Growth inhibition of suspension cultured plant cells by ribonucleases

Extracellular, stylar RNases (S-RNases) are produced by self-incompatible, solanaceous plants, such asNicotiana alata, and are thought to be involved in selfpollen rejection by acting selectively as toxins to selfpollen. In this study, the toxicity of RNases to other plant cells was tested by culturing cells ofN. alata andN. plumbaginifolia in the presence ofS-RNases fromN. alata. The growth of cultured cells ofN. plumbaginifolia was inhibited by theS-RNases, but viability was not affected. Growth of cultured cells of oneN. alata selfincompatibility genotype was inhibited by twoS-RNases, indicating that inhibition was not allele specific. Comparisons with the effects of inactivated RNase and other proteins, suggest that the inhibition of growth byS ₂-RNase was partly, but not wholly, due to RNase activity. Heat-denaturedS ₂-RNase was a very effective inhibitor of cell growth, but this inhibitory activity may be a cell surface phenomenon.     

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

Genomic clones encoding the S ₂- and S ₆-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 S ₂- and S ₆-RNase genes, despite extensive similarities between the coding regions. The DNA flanking the S ₆-RNase gene contained sequences that were moderately abundant in the genome. These repeat sequences are also present in other members of the Nicotianae.     

Elements of theS-gene complex VI. Mutations of the self-incompatibility gene,pseudo-compatibility and origin of new self-incompatibility alleles

Spontaneously occurring mutations of theS gene, involving both theS _I and theS _FI classes of alleles, were studied inNicotiana alata. The results showed that while almost all of the irradiation-induced mutants of theS gene requiredS-bearing duplication for their survival, usually in the form of a free fragment, most of the spontaneous mutants in the same species, surprisingly, did not have such a requirement. This difference has been attributed to the greater depth of mutations produced in response to the ionizing radiations, which necessitated complementation for the survival of the mutants. There is a possibility from the data that theS _FI class of alleles may have even less need for the duplication than the S_I class of alleles. Both pollen- and stylar-part mutations of theS gene were obtained, but the majority of the mutations were partial, producing less than half the normal complement of seeds per pod in the mutants. Complementation was observed in the style between a -part mutant alleleS _infF11 ^sup and a normal alleleS _F10, which was the other allele in the parental plant that produced the mutant. No complementation occurred with another normal unrelated alleleS ₂. This observation was similar to that previously recorded in the study of induced mutants inN. alata.In a cross where the two alleles of the pollen parent were both compatible the allele which was also a mutant had an advantage over the other, normal, allele. This suggests that in maize, where the occurrence of mutant forms of theS gene has been demonstrated, the preferential fertilization of ovules by pollen containing the B-chromosomes may be due to the presence of a mutant form of theS gene on the B-chromosome.Besides clear-cutS-gene mutants, there were others, showing mostly irregular, slight compatibility, which did not appear to be directly related to theS-gene mutation. In some of the progeny of certain of these mutants, partial or complete lack of the specificity of one or bothS alleles in the style was observed; in certain others all progeny were normal. This pseudo-compatibility is attributed to cytoplasmic mutations affecting the products of theS gene; however, the possibility of an effect of chance polygenic modifier combinations is not ruled out.Recent literature on theS-gene structure, mutational specificity ofS alleles, and genetic control of pseudo-compatibility is reviewed. The time ofS-gene action is discussed in relation to the mechanism of the generation of new self-incompatibility alleles.     

Cloning and sequencing of cDNAs encoding two self-incompatibility associated proteins in Solanum chacoense

Summary We have isolated and sequenced cDNAs for S₂- and S₃-alleles of the self-incompatibility locus (S-locus) in Solanum chacoense Bitt., a wild potato species displaying gametophytic self-incompatibility. The S₂-and S₃-alleles encode pistil-specific proteins of 30 kDa and 31 kDa, respectively, which were previously identified based on cosegregation with their respective alleles in genetic crosses. The amino acid sequence homology between the S₂- and S₃-proteins is 41.5%. This high degree of sequence variability between alleles is a distinctive feature of the S-gene system. Of the 31 amino acid residues which were previously found to be conserved among three Nicotiana alata S-proteins (S₂, S₃, and S₆) and two fungal ribonucleases (R Nase T₂ and R Nase Rh), 27 are also conserved in the S₂- and S₃-proteins of S. chacoense. These residues include two histidines implicated in the active site of the R Nase T₂, six cysteines, four of which form disulfide bonds in R Nase T₂, and hydrophobic residues which might form the core structure of the protein. The finding that these residues are conserved among S-proteins with very divergent sequences suggests a functional role for the ribonuclease activity of the S-protein in gametophytic self-incompatibility.     

Self-incompatibility in Petunia inflata: isolation and characterization of cDNAs encoding three S-allele-associated proteins

Summary We have identified three alleles of the S-locus controlling self-incompatibility and their associated pistil proteins in Petunia inflata, a species that displays monofactorial gametophytic self-incompatibility. These S-allele-associated proteins (S-proteins) are pistil specific, and their levels are developmentally regulated. The amino-terminal sequences determined for the three S-proteins are highly conserved and show considerable homology to those of S-proteins from Petunia hybrida, Nicotiana alata and Lycopersicon peruvianum, three other species of the Solanaceae that also exhibit gametophytic self-incompatibility. cDNA clones encoding the three S-proteins were isolated and sequenced. Comparison of their deduced amino acid sequences reveals an average homology of 75.6%, with conserved and variable residue interspersed throughout the protein. Of the 137 conserved residues, 53 are also conserved in the N. alata S-proteins studies so far; of the 64 variable residues, 29 were identified as hypervariable based on calculation of the Similarity Index. There is only one hypervariable region of significant length, and it consists of eight consecutive hypervariable residues. This region correspond approximately to the hypervariable region HV2 identified in N. alata S-proteins. Of the two classes of N. alata S-proteins previously identified, one class exhibits greater homology to the three P. inflata S-proteins reported here than to the other class of N. alata S-proteins.     

An S-RNase promoter from Nicotiana alata functions in transgenic N. alata plants but not Nicotiana tabacum

Nicotiana tabacum and Nicotiana alata plants were transformed with genomic clones of two S-RNase alleles from N. alata. Neither the S ₂ clone, with 1.6 kb of 5 sequence, nor the S ₆ clone, with 2.8 kb of 5 sequence, were expressed at detectable levels in transgenic N. tabacum plants. In N. alata, expression of the S ₂ clone was not detected, however the S ₆ clone was expressed (at low levels) in three out of four transgenic plants. An S ₆-promoter-GUS fusion gene was also expressed in transgenic N. alata but not N. tabacum. Although endogenous S-RNase genes are expressed exclusively in floral pistils, the GUS fusion was expressed in both styles and leaves.     

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.     

RNase X2, a pistil-specific ribonuclease from Petunia inflata,shares sequence similarity with solanaceous S proteins

Petunia inflata, a species with gametophytic self-incompatibility, has previously been found to contain a large number of ribonucleases in the pistil. The best characterized of the pistil ribonucleases are the products of the S alleles, the S proteins, which are thought to be involved in self-incompatibility interactions. Here we report the characterization of a gene encoding another pistil ribonuclease of P. inflata, RNase X2. Degenerate oligonucleotides, synthesized based on the amino-terminal sequence of RNase X2, were used as probes to isolate cDNA clones, one of which was in turn used as a probe to isolate genomic clones containing the gene for RNase X2, rnx2. The deduced amino acid sequence of RNase X2 shows 42% to 71% identity to the 20 solanaceous S proteins reported so far, with the highest degree of similarity being to S₃ and S₆ proteins of Nicotiana alata. The cDNA sequence predicts a leader peptide of 22 amino acids, suggesting that RNase X2, like S proteins, is an extracellular ribonuclease. Also, similar to the S gene, rnx2 is expressed only in the pistil, and contains a single intron comparable in size and identical in location to that of the S gene. However, rnx2 is not linked to the S locus, and, in contrast to the highly polymorphic S gene, it is monomorphic. The possible biological function of RNase X2 is discussed.     

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     

Effect on in Vitro Pollen Growth of an Isolated Style Glycoprotein Associated with Self-Incompatibility in Nicotiana alata

The effect on in vitro pollen tube growth of an isolated style glycoprotein (S₂-glycoprotein) associated with self-incompatibility in Nicotiana alata was investigated. Tube growth of pollen bearing the S₂-allele was inhibited, but tube growth of pollen bearing other alleles was not affected. Inhibition showed a dose response effect. The percentage of pollen grains that germinated was not significantly affected by the S₂-glycoprotein. Growth of S₂-pollen in the presence of the S₂-glycoprotein resulted in increased binding to the pollen of monoclonal antibody (PCBC3) which has a primary specificity for α-l-arabinofuranosyl residues. Growth of pollen bearing other alleles in the presence of the glycoprotein resulted in no increased binding of the antibody.     

Characterization of proteins associated with self-incompatibility in Solanum tuberosum

Summary The gametophytic self-incompatibility system of Solarium tuberosum is controlled by a single locus, designated as the S-locus. Protein extracts from potato styles of defined S-genotypes have been analysed by two-dimensional gel electrophoresis, and found to contain a group of basic glycoproteins. Each genetically determined allele S ₁ to S ₄ was associated with the presence of one of a number of these polypeptides differing slightly in isoelectric points (in the range 8.3–>9.1) and/or apparent molecular weight (ranging from 23,000 to 29,000). Two abundant basic polypeptides, one of which is apparently not glycosylated, were present in all genotypes examined. Amino-terminal protein sequence determinations revealed homologies of the S. tuberosum stylar proteins S₂, S₃ and S₄ with SI-associated polypeptides from Nicotiana alata and Lycopersicon peruvianum. With an oligonucleotide generated to the potato-S₂ N-terminal protein sequence, it was possible to detect a style-specific RNA species of 920 nucleotides. The oligonucleotide also behaved as an allele-specific probe when hybridized to total RNA of different S-genotypes.     

Molecular diversity at the self-incompatibility locus is a salient feature in natural populations of wild tomato (Lycopersicon peruvianum)

A cDNA encoding a stylar protein was cloned from flowers of self-incompatible wild tomato (Lycopersicon peruvianum). The corresponding gene was mapped to the S locus, which is responsible for self-incompatibility. The nucleotide sequence was determined for this allele, and compared to other S-related sequences in the Solanaceae. The S allele was used to probe DNA from 92 plants comprising 10 natural populations of Lycopersicon peruvianum. Hybridization was conducted under moderate and permissive stringencies in order to detect homologous sequences. Few alleles were detected, even under permissive conditions, underscoring the great sequence diversity at this locus. Those alleles that were detected are highly homologous. Sequences could not be detected in self-incompatible Nicotiana alata, self-compatible L. esculentum (cultivated tomato) or self-compatible L. hirsutum. However, hybridization to an individual of self-incompatible L. hirsutum revealed a closely related sequence that maps to the S locus in this reproductively isolated species. This supports the finding that S locus polymorphism predates speciation. The extraordinarily high degree of sequence diversity present in the gametophytic self-incompatibility system is discussed in the context of other highly divergent systems representing several kingdoms.     

Molecular and genetic characterization of novel S-RNases from a natural population of Nicotiana alata

Self-incompatibility in the Solanaceae is mediated by S-RNase alleles expressed in the style, which confer specificity for pollen recognition. Nicotiana alata has been successfully used as an experimental model to elucidate cellular and molecular aspects of S-RNase-based self-incompatibility in Solanaceae. However, S-RNase alleles of this species have not been surveyed from natural populations and consequently the S-haplotype diversity is poorly known. Here the molecular and functional characterization of seven S-RNase candidate sequences, identified from a natural population of N. alata, are reported. Six of these candidates, S ₅ , S ₂₇ , S ₇₀ , S ₇₅ , S ₁₀₇ , and S ₂₁₀ , showed plant-specific amplification in the natural population and style-specific expression, which increased gradually during bud maturation, consistent with the reported S-RNase expression. In contrast, the S ₆₃ ribonuclease was present in all plants examined and was ubiquitously expressed in different organs and bud developmental stages. Genetic segregation analysis demonstrated that S ₂₇ , S ₇₀ , S ₇₅ , S ₁₀₇ , and S ₂₁₀ alleles were fully functional novel S-RNases, while S ₅ and S ₆₃ resulted to be non-S-RNases, although with a clearly distinct pattern of expression. These results reveal the importance of performing functional analysis in studies of S-RNase allelic diversity. Comparative phylogenetic analysis of six species of Solanaceae showed that N. alata S-RNases were included in eight transgeneric S-lineages. Phylogenetic pattern obtained from the inclusion of the novel S-RNase alleles confirms that N. alata represents a broad sample of the allelic variation at the S-locus of the Solanaceae.