The molecular biology of self-incompatibility systems in flowering plants

Self-incompatibility is a common mechanism by which flowering plants can exert some control over the process of fertilization. Typically, the self-incompatibility response involves the recognition and rejection of self-incompatible pollen which leads to a block in self-fertilization and, as a consequence, promotes outcrossing. In recent years, considerable progress has been made in the molecular understanding of several self-incompatibility systems. Interestingly, a common mechanism for self-incompatibility is not employed by all flowering plants, but in fact quite diverse mechanisms have been recruited for the rejection of self-incompatible pollen. In this review, the recent advances in the self-incompatibility systems of the Solanaceae, Papaveraceae, and Brassicaceae will be described as well as some of the molecular work that is emerging for the Poaceae and the heteromorphic self-incompatibility systems.     

ROLE OF CALCIUM IN THE CALLOSE RESPONSE OF SELF-POLLINATED BRASSICA STIGMAS

In Brassica oleracea, sporophytic self-incompatibility prevents germination of self pollen, or normal growth of self pollen tubes. After self-pollination, the papillae of stigmas synthesize callose. The role of Ca⁺⁺ in the formation of stigmatic callose was tested by adding compounds that interact with Ca⁺⁺ to suspensions of pollen that were known to induce callose formation in self stigmas. The calcium channel antagonist, lanthanum, and the calcium chelating agent, EGTA, reduced or abolished the callose response to self-pollen suspensions. In the presence of Ca⁺⁺, the calcium ionophore, A23187, induced callose in stigmatic papillae when added to pollen suspensions, or alone. Therefore, callose deposition in response to incompatible pollinations appears to be a calcium-dependent process. Pretreatment of pistils with 100 μm 2-deoxy-D-glucose abolished the callose response to self-pollination, while self pollen remained inhibited and cross pollen grew normally in treated pistils. Thus, callose formation in the stigma is not an essential part of the self-incompatibility mechanism preventing the growth of self pollen in Brassica.     

Repressing the expression of self-incompatibility in crucifers by short-term high temperature treatment

Summary The effect of short-term high temperature on the expression of self-incompatibility was studied in detached flowers of Brassica oleracea, B. campestris and Raphanus sativus. The expression of self-incompatibility was repressed by treatment of pistils at 40 °C for 15 minutes. Treatment at 50 °C repressed self-incompatibility but it also disturbed pollen tube elongation into stylar tissue. S-glycoproteins did not show any quantitative changes during the intact pistil treatment under 50 °C. Callose was occasionally found in the treated papilla where the self pollen tube penetrated. The repressing effect of the 40 °C treatment was found to be reversible, and this reversibility depended upon the environmental temperature of plant. Plants grown at 15/5 °C (day/night temperature) completely recovered self-incompatibility 2 h after treatment, while those grown at 20/10°, 25/15 °C did not. The reversibility of the expression of self-incompatibility correlated with the distortion of plasma membrane in the papilla. It is considered that high temperature affects the pollen tube penetration system in pistils rather than the recognition system between pistils and pollen. The treatment of dehiscing anthers at 40 °C killed the pollen.     

Pollen-pistil interactions inBrassica oleracea: Cell calcium in self and cross pollen grains

Summary The levels of calcium in pollen grains on the stigma, after self vs. cross pollinations, were compared inBrassica oleracea, a species showing sporophytic self-incompatibility. Self pollen was characterized by higher levels of chlorotetracycline fluorescence and by higher calcium signals in energy-dispersive analysis of X-rays than cross pollen. Cellular integrity of pollen grains was maintained after rejection, and self pollen could be rescued from the stigma to germinate 4 h after pollination, suggesting that the rejection response was not irreversible.abbreviations CTC chlorotetracycline - EDAX energy dispersive analysis of x-rays - FDA fluorescein diacetate - RH relative humidity - SSI sporophytic self-incompatibility - SLSG S locus-specific glycoproteins     

A genetic map of the Nicotiana alata S locus that includes three pollen-expressed genes

The S locus of solanaceous plants includes separate genes that control the self-incompatibility phenotype of the pistil and of the pollen. The gene controlling the self-incompatibility phenotype of the pistil encodes an extracellular ribonuclease, the S-RNase. The gene(s) controlling the self-incompatibility phenotype of pollen (the pollen-S gene) has yet to be identified. As part of a long-term strategy to clone the pollen-S gene by chromosome walking, a detailed map of the region near the S locus of Nicotiana alata was generated using a total of 251 F₂ plants. The map spans an interval of approximately 2.6 cM and contains five markers as well as the S-RNase gene. Two markers were detected with heterologous probes that also detect sequences linked to the S locus of Solanum tuberosum and the homologous region of the Lycopersicon genome. Three markers were identified by differential display using N. alata pollen RNA as a template. One of these markers is a pollen-expressed sequence, 48A, which detects a polymorphic marker no more than 0.5 cM from the S locus. RNA blot analysis indicates that the 48A gene is expressed primarily during pollen development after the completion of meiosis and is therefore a candidate for the pollen-S gene. The utility of these markers and the possible involvement of 48A in the molecular mechanism of self- incompatibility are discussed. Received: 28 June 1999 / Accepted: 24 September 1999     

Molecular Determinants and Mechanisms of Gametophytic Self-Incompatibility in Fruit Trees of Rosaceae

Self-incompatibility is an important genetic mechanism that prevents inbreeding and promotes genetic polymorphism and heterosis in flowering plants. Many fruit species in the Rosaceae, including apple, pear, plum, apricot, sweet cherry, Japanese apricot, and almond, exhibit typical gametophytic self-incompatibility (GSI) controlled by an apparently single multi-allelic locus. This locus encodes at least two components from both the pollen and the pistil, and controls recognition of self- and non-self pollen. Recently, the GSI system has been investigated at the molecular and cellular levels in Rosaceae, and findings have provided some important insights as to how these two genes interact within pollen tubes that lead to specific inhibition of germination and/or growth of self-pollen tubes. In this review, molecular features of S-determinants of both pistil and pollen, identification of S-alleles, mechanisms of self-incompatibility break-down, and evolution of S-alleles are presented. Moreover, hypothetical signal transduction models in a self-incompatible system in Rosaceae are proposed based on recent findings that indicate that several signal factors are involved in GSI responses.     

Phosphorylation of style S-RNases by Ca2+-dependent protein kinases from pollen tubes

Solanaceous plants with gametophytic self-incompatibility produce ribonucleases in the transmitting tract of the style that interact with self-pollen and inhibit its growth. These ribonucleases are a series of allelic products of the S-locus, which controls self-incompatibility. Little is known about the pollen components involved in this interaction or whether a signal transduction pathway is activated during the self-incompatibility response. We have partially purified a soluble protein kinase from pollen tubes of Nicotiana alata that phosphorylates the self-incompatibility RNases (S-RNases) from N. alata but not Lycopersicon peruvianum. The soluble protein kinase (Nak-1) has several features shared by the calcium-dependent protein kinase (CDPK) class of plant protein kinases, including substrate specificity, calcium dependence, inhibition by the calmodulin antagonist calmidazolium, and cross-reaction with monoclonal antibodies raised to a CDPK from soybean. Phosphorylation of S ₂-RNase by Nak-1 is restricted to serine residues, but the site(s) of phosphorylation has not been determined and there is no evidence for allele-specific phosphorylation. The microsomal fraction from pollen tubes also phosphorylates S-RNases and this activity may be associated with proteins of M_r60 K and 69 K that cross-react with the monoclonal antibody to the soybean CDPK. These results are discussed in the context of the involvement of phosphorylation in other self-incompatibility systems.     

Inheritance and genetic mapping of self-incompatibility in Coffea canephora Pierre

Cross-compatibility behaviour of doubled haploid (DH) and hybrid genotypes of Coffea camphora was established using both phenotypic bioassay and in situ seed-set examination. The availability of DHs provided the opportunity of working with genetically homogenous pollen and female parents. The aniline blue fluorescence (ABF) method was applied to detect callose accumulation in pollen and pistil. Clear cross-compatibility/incompatibility situations were observed and confirmed by in situ seed-set analysis. Cross-compatibility analysis of hybrid combinations involving different DHs corroborated the crossing behaviour observed at the DH level. Expression of the self-incompatibility system did not appear to be affected by the low vigour of the DH. The crossing-behaviour distribution observed within DHs derived from clone IF200 confirmed that self-incompatibility in C. canephora is a gametophytic self-incompatibility system controlled by a single locus (S-locus). Reduced seed-set developments following incompatible crosses may indicate the occurrence of pseudo-incompatibility. Molecular marker linkage analysis showed that the S-locus is associated with an RFLP marker on linkage group 9. The availability of a linked DNA marker should facilitate the genetic analysis of self-incompatibility in relation to coffee breeding programmes.     

Pollen-pistil interaction in Brassica oleracea

Quantitative studies of the adhesion of pollen grains to the stigma in Brassica oleracea revealed that self-pollen is initially less firmly bound than cross-pollen. The pollen grain tryphine, believed to be important in the adhesion process, has been shown to differ in mobility following self- and cross-pollination when observed using fluorescent probes. The hydration of the pollen grains has been investigated in vitro by measuring the changes in shape, volume and fresh weight of the imbibing grains. Whilst little change in volume could be detected there was a considerable increase in fresh weight together with a change of shape. The significance of these events, which occur prior to pollen germination, is discussed in relation to their effect upon subsequent germination and expression of self-incompatibility.Abbreviations RH relative humidity - SI self-incompatibility - ConA concanavalin A - I-ANS I-anilino-napthyl-sulfonic acid     

Loss of callose in the stigma papillae does not affect the Brassica self-incompatibility phenotype

As part of the Brassicaceae self-incompatibility response, callose is deposited in the stigma papillar cells. To determine if callose plays an important role in the rejection of incompatible pollen by the stigma, transgenic Brassica napus. L. plants were produced which express the tobacco β-1,3-glucanase cDNA (the enzyme which degrades callose) in the stigma papillae. Using aniline blue fluorescence, little or no callose was detected in the papillar cells of transgenic stigmas. However, the self-incompatibility system appeared to be unaffected based on the lack of pollen tube growth and the subsequent lack of seed set. The transgene had no effect on compatible pollinations. Thus, while callose deposition is associated with the B. napus self-incompatibility response, it is not required for the rejection of incompatible pollen. Received: 14 March 1997 / Accepted: 15 April 1997     

INCOMPATIBILITY IN AMSINCKIA GRANDIFLORA (BORAGINACEAE): DISTRIBUTION OF CALLOSE PLUGS AND POLLEN TUBES FOLLOWING INTER- AND INTRAMORPH CROSSES

The distribution of callose plugs and pollen tubes was investigated following inter- and intramorph crosses of Amsinckia grandiflora (Boraginaceae), a distylous species possessing cryptic self-incompatibility. Callose plug distribution provided a good indication of the distribution of pollen tubes. Compared to intramorph crosses, many more callose plugs and pollen tubes were found in basal stylar regions following intermorph crosses, indicating that differential pollen tube growth is a likely cause of cryptic self-incompatibility. The incompatibility response differed for the floral morphs: in the pin (long-styled) morph pollen tubes were most likely to cease growth in the midstylar region, while inhibition was more likely to occur in the upper stylar region of the thrum (short-styled) morph. There was no evidence of stigmatic inhibition of pollen tubes for either morph, although the incompatibility response in the Boraginaceae is normally located in the stigmatic region.     

POLLEN-PISTIL INTERACTIONS IN TRISTYLOUS PONTEDERIA SAGITTATA (PONTEDERIACEAE). I. FLORAL HETEROMORPHISM AND STRUCTURAL FEATURES OF THE POLLEN TUBE PATHWAY

Heteromorphic characters and structural features of the pollen tube pathway are described in tristylous Pontederia sagittata to assess their influence on the pollination process and in mediating self-incompatibility behavior. Heteromorphic characters that distinguish the floral morphs include style length, stigma depth, stigmatic papillae length, stylar parenchyma cell length, area of the stylar canal, stamen height, anther size, and pollen size. Unlike several distylous species that have been investigated, the exine of pollen in P. sagittata was not strongly differentiated among the pollen types, and no differences in stigma cytochemistry were apparent. Features common to the floral morphs were a wet stigma, a hollow trilobed stylar canal separating into two sterile and one fertile canal, and a single anatropous ovule with a highly elaborated integumentary obturator. The similarity in structural features of the pollen tube pathway of P. sagittata to those found in monocotyledonous taxa with gametophytic self-incompatibility suggests that phylogenetic constraints may have influenced the evolution of trimorphic incompatibility in the Pontederiaceae.     

Mentor effects in the genus<Emphasis Type="Italic">Hieracium</Emphasis> S.STR. (<Emphasis Type="Italic">Compositae,Lactuceae</Emphasis>)

Self-incompatibility was demonstrated in the diploid taxaHieracium alpinum andH. umbellatum using isolation experiments. However, self-incompatibility was broken down in diploidH. alpinum under the influence of foreign pollen from another species of this genus (mentor effects) during a series of crossing experiments. Interestingly, failure of the SI system was also recorded in diploidH. alpinum in an intergeneric cross with the representative of the closely related genus ofPilosella. This is the first record of autogamy in the genusHieracium s.str. The possible evolutionary significance of this phenomenon is discussed.     

Cloning and expression of the UGA4 gene coding for the inducible GABA-specific transport protein of Saccharomyces cerevisiae

Japanese pear (Pyrus serotina Rehd.) exhibits gametophytic self-incompatibility. Following our previous findings that basic ribonucleases in the styles of Japanese pear are associated with self-incompatibility genes (S-RNases), stylar proteins with high pI values were analyzed by two-dimensional gel electrophoresis further to characterize S-RNases. A group of basic proteins of about 30 kDa associated with self-incompatibility genes were identified. These proteins contained sugar chains which reacted with concanavalin A and wheat germ agglutinin, and thus were designated as S-glycoproteins of Japanese pear. The fact that the S-glycoprotein was expressed at a much lower level in a self-compatible mutant than in the original variety suggested a role of S-glycoproteins in mediating self-incompatibility of Japanese pear. Immunoblot analysis indicated that S-glycoproteins are identical to previously identified S-RNases. The S-glycoproteins were predominantly expressed in the style, in the ovary in trace amounts, and not in leaf, pollen or germinated pollen. The N-terminal amino acid sequences of the S-glycoproteins showed homology not only with each other but also with those of the S-allele-associated proteins from plants of the family Solanaceae at levels of about 30–50%.     

内蒙古居群抗寒西伯利亚杏繁殖生态学研究

对内蒙古居群抗寒西伯利亚杏的12个种源同一树龄的102株进行雌蕊败育率、花粉量、花粉活力、柱头可授性及自交不亲和性进行研究,以明确西伯利亚杏主产地资源的花期生物学特性和繁殖特性,为杏杂交育种和资源利用提供理论依据。结果表明:(1)有86.27%的西伯利亚杏雌蕊败育率低于90%;73.53%的西伯利亚杏单朵花花粉量在1×104～5×104之间;86.27%的西伯利亚杏花粉活力低于50%,且寿命较短。(2)花苞在将开未开时,柱头已经具备一定的可授性,开花后1～4d内柱头可授性保持较高水平,第5天开始有下降趋势。(3)荧光显微观察结果显示,授粉后16h时,96.08%的杏花花粉管在花柱上部;授粉后24h时,74.51%的杏花花粉管仍在花柱上部;授粉后48h时,35.29%的杏花花粉管到达花柱中部;授粉后80h时,花粉管到达花柱下部的杏花约50%,但受精胚珠数为0。研究认为,西伯利亚杏基本为自交不亲和。