Axillary bud outgrowth potential is determined by parent apical bud activity

Localized bursting of mesocarp cells triggers catastrophic fruit cracking

The so-called rain-cracking of sweet cherry fruit severely threatens commercial production. Simple observation tells us that cuticular microcracking (invisible) always precedes skin macrocracking (visible). The objective here was to investigate how a macrocrack develops. Incubating detached sweet cherry fruit in deionized water induces microcracking. Incubating fruit in D₂O and concurrent magnetic resonance imaging demonstrates that water penetration occurs only (principally) through the microcracks, with nondetectable amounts penetrating the intact cuticle. Optical coherence tomography of detached, whole fruit incubated in deionized water, allowed generation of virtual cross-sections through the zone of a developing macrocrack. Outer mesocarp cell volume increased before macrocracks developed but increased at a markedly higher rate thereafter. Little change in mesocarp cell volume occurred in a control zone distant from the crack. As water incubation continued, the cell volume in the crack zone decreased, indicating leaking/bursting of individual mesocarp cells. As incubation continued still longer, the crack propagated between cells both to form a long, deep macrocrack. Outer mesocarp cell turgor did not differ significantly before and after incubation between fruit with or without macrocracks; nor between cells within the crack zone and those in a control zone distant from the macrocrack. The cumulative frequency distribution of the log-transformed turgor pressure of a population of outer mesocarp cells reveals all cell turgor data followed a normal distribution. The results demonstrate that microcracks develop into macrocracks following the volume increase of a few outer mesocarp cells and is soon accompanied by cell bursting.

Shoot branching in response to nodal roots is mimicked by application of exogenous cytokinin in Trifolium repens

In nodally-rooting prostrate herbs the outgrowth of shoot axillary buds is highly influenced by the supply of a branch-promoting signal exported from nodal roots to the shoot. The aim of this study was to establish whether cytokinin could be a candidate for the positive component within this net root stimulus (NRS). The approach taken was based on the notion that should cytokinin be the activating signal, then the effects on bud outgrowth induced by exogenous supply of cytokinin (6-benzylaminopurine (BAP)) to plants should largely mimic the responses observed when experimental manipulations alter intra-plant supply of NRS. In Trifolium repens experimental results consistently indicated that supply of BAP into the stem vasculature induced responses mimicking those induced by manipulation of NRS supply: it induced the outgrowth of a similar number of distal axillary buds, activated buds to a similar extent, had similar properties of transport along stems, induced a similar dose dependent response in distal buds and also had the ability to induce bud outgrowth in P-deficient plants. These findings indicate a requirement for further detailed hormonal analytical work to confirm this result and identify the nature of the cytokinin(s) involved in the NRS signalling pathway.

Shoot branching in nutrient-limited Trifolium repens is primarily restricted by shortage of root-derived promoter signals

Two experiments were used to test the hypothesis that regulation of axillary bud outgrowth in nutrient-limited Trifolium repens L. (white clover) is primarily via variation in the net supply of root-derived promoter signal rather than via direct nutrient effects or inhibitory influences from apical or basal tissues. In the first experiment, foliar nutrient applications to a non-rooted portion of a nutrient-limited stem increased nutrient content, size of organs and rate of growth in the treated region but branch development remained suppressed, indicating that nutrient supply does not directly regulate branching. The second experiment, using decapitation and basal branch excision treatments, showed that excision of basal branches had a major stimulatory effect on bud outgrowth whereas decapitation of the primary stem had only a minor effect. This indicates dominant and minor roles in branching regulation for, respectively, root-derived promoter signal(s) and inhibitory apical influences (apical dominance), and that any possible influence of the inhibitory strigolactone pathway on bud outgrowth is captured within the net root-derived promoter influence. Thus, the proposed hypothesis was supported by our results. These findings may be relevant for all species within the group of prostrate nodally-rooting clonal herbs.

Differential bud activation by a net positive root signal explains branching phenotype in prostrate clonal herbs: a model

Regulation of branching within perennial prostrate clonal herbs differs from the annual orthotropic species, Arabidopsis and pea, as the dominant signal transported from roots is a branching promoter, not an inhibitor. Trifolium repens, an exemplar of such prostrate species, was used to investigate the interaction between roots and branch development. This study tests whether or not current knowledge when synthesized into a predictive model is sufficient to simulate the branching pattern developing on the shoot distal to a basal root. The major concepts underpinning the model are: (i) bud outgrowth (activation) is stimulated in a dose-dependent manner by branching promoter signals from roots, (ii) the distribution of this net root stimulus (NRS) is uniform throughout the shoot system distal to the basal root but declines geometrically in intensity upon continued enlargement of this shoot system, and (iii) each bud has an outgrowth potential, equal to the activation level of the apical bud in which it forms, that moderates its response to NRS. The validity of these concepts was further tested by running simulations of the branching of a phylogenetically-distanced prostrate perennial monocotyledonous species, Tradescantia fluminensis. For both species the model reasonably accounted for the observed pattern of branching. The outgrowth potential of buds plays an important role in limiting the number of hierarchies of branching that can develop on a plant. In conclusion, for both species, the model accounted for the major factors involved in the correlative regulation of branching and is possibly also pertinent for all prostrate clonal species.

Existing branches correlatively inhibit further branching in Trifolium repens: possible mechanisms

In Trifolium repens removal of any number of existing branches distal to a nodal root stimulates development of axillary buds further along the stem such that the complement of branches distal to a nodal root remains constant. This study aimed to assess possible mechanisms by which existing branches correlatively inhibit the outgrowth of axillary buds distal to them. Treatments were applied to basal branches to evaluate the roles of three postulated inhibitory mechanisms: (I) the transport of a phloem-mobile inhibitory feedback signal from branches into the main stem; (II) the polar flow of auxin from branches into the main stem acting to limit further branch development; or (III) the basal branches functioning as sinks for a net root-derived stimulatory signal (NRS). Results showed that transport of auxin, or of a non-auxin phloem-mobile signal, from basal branches did not influence regulation of correlative inhibition and were consistent with the possibility that the intra-plant distribution of NRS could be involved in the correlative inhibition of distal buds by basal branches. This study supports existing evidence that regulation of branching in T. repens is dominated by a root-derived stimulatory signal, initially distributed via the xylem, the characterization of which will progress the generic understanding of branching regulation.