The role of ethylene and brassinosteroids in the control of sex expression and flower development in Cucurbita pepo

Abstract: In this paper we compare the sensitivity of different squash genotypes to ethylene and brassinosteroids by studying the effects of different ethylene and brassinosteroid treatments on the sexual expression and flower development of different C. pepo genotypes: Bolognese (Bog) and Vegetable Spaghetti (Veg), two contrasting lines for ethylene production and sensitivity, as well as Cora, a standard commercial hybrid. Results have demonstrated that ethylene has a much greater effect on sexual expression and flower… Show more

“…Therefore, ethylene is responsible for the arrest of stamens in the floral bud whose fate is the formation of a female flower. Since the bisexual flowers with partial stamen development observed under high temperatures produced as little ethylene as male flowers, it is unlikely that they may be produced as a consequence of a partial reduction of ethylene in the floral bud, but rather due to a reduction of ethylene in already determined female floral buds, as was previously proposed in cucumber and zucchini (Yamasaki et al, 2003;Manzano et al, 2011). The genes responsible for monoecy in melon, cucumber and zucchini, CmACS7, CsACS2 and CpACS27A, are expressed very early in the development of female flowers, and their loss of function mutations or their inhibition at early developmental stages produces a complete conversion of female into bisexual flowers and of monoecy into andromonoecy (Boualem et al, 2008Li et al, 2009;Martínez et al, 2014).…”

“…While Bog develops the first female flowers between nodes 2e4, and produces a mean of 69e75% female flowers, the sex phenotype of Veg is strongly male, delaying the development of the first female flower to nodes 15e20, and producing less than 25% female flowers, with some of the plants producing less than 5% (Manzano et al, 2010). The extreme male phenotype of Veg is determined by a major gene that confers reduced ethylene production and sensitivity, while Bog produces much more ethylene and has a higher sensitivity to the hormone (Manzano et al, 2010(Manzano et al, , 2011. Grafting was carried out when the first true leaf developed in both the rootstock and scion seedlings, following standard methods in Almería nurseries.…”

“…Given that ethylene is required for the arrest of stamens in female flower development, it would be expected that this hormone promotes female flowering transition and the number of female flowers per plant. This is true for cucurbit species such as cucumber, melon and zucchini, in which ethylene treatments reduce the initial male phase of development and increase the female to male flower ratio, while treatments with inhibitors of ethylene biosynthesis or perception, such as aminoethoxyvinylglycine (AVG) or silver thiosulphate (STS), delay female flowering and reduce the female to male flower ratio (Byers et al, 1972;Manzano et al, 2011;Pay an et al, 2006;Perl-Treves, 1999;Rudich, 1990). In watermelon, however, previous reports had shown that ethylene regulates sexual expression in a completely opposite way.…”

“…The level of ethylene in flower buds seems to be essential for both sex determination and female flower development (Manzano et al, 2013). Thus, ethylene treatments promote the production of female flowers, while treatments with inhibitors of ethylene biosynthesis or perception, such as aminoethoxyvinylglycine (AVG) or silver thiosulphate (STS), increase the number of male flowers per plant (Byers et al, 1972;DenNijs and Visser, 1980;Manzano et al, 2011;Owens et al, 1980;Pay an et al, 2006;Rudich, 1990;Rudich et al, 1969). It has been demonstrated that the monoecious phenotype of melon and Abbreviations:…”

“…Treatment with ethylene-releasing agents resulted mostly in the suppression of ovary development (Rudich and Zamski, 1985), while inhibitors of its biosynthesis and perception, hastened the appearance of the first pistillate flower and increased the pistillate to male flower ratio (Rudich and Zamski, 1985;Sugiyama et al, 1998). The masculinizing effect of ethylene in watermelon is in stark contrast to the feminizing effect of this same hormone in other cucurbit species such as cucumber, melon and squash (Manzano et al, 2011).…”

Involvement of ethylene in sex expression and female flower development in watermelon (Citrullus lanatus)

“…Therefore, ethylene is responsible for the arrest of stamens in the floral bud whose fate is the formation of a female flower. Since the bisexual flowers with partial stamen development observed under high temperatures produced as little ethylene as male flowers, it is unlikely that they may be produced as a consequence of a partial reduction of ethylene in the floral bud, but rather due to a reduction of ethylene in already determined female floral buds, as was previously proposed in cucumber and zucchini (Yamasaki et al, 2003;Manzano et al, 2011). The genes responsible for monoecy in melon, cucumber and zucchini, CmACS7, CsACS2 and CpACS27A, are expressed very early in the development of female flowers, and their loss of function mutations or their inhibition at early developmental stages produces a complete conversion of female into bisexual flowers and of monoecy into andromonoecy (Boualem et al, 2008Li et al, 2009;Martínez et al, 2014).…”

“…While Bog develops the first female flowers between nodes 2e4, and produces a mean of 69e75% female flowers, the sex phenotype of Veg is strongly male, delaying the development of the first female flower to nodes 15e20, and producing less than 25% female flowers, with some of the plants producing less than 5% (Manzano et al, 2010). The extreme male phenotype of Veg is determined by a major gene that confers reduced ethylene production and sensitivity, while Bog produces much more ethylene and has a higher sensitivity to the hormone (Manzano et al, 2010(Manzano et al, , 2011. Grafting was carried out when the first true leaf developed in both the rootstock and scion seedlings, following standard methods in Almería nurseries.…”

“…Given that ethylene is required for the arrest of stamens in female flower development, it would be expected that this hormone promotes female flowering transition and the number of female flowers per plant. This is true for cucurbit species such as cucumber, melon and zucchini, in which ethylene treatments reduce the initial male phase of development and increase the female to male flower ratio, while treatments with inhibitors of ethylene biosynthesis or perception, such as aminoethoxyvinylglycine (AVG) or silver thiosulphate (STS), delay female flowering and reduce the female to male flower ratio (Byers et al, 1972;Manzano et al, 2011;Pay an et al, 2006;Perl-Treves, 1999;Rudich, 1990). In watermelon, however, previous reports had shown that ethylene regulates sexual expression in a completely opposite way.…”

“…The level of ethylene in flower buds seems to be essential for both sex determination and female flower development (Manzano et al, 2013). Thus, ethylene treatments promote the production of female flowers, while treatments with inhibitors of ethylene biosynthesis or perception, such as aminoethoxyvinylglycine (AVG) or silver thiosulphate (STS), increase the number of male flowers per plant (Byers et al, 1972;DenNijs and Visser, 1980;Manzano et al, 2011;Owens et al, 1980;Pay an et al, 2006;Rudich, 1990;Rudich et al, 1969). It has been demonstrated that the monoecious phenotype of melon and Abbreviations:…”

“…Treatment with ethylene-releasing agents resulted mostly in the suppression of ovary development (Rudich and Zamski, 1985), while inhibitors of its biosynthesis and perception, hastened the appearance of the first pistillate flower and increased the pistillate to male flower ratio (Rudich and Zamski, 1985;Sugiyama et al, 1998). The masculinizing effect of ethylene in watermelon is in stark contrast to the feminizing effect of this same hormone in other cucurbit species such as cucumber, melon and squash (Manzano et al, 2011).…”

Involvement of ethylene in sex expression and female flower development in watermelon (Citrullus lanatus)

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