Identification of residues in a hydrophilic loop of the Papaver rhoeas S protein that play a crucial role in recognition of incompatible pollen.

The self-incompatibility response involves S allele-specific recognition between stigmatic S proteins and incompatible pollen. This response results in pollen inhibition. Defining the amino acid residues within the stigmatic S proteins that participate in S allele-specific inhibition of incompatible pollen is essential for the elucidation of the molecular basis of the self-incompatibility response. We have constructed mutant derivatives of the S1 protein from Papaver rhoeas by using site-directed mutagenesis and have tested their biological activity. This has enabled us to identify amino acid residues in the stigmatic S proteins of P. rhoeas that are required for S-specific inhibition of incompatible pollen. We report here the identification of several amino acid residues in the predicted hydrophilic loop 6 of the P. rhoeas stigmatic S1 protein that are involved in the inhibition of S1 pollen. Mutation of the only hypervariable amino acid, which is situated in this loop, resulted in the complete loss of ability of the S protein to inhibit S1 pollen. This clearly demonstrates that this residue plays a crucial role in pollen recognition and may also participate in defining allelic specificity. We have also established the importance of highly conserved amino acids adjacent to this hypervariable site. Our studies demonstrate that both variable and conserved amino acids in the region of the S protein corresponding to surface loop 6 are key elements that play a role in the recognition and inhibition of incompatible pollen in the pollen-pistil self-incompatibility reaction.     

Identification of a membrane glycoprotein in pollen of Papaver rhoeas which binds stigmatic self-incompatibility (S-) proteins

Recombinant stigmatic self-incompatibility (S-) proteins from Papaver rhoeas have previously been shown to be biologically functional, inhibiting only pollen of the same S -genotype. In an attempt to identify molecules in pollen which interact with these proteins, Western ligand blotting was used, with the recombinant S-proteins as probes followed by immunodetection of the bound S-protein. This revealed that pollen of all S -genotypes tested contained a 70–120 kDa protein which bound the S₁, S₃ and S₈ proteins in an indistinguishable manner. Binding was destroyed by pretreatment of blots with periodate, implicating a glycoprotein with activity being dependent on the glycan moiety. The activity completely partitioned into the detergent phase on condensation with Triton X-114, indicating an integral membrane protein. On aqueous two-phase partition of microsomal membrane preparations, the majority of the binding activity partitioned into the upper phase, suggesting that the molecule is located in the plasma membrane.
No equivalent binding could be detected in extracts of leaves, stems, roots or stigmas of P. rhoeas , nor in immature anthers. Identical activity was detected in pollen of some other Papaver species, but not in pollen of Brassica oleracea, Nicotiana tabacum or Petunia hybrida . The presence in mature pollen of P. rhoeas of a plasma membrane glycoprotein which binds S-proteins from the stigma of the same species, albeit in a non S -allele-specific manner, strongly suggests that this molecule has a role somewhere in the interaction of the stigma proteins with pollen. The activity is not that expected of an S-specific receptor, but by analogy with certain mammalian systems the molecule may act as an accessory receptor, or co-receptor, the presence of which may be essential for a functional interaction with an S-specific receptor.     

Evidence for DNA fragmentation triggered in the self-incompatibility response in pollen of Papaver rhoeas

Studies of the molecular and biochemical basis of self-incompatibility (SI) in Papaver rhoeas have revealed much about the signalling pathways triggered in pollen early in this response. The aim of the current investigation was to begin to study downstream events in order to elucidate some of the later cellular responses involved in the SI response and identification of the mechanisms controlling the irreversible inhibition of pollen tube growth. We have used the FragEL assay to investigate if there is any evidence for DNA fragmentation stimulated in pollen of P. rhoeas in an S-specific manner. Our data clearly demonstrate that S proteins are responsible for triggering this, specifically in incompatible, and not compatible, pollen. DNA fragmentation was first detected in incompatible pollen tubes 4 h after challenge with S proteins, and continued to increase for a further 10 h. This provides the first evidence, to our knowledge, that this phenomenon is associated with the SI response. We also demonstrate that mastoparan, which increases [Ca2+]i, also triggers DNA fragmentation in these pollen tubes, thereby implicating an involvement of Ca2+ signalling in this process. Together, our data represent a significant breakthrough in understanding of the SI response in Papaver pollen.     

The stylar 120 kDa glycoprotein is required for S-specific pollen rejection in Nicotiana

S-RNase participates in at least three mechanisms of pollen rejection. It functions in S-specific pollen rejection (self-incompatibility) and in at least two distinct interspecific mechanisms of pollen rejection in Nicotiana. S-specific pollen rejection and rejection of pollen from Nicotiana plumbaginifolia also require additional stylar proteins. Transmitting-tract-specific (TTS) protein, 120 kDa glycoprotein (120K) and pistil extensin-like protein III (PELP III) are stylar glycoproteins that bind S-RNase in vitro and are also known to interact with pollen. Here we tested whether these glycoproteins have a direct role in pollen rejection. 120K shows the most polymorphism in size between Nicotiana species. Larger 120K-like proteins are often correlated with S-specific pollen rejection. Sequencing results suggest that the polymorphism primarily reflects differences in glycosylation, although indels also occur in the predicted polypeptides. Using RNA interference (RNAi), we suppressed expression of 120K to determine if it is required for S-specific pollen rejection. Transgenic SC N. plumbaginifolia x SI Nicotiana alata (S105S105 or SC10SC10) hybrids with no detectable 120K were unable to perform S-specific pollen rejection. Thus, 120K has a direct role in S-specific pollen rejection. However, suppression of 120K had no effect on rejection of N. plumbaginifolia pollen. In contrast, suppression of HT-B, a factor previously implicated in S-specific pollen rejection, disrupts rejection of N. plumbaginifolia pollen. Thus, S-specific pollen rejection and rejection of N. plumbaginifolia pollen are mechanistically distinct, because they require different non-S-RNase factors.     

A self-fertile mutant of Phalaris produces an S protein with reduced thioredoxin activity

Gametophytic self-incompatibility in the Phalaris coerulescens is controlled by two unlinked genes, S and Z . Isolation of the S gene from the pollen of this grass species indicated that the C terminus has significant hemology with thioredoxin H proteins. The protein from the C terminus, expressed in Escherichia coli , exhibits thioredoxin-like activity. This paper demonstrates that the C terminus of the S protein from an S complete mutant shows significant reduction in thioredoxin activity when compared with the wild-type form. Both pollen and stigma have lost self-incompatibility in this mutant. Close examination of the lesions, which were found only in the C terminus of the mutant gene suggests that the substitution of a serine by an arginine is responsible for the reduced enzymatic activity. The association between reduced activity and the loss of the self-incompatibility provides evidence for a role of thioredoxin activity in the self-incompatibility reaction of this species.     

芸苔属自交不亲和细胞信号转导的研究进展

在芸苔属植物的自交不亲和细胞信号转导过程中,信号分子-SCR配体是由花粉粒产生的,被柱头乳突细胞SRK受体识别后,进行细胞内信号转导。这对受体-配体是两个由S位点编码的且高度多态的蛋白质,它们决定着自交不亲和反应。配体是位于花粉粒表面的一个小的胞被蛋白,由SCR基因编码;受体是位于柱头乳突细胞原生质膜上的跨膜的蛋白质激酶,由SRK基因编码。在自交授粉过程中,配体SCR和受体SRK的相互作用激活了受体SRK,被激活的SRK通过其下游组分ARC1介导底物的泛肽化,然后泛肽化的底物在蛋白酶体/CSN中被降解,从而导致了自交不亲和性反应。这些降解的底物可能是促进花粉水合、萌发和花粉管生长的雌蕊亲和因子。主要针对芸苔属自交不亲和细胞信号转导作一综述。     

Characterization of the SP11/SCR high-affinity binding site involved in self/nonself recognition in brassica self-incompatibility

In Brassica self-incompatibility, the recognition of self/nonself pollen grains, is controlled by the S-locus, which encodes three highly polymorphic proteins: S-locus receptor kinase (SRK), S-locus protein 11 (SP11; also designated S-locus Cys-rich protein), and S-locus glycoprotein (SLG). SP11, located in the pollen coat, determines pollen S-haplotype specificity, whereas SRK, located on the plasma membrane of stigmatic papilla cells, determines stigmatic S-haplotype specificity. SLG shares significant sequence similarity with the extracellular domain of SRK and is abundant in the stigmatic cell wall, but its function is controversial. We previously showed that SP11 binds directly to its cognate SRK with high affinity (K(d) = 0.7 nM) and induces its autophosphorylation. We also found that an SLG-like, 60-kD protein on the stigmatic membrane forms a high-affinity binding site for SP11. Here, we show that the 60-kD stigmatic membrane protein is a truncated form of SRK containing the extracellular domain, transmembrane domain, and part of the juxtamembrane domain. A transiently expressed, membrane-anchored form of SRK exhibits high-affinity binding to SP11, whereas the soluble SRK (eSRK) lacking the transmembrane domain exhibits no high-affinity binding, as is the case with SLG. The different binding affinities of the membrane-anchored SRK and soluble eSRK or SLG will be significant for the specific perception of SP11 by SRK.     

Ribonuclease activity of Petunia inflata S proteins is essential for rejection of self-pollen.

S proteins, pistil-specific ribonucleases that cosegregate with S alleles, have previously been shown to control rejection of self-pollen in Petunia inflata and Nicotiana alata, two solanaceous species that display gametophytic self-incompatibility. The ribonuclease activity of S proteins was thought to degrade RNA of self-pollen tubes, resulting in the arrest of their growth in the style. However, to date no direct evidence has been obtained. Here, the ribonuclease activity of S3 protein of P. inflata was abolished, and the effect on the pistil's ability to reject S3 pollen was examined. The S3 gene was mutagenized by replacing the codon for His-93, which has been implicated in ribonuclease activity, with a codon for asparagine, and the mutant S3 gene was introduced into P. inflata plants of S1S2 genotype. Two transgenic plants produced a level of mutant S3 protein comparable to that of the S3 protein produced in self-incompatible S1S3 and S2S3 plants, yet they failed to reject S3 pollen. The mutant S3 protein produced in these two transgenic plants did not exhibit any detectable ribonuclease activity. We have previously shown that transgenic plants (S1S2 plants transformed with the wild-type S3 gene) producing a normal level of wild-type S3 protein acquired the ability to reject S3 pollen completely. Thus, the results reported here provide direct evidence that the biochemical mechanism of gametophytic self-incompatibility in P. inflata involves the ribonuclease activity of S proteins.     

The Papaver self-incompatibility pollen S-determinant, PrpS, functions in Arabidopsis thaliana

Many angiosperms use specific interactions between pollen and pistil proteins as "self" recognition and/or rejection mechanisms to prevent self-fertilization. Self-incompatibility (SI) is encoded by a multiallelic S locus, comprising pollen and pistil S-determinants. In Papaver rhoeas, cognate pistil and pollen S-determinants, PrpS, a pollen-expressed transmembrane protein, and PrsS, a pistil-expressed secreted protein, interact to trigger a Ca(2+)-dependent signaling network, resulting in inhibition of pollen tube growth, cytoskeletal alterations, and programmed cell death (PCD) in incompatible pollen. We introduced the PrpS gene into Arabidopsis thaliana, a self-compatible model plant. Exposing transgenic A. thaliana pollen to recombinant Papaver PrsS protein triggered remarkably similar responses to those observed in incompatible Papaver pollen: S-specific inhibition and hallmark features of Papaver SI. Our findings demonstrate that Papaver PrpS is functional in a species with no SI system that diverged ~140 million years ago. This suggests that the Papaver SI system uses cellular targets that are, perhaps, common to all eudicots and that endogenous signaling components can be recruited to elicit a response that most likely never operated in this species. This will be of interest to biologists interested in the evolution of signaling networks in higher plants.     

Changes in pollen tube behaviour induced by carbon dioxide and their role in overcoming self-incompatibility in Brassica

Summary Comparative studies on self-pollination after the application of high concentrations of CO₂ gas, which is known to overcome the self-incompatibility reaction in Cruciferous species, have revealed significant changes in the pollen tubes of germinating grains prior to their penetration into the papilla cells. A remarkable increase in the width of the pollen tube was induced by treating the stigmatic papillae with high CO₂ concentrations. The width of the pollen tube appeared to be greatest with CO₂ concentrations ranging from 3% to 5%; these concentrations were also optimal for tube penetration. Callose accumulation was extensively induced in the stigmatic papilla with 10%–20% of CO₂, although a typical callosic reaction remained through the ranges appropriate for blocking self-incompatibility. Observations using the scanning electron microscope (SEM) after pollination revealed that compatible pollen tubes in cross-pollinations fused completely to the papular surface during tube penetration, while in self-pollination, pollen tubes remained on the papilla with some additional diffusate. In the case of CO₂ treatment for self-pollination, some pollen tubes behaved very similarly to the incompatible or compatible ones already described, while others were different from both of them: they showed a complete fusion, similar to compatible ones, with additional diffusate, similar to incompatible ones. These responses of the pollen and stigma to high CO₂ concentrations are discussed with respect to their effect upon the expression of self-incompatibility.     

Increased Phosphorylation of a 26-kD Pollen Protein Is Induced by the Self-Incompatibility Response in Papaver rhoeas

We have investigated whether specific protein phosphorylation events are induced in Papaver rhoeas pollen as a consequence of the self-incompatibility (SI) response. Pollen grown in vitro in the presence of 32P-orthophosphate was challenged with biologically active recombinant S proteins, and pollen proteins were extracted and analyzed. The results provide strong evidence that the increased phosphorylation of a 26-kD protein of pl 6.2, p26, is specifically induced by the SI response. This phosphorylation event occurs in living pollen tubes and was observed specifically when pollen was challenged with S proteins that are incompatible with the S alleles carried by the pollen and not when pollen was challenged with compatible or incompatible heat-denatured S proteins. Further characterization demonstrated that p26 comprises two phosphoproteins, p26.1 and p26.2, that are found in soluble and microsomal fractions, respectively. Increased phosphorylation of p26.1 is implicated in the SI response and appears to be Ca2+ and calmodulin dependent. These data argue for the involvement of a Ca2+-dependent protein kinase requiring calmodulin-like domains, whose activation comprises an intracellular signal mediating the SI response in P. rhoeas pollen.     

Ca2+-independent phosphorylation of a 68 kDa pollen protein is stimulated by the self-incompatibility response in Papaver rhoeas

The self-incompatibility (SI) response in Papaver rhoeas involves a Ca²⁺-based signalling pathway, which mediates the SI-specific inhibition of incompatible pollen. We have previously reported the identification of p26.1, a pollen protein whose phosphorylation was increased specifically as a consequence of the SI response. We have investigated whether further specific protein phosphorylation events are induced in P. rhoeas pollen. Here we report the identification of an additional pollen protein, p68, which also responds to S proteins by an increase in its phosphorylation state. This phosphorylation event occurs in living pollen tubes grown in vitro , and can be observed specifically when pollen is challenged with biologically active S proteins that are incompatible with the S alleles carried by the pollen and not when pollen was challenged with compatible S proteins. The timing of the increase in phosphorylation of p68 is temporally later than that of p26.1, occurring between 240 sec and 400 sec after challenge. This suggests that its phosphorylation is downstream of p26.1 in the SI signalling pathway(s). Surprisingly, the kinases responsible for the phosphorylation of p68 are not Ca²⁺-dependent. This, and the later timing of the p68 response, suggests that a 'second wave' of Ca²⁺-independent signalling may follow the initial Ca²⁺-dependent SI signalling. This indicates that the SI signalling pathway(s) in pollen may be quite complex.     

Identification of major lysine residues of S(3)-RNase of Petunia inflata involved in ubiquitin-26S proteasome-mediated degradation in vitro

S-RNase-based self-incompatibility has been identified in three flowering plant families, including the Solanaceae, and this self/non-self recognition mechanism between pollen and pistil is controlled by two polymorphic genes at the S -locus, S-RNase and S-locus F-box ( SLF ). S-RNase is produced in the pistil and taken up by pollen tubes in a non- S- haplotype-specific manner. How an allelic product of SLF interacts with self and non-self S-RNases to result in growth inhibition of self pollen tubes is not completely understood. One model predicts that SLF targets non-self S-RNases for ubiquitin/26S proteasome-mediated degradation, thereby only allowing self S-RNase to exert cytotoxic activity inside a pollen tube. To test this model, we studied whether any of the 20 lysine residues in S₃-RNase of Petunia inflata might be targets for ubiquitination. We identified six lysines near the C-terminus for which mutation to arginine significantly reduced ubiquitination and degradation of the mutant S₃-RNase, GST:S₃-RNase (K141–164R) in pollen tube extracts. We further showed that GST:S₃-RNase (K141–164R) and GST:S₃-RNase had similar RNase activity, suggesting that their degradation was probably not caused by an ER-associated protein degradation pathway that removes mis-folded proteins. Finally, we showed that PiSBP1 ( P. inflata S-RNase binding protein 1), a potential RING-HC subunit of the PiSLF ( P. inflata SLF)-containing E3-like complex, could target S-RNase for ubiquitination in vitro . All these results suggest that ubiquitin/26S proteasome-dependent degradation of S-RNase may be an integral part of the S-RNase-based self-incompatibility mechanism.     

A Mutant S3 RNase of Petunia inflata Lacking RNase Activity Has an Allele-Specific Dominant Negative Effect on Self-Incompatibility Interactions

Gametophytic self-incompatibility in the Solanaceae is controlled by a multiallelic locus called the S locus. Growth of pollen tubes in the pistil is inhibited when the pollen has one of the two S alleles carried by the pistil. The products of a number of pistil S alleles[mdash]S proteins or S RNases[mdash]have been identified, and their role in controlling the pistil's ability to reject self-pollen has been positively established. In contrast, the existence of pollen S allele products has so far been inferred entirely from genetic evidence. Here, we introduced a modified S3 gene of Petunia inflata encoding an S3 RNase lacking RNase activity into P. inflata plants of the S2S3 genotype to determine whether the production of the mutant protein, designated S3(H93R), would have any effect on the ability of the transgenic plants to reject S2 and S3 pollen. Analysis of the self-incompatibility behavior of 49 primary transgenic plants and the progeny of three plants (H30, H37, and H40) that produced S3(H93R) in addition to producing wild-type levels of endogenous S2 and S3 RNases revealed that S3(H93R) had a dominant negative effect on the function of the S3 RNase in rejecting self-pollen; however, it had no effect on the function of the S2 RNase. One likely explanation of the results is that S3(H93R) competes with the S3 RNase for binding to a common molecule, which is presumably the product of the pollen S3 allele.     

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.     

Self-incompatibility in Papaver: A MAP kinase signals to trigger programmed cell death

Self-incompatibility (SI) in higher plants prevents inbreeding through specific recognition and rejection of incompatible (“self”) pollen. In Papaver rhoeas, S proteins encoded by the pistil component of the S-locus interact with incompatible pollen, triggering a Ca²⁺-dependent signaling network resulting in programmed cell death (PCD). We recently showed that a mitogen-activated protein kinase (MAPK) is involved in loss of pollen viability, stimulation of caspase-3-like (DEVDase) activity and later DNA fragmentation in incompatible pollen. As p56 appears to be the only MAPK activated by SI, our data suggest that p56 could be the MAPK responsible for mediating SI-induced PCD.Key words: MAPK, self-incompatibility, PCD, caspase-3-like activity, Papaver rhoeas     

芸苔属自交不亲和细胞信号转导的研究进展

在芸苔属植物的自交不亲和细胞信号转导过程中,信号分子-SCR配体是由花粉粒产生的,被柱头乳突细胞SRK受体识别后,进行细胞内信号转导.这对受体-配体是两个由S位点编码的且高度多态的蛋白质,它们决定着自交不亲和反应.配体是位于花粉粒表面的一个小的胞被蛋白,由SCR基因编码;受体是位于柱头乳突细胞原生质膜上的跨膜的蛋白质激酶,由SRK基因编码.在自交授粉过程中,配体SCR和受体SRK的相互作用激活了受体SRK,被激活的SRK通过其下游组分ARC1介导底物的泛肽化,然后泛肽化的底物在蛋白酶体/CSN中被降解,从而导致了自交不亲和性反应.这些降解的底物可能是促进花粉水合、萌发和花粉管生长的雌蕊亲和因子.主要针对芸苔属自交不亲和细胞信号转导作一综述.