p-CPA increases the endogenous IAA content of parthenocarpic muskmelon fruit

We examined the effects of seed formation andpara-chlorophenoxyacetic acid (p-CPA)treatment on the growth and endogenous indole acetic acid (IAA) content ofmuskmelon fruit. The growth of parthenocarpic muskmelon fruit induced by 1-(2-chloro-4-pyridyl)-3-phenylurea (CPPU) declined 15 days after anthesis (DAA),resulting in smaller fruit than those pollinated at harvest.p-CPA improved the growth of parthenocarpic fruit thatweretreated between 10 and 25 DAA. Endogenous IAA levels in the seedsof artificially pollinated fruit were at their highest at 10 DAA,then decreased, and increased again after 30 to 45 DAA, whereas,the levels in the empty seeds of parthenocarpic fruit were significantly lowerthroughout development. Although endogenous IAA levels in the placenta ofpollinated fruit were lower than those in the seeds, the changing patterns werevery similar to those in the seeds. Endogenous IAA levels in the mesocarp ofpollinated fruit remained lower than those in the placenta throughout fruitgrowth, and the pattern of change was similar to that of the placenta. Levelsinthe seed, placenta and mesocarp of p-CPA-nontreatedparthenocarpic fruit stayed lower than those in pollinated fruit.p-CPA increased the levels of IAA in the seeds, placenta,and mesocarp of parthenocarpic fruit after the first treatment (10DAA) to 15 DAA, while those in the mesocarp increasedsignificantly after the second treatment (25 DAA), but did notincrease in empty seed and placenta.     

Tissue-specific organic acid metabolism in reproductive and non-reproductive parts of the fig fruit is partially induced by pollination

Organic acids are important components of overall fruit quality through flavor, taste, nutritional and medicinal values. Pollinated fig (Ficus carica L.) fruit quality is enhanced by increased acidity. We quantified the major organic acids and characterized the expression pattern of organic acid metabolic pathway-related genes in the reproductive part – inflorescence and non-reproductive part – receptacle of parthenocarpic and pollinated fig fruit during ripening. Essentially, pollinated fruit contains seeds in the inflorescence, as opposed to no seeds in the parthenocarpic inflorescence. The major organic acids – citrate and malate – were found in relatively high quantities in the inflorescence compared to the receptacle of both parthenocarpic and pollinated fig fruit. Notably, pollination increased citric acid content significantly in both inflorescence and receptacle. Genes related to the phosphoenolpyruvate carboxylase (PEPC) cycle, tricarboxylic acid cycle, citrate catabolism and glyoxylate cycle were identified in fig fruit. Expression levels of most of these genes were higher in inflorescences than in receptacles. In particular, FcPEPC and FcFUM (encoding fumarase) had significantly higher expression in the inflorescence of pollinated fruit. Most importantly, expression of the glyoxylate cycle genes FcMLS and FcICL (encoding malate synthase and isocitrate lyase, respectively) was induced to strikingly high levels in the inflorescence by pollination, and their expression level was highly positively correlated with the contents of all organic acids. Therefore, the glyoxylate cycle may be responsible for altering the accumulation of organic acids to upgrade the fruit taste during ripening, especially in the pollinated, seeded inflorescence.     

Chlorophenoxyacetic acid and chloropyridylphenylurea accelerate translocation of photoassimilates to parthenocarpic and seeded fruits of muskmelon (Cucumis melo)

We compared the effect of p-chlorophenoxyacetic acid (p-CPA) and 1-(2-chloro-4-pyridyl)-3-phenylurea (CPPU) on parthenocarpic and seeded muskmelon (Cucumis melo) fruits in regards to fruit development and the transport of photoassimilates from leaves exposed to ¹⁴CO₂ to the developing fruits. Ten days after anthesis (DAA), the fresh weight, total ¹⁴C-radioactivity and contents of ¹⁴C-sucrose and ¹⁴C-fructose were higher in the CPPU-induced parthenocarpic fruits than in seeded fruits. However, at 35 DAA, fresh weight and sucrose content in mesocarp, placenta and empty seeds of the parthenocarpic fruits were lower than in seeded fruits. Also, total ¹⁴C-radioactivity and ¹⁴C-sugar content of the parthenocarpic fruits were lower as well as the translocation rate of ¹⁴C-photoassimilates into these fruits. Application of p-CPA to the parthenocarpic fruits at 10 and 25 DAA increased fresh weight and sugar content. Moreover, these treatments elevated the total ¹⁴C-radioactivity, ¹⁴C-sucrose content and the translocation rate of ¹⁴C-photoassimilates. The ¹⁴C-radioactivity along the translocation pathway from leaf to petiole, stem, lateral shoot and peduncle showed a declining pattern but dramatically increased again in the fruits. These results suggest that the fruit's sink strength was regulated by the seed and enhanced by the application of p-CPA.     

p-CPA enhances growth and quality of muskelon fruits

The effects of para-chlorophenoxyacetic acid(p-CPA) application in improving the reduction in growthrate and sugar accumulation, and on the peel color and firmness ofparthenocarpic fruit, and its residual content in the treated fruit wereexamined. p-CPA application to parthenocarpic fruit duringthe rapid growth stage [5 or 10 days after anthesis (DAA)] enhanced the fruitweight, but was ineffective when applied at 40 DAA. p-CPA– promoting of fruit growth increased as the applied concentration rose,so the weight of fruit treated by p-CPA at 500 mgL^–1 (the highest level) was the greatest in all plots;however the peel was considerably softer and abnormal swelling occurred in thenet. p-CPA applied to parthenocarpic fruit from 5 to 25DAAincreased sucrose content, the most effective application time being justbeforethe onset of sucrose accumulation (25 DAA). Fructose and glucose contents wereconsiderably lower than that of sucrose, and were not affected byp-CPA. p-CPA promoted sucroseaccumulation when applied to pollinated fruit, which showed the highest levelofenhancement in all plots. During the maturation period, the peel ofparthenocarpic fruit was a darker green color and the netting did not fullydevelop compared to pollinated fruit. p-CPA applicationsat10 or 25 DAA improved the peel color and netting of parthenocarpic fruits;therefore, the L value was similar to that of seeded fruit and the hue angledeclined. Applications of p-CPA during the early growthstage reduced the firmness of the mesocarp concomitant with increases in theapplied concentrations. p-CPA was present in the fruit atharvest, when applied from 10 to 25 DAA, even at 20 mgL^–1. The residue level increased as the appliedconcentration rose, but p-CPA was not detected in thenon-treated plot.     

Strong synergistic effects of gibberellins with the synthetic cytokinin N-(2-chloro-4-pyridyl)-N-phenylurea on parthenocarpic fruit set and some other fruit characteristics of apple

The induction of parthenocarpic fruit set was investigated using the apple cvs. Golden Delicious and Jonagold. The gibberellins GA₃, GA₄, GA₅ and GA₇ and the synthetic phenylurea-type cytokinin CPPU (N-(2-chloro-4-pyridyl)-N-phenylurea), were applied alone and in combination to unpollinated flowers at the end of petal fall. Gibberellins induced only a marginal final set of parthenocarpic fruits. CPPU sprays were more effective, particularly in the first year. When applied in combination, CPPU and gibberellins had a positive synergistic effect on parthenocarpic fruit set and fruit size, but a negative effect on flower induction the next year. After CPPU + GA sprays, percent fruit set was similar, or greater, compared to natural pollinated trees. The parthenocarpic fruits induced by CPPU + GA had an increased length to diameter ratio. CPPU stimulated, and GA₄ and GA₇ reduced, the russeting of the parthenocarpic fruits. The internal quality of the fruits was hardly affected, but Ca-deficiency symptoms occurred more frequently in parthenocarpic fruits.     

Cell division and cell enlargement in fruit of Lagenaria leucantha as influenced by pollination and plant growth substances

The effects of NAA (naphthaleneacetic acid), GA₃ (gibberellic acid), CPPU (N-(2-chloro-4-pyridyl)-N'-phenylurea) and pollination on fruit set, cell division and enlargement were studied in Lagenaria leucantha, an important vegetable. NAA and GA₃ were ineffective in inducing parthenocarpy, whereas CPPU induced parthenocarpic fruit significantly larger than fruit that resulted from pollination. Cell division, which occurred during the first 4 days after pollination was not reactivated by NAA or GA₃, but was effectively reactivated by CPPU. The cell number of the total cross-section of CPPU-treated fruit was 117.4% of that of pollinated fruit and 154.4% of that of unpollinated at 12 DAA (days after anthesis) respectively. The CPPU-induced parthenocarpic fruit had the largest cell cross-sectional area followed, successively, by pollinated fruit, NAA-treated fruit, GA₃-treated fruit and unpollinated fruit. These results indicate that CPPU induced parthenocarpic fruit growth by directly reactivating cell division and expansion.     

Parthenocarpic Fruit Development from Grafted Ovaries of Cucuminis sativus L

Reciprocal cleft and pistillate floral bud grafts were made between parthenocarpic `Fertilla' and nonparthenocarpic `MSU 713-5' cucumber (Cucumis sativus L.) lines to localize the site for stimulation of parthenocarpic fruit set. No fruit set on `MSU 713-5' controls, scion grafted to `Fertilla,' or rootstock with `Fertilla' as the scion. `Fertilla' controls, rootstock, and scions all produced parthenocarpic fruit when grafted to `MSU 713-5.' When pistillate floral buds of `MSU 713-5' were grafted to `Fertilla,' no fruit were produced. However, individual immature pistillate buds of `Fertilla' developed into mature fruits when grafted onto `MSU 713-5.' Hence, the immature ovary is the site of stimulation for parthenocarpic fruit set in cucumber.     

Parthenocarpy and seed predation by insects in Bursera morelensis

Background and Aims

While parthenocarpy (meaning the production of fruits without seeds) may limit fecundity in many plants, its function is not clear; it has been proposed, however, that it might be associated with a strategy to avoid seed predation. Bursera morelensis is a dioecious endemic plant that produces fruits with and without seeds, and its fruits are parasitized by insects. Its reproductive system is not well described and no published evidence of parthenocarpy exists for the species. The purpose of this work was to describe the breeding system of B. morelensis and its relationship to seed predation by insects.

Methods

The breeding system was described using pollination experiments, verifying the presence of parthenocarpic fruits and apomictic seeds. Reproductive structures from flower buds to mature fruits were quantified. For fruits, an anatomical and histological characterization was made. The number of fruits in which seeds had been predated by insects was correlated with parthenocarpic fruit production.

Key Results

The major abortion of reproductive structures occurred during fruit set. The results discard the formation of apomictic seeds. Flowers that were not pollinated formed parthenocarpic fruits and these could be distinguished during early developmental stages. In parthenocarpic fruits in the first stages of development, an unusual spread of internal walls of the ovary occurred invading the locule and preventing ovule development. Unlike fruits with seeds, parthenocarpic fruits do not have calcium oxalate crystals in the ovary wall. Both fruit types can be separated in the field at fruit maturity by the presence of dehiscence, complete in seeded and partial in parthenocarpic fruits. Trees with more parthenocarpic fruits had more parasitized fruits.

Conclusions

This is the first time the anatomy of parthenocarpic fruits in Burseraceae has been described. Parthenocarpic fruits in B. morelensis might function as a deceit strategy for insect seed predators as they are unprotected both chemically and mechanically by the absence of calcium oxalate crystals.Key words: Parthenocarpy, Bursera morelensis, predation, seeds, insects, breeding system, calcium oxalate crystals     

Early Fruit Development in the Watermelon: Anatomical Comparison of Pollinated, Auxin-induced Parthenocarpic and Unpollinated Fruits

The anatomy of pollinated, auxin-induced parthenocarpic andunpollinated watermelon fruits was observed for nine days afterflowering. Parthenocarpic fruits were larger and had higherfresh weight and percentage water than pollinated fruits atday 1 but the positions were reversed by day 9. Unpollinatedfruits did not increase in size after day 3. Pericarp cells were small, of regular shape and showed no obviouschange with either time or treatment. Cell number increasedin the pollinated and parthenocarpic but not in the unpollinatedfruits. Cells divided in the flesh of the parthenocarpic but not ofthe pollinated fruits which increased in size by cell enlargementonly. Starch, present in the cells of the flesh and placentaat day 0 was absent from the unpollinated fruits at day 6. Ovules grew in both pollinated and parthenocarpic fruits largelydue to cell division in the nucellus and integuments; the pollinatedovules were larger than the parthenocarpic throughout. Embryoand endosperm development occurred in the pollinated but notin the parthenocarpic ovules. Starch was present throughoutthe nine-day period in the integuments of the pollinated andparthenocarpic ovules but was lost from the integuments of theunpollinated ovules by day 6. Pollinated and parthenocarpicovules contributed increasingly to fruit dry weight over thenine-day period. It is suggested that the ovule tissues, in particular the nucellusand integument may exert control over early development in bothpollinated and parthenocarpic fruits.     

Fruit characteristics, seed production and pollen tube growth in the wild chilli pepper Capsicum flexuosum

Fruits formed after different pollination regimes (flowers hand pollinated, unpollinated, and open pollinated) and the seeds obtained were characterized in the wild chilli pepper Capsicum flexuosum Sendtn. Pollen tube development in vivo and ovary growth were also analyzed. Seedless fruits and empty seeds were abundant among the fruits from hand pollinated and open pollinated flowers, while no more than one seed with embryo was found in a low percentage of fruits from such pollination treatments. Parthenocarpic fruits were formed from unpollinated flowers. Pollen tube growth was arrested in the upper third of the style for almost all pollen tubes except for a single one that may continue elongating occasionally. The ovary size increased continuously after pollination, even without fertilization. The sum of the evidence registered may help to explain the low number of seeds with embryo harvested, the abundance of seedless fruits formed from pollinated flowers (possibly parthenocarpic), and the high rate of parthenocarpic fruits formed from unpollinated flowers.     

Induced parthenocarpy—a way of changing the levels of endogenous hormones in tomato fruits (Lycopersicon esculentum Mill.) 1. Extractable hormones

Ethylene, indol-3-acetic acid (IAA), gibberellin-like substances (GAs) and abscisic acid (ABA) were analysed in extracts from normal, seed-containing and parthenocarpic tomato fruits throughout fruit development. Parthenocarpic fruit growth was induced with an auxin (4-CPA), morphactin (CME) or gibberellic acid (GA₃) and compared with that of pollinated control fruits. Fruit growth was only affected by the treatment with GA₃, decreasing size and fresh weight by 60%. The peak sequence of hormones during fruit development was ethylene-GAs-IAA-ABA. Seeded fruits contained the highest levels of IAA and ABA but the lowest levels of GAs. Also, in seeded fruits, a high proportion of IAA and ABA was found in the seeds whereas this was not the case for GAs.Hormone levels of tomato fruits may be successfully, easily and reproducibly altered by inducing parthenocarpic fruit growth and thus eliminating development of seeds which are a major source of hormone synthesis. In spite of markedly changed hormone levels, there was no obvious relationship between fruit growth and extractable hormones per se. However, the results indicate that a high ratio of GAs: auxins is unfavourable for growth of tomato fruits.     

Transcriptomes of Fruit Cavity Revealed by De Novo Sequence Analysis in Nai Plum (<Emphasis Type="Italic">Prunus salicina</Emphasis>)

Nai plum (Prunus salicina) is an important fruit crop in China having good taste and flavour. Cavity formation occurring during fruit development affects fruit quality. However, the molecular mechanism underlying cavity formation is unclear. To obtain differential expression profiles of cavity fruit (CF) and non-cavity fruit (nCF) in P. salicina, we sequenced the fruits at different time intervals of 7 days after anthesis (DAA), 21 and 28 DAA, respectively, and 83,869 unigenes, 3811 differentially expressed genes, 22,971 simple sequence repeats and over 14,000 single nucleotide polymorphisms were obtained. Twenty-three differentially expressed genes were selected for verification by qRT-PCR. The contents of phytohormones during fruit development showed that there was a positive relevance between phytohormone contents (IAA, ZR and GA), fruit size and ABA contents in the fruits, whereas there was a negative correlation with ZR, GA and IAA. Lower GA content in fruit before 14 DAA and higher IAA and ZR levels during later developmental stages resulted in cavity appearance. Further studies showed that differential expression of phytohormone-related genes IPT, CKX, YUCCA, GA20ox, GID1, CCS1 was determined at key fruit development stages, which is consistent with content changes of IAA, GA, ABA and ZR. Our results suggest that ABA might inhibit the synthesis of IAA, ZR and GA and cause fruit cavity formation in Nai plum.     

Genetic engineering of parthenocarpic fruit development in tomato

Parthenocarpy was engineered in two genotypes of Lycopersicon esculentum Mill. by using the DefH9-iaaM chimeric gene. The parthenocarpic trait consists of fruit set and growth in the absence of fertilization. Seedless parthenocarpic fruits were obtained from emasculated flowers, and fruits with seeds from pollinated flowers. All parthenocarpic tomato plants analysed expressed the DefH9-iaaM gene during flower development. The fruit set percentage of emasculated transgenic flowers was similar to that of control plants. In 7 out of 8 independent transgenic plants, the fresh weight of fruits derived from pollinated or emasculated flowers did not significantly differ from that of fruits obtained by pollination of the control plants. The pH of the parthenocarpic fruit was generally unaffected and the soluble solid concentration was either unchanged or increased. Thus, the DefH9-iaaM gene is a genetic tool that might be used to improve tomato productivity.