Existence of a Common Glycoprotein Homologous to S-Glycoproteins in Two Self-incompatible Homozygotes of Brassica campestris

S-Glycoproteins (S-locus-specific glycoproteins) in Brassicaspecies are present only in stigmas and thought to play an importantrole in self-incompatibility system. The stigma extract containsalso several other glycoproteins reacting with the antiserumto S-glycoproteins, among which some glycoproteins from S₈S₈-and S₉S₉-homozygotes have the same pI value. Both of the glycoproteinswhich were tentatively termed NS₈- and NS₈S₉-glycoproteins,respectively, were isolated and analyzed. Those were revealedto be identical. Its amino acid sequence was homologous withthe S-glycoproteins in Brassica species. The NS-glycoproteinswere expressed at the same time and only in stigma as S-glycoproteins. (Received July 19, 1988; Accepted September 7, 1988)     

The cDNA Sequence of NS3-Glycoprotein from Brassica campestris and its Homology to Related Proteins

A cDNA clone encoding NS₃-glycoprotein was isolated from stigmasof Brassica campestris. NS-glycoproteins correspond to the SLRI-glycoproteinsof B. oleracea and are highly conserved within the species.These data suggest that the NS-glycoproteins may play a rolein discrimination between species in the fertilization systemof Brassica. (Received September 4, 1992; Accepted November 9, 1992)     

S-Locus-Specific Glycoproteins Associated with Self-Incompatibility in Brassica campestris

Specific S-glycoproteins were isolated from three Brassica campestriscultivars homozygous with respect to the S-alleles S₈, S₉ andS₁₂. Amino acid sequences of various peptide fragments of theS-proteins were determined using a gas-phase protein sequencer,and a nearly complete amino acid sequence of the S₈-glycoproteinwas determined on the basis of the revised cDNA sequence ofthe B. oleracea S-specific glycoprotein. The lysyl endopeptidasefragments of S₉ and S₁₂-glycoproteins were aligned in comparisonwith the sequence of the S₈-glycoprotein. Although extensivesequence homology was evident among the three S-glycoproteins,the sequences of the middle part were relatively different fromeach other. The numbers and positions of N-glycosylation alsodiffered among the S-glycoproteins of Brassica species. (Received April 20, 1987; Accepted July 29, 1987)     

Self-Incompatibility-Related RNases in Styles of Japanese Pear (Pyrus serotina Rehd.)

Isoelectric focusing revealed that S-genotypes of Japanese pearvarieties with gametophytic self-incompatibility were correlatedwith the isoforms of their stylar RNases. In a self-compatiblemutant, the S-allele-related band was much less intense thanin the original variety. These observations suggest that theRNase isoforms may be the stylar products of S-genes. (Received February 21, 1992; Accepted June 19, 1992)     

Immunological Reactions of Single Pollen Grains, Electrophoresis and Enzymology of Pollen Protein Exudates

Single intact pollen grains of Oenothera organensis, when placedupon a thin layer of agar containing pollen antiserum, producecircular areas of precipitate. Pollen grains from an S₂S₂ plantdo not produce precipitate in S₆ antiserum. Pollen grains froman S₆S₆ plant and an S₂'S₄' self-compatible plant produce precipitatesin S₆ antiserum. Fifty per cent of the pollen grains from anS₂S₆ plant produce precipitate in S₆ antiserum. Protein diffusesinto buffer solutions from intact pollen grains within 212 min.As much as 40 per cent of the total protein diffuses out inan hour. Amylase and invertase were detected in the diffusatefrom pollen grains. Alkaline and acid phosphatases were confinedto the pollen grains and did not diffuse out. The serologicalprecipitates are specific to the incompatibility system.     

Identification of Stylar RNases Associated with Gametophytic Self-Incompatibility in Almond (Prunus dulcis)

Stylar proteins of 13 almond (Prunus dulcis) cultivars withknown S-genotypes were surveyed by IEF and 2D-PAGE combinedwith immunoblot and N-terminal amino acid sequence analysesto identify S-RNases associated with gametophytic self-incompatibility(SI) in this plant species. RNase activities corresponding toS_a and S_b, two of the four S-alleles tested, were identifiedby IEF and RNase activity staining. The S_a-RNase band reactedwith the anti-S₄serum prepared from Japanese pear (Pyrus serotina);no reaction with the antiserum was observed with the s_bRNaseband. When the s_a-RNase band was excised from an IEF gel stainedfor RNase activity, subjected to SDS-PAGE, and detected by immunoblotting,it appeared that this band consisted of a single protein thatreacted with the anti-s₄serum with M_r of about 28 kDa. With2D-PAGE and silver staining of the stylar extracts, all fourS-proteins could be successfully distinguished from each otherin the highly basic zone of the gel. Although S_b-, S_c-, andS_dproteins had roughly the same M_r of about 30 kDa, the S_c-proteinseemed to be slightly smaller than the S_b-protein and slightlylarger than the S_aprotein. In 2D-PAGE profiles as well, theS_a-protein had M_r of about 28 kDa, apparently smaller than theother three proteins. A bud sport, in which one of the two S-allelesof the original cultivar is impaired, was visualized as a lossof S_cprotein, which is consistent with the previous pollinationstudy. All four S-proteins reacted with the anti-S₄serum, probablybecause of the differing conformations of these S-proteins inthe IEF and 2D-PAGE gels. The S_a-protein in 2D-PAGE appearedto be identical to S_a-RNase in IEF; both bad the same M_r andwere reactive with the anti-S₄-serum. N-terminal amino acidsequence analysis of the four 5-proteins revealed that theywere highly homologous to each other and similar to the 5-RNasesof Malus, Pyrus, Scrophulariaceae, and Solanaceae. Taken together,RNases in the style are strongly suggested to be associatedwith the gametophytic SI of al- mond. This is the first reportidentofiying and characterizing S-RNase in almond. (Received July 11, 1996; Accepted December 26, 1996)     

Preliminary Characterization of Glutathione S-Transferases That Accumulate in Callus Cells of Pumpkin (Cucurbita maxima Duch.)

Glutathione S-transferases (GSTs; EC 2.5.1.18 [EC] ) in sarcocarptissue of pumpkin (Cucurbita maxima Duch.) fruit and in callusinduced from the tissue were examined. The specific activityof GST in the callus was 6.9-fold higher than that in the tissue.The specific activity in the callus remained constant duringcultivation. Column chromatography on DEAE-cellulose, hydroxylapatite,and S-hexylglutathione-agarose was used to fractionate solubleproteins that were precipitated by ammonium sulfate at 30% to70% saturation from homogenates of the sarcocarp tissue of pumpkinfruit and the callus and GST activity was monitored. Two andseven isozymes of GST were identified in the tissue and in thecallus, respectively. Furthermore, column chromatography onSephadex G-200 and SDS-polyacrylamide gel electrophoresis, indicatedthat these GST isozymes were homo- and heterodimers of subunitsof M_r 22,000 (Puga), and 23,000 (Pugb), 24,000 (Pugc) or 24,500(Pugd). Puga and Pugb were predominant in the sarcocarp tissueand in the callus, respectively. Puga, Pugb, Pugc and Pugd hadacidic pI values of 5.45, 5.00, 5.35 and 5.75, respectively.Rabbit antiserum against Pugb did not cross-react with the threeother subunits of GST during immunoblotting. (Received July 15, 1993; Accepted December 14, 1993)     

An effective time for CO2 gas treatment in overcoming self-incompatibility in Brassica

An investigation was made to determine the effective time forCO₂ treatment in overcoming self-incompatibility in Brassica.CO₂ was effective when supplied to a self-pollinated flowerwhile hundreds of pollen grains were germinating on the stigma.Since the effective time coincides with the attachment of pollentubes to papilla cells, it is thought that CO₂ produces a metabolicchange in these cells during attachement. ¹Part of a thesis submitted for the Dr. of Agr. degree by thesenior author at Tohoku University. ²Present address: Faculty of Agriculture, Kobe University, Nada-ku,Kobe, Japan. (Received December 7, 1972; )     

A Comparison of the Growth, Photosynthesis, Stomatal Conductance and Water Use Efficiency of Moricandia and Brassica Species

When grown in pots and well-watered, the relative growth ratesof the above ground parts of two species of Moricandia (M. arvensis,an intermediate C₃–C₄ species, and M. moricandioides,a C₃ species) were inferior to those of two cultivated Brassicaspecies (B. campestris and B. napus). The Moricandia specieshad thicker leaves (greater d.wt per unit leaf area) with morechlorophyll than the Brassica species and had slightly greaterrates of photosynthesis per unit leaf area at an irradiance(400–700 nm) of 2000 µmol quanta m^–2 s ^–1.Leaves of M. arvensis, known to have a CO₂ compensation pointbetween that of C₃ and C₄ species, had a lower ratio of theintercellular to atmospheric partial pressure of CO₂ (C₁/C_a)and a greater instantaneous water use efficiency (WUE) thanthose of M. moricandioides and the Brassica species. Carbon isotope discrimination (     

Existence of S-Glycoprotein-Like Proteins in Anthers of Self-Incompatible Species of Brassica

Experimental evidence is presented that there exists an antherprotein that is reactive with a polyclonal antiserum raisedagainst the stigma S-glycoprotein of the S⁸-homozygote of Brassicacampestris. The antiserum did not react with extracts of seeds,ovaries or leaves. Since this antiserum did not react with thepolysaccharide residues similar to those in S-glycoprotein,it was considered capable of identifying S-glycoprotein-likeproteins in anthers (SA-protein: S-glycopro-tein-like antherprotein). The SA-protein generated a single distinct band ata pI of about 5.0 on blots of gels after isoelectric focusingand three spots at 29 kDa and 83 kDa on blots of two-dimensionalgels, which were different from those of stigma S-glycoprotein.The SA-protein did not contain polysaccharide residue that reactedwith Con A. No allelic differences in pI were found for theSA-protein within a given species, while such differences arecommon in stigma S-glycoprotein. The SA-protein appeared inanthers at the uninucleate microspore stage which is much earlierthan the stage at which the stigma S-xglycoprotein appears.It is present in anther walls rather than in the pollen of matureanthers. The SA-protein is considered to play an important rolein sporophytic control of self-incompatibility. (Received April 2, 1991; Accepted July 24, 1991)     

Conservation of S-locus for self-incompatibility in Brassica napus (L.) and Brassica oleracea (L.)

 Self-incompatibility (SI) in Brassica is a sporophytic system, genetically determined by alleles at the S-locus, which prevents self-fertilization and encourages outbreeding. This system occurs naturally in diploid Brassica species but is introduced into amphidiploid Brassica species by interspecific breeding, so that in both cases there is a potential for yield increase due to heterosis and the combination of desirable characteristics from both parental lines. Using a polymerase chain reaction (PCR) based analysis specific for the alleles of the SLG (S-locus glycoprotein gene) located on the S-locus, we genetically mapped the S-locus of B. oleracea for SI using a F₂ population from a cross between a rapid-cycling B. oleracea line (CrGC-85) and a cabbage line (86-16-5). The linkage map contained both RFLP (restriction fragment length polymorphism) and RAPD (random amplified polymorphic DNA) markers. Similarly, the S-loci were mapped in B. napus using two different crosses (91-SN-5263×87-DHS-002; 90-DHW-1855-4×87-DHS-002) where the common male parent was self-compatible, while the S-alleles introgressed in the two different SI female parents had not been characterized. The linkage group with the S-locus in B. oleracea showed remarkable homology to the corresponding linkage group in B. napus except that in the latter there was an additional locus present, which might have been introgressed from B. rapa. The S-allele in the rapid-cycling Brassica was identified as the S₂₉ allele, the S-allele of the cabbage was the S ₅ allele. These same alleles were present in our two B. napus SI lines, but there was evidence that it might not be the active or major SI allele that caused self-incompatibility in these two B. napus crosses. Received: 7 June 1996/Accepted: 6 September 1996     

Tissue printing and its applications in self-incompatibility studies

In this study, the tissue printing technique has been used to rapidly localize in female tissues the presence of specific mRNA representing the products (or some of the products) of the self-incompatibility S-locus gene(s). The methodology, initially developed for Brassica oleracea (sporophytic self-incompatibility) has been successfully employed on Solanum chacoense (gametophytic self-incompatibility). In the Brassica system tissue printing has allowed rapid discrimination between S alleles belonging to class 1 (dominant types) vs. class 2 (recessive types), and thus parallels findings obtained by restriction analyses. In the Solanum system the level of the S-RNase messages was analysed by scanning laser densitometry, and it was found that the message levels of the allele S14 declined faster than those coming from S13 in mature flowers.     

Glycosylation of S-RNases may influence pollen rejection thresholds in Solanum chacoense

A survey of Solanum chacoense plants expressing an authenticS₁₁-RNase transgene identified a line with partial compatibilityto S₁₁ pollen. By comparing fruit set to the S-RNase levelsdetermined immunologically in single styles, the minimum levelof S₁₁-RNase required for full rejection of S₁₁ pollen was estimatedto be 18 ng per style. The S₁₁-RNase threshold levels are thusconsiderably lower than those previously reported for the S₁₂-RNase.Interestingly, these two allelic S-RNases differ dramaticallyin the extent of glycosylation, with the number of glycosylationsites varying from one (S₁₁-RNase) to four (S₁₂-RNase). It issuggested that reduced glycosylation of the S₁₁-RNase may berelated to the lower threshold for pollen rejection. Key words: Gametophytic self-incompatibility, glycosylation, pistil-by-pistil analysis, S-RNase, Solanum chacoense, threshold Received 13 August 2007; Revised 27 November 2007 Accepted 30 November 2007     

The escape behavior of marine copepods in response to a quantifiable fluid mechanical disturbance

The threshold shear values needed to elicit the escape reactionto a quantifiable fluid mechanical disturbance were comparedbetween five free-swimming oceanic copepod species. The resultsindicate a significant difference in the threshold for differentspecies of copepods and between different age groups withina single species. In general, animals captured from more energeticregimes required a higher threshold than those captured frommore pacific locations. Labidocera madurae required the highestshear values with 51.5 s^–1 for 50% of the animals testedto elicit an escape reaction (S₅₀). Acartia tonsa and Euchaetarimana, in contrast, were behaviorally the most sensitive requiringan S₅₀ of only 1.5 and 4.1 s^–1, respectively, to initiatean escape reaction. Pleuromamma xiphias and Oithona requiredintermediate shear values with an S₅₀ of 7.2 and 8.1 s^–1.When compared to literature values, the threshold needed toelicit an escape reaction was consistently higher than averageenvironmental shear values. Threshold shear values also variedsignificantly with developmental stage. Naupliar stages of A.tonsarequired greater than six times the S₅₀ value required by adultsof the same species. This suggests that the higher vulnerabilityto predation of naupliar stages of copepods may not only reflectinferior escape strength, but may also result from the higherthreshold needed to elicit an escape reaction. This study supportsthe hypothesis that selective feeding patterns exhibited bypredators of copepods may be the result of the differentialbehavioral sensitivities of different species and developmentalstages of copepods.     

Proteomic analysis of pathogenesis-related proteins (PRs) induced by compatible and incompatible interactions of pepper mild mottle virus (PMMoV) in Capsicum chinense L3 plants

Resistance conferred by the L³ gene is active against most ofthe tobamoviruses, including the Spanish strain (PMMoV-S), aP_1,2 pathotype, but not against certain strains of pepper mildmottle virus (PMMoV), termed P_1,2,3 pathotype, such as the Italianstrain (PMMoV-I). Both viruses are nearly identical at theirnucleotide sequence level (98%) and were used to challenge Capsicumchinense PI159236 plants harbouring the L³ gene in order tocarry out a comparative proteomic analysis of PR proteins inducedin this host in response to infection by either PMMoV-S or PMMoV-I.PMMoV-S induces a hypersensitive reaction (HR) in C. chinensePI159236 plant leaves with the formation of necrotic local lesionsand restriction of the virus at the primary infection sites.In this paper, C. chinense PR protein isoforms belonging tothe PR-1, β-1,3-glucanases (PR-2), chitinases (PR-3), osmotin-likeprotein (PR-5), peroxidases (PR-9), germin-like protein (PR-16),and PRp27 (PR-17) have been identified. Three of these PR proteinisoforms were specifically induced during PMMoV-S-activationof C. chinense L³ gene-mediated resistance: an acidic β-1,3-glucanaseisoform (PR-2) (M_r 44.6; pI 5.1), an osmotin-like protein (PR-5)(M_r 26.8; pI 7.5), and a basic PR-1 protein isoform (M_r 18;pI 9.4–10.0). In addition, evidence is presented for adifferential accumulation of C. chinense PR proteins and mRNAsin the compatible (PMMoV-I)–C. chinense and incompatible(PMMoV-S)–C. chinense interactions for proteins belongingto all PR proteins detected. Except for an acidic chitinase(PR-3) (M_r 30.2; pI 5.0), an earlier and higher accumulationof PR proteins and mRNAs was detected in plants associated withHR induction. Furthermore, the accumulation rates of PR proteinsand mRNA did not correlate with maximal accumulation levelsof viral RNA, thus indicating that PR protein expression mayreflect the physiological status of the plant. Key words: Capsicum chinense, compatible interaction, incompatible interaction, HR-induction, PMMoV, PR proteins Received 5 December 2007; Revised 21 January 2008 Accepted 22 January 2008     

A cDNA encoding an S-locus specific glycoprotein from Brassica oleracea plants containing the S5 self-incompatibility allele

Summary A cDNA sequence homologous to the Brassica self-incompatibility locus specific glycoprotein (SLSG) sequence was isolated from stigmas of B. oleracea plants homozygous for the S₅ allele. The nucleotide sequence of this cDNA was obtained and compared with the S₆ allelic form of the SLSG. Evidence is presented which indicates that this sequence does not specify the self-incompatibility response of pollen.Abbreviations SDS sodium dodecyl sulphate - PVP polyvinylpyrrolidone - BSA bovine serum albumin - SLSG self-incompatibility locus specific glycoprotein     

Microheterogeneity of N-glycosylation on a stylar self-incompatibility glycoprotein of Nicotiana alata

Gametophytic self-incompatibility, a mechanism that preventsinbreeding in some families of flowering plants, is mediatedby the products of a single genetic locus, the S-locus. Theproducts of the S-gene in the female sexual tissues of Nicotianaalata are an allelic series of glycoproteins with RNase activity.In this study, we report on the microheterogeneity of N-linkedglycosylation at the four potential N-glycosylation sites ofthe S²-glycoprotein. The S-glycoproteins from N.alata containfrom one to five potential N-glycosylation sites based on theconsensus sequence Asn-Xaa-Ser/Thr. The S²-glycoprotein containsfour potential N-glycosylation sites at Asn²⁷, Asn³⁷, Asn¹³⁸and Asn¹⁵⁰, designated sites I, n, IV and V, respectively. SiteIII is absent from the S₂-glycoprotein. Analysis of glycopeptidesgenerated from the S₂-glycoprotein by trypsin and chymotrypsindigestions revealed the types of glycans and the degree of microheterogeneitypresent at each site. Sites I (Asn²⁷) and IV (Asn¹³⁸) displaymicroheterogeneity, site II (Asn³⁷) contains only a single typeof N-glycan, and site V (Asn¹⁵⁰) is not glycosylated. The microheterogeneityobserved at site I on the S₂-glycoprotein is the same as thatobserved at the only site, site I, on the Srglycoprotein (Woodwardet al., Glycobiology, 2, 241-250, 1992). Since the N-glycosylationconsensus sequence at site I is conserved in all S-glycoproteinsfrom other species of self-incompatible solanaceous plants,glycosylation at this site may be important to their function.No other post-translational modifications (e.g. O-glycosylation,phosphorylation) were detected on the S₂-glycoprotein. fertilization microheterogeneity N-glycans plants RNase     

Polymorphism of the S -locus glycoprotein gene (SLG ) and the S -locus related gene (SLR1 ) in Raphanus sativus L. and self-incompatible ornamental plants in the Brassicaceae

The S-locus glycoprotein gene, SLG, which participates in the pollen-stigma interaction of self-incompatibility, and its unlinked homologue, SLR1, were analyzed in Raphanus sativus and three self-incompatible ornamental plants in the Brassicaceae. Among twenty-nine inbred lines of R. sativus, eighteen S haplotypes were identified on the basis of DNA polymorphisms detected by genomic Southern analysis using Brassica SLG probes. DNA fragments of SLG alleles specifically amplified from eight S haplotypes by PCR with class I SLG-specific primers showed different profiles following polyacrylamide gel electrophoresis, after digestion with a restriction endonuclease. The nucleotide sequences of the DNA fragments of these eight R. sativus SLG alleles were determined. Degrees of similarity of the nucleotide sequences to a Brassica SLG (S? ⁶ SLG) ranged from 85.6% to 91.9%. Amino acid sequences deduced from these had the twelve conserved cysteine residues and the three hypervariable regions characteristic of Brassica SLGs. Phylogenetic analysis of the SLG sequences from Raphanus and Brassica revealed that the Raphanus SLGs did not form an independent cluster, but were dispersed in the tree, clustering together with Brassica SLGs. These results suggest that diversification of the SLG alleles of Raphanus and Brassica occurred before differentiation of these genera. Although SLR1 sequences from Orychophragmus violaceus were shown to be relatively closely related to Brassica and Raphanus SLR1 sequences, DNA fragments that are highly homologous to the Brassica SLG were not detected in this species. Two other ornamental plants in the Brassicaceae, which are related more distantly to Brassica than Orychophragmus, also lacked sequences highly homologous to Brassica SLG genes. The evolution of self-incompatibility in the Brassicaceae is discussed.     

Structural and molecular analysis of self-incompatibility in almond (<Emphasis Type="Italic">Prunus dulcis</Emphasis>)

. A multi-approach was used to study different aspects of self-incompatibility (SI) in almond (Prunus dulcis). First, a population of almond cultivars was characterised as to their individual S-allele combination using separation of stylar protein extracts (non-equilibrium pH gradient electrofocusing) followed by staining for RNase activity, which led to the identification of one putative new allele and several new S-allele combinations. Second, a field pollination scheme was designed to study pollen tube progression and to obtain a spatial and temporal characterisation of this reproductive stage in both incompatible and compatible crosses. In addition, an anti-serum was raised against a synthetic peptide designed from an almond S-protein (S₈) and used for immunological in situ detection in pistil cryosections. S-RNases were found to accumulate intercellularly in the stylar transmitting tissue as previously reported for other rosaceous species. The results are discussed in view of the evolution of the gametophytic SI system and the models proposed for its mechanism. Gametophyte selection is also proposed as an important intraspecific barrier to fertilisation in this species.