Zhaoyu Gu

Apple MdABCF assists in the transportation of S-RNase into pollen tubes

Self-incompatibility (SI) is a reproductive isolation mechanism in flowering plants. Plants in the Solanaceae, Rosaceae and Plantaginaceae belong to the gametophytic self-incompatibility type. S-RNase, which is encoded by a female-specific gene located at the S locus, degrades RNA in the pollen tube and causes SI. Recent studies have provided evidence that S-RNase is transported non-selectively into the pollen tube, but have not specified how this transportation is accomplished. We show here that the apple (Malus domestica) MdABCF protein, which belongs to group F of the ABC transporter family, assists in transportation of S-RNase into the pollen tube. MdABCF is located in the pollen tube membrane and interacts with S-RNase. S-RNase was unable to enter the pollen tube when MdABCF was silenced by antisense oligonucleotide transfection. Our results show that MdABCF assists in transportation of either self or non-self S-RNase into the pollen tube. Moreover, MdABCF coordinates with the cytoskeleton to transport S-RNase. Blockage of S-RNase transport disrupts self-incompatibility in this system.

The Microtubule Cytoskeleton and Pollen Tube Golgi Vesicle System are Required for in Vitro S-RNase Internalization and Gametic Self-Incompatibility in Apple

S-RNase is the female determinant of gametophytic self-incompatibility in apple and is usually considered to be the reason for rejection of pollen. In this study, we investigated the role of microtubules (MTs) in internalization of S-RNases by pollen tubes cultured in vitro. The results showed that S-RNase was imported into the pollen tube where it inhibits pollen tube growth, and that S-RNase is co-localized with the Golgi vesicle during the internalization process. Moreover, MT depolymerization is observed following accumulation of S-RNases in the pollen cytosol. On the other hand, S-RNase was prevented from entering the pollen tube when the pollen was treated with the actin filament (AF) inhibitor latrunculin A (LatA), the MT inhibitor oryzalin, or the MT stabilizer taxol at subtoxic concentrations. These hindered the construction of the MT, with pollen tubes capable of growth under these conditions. Pollen tubes showed improved growth in self-pollinated styles that were pre-treated with taxol. This suggests that cytoskeleton antagonists can prevent S-RNase-mediated inhibition of pollen tubes in vivo by blocking S-RNase internalization. These results suggest that an intact and dynamic cytoskeleton is required for the in vitro internalization of S-RNase, as shown by the effects of various cytoskeleton inhibitors. S-RNase internalization takes place via a membrane/cytoskeleton-based Golgi vesicle system, which can also affect self-incompatibility in apple.

A novel gene, MdSSK1, as a component of the SCF complex rather than MdSBP1 can mediate the ubiquitination of S-RNase in apple

Summary The related components of the SCF complex in apple were cloned and it was proved that an SCF complex containing MdSSK1 rather than MdSBP1 can mediate the ubiquitination of S-RNase.

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

Abstract 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.

A CBL gene, MdCBL5, controls the calcium signal and influences pollen tube growth in apple

As a signaling molecule in plants and animals, calcium plays important roles in cell growth and development. A concentration gradient of calcium in the apex of tip-growing cells regulates polarized growth. In this study, we cloned the gene encoding a calcineurin B subunit protein, MdCBL5, in “Ralls Janet” apple. We found that MdCBL5 was strongly expressed in pollen and that the encoded protein contained the conserved calcineurin EF hand domain. Antisense-mediated silencing of MdCBL5 disrupted the calcium ion concentration gradient in the pollen tube apex and inhibited pollen tube growth. During the self-incompatibility response in apple, S-RNase uptake disrupts the calcium gradient in the pollen tube apex and inhibits pollen tube growth. Quantitative PCR analysis indicated that MdCBL5 was downregulated in pollen tubes treated with S-RNase. We confirmed the interaction between MdCBL5 and S-RNase using yeast two-hybrid, pull-down, and bimolecular fluorescence complementation (BiFC) experiments. These results show that MdCBL5 is a calcium signaling factor that interacts with S-RNases and regulates pollen tube growth and is itself likely regulated by S-RNase during the self-incompatibility response.

A Single-Nucleotide Polymorphism in the Promoter of a Hairpin RNA Contributes to Alternaria alternata Leaf Spot Resistance in Apple (Malus × domestica)

A single-nucleotide polymorphism in a hairpin RNA promoter contributes to Alternaria alternata leaf spot resistance in apple and could serve as a marker to distinguish susceptible versus resistant apple cultivars. Apple leaf spot caused by the Alternaria alternata f. sp mali (ALT1) fungus is one of the most devastating diseases of apple (Malus × domestica). We identified a hairpin RNA (hpRNA) named MdhpRNA277 that produces small RNAs and is induced by ALT1 infection in ‘NGR196’ apple. MdhpRNA277 produces mdm-siR277-1 and mdm-siR277-2, which target five resistance (R) genes that are expressed at high levels in the resistant apple variety ‘Hanfu’ and at low levels in the susceptible variety ‘NGR196’ following ALT1 infection. MdhpRNA277 was strongly induced in ‘NGR196’ but not ‘Hanfu’ following ALT1 inoculation. MdhpRNA277 promoter activity was much stronger in inoculated ‘NGR196’ versus ‘Hanfu’. We identified a single-nucleotide polymorphism (SNP) in the MdhpRNA277 promoter region between ‘NGR196’ (pMdhpRNA277-NGR196) and ‘Hanfu’ (pMdhpRNA277-HF). The transcription factor MdWHy binds to pMdhpRNA277-NGR196, but not to pMdhpRNA277-HF. Transgenic ‘GL-3’ apple expressing pMdhpRNA277-NGR196:MdhpRNA277 was more susceptible to ALT1 infection than plants expressing pMdhpRNA277-HF:MdhpRNA277 due to induced mdm-siR277 accumulation and reduced expression of the five target R genes. We confirmed that the SNP in pMdhpRNA277 is associated with A. alternata leaf spot resistance by crossing. This SNP could be used as a marker to distinguish between apple varieties that are resistant or susceptible to A. alternata leaf spot.

Apple S‐RNase triggers inhibition of tRNA aminoacylation by interacting with a soluble inorganic pyrophosphatase in growing self‐pollen tubes in vitro

Apple exhibits S-RNase-based self-incompatibility (SI), in which S-RNase plays a central role in rejecting self-pollen. It has been proposed that the arrest of pollen growth in SI of Solanaceae plants is a consequence of the degradation of pollen rRNA by S-RNase; however, the underlying mechanism in Rosaceae is still unclear. Here, we used S2 -RNase as a bait to screen an apple pollen cDNA library and characterized an apple soluble inorganic pyrophosphatase (MdPPa) that physically interacted with S-RNases. When treated with self S-RNases, apple pollen tubes showed a marked growth inhibition, as well as a decrease in endogenous soluble pyrophosphatase activity and elevated levels of inorganic pyrophosphate (PPi). In addition, S-RNase was found to bind to two variable regions of MdPPa, resulting in a noncompetitive inhibition of its activity. Silencing of MdPPa expression led to a reduction in pollen tube growth. Interestingly, tRNA aminoacylation was inhibited in self S-RNase-treated or MdPPa-silenced pollen tubes, resulting in the accumulation of uncharged tRNA. Furthermore, we provide evidence showing that this disturbance of tRNA aminoacylation is independent of RNase activity. We propose an alternative mechanism differing from RNA degradation to explain the cytotoxicity of the S-RNase apple SI process.

SLFL Genes Participate in the Ubiquitination and Degradation Reaction of S-RNase in Self-compatible Peach

It has been proved that the gametophytic self-incompatibility (GSI), mainly exists in Rosaceae and Solanaceae, is controlled by S genes, which are two tightly linked genes located at highly polymorphic S-locus: the S-RNase for pistil specificity and the F-box gene (SFB/SLF) for pollen specificity, respectively. However, the roles of those genes in SI of peach are still a subject of extensive debate. In our study, we selected 37 representative varieties according to the evolution route of peach and identified their S genotypes. We cloned pollen determinant genes mutated PperSFB1m, PperSFB2m, PperSFB4m, and normal PperSFB2, and style determinant genes PperS1-RNase, PperS2-RNase, PperS2m-RNase, and PperS4-RNase. The mutated PperSFBs encode truncated SFB proteins due to a fragment insertion. The truncated PperSFBs and normal PperSFB2 interacted with PperS-RNases demonstrated by Y2H. Normal PperSFB2 was divided into four parts: box, box-V1, V1-V2, and HVa-HVb. The box domain of PperSFB2 did not interact with PperS-RNases, both of the box-V1 and V1-V2 had interactions with PperS-RNases, while the hypervariable region of PperSFB2 HVa-HVb only interacted with PperS2-RNase showed by Y2H and BiFC assay. Bioinformatics analysis of peach genome revealed that there were other F-box genes located at S-locus, and of which three F-box genes were specifically expressed in pollen, named as PperSLFL1, PperSLFL2, and PperSLFL3, respectively. In phylogenetic analysis PperSLFLs clustered with Maloideae SFBB genes, and PperSFB genes were clustered into the other group with other SFB genes of Prunus. Protein interaction analysis revealed that the three PperSLFLs interacted with PperSSK1 and PperS-RNases with no allelic specificity. In vitro ubiquitination assay showed that PperSLFLs could tag ubiquitin molecules onto PperS-RNases. The above results suggest that three PperSLFLs are the appropriate candidates for the “general inhibitor,” which would inactivate the S-RNases in pollen tubes, involved in the self-incompatibility of peach.

SLFL Genes Participate in the Ubiquitination and Degradation of S-RNase in Self-Compatible Chinese Peach

The gametophytic self-incompatibility (SI) mediated by S-RNase of Rosaceae, Solanaceae and Plantaginaceae, is controlled by two tightly linked genes located at highly polymorphic S-locus: the S-RNase for pistil specificity and the F-box gene (SFB/SLF) for pollen specificity, respectively. The F-box gene of peach (Prunus persica) is S haplotype-specific F-box (SFB). In this study, we selected 37 representative varieties according to the evolution route of peach and identified their S genotypes. We cloned pollen determinant genes mutant PperSFB1m, PperSFB2m, PperSFB4m and normal PperSFB2, and style determinant genes S1-RNase, S2-RNase, S2m-RNase and S4-RNase. Mutant PperSFBs were translated terminated prematurely because of fragment insertion. Yeast two-hybrid showed that mutant PperSFBs and normal PperSFB2 interacted with all S-RNases. Normal PperSFB2 was divided into four parts: box, box-V1, V1-V2 and HVa-HVb. Protein interaction analyses showed that the box portion did not interact with S-RNases, both of the box-V1 and V1-V2 had interactions with S-RNases, while the hypervariable region of PperSFB2 HVa-HVb only interacted with S2-RNase. Bioinformatics analysis of peach genome revealed that there were other F-box genes located at S-locus, and of which three F-box genes were specifically expressed in pollen, namely PperSLFL1, PperSLFL2 and PperSLFL3, respectively. Phylogenetic analysis showed that PperSFBs and PperSLFLs were classified into two different clades. Yeast two-hybrid analysis revealed that as with PperSFBs, the three F-box proteins interacted with PperSSK1. Yeast two-hybrid and BiFC showed that PperSLFLs interacted with S-RNases with no allelic specificity. In vitro ubiquitination assay showed that PperSLFLs could tag ubiquitin molecules to PperS-RNases. In all, the above results suggest that three PperSLFLs are the appropriate candidates for the ‘general inhibitor’, which would inactivate the S-RNases in pollen tubes, and the role of three PperSLFL proteins is redundant, as S-RNase repressors involved in the self-incompatibility of peach.