Endogenous tassel-specific small RNAs-mediated RNA interference enables a novel glyphosate-inducible male sterility system for commercial production of hybrid seed in Zea mays L.

Heping Yang,Martin A Stoecker,Yuanji Zhang,Mike E Goley,Sergey Ivashuta,Oscar C Sparks,Marguerite J Varagona,B Elizabeth Wiggins,Youlin Qi,Jintai Huang,Jennifer King-Sitzes,Amy L Caruano-Yzermans,Brook M Van Scoyoc,Aihong Pan,Xin Li,Jiyan Ma,Wei Wang

doi:10.1371/journal.pone.0202921

Abstract

Hybrid crops produce higher yields than their inbred parents due to heterosis. For high purity of hybrid seeds, it is critical to eliminate self-pollination. Manual or mechanical removal of male parts (such as detasseling in maize) is labor-intensive, fuel and time-consuming, and can cause physical damage to female plants, resulting in significant seed yield reductions. Many male-sterility systems either require a maintainer for male-sterile line propagation or are often affected by environmental factors. Roundup® Hybridization System (RHS) utilizes glyphosate to induce male sterility, which effectively eliminates the need for maintainer lines and removal of male parts for commercial hybrid seed production. The first-generation RHS (RHS1) is based on low expression of a glyphosate-insensitive 5-enolpyruvylshikimate-3-phosphate synthase (CP4 EPSPS) in pollen. This report presents the second-generation RHS (RHS2) technology built on RNA interference (RNAi) combined with CP4 EPSPS. It utilizes maize endogenous male tissue-specific small interfering RNAs (mts-siRNAs) to trigger cleavage of the CP4 EPSPS mRNA specifically in tassels, resulting in glyphosate-sensitive male cells due to lack of the CP4 EPSPS protein. Male sterility is then induced by glyphosate application at the stages critical for pollen development, and the male-sterile plants are used as the female parent to produce hybrid seed. The endogenous mts-siRNAs are conserved across maize germplasms, and the inducible male sterility was replicated in representative germplasms through introgression of a CP4 EPSPS transgene containing the mts-siRNA target sequence. This technology combines the relative simplicity and convenience of a systemic herbicide spray methodology with targeted protein expression to create an inducible male sterility system for industrial production of row crop hybrid seeds in an environmentally-independent manner.

Highlights

Hybrid crops derived from crosses between diverse varieties of a species or different species exhibit greater growth rate, biomass, fertility and yield than their parents due to heterosis [1]
A key component of the RHS2 technology is a mts-system in plants interfering RNAs (siRNAs) target sequence is incorporated into the CP4 enolpyruvylshikimate-3-phosphate synthase (EPSPS) cassette as a unique expression regulatory element within the 3’ untranslated region (3’untranslated region (UTR)) (S2 Fig), and this is targeted by the endogenous mts-siRNAs (Fig 4A)
The RHS2 technology was created for hybrid seed production to take advantage of the naturally occurring siRNA-mediated RNA interference (RNAi) pathway in maize

Summary

Introduction

Hybrid crops derived from crosses between diverse varieties of a species or different species exhibit greater growth rate, biomass, fertility and yield than their parents due to heterosis [1]. Cytoplasmic male sterility [2]), genic male-sterility mutants [4, 5], transgenic lines in which proteins toxic to male tissues are expressed [6,7,8,9], or transgenic lines in which genes critical to male tissue development are suppressed [10,11,12,13] can be used to prepare female parents for hybrid seed production These male sterility systems require one or more maintainers for fertility restoration so that the male sterile line can be propagated [2, 14, 15]

Methods

Results

Discussion

Conclusion