Protein expression of a self-compatible allele from Lycopersicon peruvianum: introgression and behavior in a self-incompatible background

Lycopersicon peruvianum (wild tomato) is a gametophytic self-incompatible (SI) species. One natural population has been shown to harbor a self-compatible (SC) allele. A stylar protein associated with the self-compatibility allele has been elucidated using SDS-PAGE. The temporal and spatial expression of this protein is presented and compared with protein expression of two SI alleles. Hybrids containing the SC and SI alleles were used in a backcrossing program to introgress the SC allele into SI backgrounds in six independent lines. Controlled pollinations and SDS-PAGE were used to identify and select classes of progeny. After four backcross generations (approximately 97% recovery of the SI backgrounds) the SC allele still confers self-fertility in lines that contain this allele, providing evidence that the mutation to SC occurred at the S-locus and that the associated protein is likely responsible.     

Self-incompatibility is codominant in intraspecific hybrids of self-compatible and self-incompatible Lycopersicon peruvianum and L. hirsutum based on protein and DNA marker analysis

Self-compatibility was investigated separately in two species of tomato, Lycopersicon peruvianum and L. hirsutum. The codominant expression of self-compatibility (SC)/self incompatibility (SI) was established using intraspecific hybrids of SC and SI hybrids. In SC L. peruvianum, a major stylar protein of approximately 29 kDa cosegregates with self-compatibility in the progeny of SC/SI hybrids. The SC/SI hybrids are self-fertile, but only partially so, since the SI allele present in the hybrids is capable of eliminating certain genotypes in the resultant progeny. In L. hirsutum, the majority of hybrids between one accession of SI L. hirsutum f. hirsutum and one of SC L. hirsutum f. glabratum are self-fertile. Analysis of the progeny revealed that the SC and SI alleles are codominant in this species as well. A protein product for the SC allele is not obvious in style extracts of L. hirsutum f. glabratum. Segregating progeny from SC/SI hybrids of L. hirsutum were used to map the S locus against five RFLP markers on chromosome 1, and estimated map distances are given. In addition, evidence is presented that indicates that one of the DNA markers, CD15, is duplicated in L. hirsutum f. glabratum, and the duplication is not linked to the S locus.     

Genetic relatedness of Portuguese almond cultivars assessed by RAPD and ISSR markers

Randomly amplified polymorphic DNA (RAPD) and inter-simple sequence repeat (ISSR) markers were used to analyse the genetic diversity of Portuguese Prunus dulcis cultivars and their relationship to important foreign cultivars. Of the primers tested, 6 (out of 60) RAPD and 5 (out of 18) ISSR primers were selected for their reproducibility and high polymorphism. Out of 124 polymerase chain reaction fragments that were scored, 120 (96.8%) were polymorphic. All the plants could be discriminated and constitute a very heterogeneous group. Five unidentified almond plants found in the region of Foz Côa (north Portugal) and wild almond (P. webbii) from Italy and Spain were also included. Four main groups of plants could be distinguished: P. dulcis cultivars; one Foz Côa plant; P. webbii; and P. persica (outgroup). The segregating Foz Côa plant may represent a feral individual or a hybrid between P. dulcis and P. webbii.Abbreviations dNTP Deoxynucleotide triphosphate - CTAB Cetyltrimethylammonium bromide - ISSR Inter-simple sequence repeats - PCR Polymerase chain reaction - RAPD Randomly amplified polymorphic DNA - RASTM Regional Agricultural Services of Trás-os-Montes - TE Tris-EDTA buffer - UPGMA Unweighted pair group method with arithmetical averagesCommunicated by P. Puigdoménech     

A modifier locus affecting the expression of the S-RNase gene could be the cause of breakdown of self-incompatibility in almond

Self-compatibility has become the primary objective of most almond (Prunus amygdalus Batsch) breeding programmes in order to avoid the problems related to the gametophytic self-incompatibility system present in almond. The progeny of the cross ‘Vivot’ (S ₂₃ S _fa) × ‘Blanquerna’ (S ₈ S _fi) was studied because both cultivars share the same S _f allele but have a different phenotypic expression: active (S _fa) in ‘Vivot’ and inactive (S _fi) in ‘Blanquerna’. In addition, the microscopic observation of pollen tube growth after self-pollination over several years showed an unexpected self-incompatible behaviour in most seedlings of this cross. The genotypes of this progeny showed that the S _fi pollen from ‘Blanquerna’ was not able to grow down the pistils of ‘Vivot’ harbouring the S _fa allele, confirming the active function of this allele against the inactive form of the same allele, S _fi. As self-compatibility was observed in some S ₈ S ₂₃ and S ₈ S _fa individuals of this progeny, the S _f haplotype may not always be linked to the expression and transmission of self-compatibility in almond, suggesting that a modifier locus may be involved in the mechanism of self-incompatibility in plants.     

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.     

Allele-specific PCR detection of sweet cherry self-incompatibility (S) alleles S1 to S16 using consensus and allele-specific primers

PCR-based identification of all 13 known self-incompatibility (S) alleles of sweet cherry is reported. Two pairs of consensus primers were designed from our previously published cDNA sequences of S₁ to S₆ S-RNases, the stylar components of self-incompatibility, to reveal length variation of the first and the second introns. With the exception of the first intron of S₁₃, these also amplified S₇ to S₁₄ and an allele previously referred to as S_x, which we now label S₁₆. The genomic PCR products were cloned and sequenced. The partial sequence of S₁₁ matched that of S₇ and the alleles were shown to have the same functional specificity. Allele-specific primers were designed for S₇ to S₁₆, so that allele-specific primers are now available for all 13 S alleles of cherry (S₈, S₁₁ and S₁₅ are duplicates). These can be used to distinguish between S alleles with introns of similar size and to confirm genotypes determined with consensus primers. The reliability of the PCR with allele-specific primers was improved by the inclusion of an internal control. The use of the consensus and allele-specific primers was demonstrated by resolving conflicting genotypes that have been published recently and by determining genotypes of 18 new cherry cultivars. Two new groups are proposed, Group XXIII (S₃S₁₆), comprising 'Rodmersham Seedling' and 'Strawberry Heart', and Group XXIV (S₆S₁₂), comprising 'Aida' and 'Flamentiner'. Four new self-compatibility genotypes, S₃S₃, S₄S₆, S₄S₉ and S₄S₁₃, were found. The potential use of the consensus primers to reveal incompatibility alleles in other cherry species is also demonstrated.Communicated by H.F. Linskens     

Inheritance and interactions of incompatibility alleles in the tetraploid sour cherry

Three progenies of sour cherry (Prunus cerasus) were analysed to correlate self-(in)compatibility status with S-RNase phenotype in this allotetraploid hybrid of sweet and ground cherry. Self-(in)compatibility was assessed in the field and by monitoring pollen tube growth after selfing. The S-RNase phenotypes were determined by isoelectric focusing of stylar proteins and staining for RNase activity and, for the parents, confirmed by PCR. Seedling phenotypes were generally consistent with disomic segregation of S-RNase alleles. The genetic arrangements of the parents were deduced to be ‘Köröser’ (self-incompatible) S ₁ S ₄ .S _B S _D , ‘Schattenmorelle’ (self-compatible) S ₆ S ₁₃ .S _B S _B , and clone 43.87 (self-compatible) S ₄ S ₁₃ .S _B S _B , where “.” separates the two homoeologous genomes. The presence of S ₄ and S ₆ alleles at the same locus led to self-incompatibility, whereas S ₁₃ and S _B at homoeologous loci led to self-compatibility. The failure of certain heteroallelic genotypes in the three crosses or in the self-incompatible seedlings indicates that S ₄ and S ₆ are dominant to S _B . However, the success of S ₁₃ S _B pollen on styles expressing corresponding S-RNases indicates competitive interaction or lack of pollen-S components. In general, the universal compatibility of S ₁₃ S _B pollen may explain the frequent occurrence of S ₁₃ and S _B together in sour cherry cultivars. Alleles S _B and S _D , that are presumed to derive from ground cherry, and S ₁₃ , presumably from sweet cherry, were sequenced. Our findings contribute to an understanding of inheritance of self-(in)compatibility, facilitate screening of progenies for self-compatibility and provide a basis for studying molecular interactions in heteroallelic pollen.     

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.     

Genomic characterization of self-incompatibility ribonucleases (S-RNases) in European pear cultivars and development of PCR detection for 20 alleles

Sexual self-incompatibility in European pear (Pyrus communis L.) is controlled by a single locus (S-locus) encoding a polymorphic stylar ribonuclease (S-RNase) that is responsible for the female function in pollen–pistil recognition. In this study, genomic DNA sequences corresponding to five new S-RNase alleles (named S ₂₀ , S ₂₁ , S ₂₂ , S ₂₃ , and S ₂₄ ) and to S _m were characterized in European pear cultivars. Re-sequencing S _q from ‘General Le Clerc’ showed this S-RNase to encode the same protein as S ₁₂ . Based on these findings, a polymerase chain reaction (PCR)-based method was developed for the molecular typing of cultivars bearing 20 S-RNases (S ₁ –S ₁₄ , S _m , and S ₂₀ –S ₂₄ ) using consensus and allele-specific primers. Genomic PCR with consensus primers amplified product sizes characteristic of the S-RNases S ₁ , S ₂ , S ₄ , S ₁₀ , S ₁₃ , and S ₂₀ . However, the allele groups S ₃ /S ₁₂ , S ₆ /S ₈ /S ₁₁ /S ₂₂ and S ₅ /S ₇ /S ₉ /S ₁₄ /S _m /S ₂₁ /S ₂₃ /S ₂₄ amplified PCR products of similar size. To discriminate between alleles within these groups, primers to specifically amplify each S-RNase were developed. Application of this approach in 19 cultivars with published S-alleles allowed re-evaluation of one of the alleles of ‘Passe Crassane,’ ‘Conference,’ and ‘Condo.’ Finally, this method was used to assign S-genotypes to 37 cultivars. Test crosses confirmed molecular results. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

S-related protein can be recombined with self-compatibility in interspecific derivatives ofLycopersicon

Stylar proteins involved in the self-incompatible (SI) response ofLycopersicon hirsutum have been identified and mapped to the locus that controls SI (S locus).L. esculentum, a self-compatible (SC) species of cultivated tomato, does not display these proteins. Hybrids between SCL. esculentum and SIL. hirsutum are self-sterile despite these individuals bearing pollen containing theS allele ofL. esculentum. In progeny derived from backcrossing the hybrids toL. esculentum, there was a strong correlation between the presence of theS allele fromL. hirsutum and self-infertility. However, this relationship was uncoupled in a number of backcross (BC) progeny. The SI response appeared to be nonexistent in two self-fertile BC individuals that were heterozygous for theS allele ofL. hirsutum, based on Mendelian segregation of a tightly linked DNA marker,CD15, in selfed progeny. Among these progeny self-fertile individuals that were homozygous for theL. hirsutum allele of the linked marker were also determined to be homozygous for anS-related protein ofL. hirsutum through test crosses withL. esculentum. Therefore, plants were produced that were homozygous for a functionalS allele but were self-fertile. This result and other evidence suggest that theS-related proteins are not sufficient to elicit a self-incompatible response inL. esculentum and that there is a mutation(s) inL. esculentum somewhere other than theS locus that leads to self-compatibility.     

Pistil-function breakdown in a new <Emphasis Type="Italic">S</Emphasis>-allele of European pear, <Emphasis Type="Italic">S</Emphasis><Subscript><Emphasis Type="Italic">21</Emphasis></Subscript>°, confers self-compatibility

European pear exhibits RNase-based gametophytic self-incompatibility controlled by the polymorphic S-locus. S-allele diversity of cultivars has been extensively investigated; however, no mutant alleles conferring self-compatibility have been reported. In this study, two European pear cultivars, ‘Abugo’ and ‘Ceremeño’, were classified as self-compatible after fruit/seed setting and pollen tube growth examination. S-genotyping through S-PCR and sequencing identified a new S-RNase allele in the two cultivars, with identical deduced amino acid sequence as S ₂₁ , but differing at the nucleotide level. Test-pollinations and analysis of descendants suggested that the new allele is a self-compatible pistil-mutated variant of S ₂₁ , so it was named S ₂₁ °. S-genotypes assigned to ‘Abugo’ and ‘Ceremeño’ were S ₁₀ S ₂₁ ° and S ₂₁ °S ₂₅ respectively, of which S ₂₅ is a new functional S-allele of European pear. Reciprocal crosses between cultivars bearing S ₂₁ and S ₂₁ ° indicated that both alleles exhibit the same pollen function; however, cultivars bearing S ₂₁ ° had impaired pistil-S function as they failed to reject either S ₂₁ or S ₂₁ ° pollen. RT-PCR analysis showed absence of S ₂₁ °-RNase gene expression in styles of ‘Abugo’ and ‘Ceremeño’, suggesting a possible origin for S ₂₁ ° pistil dysfunction. Two polymorphisms found within the S-RNase genomic region (a retrotransposon insertion within the intron of S ₂₁ ° and indels at the 3′UTR) might explain the different pattern of expression between S ₂₁ and S ₂₁ °. Evaluation of cultivars with unknown S-genotype identified another cultivar ‘Azucar Verde’ bearing S ₂₁ °, and pollen tube growth examination confirmed self-compatibility for this cultivar as well. This is the first report of a mutated S-allele conferring self-compatibility in European pear.     

Analysis of S-RNase alleles of almond (Prunus dulcis): characterization of new sequences, resolution of synonyms and evidence of intragenic recombination

Cross-compatibility relationships in almond are controlled by a gametophytically expressed incompatibility system partly mediated by stylar RNases, of which 29 have been reported. To resolve possible synonyms and to provide data for phylogenetic analysis, 21 almond S-RNase alleles were cloned and sequenced from SP (signal peptide region) or C1 (first conserved region) to C5, except for the S ₂₉ allele, which could be cloned only from SP to C1. Nineteen sequences (S ₄ , S ₆ , S ₁₁ –S ₂₂ , S ₂₅ –S ₂₉ ) were potentially new whereas S ₁₀ and S ₂₄ had previously been published but with different labels. The sequences for S ₁₆ and S ₁₇ were identical to that for S ₁ , published previously; likewise, S ₁₅ was identical to S ₅ . In addition, S ₄ and S ₂₀ were identical, as were S ₁₃ and S ₁₉ . A revised version of the standard table of almond incompatibility genotypes is presented. Several alleles had AT or GA tandem repeats in their introns. Sequences of the 23 distinct newly cloned or already published alleles were aligned. Sliding windows analysis of Ka/Ks identified regions where positive selection may operate; in contrast to the Maloideae, most of the region from the beginning of C3 to the beginning of RC4 appeared not to be under positive selection. Phylogenetic analysis indicated four pairs of alleles had ‘bootstrap’ support > 80%: S ₅ /S ₁₀ , S ₄ /S _8, S ₁₁ /S ₂₄ , and S ₃ /S ₆ . Various motifs up to 19 residues long occurred in at least two alleles, and their distributions were consistent with intragenic recombination, as were separate phylogenetic analyses of the 5′ and 3′ sections. Sequence comparison of phylogenetically related alleles indicated the significance of the region between RC4 and C5 in defining specificity.An erratum to this article can be found at     

Origin and dissemination of the pollen-part mutated SC haplotype which confers self-compatibility in apricot (Prunus armeniaca)

In China, its centre of origin, apricot (Prunus armeniaca) is self-incompatible. However, most European cultivars are self-compatible. In most cases, self-compatibility is a result of a loss-of-function mutation within the pollen gene (SFB) in the SC haplotype. Controlled pollinations performed in this work revealed that the cross 'Ceglédi óriás' (S8S9)x'Ceglédi arany' (SCS9) set well, as expected, but the reciprocal cross did not. Apricot S8, S9 and SC haplotypes were analysed using a multilevel approach including fruit set evaluation, pollen tube growth analysis, RNase activity assays, polymerase chain reaction (PCR) analysis and DNA sequencing of the S-RNase and SFB alleles. SFB8 was revealed to be the first known progenitor allele of a naturally occurring self-compatibility allele in Prunus, and consequently SC=The first intron of SC-RNase is a phase one intron, indicating its more recent evolutionary origin compared with the second intron. Sequence analysis of different cultivars revealed that more single nucleotide polymorphisms accumulated in SC-RNase than in SFBC. New methods were designed to allow high-throughput analysis of S genotypes of apricot cultivars and selections. S-RNase sequence data from various sources helped to elucidate the putative origin and dissemination of self-compatibility in apricot conferred by the SC haplotype.     

Cloning and characterization of genomic DNA sequences of four self-incompatibility alleles in sweet cherry (<Emphasis Type="Italic">Prunus avium</Emphasis> L.)

Gametophytic self-incompatibility (GSI) in sweet cherry is determined by a locus S with multiple alleles. In the style, the S-locus codifies for an allele-specific ribonuclease (S-RNase) that is involved in the rejection of pollen that carries the same S allele. In this work we report the cloning and genomic DNA sequence analysis including the 5 flanking regions of four S-RNases of sweet cherry (Prunus avium L., Rosaceae). DNA from the cultivars Ferrovia, Pico Colorado, Taleguera Brillante and Vittoria was amplified through PCR using primers designed in the conserved sequences of sweet cherry S-RNases. Two alleles were amplified for each cultivar and three of them correspond to three new S-alleles named S ₂₃ , S ₂₄ and S ₂₅ present in 'Pico Colorado', 'Vittoria' and 'Taleguera Brillante' respectively. To confirm the identity of the amplified fragments, the genomic DNA of these three putative S-RNases and the allele S ₁₂ amplified in the cultivar Ferrovia were cloned and sequenced. The nucleotide and deduced amino-acid sequences obtained contained the structural features of rosaceous S-RNases. The isolation of the 5-flanking sequences of these four S-RNases revealed a conserved putative TATA box and high similarity among them downstream from that sequence. However, similarity was low compared with the 5-flanking regions of S-RNases from the Maloideae. S ₆ - and S ₂₄ -RNase sequences are highly similar, and most amino-acid substitutions among these two RNases occur outside the rosaceous hypervariable region (RHV), but within another highly variable region. The confirmation of the different specificity of these two S-RNases would help elucidate which regions of the S-RNase sequences play a role in S-pollen specific recognition.Communicated by H.F. Linskens     

Sequence variability and gene structure at the self-incompatibility locus of Solanum tuberosum

Summary Allelic complexity is a key feature of self-incompatibility (S) loci in gametophytic plants. We describe in this report the allelic diversity and gene structure of the S locus in Solanum tuberosum revealed by the isolation and characterization of genomic and cDNA clones encoding S-associated major pistil proteins from three alleles (S ₁, S _r1, S ₂). Genomic clones encoding the S₁ and S₂ proteins provide evidence for a simple gene structure: Two exons are separated by a small intron of 113 (S ₁) and 117 by (S ₂). Protein sequences deduced from cDNA clones encoding S₁ and S_r1 proteins show 95% homology. 15 of the 25 residues that differ between these S ₁and S _r1alleles are clustered in a short hypervariable protein segment (amino acid positions 44–68), which corresponds in the genomic clones to DNA sequences flanking the single intron. In contrast, these alleles are only 66% homologous to the S ₂allele, with the residues that differ between the alleles being scattered throughout the sequence. DNA crosshybridization experiments identify a minimum of three classes of potato S alleles: one class contains the alleles S ₁, S _r1and S ₃, the second class S ₂and an allele of the cultivar Roxy, and the third class contains at present only S ₄. It is proposed that these classes reflect the origin of the S alleles from a few ancestral S sequence types.     

Identification of new S-RNase self-incompatibility alleles and characterization of natural mutations in Iranian almond cultivars

The two main objectives of this research were to identify new S-RNase alleles in Iranian almond cultivars and to characterize naturally occurring mutations in these alleles that may cause self-compatibility. We investigated S genotypes of 22 Iranian almond cultivars using stylar RNase electrophoresis, PCR and DNA sequencing. We report six previously unidentified P. dulcis S-RNase alleles (S ₄₅ , S ₄₆ , S ₄₇ , S ₄₈ , S ₄₉ and S ₅₀ ). Four of 12 tested S-RNases were found to be non-functional in vitro: S ₄₉ , S ₅₀ , S ₂₄ /S _na and S ₂₅ /S ₄₇ . Detected point mutations in the C3 coding region of S ₄₉ - and S ₅₀ -RNase, leading to the replacement of a highly conserved cysteine and histidine residues, are with the highest probability the reason of these S-RNases inactivity. Results also suggested that ten Iranian almond cultivars display unique S genotype. All presented data confirm Iranian cultivars as valuable almond sources which are of interest to almond breeding and conservation programs.     

Biosynthesis of glycoproteins involved in the pollen-stigma interaction of incompatibility in developing flowers of Brassica oleracea L.

De-novo synthesis of the S-allele-specific glycoproteins of Brassica oleracea is demonstrated in stigmas at different developmental stages. Excised stigmas incorporate ¹⁴C-labeled amino acids into their S-glycoproteins early in development and before the self-incompatibility response is acquired, but the rate of synthesis accelerates prior to anthesis, resulting in the accumulation of high levels of the S-glycoproteins in the stigma and coinciding with the acquisition of the pollen-stigma incompatibility response. Since the self-compatible and self-incompatible zones of developing inflorescences are very sharply delineated, a threshold quantity of S-glycoproteins appears to be critical for the onset of self-incompatibility. Incorporation experiments in which [^35Smethionine was applied to intact stigma surfaces indicate that the papillae are the main sites of synthesis of the S-specific glycoproteins.Abbreviations IEF isoelectric focusing - SC self-compatibility - SDS sodium dodecyl sulfate - SI self-incompatibility