Pooled effector library screening in protoplasts rapidly identifies novel Avr genes.

Crop breeding for durable disease resistance is challenging due to the rapid evolution of pathogen virulence. While progress in resistance (R) gene cloning and stacking has accelerated in recent years1-3, the identification of corresponding avirulence (Avr) genes in many pathogens is hampered by the lack of high-throughput screening options. To address this technology gap, we developed a platform for pooled library screening in plant protoplasts to allow rapid identification of interacting R-Avr pairs. We validated this platform by isolating known and novel Avr genes from wheat stem rust (Puccinia graminis f. sp. tritici) after screening a designed library of putative effectors against individual R genes. Rapid Avr gene identification provides molecular tools to understand and track pathogen virulence evolution via genotype surveillance, which in turn will lead to optimized R gene stacking and deployment strategies. This platform should be broadly applicable to many crop pathogens and could potentially be adapted for screening genes involved in other protoplast-selectable traits.

Epigenetic Mechanisms: An Emerging Player in Plant-Microbe Interactions.

Plants have developed diverse molecular and cellular mechanisms to cope with a lifetime of exposure to a variety of pathogens. Host transcriptional reprogramming is a central part of plant defense upon pathogen recognition. Recent studies link DNA methylation and demethylation as well as chromatin remodeling by posttranslational histone modifications, including acetylation, methylation, and ubiquitination, to changes in the expression levels of defense genes upon pathogen challenge. Remarkably these inducible defense mechanisms can be primed prior to pathogen attack by epigenetic modifications and this heightened resistance state can be transmitted to subsequent generations by inheritance of these modification patterns. Beside the plant host, epigenetic mechanisms have also been implicated in virulence development of pathogens. This review highlights recent findings and insights into epigenetic mechanisms associated with interactions between plants and pathogens, in particular bacterial and fungal pathogens, and demonstrates the positive role they can have in promoting plant defense.

Emergence and Spread of New Races of Wheat Stem Rust Fungus: Continued Threat to Food Security and Prospects of Genetic Control.

Race Ug99 (TTKSK) of Puccinia graminis f. sp. tritici, detected in Uganda in 1998, has been recognized as a serious threat to food security because it possesses combined virulence to a large number of resistance genes found in current widely grown wheat (Triticum aestivum) varieties and germplasm, leading to its potential for rapid spread and evolution. Since its initial detection, variants of the Ug99 lineage of stem rust have been discovered in Eastern and Southern African countries, Yemen, Iran, and Egypt. To date, eight races belonging to the Ug99 lineage are known. Increased pathogen monitoring activities have led to the identification of other races in Africa and Asia with additional virulence to commercially important resistance genes. This has led to localized but severe stem rust epidemics becoming common once again in East Africa due to the breakdown of race-specific resistance gene SrTmp, which was deployed recently in the 'Digalu' and 'Robin' varieties in Ethiopia and Kenya, respectively. Enhanced research in the last decade under the umbrella of the Borlaug Global Rust Initiative has identified various race-specific resistance genes that can be utilized, preferably in combinations, to develop resistant varieties. Research and development of improved wheat germplasm with complex adult plant resistance (APR) based on multiple slow-rusting genes has also progressed. Once only the Sr2 gene was known to confer slow rusting APR; now, four more genes-Sr55, Sr56, Sr57, and Sr58-have been characterized and additional quantitative trait loci identified. Cloning of some rust resistance genes opens new perspectives on rust control in the future through the development of multiple resistance gene cassettes. However, at present, disease-surveillance-based chemical control, large-scale deployment of new varieties with multiple race-specific genes or adequate levels of APR, and reducing the cultivation of susceptible varieties in rust hot-spot areas remains the best stem rust management strategy.

The wheat Sr50 gene reveals rich diversity at a cereal disease resistance locus.

We identify the wheat stem rust resistance gene Sr50 (using physical mapping, mutation and complementation) as homologous to barley Mla, encoding a coiled-coil nucleotide-binding leucine-rich repeat (CC-NB-LRR) protein. We show that Sr50 confers a unique resistance specificity different from Sr31 and other genes on rye chromosome 1RS, and is effective against the broadly virulent Ug99 race lineage. Extensive haplotype diversity at the rye Sr50 locus holds promise for mining effective resistance genes.

A bacterial type III secretion assay for delivery of fungal effector proteins into wheat.

Large numbers of candidate effectors from fungal pathogens are being identified through whole-genome sequencing and in planta expression studies. Although Agrobacterium-mediated transient expression has enabled high-throughput functional analysis of effectors in dicot plants, this assay is not effective in cereal leaves. Here, we show that a nonpathogenic Pseudomonas fluorescens engineered to express the type III secretion system (T3SS) of P. syringae and the wheat pathogen Xanthomonas translucens can deliver fusion proteins containing T3SS signals from P. syringae (AvrRpm1) and X. campestris (AvrBs2) avirulence (Avr) proteins, respectively, into wheat leaf cells. A calmodulin-dependent adenylate cyclase reporter protein was delivered effectively into wheat and barley by both bacteria. Absence of any disease symptoms with P. fluorescens makes it more suitable than X. translucens for detecting a hypersensitive response (HR) induced by an effector protein with avirulence activity. We further modified the delivery system by removal of the myristoylation site from the AvrRpm1 fusion to prevent its localization to the plasma membrane which could inhibit recognition of an Avr protein. Delivery of the flax rust AvrM protein by the modified delivery system into transgenic tobacco leaves expressing the corresponding M resistance protein induced a strong HR, indicating that the system is capable of delivering a functional rust Avr protein. In a preliminary screen of effectors from the stem rust fungus Puccinia graminis f. sp. tritici, we identified one effector that induced a host genotype-specific HR in wheat. Thus, the modified AvrRpm1:effector-Pseudomonas fluorescens system is an effective tool for large-scale screening of pathogen effectors for recognition in wheat.

Plastid DNA in the nucleus: new genes for old.

Nuclear genomes of eukaryotes are bombarded by a continuous deluge of organellar DNA which contributes significantly to eukaryote evolution. Here, we present a new PCR-based method that allows the specific amplification of nuclear integrants of organellar DNA (norgs) by exploiting recent deletions present in organellar genome sequences. We have used this method to amplify nuclear integrants of plastid DNA (nupts) from the nuclear genomes of several Nicotiana species and to study the evolutionary forces acting upon these sequences. The role of nupts in endosymbiotic evolution and the different genetic factors influencing the time available for a chloroplastic gene to be functionally relocated in the nucleus are discussed.

Conservation of plastid sequences in the plant nuclear genome for millions of years facilitates endosymbiotic evolution.

The nuclear genome of eukaryotes contains large amounts of cytoplasmic organelle DNA (nuclear integrants of organelle DNA [norgs]). The recent sequencing of many mitochondrial and chloroplast genomes has enabled investigation of the potential role of norgs in endosymbiotic evolution. In this article, we describe a new polymerase chain reaction-based method that allows the identification and evolutionary study of recent and older norgs in a range of eukaryotes. We tested this method in the genus Nicotiana and obtained sequences from seven nuclear integrants of plastid DNA (nupts) totaling 25 kb in length. These nupts were estimated to have been transferred 0.033 to 5.81 million years ago. The spectrum of mutations present in the potential protein-coding sequences compared with the noncoding sequences of each nupt revealed that nupts evolve in a nuclear-specific manner and are under neutral evolution. Indels were more frequent in noncoding regions than in potential coding sequences of former chloroplastic DNA, most probably due to the presence of a higher number of homopolymeric sequences. Unexpectedly, some potential protein-coding sequences within the nupts still contained intact open reading frames for up to 5.81 million years. These results suggest that chloroplast genes transferred to the nucleus have in some cases several millions of years to acquire nuclear regulatory elements and become functional. The different factors influencing this time frame and the potential role of nupts in endosymbiotic gene transfer are discussed.

Introducing an RNA editing requirement into a plastid-localised transgene reduces but does not eliminate functional gene transfer to the nucleus.

In higher plants, DNA transfer from the plastid (chloroplast) genome to the nucleus is a frequent, ongoing process. However, there has been uncertainty over whether this transfer occurs by a direct DNA mechanism or whether RNA intermediates are involved. Previous experiments utilising transplastomic Nicotiana tabacum (tp7 and tp17) enabled the detection of plastid-to-nucleus transfer in real time. To determine whether RNA intermediates are involved in this transfer, transplastomic lines (tpneoACG) were generated containing, in their plastid genomes, a nuclear promoter-driven kanamycin resistance gene (neo) with a start codon that required plastid RNA editing but otherwise identical to tp7 and tp17. Therefore it was expected that kanamycin resistance would only be acquired following RNA-mediated transfer of neo to the nucleus. Screening of tpneoACG progeny revealed several kanamycin-resistant plants, each of which contained the neo gene located in the nucleus. Surprisingly, neo was unedited in all these plants, indicating that neoACG was active in the absence of an edited start codon and suggesting that RNA intermediates were not involved in the transfers. However, analysis of tpneoACG revealed that only a low proportion of transcripts potentially able to mediate neo transfer were edited, thus precluding unequivocal conclusions regarding the role of RNA in plastid-to-nucleus transfer. The low proportion of edited transcripts was found to be due to predominant antisense neo transcripts, rather than to low editing efficiency of the sense transcripts. This study highlights a number of important considerations in the design of experiments utilising plastid RNA editing. The results also suggest that RNA editing sites reduce but do not eliminate functional plastid-to-nucleus gene transfer. This is relevant both in an evolutionary context and in placing RNA editing-dependent genes in the plastid genome as a means of transgene containment.

Activation tagging and insertional mutagenesis in barley.

The process of activation tagging in plants involves the random distribution of plant regulatory sequences throughout the genome. The insertion of a regulatory sequence in the vicinity of an endogenous gene can alter the transcriptional pattern of this gene resulting in a mutant phenotype that arises from excess functional gene product. Activation tagging has been undertaken extensively in a number of dicot plants and also in rice. This has been achieved primarily by high-throughput plant transformation using T-DNA sequences that encode regulatory elements. Apart from rice, most cereals do not have a suitably efficient transformation system for high-throughput transformation. In this article, we detail an activation tagging system in barley that exploits the mobility of the maize Ac/Ds transposable element system to distribute a highly expressed promoter throughout the barley genome. The advantage of this approach in this species is that a relatively small number of primary transgenics are required to generate an activation tagging population. Insertion of this transposable element into genes can also generate insertional inactivation mutants enabling both gene overexpression and gene knockout mutants to be identified in the same population.

Suppression of the barley uroporphyrinogen III synthase gene by a Ds activation tagging element generates developmental photosensitivity.

Chlorophyll production involves the synthesis of photoreactive intermediates that, when in excess, are toxic due to the production of reactive oxygen species (ROS). A novel, activation-tagged barley (Hordeum vulgare) mutant is described that results from antisense suppression of a uroporphyrinogen III synthase (Uros) gene, the product of which catalyzes the sixth step in the synthesis of chlorophyll and heme. In homozygous mutant plants, uroporphyrin(ogen) I accumulates by spontaneous cyclization of hydroxyl methylbilane, the substrate of Uros. Accumulation of this tetrapyrrole intermediate results in photosensitive cell death due to the production of ROS. The efficiency of Uros gene suppression is developmentally regulated, being most effective in mature seedling leaves compared with newly emergent leaves. Reduced transcript accumulation of a number of nuclear-encoded photosynthesis genes occurs in the mutant, even under 3% light conditions, consistent with a retrograde plastid-nuclear signaling mechanism arising from Uros gene suppression. A similar set of nuclear genes was repressed in wild-type barley following treatment with a singlet oxygen-generating herbicide, but not by a superoxide generating herbicide, suggesting that the retrograde signaling apparent in the mutant is specific to singlet oxygen.

Transfer of plastid DNA to the nucleus is elevated during male gametogenesis in tobacco.

In eukaryotes, many genes were transferred to the nucleus from prokaryotic ancestors of the cytoplasmic organelles during endosymbiotic evolution. In plants, the transfer of genetic material from the plastid (chloroplast) and mitochondrion to the nucleus is a continuing process. The cellular location of a kanamycin resistance gene tailored for nuclear expression (35SneoSTLS2) was monitored in the progeny of reciprocal crosses of tobacco (Nicotiana tabacum) in which, at the start of the experiments, the reporter gene was confined either to the male or the female parental plastid genome. Among 146,000 progeny from crosses where the transplastomic parent was male, 13 transposition events were identified, whereas only one atypical transposition was identified in a screen of 273,000 transplastomic ovules. In a second experiment, a transplastomic beta-glucuronidase reporter gene, tailored to be expressed only in the nucleus, showed frequent stochastic expression that was confined to the cytoplasm in the somatic cells of several plant tissues. This gene was stably transferred in two out of 98,000 seedlings derived from a male transplastomic line crossed with a female wild type. These data demonstrate relocation of plastid DNA to the nucleus in both somatic and gametophytic tissue and reveal a large elevation of the frequency of transposition in the male germline. The results suggest a new explanation for the occurrence of uniparental inheritance in eukaryotes.

A barley activation tagging system.

Activation tagging, as the result of random genomic insertion of either promoter or enhancer sequences, can produce novel, dominant mutations by over-expression of endogenous genes. This powerful genomics tool has been used extensively in dicot species such as Arabidopsis, while rice is the only cereal for which an equivalent system exists. In this study we describe an activation tagging system in barley based upon the maize Ac/Ds transposable element system. A modified Ds element (UbiDs) containing two maize polyubiquitin promoters, transposed in families derived from multiple independent UbiDs transformants and generated new Ds insertion events at frequencies ranging from 0% to 52% per family. The majority of transposed UbiDs elements activated high levels of adjacent flanking sequence transcription. Transposon-mediated expression was detected in all barley cell and tissue types analysed suggesting that this system is applicable to all aspects of plant development and biogenesis. In addition to transcriptional activation, this system is also capable of generating insertional knockout mutants and a UbiDs inactivated allele of the granule bound starch synthase I gene (waxy) was recovered that lead to reduced amylose accumulation. The recovery and analysis of dominant over-expression phenotypes generated by this system will provide a novel approach to understanding gene function in large cereal genomes where gene redundancy may mask conventional loss-of-function mutations.

Direct protein interaction underlies gene-for-gene specificity and coevolution of the flax resistance genes and flax rust avirulence genes.

Plant resistance proteins (R proteins) recognize corresponding pathogen avirulence (Avr) proteins either indirectly through detection of changes in their host protein targets or through direct R-Avr protein interaction. Although indirect recognition imposes selection against Avr effector function, pathogen effector molecules recognized through direct interaction may overcome resistance through sequence diversification rather than loss of function. Here we show that the flax rust fungus AvrL567 genes, whose products are recognized by the L5, L6, and L7 R proteins of flax, are highly diverse, with 12 sequence variants identified from six rust strains. Seven AvrL567 variants derived from Avr alleles induce necrotic responses when expressed in flax plants containing corresponding resistance genes (R genes), whereas five variants from avr alleles do not. Differences in recognition specificity between AvrL567 variants and evidence for diversifying selection acting on these genes suggest they have been involved in a gene-specific arms race with the corresponding flax R genes. Yeast two-hybrid assays indicate that recognition is based on direct R-Avr protein interaction and recapitulate the interaction specificity observed in planta. Biochemical analysis of Escherichia coli-produced AvrL567 proteins shows that variants that escape recognition nevertheless maintain a conserved structure and stability, suggesting that the amino acid sequence differences directly affect the R-Avr protein interaction. We suggest that direct recognition associated with high genetic diversity at corresponding R and Avr gene loci represents an alternative outcome of plant-pathogen coevolution to indirect recognition associated with simple balanced polymorphisms for functional and nonfunctional R and Avr genes.

Haustorially expressed secreted proteins from flax rust are highly enriched for avirulence elicitors.

Rust fungi, obligate biotrophs that cause disease and yield losses in crops such as cereals and soybean (Glycine max), obtain nutrients from the host through haustoria, which are specialized structures that develop within host cells. Resistance of flax (Linum usitatissimum) to flax rust (Melampsora lini) involves the induction of a hypersensitive cell death response at haustoria formation sites, governed by gene-for-gene recognition between host resistance and pathogen avirulence genes. We identified genes encoding haustorially expressed secreted proteins (HESPs) by screening a flax rust haustorium-specific cDNA library. Among 429 unigenes, 21 HESPs were identified, one corresponding to the AvrL567 gene. Three other HESPs cosegregated with the independent AvrM, AvrP4, and AvrP123 loci. Expression of these genes in flax induced resistance gene-mediated cell death with the appropriate specificity, confirming their avirulence activity. AvrP4 and AvrP123 are Cys-rich proteins, and AvrP123 contains a Kazal Ser protease inhibitor signature, whereas AvrM contains no Cys residues. AvrP4 and AvrM induce cell death when expressed intracellularly, suggesting their translocation into plant cells during infection. However, secreted AvrM and AvrP4 also induce necrotic responses, with secreted AvrP4 more active than intracellular AvrP4, possibly as a result of enhanced formation of endoplasmic reticulum-dependent disulfide bonds. Addition of an endoplasmic reticulum retention signal inhibited AvrM-induced necrosis, suggesting that both AvrM and AvrP4 can reenter the plant cell after secretion in the absence of the pathogen.

A rust-inducible gene from flax (fis1) is involved in proline catabolism.

A gene fis1 from flax (Linum usitatissimum), which is induced in mesophyll cells at the site of rust (Melampsora lini) infection, is also expressed in vascular tissue, particularly in floral structures of healthy plants. This paper reports that the promoter controlling this expression is contained within 282 bp 5' to the coding region and that fis1 gene induction is specifically by the rust pathogen and not by other fungal pathogens or by wounding. The fis1 gene has 73% homology with an Arabidopsis gene which encodes delta-1-pyrroline-5-carboxylate dehydrogenase (P5CDH) which is a part of the proline degradation pathway. Transgenic flax plants that either over-express fis1 or show reduced fis1 expression due to RNA-mediated gene silencing have an unaltered morphology. However, plants with reduced fis1 expression have markedly increased sensitivity to exogenous proline and show alteration in epidermal cell morphology, callose deposition and the production of hydrogen peroxide during proline-induced death. These lines, which show a biologically significant level of fis1 suppression, have an unaltered reaction to either virulent or avirulent rust infections, as do fis1 over-expression lines. These data indicate that the fis1 gene plays a role in proline metabolism and most likely encodes for a P5CDH enzyme. However, the precise role of fis1 and P5C catabolism in the development of rust disease remains unclear.

Comparative analysis in cereals of a key proline catabolism gene.

Proline accumulation and catabolism play significant roles in adaptation to a variety of plant stresses including osmotic stress, drought, temperature, freezing, UV irradiation, heavy metals and pathogen infection. In this study, the gene Delta1 -pyrroline-5-carboxylate dehydrogenase (P5CDH), which catalyzes the second step in the conversion of proline to glutamate, is characterized in a number of cereal species. P5CDH genes from hexaploid wheat, Triticum turgidum (durum wheat), Aegilops tauschii, Triticum monococcum, barley, maize and rice were shown to be conserved in terms of gene structure and sequence, present as a single copy per haploid, non-polyploid genome and located in evolutionarily conserved linkage groups. A wheat cDNA sequence was shown by yeast complementation to encode a functional P5CDH activity. A divergently-transcribed rab7 gene was identified immediately 5' of P5CDH in all grasses examined, except rice. The rab7/P5CDH intergenic region in these species, which presumably encompasses 5' regulatory elements of both genes, showed a distinct pattern of sequence evolution with sequences in juxtaposition to each ORF conserved between barley, wheat, A. tauschii and T. monococcum. More distal 5' sequence in this intergenic region showed a higher rate of divergence, with no homology observed between these regions in the wheat and barley genomes. Maize and rice showed no similarity in regions 5' of P5CDH when compared with wheat, barley, and each other, apart from a 22 bp region of conserved non-coding sequence (CNS) that is similar to a proline response element identified in the promoter of the Arabidopsis proline dehydrogenase gene. A palindromic motif similar to this cereal CNS was also identified 5' of the Arabidopsis AtP5CDH gene showing conservation of this sequence in monocot and dicot lineages.

Molecular genetics of disease resistance in cereals.

AIMS: This Botanical Briefing attempts to summarize what is currently known about the molecular bases of disease resistance in cereal species and suggests future research directions. SCOPE: An increasing number of resistance (R) genes have been isolated from rice, maize, wheat and barley that encode both structurally related and unique proteins. This R protein diversity may be attributable to the different modus operandi employed by pathogen species in some cases, but it is also a consequence of multiple defence strategies being employed against phytopathogens. Mutational analysis of barley has identified additional genes required for activation of an R gene-mediated defence response upon pathogen infection. In some instances very closely related barley R proteins require different proteins for defence activation, demonstrating that, within a single plant species, multiple resistance signalling pathways and different resistance strategies have evolved to confer protection against a single pathogen species. Despite the apparent diversity of cereal resistance mechanisms, some of the additional molecules required for R protein function are conserved amongst cereal and dicotyledonous species and even other eukaryotic species. Thus the derivation of functional homologues and interacting partner proteins from other species is contributing to the understanding of resistance signalling in cereals. The potential and limit of utilizing the rice genome sequence for further R gene isolation from cereal species is also considered, as are the new biotechnological possibilities for disease control arising from R gene isolation. CONCLUSIONS: Molecular analyses in cereals have further highlighted the complexity of plant-pathogen co-evolution and have shown that numerous active and passive defence strategies are employed by plants against phytopathogens. Many advances in understanding the molecular basis of disease resistance in cereals have focused on monogenic resistance traits. Future research targets are likely to include less experimentally tractable, durable polygenic resistances and nonhost resistance mechanisms.

Aberrant mRNA processing of the maize Rp1-D rust resistance gene in wheat and barley.

The maize Rp1-D gene confers race-specific resistance against Puccinia sorghi (common leaf rust) isolates containing a corresponding avrRp1-D avirulence gene. An Rp1-D genomic clone and a similar Rp1-D transgene regulated by the maize ubiquitin promoter were transformed independently into susceptible maize lines and shown to confer Rp1-D resistance, demonstrating that this resistance can be transferred as a single gene. Transfer of these functional transgenes into wheat and barley did not result in novel resistances when these plants were challenged with isolates of wheat stem rust (P. graminis), wheat leaf rust (P. triticina), or barley leaf rust (P. hordei). Regardless of the promoter employed, low levels of gene expression were observed. When constitutive promoters were used for transgene expression, a majority of Rp1-D transcripts were truncated in the nucleotide binding site-encoding region by premature polyadenylation. This aberrant mRNA processing was unrelated to gene function because an inactive version of the gene also generated such transcripts. These data demonstrate that resistance gene transfer between species may not be limited only by divergence of signaling effector molecules and pathogen avirulence ligands, but potentially also by more fundamental gene expression and transcript processing limitations.

Simple and complex nuclear loci created by newly transferred chloroplast DNA in tobacco.

Transfer of organelle DNA into the nuclear genome has been significant in eukaryotic evolution, because it appears to be the origin of many nuclear genes. Most studies on organelle DNA transfer have been restricted to evolutionary events but experimental systems recently became available to monitor the process in real time. We designed an experimental screen to detect plastid DNA (ptDNA) transfers to the nucleus in whole plants grown under natural conditions. The resultant genotypes facilitated investigation of the evolutionary mechanisms underlying ptDNA transfer and nuclear integration. Here we report the characterization of nuclear loci formed by integration of newly transferred ptDNA. Large, often multiple, fragments of ptDNA between 6.0 and 22.3 kb in size are incorporated into chromosomes at single Mendelian loci. The lack of chloroplast transcripts of comparable size to the ptDNA integrants suggests that DNA molecules are directly involved in the transfer process. Microhomology (2-5 bp) and rearrangements of ptDNA and nuclear DNA were frequently found near integration sites, suggesting that nonhomologous recombination plays a major role in integration. The mechanisms of ptDNA integration appear similar to those of biolistic transformation of plant cells, but no sequence preference was identified near junctions. This article provides substantial molecular analysis of real-time ptDNA transfer and integration that has resulted from natural processes with no involvement of cell injury, infection, and tissue culture. We highlight the impact of cytoplasmic organellar genome mobility on nuclear genome evolution.

The Melampsora lini AvrL567 avirulence genes are expressed in haustoria and their products are recognized inside plant cells.

The Linum usitatissimum (flax) L gene alleles, which encode nucleotide binding site-Leu rich repeat class intracellular receptor proteins, confer resistance against the Melampsora lini (flax rust) fungus. At least 11 different L resistance specificities are known, and the corresponding avirulence genes in M. lini map to eight independent loci, some of which are complex and encode multiple specificities. We identified an M. lini cDNA marker that cosegregates in an F2 rust family with a complex locus determining avirulence on the L5, L6, and L7 resistance genes. Two related avirulence gene candidates, designated AvrL567-A and AvrL567-B, were identified in a genomic DNA contig from the avirulence allele, whereas the corresponding virulence allele contained a single copy of a related gene, AvrL567-C. Agrobacterium tumefaciens-mediated transient expression of the mature AvrL567-A or AvrL567-B (but not AvrL567-C) proteins as intracellular products in L. usitatissimum and Nicotiana tabacum (tobacco) induced a hypersensitive response-like necrosis that was dependent on coexpression of the L5, L6, or L7 resistance gene. An F1 seedling lethal or stunted growth phenotype also was observed when transgenic L. usitatissimum plants expressing AvrL567-A or AvrL567-B (but not AvrL567-C) were crossed to resistant lines containing L5, L6, or L7. The AvrL567 genes are expressed in rust haustoria and encode 127 amino acid secreted proteins. Intracellular recognition of these rust avirulence proteins implies that they are delivered into host cells across the plant membrane. Differences in the three AvrL567 protein sequences result from diversifying selection, which is consistent with a coevolutionary arms race.