Abstract
Understanding the control of fertility is critical for crop yield and breeding; this is particularly important for hybrid breeding to capitalize upon the resultant hybrid vigour. Different hybrid breeding systems have been adopted; however, these are challenging and crop specific. Mutants with environmentally reversible fertility offer valuable opportunities for hybrid breeding. The barley HvMS1 gene encodes a PHD-finger transcription factor that is expressed in the anther tapetum, which is essential for pollen development and causes complete male sterility when overexpressed in barley. This male sterility is due at least in part to indehiscent anthers resulting from incomplete tapetum degeneration, failure of anther opening, and sticky pollen under normal growth conditions (15 °C). However, dehiscence and fertility are restored when plants are grown at temperatures >20 °C, or when transferred to >20 °C during flowering prior to pollen mitosis I, with transfer at later stages unable to rescue fertility in vivo. As far as we are aware, this is the first report of thermosensitive male sterility in barley. This offers opportunities to understand the impact of temperature on pollen development and potential applications for environmentally switchable hybrid breeding systems; it also provides a 'female' male-sterile breeding tool that does not need emasculation to facilitate backcrossing.
Highlights
Population growth alongside increased desire for consumption has made food security an important global issue
We identified the HvMALE STERILITY1 (HvMS1) PHD-finger transcription factor gene that is transiently expressed in the tapetum prior to the pollen mitosis I (PMI) stage (Fernández Gómez and Wilson, 2014), which is essential for pollen development in barley and orthologous to Arabidopsis MS1 (Wilson et al, 2001) and rice PTC1 (Li et al, 2011).The Arabidopsis ms1 mutant is completely male sterile; RNAi silencing of HvMS1 in barley only showed partial sterility, whilst overexpression of HvMS1 caused complete sterility without impacting on other aspects of plant development (Fernández Gómez and Wilson, 2014)
We previously identified the orthologous gene of Arabidopsis MS1 in barley (Fernández Gómez andWilson, 2014), encoding a PHD-finger domain transcription factor that is essential for pollen formation and is expressed transiently in the tapetum immediately prior to PMI
Summary
Population growth alongside increased desire for consumption has made food security an important global issue. The FAO reported that between 2011 and 2013, an estimated 842 million people (12% of the global population) were unable to meet their dietary energy requirements (FAO, 2013). This situation is likely to worsen over time as the population is expected to increase from 6 to 9 billion. This is predicted to increase food needs by 50% by 2030, and 100% by 2050 (FAO, 2013). Estimates of heterosis yield increases vary between 3% and Temperature-sensitive male sterility in barley | 6329
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