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  • Author or Editor: Toshio Hanada x
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Most commercial cultivars of japanese plum (Prunus salicina Lindl.) exhibit S-RNase-based gametophytic self-incompatibility (GSI), although some self-compatible (SC) cultivars exist. In this study, we characterized S-RNase and SFB, the pistil and pollen S determinants of the specificity of the GSI reaction, respectively, from four S-haplotypes, including a SC (Se ) and three SI (Sa , Sb , and Sc ) S-haplotypes of japanese plum. The genomic organization and structure of the SC Se-haplotype appear intact, because the relative transcriptional orientation of its S-RNase and SFB and their intergenetic distance are similar to those of the other three SI S-haplotypes of japanese plum and other Prunus L. species. Furthermore, there is no apparent defect in the DNA sequences of Se-RNase and SFBe . However, a series of transcriptional analyses, including real-time reverse transcriptase–polymerase chain reaction, showed that the Se-RNase transcript levels in the pistil are significantly lower than those of the Sa-, Sb-, and Sc-RNases, although transcripts of SFBa , SFBb , SFBc , and SFBe are present at similar levels in pollen. Furthermore, no Se-RNase spot was detected in two-dimensional polyacrylamide gel electrophoresis profiles of stylar extracts of the cultivars with the Se-haplotype. We discuss the possible molecular basis of SC observed with the Se -haplotype with special reference to the insufficient Se-RNase accumulation incited by the very low transcriptional level of Se-RNase in pistils.

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Most of the self-compatible (SC) cultivars of almond [Prunus dulcis (Mill.) D.A. Webb. syn. P. amygdalus Batsch] have the Sf haplotype. In this study, we cloned and characterized the S locus region of the Sf haplotype of SC ‘Lauranne’. The relative transcriptional orientation of SFBf and Sf-RNase and the physical distance between them are similar to those of other functional self-incompatible (SI) S haplotypes of Prunus, indicating that the genomic structure of the SC Sf haplotype appears to be intact. Although there is no apparent mutation in the coding sequence of SFBf , the Sf-RNase sequence in this study and previously reported Sf-RNase sequences show discrepancies. First, as opposed to previous indications, the ‘Lauranne’ Sf-RNase sequence encodes a histidine residue in place of a previously reported arginine residue in the conserved C2 region of Prunus S-RNase. Direct sequencing of the polymerase chain reaction products from the Sf-RNase of ‘Tuono’ confirmed that ‘Tuono’ Sf-RNase also encodes the histidine residue. We found another difference in the ‘Lauranne’ Sf-RNase sequence and other reported Sf-RNase sequences. Namely, ‘Lauranne’ Sf-RNase encodes a phenylalanine residue in place of a previously reported leucine residue in the conserved C5 region of Prunus S-RNase. This is also the case for ‘Tuono’ Sf-RNase. Expression analysis of Sf-RNase and SFBf by reverse transcriptase–polymerase chain reaction showed that Sf-RNase transcripts were barely detectable in pistil, whereas SFBf transcripts were accumulated at a similar level to the level that was observed with SFB of other functional SI S haplotypes of almond. We discuss the possible molecular mechanisms of SC observed with the Sf haplotype with special references to the expression of Sf-RNase.

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