We present a methodology to establish the pollination requirements of apricot (Prunus armeniaca L.) cultivars combining the determination of self-(in)compatibility by fluorescence microscopy with the identification of the S-genotype by PCR analysis.
Self-incompatibility in Rosaceae is determined by a Gametophytic Self-Incompatibility System (GSI) that is mainly controlled by the multiallelic locus S. In apricot, the determination of self- and inter-(in)compatibility relationships is increasingly important, since the release of an important number of new cultivars has resulted in the increase of cultivars with unknown pollination requirements. Here, we describe a methodology that combines the determination of self-(in)compatibility by hand-pollinations and microscopy with the identification of the S-genotype by PCR analysis. For self-(in)compatibility determination, flowers at balloon stage from each cultivar were collected in the field, hand-pollinated in the laboratory, fixed, and stained with aniline blue for the observation of pollen tube behavior under the fluorescence microscopy. For the establishment of incompatibility relationships between cultivars, DNA from each cultivar was extracted from young leaves and S-alleles were identified by PCR. This approach allows establishing incompatibility groups and elucidate incompatibility relationships between cultivars, which provides a valuable information to choose suitable pollinizers in the design of new orchards and to select appropriate parents in breeding programs.
Self-incompatibility is a strategy of flowering plants to prevent self-pollination and promote outcrossing1. In Rosaceae, this mechanism is determined by a Gametophytic Self-Incompatibility System (GSI) that is mainly controlled by the multiallelic locus S2. In the style, the RNase gene encodes the S-stylar determinant, a RNase3, while a F-box protein, which determines the S-pollen determinant, is codified by the SFB gene4. The self-incompatibility interaction takes place through the inhibition of pollen tube growth along the style preventing the fertilization of the ovule5,6.
In apricot, a varietal renewal has taken place worldwide in the last two decades7,8. This introduction of an important number of new cultivars, from different public and private breeding programs, has resulted in the increase of apricot cultivars with unknown pollination requirements8.
Different methodologies have been used to determine pollination requirements in apricot. In the field, self-(in)compatibility may be established by controlled pollinations in caged trees or in emasculated flowers and subsequently recording the percentage of fruit set9,10,11,12. In addition, controlled pollinations have been carried out in the laboratory by semi-in vivo culture of flowers and analysis of the pollen tube behavior under fluorescence microscopy8,13,14,15,16,17. Recently, molecular techniques, such as PCR analysis and sequencing, have allowed the characterization of incompatibility relationships based on the study of the RNase and SFB genes18,19. In apricot, thirty-three S-alleles have been reported (S1 に S20, S22 に S30, S52, S53, Sv, Sx), including one allele related with self-compatibility (Sc)12,18,20,21,22,23,24. Up to now, 26 incompatibility groups have been stablished in this species according to the S-genotype8,9,17,25,26,27. Cultivars with the same S-alleles are inter-incompatible, whereas cultivars with at least one different S-allele and, consequently, allocated in different incompatible groups, are inter-compatible.
To define the pollination requirements of apricot cultivars, we describe a methodology that combines the determination of self-(in)compatibility by fluorescence microscopy with the identification of the S-genotype by PCR analysis in apricot cultivars. This approach allows establishing incompatibility groups and elucidate incompatibility relationships between cultivars.
1. Self-(in)compatibility determination
2. DNA extraction
3. S-allele identification
Pollination studies in apricot require the use of flowers at the late balloon stage one day before anthesis (Figure 1A). This stage is considered the most favorable for both pollen and pistil collection, since floral structures are nearly mature, but anther dehiscence has not yet occurred. This prevents the interference of undesired pollen, not only of pollen from the same flower but also from other flowers, since the closed petals impede the arrival of insects carrying external pollen. The pollen grains are easily sieved through a fine mesh (Figure 1B) from dehisced anthers previously placed on a piece of paper for 24 h at room temperature or with slight extra heat. Likewise, pistils are obtained from flowers at balloon stage after the removing of petals, sepals and stamens with the help of tweezers or fingernails (Figure 1C). Pistils can be self- and cross-pollinated with a fine brush (Figure 1D).
The hermaphroditic flowers of apricot have five dark red sepals, five white petals (Figure 1A), a single pistil (Figure 2A) and 25-30 stamens. The pistil has three main structures: stigma, style and ovary. The ovary has two ovules, and the fertilization of at least one of them is required for fruit setting. During pollination, insects, mainly bees, transfer pollen grains to the stigma (Figure 1A), where they germinate (Figure 2B) within 24 h following pollination. A pollen tube is produced from each germinating pollen grain, which grows through the pistil structures to reach the ovary after 3-4 days and fertilize one of the two ovules after around 7 days. In self-incompatible cultivars in which the S allele of the pollen grain is the same as one of the two of the pistils, pollen tube stops growing at the upper style, preventing fertilization (Figure 2C). However, the pollen tubes from a compatible cultivar, with a different S allele, can grow through the style (Figure 2D), reach the ovary (Figure 2E) and fertilize one of the two ovules.
The analysis of in vitro pollen germination showed good pollen viability in all the cultivars analyzed here, since most pollen tubes were longer than the length of the pollen grain after 24 h in the culture medium. Germinated pollen grains were observed at the stigma surface (Figure 2B) in pistils from all pollinations, indicating adequate pollination (Figure 3).
To determine the self-(in)compatibility for each cultivar, pollen tube behavior in self- and cross-pollinations done in laboratory-controlled conditions was observed under fluorescence microscopy. Pollen tube growth was recorded along the style in all the pistils examined. Cultivars were considered as self-incompatible when pollen tube growth was arrested along the style in most self-pollinated pistils (Figure 2C, Figure 3) and self-compatible when at least one pollen tube reached the base of the style in most of the pistils examined (Figure 2E, Figure 3).
The study of the S-locus by PCR analysis allowed characterizing the S-genotype of each cultivar. Firstly, the S-alleles were identified by the amplification of the first S-RNase intron using the primers SRc-F/SRc-R (Table 2). The size of the amplified fragments was analyzed by capillary electrophoresis (Figure 4A) and was used to classify the genotypes analyzed in their corresponding incompatibility group (I.G.) (Table 3).
Some pairs of alleles, such as S1 and S7 or S6 and S9, showed similar fragment sizes for the first intron. Thus, the differentiation of these alleles was done by amplifying a region of the second intron of the RNase with the primers Pru-C2/PruC4R, SHLM1/SHLM2 and SHLM3/SHLM4 (Table 2). The PruC2/PruC4R primer combination was used to distinguish between S6 and S9. For S6, a fragment of 1300 bp was amplified whereas a fragment of around 700 bp was observed for the S9 allele (Figure 4B, Table 3). The specific primers SHLM1/SHLM2 and SHLM3/SHLM4 amplified a fragment of approximately 650 bp in the S1 allele and 413 bp in the S7 allele (Figure 4C, Table 3).
The primers AprFBC8-(F/R) that amplify the V2 and HVb variable regions of the SFB gene were used to distinguish Sc and S8 alleles since both alleles show identical RNase sequence. The S8 allele showed a PCR-fragment of approximately 150 bp whereas a 500 bp fragment corresponded to the Sc allele (Figure 4D, Table 3). Once the S-genotype was determined for all the cultivars, self-incompatible cultivars were assigned to their corresponding incompatibility groups based on their S-alleles (Table 3).
This approach requires determining the self-(in)compatibility of each cultivar by controlled self- and cross-pollinations in the laboratory (Figure 5A) concomitantly with the characterization of the S-genotype by genetic analysis (Figure 5B). As a result, the pollination requirements of each cultivar and the incompatibility relationships among apricot cultivars can be determined.
Figure 1. Experimental set up for the determination of self-(in)compatibility in apricot.
(A) Flowers at balloon stage (black arrows) in the field. (B) Sieve of pollen grains using a fine mesh. (C) Pistils placed on florist foam in water. (D) Hand-pollination of the pistils with the help of a paintbrush. Please click here to view a larger version of this figure.
Figure 2. Diagrammatic representation of gametophytic incompatibility relationships in apricot flowers.
(A) In Gametophytic Self-Incompatibility (GSI), both compatible and incompatible pollen grains germinate on the stigma. The pollen grain carries one of two S-alleles of the original genotype, in this case either S1 or S2. If the S-allele of the pollen grain matches one of the two S-alleles of the pistil, in this case S1S3, pollen tube growth is inhibited in the upper one-third of the style. (B) Germination of pollen grains on the stigma surface. (C) Pollen tube arrested in the style indicating an incompatible behavior. (D) Pollen tubes growing along the style. (E) Pollen tubes at the base of the style indicating a compatible behavior. Scale bars, 100 μm. Please click here to view a larger version of this figure.
Figure 3. Representative results of pollen germination and pollen tube growth through the style for self-compatible and self-incompatible cultivars after self-pollinations.
Percentage of pistils with pollen grains germinating at the stigma surface, with pollen tubes in halfway the style, at the base of the style, and reaching the ovule. Please click here to view a larger version of this figure.
Figure 4. PCR fragment amplification using five primer pair combinations for the identification of S-alleles.
(A) Gene analyzer output for the SRc-(F/R) primers showing the size of the two amplified fragments of the RNase first intron region corresponding to the S-alleles. (B) PCR amplification using the primers PruC2/PruC4R for the identification of the S6 and S9 alleles. (C) PCR products obtained using the specific primers SHLM1 and SHLM2 for the differentiation of the S1 allele and SHLM3 and SHLM4 to distinguish the S7 allele. (D) PCR amplification with the AprFBC8-(F/R) primers for identifying Sc and S8 alleles. MI: 1 kb DNA Ladder. MII: 100 bp DNA Ladder. Please click here to view a larger version of this figure.
Figure 5. Scheme of the experimental design to elucidate the self- and inter-(in) compatibility relationships in apricot cultivars.
(A) Workflow of self-(in)compatibility determination by controlled pollinations in the laboratory. (B) Workflow of the S-allele identification by molecular approaches. Please click here to view a larger version of this figure.
PCR Master Mix | Thermocycler conditions | ||||||
Components | Final Concentration | 15 μL reaction | Cycle Step | Temperature | Time | Cycles | |
10x NH4 Reaction Buffer | 10x | 1.5 μL | Initial denaturation | 94 °C | 3 min | 1 | |
50 mM MgCl2 Solution | 25 mM | 1.2 μL | Denaturing | 94 °C | 1 min | 35 | |
100 mM dNTP | 2.5 mM | 0.6 μL | Annealing | 55 °C | 1 min | ||
Primer SRc-F | 10 μM | 0.6 μL | Extension | 72 °C | 3 min | ||
Primer SRc-R | 10 μM | 0.6 μL | Final Extension | 72 °C | 5 min | 1 | |
500 U Taq DNA Polymerase | 0.5 U | 0.2 μL | 4 °C | hold | |||
H2O | 8.3 μL | ||||||
Components | Final Concentration | 25 μL reaction | Cycle Step | Temperature | Time | Cycles | |
10x PCR buffer | 10x | 2.5 μL | Initial denaturation | 94 °C | 2 min | 1 | |
5x Q-solution | 5x | 5 μL | Denaturing | 94 °C | 10 s | 10 | |
100 mM dNTP | 2.5 mM | 0.5 μL | Annealing | 55 °C | 2 min | ||
Primer PruC2 | 10 μM | 0.2 μL | Extension | 68 °C | 2 min | ||
Primer C4R | 10 μM | 0.2 μL | Denaturing | 94 °C | 10 s | 25 | |
250 U Taq DNA Polymerase | 10 U | 0.13 μL | Annealing | 58 °C | 2 min | ||
H2O | 15.5 μL | Extension* | 68 °C | 2 min | |||
Final Extension | 72 °C | 5 min | 1 | ||||
4 °C | hold | ||||||
* with 10 s added each cycle to the 68 %C extension step. | |||||||
Components | Final Concentration | 25 μL reaction | Cycle Step | Temperature | Time | Cycles | |
10x PCR buffer | 10x | 2.5 μL | Initial denaturation | 94 °C | 2 min | 1 | |
5x Q-solution | 5x | 5 μL | Denaturing | 94 °C | 30 s | 35 | |
100 mM dNTP | 2.5 mM | 0.5 μL | Annealing | 62 °C | 1.5 min | ||
Primer SHLM1 | 10 μM | 0.2 μL | Extension | 72 °C | 2 min | ||
Primer SHLM2 | 10 μM | 0.2 μL | Final Extension | 72 °C | 5 min | 1 | |
250 U Taq DNA Polymerase | 10 U | 0.13 μL | 4 °C | hold | |||
H2O | 15.5 μL | ||||||
Components | Final Concentration | 20 μL reaction | Cycle Step | Temperature | Time | Cycles | |
5x PCR Buffer | 5x | 4 μL | Initial denaturation | 98 °C | 30 s | 1 | |
dNTP | 2.5 mM | 1.6 μL | Denaturing | 98 °C | 10 s | 35 | |
Primer SHLM3 | 10 μM | 1 μL | Annealing | 51 °C | 30 s | ||
Primer SHLM4 | 10 μM | 1 μL | Extension | 72 °C | 1 min | ||
100 U DNA Polymerase | 5 U | 0.2 μL | Final Extension | 72 °C | 5 min | 1 | |
H2O | 12.4 μL | 4 °C | hold | ||||
Components | Final Concentration | 25 μL reaction | Cycle Step | Temperature | Time | Cycles | |
10x PCR buffer | 10x | 2.5 μL | Initial denaturation | 94 °C | 2 min | 1 | |
100 mM dNTP | 2.5 mM | 2 μL | Denaturing | 94 °C | 30 s | 35 | |
Primer FBC8-F | 10 μM | 1 μL | Annealing | 55 °C | 1.5 min | ||
Primer FBC8-R | 10 μM | 1 μL | Extension | 72 °C | 2 min | ||
250 U Taq DNA Polymerase | 10 U | 0.125 μL | Final Extension | 72 °C | 5 min | 1 | |
H2O | 17.4 μL | 4 °C | hold |
Table 1. Reaction and cycling conditions for different primer combinations used in this protocol.
Primers | Sequence | Reference |
SRc-F | 5'-CTCGCTTTCCTTGTTCTTGC-3' | 18 |
SRc-R | 5'-GGCCATTGTTGCACCCCTTG-3' | 18 |
Pru-C2 | 5'-CTTTGGCCAAGTAATTATTCAAACC-3' | 35 |
Pru-C4R | 5'-GGATGTGGTACGATTGAAGCG-3' | 35 |
SHLM1-F | 5'-GGTGGAGGTGATAAGGTAGCC-3' | 17 |
SHLM2-R | 5'-GGCTGCATAAGGAAGCTGTAGG-3' | 17 |
SHLM3-F | 5'-TATATCTTACTCTTTGGC-3' | 17 |
SHLM4-R | 5'-CACTATGATAATGTGTATG-3' | 17 |
AprFBC8-F | 5'-CATGGAAAAAGCTGACTTATGG-3' | 26 |
AprFBC8-R | 5'-GCCTCTAATGTCATCTACTCTTAG-3' | 26 |
Table 2. Primers used in this protocol, sequence and reference for S-genotype characterization in Prunus armeniaca.
Cultivar | SRc-(F/R) (bp) | PruC2/PruC4R (bp) | SHLM1/SHLM2 (bp) | SHLM3/SHLM4 (bp) | AprFBC8-(F/R) (bp) | S-Genotype | Incompatibility group (I.G) |
Wonder Cot8 | 420, 420 | 749, 1386 | S6S9 | VIII | |||
Magic Cot8 | 334, 420 | 749 | S2S9 | XX | |||
Goldstrike8 | 334, 420 | 749 | S2S9 | – | |||
T06917 | 334, 408 | 650 | S1S2 | I | |||
T12017 | 334, 408 | 650 | S1S2 | – | |||
C-6 | 334, 408 | 413 | S2S7 | IV | |||
Cooper Cot8 | 274, 408 | 650 | S1S3 | XVIII | |||
Apriqueen | 358, 358 | 500 | ScSc | – | |||
Bergecot8 | 334, 358 | 500 | S2Sc | – | |||
Spring Blush8 | 274, 358 | 150 | S3S8 | XXI |
Table 3. S-genotyping of apricot cultivars with five primer pairs used in this protocol and incompatibility group assignment. The different polymerase chain reaction product sizes of S-alleles amplified using SRc-(F/R), PruC2/PruC4R, SHLM1/ SHLM2, SHLM3/SHLM4, and AprFBC8-(F/R) primers are shown in the table.
Traditionally, most commercial apricot European cultivars were self-compatible36. Nevertheless, the use of North American self-incompatible cultivars as parents in breeding programs in the last decades has resulted in the release of an increasing number of new self-incompatible cultivars with unknown pollination requirements7,8,37. Thus, the determination of self- and inter-(in)compatibility relationships in apricot cultivars is increasingly important. This is accentuated in those areas where winter chilling is decreasing, since high year to year variations in the time of flowering are preventing the coincidence in flowering of cultivars and their pollenizers in many cases, especially in cultivars with high chilling requirements38. The methodology described herein, combining hand-pollination, microscopy and genetic analyses has been very useful to determine the self(in)compatibility of each cultivar and to establish its potential pollinizer cultivars.
Pollination requirements can be determined through field-control experiments in orchard conditions11,39. However, the exposition to external factors including meteorological adverse conditions can cause pollination failure10, which may result in erroneous diagnoses of self-incompatibility. The methodology described herein allows to evaluate self-(in)compatibility more accurately by microscopy observations of hand-pollinated flowers in laboratory-controlled conditions, avoiding environmental influence. Moreover, this approach allows analyzing a higher number of cultivars per year, since only a small number of flowers is required instead of several adult trees for each cultivar that are required in field experiments40.
Incompatibility relationships can be established combining hand-pollinations and microscopy14. However, pollinations can only be performed for a short period during the flowering season in spring, and adult trees near the laboratory are needed, since the lifespan of the flowers collected is very short. Thus, the number of incompatibility relationships that can be analyzed by controlled hand-pollinations in each season is very low. The characterization of the genes encoded by the S-locus has enabled the development of PCR-based methods for S-allele genotyping18,41. This approach accelerates S-allele identification since it does not require flowers, and the experiments can be carried out with any vegetative tissue42. This extends the period during which plant material, usually young leaves, can be collected43. Furthermore, the leaves can be lyophilized or frozen, so that the analysis can be done at any time of the year, unlike pollinations that can only be done on fresh flowers during the flowering season44. An additional benefit is that leaves can be collected from young trees even before entering flowering age, facilitating the collection of samples and the early obtaining of results45.
The genetic analysis allows a better differentiation of self-incompatibility alleles since it provides precise results of amplified fragment sizes21,46. To date, thirty-three S-alleles have been identified in apricot12,18,20,21,22,23,24, which has allowed to establish 36 incompatibility groups based on S-genotype8,9,17,25,26,27. On the other hand, a drawback of this methodology is that different alleles in the same range size or mutations can be erroneously identified as the same allele. Thus, Sc and S8 alleles are identical for the RNase sequence but a 358-bp insertion is found in the SFB gene of Sc19. Likewise, the first intron region of the alleles S1 and S7 are identical and are indistinguishable using the primers SRc-F/SRc-R. In addition, several homologies, such as S6 and S528 or S20 and S55, and S7, S13 (EF062341) and S4617, have been found because some of these alleles have been partially sequenced or by failures during PCR amplification and, consequently, further work is needed to distinguish them correctly.
PCR analysis and S-RNase sequencing are adequate for establishing incompatibility relationships through the identification of S-alleles and the allocation of cultivars in their corresponding Incompatibility Group8,17,26,27. However, this methodology has the limitation of preventing the determination of the self-(in)compatibility for particular apricot cultivars. Self-compatibility (SC) has been associated to particular S-alleles in other Prunus species47, as almond (Sf)48,49 or sweet cherry (S4’)50,51. However, in apricot, the Sc allele, which has been associated to SC21, can be erroneously identified as S8, a self-incompatible allele19,22, and possible mutations not linked to the S locus, as the M-locus12,52, conferring SC have been identified. Recently, the M-locus has been genotyped using SSR markers12. Therefore, the genetic identification of SC for apricot genotypes needs further research and, in order to avoid mistakes due to factors not linked to the S locus, in this work the characterization of self-(in)compatibility has been determined also by phenotyping the behavior of the pollen tubes through the pistil of self-pollinated flowers.
The methodology described herein combining the determination of self-(in)compatibility by hand-pollinations in laboratory conditions with the subsequent observation of the behavior of pollen tubes in the pistil of controlled self-pollinations under the fluorescence microscopy and the identification of the S-genotype by PCR analysis allows establishing the pollination requirements of apricot cultivars. This provides a valuable information for growers and breeders, since it allows establishing the incompatibility relationships between cultivars to choose suitable pollinizers in the design of new orchards as well as to select appropriate parents to design new crosses in apricot breeding programs.
The authors have nothing to disclose.
This research was funded by Ministerio de Ciencia, Innovación y Universidades-European Regional Development Fund, European Union (AGL2016-77267-R, and AGL2015-74071-JIN); Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria (RFP2015-00015-00, RTA2017-00003-00); Gobierno de Aragón-European Social Fund, European Union (Grupo Consolidado A12_17R), Fundación Biodiversidad, and Agroseguro S.A.
Agarose D1 Low EEO | Conda | 8010.22 | |
BIOTAQ DNA Polymerase kit | Bioline | BIO-21060 | |
Bright field microscope | Leica Microsystems | DM2500 | |
CEQ System Software | Beckman Coulter | ||
DNeasy Plant Mini Kit | QIAGEN | 69106 | |
dNTP Set, 4 x 25 µmol | Bioline | BIO-39025 | |
GenomeLab DNA Size Standard Kit – 400 | Beckman Coulter | 608098 | |
GenomeLab GeXP Genetic Analysis System | Beckman Coulter | ||
GenomeLab Separation Buffer | Beckman Coulter | 608012 | |
GenomeLab Separation Gel LPA-1 | Beckman Coulter | 391438 | |
HyperLadder 100bp | Bioline | BIO-33029 | |
HyperLadder 1kb | Bioline | BIO-33025 | |
Image Analysis System | Leica Microsystems | ||
Molecular Imager VersaDoc MP 4000 system | Bio-Rad | 170-8640 | |
NanoDrop One Spectrophotometer | Thermo Fisher Scientific | 13-400-518 | |
pH-Meter BASIC 20 | Crison | ||
Phusion High-Fidelity PCR Kit | Thermo Fisher Scientific | F553S | |
Power Pack P 25 T | Biometra | ||
Primer Forward | Isogen Life Science | ||
Primer Reverse | Isogen Life Science | ||
Quantity One Software | Bio-Rad | ||
Stereoscopic microscope | Leica Microsystems | MZ-16 | |
Sub-Cell GT | Bio-Rad | ||
SYBR Safe DNA Gel Stain | Thermo Fisher Scientific | S33102 | |
T100 Thermal Cycler | Bio-Rad | 1861096 | |
Taq DNA Polymerase | QIAGEN | 201203 | |
Vertical Stand Autoclave | JP Selecta |