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     

Identification of self-incompatibility genotypes of almond by allele-specific PCR analysis

In almond, gametophytic self-incompatibility is controlled by a single multiallelic locus (S-locus). In styles, the products of S-alleles are ribonucleases, the S-RNases. Cultivated almond in California have four predominant S-alleles (S ^a, S ^b, S ^c, S ^d). We previously reported the cDNA cloning of three of these alleles, namely S ^b, S ^c and S ^d. In this paper we report the cloning and DNA sequence analysis of the S ^a allele. The S^a-RNase displays approximately 55% similarity at the amino-acid level with other almond S-RNases (S^b, S^c, and S^d) and this similarity was lower than that observed among the S^b, S^c and S^d-RNases. Using the cDNA sequence, a PCR-based identification system using genomic DNA was developed for each of the S-RNase alleles. Five almond cultivars with known self-incompatibility (SI) geno-types were analyzed. Common sequences among four S-alleles were used to create four primers, which, when used as sets, amplify DNA bands of unique size that corresponded to each of the four almond S-alleles; S ^a (602 bp), S ^b (1083 bp), S ^c (221 bp) and S ^d (343 bp). All PCR products obtained from genomic DNA isolated from the five almond cultivars were cloned and their DNA sequence obtained. The nucleotide sequence of these genomic DNA fragments matched the corresponding S-allele cDNA sequence in every case. The amplified products obtained for the S ^a- and S ^b-alleles were both longer than that expected for the coding region, revealing the presence of an intron of 84 bp in the S ^a-allele and 556 bp in the S ^b-allele. Both introns are present within the site of the hypervariable region common in S-RNases from the Rosaceae family and which may be important for S specificity. The exon portions of the genomic DNA sequences were completely consistent with the cDNA sequence of the corresponding S-allele. A useful application of these primers would be to identify the S-genotype of progeny in a breeding program, new varieties in an almond nursery, or new grower selections at the seedling stage. Received: 21 June 1999 / Accepted: 15 November 1999     

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.     

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.     

Screening and characterization of apple Rho-like GTPase (MdROPs) genes related to S-RNase mediated self-incompatibility

ROP/Rac GTPase is a conserved class of proteins which play diverse signalling roles in plants. They regulate many fundamental cellular processes such as F-actin dynamics, cell polarity and polar growth. Using apple genomic database analyses, nine ROP family members were cloned for the first time in a fruit tree (apple). Phylogenetic analyses indicated that the nine MdROPs were distributed into two groups, as previously described in the literature for model plants. Expression analyses show all MdROPs were highly expressed in pollen, in particular MdROP1, 3, 4 and 8. Yeast two hybrid and bimolecular fluorescence complementation analyses indicated MdROP8 interacts with S-RNase, a pistil determinate factor in gametophyte self-incompatibility. The pollen tube microtubule is shown to depolymerize in response to S-RNase treatment, during which the expression of MdROP8 rapidly decreased. These results indicate MdROP8 is related to S-RNase mediated self-incompatibility, and gives some useful evidence in modeling the relationship between cytoskeleton depolymerization and pollen tube growth inhibition during the apple SI reaction.     

Identification of pistil-specific proteins associated with three self-incompatibility alleles in Solanum chacoense

Summary Pistil proteins associated with three different S-alleles of the self-incompatibility locus (S locus) in Solanum chacoense have been identified which cosegregated with their respective S alleles in a series of genetic crosses involving six S. chacoense plants, their F₁ progeny, and backcrosses. The molecular weights of these three S-allele-associated proteins, designated S₁ S₂, and S₃, were 29 kDa, 30 kDa, and 31 kDa, respectively. They were all basic proteins with a similar pI of approximately 8.6. They have been found only in the stigma and style of the pistil where their maximum synthesis was reached at one day before anthesis. Their rate of synthesis in both self- and cross-pollinated pistils was the same as that in the unpollinated pistil until 2 days after pollination.On sabbatical leave from Laboratoire de Genetique et Physiologie du Developpement des Plantes, C.N.R.S., F-91190 Gifsur-Yvette, France     

Identification and functional characterization of natural human melanocortin 1 receptor mutant alleles in Pakistani population

Melanocortin 1 receptor (MC1R), a Gs protein‐coupled receptor of the melanocyte's plasma membrane, is a major determinant of skin pigmentation and phototype. Upon activation by α‐melanocyte stimulating hormone, MC1R triggers the cAMP cascade to stimulate eumelanogenesis. We used whole‐exome sequencing to identify causative alleles in Pakistani families with skin and hair hypopigmentation. Six MC1R mutations segregated with the phenotype in seven families, including a p.Val174del in‐frame deletion and a p.Tyr298* nonsense mutation, that were analyzed for function in heterologous HEK293 cells. p.Tyr298* MC1R showed no agonist‐induced signaling to the cAMP or ERK pathways, nor detectable agonist binding. Conversely, signaling was comparable for p.Val174del and wild‐type in HEK cells overexpressing the proteins, but binding analysis suggested impaired cell surface expression. Flow cytometry and confocal imaging studies revealed reduced plasma membrane expression of p.Val174del and p.Tyr298*. Therefore, p.Tyr298* was a total loss‐of‐function (LOF) allele, while p.Val174del displayed a partial LOF attribute.     

Evolutionary dynamics of self-incompatibility alleles in Brassica

Self-incompatibility in Brassica entails the rejection of pollen grains that express specificities held in common with the seed parent. In Brassica, pollen specificity is encoded at the multipartite S-locus, a complex region comprising many expressed genes. A number of species within the Brassicaceae express sporophytic self-incompatibility, under which individual pollen grains bear specificities determined by one or both S-haplotypes of the pollen parent. Classical genetic and nucleotide-level analyses of the S-locus have revealed a dichotomy in sequence and function among S-haplotypes; in particular, all class I haplotypes show dominance over all class II haplotypes in determination of pollen specificity. Analysis of an evolutionary model that explicitly incorporates features of the Brassica system, including the class dichotomy, indicates that class II haplotypes may invade populations at lower rates and decline to extinction at higher rates than class I haplotypes. This analysis suggests convergence to an evolutionarily persistent state characterized by the maintenance in high frequency of a single class II haplotype together with many class I haplotypes, each in low frequency. This expectation appears to be consistent with empirical observations of high frequencies of relatively few distinct recessive haplotypes.     

Basic RNases of wild almond (Prunus webbii): cloning and characterization of six new S-RNase and one "non-S RNase" genes

In order to investigate the S-RNase allele structure of a Prunus webbii population from the Montenegrin region of the Balkans, we analyzed 10 Prunus webbii accessions. We detected 10 different S-RNase allelic variants and obtained the nucleotide sequences for six S-RNases. The BLAST analysis showed that these six sequences were new Prunus webbii S-RNase alleles. It also revealed that one of sequenced alleles, S(9)-RNase, coded for an amino acid sequence identical to that for Prunus dulcis S(14)-RNase, except for a single conservative amino acid replacement in the signal peptide region. Another, S(3)-RNase, was shown to differ by only three amino acid residues from Prunus salicina Se-RNase. The allele S(7)-RNase was found to be inactive by stylar protein isoelectric focusing followed by RNase-specific staining, but the reason for the inactivity was not at the coding sequence level. Further, in five of the 10 analyzed accessions, we detected the presence of one active basic RNase (marked PW(1)) that did not amplify with S-RNase-specific DNA primers. However, it was amplified with primers designed from the PA1 RNase nucleotide sequence (basic "non-S RNase" of Prunus avium) and the obtained sequence showed high homology (80%) with the PA1 allele. Although homologs of PA1 "non-S RNases" have been reported in four other Prunus species, this is the first recorded homolog in Prunus webbii. The evolutionary implications of the data are discussed.     

Elements of theS-gene complex VI. Mutations of the self-incompatibility gene,pseudo-compatibility and origin of new self-incompatibility alleles

Spontaneously occurring mutations of theS gene, involving both theS _I and theS _FI classes of alleles, were studied inNicotiana alata. The results showed that while almost all of the irradiation-induced mutants of theS gene requiredS-bearing duplication for their survival, usually in the form of a free fragment, most of the spontaneous mutants in the same species, surprisingly, did not have such a requirement. This difference has been attributed to the greater depth of mutations produced in response to the ionizing radiations, which necessitated complementation for the survival of the mutants. There is a possibility from the data that theS _FI class of alleles may have even less need for the duplication than the S_I class of alleles. Both pollen- and stylar-part mutations of theS gene were obtained, but the majority of the mutations were partial, producing less than half the normal complement of seeds per pod in the mutants. Complementation was observed in the style between a -part mutant alleleS _infF11 ^sup and a normal alleleS _F10, which was the other allele in the parental plant that produced the mutant. No complementation occurred with another normal unrelated alleleS ₂. This observation was similar to that previously recorded in the study of induced mutants inN. alata.In a cross where the two alleles of the pollen parent were both compatible the allele which was also a mutant had an advantage over the other, normal, allele. This suggests that in maize, where the occurrence of mutant forms of theS gene has been demonstrated, the preferential fertilization of ovules by pollen containing the B-chromosomes may be due to the presence of a mutant form of theS gene on the B-chromosome.Besides clear-cutS-gene mutants, there were others, showing mostly irregular, slight compatibility, which did not appear to be directly related to theS-gene mutation. In some of the progeny of certain of these mutants, partial or complete lack of the specificity of one or bothS alleles in the style was observed; in certain others all progeny were normal. This pseudo-compatibility is attributed to cytoplasmic mutations affecting the products of theS gene; however, the possibility of an effect of chance polygenic modifier combinations is not ruled out.Recent literature on theS-gene structure, mutational specificity ofS alleles, and genetic control of pseudo-compatibility is reviewed. The time ofS-gene action is discussed in relation to the mechanism of the generation of new self-incompatibility alleles.     

Population dynamics of sex-determining alleles in honey bees and self-incompatibility alleles in plants

Mathematical theories of the population dynamics of sex-determining alleles in honey bees are developed. It is shown that in an infinitely large population the equilibrium frequency of a sex allele is 1/n, where n is the number of alleles in the population, and the asymptotic rate of approach to this equilibrium is 2/(3n) per generation. Formulae for the distribution of allele frequencies and the effective and actual numbers of alleles that can be maintained in a finite population are derived by taking into account the population size and mutation rate. It is shown that the allele frequencies in a finite population may deviate considerably from 1/n. Using these results, available data on the number of sex alleles in honey bee populations are discussed. It is also shown that the number of self-incompatibility alleles in plants can be studied in a much simpler way by the method used in this paper. A brief discussion about general overdominant selection is presented.     

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.     

Identification and characterization of new BoLA-DRB3 alleles by heteroduplex analysis and direct sequencing

A sample of 52 mixed-breed dairy cattle (Holstein Friesian and Jersey) and 51 beef cattle (Hereford) from south-east Queensland was studied. The second exon of BoLA-DRB3 was amplified by polymerase chain reaction (PCR), and polymorphisms were detected by heteroduplex analysis. A large number of different heteroduplex patterns indicated extensive sequence polymorphism. Direct sequencing of PCR products from 17 homozygotes and cloning and sequencing of PCR product from two heterozygotes resulted in the identification and characterization of four novel alleles. The previously described allele BoLA-DRB3 * 2A is characterized by an amino acid deletion at position 65. We have identified three animals that are homozygous for this amino acid deletion, indicating that the deletion is unlikely to result in loss of function. Two of these animals had allele BoLA-DRB3 * 2A, and one had a novel allele with codon 65 deleted but differing from BoLA-DRB3 * 2A at a number of other amino acid positions. In conclusion, heteroduplex analysis allows rapid discrimination between homozygotes and heterozygotes, and enables rapid identification of new BoLA-DRB3 alleles.     

Identification of Ppd-B1 alleles in common wheat cultivars by CAPS marker

Photoperiod response is a major determinant of the duration of growth stages in common wheat. In common wheat, many genes play a role in determining flowering time, but the Ppd genes located on the homoeologous group 2 play a major role. Of these Ppd-B1 is located on the short arm of 2B. In 107 common wheat cultivars grown in Poland and neighboring countries, the identification of Ppd-B1 alleles using in-del analysis by using a CAPS markers was investigated. 87 cultivars were shown to carry dominant Ppd-B1 alleles. This shows that Ppd-B1 alleles is have been widely used in common wheat breeding programme in these countries. Recessive ppd-B1 alleles were found only in 20 cultivars (12 Polish, 5 former Soviet Union, 2 German, 1 Swedish).     

Identification of S-RNase and peroxidase in petunia nectar

Previous SDS PAGE gel analysis of the floral nectars from petunia and tobacco plants revealed significant differences in the protein patterns. Petunia floral nectar was shown to contain a number of RNase activities by in gel RNase activity assay. To identify these proteins in more detail, the bands with RNase activity were excised from gel and subjected to trypsin digestion followed by LC-MS/MS analysis. This analysis revealed that S-RNases accumulate in nectar from Petunia hybrida, where they should carry out a biological function different from self-pollen rejection. In addition, other proteins were identified by the LC-MS/MS analysis. These proteins include a peroxidase, an endochitinase, and a putative fructokinase. Each of these proteins contained a secretory signal sequence that marked them as potential nectar proteins. We developed RT-PCR assays for each of these five proteins and demonstrated that each of these proteins was expressed in the petunia floral nectary. A discussion of the role of these proteins in antimicrobial activity in nectar is presented.     

Genomic characterization of self-incompatibility ribonucleases in the Central Asian pear germplasm and introgression of new alleles from other species of the genus Pyrus

The Pyrus species exhibit the so-called S-RNase-based gametophytic self-incompatibility system, which is considered to be the most widespread self-incompatibility system among flowering plants. In this study, 57 Iranian pear (Pyrus communis L.) domestic cultivars and wild genotypes, plus 21 European pear cultivars used as references, were genotyped adopting a PCR-based genotyping assay using consensus and allele-specific primers. The results revealed traces of significant genetic contribution in the Iranian traditional varieties and genotypes from other Pyrus species; the genetic contribution of Japanese pear clearly emerged with the detection of some Pyrus pyrifolia S-RNase alleles. Moreover, our results highlighted the presence of three new S-RNase alleles (named S₁₂₆, S₁₂₇, and S₁₂₈) that were not previously identified in P. communis, possibly introduced in the germplasm of cultivated pear through gene transfer from other cultivated or wild species.