The M locus and ethylene-controlled sex determination in andromonoecious cucumber plants.

Sex determination in cucumber (Cucumis sativus L.) plants is genetically controlled by the F and M loci. These loci interact to produce three different sexual phenotypes: gynoecious (M-F-), monoecious (M-ff), and andromonoecious (mmff). Gynoecious cucumber plants produce more ethylene than do monoecious plants. We found that the levels of ethylene production and the accumulation of CS-ACS2 mRNA in andromonoecious cucumber plants did not differ from those in monoecious plants and were lower than the levels measured in gynoecious plants. Ethylene inhibited stamen development in gynoecious cucumbers but not in andromonoecious ones. Furthermore, ethylene caused substantial increases in the accumulation of CS-ETR2, CS-ERS, and CS-ACS2 mRNA in monoecious and gynoecious cucumber plants, but not in andromonoecious one. In addition, the inhibitory effect of ethylene on hypocotyl elongation in andromonoecious cucumber plants was less than that in monoecious and gynoecious plants. These results suggest that ethylene responses in andromonoecious cucumber plants are reduced from those in monoecious and gynoecious plants. This is the first evidence that ethylene signals may influence the product of the M locus and thus inhibit stamen development in cucumber. The andromonoecious line provides novel material for studying the function of the M locus during sex determination in flowering cucumbers.     

Characterization of ethylene effects on sex determination in cucumber plants

Sex differentiation in cucumber plants (Cucumis sativus L.) appears to be determined by the selective arrest of the stamen or pistil primordia. We investigated the influence of an ethylene-releasing agent (ethephon) or an inhibitor of ethylene biosynthesis (aminoethoxyvinyl glycine) on sex differentiation in different developmental stages of flower buds. These treatments influence sex determination only at the stamen primordia differentiation stage in both monoecious and gynoecious cucumbers. To clarify the relationships between the ethylene-producing tissues and the ethylene-perceiving tissues in inducing female flowers in the cucumber, we examined the localization of mRNA accumulation of both the ACC synthase gene (CS-ACS2) and the ethylene-receptor-related genes (CS-ETR1, CS-ETR2, and CS-ERS) in flower buds by in situ hybridization analysis. CS-ACS2 mRNA was detected in the pistil primordia of gynoecious cucumbers, whereas it was located in the tissues just below the pistil primordia and at the adaxial side of the petals in monoecious cucumbers. In flower buds of andromonoecious cucumbers, only CS-ETR1 mRNA was detected, and was located in the pistil primordia. The localization of the mRNAs of the three ethylene-receptor-related genes in the flower buds of monoecious and gynoecious cucumbers overlap but are not identical. We discuss the relationship between the mRNA accumulation patterns and sex expression in cucumber plants.     

Correlation between development of female flower buds and expression of the CS-ACS2 gene in cucumber plants

Ethylene plays a key role in sex determination of cucumber flowers. Gynoecious cucumber shoots produce more ethylene than monoecious shoots. Because monoecious cucumbers produce both male and female flower buds in the shoot apex and because the relative proportions of male and female flowers vary due to growing conditions, the question arises as to whether the regulation of ethylene biosynthesis in each flower bud determines the sex of the flower. Therefore, the expression of a 1-aminocyclopropane-1-carboxylic acid synthase gene, CS-ACS2, was examined in cucumber flower buds at different stages of development. The results revealed that CS-ACS2 mRNA began to accumulate just beneath the pistil primordia of flower buds at the bisexual stage, but was not detected prior to the formation of the pistil primordia. In buds determined to develop as female flowers, CS-ACS2 mRNA continued to accumulate in the central region of the developing ovary where ovules and placenta form. In gynoecious cucumber plants that produce only female flowers, accumulation of CS-ACS2 mRNA was detected in all flower buds at the bisexual stage and at later developmental stages. In monoecious cucumber, flower buds situated on some nodes accumulated CS-ACS2 mRNA, but others did not. The proportion of male and female flowers in monoecious cucumbers varied depending on the growth conditions, but was correlated with changes in accumulation of CS-ACS2 mRNA in flower buds. These results demonstrate that CS-ACS2-mediated biosynthesis of ethylene in individual flower buds is associated with the differentiation and development of female flowers.     

Molecular characterization and isolation of the <Emphasis Type="Italic">F/f</Emphasis> gene for femaleness in cucumber (<Emphasis Type="Italic">Cucumis sativus</Emphasis> L.)

The biological processes leading to sex expression in plants are of tremendous practical significance for fruit production of many agricultural and horticultural crops. Sex-expression studies in cucumber showed that the different sex types are determined by three major genes: M/m, F/f and A/a. The M/m gene in the dominant condition suppresses stamina development and thus leads to female flowers. The F/f gene in the dominant condition shifts the monoecious sex pattern downwards and promotes femaleness by causing a higher level of ethylene in the plant. To investigate the molecular character of the gene F/f, we used nearly isogenic gynoecious (MMFF) and monoecious (MMff) lines (NIL) produced by our own backcross programme. Our investigations confirmed the result of other groups that an additional genomic ACC synthase (key enzyme of ethylene biosynthesis) sequence (CsACS1G) should exist in gynoecious genotypes. A linkage was also verified between the F/f locus and the CsACS1G sequence with our plant material. After the exploration of different Southern hybridization patterns originating from different CsACS1 probes, a restriction map of the CsACS1 locus was constructed. By using this restriction map, the duplication of the CsACS1 gene and following mutation of the CsACS1G gene could be explained. The promoter regions of the genes CsACS1G and CsACS1 were amplified in a splinkerette PCR and sequenced. An exclusive amplification of the new isolated sequence (CsACS1G) in gynoecious (MMFF) and sub-gynoecious (MMFf) genotypes confirmed that the isolated gene is the dominant F allele.     

AFLP marker polymorphism in cucumber (Cucumis sativus L.) near isogenic lines differing in sex expression

The AFLP technique was used to evaluate the level of polymorphism between two pairs of isogenic cucumber (Cucumis sativus L.) lines (NIL) differing in flower sex expression. The BSA techniques were also applied to find molecular markers linked to sex determination genes (dominant alleles) in those cucumber lines. Sex determination in cucumber is controlled by three main loci F, M and Gy. The interaction of these loci is responsible for the formation of the various phenotypes of flowers in respect to sex in the analyzed lines [corrected]. A female line 2gg with a ff/MM/gygy genotype, isogenic to a monoecious line B10 (genotype ff/MM/GyGy), and a female line Gy3 with a FF/MM/GyGy genotype, isogenic to a hermaphroditic line HGy3 (genotype FF/mm/GyGy). Using 56 combinations of AFLP primers, used for the analysis of lines 2gg and B10, gave 3794 bands, of which 155 (4.1%) were polymorphic. Ten bands distinguished gynoecious and monoecious bulks appearing at the same time in the appropriate parent; they are believed to be linked to the Gy locus. The isogenic lines Gy3 and HGy3 showed a higher level of polymorphism (14.2%). In this case, 55 combinations of primers gave 2996 reaction products, of which 430 showed variation. Twenty bands occurred in one bulk and in one parent, so they are probably associated with the M locus. Using the AFLP technique, the isogenicity of the lines was evaluated. The level of polymorphism (per pair of primer) between lines 2gg and B10 is 0.072% and is four times lower than that between the Gy3 and HGy3 lines (0.27%). The differences in the isogenicity of the lines can result from the degree of their relatedness, which may reflect the way they were derived.     

Auxin,biosynthesis of ethylene and sex expression in cucumber (Cucumis sativus)

Ethylene production, level of 1-aminocyclopropane-1-carboxylic acid (ACC) and activity of the ethylene forming enzyme (EFE) were higher in apices of gynoecious cucumber (Cucumis sativus cv. Alma) as compared to monoecious cucumber (C. sativus cv. Elem). Application of indole-3-acetic acid (IAA) enhanced ethylene and ACC production in both cultivars. The stimulatory effect of IAA was more pronounced in gynoecious apices. Induction of ethylene production and accumulation of ACC resulting from treatment with IAA were effectively blocked by aminoethoxyvinylglycine (AVG). Content of endogenous IAA, measured by an enzyme immunoassay, was lower in gynoecious cucumber as compared to monoecious one. Treatment of gynoecious plants with the antiauxins -(p-chlorophenoxy)isobutyric acid (PCIB) and -naphthaleneacetic acid (-NAA) did not inhibit female sex expression.It appears that although exogenous IAA enhances ACC and ethylene production, endogenous IAA might not have a major role in the control of sex expression in cucumber of the Beit-Alfa type.Prof. Rudich passed away in May 1986.     

Sexual differentiation in cucumber: The effects of abscisic acid and other growth regulators on various sex genotypes

AbA, ethephon and gibberellin were applied to cucumber plantsof monoecious, gynoecious, andromoneocious and hermaphroditeinbred lines, as well as to F₁ (gynoecious?monoecious) plants.Exogenous AbA enhanced the male tendency in monoecious cucumberplants and the female tendency in gynoecious plants, irrespectiveof light regime. Exogenous ethephon treatments increased thefemale tendency in monoecious plants, and decreased it in gynoeciousones. These effects were influenced by day length. ExogenousAbA counteracted the effect of gibberellin (A₄₊₇) treatmentin gynoecious plants, but had no such effect in monoecious ones. In addition to its differential effect on sexual differentiation,AbA stimulated flower development in gynoecious plants and inhibitedit in monoecious plants. These responses to AbA are discussedin the light of previously reported effects of plant growthregulators on various sex types of cucumber. The present resultsare being integrated into an updated working hypothesis on sexcontrol in cucumbers. (Received August 30, 1976; )     

Isolation of a partial sequence of a putative nucleotide sugar epimerase, which may involve in stamen development in cucumber (Cucumis sativus L.)

Sex determination is the most widely studied subject in cucumber. The sex of cucumber plants can be monoecious, hermaphrodite, gynoecious, androecious, or andromonoecious. Besides environmental factors, three major genes, F/f, M/m, and A/a mainly govern the sex types in cucumber. Regardless of their sex all floral buds are bisexual at the early bud stage. A stage specific arrest of either stamen or carpel leads to unisexual flower development. The possible downstream product of the interaction of the sex determining genes that may directly allow the growth or selectively arrest stamen or pistil is not yet identified. Therefore, in the current study, we performed suppression subtractive hybridization using floral buds from nearly isogenic gynoecious and hermaphrodite cucumber plants and identified for the first time a cDNA homologous to nucleotide sugar epimerase. The expression level of the isolated putative nucleotide sugar epimerase is weak in female floral buds but strong in bisexual and male flowers. The weak level of the putative nucleotide sugar epimerase may be an indication for its improper functioning, which may influence stamen development in cucumber plants.     

The level of phytohormones in monoecious and gynoecious cucumbers as affected by photoperiod and ethephon

The endogenous levels of auxin, gibberellin, and inhibitors were followed in monoecious and gynoecious cucumber (Cucumis sativus L.) plants, and in plants treated with the ethylene-releasing compound Ethephon (2-chloroethyl phosphonic acid). Higher auxin inhibitor and lower gibberellin levels were associated with female tendency. The endogenous level of gibberellin and auxin decreased in Ethephon-treated plants. Application of Ethephon induced a rise in abscisic acid. Root application of abscisic acid promoted female tendency of gynoecious cucumbers grown under conditions which increase maleness. High CO₂ levels, which are known to antagonize ethylene, increased maleness of gynoecious cucumbers. The possibility of interrelationship between gibberellin, auxin, ethylene, and abscisic acid on sex expression are discussed.     

Sex expression in cucumber plants as affected by mechanical stress

Sex expression in cucumber plants, as affected by mechanicalstress, was examined using 4 cultivars with different geneticbackgrounds for sex expression. Mechanical stress given to theplant greatly reduced growth and increased the number of pistillate(female) flowers in the monoecious type, but it had no effecton the sex expression of the gynoecious type. The effect ofmechanical stress on the growth and sex expression of the monoecioustype was nullified by the foliar application of gibberellinA₄₊₇. Silver nitrate also was effective in nullifying the effectof mechanical stress on sex expression, but not the effect ofgrowth retardation. Pistillate flowers in a gynoecious strainwere reduced by silver nitrate. (Received October 18, 1979; )     

Mapping and QTL analysis of horticultural traits in a narrow cross in cucumber (Cucumis sativus L.) using random-amplified polymorphic DNA markers

An 80-point genetic map [77 random-amplified polymorphic DNAs (RAPD), F (female sex expression), de (determinate), and ll (little leaf)] was constructed from a narrow cross in cucumber using the determinate, gynoecious, standard-sized leaf line G421 and the indeterminate, monoecious, little leaf line H-19. The map defined nine linkage groups and spanned ca. 600 cM with an average distance between markers of 8.4 ± 9.4 cM. The RAPD loci BC-551 and BC-592 were found to flank ll at 3.4 and 12.2 cM, respectively. The locus OP-L18-2 was linked (16 cM) to de, and the F locus was flanked by markers at 44 and 31 cM. One-hundred F3 families were used to identify quantitative trait loci (QTL) for sex expression, main stem length, number of lateral branches, days to anthesis, fruit number and weight, fruit length and diameter, and fruit length: diameter ratio in two replicated test locations (Wisconsin and Georgia). QTL on linkage group B explained major portions (R2 = ca. 2 to 74%) of the variation observed for sex expression, main stem length, lateral branch number, and fruit diameter (LOD = 2.1 to 29.8). Although ca. 62 to 74% of the variation for sex expression was associated with a putative QTL spanning the F locus (OP-AJ-2 to F and F to de), other regions (three) of the genome were important for the determination of sex in the F3 families examined depending upon environment. The number of genomic regions affecting main stem length (five) and number of lateral branches (three) coincided with expectations as determined by calculations of minimum number of genes in previous studies. Evaluation of QTL associated with several fruit number determinants of early, first-harvest yield demonstrating additive genetic variance (i.e., sex expression, main stem length, and number of laterals) suggests that marker-assisted selection may have utility for the development of determinate, multiple lateral branching germplasm suited for once-over mechanical harvesting in this population.