Anatomical aspects of hormonal regulation of abscission in citrus – The shoot-peduncle abscission zone in the non-abscising stage

Although mature citrus fruits [ Citrus sinensis (L.) Osbeck cv. Shamouti] did not abscise at the peduncle-shoot abscission zone (AZ–A) when incubated in ethylene environment, abscission processes did occur in a limited number of cell layers situated in the inner bark, the starch sheath region, and in the pith of AZ–A. These processes were regulated by 2,4-D and ethylene treatments. Cells responding to the "separation processes", particularly in the ethylene treatment, underwent either (a) cell wall swelling, dissolving and breakdown, or (b) growth and expansion in a radial plane. Further away from the dissolving area, the response of some cells of the mid and outer bark took the form of divisions or growth in a circumferential plane, while other cells remained unchanged. Non-responding tissues of the outer bark formed a "sleeve" of undissolved cells, and the vascular cylinder produced no abscission in AZ–A. It is concluded that the partial cell wall dissolution in AZ–A explains the increased activity of cellulase and polygalacturonase in the non-abscising AZ–A of the mature fruit (Greenberg et al. 1975. Physiol. Plant. 37: 1–7).     

Direct current electrical field effects on intact plant organs

Intact plant tissues (of hypocotyls, radicles, cotyledons and leaves) were contracted by applying a low DC electrical field through them. Stomatal opening as a result of the electrical treatment of leaves was observed, presumably due to the differential influence of the electrical treatment on guard cell turgor pressure versus turgor pressure of the surrounding epidermal cells. In addition, leakage of minerals from the treated leaves was detected (higher contents of potassium, sodium, calcium and sulfur), as was leakage of betanin from electrically treated red beet roots (higher OD value of the immersion solution with increasing time of applied electrical field). Application of such a treatment can be used for initial drying or as part of another more drastic drying method. The advantages of this method lie in its nonthermal character and its potential to increase the quality of processed foods by maintaining their "like-fresh" quality, e.g., fruits and vegetables that are less damaged by browning. An understanding of the mechanism involved in this nonthermal application can help in controlling the process and predicting its outcome.     

Lead accumulation in the aquatic fern Azolla filiculoides.

In this study, we characterized lead (Pb2+) accumulation and storage by the aquatic fern Azolla filiculoides. Lead precipitates were detected in the vacuoles of mesophyll cells of Azolla plants cultured for 6 d in rich growth medium containing 20 mg l(-1) Pb2+. Energy dispersive spectroscopy (EDS) analysis of the relative element content of leaves collected from these plants revealed a 100% increase in the levels of P, S, Na and Ca and a 40% decrease in Mg and Cl compared to the untreated plants. Both Azolla whole plants and isolated apoplasts were incubated for 6 d in 20 mg l(-1) Pb2+. Lead content in the whole plant composed 0.37%, 2.3% and 1.8% of the dry weight after 2, 4 and 6 d of growth, respectively, while the isolated Azolla apoplast contained 0.125%, 1.22% and 1.4% Pb2+, respectively. Lead content in Azolla whole plant increase by 200%, 100% and 22% after 2, 4 and 6 d of growth, respectively, when compared to Azolla apoplast. Dark, electron dense deposits of lead were observed in light and transmission electron microscope in leaf cells treated with lead. All the observed lead deposits were localized in vacuoles while larger lead deposits were found in mature leaves than in young leaves. No lead deposits were found in cells of the cyanobiont Anabaena when the plants were exposed to similar conditions. Activity and content of V-H+-ATPase were studied in Azolla plants grown in the presence of 20, 40 and 80 mg l(-1) of lead for a period of 4 d. Activity of V-H+-ATPase was increased by 190%, 210% and 220%, respectively, but the content of V-H+-ATPase was reduced by all lead concentrations.     

L-Myo-inositol 1-phosphate synthase in the aquatic fern Azolla filiculoides.

L-Myo-inositol 1-phosphate synthase (INPS EC 5.5.1.4) catalyzes the conversion of D-glucose 6-phosphate to L-myo-inositol 1-phosphate. INPS is a key enzyme involved in the biosynthesis of phytate which is a common form of stored phosphates in higher plants. The present study monitored the increase of INPS expression in Azolla filiculoides resulting from exposure to inorganic phosphates, metals and salt stress. The expression of INPS was significantly higher in Azolla plants that were grown in rich mineral growth medium than those maintained on nutritional growth medium. The expression of INPS protein and corresponding mRNA increased in plants cultured in minimal nutritional growth medium when phosphate or Zn2+, Cd2+ and NaCl were added to the growth medium. When employing rich mineral growth medium, INPS protein content increased with the addition of Zn2+, but decreased in the presence of Cd2+ and NaCl. These results indicated that accumulation of phytate in Azolla is a result of the intensified expression of INPS protein and mRNA, and its regulation may be primarily derived by the uptake of inorganic phosphate, and Zn2+, Cd2+ or NaCl.     

Growth of rose flower peduncles and effects of applied plant growth regulators

Removal of flower buds results in abscission of peduncles of the rose cv. Nubia and cessation of peduncle growth in cv. Mercedes. Peduncle growth was inhibited when pistils and stamens were removed, but was not affected by removal only of sepals and petals. Growth of the decapitated peduncles of Mercedes was partially restored by the application of auxin in lanolin paste on the base of the peduncle and was completely restored by the application of gibberellin, while the combined application of auxin and gibberellin was the most effective for growth restoration. Growth of non-decapitated Nubia peduncles was promoted by application of gibberellin or gibberellin and auxin but not auxin alone.Peduncle elongation of both cultivars was not affected by application of cytokinin and the effect of gibberellin was antagonized by combined application with cytokinin. The peduncles strength (resistance to bending) was affected more strongly by auxin than by gibberellin, and most strongly when auxin and gibberellin were combined. The effect of auxin on the strength of peduncles, but not of gibberellin, was antagonized by application of cytokinin. Excised, non-decapitated flowering stems of Nubia treated with gibberellin and auxin in situ, showed, recovery of the peduncles from wilting after exposure to heat conditions.     

Salicylic acid stimulates secretion of the normally symplastic enzyme mannitol dehydrogenase: a possible defense against mannitol-secreting fungal pathogens

The sugar alcohol mannitol is an important carbohydrate with well-documented roles in both metabolism and osmoprotection in many plants and fungi. In addition to these traditionally recognized roles, mannitol is reported to be an antioxidant and as such may play a role in host–pathogen interactions. Current research suggests that pathogenic fungi can secrete mannitol into the apoplast to suppress reactive oxygen-mediated host defenses. Immunoelectron microscopy, immunoblot, and biochemical data reported here show that the normally symplastic plant enzyme, mannitol dehydrogenase (MTD), is secreted into the apoplast after treatment with the endogenous inducer of plant defense responses salicylic acid (SA). In contrast, a cytoplasmic marker protein, hexokinase, remained cytoplasmic after SA-treatment. Secreted MTD retained activity after export to the apoplast. Given that MTD converts mannitol to the sugar mannose, MTD secretion may be an important component of plant defense against mannitol-secreting fungal pathogens such as Alternaria. After SA treatment, MTD was not detected in the Golgi apparatus, and its SA-induced secretion was resistant to brefeldin A, an inhibitor of Golgi-mediated protein transport. Together with the absence of a known extracellular targeting sequence on the MTD protein, these data suggest that a plant’s response to pathogen challenge may include secretion of selected defensive proteins by as yet uncharacterized, non-Golgi mechanisms.     

Gibberellin regulates post-microsporogenesis processes in petunia anthers

Previous studies have suggested that gibberellins (GAs) are produced in petunia anthers and transported to the corolla to induce growth and pigmentation. In this work, we studied the role of GA in the regulation of anther development. When petunia plants were treated with the GA-biosynthesis inhibitor paclobutrazol, anther development was arrested. Microscopic analysis of these anthers revealed that paclobutrazol inhibits post-meiotic developmental processes. The treated anthers contained pollen grains but the connective tissue and tapetum cells were degenerated. A similar phenotype was obtained when the Arabidopsis GA-signal repressor, SPY, was over-expressed in transgenic petunia plants, i.e. anther development was arrested following microsporogenesis. The expression of the GA-induced gene, GIP , can be used in petunia as a molecular marker to study GA responses. GA₃ treatment of young anthers promoted, and paclobutrazol inhibited, GIP expression, suggesting that the hormone controls the natural activation of the gene in the anthers. Analyses of GIP expression during anther development revealed that the gene is induced only after microsporogenesis. This observation further suggests a role for GA in the regulation of post-meiotic processes during petunia anther development.     

Phloem-Specific Expression of the Tobacco Mosaic Virus Movement Protein Alters Carbon Metabolism and Partitioning in Transgenic Potato Plants

The tobacco mosaic virus movement protein (TMV-MP) has pleiotropic effects when expressed in transgenic tobacco (Nicotiana tabacum) plants. In addition to its ability to increase the plasmodesmal size-exclusion limit, the TMV-MP alters carbohydrate metabolism in source leaves and dry matter partitioning between the various plant organs. In the present study the TMV-MP was expressed under the control of a phloem-specific promoter (rolC), and this system was employed to further explore the potential sites at which the TMV-MP exerts its influence over carbon metabolism and transport in transgenic potato (Solanum tuberosum) plants. Immunohistochemical analyses indicated that the TMV-MP was localized mainly to phloem parenchyma and companion cells. Starch and sucrose accumulated in source leaves of these plants to significantly higher levels compared with control potato lines. In addition, the rate of sucrose efflux from excised petioles was lower compared with control plants. Furthermore, under short-day conditions, carbon partitioning was lower to the roots and higher to tubers in rolC plants compared with controls. These results are discussed in terms of the mode(s) by which the TMV-MP exerts its influence over carbon metabolism and photoassimilate translocation.     

Short- and Long-eared High-yielding Hexaploid Wheat Cultivars: which has Unexpressed Potential for Higher Yield?

This investigation was designed to assess unexpressed potentialfor high yield and evaluate the sink strength of two high-yieldingwheat cultivars: a tall plant with long ears (LE), and a semi-dwarfwith short ears (SE). This was done by (1) removing one-thirdof the ear's distal end (decapitation), thereby inducing thedevelopment of additional florets, which usually do not form,on the untouched portion of the ear, and (2) by increasing thecompetition between the ears and the vegetative tissue's viathe application of gibberellic acid (GA). The number of grainsincreased on the untouched basal spikelets of the decapitatedears in both cultivars. The LE type fully recovered (100%) thenumber and mass of grains on the untouched portion of the decapitatedear. The decapitated SE type recovered 91% of the grain numberbut only 80% of individual grain mass. Thus, the total yield(number x mass) achieved by the untouched portion of the decapitatedear was 100% in the LE type and 80% in the SE type. Gibberelicacid treatment increased culm length in the tall LE plants butthis did not affect grain number of mass. Conversely, GA hadno significant effect on culm length of the semi-dwarf SE typebut significantly decreased their total grain yield. This effectwas due to a reduction in grain number by 64% of the control,rather than decreasing grain mass. Mean grain mass was not affectedby GA in either cultivar. A gradual increase in insoluble sugarconcentration (starch and fructan) in the ear peduncle duringthe first month after anthesis, followed by a sharp decreaselater, was found in the control and treated plants of both cultivars.In general, the concentrations of both soluble and insolublesugars declined as grain filling progressed, except for a noticeableincrease in total soluble sugars in the peduncles of the decapitatedears of the LE type. The results of this study suggest thatof the two high-yielding wheat cultivars that usually give identicalyields, the one with long multispikelet ears (LE) and lightergrains has significantly greater unexpressed potential for highyield than the cultivar with shorter ears (SE) and heavier grains.Copyright1995, 1999 Academic Press Ear, gibberellic acid, GA, grain number, grain mass, grain yield, sink strength, spikelet, Triticum aestivum, wheat     

Light,dark and growth regulator involvement in groundnut (Arachis hypogaea L.) pod development

Gynophore elongation and pod formation were studied in peanut plants (Arachis hypogaea L.) under light and dark conditions in vivo. The gynophores elongated until pod formation was initiated. Pod (3–20 mm length) development could be totally controlled by alternating dark (switched on) and light (switched off) conditions, repeatedly. Gynophore elongation responded conversely to light/dark conditions, compared to pods. In this study we aimed to correlate the light/dark effects with endogenous growth substances. The levels of endogenous growth substances were determined in the different stags of pod development. Gynophores shortly after penetration into the soil, ‘white’ gynophores, released twice the amount of ethylene as compared to the aerial green ones, or to gynophores bearing pods. Ethylene inhibitors had no effect on the percent of gynophores that developed pods, but affected pod size which were smaller compared to the control. A similar level of IAA was extracted from gynophore tips of green gynophores, ‘white’ gynophores and pods. ABA levels differed between the three stages and were highest in the green gynophores and lowest in the pods.