Influence of intraovular reserves on ovule fate in apricot (Prunus armeniaca L.)

 In many plant species with multiovulate ovaries, a considerable reduction in the number of ovules takes place. However, the underlying physiological causes are not clear. In Prunus spp., although flowers present two ovules, usually only one seed is produced. We have followed the development and degeneration of the two ovules in apricot (Prunus armeniaca L.) and examined the extent to which carbohydrates within the ovule might be involved in determining the fate of the ovule. While the primary ovule grows in the days following anthesis, growth of the secondary ovule is arrested. Starch distribution along the different ovular tissues exhibits several changes that are different in the two ovules. Primary ovule growth is inversely related to starch content and this growth takes place independently of pollination since it occurs in the same way in pollinated and unpollinated flowers. In the secondary ovule, starch disappears simultaneously from all ovular structures and callose is layered at the chalazal end of the nucellus. The size of the secondary ovule does not change significantly from anthesis to degeneration, and callose starts to accumulate 5 days after anthesis. Likewise, this process occurs independently of pollination. These results are discussed in terms of the implications of the starch content of ovules in fertilization success and ovule fate. Received: 26 August 1997 / Revision accepted: 17 December 1997     

The signals to trigger the initiation of ovule enlargement are from the pollen tubes: The direct evidence

In angiosperms, initiation of ovule enlargement represents the start of seed development, the molecular mechanism of which is not yet elucidated.It was previously reported that pollen tube contents,rather than double fertilization, can trigger ovule enlargement. However, it remains unclear whether the signal(s) to trigger the initiation of ovule enlargement are from the sperm cells or from the pollen tubes.Recently, we identified a mutant drop1- drop2-, which produces pollen tubes with no sperm cells. Taking advantage of this special genetic material, we conducted pollination assays, and found that the ovules pollinated with drop1- drop2- pollen could initiate the enlargement and exhibited significant enlarged sizes at 36 h after pollination in comparison with those unpollinated ovules. However, the sizes of the ovules pollinated with drop1- drop2- pollen are significantly smaller than those of the ovules pollinated with wildtype pollen. These results demonstrate that the pollen tube, rather than the sperm cells, release the signal to trigger the initiation of ovule enlargement, and that double fertilization is required for further enlargement of the seeds.     

Pollen tube reallocation in two preanthesis cleistogamous species, Ranalisma rostratum and Sagittaria guyanensis ssp. lappula (Alismataceae)

Pollen deposition on stigmas and pollen tube growth in two apocarpous species, Ranalisma rostratum and Sagittaria guyanensis ssp. lappula (Alismataceae), were examined with fluorescence microscopy. The reallocation of pollen tubes among pistils was observed in both species. The percentage of pollinated stigmas per flower was only 22.0% in R. rostratum and 51.0% in S. guyanensis, though the seed/ovule ratios are higher than 65% in both species. The number of pollen grains on each single stigma ranged from 0 to 96 in R. rostratum, and from 0 to 125 in S. guyanensis. When more than one pollen grain deposited on a stigma, all pollen tubes grew to the ovary, but only one of them turned towards the ovule and finally entered the nucleus. The other tubes grew through the receptacle tissue into ovules of adjacent carpels whose stigmas were unpollinated or pollinated later. The intercarpellary growth of pollen tubes could be a mechanism to increase the efficiency of sexual reproduction in an apocarpous gynoecium with low pollination on the pistils.     

Effect of pollination or treatment with growth regulators on levels of extractable hormones in tomato ovaries and young fruits

Levels of extractable free indolyl-3-acetic acid (IAA), gibberellin-like substances (GA's), and abscisic acid (ABA) were analysed in tomato ovaries ( Lycopersicon esculentum Mill.) before pollination as well as in fruits 5 and 10 days after pollination or treatment with growth regulators to induce parthenocarpic fruit development. Growth regulators applied were a naphthoquinone (bendroquinone), an auxin (4-CPA), a morphactin (CME), and a benzothiadiazole (DU).
The initial high levels of ABA (2.7 μg/g dry weight) in unpollinated ovaries decreased to one third or less after 5 and 10 days. In contrast levels of IAA increased from 80 up to 180 ng/g dry weight. Activity of GA's could be detected only in young fruits but not in unpollinated ovaries.
The possible relevance of these findings for tomato fruit-set is discussed.     

Self‐pollination and parthenocarpic ability in developing ovaries of self‐incompatible Clementine mandarins (Citrus clementina)

This study aimed to determine if self‐pollination is needed to trigger facultative parthenocarpy in self‐incompatible Clementine mandarins (Citrus clementina Hort. ex Tan.). ‘Marisol’ and ‘Clemenules’ mandarins were selected, and self‐pollinated and un‐pollinated flowers from both cultivars were used for comparison. These mandarins are always seedless after self‐pollination and show high and low ability to develop substantial parthenocarpic fruits, respectively. The time‐course for pollen grain germination, tube growth and ovule abortion was analyzed as well as that for carbohydrates, active gibberellins (GA₁ and GA₄), auxin (IAA) and abscisic acid (ABA) content in the ovary. ‘Clemenules’ showed higher pollen grain germination, but pollen tube development was arrested in the upper style 9 days after pollination in both cultivars. Self‐pollination did not stimulate parthenocarpy, whereas both un‐pollinated and self‐pollinated ovaries set fruit regardless of the cultivar. On the other hand, ‘Marisol’ un‐pollinated flowers showed greater parthenocarpic ovary growth than ‘Clemenules’ un‐pollinated flowers, i.e. higher ovule abortion rate (+21%), higher fruit set (+44%) and higher fruit weight (+50%). Further, the greater parthenocarpic ability of ‘Marisol’ paralleled higher levels of GA₁ in the ovary (+34% at anthesis). ‘Marisol’ ovary also showed higher hexoses and starch mobilization, but lower ABA levels (?64% at anthesis). Self‐pollination did not modify carbohydrates or GA content in the ovary compared to un‐pollination. Results indicate that parthenocarpy in the Clementine mandarin is pollination‐independent with its ability to set depending on the ovary hormone levels. These findings suggest that parthenocarpy in fertile self‐incompatible mandarins is constitutively regulated.     

Prolongation of Embryo Sac Viability in Pear (Pyrus communis) Following Pollination or Treatment with Gibberellic Acid

Embryo sac development has been investigated in unpollinated,cross pollinated and gibberellic acid (GA₂) treated flowersof Pyrus communis L. While pollination and GA₃ treatments donot alter embryo sac development, they prolong embryo sac viability.In untreated unpollinated flowers, ovules degenerate between12 and 21 d after anthesis, while in cross pollinated and GA₃treated flowers this degeneration is postponed by about 10 d.Thus, in a cross pollinated flower this extends the period overwhich a successful fertilization can take place. This increasedperiod of viability is accompanied by an elongation of the embryosac itself. Elongation takes place two weeks prior to fertilizationin cross pollinated flowers. The extension of life span of embryo sacs following pollinationand treatment with gibberellic acid indicates that a stimulusinduced by ‘pollination’ could be mediated by GA₃Whatever its mechanism of operation, the prolongation of embryosac viability by pollination represents a selective advantage,in that the period at which the ovules are receptive to fertilizationmust be significantly extended. Embryo sac, gibberellic acid, Pyrus communis, pear, pollination     

Digital image analysis of expansion growth of cultured cotton ovules with fibers and their responses to ABA

Cotton ovule cultures have obvious advantages over whole plants when experimental protocols call for inhibitors, radio-labeled precursors or controlled environmental conditions to be tested. The responses of ovule expansion growth and attached fiber elongation to external factors require accurate measurement techniques. This paper presents a new method for digital image analysis of the growth area of cotton ovules with fibers at high resolution. The method was characterized under constant conditions and during dynamic responses to different levels of ABA (abscisic acid) treatment. The growth area was treated as area occupied within the outline of the Petri dish image of the growing ovule with fibers. Growth area increase showed the same trends as fiber length increase and was significantly correlated with the fiber length increase under different levels of ABA treatment (r ² = 0.97). This new analysis method provides a simple, noninvasive, and more accurate approach for growth analysis in the cotton ovule culture system. Using this method, the effects of ABA on expansion growth of ovule with fibers were characterized.     

Parasitism of seed of Douglas fir (<Emphasis Type="Italic">Pseudotsuga menziesii</Emphasis>) by the seed chalcid, <Emphasis Type="Italic">Megastigmus spermotrophus</Emphasis>, and its influence on seed hormone physiology

Parasitism of Douglas fir (Pseudotsuga menziesii) megagametophytes by the seed chalcid, Megastigmus spermotrophus Wachtl, occurs naturally after pollination but before fertilization. In the absence of fertilization, the presence of insect larvae within the megagametophyte prevents abortion and the storage tissue continues to develop as if the seed had been fertilized. We investigated the effect of parasitism on the metabolism of abscisic acid (ABA), auxins, cytokinins, and gibberellins during early development of Douglas fir seeds. Hormones and hormone metabolites of infested and uninfested megagametophytes with or without pollination were analyzed by HPLC–ESI/MS/MS. At 1 week after Megastigmus introduction, the insect’s presence stimulated ABA accumulation in unpollinated megagametophytes compared to unpollinated, unparasitized megagametophytes. In pollinated material, parasitism did not stimulate ABA accumulation compared to levels present in unparasitized megagametophytes. In all four treatments, the metabolism of ABA occurred primarily through conjugation to the ABA glucose ester (ABAGE), while the 7′-, 8′- and, 9′-hydroxylation pathways were only minor. ABAGE levels declined with time in all treatments and this occurred to a greater extent in pollinated, parasitized megagametophytes, suggesting that the insect’s presence induced the dramatic decrease in ABAGE. Although there were temporal variations in the auxin, cytokinin, and gibberellin profiles of parasitized megagametophytes, the profiles were generally similar to those of unparasitized megagametophytes. Our results suggest that failure of parasitized megagametophytes to abort may be due to the insect inducing similar hormone profiles to those present during normal development of Douglas fir seed.     

Fluctuation in levels of endogenous plant hormones in ovules of normal and mutant cotton during flowering and their relation to fiber development

The contents of indole-3-acetic acid (IAA), gibberellins (GAs), abscisic acid (ABA), and cytokinins were determined in ovules of normal cotton (Tm-1) and a kind of fiber differentiation mutant (Xin) before and after flowering by enzyme-linked immunosorbent assays. It was found that 24 h before flowering, a peak of IAA content was observed in ovules of Tm-1, whereas in ovules of Xin, a low level of IAA was determined. From –1 day (1 day before flowering) to +3 days (3 days after flowering), GA₁₊₃ levels in ovules of Xin were 40–70% lower than those of Tm-1; GA₄₊₇ levels were very low, and there was no visible difference in GA₄₊₇ content between normal and mutant cotton. The ABA content in ovule of Tm-1 decreased by 70% 3 days after flowering, whereas that of Xin only decreased by 20%. The levels of cytokinins in ovules of Tm-1 decreased after flowering, and those of Xin kept up a steady increase.Abbreviations IAA indole-3-acetic acid - GA gibberellin - ABA abscisic acid - ELISA enzyme-linked immunosorbent assay - FW fresh weight - PBS phosphate-buffered saline - iPA isopentenyladenosine - ZR zeatin riboside - DHZR dihydrozeatin riboside - CTK cytokinin     

Hormonal Control of Parthenocarpic Ovary Growth by the Apical Shoot in Pea

The role of the apical shoot as a source of inhibitors preventing fruit growth in the absence of a stimulus (e.g. pollination or application of gibberellic acid) has been investigated in pea (Pisum sativum L.). Plant decapitation stimulated parthenocarpic growth, even in derooted plants, and this effect was counteracted by the application of indole acetic acid (IAA) or abscisic acid (ABA) in agar blocks to the severed stump. The treatment of unpollinated ovaries with gibberellic acid blocked the effect of IAA or ABA applied to the stump. [³H]IAA and [³H]ABA applied to the stump were transported basipetally, and [³H]ABA but not [³H]IAA was also detected in unpollinated ovaries. The concentration of ABA in unpollinated ovaries increased significantly in the absence of a promotive stimulus. The application of IAA to the stump enhanced by 2- to 5-fold the concentration of ABA in the inhibited ovary, whereas the inhibition of IAA transport from the apical shoot by triiodobenzoic acid decreased the ovary content of ABA (to approximately one-half). Triiodobenzoic acid alone, however, was unable to stimulate ovary growth. Thus, in addition to removing IAA transport from the apical shoot, the accumulation of a promotive factor is also necessary to induce parthenocarpic growth in decapitated plants.     

Hormonal status of the pollen-pistil system at the progamic phase of fertilization after compatible and incompatible pollination in Petunia hybrida L.

The hormonal status of the pollen-pistil system in Petunia hybrida L. during the progamic phase of fertilization was investigated. The contents of indolyl-3-acetic acid (IAA), abscisic acid (ABA), and cytokinins, as well as the rate of ethylene production in the pistils and their parts (stigma, style, and ovary) were measured over an 8-h period following compatible and self-incompatible pollination. In both pollinations, the phytohormones were present in various proportions in the stigma, style and ovary: the stigma was the main site of ethylene synthesis and contained 90% of the ABA, while the style contained 80% of the total cytokinin content in the pollinated pistil. Relatively low levels of hormones in the ovary did not influence the hormonal status of the pollen-pistil system. The interaction of the male gametophyte with the stigmatic tissues was accompanied by a 7- to 10-fold increase in ethylene production and a 1.5- to 2.0-fold increase in IAA content in the pollen-pistil system over 0–4 h. Pollen tube growth after self-incompatible pollination, in contrast to compatible pollination, was accompanied by a 3-fold increase in the ABA content in the stigma and style and by a 5-fold higher cytokinin content in the stylar tissues. Thus, the ethylene/ABA status of the stigma may play a role in controlling the processes of adhesion, hydration, and germination of pollen grains during pollination while the auxin/cytokinin status of the style may be involved in controlling pollen tube growth.     

CHEMOTROPIC ACTIVITY AND THE PATHWAY OF THE POLLEN TUBE IN LILY,

A study of the pollen tube pathway in Lilium leucanthum var. centifolium and in L. regale reveals that the entire pathway from stigma to ovule is lined with cytologically unique stigmatoid cells. Assays for chemotropic activity of tissues and exudates along the pathway of pollinated or unpollinated pistils showed that onset of chemotropic activity progressed basipetally (and, when pollinated, in advance of the pollen tubes), commencing at the stigma 3-5 days before anthesis and appearing in the ovules 1-2 days after anthesis. Activity persists about 10 days in ovules of pollinated pistils and for 14-16 days in ovules of non-pollinated pistils. Attempts to localize the source of the chemotropic factor showed that gynoecial tissues bearing stigmatoid cells are chemo-tropically active while slices of style or ovary wall lacking stigmatoid cells are inactive. When ovules were sliced transversely and the micropylar and chalazal halves assayed, only the micropylar half showed activity. We suggest that the ovules and the stigmatoid tissue along the pollen tube pathway are the sources of the chemotropic factor responsible for the directional growth of the pollen tube.     

Pollen tubes enter neighbouring ovules by way of receptacle tissue,resulting in increased fruit-set in Sagittaria potamogetifolia Merr

Using fluorescence microscopy, deposition of pollen on stigmas and pollen tube growth in the gynoecium of Sagittaria potamogetifolia Merr., a monoecious species with an apocarpous gynoecium, were observed. The maximum rate of pollination averaged 83.9 +/- 4.7 %, and the number of pollen grains per stigma ranged from zero to 30. Pollen tubes grew through one stigma to the base of the ovary at almost the same speed, but generally only one of the pollen tubes then turned towards the ovule and finally entered the nucellus through the micropyle. The other pollen tubes grew through the ovary base and the receptacle tissue into ovules of adjacent carpels whose stigmas were not pollinated or which had been pollinated later. This phenomenon is termed pollen tube 'reallocation' by the authors. To verify the direct effect of the phenomenon on fruit set, artificial pollination experiments were conducted in which two or more pollen grains were placed onto only one stigma in each gynoecium; frequently more than one fruitlet was obtained from each flower treated. The reallocation of pollen tubes among pistils in the gynoecium could effect fertilization of ovules of unpollinated pistils and lead to an increase in sexual reproduction efficiency. It would, to some extent, also increase pollen tube competition among pistils of the whole gynoecium.     

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.     

Effects of abscisic acid on in vitro growth of cotton fiber

Summary Abscisic acid (ABA) inhibits in vitro growth of cotton (Gossypium hirsutum L.) fiber and is effective only when applied during the first four days of culture started on the day of anthesis. Abscisic acid causes a small increase in potassium uptake by the ovules and also enhances leakage of potassium from them. During their period of rapid growth, fibers produced by ABA-treated ovules have a higher potassium content and a lower malate content as compared to fibers on untreated control ovules. Results are discussed in the light of earlier reports on the in vitro growth of cotton fiber and effects of abscisic acid on other plant tissues. It is suggested that ABA inhibits fiber growth, in part, by interfering with malate metabolism.Abbreviations ABA abscisic acid - GA₃ gibberellic acid - IAA indole-3-acetic acid - TFU total fiber units     

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.     

Effect of phytohormones on fiber initiation of cotton ovule

In order to study the effect of phytohormones on cotton fiber initiation, contents of four endogenous phytohormones and activities of four related enzymes in ovules (in vivo) of a fuzzless–lintless mutant (fl) and its wild-type (FL) line were measured from 4 days before anthesis (day −4) to 4 days after anthesis (day 4). The results showed that contents of indole-3-acetic acid, gibberellic acid (GA), and zeatin riboside in fl ovules were lower than those in FL ovules. Therefore, indole-3-acetic acid, GA, and zeatin riboside were thought to be the promoters of fiber initiation. Although abscisic acid (ABA) content in fl ovule was slightly higher than that in FL ovule on day 0, which might imply that ABA inhibited fiber initiation. Fiber initiation could also be influenced by enzyme through regulating synthesis and degradation of related phytohormones since fl ovules were significantly higher in activities of indole-3-acetic acid oxidase, cytokinin oxidase and peroxidase, but lower in activity of tryptophan synthetase than those in FL ovules. To test the above hypothesis, exogenous plant growth regulators were also applied for the culture of ovules from fl and FL in vitro. When no regulators were added, no fiber was induced on fl ovule, but a few fibers were induced in FL ovule. Higher total fiber units (TFU) were observed when indole-3-acetic acid and gibberellic acid (GA₃) were applied either separately or in combination to media. TFU did not increased with zeatin riboside alone, but the highest TFU was achieved when zeatin riboside was applied together with indole-3 acetic acid and GA₃, which implied that fiber initiation could be promoted by them as additive.     

Levels of Cytokinins in the Ovules of Cotton Mutants with Altered Fiber Development

Endogenous levels of cytokinin and abscisic acid (ABA) were determined in ovules of normal cotton (TM-1) and four fiber differentiation mutants (n2, Ligon lintless, H10, and Xu142) before and after flowering by enzyme-linked immunosorbent assays. The fluctuation patterns of ABA levels in ovules of normal cotton and mutants were similar. At the fiber elongation stage, ABA content was low, and from 1 day after flowering, the ABA content decreased steadily. On the other hand, the peaks of isopentenyladenine and isopentenyladenosine in ovules of TM-1 were observed 1 day before flowering. The level of cytokinins decreased after flowering in TM-1, whereas in the mutants it increased steadily. These results indicate that endogenous ABA is probably not the main inhibitor for fiber elongation and that endogenous cytokinins likely play a dual role in fiber development. Before flowering, cytokinins function as one of the stimuli for the initiation of fibers, but after flowering, cytokinins inhibit fiber growth. Received February 18, 1997; accepted June 11, 1997