Trans-specific <Emphasis Type="Italic">S</Emphasis>-RNase and SFB alleles in <Emphasis Type="Italic">Prunus</Emphasis> self-incompatibility haplotypes

Self-incompatibility in the genus Prunus is controlled by two genes at the S-locus, S-RNase and SFB. Both genes exhibit the high polymorphism and high sequence diversity characteristic of plant self-incompatibility systems. Deduced polypeptide sequences of three myrobalan and three domestic plum S-RNases showed over 97% identity with S-RNases from other Prunus species, including almond, sweet cherry, Japanese apricot and Japanese plum. The second intron, which is generally highly polymorphic between alleles was also remarkably well conserved within these S-allele pairs. Degenerate consensus primers were developed and used to amplify and sequence the co-adapted polymorphic SFB alleles. Sequence comparisons also indicated high degrees of polypeptide sequence identity between three myrobalan and the three domestic plum SFB alleles and the corresponding Prunus SFB alleles. We discuss these trans-specific allele identities in terms of S-allele function, evolution of new allele specificities and Prunus taxonomy and speciation. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

<Emphasis Type="Italic">S</Emphasis> genotyping and <Emphasis Type="Italic">S</Emphasis> screening utilizing <Emphasis Type="Italic">SFB</Emphasis> gene polymorphism in Japanese plum and sweet cherry by dot-blot analysis

Most Rosaceae fruit trees such as Japanese plum and sweet cherry have a gametophytic self-incompatibility (GSI) system controlled by a single S locus containing at least two linked genes with multiple alleles, i.e., S-RNase as a pistil determinant and SFB (S-haplotype-specific F-box gene) as a candidate for the pollen S determinant. For identification of S genotypes, many methods based on polymerase chain reaction (PCR) utilizing polymorphism in length of the S-RNase and SFB gene have been developed. In this study, we developed two dot-blot analysis methods for S-haplotype identification utilizing allele-specific oligonucleotides based on the SFB-HVa region, which has high sequence polymorphism. Dot-blotting of allele-specific oligonucleotides hybridized with digoxigenin-labeled PCR products allowed S genotyping of plants with nine S haplotypes (S-a, S-b, S-c, S-e, S-f, S-h, S-k, S-7 and S-10) in Japanese plum and ten S haplotypes (S-1, S-2, S-3, S-4, S-4′, S-5, S-6, S-7, S-9 and S-16) in sweet cherry (dot-blot-S-genotyping). In addition, dot-blotting of PCR products of SFB probed with the allele-specific oligonucleotides, occasionally utilizing competitive hybridization, was successful in screening for a desirable S haplotype in sweet cherry (dot-blot-S-screening).     

Identification of <Emphasis Type="Italic">S</Emphasis>-haplotype-specific F-box gene in Japanese plum (<Emphasis Type="Italic">Prunus salicina</Emphasis> Lindl.)

Self-incompatibility has been studied extensively at the molecular level in Solanaceae, Rosaceae and Scrophulariaceae, all of which exhibit gametophytic self-incompatibility controlled by a single polymorphic locus containing at least two linked genes, i.e., the S-RNase gene and the pollen-expressed SFB/SLF (S-haplotype-specific F-box/S-locus F-box) gene. However, the SFB gene in Japanese plum (Prunus salicina Lindl.) has not yet been identified. We determined eight novel sequences homologous to the SFB genes of other Prunus species and named these sequences PsSFB. The gene structure of the SFB genes and the characteristic domains in deduced amino acid sequences were conserved. Three sequences from 410 to 2,800 bp of the intergenic region between the PsSFB sequences and the S-RNase alleles were obtained. The eight identified PsSFB sequences showed S-haplotype-specific polymorphism, with 74–83% amino acid identity. These alleles were exclusively expressed in the pollen. These results suggest that the PsSFB alleles are the pollen S-determinants of GSI in Japanese plum. Nucleotide sequence data reported are available in the NCBI database under the accession numbers DQ849084–DQ849090 and DQ849118.     

<Emphasis Type="Italic">Prunus</Emphasis> microsatellite marker transferability across rosaceous crops

A total of 145 microsatellite primer pairs from Prunus DNA sequences were studied for transferability in a set of eight cultivars from nine rosaceous species (almond, peach, apricot, Japanese plum, European plum, cherry, apple, pear, and strawberry), 25 each of almond genomic, peach genomic, peach expressed sequence tags (EST), and Japanese plum genomic, 22 of almond EST, and 23 of apricot (13 EST and 10 genomic), all known to produce single-locus and polymorphic simple-sequence repeats in the species where they were developed. Most primer pairs (83.6%) amplified bands of the expected size range in other Prunus. Transferability, i.e., the proportion of microsatellites that amplified and were polymorphic, was also high in Prunus (63.9%). Almond and Japanese plum were the most variable among the diploid species (all but the hexaploid European plum) and peach the least polymorphic. Thirty-one microsatellites amplified and were polymorphic in all Prunus species studied, 12 of which, covering its whole genome, are proposed as the “universal Prunus set”. In contrast, only 16.3% were transferable in species of other Rosaceae genera (apple, pear, and strawberry). Polymorphic Prunus microsatellites also detected lower levels of variability in the non-congeneric species. No significant differences were detected in transferability and the ability to detect variability between microsatellites of EST and genomic origin.     

Primary structural features of the<Emphasis Type="Italic"> S</Emphasis> haplotype-specific F-box protein,SFB, in<Emphasis Type="Italic"> Prunus</Emphasis>

The gene SFB encodes an F-box protein that has appropriate S-haplotype-specific variation to be the pollen determinant in the S-RNase-based gametophytic self-incompatibility (GSI) reaction in Prunus (Rosaceae). To further characterize Prunus SFB, we cloned and sequenced four additional alleles from sweet cherry (P. avium), SFB ¹ , SFB ² , SFB ⁴ , and SFB ⁵ . These four alleles showed haplotype-specific sequence diversity similar to the other nine SFB alleles that have been cloned. In an amino acid alignment of Prunus SFBs, including the four newly cloned alleles, 121 out of the 384 sites were conserved and an additional 65 sites had only conservative replacements. Amino acid identity among the SFBs ranged from 66.0% to 82.5%. Based on normed variability indices (NVI), 34 of the non-conserved sites were considered to be highly variable. Most of the variable sites were located at the C-terminal region. A window-averaged plot of NVI indicated that there were two variable and two hypervariable regions. These variable and hypervariable regions appeared to be hydrophilic or at least not strongly hydrophobic, which suggests that these regions may be exposed on the surface and function in the allele specificity of the GSI reaction. Evidence of positive selection was detected using maximum likelihood methods with sites under positive selection concentrated in the variable and hypervariable regions.K. Ikeda and B. Igic contributed equally to this paperNucleotide sequence data reported will appear in the EMBL, GenBank and DDBJ nucleotide sequence databases under the accession numbers AB111518, AB111519, AB111520, and AB111521, for SFB ¹, SFB ², SFB ⁵, and SFB ⁴, respectively     

PCR markers for mutated <Emphasis Type="Italic">S</Emphasis>-haplotypes enable discrimination between self-incompatible and self-compatible sour cherry selections

Tetraploid sour cherry (Prunus cerasus L.) exhibits gametophytic self-incompatibility (GSI) whereby the specificity of self-pollen rejection is controlled by alleles of the stylar and pollen specificity genes, the S-RNase and SFB (S haplotype-specific F-box protein gene), respectively. As sour cherry selections can be either self-compatible (SC) or self-incompatible (SI), polyploidy per se does not result in SC. Instead, the genotype dependent loss of SI in sour cherry is due to the accumulation of non-functional S-haplotypes. The presence of two or more non-functional S-haplotypes within sour cherry 2x pollen renders that pollen SC. We previously determined that sour cherry has non-functional S-haplotypes for the S ₁ -, S ₆ - and S ₁₃ -haplotypes that are also present in diploid sweet cherry (P. avium L.). The mutations underlying these non-functional S-haplotypes have been determined to be structural alterations of either the S-RNase or SFB. Based on these structural alterations we designed derived cleaved amplified polymorphic sequence (dCAPS) markers and S-haplotype specific primer pairs that took advantage of either the length polymorphisms between S-haplotypes, differential S-haplotype sequences, or differential restriction enzyme cut sites. These primer pairs can discriminate among the mutant and wild-type S-haplotypes thereby enabling the identification of the S-haplotypes present in a sour cherry individual. This information can be used to determine whether the individual is either SC or SI. In a sour cherry breeding program, the ability to discriminate between SI and SC individuals at the seedling stage so that SI individuals can be discarded prior to field planting, dramatically increases the program’s efficiency and cost-effectiveness.     

Characterization of the <Emphasis Type="Italic">RMja</Emphasis> gene for resistance to root-knot nematodes in almond: spectrum,location, and interest for <Emphasis Type="Italic">Prunus</Emphasis> breeding

In Prunus spp., resistance genes to root-knot nematodes (RKN), Meloidogyne arenaria, Meloidogyne incognita, Meloidogyne javanica, and Meloidogyne floridensis, confer either a complete spectrum, e.g., the Ma and Rjap genes in Myrobalan and Japanese plums (subgenus Prunophora), respectively, or a more restricted spectrum, e.g., the RMia gene (M. arenaria + M. incognita) in peach (subgenus Amygdalus). We report here characterization data of the RMja gene from the almond Alnem1, another Amygdalus source. The study of its spectrum is hampered by the inability of almond to be propagated by cuttings; we overcame this problem by using F1 and BC1 crosses with previously genotyped Myrobalan plums that conferred their rooting ability to hybrids for simultaneous evaluation to different RKN. As expected from a homozygous dominant resistance, BC1 progenies of Alnem1 segregated for resistance to M. javanica but were uniformly susceptible to M. incognita and M. floridensis, demonstrating that RMja controlled M. javanica but not M. incognita nor M. floridensis. SSR markers covering the Prunus reference map placed RMja on LG7 in the same region as Ma and Rjap and thus showed its independence from the RMia gene (LG2) of the botanically closer peach. The spectrum of this gene allows the theoretical construction of interspecific rootstocks, Myrobalan plum × (almond × peach), which cumulate RMja with Ma and RMia and are protected from each of the predominant RKN affecting Prunus, i.e., M. arenaria, M. incognita, and M. javanica, by at least two genes. This pyramiding strategy should offer to rootstock material an unprecedented guarantee of durable RKN resistance.     

Development of SCAR markers linked to self-incompatibility in <Emphasis Type="Italic">Brassica napus</Emphasis> L.

‘SI1300’ is a self-incompatible Brassica napus line generated by introgressing an S haplotype from B. rapa ‘Xishuibai’ into a rapeseed cultivar ‘Huayou No. 1’. Five S-locus specific primer pairs were employed to develop cleaved amplified polymorphic sequences (CAPS) markers linked the S haplotype of ‘SI1300’. Two segregating populations (F₂ and BC₁) from the cross between ‘SI1300’ and self-compatible European spring cultivar ‘Defender’, were generated to verify the molecular markers. CAPS analysis revealed no desirable polymorphism between self-incompatible and self-compatible plants. Twenty primer pairs were designed based on the homology-based candidate gene method, and six dominant sequence characterized amplified region (SCAR) markers linked with the S-locus were developed. Of the six markers, three were derived from the SRK and SP11 alleles of class II B. rapa S haplotypes and linked with S haplotype of ‘SI1300’. The other three markers were designed from the SLG-A10 and co-segregated with S haplotype of ‘Defender’. We successfully combined two pairs of them and characterized two multiplex PCR markers which could discriminate the homozygous and heterozygous genotypes. These markers were further validated in 24 F₃ and 22 BC₁F₂ lines of ‘SI1300 × Defender’ and another two segregating populations from the cross ‘SI1300 × Yu No. 9’. Nucleotide sequences of fragments linked with S-locus of ‘SI1300’ showed 99% identity to B. rapa class II S-60 haplotype, and fragments from ‘Defender’ were 97% and 94% identical to SLG and SRK of B. rapa class I S-47 haplotype, respectively. ‘SI1300’ was considered to carry two class II S haplotypes and the S haplotype on the A-genome derived from B. rapa ‘Xishuibai’ determines the SI phenotype, while ‘Defender’ carry a class I S haplotype derived from B. rapa and a class II S haplotype from B. oleracea. SCAR markers developed in this study will be helpful for improving SI lines and accelerating marker-assisted selection process in rapeseed SI hybrid breeding program.     

Simple and efficient methods for <Emphasis Type="Italic">S</Emphasis> genotyping and <Emphasis Type="Italic">S</Emphasis> screening in genus <Emphasis Type="Italic">Brassica</Emphasis> by dot-blot analysis

In F₁ hybrid breeding of Brassica vegetables utilizing the self-incompatibility system, identification of S genotypes in breeding lines is required. In the present study, we developed S-tester lines of 87 S haplotypes, i.e., 42 S haplotypes in B. rapa and 45 S haplotypes in B. oleracea. With these materials, we established a simple, efficient, and reliable dot-blot technique for S genotyping for 40 S haplotypes of B. rapa and and 33 of B. oleracea using allele-specific oligonucleotide probes and allele-specific primer pairs designed from sequences of each SP11 allele. In this method, DNA fragments amplified using multiplex primer pairs with digoxigenin-dUTP were hybridized with dot-blotted allele-specific oligonucleotide probes with distinct signals. In addition, we developed a screening method for identification of plants harboring a particular S haplotype using a labeled allele-specific oligonucleotide probe. This method is considered to be useful for purity testing of F₁ hybrid seeds.     

Genetic structure of <Emphasis Type="Italic">Varroa destructor</Emphasis> populations infesting <Emphasis Type="Italic">Apis mellifera</Emphasis> colonies in Argentina

Although mitochondrial DNA mapping of Varroa destructor revealed the presence of several haplotypes, only two of them (Korean and Japanese haplotypes) were capable to infest Apis mellifera populations. Even though the Korean haplotype is the only one that has been reported in Argentina, these conclusions were based on mites sampled in apiaries from a specific geographical place (Buenos Aires province). To study mites from several sites of Argentina could reveal the presence of the Japanese genotype, especially considering sites near to Brazil, where Japanese haplotype was already detected. The aim of this work was to study the genetic structure of V. destructor populations from apiaries located in various provinces of Argentina, in order to determine the presence of different haplotypes. The study was carried out between January 2006 and December 2009. Phoretic adult Varroa mites were collected from honey bee workers sampled from colonies of A. mellifera located in Entre Ríos, Buenos Aires, Corrientes, Río Negro, Santa Cruz and Neuquén provinces. Twenty female mites from each sampling site were used to carry out the genetic analysis. For DNA extraction a nondestructive method was used. DNA sequences were compared to Korean haplotype (AF106899) and Japanese haplotype (AF106897). All DNA sequences obtained from mite populations sampled in Argentina, share 98% of similitude with Korean Haplotype (AF106899). Taking into account these results, we are able to conclude that Korean haplotype is cosmopolite in Argentina.     

<Emphasis Type="Italic">S</Emphasis> locus-linked F-box genes expressed in anthers of <Emphasis Type="Italic">Hordeum bulbosum</Emphasis>

Diploid Hordeum bulbosum (a wild relative of cultivated barley) exhibits a two-locus self-incompatibility (SI) system gametophytically controlled by the unlinked multiallelic loci S and Z. This unique SI system is observed in the grasses (Poaceae) including the tribe Triticeae. This paper describes the identification and characterization of two F-box genes cosegregating with the S locus in H. bulbosum, named Hordeum S locus-linked F-box 1 (HSLF1) and HSLF2, which were derived from an S ₃ haplotype-specific clone (HAS175) obtained by previous AMF (AFLP-based mRNA fingerprinting) analysis. Sequence analysis showed that both genes encode similar F-box proteins with a C-terminal leucine-rich repeat (LRR) domain, which are distinct from S locus (or S haplotype-specific) F-box protein (SLF/SFB), a class of F-box proteins identified as the pollen S determinant in S-RNase-based gametophytic SI systems. A number of homologous F-box genes with an LRR domain were found in the rice genome, although the functions of the gene family are unknown. One allele of the HSLF1 gene (HSLF1-S ₃) was expressed specifically in mature anthers, whereas no expression was detected from the other two alleles examined. Although the degree of sequence polymorphism among the three HSLF1 alleles was low, a frameshift mutation was found in one of the unexpressed alleles. The HSLF2 gene showed a low level of expression with no tissue specificity as well as little sequence polymorphism among the three alleles. The multiplicity of S locus-linked F-box genes is discussed in comparison with those found in the S-RNase-based SI system. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Nucleotide sequence data reported are available in the DDBJ/EMBL/GenBank databases under the accession numbers AB511822–AB511825 and AB511859–AB511862.     

Haplotypes of <Emphasis Type="Italic">Fallopia</Emphasis> introduced into the US

In the US, clonal growth of Fallopia japonica, Fallopia sachalinensis and their hybrid Fallopia x bohemica (Polygonaceae) is prominent, yet sexual reproduction and hybridization contribute to the genetic complexity of swarms. The contribution to this diversity from multiple introductions is unknown. Using 800 bp of the non-coding chloroplast marker accD–rbcL, we compared 21 Japanese haplotypes with 46 US samples from 11 states, 2 Canadian samples, and 6 European samples from 4 countries, in order to investigate if there were repeated introductions from Asia. While most North American and all European haplotypes accessions in our collection matched a single widespread haplotype, we identified 8 other haplotypes. Three haplotypes of F. japonica (including the widespread haplotype) and one F. sachalinensis matched previously identified Japanese haplotypes, supporting the hypothesis of multiple introductions in the US. Five additional US haplotypes were detected once. Four of these differed from Japanese haplotypes by one single nucleotide polymorphism (SNP), possibly indicating a recent in situ change. The fifth haplotype represents a garden cultivar, which differed from all F. japonica haplotypes. It therefore appears that the US genetic diversity of these taxa has three sources: intra-specific reproduction, inter-specific reproduction, and multiple sources of introduction.     

Structural and molecular analysis of self-incompatibility in almond (<Emphasis Type="Italic">Prunus dulcis</Emphasis>)

. A multi-approach was used to study different aspects of self-incompatibility (SI) in almond (Prunus dulcis). First, a population of almond cultivars was characterised as to their individual S-allele combination using separation of stylar protein extracts (non-equilibrium pH gradient electrofocusing) followed by staining for RNase activity, which led to the identification of one putative new allele and several new S-allele combinations. Second, a field pollination scheme was designed to study pollen tube progression and to obtain a spatial and temporal characterisation of this reproductive stage in both incompatible and compatible crosses. In addition, an anti-serum was raised against a synthetic peptide designed from an almond S-protein (S₈) and used for immunological in situ detection in pistil cryosections. S-RNases were found to accumulate intercellularly in the stylar transmitting tissue as previously reported for other rosaceous species. The results are discussed in view of the evolution of the gametophytic SI system and the models proposed for its mechanism. Gametophyte selection is also proposed as an important intraspecific barrier to fertilisation in this species.     

Micropropagation of ornamental <Emphasis Type="Italic">Prunus</Emphasis> spp. and GF305 peach,a <Emphasis Type="Italic">Prunus</Emphasis> viral indicator

A micropropagation approach was developed for nine ornamental Prunus species, P. americana, P. cistena, P. glandulosa, P. serrulata ‘Kwanzan’, P. laurocerasus, P. sargentii, P. tomentosa, P. triloba, P. virginiana ‘Schubert’, commercially important in North America, and GF305 peach, commonly used for Prunus virus indexing. The micropropagation cycle based on proliferation of vegetative tissues includes establishment of tissue culture through introduction of shoot meristems in vitro, shoot proliferation, root induction and plant acclimatization steps and can be completed in 5 months. A meristem sterilization protocol minimized bacterial and fungal contamination. Multiple shoot formation in ornamental Prunus was obtained through the use of 1 mg l⁻¹ 6-benzyladenine. For GF305 peach, alteration in the sugar composition, fructose instead of sucrose, and addition of 1 mg l⁻¹ ferulic acid had a significant impact on the shoot proliferation rate and maintenance of long-term in vitro culture. Rooting and plant acclimatization conditions were improved using a two-step protocol with a 4-day root induction in indole-3-butiric acid (IBA)-containing media with consequent 3-week root elongation in IBA-free media. One-month incubation of rooted shoots in a vermiculite-based medium resulted in additional shoot and root growth and provided better acclimatization and plant recovery. The micropropagation approach can be used for maintenance of the clonal properties for Prunus spp. as well as a protocol to support meristem therapy against viral infection.     

Nucleotide sequence analysis of <Emphasis Type="Italic">S</Emphasis>-locus genes to unify <Emphasis Type="Italic">S</Emphasis> haplotype nomenclature in radish

Radish, belonging to the family Brassicaceae, has a self-incompatibility which is controlled by multiple alleles on the S locus. To employ the self-incompatibility in an F₁ breeding system, identification of S haplotypes is necessary. Since collection of S haplotypes and determination of nucleotide sequences of SLG, SRK, and SCR alleles in cultivated radish have been conducted by different groups independently, the same or similar sequences with different S haplotype names and different sequences with the same S haplotype names have been registered in public databases, resulting in confusion of S haplotype names for researchers and breeders. In the present study, we developed S homozygous lines from radish F₁ hybrid cultivars in Japan and determined the nucleotide sequences of SCR, the S domain and the kinase domain of SRK, and the SLG of a large number of S haplotypes. Comparing these sequences with our previously published sequences, the haplotypes were ordered into 23 different S haplotypes. The sequences of the 23 S haplotypes were compared with S haplotype sequences registered by different groups, and we suggested a unification of these S haplotypes. Furthermore, dot-blot hybridization using SRK allele-specific probes was examined for developing a standard method for S haplotype identification.     

Physical size of the <Emphasis Type="Italic">S</Emphasis> locus region defined by genetic recombination and genome sequencing in <Emphasis Type="Italic">Ipomoea trifida</Emphasis>, Convolvulaceae

Sporophytic self-incompatibility (SSI) in the genus Ipomoea (Convolvulaceae) is controlled by a single polymorphic S locus. We have previously analyzed genomic sequences of an approximately 300 kb region spanning the S locus of the S ₁ haplotype and characterized the genomic structure around this locus. Here, we further define the physical size of the S locus region by mapping recombination breakpoints, based on sequence analysis of PCR fragments amplified from the genomic DNA of recombinants. From the recombination analysis, the S locus of the S ₁ haplotype was delimited to a 0.23 cM region of the linkage map, which corresponds to a maximum physical size of 212 kb. To analyze differences in genomic organization between S haplotypes, fosmid contigs spanning approximately 67 kb of the S ₁₀ haplotype were sequenced. Comparison with the S ₁ genomic sequence revealed that the S haplotype-specific divergent regions (SDRs) spanned 50.7 and 34.5 kb in the S ₁ and S ₁₀ haplotypes, respectively and that their flanking regions showed a high sequence similarity. In the sequenced region of the S ₁₀ haplotype, five of the 12 predicted open reading frames (ORFs) were found to be located in the divergent region and showed co-linear organization of genes between the two S haplotypes. Based on the size of the SDRs, the physical size of the S locus was estimated to fall within the range 34–50 kb in Ipomoea.     

Genetic features of a pollen-part mutation suggest an inhibitory role for the <Emphasis Type="Italic">Antirrhinum</Emphasis> pollen self-incompatibility determinant

Self-incompatibility (SI), an important barrier to inbreeding in flowering plants, is controlled in many species by a single polymorphic S-locus. In the Solanaceae, two tightly linked S-locus genes, S-RNase and SLF (S-locus F-box)/SFB (S-haplotype-specific F-box), control SI expression in pistil and pollen, respectively. The pollen S-determinant appears to function to inhibit all but self S-RNase in the Solanaceae, but its genetic function in the closely-related Plantaginaceae remains equivocal. We have employed transposon mutagenesis in a member of the Plantaginaceae (Antirrhinum) to generate a pollen-part SI-breakdown mutant Pma1 (Pollen-part mutation in Antirrhinum1). Molecular genetic analyses showed that an extra telocentric chromosome containing AhSLF-S ₁ is present in its self-compatible but not in its SI progeny. Furthermore, analysis of the effects of selection revealed positive selection acting on both SLFs and SFBs, but with a stronger purifying selection on SLFs. Taken together, our results suggest an inhibitor role of the pollen S in the Plantaginaceae (as represented by Antirrhinum), similar to that found in the Solanaceae. The implication of these findings is discussed in the context of S-locus evolution in flowering plants. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Yongbiao Xue, Yijing Zhang, and Qiuying Yang contributed equally to this work.     

Isolation and <Emphasis Type="Italic">S</Emphasis>-genotyping application of <Emphasis Type="Italic">S</Emphasis>-allelic polymorphic <Emphasis Type="Italic">MdSLFB</Emphasis>s in apple (<Emphasis Type="Italic">Malus domestica</Emphasis> Borkh.)

Apple (Malus domestica Borkh.) possesses gametophytic self-incompatibility (GSI) which is controlled by S-RNase in the pistil as well as a pollen S-determinant that has not been well characterized. The identification of S-locus F-box brother (SFBB) genes, which are good candidates for the pollen S-determinant in apple and pear, indicated the presence of multiple S-allelic polymorphic F-box genes at the S-locus. In apple, two SFBB gene groups have been described, while there are at least three groups in pear. In this report, we identified five MdSLFB (S-RNase-linked F-box) genes from four different S-genotypes of apple. These genes showed pollen- and S-allele-specific expression with a high polymorphism among S-alleles. The phylogenetic tree suggested that some of them belong to SFBBα or β groups as described previously, while others appear to be different from SFBBs. In particular, the presence of MdSLFB3 and MdSLFB9 suggested that there are more S-allelic polymorphic F-box gene groups in the S-locus besides α and β. Based on the sequence polymorphism of MdSLFBs, we developed an S-genotyping system for apple cultivars. In addition, we isolated twelve MdSLFB-like genes, which showed pollen-specific expression without S-allelic polymorphism.     

A major locus for resistance to <Emphasis Type="Italic">Botryosphaeria dothidea</Emphasis> in <Emphasis Type="Italic">Prunus</Emphasis>

Species in the fungal family Botryosphaeriaceae are significant pathogens of peach. The climatic conditions in the Southeastern USA are conducive to the development of peach fungal gummosis (PFG) with an estimated yield reduction of up to 40% in severe cases. Genotypes with resistance to this PFG were identified in interspecific crosses and segregating backcross populations generated using Kansu peach (Prunus kansuensis Rehder), almond [Prunus dulcis (Mill.) D.A. Webb], and peach [Prunus persica (L.) Batsch]. Hybrids were evaluated for four consecutive years in field conditions. Data generated was validated in different environments using clonal replicates of the hybrids. The F₁ and BC₁F₁ segregation population data suggest a dominant allele for PFG resistance originating from almond. Segregation and mapping analysis located the PFG resistance locus on a chimeric linkage groups 6–8 near the leaf color locus. The molecular markers identified will facilitate marker-assisted selection (MAS) and introgression of this resistance trait into commercial peach germplasm.