Apical Dominance in the 'Rogue' Tomato

The rogue tomato exhibits less apical dominance than the normalplant though the degree of correlative inhibition varies considerablybetween winter- and summer-sown plants. An examination of thelevel of endogenous hormones in both rogue and normal plantsat both times of year indicates that the degree of branchingis strongly associated with the levels of auxin in the tissue.It is suggested that this hormone has an effect on apical dominanceby virtue of its role in hormone-directed transport and by itseffect on the formation of abscisic acid in the region of thelateral buds. The results are discussed in relation to currenthypotheses of the mechanism of apical dominance.     

Apical Dominance in the Tomato: Some Further Observations on Isogenic Lines Showing Varying Degrees of Side-shoot Development

A study has been made of the distribution of substances resemblingindol-3-ylacetic acid (IAA), abscisic acid (ABA) and cytokinin-likesubstances in the stem tissue of Craigella tomato plants ascompared with that found in two isogenic lines of this variety,Craigella Blind (blbl) and Craigella Lateral Suppressor (lsls),in both of which side shoot growth is suppressed to varyingdegrees. There was no evidence to suggest that the distributionof these hormones in the stem had any association with the differentpatterns of side shoot development of the three types, thoughsome of the lateral suppressor plants which exhibited only partialbud inhibition did show a relation between high auxin and abscisicacid levels and lack of side shoot development from the centralnodes of the shoot. Decapitation led to a stimulation of bud outgrowth from allnodes of the Craigella plants but the lateral suppressor plantsremained inhibited. The blind plants were found to initiatebud primordia at the cotyledonary nodes only when the severedapex was replaced by exogenous IAA. The results are discussed in relation to our knowledge of themechanisms controlling apical dominance in the tomato. Lycopersicon esculentumL, tomato, apical dominance, growth regulation, indol-3-ylacetic acid, abscisic acid, cytokinins     

Light Effects on Apical Dominance

Reducing light intensity from 18·0 klx to 5·4klx promoted main-stem growth in Phaseolus vulgaris but leftlateral extension unaffected. Shading individual laterals orapices of main stems promoted elongation of the shaded portion.Increasing day length from 8 to 16 or 24 h did not greatly affectplant growth if full-intensity and full-spectrum light was used.If, however, the additional light was supplied by incandescenttubes containing a high proportion of infra-red light, growthof main stems but not laterals was induced in proportion tothe length of the additional light period. It is suggested thatthe increased growth of the main stem in response to infra-redlight prevented the equivalent response of the laterals becauseof the enhanced ability of the main stem to suppress lateralelongation.     

Apical Dominance in Vicia faba

Apical dominance phenomena have been studied in seedlings ofVicia faba particularly in relation to the movement about theplant of uracil-2-¹⁴C applied to the cotyledons. Decapitationjust below the second node releases the growth of the lowermostlateral bud and inhibition is completely reimposed by applicationof indole-3-acetic acid (IAA) to the cut surface. Uracil-2-¹⁴Capplied in solution to the cotyledons is distributed in thestems of all experimental seedlings with no consistent differencesdue to decapitation or IAA application. On the other hand, decapitationresults in a rapid increase in uracil-2-¹⁴C content in the lateralbuds which far exceeds their promoted growth. This uptake iscompletely suppressed by IAA application. A ring of tri-iodobenzoicacid (TIBA)-lanolin paste around the stem above the bud suppressesIAA action both in bud growth and on uracil-2-¹⁴C uptake, andalso on the movement of IAA-1-¹⁴C down the stem. TIBA-application to the base of the bud does not prevent IAAaction on bud growth, but also does not prevent the movementof IAA-1-¹⁴C (or a water soluble product of its metabolism)into the bud. Direct application of kinetin to the lateral bud of intact plantscauses a short-lived release of growth. Gibberellic acid producesa smaller and scarcely significant increase which is additiveto the kinetin effect. Neither has any effect on uracil-2-¹⁴Cmovement into the bud. The implications of these findings are discussed in relationto various existing theories of the mode of auxin action inapical dominance and it is concluded that their strongest supportis for a mechanism involving the suppression of phloem differentiationin the vascular supply to the bud.     

Differential Responses of Buds along the Shoot to Factors Involved in Apical Dominance

Intact and decapitated 6-node shoots of Hygrophila sp. weregrown aseptically immersed in liquid half-strength Knop's solutionwith microelements and 2% (w/v) sucrose (control medium), andin medium with 0.1 mg l^–1 benzyladenine (BA). In intactshoots grown in control medium apical dominance suppressed outgrowthof the lateral buds; in decapitated shoots buds grew out atseveral of the most apical nodes, increasing in size acropetally.There was a lag in outgrowth of the bud at the most apical node,attributable to its initially smaller size. Lateral shoots grewout first at basal nodes of intact shoots in BA medium, decreasingin size acropetally; in decapitated shoots in BA medium lateralshoots of approximately equal size grew out at all nodes. Differentialeffects of decapitation and cytokinin treatment on lateral shootoutgrowth along the shoot could be interpreted by postulatinga basipetally decreasing gradient of endogenous auxin concentrationin the intact shoot. Application of 20 mg l^–1 indoleaceticacid (IAA) in agar to decapitated shoots completely preventedbud outgrowth for at least 7 d in control medium, inhibitingit thereafter, and inhibited bud outgrowth in BA medium, thussupporting the hypothesis. Comparison of lateral shoot outgrowthin whole decapitated shoots and severed decapitated shoots (isolatednodes) lent no support to the alternative hypothesis that theremight be an acropetally decreasing concentration gradient ofa bud-promoting substance in the intact shoot, and demonstratedmuch greater lateral shoot growth in isolated nodes. The resultsemphasize important correlative relationships between the partsof a shoot with several nodes.     

Axillary Bud Formation in Two Isogenic Lines of Tomato Showing Different Degrees of Apical Dominance

Grafting experiments have been carried out in which rootstocksof the cultivar Craigella were paired with scions of an isogenicline Craigella Lateral Suppressor (ls ls) and vice versa, andthe levels of hormones in the roots and shoots of the graftedplants examined. The roots of Craigella plants differed from those of LateralSuppressor in that they contained a higher proportion of a cytokininthat co-chromatographed with N⁶ - (²—isopentenyl) adenosine.Reciprocal grafts did not lead to any qualitative or quantitativechanges in the cytokinins in the roots of either line. GraftingLateral Suppressor scions on Craigella rootstocks led to anincrease in the IAA content of the apical region and the ABAcontent of the stem tissue immediately below it, but when Craigellascions were grafted on Lateral Suppressor rootstocks there wereno changes in the level of either hormone. Cytokinins applied to the leaf axils of Lateral Suppressor plantsresulted in lateral bud initiation in the axils above the pointof treatment but not if the plants were also given a short periodof far-red light at the end of the photoperiod. Cytokinins wereineffective in initiating lateral buds in grafted Lateral Suppressorscions. It is suggested that root-produced cytokinins influence lateralbud outgrowth indirectly by way of their effect on the levelsof IAA and ABA in the shoot. Lycopersicon esculentum Mill., tomato, apical dominance, growth regulation, indol-3yl acetic acid, abscisic acid, cytokinins     

Hormones and Apical Dominance in the Fern Davallia

Lateral buds of the fern Davallia trichomanoides are releasedfrom inhibition by the removal of the main shoot apex. However,auxin is not capable of substituting for the apex in decapitatedshoots nor can auxin in shoot tips be detected by bioassay orextraction and chromatography. Expanding leaves of this speciescontain auxin, but these organs are not responsible for inhibitionof lateral bud growth. The response of lateral buds to an exogenouslyapplied cytokinin does not result in initial bud break. It isconcluded that the hormonal factors known to govern apical dominancein seed plants are not responsible for the regulation of differentialbud expansion in this fern.     

Apical Dominance in Phaseolus vulgaris L.

Although determinations of the ABA content of lateral buds ofPhaseolus vulgaris revealed no difference between decapitatedand intact control plants in the first 12 h following decapitation,a relative decrease in the ABA content of lateral buds of decapitatedplants was detectable 24 h following decapitation. Shoot decapitationwas also observed to result in a decrease in the ABA contentof stem tissue. The application of IAA to the stem of decapitatedplants prevented these changes and increased the ABA contentof stem tissue relative to that of intact plants. The levelsof IAA and ABA were also determined in the stem tissue fromthe nodes of intact bean plants. The possible interdependenceof these two plant hormones was further investigated by a studyof [2_–14ClABA metabolism. The results are discussed inrelation to the possible role of these hormones in apical dominance. Key words: Apical dominance, Abscisic acid, Indole-3-acetic acid     

The Mechanism of Apical Dominance in Coleus

The development of lateral buds in isolated stems of Coleus blumei is inhibited by low concentrations of indoleacetic acid or other auxins, just as in other plants. The inhibition can be fully reversed by kinetin, about 3 times as much kinetin as IAA being needed. However, the outgrowth of the same lateral buds on intact Coleus plants is sensitive to environmental conditions, well-nourished plants in full daylight often showing little inhibition by applied auxin. It is shown that (a) the solvent used for IAA, (b) the light intensity and (c) the nitrogen and phosphorus nutrition, all control the sensitivity of the buds to auxin inhibition. Using water instead of lanolin, lowering the light intensity or decreasing the supply of either nitrogen or phosphorus all increase the degree of apical dominance.     

乙烯在豌豆植株顶端优势中的作用

用人工合成细胞分裂素BAP和CPPU处理豌豆植株叶腋可诱导处理部位侧芽的生长,同时伴有大量乙烯产生;用乙烯合成抑制剂AVG处理或植株去顶同样可导致创芽生长,但乙烯释放量却明显少于对照,表明侧芽的生长与乙烯释放量的多少无关。而3种物质处理后诱导产生的侧芽的数目、长度及其鲜重与处理部位内源IAA含量的增加则呈正相关。     

Hormone Interaction in Apical Dominance in Phaseolus vulgaris L.

Gibberellic acid (GA₃), kinetin, and indole-3yl-acetic acid(IAA) were applied to roots of Phaseolus vulgaris under twodifferent light intensities and when either young or old leaveswere removed In all cases GA₃, promoted stem and lateral growth,especially when light intensity was reduced. Promotion by GA₃,of stem growth under reduced light was reduced if IAA and kinetinwere present; promotion of lateral growth under reduced lightwas reduced if IAA was added and eliminated if kinetin or kinetinplus IAA were added to GA₃. Removal of young and mature leavesreduced main stem growth; removal of young leaves promoted,and of mature leaves reduced, lateral shoot growth. We suggestthat shoot growth and apical dominance are governed by the balanceof hormones present in elongating internodes. There may be twoways of modifying this balance; firstly by altering light, temperature,or nutrients, or by applying hormones generally to the plant.Secondly, local modifications can be made by removing apicesor young leaves, or applying hormones in lanolin to specificareas. Knowledge of both the general and local conditions maybe necessary for a complete understanding of apical dominance.     

脱落酸与向日葵顶端优势关系的研究

本文选用顶端优势程度不同的两个品种向日葵,进行了外源脱落酸的处理实验和内源脱落酸含量的测定,从而对“顶端产生的生长素是通过诱导植物组织内产生或者使其保持有较高水平的脱落酸,由此对侧芽的生长起抑制作用”的假说进行了验证。结果则表明,节内脱落酸的含量及其变化与向日葵的顶端优势无关。     

Cytokinin/Auxin Control of Apical Dominance in Ipomoea nil

Although the concept of apical dominance control by the ratioof cytokinin to auxin is not new, recent experimentation withtransgenic plants has given this concept renewed attention.In the present study, it has been demonstrated that cytokinintreatments can partially reverse the inhibitory effect of auxinon lateral bud outgrowth in intact shoots of Ipomoea nil. Althoughless conclusive, this also appeared to occur in buds of isolatednodes. Auxin inhibited lateral bud outgrowth when applied eitherto the top of the stump of the decapitated shoot or directlyto the bud itself. However, the fact that cytokinin promotiveeffects on bud outgrowth are known to occur when cytokinin isapplied directly to the bud suggests different transport tissuesand/or sites of action for the two hormones. Cytokinin antagonistswere shown in some experiments to have a synergistic effectwith benzyladenine on the promotion of bud outgrowth. If theratio of cytokinin to auxin does control apical dominance, thenthe next critical question is how do these hormones interactin this correlative process? The hypothesis that shoot-derivedauxin inhibits lateral bud outgrowth indirectly by depletingcytokinin content in the shoots via inhibition of its productionin the roots was not supported in the present study which demonstratedthat the repressibility of lateral bud outgrowth by auxin treatmentsat various positions on the shoot was not correlated with proximityto the roots but rather with proximity to the buds. Resultsalso suggested that auxin in subtending mature leaves as wellas that in the shoot apex and adjacent small leaves may contributeto the apical dominance of a shoot. (Received September 24, 1996; Accepted March 16, 1997)     

植物的顶端优势和水分上升机理新说

植物体有一个能量系统,由植物顶端、由植物顶端、形成层及其初生韧皮部和木质部、传递细胞等组成。这些细胞含线粒体量多质好,摘顶等刺激这些地方ＡＴＰ复合酶能产生大量能量,通过胞间连丝引起连锁反应并刺激和激活激素、营养物质等而产生生命活动、项端优势等。植物细胞的原生质是一种液晶,只需极少能量便能产生很大的作用。除去顶芽,刺激线粒体能产生大量能量供给侧芽,激活侧芽激素等而使侧芽生长,由于能量作功,逐渐减少,     

Anticytokinin Effect on Apical Dominance Release in in vitro Cultured Rosa Hybrida L.

Effects of two cytokinin antagonists - 2-chloro-4-cyclobutyl-amino-6-ethylamino-1,3,5-triazine and N-(4-pyridyl)-O-(4-chlorophenyl)carbamate - on bud break and outgrowth in single nodes from two Rosa hybrida cultivars differing in their apical dominance were studied. The compounds were applied at three different concentrations separately or in combination with benzyladenine. Cytokinin antagonists reduced the number of the sprouted buds in both cultivars at different extent. Their effect was strongly dependent on both concentration applied and culture period duration. The replacement of anticytokinins with benzyladenine in the medium resulted in overcoming of the bud break suppression. Both compounds significantly inhibited bud outgrowth as well.     

Endogenous Cytokinins and the Breaking of Dormancy and Apical Dominance in Potato Tubers

Cytokinins are present in all parts of potato tubers, and areequally distributed between the apical, lateral, and internodaltissue when dormant. However, the breaking of dormancy coincidedwith a rapid increase in the free base cytokinin levels in theapical buds and the tissue adjacent to it. These high levelsof cytokinin in the apical tissue were maintained while apicaldominance was displayed. Once apical dominance was overcomethe cytokinin levels in the lateral buds and the tissue adjacentto them were similar to the levels in the apical regions. Thepresent evidence suggests that cytokinin glucosides are transportedto the meristematic regions of the tubers where they are hydrolysedto their free bases. Amounts of free bases in excess of thoserequired for growth are apparently again converted to storageforms (particularly zeatin glucoside) in the meristematic regionsof the tubers and in the sprouts.     

Light and Hormone Interaction in Apical Dominance in Phaseolus vulgaris L.

Gibberellic acid (GA₂), kinetin, and indole-3yl-acetic acid(IAA) each at four concentrations (0, 0.5, 5, and 50 µM)were applied alone and in all possible combinations to rootsof Phaseolus vulgaris L. grown under four different light regimes(7000, 14 000, 21 000, and 28 000 lx). GA₃ increased growthof main stem and laterals but reduced apical dominance, especiallyin the absence of, or at low kinetin concentrations. A highlevel of kinetin lowered GA₃ induced growth of main stems and,to a lesser extent, laterals. Kinetin greatly reduced apicaldominance, especially in the absence of, or at low GA₃ concentrations.IAA slightly reduced growth of main stems and laterals and slightlyincreased apical dominance. Generally the magnitude of the IAAeffects were less than those of GA₃ or kinetin and there wereless interaction between IAA and other factors than betweenGA₃ or kinetin and other factors. Light affected growth of bothmain stem and laterals but the effect was dependent on GA₃ andkinetin levels and the interactions were complex. Generallya hormone balance seems to be operative with gibberellin-promotinggrowth of main stem and laterals and cytokinins and possiblyauxins preventing excessive elongation. Differential responsesbetween main stem and lateral may be due to different localhormone concentrations and over-all responses may be temperedby light intensity.