Use of Vital Dyes in Conjunction with the Semivitro Technic for the Detection of Pollen Tube Sperm Nuclei

The technique we describe here is a modification of that used by Hough et al. (1985), combined with “semivitro” pollen tube observations. With the semivitro technique, pollen tubes grow from the cut ends of pollinated styles (Brewbaker and Majumder 1961). Pollen of Nicotiana alata was presoaked for 15 min in simplified medium (Brewbaker and Kwack 1963) (10% sucrose, 300 ppm Ca(NO₃)₂, 100 ppm H₃BO₃ with the addition of 0.5 mg/ml of Hoechst 33258 stain from Serva Biochemicals, Heidelberg, Control H, purchased June 1983). (For germination of Nicotiana alata pollen in vitro, we use this same solution, except with 12% sucrose). After this prestaining, the pollen suspension was centrifuged for 5 min at 1200 × g, the pellet resuspended in control Brewbaker medium (i.e., no stain), recentrifuged and used to pollinate detached pistils. The pistils were then incubated at 25 C in a water-saturated atmosphere for 20 hr. At this time, the styles were cut just ahead of the front of the growing pollen tubes (Mulcahy and Mulcahy 1985) and the cut stylar ends each dipped in fresh control Brewbaker medium. Twelve to 24 hours later, tubes growing out of the cut styles were viewed by fluorescence microscopy (exciter filter, BG 12 + KV 418, beam splitter, 500 nm, and barrier filter OG 515). A distinct green fluorescence was seen in the generative and vegetative nuclei (Fig. 1).     

Division in Isolated Generative Cells of Allemanda neriilolia

An osmotic shock method of isolating generative cells from Allemanda neriifolia was described. Fresh pollen grains were first placed ill a Brewbaker and Kwack's medium (BK medium) containing 50% sucrose, incubated at 28℃ for 2 hours. During this incubation period pollen grains germinated and produced pollen tubes measuring about 200 μm long. After this initial incubation period, a fixed amount of BK medium without sucrose was added thus diluting the original medium to a sucrose concentration of 30% – an optimum concentration for generative cell growth. The addition, of the BK medium without sucrose brought about an osmotic shock effect on the pollen tubes and caused most of the tubes to burst at the tip region thus releasing the contents together with the generative cell from the tube into the 30% sucrose + BK medium. After isolation and filtering into a fresh lot of 30% sucrose + BK medium, generative cells changed from spindle into spherical-shaped cells. In the 30% sucrose + BK medium, the generative cells divided and within a short period of 3 to 5 hours a laege number of cells at various stages of mitosis was obtained.     

Combination of u.v.-B. and ozone reduces pollen tube growth more than either stress alone

The rate of in vitro Nicotiana tabacum L. “Bel-W3” pollen tube growth was reduced 62 and 44%, respectively, when pollen tubes were exposed to 120 ppb ozone (O₃) for 3 hr or 300 μW/cm² ultraviolet-B (u.v.-B) radiation for 30 min. Petunia hybrida Vilm. “White Cascade” pollen tube growth was reduced 34 and 59%, respectively, upon exposure to O₃ or u.v.-B at the above doses. The combination of u.v.-B at 300 μW/cm² for 30 min, followed by O₃ at 120 ppb for 3 hr, reduced pollen tube growth by 79% for “Bel-W3” and 75% for “White Cascade”. The effect appeared to be additive, implying that different target areas may be affected by the two stressors. In the Northeast, plants are exposed to both u.v.-B and O₃ during the normal growing season. This may result in an unexpectedly higher stress on the reproductive system than had been previously suspected based on these two stressors acting individually.     

Staining and Observing Pollen Tubes in the Style by Means of Fluorescence

Pollen tubes in the styles of the tomato and of other flowering plants can be observed by using the following technic. Styles are fixed in formalin-acetic-80% alcohol (1:1:8) and cleared and softened in a strong (8 N) sodium hydroxide solution. Staining is accomplished in a 0.1% solution of water-soluble aniline blue dye dissolved in 0.1 N, K₃PO₄. The styles are smeared or are observed whole under a conventional or dissecting microscope by direct illumination with ultraviolet light of a wavelength of about 356 m°. Observations are made in a darkened room. Under these conditions callose fluoresces bright yellow-green and contrasts strongly with the bluish or grayish fluorescence of the stylar tissue. The pollen tubes are outlined by a callose lining and irregularly spaced callose plugs.     

从水稻花粉管分离精细胞(简报)

精细胞的分离是植物生殖工程的一个重要组成部分,是目前被子植物有性生殖研究的一个活跃领域[1,2]。随着精细胞分离技术的完善和分离出精细胞的植物类型的增加,目前对精细胞的分子生物学研究已有一些进展,主要是精细胞特异蛋白的分离[3,4]和cDNA文库的构建以及一些精细胞特异基因的分离[5,6]。     

Handling Germinated Pollen on Millipore Membrane During the Feulgen and Autoradiographic Procedures

To prevent loss of pollen during the Feulgen's procedure, the pollen was grown on an autoclaved membrane filter (Millipore AA WP 025 00) in contact with a sterilized medium containing agar 0.5-1%, sucrose according to the genus (Malus 0.3-0.5 M; Persica and Tulipa 0.4 M), and H₃BO₃, 0.01%. To fix the germinated pollen of most species, the membrane was placed for 2 hr to overnight at 2-4 C on filter paper wet with the following mixture: OsO₄, 1 gm; CrO₃, 1.66 gm; and distilled water, 233 ml. To fix Persica pollen, 10% of glacial acetic acid had to be added to the fixative. Washing with distilled water and bleaching with a mixture of 3% H₂O₂ and sat. aq. ammonium oxalate, 1:1, were performed also on filter paper. Similarly, the preparation was processed for Feulgen staining by use of pieces of filter paper wet with the required fluids. Hydrolysis preceding the Schiff's reagent was performed at room temperature with 5 N HCl for 18 min. The differentiation after the Schiff's action was with 2% K₂S₂O₅ buffered to pH 2.3 with 9 ml of phosphate buffer (KH₂PO₄, 1.4 gm; conc. HCl, 0.35 ml and distilled water to make 100 ml). The stained pollen was floated off the membrane with a drop of glacial acetic acid to a gelatinized or an albumenized slide, and squashed. When the coverslip is removed the preparation may be either dehydrated and mounted or coated with autoradiographic film.     

烟草精细胞两个群体的分离

高等植物的倾向受精是一个非常吸引人的研究课题,目前对其机理还不清楚.要想探索高等植物倾向受精现象,前提之一是要分离出一定数量的两个精细胞群体作为分子生物学研究方法的材料.以前的研究表明,烟草(Nicotiana tabacum L.)花粉管中的两个精细胞体积差异明显.这种异型性的精细胞可能与倾向受精有关.烟草是二胞型花粉,生殖细胞只在体内生长的花粉管中才分裂形成两个精细胞.用体内/体外技术培养出花粉管后,爆破花粉管即可释放出花粉管内含物,其中包括两个精细胞.用微量酶液可使两个精细胞分开.然后用显微操作器可挑选出两个大小不同、数量上千的精细胞群体.这种单一纯化的精细胞群体为用分子生物学方法区分两个精细胞的DNA和蛋白质差异打下基础.本研究是高等植物的第二例、二胞花粉植物中的第一例分离两个特定精细胞群体的尝试,为构建烟草两个精细胞的cDNA文库创造了条件.     

Germination of trinucleated pollen: formulation of a new medium for Capsella bursa-pastoris

Summary In Brewbaker and Kwack's medium (BK) only 16% of the pollen grains germinated, and these produced pollen tubes having a maximum length of 25 m. With a solution based on Monnier's medium 47% germination and 160-mlong pollen tubes were observed. Calcium was shown to be essential for germination; the optimal concentration was 880 mg/l calcium chloride. The optimal concentrations of magnesium sulphate and boric acid were 360 and 50 mg/l, respectively. Germination at pH 4.0 but also pH 8.0 and the presence of vitamins B1 and B6 (1 mg/l each) were stimulatory. Polyethylene glycol (PEG) was superior to sucrose as an osmoticum and germination and tube length were significantly improved using PEG 4000 at a concentration of 120 g/l (0.03 M). Equimolar concentrations of PEG 400 and PEG 600 gave inferior results. Combining PEG with sucrose in the medium did not improve germination or increase tube length.     

Isolation of Pollen Protoplasts in Nicotiana tabacum

A new method for isolation of quantities of mature pollen protoplasts in Nicotiana tabacum has been established. The first step was to germinate mature pollen in Brewbaker and Kwack medium containing 20% sucrose. When most of the pollen grains had just germinated short pollen tubes, they were transferred to an enzymatic solution for the second step. The enzymatic solution contained 1% pectinase, 1% cellulase, 0.5% potassium dextran sulfate, 1 mol/L mannitol, 0.4 mol/L sorbitol in Dx medium with or without 15% Ficoll. The enzymes firstly degraded the pollen tube wall and then the intine. As a result, intact pollen protoplasts were released with the isolation rate up to 50%-70%. Factors affecting pollen protoplast isolation during the germination and maceration of pollen grains were studied. The suceees depended on two key points:pollen germination duration and osmotieum concentration. The optimal germination duration was 30 rain at 30℃. When it was too long, long pollen tubes formed and subsequently, large number of subprotoplasts instead of whole protoplasts were yielded, as the case reported by previous investigators. The optimal concentration of mannitol and sorbitol in enzyme solution was as high as 1.4 mol/L in total. Lowering of the osmoticum concentration resulted in decrease of percentage of pollen protoplasts.     

Evaluation of pollen tube growth ability in Petunia species having different style lengths

Pollen tube growth is essential for the fertilization process in angiosperms. When pollen grains arrive on the stigma, they germinate, and the pollen tubes elongate through the styles of the pistils to deliver sperm cells into the ovules to produce the seeds. The relationship between the growth rate and style length remains unclear. In previous studies, we developed a liquid pollen germination medium for observing pollen tube growth. In this study, using this medium, we examined the pollen tube growth ability in Petunia axillaris subsp. axillaris, P. axillaris subsp. parodii, P. integrifolia, and P. occidentalis, which have different style lengths. Petunia occidentalis had the longest pollen tubes after 6 h of culture but had a relatively shorter style. Conversely, the pollination experiments revealed that P. axillaris subsp. parodii, which had the longest style, produced the longest pollen tubes in vivo. The results revealed no clear relationship between the style lengths and the growth rate of pollen tubes in vitro. Interspecific pollinations indicated that the styles affected pollen tube growth. We concluded that, in vitro, the pollen tubes grow without being affected by the styles, whereas, in vivo, the styles significantly affected pollen tube growth. Furthermore, interspecific pollination experiments implied that the pollen tube growth tended to be suppressed in the styles of self-incompatibility species. Finally, we discussed the pollen tube growth ability in relation to style lengths.     

The Nutritional Role of Pistil Exudate in Pollen Tube Wall Formation in Lilium longiflorum: I. Utilization of Injected Stigmatic Exudate

A quantity of labeled stigmatic exudate, collected from detached Lilium longiflorum (cv. Ace) pistils labeled with d-glucose-1-¹⁴C, was fractionated on Sephadex G-100 and the polysaccharide component, G-100-I, was injected into the hollow styles of unlabeled detached pistils (cv. Ace) which had been removed on the day after anthesis from the plant. Injected pistils were immediately cross-pollinated with L. longiflorum (cv. No. 44) pollen. Eighty-four hours later, pistils were dissected to recover the pollen tubes, expended exudate, and labeled tissues of the stigma and style. Distribution of label revealed that at least 25% of the carbohydrate substance in excised pollen tubes was derived from G-100-I. The composition of expended exudate adhering to pollen tubes, of pollen tube cytoplasm, and of pollen tube walls suggests that utilization of exudate by growing pollen tubes involves uptake and incorporation into pollen tube cytoplasm of exudate polysaccharide fragments followed by extensive metabolism of at least a portion of the incorporated carbohydrate prior to its utilization for pollen tube wall biosynthesis. Results suggest the presence of at least two polysaccharide components in G-100-I, one which resists major degradation following injection into the style and another which undergoes measurable degradation both before and after entry into the pollen tube.     

Staining Germinating Pollen and Pollen Tubes

Germinating pollen on stigmas and pollen tubes in styles of Antirrhinum, Brassica, Oenothera, Raphanus, Rosa, solatium and Tagetes spp. were prepared for examination as follows: The styles were fixed in ethyl alcohol-acetic acid 3:1 for 1 hr, and hydrolyzed at 60°C for 5 to 60 min (depending on the species) in 45% acetic acid. The stigma with its attached strand(s) of stigmatoid tissue was then dissected out under a stereoscopic microscope, placed in a few drops of a staining solution made by dissolving 150 mg of safranin O and 20 mg of aniline blue in 25 ml of hot 45% acetic acid. After 5-15 min in this stain, the tissue was placed in a fresh drop of stain on a microscope slide and gently squashed under a cover glass. Because of a gradual precipitation of the aniline blue component, the stain had to be filtered regularly before use. However, a staining solution could be kept at room temperature for several weeks.     

Influence du pH sur la synthèse de l''oxidase (cytochrome a3) chez Bacillus coagulans, microorganisme thermophile, capable d'' “adaptation respiratoire”

In a new series of experiments on Bacillus coagulans (ATCC 11.369), it was demonstrated that this organism possesses a respiratory system with cytochromes b, c₁, c, (a+a₃) and also cytochrome o. A small decrease in the pH of the growth medium from 6.5 to 5.5 increases the respiratory activity by a factor of 4 and induces a variation of the absorption ratio [₆₀₃ (a+a₃)]/[₅₆₀ (b+c)] resulting in a preponderant increase in the ₆₀₃ absorption. The kinetic studies of the respiratory system synthesis during the phenomenon of “respiratory adaptation” have shown that lowering the pH of the adaption medium has the same effect. Spectral studies of membrane fractions (red dithionite) with or without carbon monoxide showed a preferential synthesis of oxidase a₃.     

Fine-Structure Locations of α-Glucan Phosphorylase, As Shown by Lead Precipitation and Electron Microscopy

Sites of glucan phosphorylase activity in fine structures, as shown by the lead precipitation method (Hori, Stain Techn., 39: 275, 1964) were studied by electron microscopy. Rat livers were fixed 2 hr at 0 C in buffered 2.5% glutaraldehyde, frozen-sections cut and incubated in the medium containing glucose-1-phosphate, 2.7 mM; NaF, 20 mM; acetate buffer, pH 5.8, 80 mM; Pb(NO₃)₂, 4.2 mM; and sucrose, 0.44 M; refixed in buffered 1% OsO₄, dehydrated and embedded in Epon 812 as usual. The reaction product was found in close association with endoplasmic reticulum, but not in mitochondria, nuclear membrane and the cisternae of endoplasmic reticulum. The possibility of demonstrating by the present method the indirect hydrolysis of glucose-1-phosphate through the phosphoglucomutase-glucose-6-phosphatase system was ruled out by inhibiting glucose-6-phosphatase with fluoride and ethanol.     

Characterization of the pollen growth transition in self-incompatible <Emphasis Type="Italic">Petunia inflata</Emphasis>

In Petunia inflata, as in other species that shed bicellular pollen, early pollen tube growth in the pistil is slow, then increases 2- to 5-fold depending on the genotype of the female parent. We refer to the time point at which pollen tubes enter the accelerated phase of growth as the pollen growth transition (PGT). Here, we present evidence that pre-PGT and post-PGT growth are quantitatively and qualitatively different, and that the PGT is triggered when pollen tubes reach the transition zone (TZ) below the stigma. The capacity of various pistil zones to precipitate the PGT was tested through 'stump' pollinations: varying lengths of the pistil apex were excised, the cut surface of the remaining pistil (the stump) coated with stigmatic exudates then dusted with compatible pollen. Pollen applied to TZ tissues entered the PGT earlier than pollen growing in intact control pistils; the PGT was delayed in stylar stumps, largely because of delayed germination and reduced pre-PGT growth. In immature pistils, the PGT was delayed by several hours relative to its onset in mature pistils. The PGT fails to occur in pollen cultured in vitro. Collectively, the data suggest that pollen tubes become competent to enter the PGT when they reach a critical size, but the physicochemical environment of the transmitting tissue is necessary for triggering the cellular changes that result in accelerated growth. An analysis of the distribution of pollen tube tips before and after the PGT suggests that pollen competition is most intense during the pre-PGT phase.     

Influence of elevated CO2 and ozone concentrations on late blight resistance and growth of potato plants

Potato plants (Solanum tuberosum L. cv. Indira) with high susceptibility to the late blight pathogen Phytophthora infestans were exposed for 4 weeks to two different CO₂ concentrations (400/700 ppm) combined with ambient and double ambient ozone concentrations (first experiment) and with 1/5 ambient and ambient ozone concentrations (second experiment) in climate chambers. Leaves of the potato plants were then inoculated with Phytophthora infestans zoospores. Plants from the “high CO₂” variant showed a significantly increased resistance to the pathogen, verified by visual evaluation and quantitative real-time PCR, whereas plants treated with double ambient ozone were slightly more susceptible. An increase in the constitutive activities of the PR-proteins β-1,3-glucanase and osmotin in leaves of plants exposed to 700 ppm CO₂ correlated with the increase in resistance at this CO₂-concentration. Biomass parameters were barely affected by the elevated CO₂-concentration but decreased with increasing ozone concentrations. Biochemical analyses revealed that the content of starch as well as the content of soluble sugars in leaves were highest at the double ambient ozone/700 ppm CO₂ variants pointing to an ozone-induced inhibition of assimilate allocation from leaves to tubers. Leaf C/N-ratio increased at elevated CO₂-concentrations due to a decrease in N-content. The effect of the ozone- and CO₂-induced biochemical changes on the resistance response of potato towards Phytophthora infestans is discussed.     

THE ESSENTIAL ROLE OF CALCIUM ION IN POLLEN GERMINATION AND POLLEN TUBE GROWTH

Brewbaker, James L., and Beyoung H. Kwack. (U. Hawaii, Honolulu.) The essential role of calcium ion in pollen germination and pollen tube growth. Amer. Jour. Bot. 50(9): 859–865. Illus. 1963.—A pollen population effect occurs whenever pollen grains are grown in vitro. Small pollen populations germinate and grow poorly if at all, under conditions which support excellent growth of large pollen populations. The pollen population effect is overcome completely by a growth factor obtained in water extracts of many plant tissues. This factor is shown to be the calcium ion, and its action confirmed in 86 species representing 39 plant families. Other ions (K⁺, Mg⁺⁺, Na⁺) serve in supporting roles to the uptake or binding of calcium. The high requirement of calcium (300–5000 ppm, as Ca (NO₃)₂·4H₂O, for optimum growth) and low calcium content of most pollen may conspire to give calcium a governing role in the growth of pollen tubes both in vitro and in situ. It is suspected that ramifications of this role extend to the self-incompatibilities of plants and to the curious types of arrested tube growth distinguishing, for example, the orchids. A culture medium which proved its merit in a wide variety of pollen growth studies included, in distilled water, 10% sucrose, 100 ppm H₃BO₃, 300 ppm Ca (NO₃)₂·4H₂O, 200 ppm MgSO₄·7H₂O and 100 ppm KNO₃.     

Semi in vivo pollen tube growth of Aechmea fasciata

With semi in vivo pollen tube growth assays, stigmas are pollinated in vivo and, after a fixed time interval, the styles are isolated from the ovary and placed on culture medium in vitro. Semi in vitro pollination includes isolation of the stigma and style complex, followed by pollination and placing the stylar end on nutrient medium. After semi in vivo pollination more and longer pollen tubes protruded from the cut end of the styles into medium, in comparison to semi in vitro pollination. Medium with 3 g l^–1 agar was better than that with 6 g l^–1 agar for pollen tube growth after the tubes emerged from the cut style. Semi in vitro pollination of the reversed style indicated that pollen tube growth was not influenced by the direction of the style. Fructose and glucose inhibited pollen tube growth compared to sucrose. Swollen tips characterized tube growth inhibition. After semi in vivo pollination all generative nuclei had divided to give two sperm nuclei. The average distance between the last sperm nucleus and the pollen tube tip as well as the distance between the two sperm nuclei diminished in growing pollen tubes between 24 and 48 h after pollination. The arrangements between the vegetative and the generative nuclei did not differ in semi in vivo and in vitro cultured pollen tubes of Aechmea fasciata. This information is important to explain why fertilization rate is low after placental pollination in comparison to placental grafted style pollination of Aechmea fasciata. The data may also contribute to the improvement of in vitro fertilization methods in Bromeliaceae and other higher plants.     

Fluorescence Microscopic Observations on Actin Filament Distribution in Corn Pollen and Gladiolus Pollen Protoplasts

Actin filament (AF) distribution in Zea mays pollen and Gladiolus gandavensis pollen protoplasts was localized by FITC conjugated phalloidin fluorescence microprobe. The pollen was incubated in Brewbaker and Kwack (BK) medium, and the pollen protoplasts were isolated enzymatically and cultured in K3 medium containing various supplements by a previously reported method. Samples were fixed for 30 min with 1.5% paraformaldehyde dissolved in 0.1 mol/1 phosphate buffer (pH 7), half strength of BK elements, 1 mol/1 EGTA and sucrose, stained for 30–60 min with 1 μg/ml FITC-phalloidin in the buffer solution, and observed by a fluorescence microscopy. In hydrated corn pollen grains, the AFs constituted an irregular network. Prior to germination a part of the pollen grains showed polarized pattern of Afs. At the opposite pole to the germ pore, there was a center from which AF bundles radiated and converged toward the pore, often making a spindle-shaped configuration. In just isolated gladiolus pollen protoplasts, the AFs appeared as irregular fine network. After 4–7h of culture, the AF distribution coincided in some cases with the unevenly regenerated new wall area as exhibited by FITC-phalloidin and Calcofluor White ST double staining, indicating a possible involvement of AF in wall synthesis. After 17–18 h of culture, a part of the pollen protoplasts went on germination. The AFs became polarized in such protoplasts and converged into the tubes produced, and ran longitudinally along the tubes just like in the tubes germinated from pollen grains. However, in ungerminated pollen protoplasts, the AFs behaved abnormalty, showing various irregular arrangements. When protoplasts bursted, the actin aggregates often located at the protrusion site from which the protoplasts would burst, and were discharged into the medium. In neither corn pollen nor gladiolus pollen protoplasts AFs were observed within the generative or sperm cells.