The ScRALF3 secreted peptide is involved in sporophyte to gametophyte signalling and affects pollen mitosis I.

Signalling events through small peptides are essential in multiple aspects of plant reproduction. The ScRALF3 Solanum chacoense Rapid Alkalinization Factor (RALF) peptide was previously shown to regulate multiple aspects of cell-cell communication between the surrounding sporophytic tissue and the female gametophyte during ovule development. We analysed the global expression pattern of ScRALF3 with GUS reporter gene under control of the ScRALF3 promoter and validated it with in situ hybridisation. To better understand the role of ScRALF3 we used three different RNA interference (RNAi) lines that reduced the expression of ScRALF3 during pollen development. Both expression methods showed the presence of ScRALF3 in different tissues, including stigma, style, vascular tissues and during stamen development. Down-regulation of ScRALF3 expression through RNAi showed drastic defects in early stages of pollen development, mainly on the first mitosis. These results suggest that the ScRALF3 secreted peptide regulates the transition from sporogenesis to gametogenesis in both male and female gametophytes.

Molecular analysis of the stylar-expressed Solanum chacoense small asparagine-rich protein family related to the HT modifier of gametophytic self-incompatibility in Nicotiana.

Gametophytic self-incompatibility (GSI) systems involving the expression of stylar ribonucleases have been described and extensively studied in many plant families including the Solanaceae, Rosaceae and Scrophulariaceae. Pollen recognition and rejection is governed in the style by specific ribonucleases called S-RNases, but in many self-incompatibility (SI) systems, modifier loci that can modulate the SI response have been described at the genetic level. Here, we present at the molecular level, the isolation and characterization of two Solanum chacoense homologues of the Nicotiana HT modifier that had been previously shown to be necessary for the SI reaction to occur in N. alata (McClure et al., 1999). HT homologues from other solanaceous species have also been isolated and a phylogenetic analysis reveals that the HT genes fall into two groups. In S. chacoense, these small proteins named ScHT-A and ScHT-B are expressed in the style and are developmentally regulated during anthesis identically to the S-RNases as well as following compatible and incompatible pollination. To elucidate the precise role of each HT isoform, antisense ScHT-A and RNAi ScHT-B lines were generated. Conversion from SI to self-compatibility (SC) was only observed in RNAi ScHT-B lines with reduced levels of ScHT-B mRNA. These results confirm the role of the HT modifier in solanaceous SI and indicate that only the HT-B isoform is directly involved in SI.

Genotype-dependent differences in S12-RNase expression lead to sporadic self-compatibility.

Sporadic self-compatibility, the occasional fruit formation after otherwise incompatible pollinations, has been observed in some S12-containing genotypes of Solanum chacoense but not in others. We have sequenced this S12 allele and analyzed its expression in four different genotypes. The S12-RNase levels were generally less abundant than those of other S-RNases present in the same plants. In addition, two-fold and five-fold differences in the amount of S12-RNase and S12 RNA, respectively, were observed among the genotypes analyzed. A comparison with the genetic data showed that genotypes with the highest levels were fully and permanently self-incompatible, whereas those with the lowest levels were those in which sporadic self-compatibility had been observed. The mature protein contains four potential glycosylation sites and genotype-specific differences in the pattern of glycosylation are also observed. Our results suggest the presence of modifier genes which affect, in a genotype-dependent manner, the level of expression and the post-translational modification of the S12-RNase.

Pollination, wounding and jasmonate treatments induce the expression of a developmentally regulated pistil dioxygenase at a distance, in the ovary, in the wild potato Solanum chacoense Bitt.

Pollination and fertilization trigger unique developmental programs leading to embryogenesis, ovary maturation and seed set. Pistil tissues are actively involved in pollen tube growth and respond to the presence of the growing pollen tubes by modulating the expression of specific genes. Using subtractive hybridization to isolate genes involved in pollen-pistil interactions and fertilization, we have isolated a pollination- and fertilization-induced dioxygenase which is predominantly expressed in the pistil. In situ hybridization analyses revealed that the SPP2 dioxygenase (Solanum pollinated pistil) from the self-incompatible wild potato Solanum chacoense Bitt. is also developmentally regulated, with mRNA levels gradually regressing from the tip of the style towards the ovary during pistil development. At maturity, the upper limit of SPP2 transcript distribution coincided with the abscission zone of the style and SPP2 dioxygenase expression in ovaries coincided with the fertilization receptivity period of the flower. Pollination, as well as wounding of the style, induced an increase in SPP2 mRNA steady-state levels at a distance, in the ovary. Treatments with stress hormones including methyl jasmonate, jasmonic acid and salicylic acid mimicked the wound response and also induced SPP2 transcripts in the ovary. The SPP2 dioxygenase could be involved in the biosynthesis of deterrent alkaloids in reproductive tissues or in generating chemical signals involved in pollen tube guidance.

Production of an S RNase with dual specificity suggests a novel hypothesis for the generation of new S alleles.

Gametophytic self-incompatibility in plants involves rejection of pollen when pistil and pollen share the same allele at the S locus. This locus is highly multiallelic, but the mechanism by which new functional S alleles are generated in nature has not been determined and remains one of the most intriguing conceptual barriers to a full understanding of self-incompatibility. The S(11) and S(13) RNases of Solanum chacoense differ by only 10 amino acids, but they are phenotypically distinct (i.e., they reject either S(11) or S(13) pollen, respectively). These RNases are thus ideally suited for a dissection of the elements involved in recognition specificity. We have previously found that the modification of four amino acid residues in the S(11) RNase to match those in the S(13) RNase was sufficient to completely replace the S(11) phenotype with the S(13) phenotype. We now show that an S(11) RNase in which only three amino acid residues were modified to match those in the S(13) RNase displays the unprecedented property of dual specificity (i.e., the simultaneous rejection of both S(11) and S(13) pollen). Thus, S(12)S(14) plants expressing this hybrid S RNase rejected S(11), S(12), S(13), and S(14) pollen yet allowed S(15) pollen to pass freely. Surprisingly, only a single base pair differs between the dual-specific S allele and a monospecific S(13) allele. Dual-specific S RNases represent a previously unsuspected category of S alleles. We propose that dual-specific alleles play a critical role in establishing novel S alleles, because the plants harboring them could maintain their old recognition phenotype while acquiring a new one.

Fertilization and wounding of the style induce the expression of a highly conserved plant gene homologous to a Plasmodium falciparum surface antigen in the wild potato Solanum chacoense Bitt.

Pistil tissues are actively involved in pollen tube growth and respond to the presence of the growing pollen tubes by modulating the expression of specific genes. Once fertilization has occurred, complex developmental programs lead to embryogenesis, ovary maturation, and seed set. In order to understand the early events that follow pollination and fertilization we have used a subtractive hybridization approach to characterize genes which are related to pollination and fertilization events. One cDNA clone isolated and named SPP30 (Solanum pollinated pistil) was found to share significant sequence identities with a Plasmodium falciparum (malaria parasite) surface antigen and a yeast gene of unknown function. Searches in recent EST databases also revealed that SPP30 homologues are found in both monocot and dicot species. The presence of this conserved gene in evolutionarily distant organisms such as yeast, Plasmodium, and plants suggests that it codes for an essential cellular function. This is also strengthened by its extremely high sequence conservation in both monocots and dicots where virtually all substitutions tolerated are conservative.

Hypervariable Domains of Self-Incompatibility RNases Mediate Allele-Specific Pollen Recognition.

Self-incompatibility (SI) in angiosperms is a genetic mechanism that promotes outcrossing through rejection of self-pollen. In the Solanaceae, SI is determined by a multiallelic S locus whose only known product is an S RNase. S RNases show a characteristic pattern of five conserved and two hypervariable regions. These are thought to be involved in the catalytic function and in allelic specificity, respectively. When the Solanum chacoense S12S14 genotype is transformed with an S11 RNase, the styles of plants expressing significant levels of the transgene reject S11 pollen. A previously characterized S RNase, S13, differs from the S11 RNase by only 10 amino acids, four of which are located in the hypervariable regions. When S12S14 plants were transformed with a chimeric S11 gene in which these four residues were substituted with those present in the S13 RNase, the transgenic plants acquired the S13 phenotype. This result demonstrates that the S RNase hypervariable regions control allelic specificity.

A retrotransposon-like sequence linked to the S-locus of Nicotiana alata is expressed in styles in response to touch.

We have identified a family of repetitive sequences in the genome of Nicotiana alata named Tna1 (Transposon of N. alata). The first element we characterised was a genomic clone for the N. alata s6-ribonuclease (S6-RNase), a gene required for self-incompatibility in this species. The DNA sequence of this element resembles the integrase domain of retrotransposons of the gypsy class and is most similar to a retrotransposon from Lilium henryi. A transcript present in N.alata styles (self-incompatibility genotype S6S6) hybridized to Tna1 and accumulated in the style following either pollination or touching. This transcript was cloned from a cDNA library and was encoded by second, partial Tna1 elements. Neither the transcribed sequence nor the original Tna1 element contain an open reading frame or is likely to be able to transpose. The second element was mapped using a population of N.alata plants segregating for alleles of the self-incompatibility locus and is closely linked to the S6-allele. The Tna1 element is present in a number of Nicotiana species and appears to have been active at least twice during the evolution of this genus.

The S-locus of Nicotiana alata: genomic organization and sequence analysis of two S-RNase alleles.

Genomic clones encoding the S2- and S6-RNases of Nicotiana alata Link and Otto, which are the allelic stylar products of the self-incompatibility (S) locus, were isolated and sequenced. Analysis of genomic DNA by pulsed-field gel electrophoresis and Southern blotting indicates the presence of only a single S-RNase gene in the N. alata genome. The sequences of the open-reading frames in the genomic and corresponding cDNA clones were identical. The organization of the genes was similar to that of other S-RNase genes from solanaceous plants. No sequence similarity was found between the DNA flanking the S2- and S6-RNase genes, despite extensive similarities between the coding regions. The DNA flanking the S6-RNase gene contained sequences that were moderately abundant in the genome. These repeat sequences are also present in other members of the Nicotianae.

The Activation of the Potato PR-10a Gene Requires the Phosphorylation of the Nuclear Factor PBF-1.

The pathogenesis-related gene PR-10a (formerly STH[middot]2) is induced in various organs of potato after wounding, elicitor treatment, or infection by Phytophthora infestans. Deletion analysis of the promoter of the PR-10a gene enabled us to identify a 50-bp region, located between positions -155 and -105, necessary for the elicitor responsiveness of the [beta]-glucuronidase reporter gene in transgenic potato plants. Within this region, a 30-bp sequence, located between positions -135 and -105, was necessary for the activation of the promoter by the elicitor. However, strong promoter activity after elicitor treatment required the presence of a 20-bp sequence located between positions -155 and -135. The region between -135 and -105 was specifically recognized by two nuclear factors, PBF-1 (PR-10a Binding Factor 1) and PBF-2, and binding of PBF-1 was coordinated with the accumulation of the PR-10a mRNA. Gel shift assays using nuclear extracts pretreated with sodium deoxycholate or alkaline phosphatase suggested that PBF-1 is a multimeric factor in which at least one of the constituent proteins can be phosphorylated. Treatment with alkaline phosphatase also indicated that binding of PBF-1 is positively regulated by phosphorylation and that it is phosphorylated only in tissues in which PR-10a is expressed. The use of protein phosphatase and kinase inhibitors in vivo provided additional evidence that wounding and elicitor treatment induce the phosphorylation of PBF-1 and that this phosphorylation is associated with gene activation.

Self-incompatibility: how plants avoid illegitimate offspring.

In some families of flowering plants, a single self-incompatibility (S) locus prevents the fertilization of flowers by pollen from the same plant. Self-incompatibility of this type involves the interaction of molecules produced by the S locus in pollen with those present in the female tissues (pistil). Until recently, the pistil products of the S locus were known in only two families, the Brassicaceae (which includes the cabbages and mustards) and Solanaceae (potatoes and tomatoes). A paper in this issue of the Proceedings describes the molecules associated with self-incompatibility in a third family, the Papaveraceae (poppies). We review current research on self-incompatibility in these three families and discuss the implications of the latest findings in poppy on the likely evolution of self-incompatibility in flowering plants. We also compare research into self-incompatibility with recent progress in understanding the mechanisms by which plants overcome infection by certain pathogens.

Identification of cis-acting elements involved in the regulation of the pathogenesis-related gene STH-2 in potato.

We have characterized a genomic clone containing the potato pathogenesis-related genes STH-2 and STH-21. The two genes are found 4 kb apart on the same chromosome and their sequences are highly similar. They present the same transcriptional orientation and are both interrupted by a single intron. A chimaeric gene consisting of 1015 bp of 5'-flanking sequence and part of the first exon of STH-2 fused to the bacterial beta-glucuronidase gene was highly-expressed in tubers of transgenic potato plants after wounding and elicitor treatments. The levels of activity observed in these transgenic plants parallel those observed for the accumulation of STH-2 mRNAs under similar conditions. This indicates that cis-acting elements necessary for the proper activation of the gene are present within 1 kb of 5'-flanking sequences. Functional analysis of 5' deletions of the STH-2/GUS constructs by transient expression in leaf protoplasts revealed the presence of an upstream regulatory sequence between -135 and -52 which contains a TGAC motif, and a possible negative regulatory region between -52 and -28. A factor present in nuclear extracts of wounded potato tubers was found to bind specifically to nucleotides located between -135 to -105, suggesting that this region contains important cis-regulatory elements.

Concurrent synthesis and degradation of alcohol dehydrogenase in elicitor-treated and wounded potato tubers.

The accumulation of alcohol dehydrogenase (ADH) in arachidonic acid-elicited potato (Solanum tuberosum L.) tuber discs was studied. In accordance with our previous report of the accumulation of Adh mRNA beginning 2 hours after elicitor treatment (DP Matton, CP Constabel, N Brisson [1990] Plant Mol Biol 14: 775-783), immunoprecipitation of ADH from in vivo labeled discs indicated that ADH synthesis occurred as early as 12 hours after treatment. However, levels of ADH activity and protein, as shown by enzyme assay and immunoblot, did not rise in parallel but decreased during the first 24 hours of treatment. After 24 hours, ADH activity and protein began to increase, reaching a several-fold increase at 96 hours after elicitation. Water-treated control discs showed a similar though delayed and less pronounced pattern. These results imply a turnover of ADH following elicitor treatment of potato tuber discs. As shown by nondenaturing gel electrophoresis, the synthesis and degradation involved the same ADH isozyme.

Alcohol dehydrogenase gene expression in potato following elicitor and stress treatment.

A cDNA clone corresponding to a mRNA that rapidly accumulates during the hypersensitive-like response induced by elicitor treatment of potato (Solanum tuberosum L.) tuber was characterized. The clone encodes a polypeptide (Mr = 41,097) having 83%-85% amino acid identity with known plant alcohol dehydrogenase sequences (ADH; EC 1.1.1.1). The identity of the clone was confirmed by measuring the ADH enzyme activity in extracts of Escherichia coli transformed with the cDNA clone. In potato tuber disks, a wide range of stresses, including treatment with fatty acid elicitors, salicylic acid, UV light and anaerobiosis, was shown to induce accumulation of Adh transcripts. In stems, a high constitutive level of Adh transcripts could be detected in 4-week old plants, but not in 8-week old plants. However, the mRNA could be induced to accumulate in stems of 8-week old plants by treatment with arachidonic acid elicitor or by anaerobiosis. Induction in leaves was also obtained during anaerobiosis and after treatment with a Phytophthora infestans mycelial homogenate.

Cloning, expression, and sequence conservation of pathogenesis-related gene transcripts of potato.

Treatment of potato tuber disks with arachidonic acid elicits the accumulation of several mRNAs. cDNA clones corresponding to two of these mRNAs were isolated and characterized. Nucleotide sequence analysis reveals that both clones (pSTH-2 and pSTH-21) contain an open-reading frame coding for a 155-amino acid polypeptide. The polypeptides encoded by the two clones differ by only six amino acids and show a high degree of similarity with PR protein sequences from pea (approximately 42%) and parsley (approximately 37%). mRNAs corresponding to the two potato cDNA clones also accumulate in Solanum chacoense and in tomato following elicitor treatment. Maximum accumulation of the mRNAs corresponding to the two cDNA clones is reached 24 hr after elicitor treatment of the tuber disks. pSTH-2-related mRNAs also accumulate in tubers after wounding or treatment with eicosapentaenoic acid and are detected in potato and tomato leaves treated with a Phytophthora infestans mycelium homogenate. The presence of these conserved genes in species from three plant families and the similarity of their induction pattern suggest an important function during the plant defense response.

Differential accumulation of potato tuber mRNAs during the hypersensitive response induced by arachidonic acid elicitor.

Accumulation of messenger RNAs in potato tuber discs was analysed during the hypersensitive response induced by treatment with the biotic elicitor arachidonic acid. In vitro translation of polysomal poly(A)(+) RNAs indicated that the accumulation of some sixteen mRNAs varied following treatment with arachidonic acid, and that the level of thirteen of these was increased. Two cDNA closes (pSTH-1 and-2) were isolated from a library of elicitor-treated tissue cDNAs. Northern blot analysis using these clones as molecular probes indicated that the levels of at least two mRNAs were markedly increased after elicitor treatment. In hybrid-released translation experiments, each of the cDNA clones selected more than one mRNA. Translation of these mRNAs yielded two polypeptides of Mr 45 000 (for the pSTH-1 clone), and three polypeptides of Me 17 000 (for the pSTH-2 clone). The low molecular weight polypeptides may correspond to potato pathogenesis-related (PR) proteins.