Wild and Rare Self-Incompatibility Allele S17 Found in 24 Sweet Cherry (Prunus avium L.) Cultivars

The pollination of self-incompatible diploid sweet cherry is determined by the S-locus alleles. We resolved the S-alleles of 50 sweet cherry cultivars grown in Estonia and determined their incompatibility groups, which were previously unknown for most of the tested cultivars. We used consensus primers SI-19/20, SI-31/32, PaConsI, and PaConsII followed by allele-specific primers and sequencing to identify sweet cherry S-genotypes. Surprisingly, 48% (24/50) of the tested cultivars, including 17 Estonian cultivars, carry the rare S-allele S₁₇, which had initially been described in wild sweet cherries in Belgium and Germany. The S₁₇-allele in Estonian cultivars could originate from ‘Leningradskaya tchernaya’ (S₆|S₁₇), which has been extensively used in Estonian sweet cherry breeding. Four studied cultivars carrying S₁₇ are partly self-compatible, whereas the other 20 cultivars with S₁₇ have not been reported to be self-compatible. The recommended pollinator of seven self-incompatible sweet cherries is of the same S-genotype, including four with S₁₇-allele, suggesting heritable reduced effectiveness of self-infertility. We classified the newly genotyped sweet cherry cultivars into 15 known incompatibility groups, and we proposed four new incompatibility groups, 64–67, for S-locus genotypes S₃|S₁₇, S₄|S₁₇, S₅|S₁₇, and S₆|S₁₇, respectively, which makes them excellent pollinators all across Europe. Alternatively, the frequency of S₁₇ might be underestimated in Eastern European populations and some currently unidentified sweet cherry S-alleles might potentially be S₁₇.

     

24份甜樱桃材料自交不亲和S基因型鉴定

甜樱桃品种绝大部分自交不亲和,限制了甜樱桃的正确评价和合理利用,因此自交不亲和基因型的鉴定对于生产具有重要意义。以24个甜樱桃主栽品种为材料,用5对蔷薇科李属引物组合对24个甜樱桃品种进行了S等位基因的PCR扩增,克隆S基因的扩增片段,用核酸序列在Gen Bank上搜索,确定了5种S基因的核酸序列和大小。结果表明:Pru C2+Pru C4R引物组合扩增效果最好;在琼脂糖凝胶上位置相同的扩增带其核酸序列相同,是同一种S基因;5种S基因扩增片段的大小分别是S1为800 bp,S3为762 bp,S4为962bp,S5为300 bp,S6为456 bp,S9为650 bp;24个甜樱桃S基因型是红手球、早红宝石为S1S3,拉宾斯S1S4',红宝石S1S6,布鲁克斯S1S9,那翁S3S4,秦林、泰安大紫、先锋、早大果、丽珠、美早、5-106、左滕锦、桑提娜为S3S6,黑珍珠、红灯、萨米脱、秦樱为S3S9,胜利为S5S9,明珠、红蜜、雷尼、滨库为S6S9。     

New findings in apple S-genotype analysis resolve previous confusion and request the re-numbering of some S-alleles

Apple trees display gametophytic self-incompatibility which is controlled by a series of polymorphic S-alleles. To resolve the discrepancies in S-allele assignment that appeared in the literature, we have re-examined the identity of S-alleles known from domestic apple cultivars. Upon an alignment of S-allele nucleotide sequences, we designed allele-specific primer pairs to selectively amplify a single S-allele per reaction. Alternatively, highly similar S-alleles that were co-amplified with the same primer pair were discriminated through their distinct restriction digestion pattern. This is an extension of our previously developed allele-specific PCR amplification approach to reveal the S-genotypes in apple cultivars. Amplification parameters were optimised for the unique detection of the 15 apple S-alleles of which the nucleotide sequences are known. Both the old cultivars with a known S-genotype and a number of more common cultivars were assayed with this method. In most cases, our data coincided with those obtained through phenotypic and S-RNase analysis. However, three S-alleles were shown to relate to RNases that were previously proposed as being encoded by distinct S-alleles. For another S-allele the corresponding gene product has not been discriminated. Consequently, we propose the re-numbering of these four S-alleles. Furthermore, two alleles that were previously identified as S(27a) and S(27b) now received a distinct number, despite their identical S-specificity. To ease widespread future analysis of S-genotypes, we identified common cultivars that may function as a witness for bearing a particular S-allele. We discuss the assignment of new S-alleles which should help to avoid further confusion.     

Assessment of genetic diversity of Czech sweet cherry cultivars using microsatellite markers

We analyzed 24 sweet and wild cherry genotypes collected in Czech Republic to determine genetic variation, using previously described 16 SSR primers to adapt a fast, reliable method for preliminary screening and comparison of sweet cherry germplasm collections. All SSRs were polymorphic and they were able all together to distinguish unambiguously the genotypes. These SSR primers generated 70 alleles; the number of alleles per primer ranged from 2 to 7, with a mean of 4.4 putative alleles per primer combination. The primer UDP-98-412 gave the highest number of polymorphic bands (totally 7), while Empa2 and Empa3 gave the lowest number (2). The allele frequency varied from 2.1% to 87.5%. We observed 10% of unique alleles at different loci. The observed heterozygosity value ranged from 0.25 to 0.96 with an average of 0.72 while expected heterozygosity value varied from 0.22 to 0.75 with an average of 0.59. The PIC value ranged from 0.21 to 0.71 with a mean value of 0.523. Cluster analysis separated the investigated cultivars in two groups. High level of genetic diversity obtained in the collection and proved to be sufficiently genetically diverse and therefore these genotypes would be useful to breeders for the development of new cherry cultivars.     

Microevolution of S-allele frequencies in wild cherry populations: respective impacts of negative frequency dependent selection and genetic drift

Negative frequency dependent selection (NFDS) is supposed to be the main force controlling allele evolution at the gametophytic self-incompatibility locus (S-locus) in strictly outcrossing species. Genetic drift also influences S-allele evolution. In perennial sessile organisms, evolution of allelic frequencies over two generations is mainly shaped by individual fecundities and spatial processes. Using wild cherry populations between two successive generations, we tested whether S-alleles evolved following NFDS qualitative and quantitative predictions. We showed that allelic variation was negatively correlated with parental allelic frequency as expected under NFDS. However, NFDS predictions in finite population failed to predict more than half S-allele quantitative evolution. We developed a spatially explicit mating model that included the S-locus. We studied the effects of self-incompatibility and local drift within populations due to pollen dispersal in spatially distributed individuals, and variation in male fecundity on male mating success and allelic frequency evolution. Male mating success was negatively related to male allelic frequency as expected under NFDS. Spatial genetic structure combined with self-incompatibility resulted in higher effective pollen dispersal. Limited pollen dispersal in structured distributions of individuals and genotypes and unequal pollen production significantly contributed to S-allele frequency evolution by creating local drift effects strong enough to counteract the NFDS effect on some alleles.     

Re-examination of the self-incompatibility genotype of apple cultivars containing putative ’new’ S-alleles

Recently, the self-incompatibility (S-) genotypes of 56 apple cultivars were examined by protein analysis, which led to the identification by Boskovic and Tobutt of 14 putative ’new’ S-alleles, S12 to S25. This paper reports a re-examination of the S-genotypes of some of these cultivars through S-allele ’specific’ PCR and sequence analysis. The results obtained by this analysis indicated that the number of S-alleles that are present in apple is probably smaller than the number proposed by Boskovic and Tobutt. The existence of three ’new’ S-alleles (S20, S22 and S24) was confirmed. The existence of two other putative ’new’ S-alleles (S23 and S25) was, however, contradicted. The coding sequences of the S-alleles that correspond to the S10 and the S25 ribonuclease bands as well as those corresponding to the S22 and the S23 ribonuclease bands were shown to be identical in sequence. Interestingly, the S-allele corresponding to the S22 and the S23 ribonuclease bands shared a high sequence identity (99% identity) with S27, which was previously cloned and sequenced from Baskatong, but which was not included in the analysis conducted by Boskovic and Tobutt. Both S-alleles only differ in point mutations, which are not translated into differences in amino-acid sequence. To our knowledge, this is the first report of two S-alleles that differ at the nucleotide level but still encode for identical S-RNases. The implications of these observations for determining the S-genotypes of plants by PCR analysis or protein analysis are discussed. Received: 10 January 2001 / Accepted: 19 January 2001     

Allelic diversity of S-RNase at the self-incompatibility locus in natural flowering cherry populations (Prunus lannesiana var. speciosa)

In the Rosaceae family, which includes Prunus, gametophytic self-incompatibility (GSI) is controlled by a single multiallelic locus (S-locus), and the S-locus product expressed in the pistils is a glycoprotein with ribonuclease activity (S-RNase). Two populations of flowering cherry (Prunus lannesiana var. speciosa), located on Hachijo Island in Japan's Izu Islands, were sampled, and S-allele diversity was surveyed based on the sequence polymorphism of S-RNase. A total of seven S-alleles were cloned and sequenced. The S-RNases of flowering cherry showed high homology to those of Prunus cultivars (P. avium and P. dulcis). In the phylogenetic tree, the S-RNases of flowering cherry and other Prunus cultivars formed a distinct group, but they did not form species-specific subgroups. The nucleotide substitution pattern in S-RNases of flowering cherry showed no excess of nonsynonymous substitutions relative to synonymous substitutions. However, the S-RNases of flowering cherry had a higher Ka/Ks ratio than those of other Prunus cultivars, and a subtle heterogeneity in the nucleotide substitution rates was observed among the Prunus species. The S-genotype of each individual was determined by Southern blotting of restriction enzyme-digested genomic DNA, using cDNA for S-RNase as a probe. A total of 22 S-alleles were identified. All individuals examined were heterozygous, as expected under GSI. The allele frequencies were, contrary to the expectation under GSI, significantly unequal. The two populations studied showed a high degree of overlap, with 18 shared alleles. However, the allele frequencies differed considerably between the two populations.     

Genetic diversity in wild sweet cherries (Prunus avium) in Turkey revealed by SSR markers

Wild sweet cherry (Prunus avium) trees are abundant in the northern part of Turkey, including the Coruh Valley. We analyzed 18 wild sweet cherry genotypes collected from diverse environments in the upper Coruh Valley in Turkey to determine genetic variation, using 10 SSR primers. These SSR primers generated 46 alleles; the number of alleles per primer ranged from 3 to 7, with a mean of 4.6. The primer PS12A02 gave the highest number of polymorphic bands (N = 7), while CPSCT010, UDAp-401 and UDAp-404 gave the lowest number (N = 3). Seven groups were separated in the dendrogram, although most of the genotypes did not cluster according to phenological and morphological traits. This level of genetic diversity in these wild sweet cherry genotypes is very high and therefore these trees would be useful as breeders for crosses between cultivated sweet cherry and wild genotypes.     

Analysis of self-incompatibility interactions in 30 resynthesized Brassica napus lines. I. Fluorescence microscopic studies

Thirty Brassica napus lines have been developed through interspecific hybridization of B. oleracea and B. campestris lines with defined S-allele constitutions. These lines, which represent 29 different S-allele combinations, were tested in a diallel of test-pollinations to determine the activity of the introgressed S-alleles and intergenomic dominance relationships. Some consistent trends were observed: B. oleracea S-alleles high in the dominance series (e.g. S₈, S₁₄, S₂₉) were always active in the resynthesized B. napus lines, whereas recessive S-alleles (S₂, S₁₅) lost their activity in some test combinations. The B. campestris S-alleles were active in most cases, although 2 alleles were partially inactivated by the recessive B. oleracea allele S₁₅.     

Determining self-incompatibility genotypes in Belgian wild cherries

ABSTRACT The self-incompatibility (S) genotypes of a collection of 65 Belgian accessions of wild cherry, selected within two populations and planted in a seed orchard, were determined using polymerase chain reaction (PCR) methods. Initially, DNA extracts were amplified with consensus primers that amplify across the second intron of the S-ribonuclease gene which shows considerable length polymorphism. The provisional genotypes deduced were checked with the appropriate allele-specific primers for the known alleles S(1) to S(16). Putative new alleles were subjected to PCR with consensus primers amplifying across the first intron. Six new alleles, S(17) to S(22), were thus indicated on the basis of the estimated lengths of the first and second intron PCR products. Examples of these alleles were partially sequenced and were indeed mutually distinct and different from the known alleles. The incompatibility genotypes of all 65 accessions were determined and one triploid individual was found. Seventeen alleles were detected in all. Allele frequencies differed between samples and the expected total number of alleles in the underlying populations was estimated. The wild cherry populations differed significantly with respect to allelic frequencies from sweet cherry cultivars; alleles S(4) and S(5), which are moderately frequent in sweet cherry, were absent from the wild cherry accessions. The knowledge of the S genotypes will be useful for studying the gene flow within the seed orchard and these approaches should also be informative in wild populations.     

Molecular variation at the self-incompatibility locus in natural populations of the genera Antirrhinum and Misopates

The self-incompatibility system of flowering plants is a classic example of extreme allelic polymorphism maintained by frequency-dependent selection. We used primers designed from three published Antirrhinum hispanicum S-allele sequences in PCR reactions with genomic DNA of plants sampled from natural populations of Antirrhinum and Misopates species. Not surprisingly, given the polymorphism of S-alleles, only a minority of individuals yielded PCR products of the expected size. These yielded 35 genomic sequences, of nine different sequence types of which eight are highly similar to the A. hispanicum S-allele sequences, and one to a very similar unpublished Antirrhinum S-like RNase sequence. The sequence types are well separated from the S-RNase sequences from Solanaceae and Rosaceae, and also from most known "S-like" RNase sequences (which encode proteins not involved in self-incompatibility). An association with incompatibility types has so far been established for only one of the putative S-alleles, but we describe evidence that the other sequences are also S-alleles. Variability in these sequences follows the pattern of conserved and hypervariable regions seen in other S-RNases, but no regions have higher replacement than silent diversity, unlike the results in some other species.     

Evolutionary analysis of S-RNase genes from Rosaceae species

Eight new cDNA sequences for S-RNases were cloned and analysed from almond (Prunus dulcis) cultivars of European origin, and compared to published sequences from other Rosaceae species. Insertions/deletions of 10-20 amino acid residues were detected in the RC4 and C5 domains of S-RNases from almond and sweet cherry. The S-RNases of the Prunus species and those of the genera Malus and Pyrus formed two distinct groups on phylogenetic analysis. Nucleotide substitutions were analysed in the S-RNase genes of these species. The S-genes of almond and sweet cherry have a lower Ka/Ks value than those of apple, pear and wild apple do. The fact that there is no fixed difference between the S-RNase genes of almond and sweet cherry, or between apple and pear, suggests that nucleotide substitutions only introduce transient polymorphism into the two groups, and rarely became fixed and contribute to divergence. Through the comparative study of 17 S-RNase genes from the genus Prunus and 18 from the genera Malus and Pyrus, some fixed nucleotide differences between the two groups were identified. These differences do not appear to be the result of selection for adaptive mutations, since the number of replacement substitutions is not significantly greater than the number of synonymous substitutions. S-RNase genes of almond and sweet cherry, and of apple and pear, showed little heterogeneity in nucleotide substitution rates. However, heterogeneity was observed between the two groups of S-alleles, with the Prunus alleles exhibiting a lower rate of non-synonymous substitutions than alleles from Malus and Pyrus. The evolutionary relationships between these species are discussed.     

Identification and genetic diversity of plum cultivars grown in Belarus

A study of the collection of sour cherry, sweet cherry, common plum, diploid and tetraploid types of plums, and apricots grown in Belarus carried out using 20 SSR markers showed that they are characterized by high genetic diversity. Among 106 genotypes, 524 polymorphic alleles were identified. The average number of alleles was 15.4 in common plum samples, 11.3 in diploid and tetraploid plum, 9.3 in sour cherry, 6.0 in apricot, and 4.9 in sweet cherry. The greatest genetic diversity is characteristic of common plum cultivars (PD = 0.811). The genetic diversity decreases as follows: diploid plum (PD = 0.741), sour cherry (PD = 0.721), apricot (PD = 0.673), and sweet cherry (PD = 0.655). Cluster analysis shows that the degree of intraspecific divergence in sour cherry and sweet cherry cultivars is less than that of common plum, diploid plum, and apricot plum. Although apricots and plums belong to the subgenus Prunophora, according to the results of SSR analysis, apricot cultivars form a cluster that is more distant from both Cerasus and Prunophora. A set of seven SSR markers (EMPA001, EMPA005, EMPA018, EMPA026 and BPPCT025, BPPCT026, BPPCT039) was selected for DNA identification of cultivars of sour cherry, sweet cherry, common plum, diploid plum, and apricot, as well as species and interspecies hybrids.     

白梨和砂梨S基因型确定及S34新基因的分离

梨是配子体型自交不亲和植物,确定不同品种的S基因型是科学杂交授粉及提高梨产量和品质的基础。本文根据砂梨S1-9等位基因一级结构特征,设计特异引物PF和PR,以白梨（Pyrus bretschneideri）种鹅梨（Pyrus bretschneideri‘Eli’）和砂梨（Pyrus pyrifolia）品种博多青（Pyrus pyrifolia‘Hakataao’）的叶片基因组DNA为模板,通过PCR·RFLP系统检测、克隆测序以及生物信息学分析,分离鉴定了它们的片段大小相似的2条S等位基因,从中获得1条新的S基因,命名为S34-RNase基因,并确定了这2个梨品种的S基因型,分别为鹅梨S13S34和博多青S22S34。     

Genetic diversity of some Iranian sweet cherry (<Emphasis Type="Italic">Prunus avium</Emphasis>) cultivars using microsatellite markers and morphological traits

The aim of this study was to characterize 23 important Iranian sweet cherry (Prunus avium) cultivars collected from different provinces of Iran and 1 foreign cultivar, which was used as control, considered for breeding programs by using 21 microsatellite markers and 27 morphological traits. In sweet cherry (Prunus avium) accessions, leaf, fruit, and stone morphological characters were evaluated during two consecutive years. The study revealed a high variability in the set of evaluated sweet cherry accessions. The majority of important correlations were determined among variables representing fruit and leaf size and variables related to color. Cluster analysis distinguished sweet cherry accessions into two distinct groups. Principal component analysis (PCA) of qualitative and quantitative morphological parameters explained over 86.59% of total variability in the first seven axes. In PCA, leaf traits such as leaf length and width, and fruit traits such as length, width, and weight, and fruit flesh and juice color were predominant in the first two components, indicating that they were useful for the assessment of sweet cherry germplasm characterization. Out of 21 SSR markers, 16 were polymorphic, producing 177 alleles that varied from 4 to 16 alleles (9.35 on average) with a mean heterozygosity value of 0.82 that produced successful amplifications and revealed DNA polymorphisms. Allele size varied from 95 to 290 bp. Cluster analyses showed that the studied sweet cherry genotypes were classified into five main groups based mainly on their species characteristics and SSR data. In general, our results did not show a clear structuring of genetic variability within the Iranian diffusion area of sweet cherry, so it was not possible to draw any indications on regions of provenance delimitation. The results of this study contribute to a better understanding of sweet cherry genetic variations in Iran, thus making for more efficient programs aimed at preserving biodiversity and more rational planning of the management of reproductive material.     

AFLP reveals structural details of genetic diversity within cultivated olive germplasm from the Eastern Mediterranean

Amplified fragment length polymorphism (AFLP) analysis was used to assess genetic inter-relationships among olive varieties cultivated in the Eastern Mediterranean Basin. The genotypes sampled included most of the important cultivars from Turkey, Greece and the Middle East and selected genotypes from the Western Mediterranean area. A total of 119 polymorphic markers were generated from five selective primer-pair combinations. The combined data sets generated by just two primer-pairs were adequate to discriminate between all 65 genotypes, while each primer-pair could individually identify up to 64 genotypes. A factorial correspondence analysis (FCA) plot indicated that the cultivars clustered into two relatively modestly defined groups. The first broad group was dominated by cultivars from Turkey but also included genotypes originating from the Middle East (Syria and Lebanon) that collectively formed a tight subcluster. The second group comprised Greek cultivars and those originating from the Western Mediterranean. A significant genetic distance value between Greek and Turkish cultivars was provided by an analysis of molecular variance (amova). There was also evidence of substructure here, with an apparent separation of most Spanish and Italian clones. These findings are in general accordance to previous suggestions of an East-West divergence of olive cultivars, although the dichotomy is less extensive than reported previously and complicated by regional variation within each group.     

白梨和砂梨S基因型确定及S34新基因的分离

梨是配子体型自交不亲和植物, 确定不同品种的S基因型是科学杂交授粉及提高梨产量和品质的基础。本文根据砂梨S1-9等位基因一级结构特征, 设计特异引物PF和PR, 以白梨(Pyrus bretschneideri)品种鹅梨(Pyrus bretschneideri ‘El i’) 和砂梨(Pyrus pyrifolia)品种博多青(Pyrus pyri folia ‘Hakataao’) 的叶片基因组DNA为模板, 通过 PCR-RFLP系统检测、克隆测 序以及生物信息学分析, 分离鉴定了它们的片段大小相似的2条S等位基因, 从中获得1条新的S基因, 命名为S34-RNase基因, 并确定了这2个梨品种的S基因型, 分别为鹅梨S13S34和博多青S22S34。     

Inheritance and linkage of isozymes in sweet cherry (Prunus avium L.)

Eight polymorphic isozyme loci, 6PGD, G6PD, MDH, PGM, SKDH, FDP, GOT and IDH, in sweet cherry where found to be in one linkage group, with a ninth isozyme locus, GPI, being in another linkage group on a different chromosome. Isozymes were also linked to the incompatibility S locus and this explained the disturbed segregation ratios observed in the first generation from controlled hybridisations between different sweet cherry cultivars. Analysis revealed close linkage between the isozyme and S loci. The results supported a pre-existing theory that the S gene in cherry consists of three linked segments each coding for a different function. Progeny derived from selfing of Stella, the self-fertile cherry cultivar, also showed disturbed segregation ratios and an absence of homozygotes for the isozyme loci assayed. This demonstrated that codominant inheritance of the S alleles had not been effected by the self-fertile mutation.     

Pollen performance as affected by the pistilar genotype in sweet cherry (Prunus avium L.)

Summary Differences in pollen performance in higher plants can result in significant selective advantages for some particular genotypes leading to both gametophytic and sexual selection. However, the possibility of selection among male gametophytes has been questioned since natural selection could lead to the fixation of alleles for the best competing male genotypes. These two apparently conflicting hypotheses could be reconciled if pollen performance, rather than operating in absolute terms, could be modulated by the pistilar genotype. Thus, pollen performance in vivo and in vitro has been compared in four sweet cherry (Primus avium L.) cultivars. Differences among the cultivars studied have been recorded in the speed and final pollen germination percentages both in vivo and in vitro. The results obtained show that the female genotype also modulates the final result of pollen performance. These two factors are not merely additive but, on the contrary, the interaction between them affects pollen behavior in vivo. This fact has clear implications for gametophytic and sexual selection since the best male-female combinations can be favored and this could explain the variability observed for pollen performance in nature.