Tetsuyuki Entani

Comparative analysis of the self‐incompatibility (S‐) locus region of Prunus mume: identification of a pollen‐expressed F‐box gene with allelic diversity

Background: Self‐incompatibility (SI) in the Solanaceae, Rosaceae and Scrophulariaceae is gametophytically controlled by a single polymorphic locus, termed the S‐locus. To date, the only known S‐locus product is a polymorphic ribonuclease, termed S‐RNase, which is secreted by stylar tissue and thought to act as a cytotoxin that degrades the RNA of incompatible pollen tubes. However, understanding how S‐RNase causes S‐haplotype specific inhibition of pollen tubes has been hampered by the lack of a cloned pollen S‐determinant gene.

Collaborative non-self recognition system in S-RNase-based self-incompatibility.

Dissecting Self-Incompatibility Although the pollen may be available for a flower to fertilize itself, molecular determinants on the pollen and the pistil prevent inbreeding in a process termed self-incompatibility. In the Petunia self-incompatibility, if male determinants (F-box proteins) on pollen are recognized by a female ribonuclease determinant on the pistil, the pollen tube is killed when its ribosomal RNA is digested. Outcrossed fertilizations can occur because of allelic diversity in the female that fails to recognize its male counterparts; however, the genetic diversity of the ribonuclease gene is greater than that of the known F-box gene. Kubo et al. (p. 796; see the Perspective by Indriolo and Goring) have discovered that there are several related F-box genes in Petunia, each of which brings its own allelic diversity to bear—thus, increasing the variety of potential mating partners. A highly diverse set of (male) pollen-determinant proteins in Petunia recognizes non-self (female) pistil determinants. Self-incompatibility in flowering plants prevents inbreeding and promotes outcrossing to generate genetic diversity. In Solanaceae, a multiallelic gene, S-locus F-box (SLF), was previously shown to encode the pollen determinant in self-incompatibility. It was postulated that an SLF allelic product specifically detoxifies its non-self S-ribonucleases (S-RNases), allelic products of the pistil determinant, inside pollen tubes via the ubiquitin–26S-proteasome system, thereby allowing compatible pollinations. However, it remained puzzling how SLF, with much lower allelic sequence diversity than S-RNase, might have the capacity to recognize a large repertoire of non-self S-RNases. We used in vivo functional assays and protein interaction assays to show that in Petunia, at least three types of divergent SLF proteins function as the pollen determinant, each recognizing a subset of non-self S-RNases. Our findings reveal a collaborative non-self recognition system in plants.

Fine-Tuning of the Cytoplasmic Ca2+ Concentration Is Essential for Pollen Tube Growth

Pollen tube growth is crucial for the delivery of sperm cells to the ovule during flowering plant reproduction. Previous in vitro imaging of Lilium longiflorum and Nicotiana tabacum has shown that growing pollen tubes exhibit a tip-focused Ca2+ concentration ([Ca2+]) gradient and regular oscillations of the cytosolic [Ca2+] ([Ca2+]cyt) in the tip region. Whether this [Ca2+] gradient and/or [Ca2+]cyt oscillations are present as the tube grows through the stigma (in vivo condition), however, is still not clear. We monitored [Ca2+]cyt dynamics in pollen tubes under various conditions using Arabidopsis (Arabidopsis thaliana) and N. tabacum expressing yellow cameleon 3.60, a fluorescent calcium indicator with a large dynamic range. The tip-focused [Ca2+]cyt gradient was always observed in growing pollen tubes. Regular oscillations of the [Ca2+]cyt, however, were rarely identified in Arabidopsis or N. tabacum pollen tubes grown under the in vivo condition or in those placed in germination medium just after they had grown through a style (semi-in vivo condition). On the other hand, regular oscillations were observed in vitro in both growing and nongrowing pollen tubes, although the oscillation amplitude was 5-fold greater in the nongrowing pollen tubes compared with growing pollen tubes. These results suggested that a submicromolar [Ca2+]cyt in the tip region is essential for pollen tube growth, whereas a regular [Ca2+] oscillation is not. Next, we monitored [Ca2+] dynamics in the endoplasmic reticulum ([Ca2+]ER) in relation to Arabidopsis pollen tube growth using yellow cameleon 4.60, which has a lower affinity for Ca2+ compared with yellow cameleon 3.60. The [Ca2+]ER in pollen tubes grown under the semi-in vivo condition was between 100 and 500 μm. In addition, cyclopiazonic acid, an inhibitor of ER-type Ca2+-ATPases, inhibited growth and decreased the [Ca2+]ER. Our observations suggest that the ER serves as one of the Ca2+ stores in the pollen tube and cyclopiazonic acid-sensitive Ca2+-ATPases in the ER are required for pollen tube growth.

The Dominance of Alleles Controlling Self-Incompatibility in Brassica Pollen Is Regulated at the RNA Level

Self-incompatibility (SI) in Brassica is controlled sporophytically by the multiallelic S-locus. The SI phenotype of pollen in an S-heterozygote is determined by the relationship between the two S-haplotypes it carries, and dominant/recessive relationships often are observed between the two S-haplotypes. The S-locus protein 11 (SP11, also known as the S-locus cysteine-rich protein) gene has been cloned from many pollen-dominant S-haplotypes (class I) and shown to encode the pollen S-determinant. However, SP11 from pollen-recessive S-haplotypes (class II) has never been identified by homology-based cloning strategies, and how the dominant/recessive interactions between the two classes occur was not known. We report here the identification and molecular characterization of SP11s from six class II S-haplotypes of B. rapa and B. oleracea. Phylogenetic analysis revealed that the class II SP11s form a distinct group separated from class I SP11s. The promoter sequences and expression patterns of SP11s also were different between the two classes. The mRNA of class II SP11, which was detected predominantly in the anther tapetum in homozygotes, was not detected in the heterozygotes of class I and class II S-haplotypes, suggesting that the dominant/recessive relationships of pollen are regulated at the mRNA level of SP11s.

Design of Peptide Inhibitors for the Importin α/β Nuclear Import Pathway by Activity-Based Profiling

Despite the current availability of selective inhibitors for the classical nuclear export pathway, no inhibitor for the classical nuclear import pathway has been developed. Here we describe the development of specific inhibitors for the importin alpha/beta pathway using a novel method of peptide inhibitor design. An activity-based profile was created via systematic mutational analysis of a peptide template of a nuclear localization signal. An additivity-based design using the activity-based profile generated two peptides with affinities for importin alpha that were approximately 5 million times higher than that of the starting template sequence. The high affinity of these peptides resulted in specific inhibition of the importin alpha/beta pathway. These peptide inhibitors provide a useful tool for studying nuclear import events. Moreover, our inhibitor design method should enable the development of potent inhibitors from a peptide seed.

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 (Kd = 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.

Centromeric localization of an S-RNase gene in Petunia hybrida vilm

Abstract S-RNase has been identified to be an S-allele-specific stylar determinant contributing to the self-incompatibility response in Solanaceae. In order to examine the physical location of the S-RNase gene, multi-color fluorescence in situ hybridization (FISH) using the SB1-RNase cDNA probe and ribosomal RNA gene (rDNA) probe was performed on an SB1SB2 heterozygote of Petunia hybrida. The SB1-RNase gene was detected as a doublet signal close to the centromere of chromosome III. Next, we performed FISH using a large genome probe prepared from a λSB1–311 clone (20 kb) which contains the SB1-RNase gene and its 3´ flanking region. This probe hybridized to the centromeric regions of all P. hybrida chromosomes. Sequence analysis of the λSB1–311 clone revealed the presence of a repetitive sequence consisting of a novel 666 bp unit sequence. A subclone (pBS-SB1B5) containing this unit sequence also hybridized to all of the centromeric regions, confirming that this unit is the centromeric specific repetitive sequence. These data suggested that the SB1-RNase gene is located very close to (within a distance of 12 kb from) the centromeric-specific repetitive sequence. Likewise, the pBS-SB1B5 probe hybridized to the centromeric regions of all chromosomes in P. littoralis, another Petunia species. However, the probe did not hybridize to the centromere of the chromosomes from other species in Solanaceae. These results suggested that this centromeric repetitive sequence might be a genus-specific one.

Cytoplasmic Ca2+ changes dynamically during the interaction of the pollen tube with synergid cells

The directional growth of the pollen tube from the stigma to the embryo sac in the ovules is regulated by pollen-pistil interactions based on intercellular communication. Although pollen tube growth is regulated by the cytoplasmic Ca2+ concentration ([Ca2+]cyt), it is not known whether [Ca2+]cyt is involved in pollen tube guidance and reception. Using Arabidopsis expressing the GFP-based Ca2+-sensor yellow cameleon 3.60 (YC3.60) in pollen tubes and synergid cells, we monitored Ca2+ dynamics in these cells during pollen tube guidance and reception under semi-in vivo fertilization conditions. In the pollen tube growing towards the micropyle, pollen tubes initiated turning within 150 μm of the micropylar opening; the [Ca2+]cyt in these pollen tube tips was higher than in those not growing towards an ovule in assays with myb98 mutant ovules, in which pollen tube guidance is disrupted. These results suggest that attractants secreted from the ovules affect Ca2+ dynamics in the pollen tube. [Ca2+]cyt in synergid cells did not change when the pollen tube grew towards the micropyle or entered the ovule. Upon pollen tube arrival at the synergid cell, however, [Ca2+]cyt oscillation began at the micropylar pole of the synergid, spreading towards the chalazal pole. Finally, [Ca2+]cyt in the synergid cell reached a maximum at pollen tube rupture. These results suggest that signals from the pollen tube induce Ca2+ oscillations in synergid cells, and that this Ca2+ oscillation is involved in the interaction between the pollen tube and synergid cell.

Actin Dynamics in Papilla Cells of Brassica rapa during Self- and Cross-Pollination

The self-incompatibility system of the plant species Brassica is controlled by the S-locus, which contains S-RECEPTOR KINASE (SRK) and S-LOCUS PROTEIN11 (SP11). SP11 binding to SRK induces SRK autophosphorylation and initiates a signaling cascade leading to the rejection of self pollen. However, the mechanism controlling hydration and germination arrest during self-pollination is unclear. In this study, we examined the role of actin, a key cytoskeletal component regulating the transport system for hydration and germination in the papilla cell during pollination. Using rhodamine-phalloidin staining, we showed that cross-pollination induced actin polymerization, whereas self-pollination induced actin reorganization and likely depolymerization. By monitoring transiently expressed green fluorescent protein fused to the actin-binding domain of mouse talin, we observed the concentration of actin bundles at the cross-pollen attachment site and actin reorganization and likely depolymerization at the self-pollen attachment site; the results correspond to those obtained by rhodamine-phalloidin staining. We further showed that the coat of self pollen is sufficient to mediate this response. The actin-depolymerizing drug cytochalasin D significantly inhibited pollen hydration and germination during cross-pollination, further emphasizing a role for actin in these processes. Additionally, three-dimensional electron microscopic tomography revealed the close association of the actin cytoskeleton with an apical vacuole network. Self-pollination disrupted the vacuole network, whereas cross-pollination led to vacuolar rearrangements toward the site of pollen attachment. Taken together, our data suggest that self- and cross-pollination differentially affect the dynamics of the actin cytoskeleton, leading to changes in vacuolar structure associated with hydration and germination.

Gene duplication and genetic exchange drive the evolution of S-RNase-based self-incompatibility in Petunia

Self-incompatibility (SI) systems in flowering plants distinguish self- and non-self pollen to prevent inbreeding. While other SI systems rely on the self-recognition between specific male- and female-determinants, the Solanaceae family has a non-self recognition system resulting in the detoxification of female-determinants of S-ribonucleases (S-RNases), expressed in pistils, by multiple male-determinants of S-locus F-box proteins (SLFs), expressed in pollen. It is not known how many SLF components of this non-self recognition system there are in Solanaceae species, or how they evolved. We identified 16-20 SLFs in each S-haplotype in SI Petunia, from a total of 168 SLF sequences using large-scale next-generation sequencing and genomic polymerase chain reaction (PCR) techniques. We predicted the target S-RNases of SLFs by assuming that a particular S-allele must not have a conserved SLF that recognizes its own S-RNase, and validated these predictions by transformation experiments. A simple mathematical model confirmed that 16-20 SLF sequences would be adequate to recognize the vast majority of target S-RNases. We found evidence of gene conversion events, which we suggest are essential to the constitution of a non-self recognition system and also contribute to self-compatible mutations.