prediction programs. These criteriawere used after excluding identified transposons.

All of the Rp1 homologs and retrotransposons were aligned usingCLUSTAL X (Thompson et al., 1997). Rates of nucleotide substitutionwere estimated using the distance measures of Nei and Gojobori(1986) and the Jukes-Cantor correction as implemented in theMEGA2 (Molecular Evolutionary Genetic Analysis) package (Kumaret al., 2001). Synonymous substitution rates were estimatedas implemented in MEGA2. Divergence times (T) were estimatedfor retrotransposons using k = K/2T, where k is the absoluterate of synonymous substitution per site per year for the adh1and adh2 genes in grasses and K is the estimated number of substitutionsper site between sequences using the Kimura two-parameter method(Kimura, 1980). A 2 x 2 contingency table G test was used totest for the significance of differences in synonymous and nonsynonymoussubstitution rates (Zhang et al., 1997).

Upon request, all novel materials described in this articlewill be made available in a timely manner for noncommercialresearch purposes.

Accession Numbers
The GenBank accession numbers for the sequences reported inthis article are AF466931 (Zm163K15) and AF466932 (Zm206C17/Zm238E11).

Acknowledgments

This work was funded by the National Science Foundation PlantGenome Program (Grant 9975618).

Footnotes

Article, publication date, and citation information can be foundat www.plantcell.org/cgi/doi/10.1105/tpc.006338.

Received July 22, 2002; accepted September 26, 2002.

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