Downregulated expression of S2-RNase attenuates self-incompatibility in \u201cGuiyou No. 1\u201d pummelo

Jianbing Hu,Binghao Liu,Qiang Xu,Xiangling Chen,Kang Peng,Hao Wen,Chuanwu Chen,Xiuxin Deng,Lijun Chai,Zhuangmin Wei,Peng Chen,Junli Ye,Chenchen Liu,Muhammad Husnain Ahmad,Chongling Deng,Robert M Larkin

doi:10.1038/s41438-021-00634-8

Abstract

Self-incompatibility (SI) substantially restricts the yield and quality of citrus. Therefore, breeding and analyzing self-compatible germplasm is of great theoretical and practical significance for citrus. Here, we focus on the mechanism of a self-compatibility mutation in ‘Guiyou No. 1’ pummelo (Citrus maxima), which is a spontaneous mutant of ‘Shatian’ pummelo (Citrus maxima, self-incompatibility). The rate of fruit set and the growth of pollen tubes in the pistil confirmed that a spontaneous mutation in the pistil is responsible for the self-compatibility of ‘Guiyou No. 1’. Segregation ratios of the S genotype in F1 progeny, expression analysis, and western blotting validated that the reduced levels of S2-RNase mRNA contribute to the loss of SI in ‘Guiyou No. 1’. Furthermore, we report a phased assembly of the ‘Guiyou No. 1’ pummelo genome and obtained two complete and well-annotated S haplotypes. Coupled with an analysis of SV variations, methylation levels, and gene expression, we identified a candidate gene (CgHB40), that may influence the regulation of the S2-RNase promoter. Our data provide evidence that a mutation that affects the pistil led to the loss of SI in ‘Guiyou No. 1’ by influencing a poorly understood mechanism that affects transcriptional regulation. This work significantly advances our understanding of the genetic basis of the SI system in citrus and provides information on the regulation of S-RNase genes.

Highlights

Self-incompatibility (SI) is a reproductive strategy adopted by flowering plants to prevent inbreeding and promote outcrossing; it is a reproductive strategy that promotes genetic diversity[1]
Coupled with an analysis of Structural variants (SVs) variations, methylation levels, and gene expression, we identified a candidate gene (CgHB40), that may influence the regulation of the S2-RNase promoter
Is a component of a Skp1-Cullin1-F-box (SCF) complex that promotes the growth of nonself pollen tubes by ubiquitinating and degrading nonself S determinant encodes an exocrine protein (S-RNase) in a 26S proteasome-dependent manner[7,8,9,10]

Summary

Introduction

Self-incompatibility (SI) is a reproductive strategy adopted by flowering plants to prevent inbreeding and promote outcrossing; it is a reproductive strategy that promotes genetic diversity[1]. The SI system has been classified into two types, sporophytic SI (SSI) and gametophytic SI (GSI), based on the genetic mechanism controlling the SI phenotype of the pollen[2,3]. Each SI system is a component of a Skp1-Cullin1-F-box (SCF) complex that promotes the growth of nonself pollen tubes by ubiquitinating and degrading nonself S-RNases in a 26S proteasome-dependent manner[7,8,9,10]. SI can limit reproduction, especially during agricultural production. This is a short-term disadvantage of SI that is expected to promote frequent transitions to SC5

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Results

Conclusion