Bayesian QTL analyses using pedigreed families of an outcrossing species, with application to fruit firmness in apple.

KEY MESSAGE: Proof of concept of Bayesian integrated QTL analyses across pedigree-related families from breeding programs of an outbreeding species. Results include QTL confidence intervals, individuals' genotype probabilities and genomic breeding values. Bayesian QTL linkage mapping approaches offer the flexibility to study multiple full sib families with known pedigrees simultaneously. Such a joint analysis increases the probability of detecting these quantitative trait loci (QTL) and provide insight of the magnitude of QTL across different genetic backgrounds. Here, we present an improved Bayesian multi-QTL pedigree-based approach on an outcrossing species using progenies with different (complex) genetic relationships. Different modeling assumptions were studied in the QTL analyses, i.e., the a priori expected number of QTL varied and polygenic effects were considered. The inferences include number of QTL, additive QTL effect sizes and supporting credible intervals, posterior probabilities of QTL genotypes for all individuals in the dataset, and QTL-based as well as genome-wide breeding values. All these features have been implemented in the FlexQTL(™) software. We analyzed fruit firmness in a large apple dataset that comprised 1,347 individuals forming 27 full sib families and their known ancestral pedigrees, with genotypes for 87 SSR markers on 17 chromosomes. We report strong or positive evidence for 14 QTL for fruit firmness on eight chromosomes, validating our approach as several of these QTL were reported previously, though dispersed over a series of studies based on single mapping populations. Interpretation of linked QTL was possible via individuals' QTL genotypes. The correlation between the genomic breeding values and phenotypes was on average 90 %, but varied with the number of detected QTL in a family. The detailed posterior knowledge on QTL of potential parents is critical for the efficiency of marker-assisted breeding.

First Report of Asian Brown Rot Caused by Monilia polystroma on Apricot in Switzerland.

A survey for Monilia fructicola (G. Winter) Honey on apricots (Prunus armeniaca L.) was conducted in July and August 2009 and 2010 in Canton Wallis, Switzerland. Mummies of fruits showing brown rot were collected and isolations were conducted. Nearly 200 fungal isolates, tentatively identified as M. fructigena, were retested with a multiplex PCR (1). With the Agilent 2100 Bioanalyzer (Agilent Technologies, Basel, Switzerland) instead of 1.5% agarose gels, the 23 bp difference between the diagnostic fragments of M. fructigena and M. polystroma van Leeuwen (1) could clearly be scored. M. polystroma was diagnosed in 3 of 65 and 1 of 132 isolates collected in 2009 (13 orchards) and 2010 (10 orchards), respectively. The internal transcribed spacer (ITS) regions of four isolates (09-G4, 09-P16, 09-S5, and 10-C6) were amplified and sequenced (4). The four sequences (GenBank No. JN128835) as well as those of the Hungarian isolate UFT (AM937114 [3]) were identical and highly similar to the type sequence for M. polystroma (Y17876 [2]). The type sequence had a "T" at position 414, which was lacking in the other five sequences. The genomic region of unknown function used by Côté et al. (1) to develop their PCR diagnostic tool was sequenced for isolate 09-G4 with primers MFG.for (3) and M Poly rev 5'-CCACTTACATTTTTGGCTATTG-3'. The Swiss isolate (GenBank No. JN128836) and the Hungarian isolate UFT (AM937120) sequences were identical. The pathogenicity of isolate 09-G4 was tested on Golden delicious apples. Six apples were surface sterilized (70% ethanol), halved, and placed in sterile plastic boxes cut-side down. Further, six half apples were wounded in the center with a round scalpel with a diameter of 1 cm and inoculated with a round, potato dextrose agar (PDA) plug (1-cm diameter) of actively growing mycelium (5- to 7-day-old culture). Control apples (six halves) were treated with a PDA plug without mycelium. All fruits were incubated at 20°C with a 12-h light 12-h dark cycle. Seven days after inoculation, typical brown rot symptoms were visible on all inoculated fruits. Mock inoculated fruits remained healthy. Three inoculated halves, in addition to the brown rot symptoms, also produced sporodochia and around the inoculation point the tissue become black. With the multiplex PCR (1), M. polystroma was identified as the pathogen causing brown rot symptoms on the inoculated apples. The ellipsoid single-cell hyaline conidia of isolate 09-G4 grown on the Golden delicious apples averaged 15.2 ± 4.0 × 8.97 ± 1.1 µm and were the expected size for M. polystroma conidia (14.9 to 9.1 µm [4]). The first evidence of a new Monilia species was reported by Fulton et al. (2). They found that M. fructigena isolates from Japan were distinguishable from European isolates by five base substitutions in the ITS region (four in ITS1 and one in ITS2). Later, van Leeuwen et al. (4) found that the two groups of isolates could also be distinguished by morphological differences and described the new species as M. polystroma. According to the Centre for Agricultural Bioscience International, the impact of M. polystroma in a new area is presumed to be the same or very similar to that of M. fructigena. To our knowledge, this is the first report of M. polystroma in Swiss orchards. References: (1) M.-J. Côté et al. Plant Dis. 88:1219, 2004. (2) C. E. Fulton et al. Eur. J. Plant Pathol. 105:495, 1999. (3) M. Petróczy and L. Palkovics. Eur. J. Plant Pathol. 125:343, 2009. (4) G. C. M. van Leeuwen et al. Mycol. Res. 106:444, 2002.

First Report of the ß-Tubulin E198A Mutation Conferring Resistance to Methyl Benzimidazole Carbamates in European Isolates of Monilinia fructicola.

The causal agent of brown rot on stone and pome fruits, Monilinia fructicola (G. Wint.), is a quarantine pathogen in Europe. It has been detected in Austria (later eradicated), Spain, the Czech Republic, Italy, Germany, and Switzerland (1). In the United States and other countries, M. fructicola isolates were reported to show resistance to different classes of fungicides, including methyl benzimidazole carbamates (MBC) (2). Lichou et al. (2) reported the presence of isolates resistant to the MBC carbendazim in France, but the mechanisms inducing MBC resistance in these isolates were not studied. Ma et al. (3) in California, and more recently, Zhu et al. (4) in South Carolina, demonstrated that the molecular mechanisms accounting for low and high levels of resistance to MBC fungicides in M. fructicola isolates were the mutations H6Y and E198A, respectively, in the ß-tubulin gene. Four M. fructicola isolates each from Italy, France, Spain, and Switzerland (16 isolates total), all having an unknown level of MBC resistance, were selected. In each isolate, the section of the ß-tubulin gene containing the two potentially mutant codons was PCR-amplified with the primers TubA and TubR1 (3) and the amplicons were sequenced directly. Sequence analysis revealed the amino acid histidine (H) at codon 6 in all the isolates, which would not predict MBC resistance, while alanine (A) at codon 198 (the mutation predictive of a high level of MBC resistance) was found in all isolates from Spain and Switzerland and in three isolates each from France and Italy. A representative sequence of the four identical partial ß-tubulin gene sequences from the Swiss isolates was submitted to GenBank under the Accession No. HQ709265. All isolates were tested in a potato dextrose agar (PDA) petri dish assay for resistance to the MBC fungicide thiophanate-methyl (Nippon Soda Co., Ltd., Tokyo, Japan) at the discriminatory dose of 50 µg/ml (4). All isolates with the E198A mutation were able to grow on the media, while the two isolates without the E198A mutation were not able to grow. The result indicated that most isolates had a high level of resistance to the MBC fungicide. To our knowledge, this is the first report of the presence of the E198A mutation conferring resistance to MBC fungicides in European isolates of M. fructicola. As the mutation appears to be widely distributed, we anticipate that MBC fungicides may be ineffective at controlling brown rot in countries with occurrence of M. fructicola. References: (1) M. Hilber-Bodmer et al. Plant Dis. 94:643, 2010. (2) J. Lichou et al. Phytoma 547:22, 2002. (3) Z. H. Ma et al. Appl. Environ. Microbiol. 69:7145, 2003. (4) F. X. Zhu et al. Plant Dis. 94:1511, 2010.

Mapping of quantitative trait loci for fire blight resistance in the apple cultivars 'Florina' and 'Nova Easygro'.

Fire blight is a devastating bacterial disease of rosaceous plants. Its damage to apple production is a major concern, since no existing control option has proven to be completely effective. Some commercial apple varieties, such as 'Florina' and 'Nova Easygro', exhibit a consistent level of resistance to fire blight. In this study, we used an F1 progeny of 'Florina' × 'Nova Easygro' to build parental genetic maps and identify quantitative trait loci (QTLs) related to fire blight resistance. Linkage maps were constructed using a set of microsatellites and enriched with amplified fragment length polymorphism (AFLP) markers. In parallel, progeny plants were artificially inoculated with Erwinia amylovora strain CFBP 1430 in a quarantine glasshouse. Shoot length measured 7 days after inoculation (DAI) and lesion length measured 7 and 14 DAI were used to calculate the lesion length as a percentage of the shoot length (PLL1 and PLL2, respectively). Percent lesion length data were log10-transformed (log10(PLL)) and used to perform the Kruskal-Wallis test, interval mapping (IM), and multiple QTL mapping (MQM). Two significant fire blight resistance QTLs were detected in 'Florina'. One QTL was mapped on linkage group 10 by IM and MQM; it explained 17.9% and 15.3% of the phenotypic variation by MQM with log10(PLL1) and log10(PLL2) data, respectively. A second QTL was identified on linkage group 5 by MQM with log10(PLL2) data; it explained 10.1% of the phenotypic variation. Genotyping the plants of 'Florina' pedigree with the microsatellites flanking the QTLs showed that the QTLs on linkage groups 5 and 10 were inherited from 'Jonathan' and 'Starking' (a 'Red Delicious' sport mutation), respectively. Other putative QTLs (defined as QTLs with LOD scores above the chromosomal threshold and below the genome-wide threshold) were detected by IM on linkage groups 5 and 9 of 'Nova Easygro'.

First Report of Brown Rot Caused by Monilinia fructicola on Apricot in a Swiss Orchard.

Monilinia fructicola (G. Wint.), causal agent of brown rot on stone and pome fruits, is a quarantine pathogen in Europe (EPPO A2 quarantine pest). Since it was first discovered in French orchards in 2001, this pathogen has been officially identified from orchards in Austria (eradicated), Spain, Czech Republic, Italy, and Germany. M. fructicola has also been reported on imported fruit in Hungary and Switzerland (2). Orchard surveys in Switzerland in 2003 and 2005 found no evidence of natural infections (2). From July to August 2008, a large-scale survey of orchards was conducted in the primary apricot- (Prunus armeniaca Linn.) production region of Switzerland (Canton Valais). Apricots showing brown rot symptoms were collected from 57 different orchards at packinghouses (152 samples). In addition, mummies and fresh fruits showing brown rot symptoms were directly collected from three orchards (70 samples). All samples were tested using the PCR-based assay of Côté et al. (3). Ten apricots, originating from an orchard where the samples were directly collected from the trees, tested positive for M. fructicola. These apricots showed brown, sunken lesions covered with grayish pustules. The remaining brown rot samples were identified as M. laxa and M. fructigena. The positive samples were confirmed by the M. fructicola PCR protocols of Hughes et al. (4), following the EPPO diagnostic protocol (1). Eight amplicons obtained with the PCR protocol of Hughes et al. (4) were sequenced, compared with each other, and blasted to the NCBI database. These amplicons were identical to each other and had a 100% match to 16 M. fructicola isolates originating from several countries including the United States, New Zealand, Japan, and China. The unicellular, hyaline, lemon-shaped conidia of three isolates grown at 22°C on PDA averaged 14.4 ± 1.3 µm long and 8.8 ± 0.77 µm wide, therefore fitting the description for M. fructicola (1). Koch's postulates were fulfilled by reproducing brown rot symptoms on mature apricots inoculated with conidia. Six days after inoculation, typical brown rot symptoms appeared on inoculated fruits while control fruits remained healthy. Molecular tests performed with the protocol of Côté et al. (3) and Hughes et al. (4) confirmed the presence of M. fructicola on the inoculated fruits. In 2009, the presence M. fructicola in the orchard where the pathogen was detected in 2008 was verified. One hundred and thirty-seven apricots showing brown rot symptoms were collected and tested (3). M. fructicola was recovered from two samples, indicating the persistence of the pathogen in the orchard. To our knowledge, this is the first report of natural infection of M. fructicola in a Swiss orchard. References: (1) Anonymous. OEPP/EPPO Bull. 33:281, 2003. (2) E. Bosshard et al. Plant Dis. 90:1554, 2006. (3) M.-J. Côté et al. Plant Dis. 88:1219, 2004. (4) K. J. D. Hughes et al. OEPP/EPPO Bull. 30:507, 2000.

Inheritance studies of apple scab resistance and identification of Rvi14, a new major gene that acts together with other broad-spectrum QTL.

Scab, caused by the fungal pathogen Venturia inaequalis, is the most common disease of cultivated apple (Malus xdomestica). The fungal races 6 and 7 have now overcome the major resistance gene Vf, which is widely used in apple breeding programmes. New breeding strategies to achieve durable resistance are thus necessary. The aim of this study was to determine the genetic basis of quantitative resistance of the apple cultivar 'Dülmener Rosenapfel', known to be scab resistant under different environmental conditions. An F1 progeny derived from the cross between the susceptible cultivar 'Gala' and 'Dülmener Rosenapfel' was tested in a greenhouse with a multi-isolate inoculum of V. inaequalis. Rvi14, a new major gene that conditions a chlorotic-type reaction, was mapped on linkage group (LG) 6 in a genomic region not known to be involved in disease resistance. A further three quantitative trait loci (QTL) for resistance were identified. One co-localized with Rvi14 on LG6, whereas the remaining two were detected on LG11 and LG17, in genomic regions already reported to carry broad-spectrum QTL in other genetic backgrounds. Since a selective genotyping approach was used to detect QTL, an expectation-maximization (EM) computation was used to estimate the corrected QTL contributions to phenotypic variation and was validated by entire progeny genotyping.

A new versatile database created for geneticists and breeders to link molecular and phenotypic data in perennial crops: the AppleBreed DataBase.

OBJECTIVE: AppleBreed DataBase (DB) aims to store genotypic and phenotypic data from multiple pedigree verified plant populations (crosses, breeding selections and commercial cultivars) so that they are easily accessible for geneticists and breeders. It will help in elucidating the genetics of economically important traits, in identifying molecular markers associated with agronomic traits, in allele mining and in choosing the best parental cultivars for breeding. It also provides high traceability of data over generations, years and localities. AppleBreed DB could serve as a generic database design for other perennial crops with long economic lifespans, long juvenile periods and clonal propagation. RESULTS: AppleBreed DB is organized as a relational database. The core element is the GENOTYPE entity, which has two sub-classes at the physical level: TREE and DNA-SAMPLE. This approach facilitates all links between plant material, phenotypic and molecular data. The entities TREE, DNA-SAMPLE, PHENOTYPE and MOLECULAR DATA allow multi-annual observations to be stored as individual samples of individual trees, even if the nature of these observations differs greatly (e.g. molecular data on parts of the apple genome, physico-chemical measurements of fruit quality traits, and evaluation of disease resistance). AppleBreed DB also includes synonyms for cultivars and pedigrees. Finally, it can be loaded and explored through the web, and comes with tools to present basic statistical overviews and with validation procedures for phenotypic and marker data to certify data quality. AppleBreed DB was developed initially as a tool for scientists involved in apple genetics within the framework of the European project, 'High-quality Disease Resistance in Apples for Sustainable Agriculture' (HiDRAS), but it is also applicable to many other perennial crops.

Construction of a contig of BAC clones spanning the region of the apple scab avirulence gene AvrVg.

The ascomycete Venturia inaequalis, causal pathogen of apple scab, underlies a gene-for-gene relationship with its host plant apple (Malus spp.). 'Golden Delicious', one of the most common cultivated apples in the world, carries the ephemeral resistance gene Vg. Avirulence gene AvrVg, matching resistance gene Vg has recently been mapped on the V. inaequalis genome. In this paper, we present the construction of a BAC library from a V. inaequalis AvrVg isolate. The library is composed of 7680 clones, with an average insert size of 80kb. By hybridization, it has been estimated that the library contains six haploid genome equivalents. Thus the V. inaequalis genome can be predicted to be approximately 100Mb in size. A chromosome walk, starting from the marker VirQ5 co-segregating with AvrVg, has been performed using the BAC library. Twelve BAC clones were identified during four steps of the chromosome walking. The size of the resulting contig is approximately 330kb.

Genetic mapping of the pear scab resistance gene Vnk of Japanese pear cultivar Kinchaku.

Pear scab (caused by Venturia nashicola) is one of the most harmful diseases of pears, especially Japanese and Chinese pear species. The molecular identification and early selection of resistant plants could greatly improve pear breeding. We have identified the position of the scab resistance gene, designated Vnk in an indigenous Japanese pear cultivar Kinchaku, within the pear genome by using simple sequence repeat (SSR) markers derived from pear and apple. The position of Vnk was identified in the central region of linkage group 1 of Kinchaku. Several amplified fragment length polymorphism (AFLP) markers linked to Vnk were obtained by bulked segregant analysis. Among them, the AFLP marker closest to Vnk was converted into a sequence tagged site (STS) marker. Four random amplified polymorphic DNA (RAPD) markers previously found to be loosely associated with Vnk (Iketani et al. 2001) were successfully converted into STS markers. Six markers (one SSR Hi02c07 and five STSs converted from AFLP and RAPD) showed tight linkages to Vnk, being mapped with distances ranging from 2.4 to 12.4 cM. The SSR CH-Vf2, which was isolated from a BAC clone of the contig containing the apple scab gene Vf, was mapped at the bottom of linkage group 1 in Kinchaku, suggesting that the Vnk and Vf loci are located in different genomic regions of the same homologous linkage group.

Mapping of the apple scab-resistance gene Vb.

Apple scab, caused by the fungus Venturia inaequalis, is the major production constraint in temperate zones with humid springs. Normally, its control relies on frequent and regular fungicide applications. Because this control strategy has come under increasing criticism, major efforts are being directed toward the breeding of scab-resistant apple cultivars. Modern apple breeding programs include the use of molecular markers, making it possible to combine several different scab-resistance genes in 1 apple cultivar (pyramiding) and to speed up the breeding process. The apple scab-resistance gene Vb is derived from the Siberian crab apple 'Hansen's baccata #2', and is 1 of the 6 "historical" major apple scab-resistance genes (Vf, Va, Vr, Vbj, Vm, and Vb). Molecular markers have been published for all these genes, except Vr. In testcross experiments conducted in the 1960s, it was reported that Vb segregated independently from 3 other major resistance genes, including Vf. Recently, however, Vb and Vf have both been mapped on linkage group 1, a result that contrasts with the findings from former testcross experiments. In this study, simple sequence repeat (SSR) markers were used to identify the precise position of Vb in a cross of 'Golden Delicious' (vbvb) and 'Hansen's baccata #2' (Vbvb). A genome scanning approach, a fast method already used to map apple scab-resistance genes Vr2 and Vm, was used, and the Vb locus was identified on linkage group 12, between the SSR markers Hi02d05 and Hi07f01. This finding confirms the independent segregation of Vb from Vf. With the identification of SSR markers linked to Vb, another major apple scab-resistance gene has become available; breeders can use it to develop durable resistant cultivars with several different resistance genes.

Identification by genome scanning approach (GSA) of a microsatellite tightly associated with the apple scab resistance gene Vm.

For all known major apple scab resistance genes except Vr, molecular markers have been published. However, the precise position of some of these genes, in the apple genome, remains to be identified. Knowledge about the relative position of apple scab resistance genes is necessary to preliminarily evaluate the probability of success of their pyramidization. Pyramidization of different resistance genes into the same genotype is a reliable way to create cultivars with durable apple scab resistance. Applying the genome scanning approach (GSA), we identified the linkage group of the scab resistance gene Vm, derived from Malus micromalus, and we found a new molecular marker tightly associated with the gene. The simple sequence repeat Hi07h02, previously mapped on linkage group 17, cosegregates with the Vm gene (no recombinants in the 95 plants tested). The already published sequence-characterized amplified region Vm marker OPB12(687) was found to be linked at about 5 cM from the resistance gene and, therefore, this marker also maps on linkage group 17 of apple. This is the first report of the discovery of a major apple scab resistance gene on linkage group 17. The advantages of using GSA for the identification of molecular markers for qualitative traits are discussed.

Identification of functional apple scab resistance gene promoters.

Apple scab (Venturia inaequalis) is one of the most damaging diseases affecting commercial apple production. Some wild Malus species possess resistance against apple scab. One gene, HcrVf2, from a cluster of three genes derived from the wild apple Malus floribunda clone 821, has recently been shown to confer resistance to apple scab when transferred into a scab-susceptible apple variety. For this proof-of-function experiment, the use of the 35S promoter from Cauliflower mosaic virus was reliable and appropriate. However, in order to reduce the amount of non-plant DNA in genetically modified apple to a minimum, with the aim of increasing genetically modified organism acceptability, these genes would ideally be regulated by their own promoters. In this study, sequences from the promoter region of the three members of the HcrVf gene family were compared. Promoter constructs containing progressive 5' deletions were prepared and used for functional analyses. Qualitative assessment confirmed promoter activity in apple. Quantitative promoter comparison was carried out in tobacco (Nicotiana glutinosa) and led to the identification of several promoter regions with different strengths from a basal level to half the strength of the 35S promoter from Cauliflower mosaic virus.

Development of a High-Throughput Method for Quantification of Plasmopara viticola DNA in Grapevine Leaves by Means of Quantitative Real-Time Polymerase Chain Reaction.

ABSTRACT Plasmopara viticola is a strictly biotrophic oomycete that causes downy mildew, which is one of the most important grapevine diseases. Control of the disease is most often achieved by fungicide applications, which may have severe environmental consequences. Therefore, alternative control strategies based on biocontrol agents (BCAs) are currently in development. Thousands of potential BCAs have to be screened for their antagonist efficacy against Plasmopara viticola. Evaluation of their effect on the pathogen can be achieved by detecting the amount of P. viticola DNA in leaves treated with potential antagonists and infected with the pathogen. In this study, a rapid high-throughput method was developed for relative quantification of P. viticola DNA directly from Vitis vinifera leaves by means of multiplex real-time quantitative polymerase chain reaction (PCR) with TaqMan chemistry. This method allows simultaneous amplification, but independent detection, of pathogen and host DNA by using species-specific primers and TaqMan probes that are labeled with different fluorescent dyes. Including detection of V. vinifera DNA in the tests is fundamental because it provides an endogenous reference and allows normalization for variations caused by sample-to-sample differences in DNA extraction, PCR efficiencies, and pipetting volumes. The developed method allows highly sensitive and specific detection of P. viticola DNA (minimal detectable quantity of 0.1 pg). Moreover, high precision and reproducibility of TaqMan assays were observed over a linear range of four orders of magnitude, confirming the reliability of the developed PCR assay. Potential applications range from screening for BCA efficiency to evaluation of fungicide efficacy, or assessment of host resistance.

Molecular markers linked to the apple scab resistance gene Vbj derived from Malus baccata jackii.

Breeding for scab-resistant apple cultivars by pyramiding several resistance genes in the same genetic background is a promising way to control apple scab caused by the fungus Venturia inaequalis. To achieve this goal, DNA markers linked to the genes of interest are required in order to select seedlings with the desired resistance allele combinations. For several apple scab resistance genes, molecular markers are already available; but until now, none existed for the apple scab resistance gene Vbj originating from the crab apple Malus baccata jackii. Using bulk segregant analysis, three RAPD markers linked to Vbj were first identified. These markers were transformed into more reliable sequence-characterised amplified region (SCAR) markers that proved to be co-dominant. In addition, three SSR markers and one SCAR were identified by comparing homologous linkage groups of existing genetic maps. Discarding plants showing genotype-phenotype incongruence (GPI plants) plants, a linkage map was calculated. Vbj mapped between the markers CH05e03 (SSR) and T6-SCAR, at 0.6 cM from CH05e03 and at 3.9 cM from T6-SCAR. Without the removal of the GPI plants, Vbj was placed 15 cM away from the closest markers. Problems and pitfalls due to GPI plants and the consequences for mapping the resistance gene accurately are discussed. Finally, the usefulness of co-dominant markers for pedigree analysis is also demonstrated.

Vr2: a new apple scab resistance gene.

Reports from several European countries of the breakdown of the Vf resistance, the most frequently used source of resistance in breeding programs against apple scab, emphasize the urgency of diversifying the basis of apple scab resistance and pyramiding different apple scab resistances with the use of their associated molecular markers. GMAL 2473 is an apple scab resistant selection thought to carry the resistance gene Vr. We report the identification by BSA of three AFLP markers and one RAPD marker associated with the GMAL 2473 resistance gene. SSRs associated with the resistance gene were found by (1) identifying the linkage group carrying the apple scab resistance and (2) testing the SSRs previously mapped in the same region. One such SSR, CH02c02a, mapped on linkage group 2, co-segregates with the resistance gene. GAML 2473 was tested with molecular markers associated with other apple scab resistance genes, and accessions carrying known apple scab resistance genes were tested with the SSR linked to the resistance gene found in GMAL 2473. The results indicate that GMAL 2473 does not carry Vr, and that a new apple scab resistance gene, named Vr2, has been identified.

Cloning and linkage mapping of resistance gene homologues in apple.

Apple ( Malus x domestica Borkh.) sequences sharing homology with known resistance genes were cloned using a PCR-based approach with degenerate oligonucleotide primers designed on conserved regions of the nucleotide-binding site (NBS). Sequence analysis of the amplified fragments indicated the presence of at least 27 families of NBS-containing genes in apple, each composed of several very similar or nearly identical sequences. The NBS-leucine-rich repeat homologues appeared to include members of the two major groups that have been described in dicot plants: one possessing a toll-interleukin receptor element and one lacking such a domain. Genetic mapping of the cloned sequences was achieved through the development of CAPS and SSCP markers using a segregating population of a cross between the two apple cultivars Fiesta and Discovery. Several of the apple resistance gene homologues mapped in the vicinity, or at least on the same linkage group, of known loci controlling resistance to various pathogens. The utility of resistance gene-homologue sequences as molecular markers for breeding purposes and for gene cloning is discussed.

Mapping Quantitative Field Resistance Against Apple Scab in a 'Fiesta' x 'Discovery' Progeny.

ABSTRACT Breeding of resistant apple cultivars (Malus x domestica) as a disease management strategy relies on the knowledge and understanding of the underlying genetics. The availability of molecular markers and genetic linkage maps enables the detection and the analysis of major resistance genes as well as of quantitative trait loci (QTL) contributing to the resistance of a genotype. Such a genetic linkage map was constructed, based on a segregating population of the cross between apple cvs. Fiesta (syn. Red Pippin) and Discovery. The progeny was observed for 3 years at three different sites in Switzerland and field resistance against apple scab (Venturia inaequalis) was assessed. Only a weak correlation was detected between leaf scab and fruit scab. A QTL analysis was performed, based on the genetic linkage map consisting of 804 molecular markers and covering all 17 chromosomes of apple. With the maximum likelihood-based interval mapping method, eight genomic regions were identified, six conferring resistance against leaf scab and two conferring fruit scab resistance. Although cv. Discovery showed a much stronger resistance against scab in the field, most QTL identified were attributed to the more susceptible parent 'Fiesta'. This indicated a high degree of homozygosity at the scab resistance loci in 'Discovery', preventing their detection in the progeny due to the lack of segregation.

Apple contains receptor-like genes homologous to the Cladosporium fulvum resistance gene family of tomato with a cluster of genes cosegregating with Vf apple scab resistance.

Scab caused by the fungal pathogen Venturia inaequalis is the most common disease of cultivated apple (Malus x domestica Borkh.). Monogenic resistance against scab is found in some small-fruited wild Malus species and has been used in apple breeding for scab resistance. Vf resistance of Malus floribunda 821 is the most widely used scab resistance source. Because breeding a high-quality cultivar in perennial fruit trees takes dozens of years, cloning disease resistance genes and using them in the transformation of high-quality apple varieties would be advantageous. We report the identification of a cluster of receptor-like genes with homology to the Cladosporium fulvum (Cf) resistance gene family of tomato on bacterial artificial chromosome clones derived from the Vf scab resistance locus. Three members of the cluster were sequenced completely. Similar to the Cf gene family of tomato, the deduced amino acid sequences coded by these genes contain an extracellular leucine-rich repeat domain and a transmembrane domain. The transcription of three members of the cluster was determined by reverse transcriptionpolymerase chain reaction to be constitutive, and the transcription and translation start of one member was verified by 5' rapid amplification of cDNA ends. We discuss the parallels between Cf resistance of tomato and Vf resistance of apple and the possibility that one of the members of the gene cluster is the Vf gene. Cf homologs from other regions of the apple genome also were identified and are likely to present other scab resistance genes.

Construction of a 550 kb BAC contig spanning the genomic region containing the apple scab resistance gene Vf.

A positional cloning project was started in apple with the aim of isolating the Vf resistance gene of Malus floribunda 821. Vf confers resistance against apple scab, the most important disease in apple orchards. A chromosome walk starting from two molecular markers (M18-CAPS and AM19-SCAR) flanking Vf was performed, using a bacterial artificial chromosome (BAC) library containing inserts of the cultivar Florina, which is heterozygous for Vf. Thirteen BAC clones spanning the region between the two markers were identified in nine chromosome walking steps. The size of the resulting contig is approximately 550 kb. In order to map the Vf region in more detail, we analyzed over 2000 plants from different populations segregating for Vf with markers produced from BAC end sequences. In this way, we were able to restrict the possible location of the Vf gene to a minimum of five clones spanning an interval of approximately 350 kb.