Ethylene Binding to Senescing Carnation Petals

Brown, J. H., Legge, R. L., Sisler, E. C, Baker, J E. and Thompson,J. E. 1986. Ethylene binding to senescing carnation petals.—J.exp. Bot 37: 526–534. Ethylene binding to carnation petals is significantly higheron a fresh weight basis for young fully expanded flowers thanfor older flowers showing petal-inrolling symptoms. The peakin ethylene binding precedes the climacteric-like rise in ethyleneproduction even when production of endogenous ethylene is inhibitedby incorporating amino-oxyacetic acid into the petals. FromScatchard analyses of ethylene binding, it has been estimatedthat petals from young fully expanded flowers have 11?10⁴ bindingsites per cell, whereas petals from senescent flowers showingextensive petal inrolling have 0.6?1010⁴ binding sites per cell.It is also apparent from the Scatchard analyses that the affinityof binding sites for ethylene decreases with advancing age ofthe flowers. The decline in number of binding sites with advancingage can be essentially accounted for by the extensive breakdownof membranes that accompanies senescence. However, the decreasedaffinity for ethylene in the older tissue suggests that thebinding sites become altered with advancing senescence. Key words: Carnation, ethylene binding, senescence     

Enhanced growth and ethylene increases spiral grain formation in Picea abies and Abies balsamea trees

Spiral grain angle in Norway spruce (Picea abies) trees and balsam fir (Abies balsamea) seedlings was investigated in relation to growth rate, endogenous and applied ethylene. Trees from stands of Norway spruce, which were irrigated and fertilised in order to enhance growth, and trees having different growth rates in non-treated stands were studied. Stem growth rate at the stand level (m³ ha^-1 year^-1) was measured annually, or by means of microscopy on stem sections as the number and size of tracheids produced. Enhanced growth increased ethylene evolution and maintained a high level of left-handed spiral grain angle in comparison to slower-growing trees. An increased number of earlywood tracheids in fast growing trees was correlated to a more left-handed spiral grain angle. Ethrel, applied to stems of balsam fir seedlings, increased the internal ethylene levels in parallel with increased left-handed spiral grain angle. The results indicate that ethylene regulates the extent of spiral grain angle.     

Involvement of Ethylene in Chromosaponin-Induced Stimulation of Growth in Lettuce Roots

To elucidate the mode of action of chromosaponin I (CSI) instimulating the growth of lettuce roots (Lactuca sativa L. cv.Grand Rapids), the possible involvement of ethylene was examined.Lettuce seedlings evolved ethylene at a rate of 0.7 nl 10 seeds–¹h–¹. The growth of lettuce roots was stimulated by 2-aminoethoxyvinyl-glycine(AVG), an inhibitor of ethylene synthesis, and 2,5-norbornadiene(NBD), an inhibitor of ethylene action, as well as by CSI. Incontrast to ethylene, treatments with CSI, AVG and NBD promotedlongitudinal elongation of cortical cells of roots and inhibitedtheir lateral expansion. Application of CSI slightly reducedethylene production from lettuce, but this reduction was notsufficient to account for the CSI-in-duced stimulation of growth.The maximal promotive effects of AVG and NBD were obtained at3 µM and 150 µl liter–¹, respectively. Thegrowth promotion by CSI disappeared in the presence of the optimumlevels of AVG or NBD; a further addition of ethylene causedthe stimulatory effects of CSI to increase, depending on theconcentration of ethylene. Thus, CSI reduced both the sensitivityof the roots to ethylene and the maximal effects of ethylene.The CSI-induced stimulation of growth was ascribed to the reductionof the response to ethylene in the lettuce roots. (Received December 20, 1996; Accepted March 16, 1997)     

Roles of Ethylene and Indol-3yl-acetic Acid in Petiole Epinasty in Helianthus annuus and the Modifying Influence of Gibberellic Acid

The effect of 12 h exposure to ethylene upon epinastic curvatureand elongation of a 5-cm segment in the attached petiole ofHelianthus annuus has been investigated in either normal orGA₂-treated plants. Curvature of segments occurred rapidly inthe first. 6 h during exposure of normal plants to either 1.0or 40.0 parts/10⁶ ethylene, and continued slowly from 6 to 12h. After the ethylene treatment, recovery from the induced curvaturewas completed in 12 h. In 0.2 parts/10⁶ ethylene, recovery fromthe epinastic curvature began during the second half of thetreatment period. Pre-treatment of plants with 60 µg GA₃,did not change the epinastic response to 40.0 parts/10⁶ ethylene.In 10.0 parts/10⁶ ethylene, recovery commenced towards the endof the treatment period, while in 1.0 parts/10⁶ the onset ofepinasty was delayed by about 6 h. In 0.2 parts/10⁶ ethylenethe epinastic response was slight. Ethylene accelerated elongation in the upper half of the petiolesegment. This response was completed within 12 h in all concentrationsand in both normal and GA₃-treated plants. The mean elongationrate in the lower half was depressed from 4.6 to 1.0 mm 24h^–1in 40.0 parts/10⁶ but immediately afterwards it rose to 14.2mm 24 h^–1. A similar response occurred in 1.0 parts/10⁶.In contrast, the elongation of the lower half of the petiolesegment was stimulated by 0.2 parts/10⁶ ethylene. GA₂-treatedplants showed an initial depression of elongation in the lowerhalf in 10.0 or 40.0 parts/10⁶ ethylene, but in the second partof the treatment period the elongation rate recovered to thatof the control segments. Both 0.2 and 1.0 parts/10⁶ ethylenestimulated elongation growth in the lower half of segments inGA₂-treated plants. Removal of the leaf lamina inhibited segment elongation, butdid not affect the growth response of the upper half to 40.0parts/10⁶ ethylene. In contrast the lower half of the segmentno longer showed the usual growth responses to 40.0 parts/10⁶ethylene, although these were partially retained when 10µgof IAA was applied to the cut end of the petiole.     

Auxin and Ethylene Control of Growth in Seedlings of Zea mays L. and Avena sativa L

The effects of applied ethylene on the growth of coleoptilesand mesocotyls of etiolated monocot seedlings (oat and maize)have been compared with those on the epicotyl of a dicot seedling(the etiolated pea). Significant inhibition of elongation by ethylene (10 µll^–1for 24 h) was found in intact seedlings of all three species,but lateral expansion growth was observed only in the pea internodeand oat mesocotyl tissue. The sensitivity of the growth of seedlingparts to ethylene is in the decreasing order pea internode,oat coleoptile and oat mesocotyl, with maize exhibiting theleast growth response. Although excised segments of mesocotyland coleoptile or pea internode all exhibit enhanced elongationgrowth in IAA solutions (10^–6–2 ? 10^–5 moll^–1), no consistent effects were found in ethylene. Ethyleneproduction in segments was significantly enhanced by applicationof auxin (IAA, 10^–5 mol l^–6 or less) in all tissuesexcept those of the eat mesocotyl. Segments of maize show a slow rate of metabolism of applied[2-¹⁴C]IAA (30 per cent converted to other metabolites within9 h) and a high capacity for polar auxin transport. Ethylene(10 µl l^–1 for 24 h) has little effect on eitherof these processes. The oat has a smaller capacity for polartransport than maize and the rate ef metabolism of auxin isas fast as in the pea (90 per cent metabolized in 6 h). Althoughethylene pretreatment does not change the rate of auxin metabolismin oat, there is a marked reduction in auxin transport. It is proposed that the insensitivity of maize seedlings toethylene is related to the supply and persistence of auxin whichcould protect the seedling against the effects of applied orendogenously produced ethylene. Although the mesocotyl of oatis sensitive to applied ethylene it may be in part protectedagainst ethylene in vivo by the absence of an auxin-enhancedethylene production system. The results are discussed in relationto a model for the auxin and ethylene control of cell growthin the pea.     

The effect of ethylene on auxin-induced growth of excised rice coleoptile segments

Elongation growth induced by exogenous auxin of apical coleoptilesegments of etiolated rice seedlings was promoted by ethylene.In the absence of exogenous auxin, growth promotion was notobserved. The highest promotion by ethylene was obtained at10^–6 M of indole-3-acetic acid, a suboptimal concentrationfor auxin-induced elongation. Level of ethylene which achievedthe effect was less than 1 µl per liter of an incubationatmosphere. ¹Present address: The Ocean Research Institute, University ofTokyo, Nakano, Tokyo, Japan (Received May 27, 1970; )     

Effect of Ethylene and Culture Environment on Rice Callus Proliferation

Modifications to the gaseous envelope by callus during culturein Petri dishes were shown to reduce growth and promote necrosisof several rice (Oryza sativa L.) cultivars. Incubatingcallusunder a continuous flow of gas mixtures of known compositionsuggested that the inhibition of growth was caused by the accumulationof ethylene, the depletion of oxygen and, to a lesser extent,the accumulation of carbon dioxide. In order to evaluate theimportance of ethylene accumulation aminoethoxyvinylglycine(AVG), 1-aminocyclopropane-l-carboxylic acid (ACC and silvernitrate (AgNO₃), were added to the nutrient medium and ethylenemeasurements performed during callus culture. Ethylene restrictedcallus growth particularly under high (35 °C) as comparedto moderate (25 °C) temperatures and under illuminated ascompared to darkened incubation. Under illuminated incubationat 25 °C AVG (5 mmol m^–3) and AgNO°(50 mmol m^–3)significantly improvedcallus growth (100 and 60% respectively)while ACC (200 mmol m^–3) significantly decreased growth(40%). AVG and AgNO₃ were less effective under dark incubationat 25 °C where ethylene production was lower. Furthermore,callus growth was significantly better in large as comparedto small culture vessels since the ethylene concentration wasdiluted and more oxygen was available for respiration. Bettercontrol of ethylene and increased oxygen availability couldbe a way ofproducing healthy callus for the formation of embryogenictissues of otherwise recalcitrant cultivars of rice (e.g. IndicaIR42) and may be a way of improving manipulation of other cerealspecies. Key words: 1-Aminocyclopropane-1-carboxylic acid, aminoethoxyvinylglycine, callus, ethylene, Oryza sativa, silver nitrate     

Cooperation of Ethylene and Auxin in the Growth Regulation of Rice Coleoptile Segments

Elongation of coleoptile segments, having or not having a tip,excised from rice (Oryza sativa L. cv. Sasanishiki) seedlingswas promoted by exogenous ethylene above 0.3 µl l^–1as well as by IAA above 0.1 µM. Ethylene production ofdecapitated segments was stimulated by IAA above 1.0µM,and this was strongly inhibited by 1.0 µM AVG. AVG inhibitedthe IAA-stimulated elongation of the decapitated segment witha 4 h lag period, and this was completely recovered by ethyleneapplied at the concentration of 0.03 µl l^–1, whichhad no effect on elongation without exogenous IAA. The effectsof IAA and ethylene on elongation were additive. These factsshow that ethylene produced in response to IAA promotes ricecoleoptile elongation in concert with IAA, probably by prolongingthe possible duration of the IAA-stimulated elongation, butthat they act independently of each other. Moreover, AVG stronglyinhibited the endogenous growth of coleoptile segments withtips and this effect was nullified by the exogenous applicationof 0.03 µl l^–1 ethylene. These data imply that theelongation of intact rice coleoptiles may be regulated cooperativelyby endogenous ethylene and auxin in the same manner as foundin the IAA-stimulated elongation of the decapitated coleoptilesegments. Key words: oryza sativa, Ethylene, Auxin, Coleoptile growth     

Effects of Calcium on NAD(H)-Glutamate Dehydrogenase from Turnip (Brassica rapa L.) Mitochondria

The effect of Ca²⁺ and ammonia on mitochondrial NADH-glutamatedehydrogenase (GDH: EC 1.4.1.2 [EC] ) isolated from turnip root (Brassicarapa L.) activity was examined. Increasing the ammonia [(NH₄)₂SO₄]concentration led to significant substrate inhibition whichcould be reversed by micromolar levels of Ca²⁺. The sensitivityof the enzyme to ammonia inhibition and its reversal by Ca²⁺was affected by proteolysis. After treatment with various proteases,lower concentrations of Ca²⁺ were capable of fully activatingthe enzyme or overcoming the inhibitory effects of high ammonium,compared to non-treated enzyme. However, the protease-treatedenzyme was still sensitive to ethylene glycol-bis(ß-aminoethylether) N,N,N',N'-tetraacetate (EGTA). In contrast, NADH-GDHactivity was inhibited approx. 30% by organic mercurials (200µm), but the residual activity was not affected by thesubsequent additions of EGTA. NADH-GDH activity could also bestimulated by additions of high concentrations of NaCl (300mM) in the absence of added Ca²⁺. These results suggest thathydrophobic and -SH groups may be involved in the regulationof mitochondrial NADH-GDH activity by Ca²⁺. ² Present address: CSIRO Division of Horticulture, Urrbrae,S.A. 5064, Australia (Received April 18, 1990; Accepted July 23, 1990)     

BIOGENESIS OF ETHYLENE IN APPLE TISSUE: I. FORMATION OF ETHYLENE FROM GLUCOSE, ACETATE, PYRUVATE, AND ACETALDEHYDE IN APPLE TISSUE

1. With the aim of elucidating the path of carbon in the formationof ethylene in plants, studies were made on the incorporationof ¹⁴C into ethylene evolved from apple slices, using several¹⁴C- labeled compounds as substrates. The effects of inhibitorswere also investigated. 2. The formation of ethylene-¹⁴C from glucose-¹⁴C was inhibitedby fluoride, but unaffected by arsenite, thus suggesting thatglucose is converted to ethylene via pyruvate. 3. Acetate is converted to ethylene after cleavage of C-l andC-2. Only a small portion of the latter (C-2) enters the moleculeof ethylene, the former (C-l) is detected in carbon dioxide.On the other hand, 2, and 3-carbons of pyruvate are converted,without splitting, to ethylene. 4. On removal of air, the incorporation of ¹⁴C into ethylenefrom acetate-2-¹⁴C was depressed, while that from pyruvate-¹⁴Cwas unaffected. 5. Acetaldehyde-l,2-¹⁴C is converted to ethylene without conversioninto ethanol. 6. These results are interpreted to suggest the occurrence ofthe pathway in which pyruvate and acetaldehyde may serve asprecursors of ethylene. ¹ A part of this paper was read at the regular Meeting of KansaiBranch of the Agricultural Chemical Society of Japan in Kyoto,October, 1964, and at the Annual Meeting of the Japanese Societyof Plant Physiologists in Tokyo, April, 1965 and presented ina preliminary form elsewhere (10).     

Compensatory Aspects of the Biosynthesis of Spermidine in Tobacco Cells in Suspension Culture

The relationship between the biosynthesis of polyamines andethylene was examined in suspension cultures of Nicotiana tabacumL. cells. Aminooxyacetic acid (AOA), an inhibitor of 1-aminocyclopropane-1-carboxylicacid synthase, inhibited the production of ethylene and raisedlevels of spermidine by increasing the availability of S-adenosylmethionine(SAM) for the synthesis of polyamines. In contrast, methylglyoxalbis (guanylhydrazone) (MGBG), an inhibitor of S-adenosylmethioninedecarboxylase (SAMDC), an enzyme involved in the biosynthesisof polyamines, caused a slight increase in the rate of biosynthesisof ethylene. However MGBG did not decrease the rate of biosynthesisof polyamines in 10-day-old senescing cells. Although MGBG inhibitedthe conversion of L-[U-^l4C]methionine into labeled spermidinevia SAM both in 4-day-and in 10-day-cultured cells, it stimulatedthe conversion of L-[U-^l4C]aspartic acid into labeled spermidinein 10-day-cultured cells. In actively dividing 4-day-culturedcells, L-[U-¹⁴C]homo-serine was also converted into polyamines.In senescing cells, which produce large amounts of ethylene,the biosynthesis of spermidine from aspartic acid coincidedwith that from methionine. In actively growing cells, whichproduce large amounts of polyamines, the biosynthesis of spermidinefrom homoserine coincided with that from methionine. These resultsindicate that homoserine and aspartic acid can be both usedas precursors in the biosynthesis of polyamines and help tomaintain appropriate titers of polyamines, when SAMDC is inhibitedand the level of decarboxylated SAM becomes limiting. (Received May 14, 1990; Accepted March 11, 1991)     

Picoplankton dynamics in Davies Reef lagoon, the Great Barrier Reef, Australia

The diel variations in abundance and frequency of dividing cells(FDC) of coccoid cyanobacteria in a coral reef lagoon were investigatedin June, September and December 1989, and April 1990. Cyanobacteriaand picoplanktonic eukaryotes (<3 µm) were sampledmonthly from January to December 1990. The average abundancesof cyanobacteria and eukaryotes ranged between 1.17–10.0610⁴cells ml^–1 and 0.16–2.4110⁴ cells ml^–1, respectively,with abundances of both being higher in summer (November-April)than in winter (May-October). The ratio of cyanobacteria toeukaryotes fluctuated from 1.93 to 8.67, independent of theseasonal variation in their abundances. The instantaneous growthrate of cyanobacteria, which was estimated from the daytimeabundance increment, ranged between 0.430 and 3.144 day^–1The estimated daily specific growth rate of cyanobacteria bythe FDC method ranged between 0.231 and 0.966 day^–1. InApril, despite the high specific growth rate and low flushingconditions. cyanobacterial abundance showed a cyclic diel pattern,suggesting a strong grazing impact on their population.     

Response of Developing Apple Fruits to Ethylene Treatment

Knee, M., Hatfield, S. G. S. and Bramlage, W. B. 1987. Responseof developing fruits to ethylene treatment.—J. exp. Bot.38: 972–979. Fruits of apple (Malus domestica Borkh. cv. Cox's Orange Pippin)were treated with various concentrations of ethylene usuallyfor 48 h to determine their response in relation to stage ofdevelopment. The main response recorded was the reduction byethylene of the delay in onset of rapid ethylene production(DEP) in individual fruits. Early in development low concentrationsof ethylene had little effect but DEP was progressively reducedby concentrations up to 10⁷ mm³ m^–3. As the fruit approachedthe natural onset of rapid ethylene synthesis concentrationsof 10² and 10³ mm³ m^–3 became increasingly effective.Increasing the duration of treatments with a fixed concentrationreduced DEP proportionately. Delay after harvest in applyinga 48 h treatment had little effect on the relation between DEPand concentration of ethylene applied. Although resistance todiffusion of gas in fruits increased during fruit developmentthis resistance was never large enough to affect the relationof concentration and response. Key words: ethylene, fruit ripening, Malus domestica     

Relations Between Indoleacetic Acid, Calcium Ions and Ethylene in the Regulation of Growth and Cell Wall Composition in Picea abies

Effects of indoleacetic acid, calcium ions and ethylene on thegrowth of and deposition of different cell wall fractions inthe hypocotyl of Norway spruce (Picea abies (L.) Karst.) seedlingswere investigated. Indoleacetic acid progressively stimulated cellulose depositionas the amount of added Ca²⁺ increased. In contrast, indoleaceticacid promoted lignification and the deposition of non-cellulosicpolysaccharides only in the absence of added Ca²⁺ . When Ca²⁺was added, the indoleacetic acid effect disappeared. Similarly,indoleacetic acid promoted non-cellulosic polysaccharide depositiononly in the absence of ethylene. At increasing ethylene levelsthe effect of indoleacetic acid on non-cellulosic polysaccharidedeposition disappeared and indoleacetic acid instead promotedcellulose deposition. The response to indoleacetic acid depended on the Ca²⁺ concentrationand on the rate of ethylene production. The relationship betweenindoleacetic acid and Ca²⁺ seemed complex, but clearly indoleaceticacid could partially overcome a Ca²⁺ deficiency. The resultssuggest that ethylene may be a factor of particular importancefor the type of polysaccharide deposition during cell wall formation. Key words: Calcium, cell wall, conifers, ethylene, indoleacetic acid     

Biosynthesis of ethylene in sweet potato root tissue

The biosynthetic pathway of ethylene in freshly cut and blackrot-diseased tissues of sweet potato roots was investigated.Glucose-U-¹⁴C administration gave labeled ethylene in both freshand diseased tissues, but at the early stage of infection, therewas ethylene production which was not derived from the fed ¹⁴C-glucose.Acetate-1-¹⁴C and acetate-2-¹⁴C were equally incorporated intoethylene produced from fresh tissue, but acetate-2-¹⁴C was preferentiallyincorporated into ethylene from diseased tissue. Pyruvate-3-¹⁴Cwas more efficient as a precursor than was acetate or glucosein fresh tissue, while its efficiency was the same as that ofacetate in diseased tissue. Monofluoroacetate promoted pyruvate-3-¹⁴Cincorporation in fresh tissue but inhibited incorporation indiseased tissue. We concluded that the TCA cycle is involvedin the case of diseased tissue but not in fresh tissue; thus,showing different pathways for ethylene production in each tissue.In addition, in diseased tissue, ethylene is assumed to be producedfrom some cellular component(s), not easily synthesized fromglucose through fungus infection, but is degraded as soon asinfection commences. ¹This paper constitutes Part 85 of the Phytopathological Chemistryof Sweet Potato with Black Rot and Injury ²Present address: The Institute for Biochemical Regulation,Faculty of Agriculture, Nagoya University, Chikusa, Nagoya 464,Japan (Received April 20, 1970; )     

Lateral Bud Growth in Phaseolus vulgaris L. and the Levels of Ethylene in the Bud and Adjacent Tissue

Ethephon and the ethylene inhibitors Ag⁺ and aminoethoxyvinylglycine (AVG) inhibited outgrowth of the axillary bud of thefirst trifoliate leaf in decapitated plants of Phaseolus vulgaris.Endogenous ethylene levels decreased in the stem upon decapitationalthough it is not conclusive that a causal relationship existsbetween this decrease and the release of axillary buds frominhibition. The proposition that auxin-induced ethylene is responsiblefor the suppression of axillary bud growth in the decapitatedplant when the apical shoot is replaced by auxin is not borneout in this study. Application of IAA directly to the axillarybud of intact plants gave rise to a transient increase in budgrowth. This growth increment was annulled when AVG was suppliedwith IAA to the bud despite the fact that the dosage of AVGused did not affect the normal slow growth rate of the bud ofthe intact plant or bud outgrowth resulting from shoot decapitation.     

Ethylene Production by the Lichen Ramalina duriaei

The lichen Ramalina duriaei evolved ethylene when in a wettedstate, the rate of ethylene evolution being constant for atleast the first 20 h. Inhibitors of the ACC (I-aminocyclopropane-I-carboxylicacid) pathway did not inhibit ethylene production. Metal ionsstimulated the production, with Fe²⁺ being the most effective.This stimulation was not affected by inhibitors of the ACC pathwaybut was inhibited by free radical scavengers such as propylgallateand quercitin. Endogenous ACC content was similar whether thelichens were producing ethylene at a basal rate or during Fe²⁺-stimulatedethylene formation. Malondialdehyde and aldehyde contents werehigher in the presence of Fe²⁺. The results are discussed interms of known pathways of ethylene production by micro-organisms. ACC, ethylene, metal ions, methionine, 2-oxo-methylthiobutyric acid, Ramalina duriaei (De Not.) Bagl     

Time sequence of the effect of ethylene on transport, uptake and decarboxylation of auxin

The effect of ethylene on the uptake, decarboxylation and basipetaltransport of IAA-1-¹⁴C, IAA-2-¹⁴C and NAA-1-¹⁴C in cotton stemsections (Gossypium hirsutum L., var. Stoneville 213) was studied.A reduction in the capacity of cotton stem sections to transportauxin basipetally appears in sections excised from plants exposedto ethylene for only 3 hr and increases with fumigation time. In addition to reducing transport, increasing ethylene pretreatmentperiods from 3 to 15 hr also progressively reduced the uptakeof ¹⁴C and increased the release of ¹⁴C as ¹⁴CO₂ from IAA-1-¹⁴C.The effect of ethylene on the decarboxylation of IAA-1-¹⁴C wassignificant when expressed as either the cpm of ¹⁴C releasedper hr per mg dry weight or the cpm released per hr per mm²in contact with the IAA donor. Comparative experiments usingIAA-1-¹⁴C and IAA-2-¹⁴C demonstrated that the effect of ethyleneon the decarboxylation of IAA was primarily a cut surface effectwhich apparently contributes to the reduction of IAA uptakeby ethylene. Although ethylene significantly reduced the transport of NAA-1-¹⁴C,uptake was significantly increased rather than decreased aswith IAA-1-¹⁴C while decarboxylation was unaffected. Ethylene pretreatment caused no significant changes in the dryweight or the cross-sectional area of the absorbing surfaceof the transport tissue. ¹A contribution of the Texas Agricultural Experiment Station.Supported in part by Grant GB-5640, National Science Foundationand grants from the Cotton Producers Institute and the NationalCotton Council of America. ²Present address: Central Research Department, E. I. Du PontDe Nemours and Company, Wilmington, Delaware 19898, U. S. A. (Received May 29, 1969; )     

Auxin Regulation of the Response of Phaseolus vulgaris to a Fungal Elicitor

The effect of IAA and 2,4-D on the response of Phaseolus vulgaristo limiting concentrations of cell wall elicitors of Colletotrichumlindemuthianum was investigated in attached leaves of both thesusceptible, Pinto, and resistant, Kievit, cultivars. Low concentrationsof the plant hormones augmented the response, as measured bychanges in the activity of enzymes of the flavanoid pathway(phenylalanine ammonia-lyase (PAL) and -coumaric acid coenzyme-Aligase (-CL)) and phytoalexin concentration, both cultivars.This contrasts to a previous study with ethylene, where augmentationwas observed in leaves of cv. Kievit only; however, in the absenceof elicitor neither auxin nor ethylene have any effect. It wasalso observed that IAA promoted the synthesis of ethylene inthe leaves of cv. Kievit; inhibition of ethylene synthesis demonstratedthat the hormone could, nevertheless, act independently of ethyleneto enhance phytoalexin synthesis. The effect of auxin was particularly pronounced on PAL—hithertoidentified as a key regulatory enzyme on the flavanoid pathwaywhich, it is proposed, could be under the dual regulation ofboth auxin and ethylene. Similarly, the mode of action of auxinwas shown to resemble that of ethylene in that its effect isbrought about, partially if not entirely, as a result of itsregulation of the synthesis of enzymes of the flavanoid pathway. ¹Present address: School of Chemistry, Molecular and BiologicalSciences, University of Sussex, Brighton, U.K. (Received February 7, 1990; Accepted May 8, 1990)     

Effect of Growth Regulators and Light on Pollen Germination and Pollen Tube Growth in Pinus roxburghii Sarg

Pine (Pinus roxburghii) pollen grown in suspension cultureswas used to study the effects of growth regulators and lightconditions on germination and pollen tube growth. Indol-3-ylacetic acid, gibberellic acid, ethylene, abscisic acid and cyclicAMP (cAMP) at low concentrations (1–10 mg 1^–1) promotedgermination and tube growth. Addition of 1 and 10 mg 1^–1cAMP to any of the growth regulators had a promotory effect.Pollen tube growth decreased in white light as compared to thedark, and was increased in red light. Far-red light counteractedthe effect of red light. The effect of growth regulators incausing the enhanced tube growth appears to be manifested throughsubstances such as cAMP, and phytochrome seems to be involved. Pinus roxburghii, pine, pollen germination, pollen tube growth, growth regulators, cyclic AMP, phytochrome