Structural Analysis and Molecular Model of a Self-Incompatibility RNase from Wild Tomato

doi:10.1104/pp.116.2.463

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Structural Analysis and Molecular Model of a Self-Incompatibility RNase from Wild Tomato¹

Simon Parry, Ed Newbigin, David Craik, Kazuo T. Nakamura, Antony Bacic^*, and David Oxley

Plant Cell Biology Research Centre, School of Botany, University of Melbourne, Parkville, VIC 3052, Australia (S.P., E.N., A.B., D.O.); Centre for Drug Design and Development, University of Queensland, QLD 4072, Australia (D.C.); and School of Pharmaceutical Sciences, Showa University, Hatanodai, Tokyo 142, Japan (K.T.N.)

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

Self-incompatibility RNases (S-RNases) are an allelic series of style glycoproteins associated with rejection of self-pollenin solanaceous plants. The nucleotide sequences of S-RNase allelesfrom several genera have been determined, but the structure ofthe gene products has only been described for those from Nicotianaalata. We report on the N-glycan structures and the disulfidebonding of the S₃-RNase from wild tomato (Lycopersicon peruvianum)and use this and other information to construct a model of thismolecule. The S₃-RNase has a single N-glycosylation site (Asn-28)to which one of three N-glycans is attached. S₃-RNase has sevenCys residues; six are involved in disulfide linkages (Cys-16-Cys-21,Cys-46-Cys-91, and Cys-166-Cys-177), and one has a free thiolgroup (Cys-150). The disulfide-bonding pattern is consistent withthat observed in RNase Rh, a related RNase for which radiographic-crystallographicinformation is available. A molecular model of the S₃-RNase showsthat four of the most variable regions of the S-RNases are clusteredon one surface of the molecule. This is discussed in the contextof recent experiments that set out to determine the regions ofthe S-RNase important for recognition during the self-incompatibilityresponse.

INTRODUCTION

Top
Abstract
Introduction
Methods
Results
Discussion
References

Self-incompatibility is a prezygotic barrier that prevents a plant from being fertilized by its own pollen (de Nettancourt,1977). In solanaceous plants such as wild tomato (Lycopersiconperuvianum), self-incompatibility is controlled by a single locus(the S-locus) with multiple alleles (Clarke and Newbigin, 1993).Fertilization is prevented if one of the S-alleles of the diploidfemale reproductive tissue, the pistil, matches the S-allele expressedby the haploid pollen. The only product known to be encoded bythe S-locus of solanaceous plants is an allelic series of extracellularstylar glycoproteins with RNase activity, known as the S-RNases(McClure et al., 1989). S-RNases are presumed to interact in anallele-specific manner with the unknown product of the S-locusin pollen to initiate a response that discriminates between "self"and "nonself" pollen.

Amino acid sequence identity between S-RNase alleles can be as low as 40%, although alignment of the sequence of differentS-RNase alleles reveals a common structure comprised of five regionsof highly conserved sequence and two regions of a sequence highlyvariable between alleles (hypervariable regions) (Tsai et al.,1992). The amino acid residues of the hypervariable regions aretypically hydrophilic and are thus predicted to be exposed onthe surface of the molecule, where they presumably interact withthe pollen component of the S-locus (Anderson et al., 1989). Presenceof the hypervariable region on the surface depends on the overallstructure of the S-RNase, which is in part determined by disulfidebonding. The number of Cys residues in different S-RNases variesbetween 7 and 10, although the position of these residues in themolecule is conserved (Tsai et al., 1992). This suggests thatdespite their widely different primary sequences, the S-RNasesproduced by different S-alleles have similar three-dimensionalstructures.

Carbohydrates are also expected to be a dominant feature on the S-RNase surface. S-RNases from another solanaceous plant,Nicotiana alata, are N-glycosylated (Woodward et al., 1989, 1992;Oxley et al., 1996). Most S-RNases have several potential sitesfor the attachment of N-glycans, with one site toward the N terminuspresent in almost all of the S-RNases sequenced to date (Oxleyet al., 1996). The structure of the N-linked oligosaccharidesof several S-RNases from N. alata is known (Woodward et al., 1992;Oxley et al., 1996).

To further understand the overall structure of the solanaceous S-RNases, we established the disulfide bonds and the N-linkedglycans of S₃-RNase from L. peruvianum. The disulfide bonds, togetherwith the primary sequence of the protein gained from the cDNAsequence (Royo et al., 1994) and the crystal structure of therelated fungal RNase Rh (Kurihara et al., 1992), allowed us toconstruct a molecular model of the S₃-RNase. This model has providedinsights into the spatial arrangements of the variable regionsof the S-RNases.

	MATERIALS AND METHODS

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Wild tomato (Lycopersicon peruvianum L. Mill.) plants with the self-incompatibility genotype S₃S₃ were grown and maintainedas described previously (Mau et al., 1986).

Purification of S₃-RNase from L. peruvianum

S₃-RNase was prepared by HIC, as described previously (Parry et al., 1997

). For experiments requiring native protein, thefraction from the HIC column containing S₃-RNase (where S₃-RNasecomprises 80% of total protein by weight) was used. After treatment,the S₃-RNase was purified to homogeneity by RP-HPLC (see below).For experiments not requiring native protein, RP-HPLC-purifiedS₃-RNase was used.

RP-HPLC

RP-HPLC was performed on a system comprised of a solvent delivery system and a diode array detector (model 126 and model 168,respectively, System Gold HPLC, Beckman). RP separations wereperformed on C-8 columns (RP-300, Brownlee Aquapore, Santa Clara,CA; 4.6 × 100 mm or 2.1 × 100 mm). Solvent A was 0.1% (v/v) aqueousTFA, and solvent B was 0.089% TFA in 60% aqueous acetonitrile(v/v). The columns were developed over 60 min at flow rates of1 mL/min (4.6-mm column) or 0.4 mL/min (2.1-mm column), with alinear gradient of 0 to 100% solvent B. The effluent from theHIC and the RP-HPLC columns was continuously monitoredat 215 and 280 nm, and fractions containing the S₃-RNase werecollected.

Alkylation of Thiol Groups

S₃-RNase was alkylated under either nonreducing or reducing conditions. Under nonreducing conditions, native S₃-RNase (100µg) was exchanged into 50 mm sodium acetate, pH 5.0, using a PD-10column (Pharmacia). After the volume of this solution was reducedto approximately 100 µL using a spin column (Centricon 10, Amicon),the S₃-RNase was treated with 20 mm 4-vinylpyridine, 10 mm EDTA,and 6 m guanidinium chloride for 2.5 h at room temperature. Underreducing conditions, S₃-RNase (200 µg) purified by RP-HPLC wasreduced for 30 min at 50°C in 6 m guanidinium chloride, 0.1 m(NH₄)HCO₃, pH 8.6, 10 mm EDTA, and 20 mm DTT (final reaction volume,500 µL), and then alkylated with 100 mm 4-vinylpyridine for 30min at room temperature. In both cases the alkylation reactionwas diluted (4×) with water and fractionated on the 4.6- × 100-mmRP-HPLC column, and the collected fraction was dried by vacuumcentrifugation.

Trypsin Digestion

Alkylated S₃-RNase was dissolved in 0.1 m (NH₄)HCO₃, pH 8.6, containing 20% (v/v) propan-2-ol (Welinder, 1988

), and treatedwith sequencing-grade trypsin (Sigma) at an enzyme:substrate ratioof approximately 1:50 (w/w) at 22°C for 18 h. Tryptic peptideswere fractionated by RP-HPLC on a 2.1- × 100-mm column and storedat $-$ 20°C.

ESI-MS

ESI-MS was performed on a double-focusing, two-sector mass spectrometer (MAT 95, Finnigan MAT, Bremen, Germany) equipped withan electrospray source (Finnigan). A constant stream of acetonitrile:0.02%aqueous acetic acid (50:50, v/v) was pumped into the source at3 µL/min using a syringe pump (Harvard Apparatus, Inc., SouthNatick, MA). Samples dissolved in the same solvent wereintroduced into the source using an injector (Rheodyne, Cotati,CA). Spectra were acquired by scanning from 400 to 2000 D at 10s/decade.

N-Terminal Peptide Sequencing

Peptides were sequenced on an automated protein sequencer (model LF3400, Beckman) according to the manufacturer's instructions.

Enzymatic Deglycosylation of S₃-RNase

S₃-RNase purified by RP-HPLC was dried by vacuum centrifugation and deglycosylated with PNGase F (Boehringer Mannheim), asdescribed previously (Oxley et al., 1996

). Deglycosylated S₃-RNasewas precipitated with methanol (4 volumes) at $-$ 20°C for 40 min,and pelleted by centrifugation at 15,800g for 5 min at 4°C. Thesupernatant was dried to approximately 200 µL by vacuum centrifugation,applied to prewashed 3MM paper (Whatman), and run at room temperaturefor 24 h in a descending chromatography system in butanol:ethanol:water(4:1:1, v/v) to remove contaminants (Takasaki et al., 1982

). N-glycanswere eluted from the paper with water, dried in vacuo, and fractionatedby high-pH anion-exchange HPLC on a column (4 × 250 mm, CarboPacPA1, Dionex, Sunnyvale, CA) coupled to an HPLC system (Dionex),essentially as described previously (Oxley et al., 1996

). Chromatographywas performed at 1 mL/min using a 30-min linear gradient of 0to 50 mm sodium acetate in 0.1 m sodium hydroxide.

Enzymatic Deglycosylation of Glycopeptides

Glycopeptides, generated by tryptic digestion and purified by RP-HPLC, were dried by vacuum centrifugation and deglycosylatedusing PNGase F in the presence of 50 mm (NH₄)HCO₃ buffer(35°C for 18 h). The reaction was loaded onto a 2.1-mm RP-HPLCcolumn, and the released N-glycans present in the unbound fractionwere collected and dried.

Methylation Analysis

Methylation analyses were performed as described previously (Oxley et al., 1996

) except that the mass spectrometer was operatedin selected-ion monitoring mode for the ions of m/z 101, 117,118, 129, 131, 145, 159, 161, 162, 175, 189, 190, 203, 205, 261,262, and 305.

Determination of Three-Dimensional Structure

The homology model of S₃-RNase from L. peruvianum was constructed using the program INSIGHT (Biosym Technologies, San Diego,CA) based on the radiographic coordinates of RNase Rh (Kuriharaet al., 1992

). Sequences were aligned using a proprietary algorithmwithin INSIGHT, and then adjusted manually to preserve as muchof the secondary structure as possible. The coordinates for residuesof S₃-RNase in the conserved regions were then derived from thoseof RNase Rh. The coordinates for nonconserved loop regions weregenerated from a search for sequences of similar size and terminispacing from the PDB database, except the loop between strands $beta$ 1 and $beta$ 2, which was generated de novo. The loops were then graftedonto the coordinates of the conserved regions of secondary structure.The complete set of coordinates was then energy minimized andsubjected to restrained molecular dynamics to produce the finalhomology model.

	RESULTS

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Structure of N-Linked Glycans on S₃-RNase

The cDNA sequence of S₃-RNase from L. peruvianum has been determined (Royo et al., 1994

) and the predicted amino acid sequencecontains a single potential N-glycosylation site (consensus sequenceAsn-28-Phe-Thr; Fig. 1). Carbohydrate is attached to this sitesince treatment with PNGase F caused a decrease in the molecularmass of S₃-RNase when analyzed by SDS-PAGE (data not shown). S₃-RNasewas incubated with the alkylating agent 4-vinylpyridine and thendigested with trypsin. The resulting peptides were separated byRP-HPLC and analyzed by ESI-MS (Fig. 2; Table I). ESI-MS showedthat fractions 3 and 4 (both containing Asn-28) had molecularmasses that were 893 and 1096 D larger than those calculated fromtheir amino acid sequences. When corrected for the loss of 18D (water) in the formation of the N-glycosidic bond, these increasesin molecular mass correspond to the glycan compositions Hex₃HexNAc₂and Hex₃HexNAc₃, respectively (where Hex is hexose and HexNAcis N-acetyl-hexosamine) (Table II). Extensive fragmentation ofthe glycan moiety of the glycopeptide was observed in the ESI-MSof fractions 3 and 4. Thus, in addition to the intact glycopeptides(peptide+Hex₃HexNAc₂ and peptide+Hex₃HexNAc₃), ions correspondingto peptide, peptide+HexNAc, peptide+HexNAc₂, peptide+Hex₁HexNAc₂,and peptide+Hex₂HexNAc₂ were also observed.

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Figure 1. Deduced amino acid sequence from the cDNA sequence of S₃-RNase from L. peruvianum (Royo et al., 1994

). Arrows with numbersindicate peptides generated from trypsin digestion of S-pyridylethylatedS₃-RNase characterized in Table I. Predicted structural motifs( $alpha$ -helices A-F and $beta$ -sheets 1-7) are indicated above the aminoacid sequence. Branch structure designates the N-glycosylationsite. The asterisk represents the site of S-pyridylethylation.Dotted lines show positions of disulfide bonds determined in thisstudy.

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Figure 2. RP-HPLC chromatogram of the trypsin digestion products of S-pyridylethylated S₃-RNase. Numbered bars indicate the fractionsthat were collected and analyzed.

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Table I. ESI-MS and N-terminal sequencing data of peptides generated from a tryptic digest of S-pyridylethylated S₃-RNase (see Fig.2)

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Table II. ESI-MS data for N-glycans of S₃-RNase from L. peruvianum

Some plant N-glycans have been shown to have a truncated core structure (Bouwstra et al., 1990), so it is possible that someof these putative fragment ions were actually pseudomolecularions of peptides bearing truncated glycans. To confirm that thesmaller pseudomolecular ions observed in the mass spectra of theglycopeptides were due to fragmentation of the glycans and didnot reflect the natural state of glycosylation, fractions 3 and4 were enzymatically deglycosylated by PNGase F and, after per-O-methylation,the mixture of N-glycans was analyzed by ESI-MS (Table II). Twomajor components with molecular masses of 1149.3 and 1394.2 Dcorresponded to the glycans Hex₃HexNAc₂ and Hex₃HexNAc₃, respectively(Table II). These glycans constituted 60 and 35% of the totalN-glycans, respectively. A glycan not previously detected on theglycopeptides, and with a molecular mass of 1555.4 D after per-O-methylation,represented the remaining 5%, and corresponded to a glycan withthe composition Hex₃Pent₁HexNAc₃ (where Pent is pentose). No glycanswith molecular masses smaller than 1149.3 D were detected.

To gain information on the linkages of the carbohydrate residues, N-glycans were released from intact S₃-RNase by PNGase Fand fractionated by high-pH anion-exchange HPLC. Each of the collectedpeaks was methylated and then analyzed by ESI-MS. Only two peaks(S₃a and S₃b) contained carbohydrate. Glycans S₃a and S₃b yieldedpseudomolecular ions ([M+Na]⁺) at m/z 1172.3 and 1417.2, corresponding to Hex₃HexNAc₂ and Hex₃HexNAc₃,respectively. No pseudomolecular ions corresponding to Hex₃Pent₁HexNAc₃were detected at this level of loading.

The per-O-methylated glycans S₃a and S₃b were hydrolyzed, reduced, acetylated, and then analyzed by GC-MS. Glycan S₃a yieldedthe derivatives of t-Manp, 3,6-Manp, and 4-GlcpNAc residues. GlycanS₃b yielded these same derivatives, as well as derivatives of2-Manp and t-GlcpNAc residues. Based on this linkage informationand the ESI-MS data, the structures of S₃a and S₃b were deduced(Fig. 3). It was not possible to ascertain whether the terminal,nonreducing GlcNAc of S₃b was linked to Man-4 or Man-4 $'$ .However, in N-glycans from N. alata S-RNases, this GlcNAc is alwayslinked to Man-4 (Woodward et al., 1992; Oxley and Bacic,1995; Oxley et al., 1996), and it is likely to be the same inthe L. peruvianum S-RNases. Similarly, based on the known N-glycanstructures found on N. alata S-RNases, S₃c is probably based onthe S₃b core (Man₃GlcNAc₃) with a Xylp residue linked at O-2 ofMan-3 (Fig. 3).

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Figure 3. Proposed structure of the N-glycans on S₃-RNase from L. peruvianum.

Identification of Disulfide Bonds in S₃-RNase

There are seven Cys residues in the amino acid sequence of S₃-RNase from L. peruvianum (Royo et al., 1994

; Fig. 1). Therefore,at least one of the Cys residues cannot be involved in an intramoleculardisulfide linkage. To prevent disulfide bond interchange, nativeS₃-RNase was treated with the alkylating agent 4-vinylpyridine.Under nondenaturing conditions no alkylation of thiol groups wasobserved, so the reaction was performed under denaturing conditionsbut at low pH to favor the alkylation of free thiol groups overdisulfide interchange (Friedman et al., 1970

). After 30 min anabsorbance band characteristic of a pyridylethyl group was detectedon the S₃-RNase. The alkylated S₃-RNase was digested with trypsin,and the products were separated by RP-HPLC (Fig. 2).

The molecular mass of the tryptic peptide(s) in each collected fraction was determined by ESI-MS and the results are summarizedin Table I. Peptides were assigned by comparing the observedmolecular masses with those calculated for every possible trypticpeptide of nonreduced S₃-RNase. Four fractions (2, 6, 7, and 8)contained peptides linked by disulfide bonds (Fig. 1; Table I).Fraction 2 was identified by ESI-MS as Ser-14-Lys-17-S-S-Tyr-20-Arg-27,indicating a disulfide bond between Cys-16 and Cys-21. Edman sequencingof this fraction yielded two N-terminal sequences (Ser-Phe-Xaa-Xaaand Tyr-Xaa-Pro-Asn), which is consistent with this assignment(Table I). The pseudomolecular ion ([M+H]⁺) at m/z 3572.2 observed in the mass spectrum of fraction 7 correspondedto the peptide Ile-41-Lys-49-S-S-His-88-Lys-109, indicating adisulfide bond between Cys-46 and Cys-91. Again, the N-terminal sequences of fraction 7 (Ile-Met-Pro-Ile-Asn-Xaaand His-Gly-Thr-Xaa-Ser-Val) confirmed this assignment. Fraction6, which was a shoulder on the leading edge of fraction 7, wasidentical to fraction 7 except that tryptic cleavage occurredafter Lys-86 rather than Lys-87.

The UV spectrum of fraction 8 contained a strong absorbance band at 254 nm, indicative of a pyridylethyl group. The molecularmass of fraction 8 was greater than that calculated for the peptideGlu-144-Arg-169-S-S-Glu-170-Arg-178 by 105.1 D, an amount correspondingto a pyridylethyl group. N-terminal sequence analysis (Glu-Val-Pro-Asn-Leu-Asn-peCys[where pe is pyridylethyl] and Glu-Gly-Thr-Thr-Val-Ile-Ala) confirmedthe assignment of fraction 8 and identified Cys-150 as the pyridylethyl-labeledresidue. The disulfide bond linking Glu-144-Arg-169 to Glu-170-Arg-178must therefore be between Cys-166 and Cys-177.

Three-Dimensional Structure of S₃-RNase

A homology model for the three-dimensional structure of S₃-RNase from L. peruvianum was constructed from the coordinates ofRNase Rh (Kurihara et al., 1992

) and this is shown in Figure 4.A sequence alignment of the two proteins shows that most of thedifferences occur in loop regions rather than in regions of secondarystructure. The model thus incorporates all of the elements ofthe secondary structure of RNase Rh. These include seven $beta$ -strands, $beta$ 1 (4-9), $beta$ 2 (31-37), $beta$ 3 (127-130), $beta$ 4 (147-151), $beta$ 5 (160-170), $beta$ 6 (173-177), and $beta$ 7 (188-191); and six helices, A (51-60), B,(60-71), C (76-88), D (95-112), E (113-120), and F (131-143) (Fig.1). Differences between the two proteins include the fact thatthe N-terminal 22 residues of RNase Rh are absent in S₃-RNaseand the loop between strand $beta$ 2 and helix A is significantly shorterin S₃-RNase. In contrast, the loop between strands $beta$ 1 and $beta$ 2 isextended by eight residues, and the loop between strands $beta$ 4 and $beta$ 5 is extended by three residues in S₃-RNase relative to RNaseRh. It is interesting that most of the residues that are absentin S₃-RNase originate from a contiguous surface patch near theN terminus of RNase Rh (upper right side of Fig. 4a), whereasmost of the extra residues in S₃-RNase form a new surface patchnear the C terminus (left side of Fig. 4a).

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Figure 4. a and b, Two views (rotated by 90° about a vertical axis) of a homology model of the S₃-RNase from L. peruvianum. The modelis based on the three-dimensional crystal structure of RNase Rhfrom Rhizopus niveus (Kurihara et al., 1992

), which has 32% sequenceidentity with S₃-RNase. $alpha$ -Helices (A-F) and $beta$ -sheets ( $beta$ 1- $beta$ 7) arelabeled (see Fig. 1 for an alignment between the amino acid sequenceand the structural motifs). The conformation of the loop betweenstrands $beta$ 1 and $beta$ 2 is arbitrary, as it is of substantially differentlength and has no sequence identity to the corresponding loopin RNase Rh. Ball and stick structures of the three disulfidebonds, the free Cys residue (brown), and the active site residues(His-32 and His-88, black; Gln-84, light blue) are shown. TheN-glycosylation site (Asn-28, pink) is shown as a space-filledstructure. The four hypervariable regions are shown in blue. TheN and C termini of S₃-RNase are labeled in a.

All disulfide bonds determined experimentally in the current study are indicated on the model in Figure 4 and are consistentwith the radiographic structure of RNase Rh. One of them, Cys-46-Cys-91,is homologous with a related disulfide bond in RNase Rh (Cys-63-Cys-112),despite being located in a region of the sequence that is nothighly conserved and is heavily truncated in S₃-RNase relativeto RNase Rh. This disulfide bond appears to play a crucial rolein tethering two loops, one that joins strand $beta$ 2 to helix A andanother that joins helix C to helix D, as can been seen from Figure4. These elements of secondary structure are crucial to the orientationof the active site residues, so the high degree of conservationof Cys residues in the connecting loops is not surprising. Thedisulfide bonds Cys-16-Cys-21 and Cys-166-Cys-177 are not presentin RNase Rh, but in the case of the latter bond, the correspondingresidues in RNase Rh (Tyr-193 and Thr-205) are adjacent basedon the sequence alignment used in building the homology model.The other disulfide bond, Cys-16-Cys-21, occurs across a new extendedloop between strands $beta$ 1 and $beta$ 2, and thus has no homology withRNase Rh. It presumably serves to conformationally restrict whatmight otherwise be a relatively flexible loop.

The highest sequence conservation between RNase Rh and S₃-RNase occurs in strand $beta$ 2, which is identical in the two proteinsexcept for a Leu-Ile substitution. This strand contains one oftwo histidines (His-32, using S₃-RNase numbering) implicated atthe active site of RNase Rh. The other active-site His (His-88,using S₃-RNase numbering) is located at the terminus of helixC, in another highly conserved region. In RNase Rh, Glu-105 ishydrogen bonded to the two active-site His residues. In S₃-RNasethe corresponding Glu is replaced by Gln-84. In RNase Rh a Trpresidue was predicted from chemical modification studies (Sandaand Irie, 1980) to be near the active site. In the radiographicstructure, this is hydrogen bonded to the carboxyl group of Glu-105and stacked with the imidazole ring of His-109. It was proposedthat the function of the indole ring of Trp is to fix the orientationof the side chains of these two groups (Kurihara et al., 1992).The high sequence conservation and predicted structural similaritysuggests a similar role for this conserved Trp-35 in S₃-RNase.

	DISCUSSION

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The microheterogeneity of the N-glycans from S₃-RNase of L. peruvianum is consistent with that observed in the S-RNases fromN. alata (Woodward et al., 1992; Oxley and Bacic, 1995; Oxleyet al., 1996), although, overall, the glycans from L. peruvianumare smaller than those found in N. alata. The single potentialN-glycosylation site in the amino acid sequence of S₃-RNase fromL. peruvianum is conserved in almost all S-RNases sequenced todate (Oxley et al., 1996). Although the glycans attached to thissite may have some biological role, they do not appear to be involvedin determining the self-incompatibility phenotype. Transgenicpetunia plants expressing an S-RNase lacking this site still rejectedpollen carrying the corresponding S-allele (Karunanandaa et al.,1994). Furthermore, the structural similarities of the glycansin N. alata suggest that the N-glycans do not encode allelic specificity(Woodward et al., 1992), although the possibility that these oligosaccharidesparticipate in a nonallelic recognition event cannot be excluded.Alternatively, it is possible that the N-glycans assist in stabilizingthe conformation of the native molecule in solution.

The position of each of the three disulfide bonds in S₃-RNase from L. peruvianum is the same as that in S₂-RNase from N. alata(Oxley and Bacic, 1996), although S₂-RNase has an additional disulfidebond in the C-terminal region of the molecule. The extra disulfidebond in N. alata S₂-RNase is between the N. alata equivalent ofCys-150 and a Cys residue that is absent in the L. peruvianum S₃-RNase.Since S₃-RNase shares a similar disulfide bond pattern with bothS₂-RNase and the fungal RNase, RNase Rh (Kurihara et al., 1992),it is likely that all of these molecules have a similar three-dimensionalstructure.

Cys-150 has a free sulfydryl group in S₃-RNase, in contrast to RNase Rh, in which the corresponding Cys-182 is paired in adisulfide bond. Since Cys-150 did not react with 4-vinylpyridine,the free thiol group must be at least partially inaccessible tosolvent, probably because of the steric hindrance of neighboringresidues. At least one free Cys residue has been found in allof the S-RNases examined, including those with an even numberof Cys residues, although the location of the free Cys residueis not conserved. For example, in the L. peruvianum S₃-RNase Cys-150is free, whereas in the N. alata S₆-RNase, which has 10 Cys residues,both Cys-76 and Cys-92 (numbers relative to L. peruvianum S₃-RNase)are free (Ishimizu et al., 1995). Interactions between S-RNasesand other molecules, particularly those in pollen, are importantfor determining the self-incompatibility response. The presenceof a free thiol group on S-RNase may play a role in these interactions;for example, under appropriate conditions it can lead to self-associationof S-RNase molecules (Oxley and Bacic, 1996).

In an alignment of S-RNase sequences from different solanaceous genera, there are two major stretches of sequence (Hva andHvb) with very little sequence identity (Tsai et al., 1992). Inthe model presented here, these regions form a continuous surfaceon one side of the S-RNase (top surface, Fig. 4), although thesesequences are separated from each other in the primary structureof the molecule. This surface also includes two smaller regions,one between Lys-17 and Pro-22, and one between Val-93 and Gln-100,identified as variable between different S-RNase alleles (Haringet al., 1990). Together, these four variable regions may constitutean important part of the allele-specific binding site for thepollen product of the S-locus.

Recent studies in which sequence domains were exchanged between two N. alata S-RNases concluded that recognition was not localizedto a specific domain on the S-RNase but was dispersed over theentire molecule (Zurek et al., 1997). Chimeric proteins containingmost of the sequence from one S-RNase (including the four variabledomains identified by Haring et al. [1990]) and a small amountof sequence from another did not cause transgenic plants to rejectpollen in an allele-specific manner (Zurek et al., 1997). It ispossible that the pollen component of the S-locus binds to a moreextended region of the S-RNase, perhaps including some C-terminalregions, or that the chimeric S-RNases did not present the allelicrecognition domains in their native conformation. Differencesin the amount of carbohydrate attached to the various chimericS-RNases (which have two to four potential N-glycosylation sites)may also contribute to perturbations in folding. The model ofL. peruvianum S₃-RNase presented here may help to predict whichregions are likely to be exposed and hence could interact withthe pollen component of the S-locus in future experiments withchimeric S-RNases.

	FOOTNOTES

¹ This work was supported by a Special Research Centre grant from the Australian Research Council. We acknowledge support forthe purchase of the electrospray-ionization mass spectrometerfrom the Clive and Vera Ramaciotti Foundations, the Ian PotterFoundation, The Australian Research Council, and the Universityof Melbourne. S.P. is the recipient of a Melbourne UniversityScholarship from the Faculty of Science and School of Botany.
^* Corresponding author; e-mail antony_bacic{at}mac.unimelb.edu.au; fax 61-3-9347-1071.

Received May 27, 1997; accepted October 14, 1997.

ABBREVIATIONS

Abbreviations: ESI, electrospray ionization. HIC, hydrophobic-interaction chromatography. RP, reversed-phase. S-RNase, self-incompatibility RNase. TFA, trifluoroacetic acid.

	ACKNOWLEDGMENTS

Thanks to Dr. G. Currie and Ms. K. Dunse for assistance with the ESI-MS and peptide sequencing, respectively. We also thankProf. A.E. Clarke for her support in this project and for helpfuldiscussions.

	LITERATURE CITED

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Structural Analysis and Molecular Model of a Self-Incompatibility RNase from Wild Tomato1

Copyright Clearance Center: 0032-0889/98/116/0463/07 © 1998 American Society of Plant Physiologists

Structural Analysis and Molecular Model of a Self-Incompatibility RNase from Wild Tomato¹

Copyright Clearance Center: 0032-0889/98/116/0463/07

© 1998 American Society of Plant Physiologists