ANATOMY OF NODES VS. INTERNODES IN COLEUS: THE NODAL CAMBIUM

Secondary growth begins in the nodal regions before the internodal regions in Coleus, so that longitudinally discontinuous vascular cambia are formed in the 6th through the 9th or 10th nodes, where the internodal cambium becomes continuous between nodal cambia. The nodal cambia are identifiable by radial seriation in interfascicular regions, typical cytology of fusiform initials, and the presence of a ray system. Anatomical features distinct from the primary plant body are shared by the nodal and internodal cambia. Branching of primary vascular strands, restricted to procambium and phloem, is virtually confined to nodal regions. In secondary growth, vascular branching of xylem and phloem occurs in both nodes and internodes. Xylem strand branches are formed only from derivatives of vascular cambia. It is proposed that the cambium provides the secondary plant body an efficient channel for lateral auxin transport, by which branching across interfascicular regions is facilitated.     

Clonal analysis of corn plant development

The formation of the lower nodes and internodes in maize (Zea mays L.) and the progression of their differentiation was investigated by generating clonal sectors from cells of the apical meristem. Marked clones were induced by irradiating dry seeds (kernels) and 2-, 8- and 13-day-old seedlings heterozygous for anthocyanin markers (b, pl) and a chlorophyll factor (wd). The extent and apparent number of cells generating the internodes 2–6, which normally remain condensed, were traced by promoting the elongation of these internodes with gibberellic acid. At the mature seed stage, internodes 2 and 3 are undergoing longitudinal expansion and each is represented by two or three circumferential populations of cells. Internodes 4 and 5 are in the process of radial expansion and each is represented by a single circumferential population of cells. At nodes 2–4, the cells for leaves and internodes have separated but such a separation has not occurred for nodes 5 and 6. The formation and expansion of basal six internodes progressed acropetally, i.e. from the base toward distal nodes. Analysis of sectors induced at the seedling stage shows that the formation of middle and top internodes also progress acropetally. The basal, middle and top internodes were found to develop at different apparent cell numbers in the apical meristem.     

Auxin Concentrations in Nodes and Internodes ofImpatiens sultani

Greater concentrations of auxin at nodes than in internodes,resulting from some nodal barrier to basipetal transport, havelong been postulated as the cause of early differentiation ofinitially isolated xylem and cambium at the nodes. However,this study, using [¹⁴C] indole-3-acetic acid (IAA) applied apicallyand gas chromatography-mass spectrometry, found that in stemsofImpatiens sultanithe IAA concentrations (per unit f. wt) atnodes were similar to those in adjacent internodes, though alittle greater at nodes if expressed per unit length of stemand a little less per unit d. wt. By contrast, in decapitatedshoots and in stem explants of dicotyledons, loss of the apicalsource of basipetally flowing auxin can result in auxin drainagewith some auxin retention in the uppermost remaining nodes.When [¹⁴C]IAA was applied apically to shoots for 4 h and stemexplants were excised, the explants had no nodal accumulationinitially whereas comparable explants incubated for 20 h revealedsignificant nodal accumulation. If decapitation leads both tonodal auxin accumulation and to adventitious abscission justabove the node, this fits the hypothesis that abscission sitesare positioned where auxin concentration decreases locally inthe apical direction. Difficulties in quantifying nodal auxindynamics are discussed, and some crude estimates of metabolicrates and locations of the auxin are presented.Copyright 1999Annals of Botany Company Abscission, auxin,Impatiens sultani, indole-3-acetic acid, node.     

Immunolocalisation of the cytoskeleton to plasmodesmata of Chara corallina

The macromolecular structure of plasmodesmata in the giant celled freshwater alga, Chara corallina, was examined using antibodies against cytoskeletal elements. The large internodal cells of Chara are separated by a nodal complex of smaller cells which are interconnected by plasmodesmata. Putative plasmodesmata-associated proteins can be identified by a comparison of proteins extracted from preparations of clean walls of nodal complexes and those extracted from the external walls of internodal cells which have no plasmodesmata. Actin and tubulin were identified in the protein extracts of nodal walls and the cytoplasm of nodes and internodes but not in the extracts of internodal external walls. Immunogold labelling confirmed the localisation of actin and myosin to plasmodesmata of Chara.     

Studies on mechano-perception in the Characeae: transduction of pressure signals into electrical signals

Mechano-perception by Chara cells was studied with an emphasis on the role of the nodal complex in transducing pressure signals into electrical signals. Three types of experimental material were used: (1) tandem internodal cells connected by a single layer of nodal cells; (2) single internodal cells, from which either apical or basal nodes were removed by ligation and cutting; (3) single internodes from which both nodes had been removed. Exposure to a hypertonic solution (sorbitol or sucrose) induced a depolarization at the node in 1 and 2. Depolarization did not occur at the ligated end of the cell in 2, or at all in 3. Addition of K+ increased the magnitude of the response, whilst it was significantly decreased by the divalent cations, Ca2+ and Mg2+. Electrical resistance decreased at the node during the depolarization, showing that a passive diffusion potential was responsible. I suggest that the change in the trans-nodal hydraulic pressure difference mechanically stretches the plasma membrane, and this induces the electrical depolarization.     

Adaptive variation in physiological traits underpinning stem elongation responses among nodally-rooting stoloniferous herbs

For nodally-rooting stoloniferous herbs a close physiological link exists between the growth of nodal roots and development of shoot tissues of phytomers distal to them. Furthermore, in Trifolium, presence of nodal roots at phytomers proximal to the youngest nodal root on a stem influences the allocation of carbon along the stem when that stem encounters a patch preventing further formation of nodal roots. In this study six further phylogenetically and morphologically diverse stoloniferous species, selected so that they varied along the phalanx–guerrilla continuum (Acaena (Rosaceae), Leptinella (Asteraceae), Mentha (Lamiaceae), Vinca (Apocynaceae), Lamiastrum (Lamiaceae) and Glechoma (Lamiaceae)), were used to test the null hypothesis: that in all stoloniferous species the proportional allocation of carbon to the youngest nodal root decreases if proximally located roots are present when their stems extend into an environment preventing further nodal rooting. As Glechoma and Lamiastrum failed to change their proportional allocation to the youngest nodal root whilst the other five species varied their proportional allocation, with the species with shortest internodes (Acaena and Leptinella) changing the most, we reject this hypothesis. In addition, upon the transition to a dry environment, internode lengths in species with longer internodes (Glechoma and Lamiastrum) were markedly increased (doubled) whilst those in species with shorter internodes showed no response. We suggest this response is driven by apical bud tissues sensing changes in the humidity of their micro-environment and then modifying the length of internodes developing proximal to them. The extent of both these physiological responses correlated linearly with internode length of species (or position along the phalanx–guerrilla continuum), suggesting that these three traits were co-evolving, possibly in response to variation in grain of environmental heterogeneity, in such a way that the trade-off between the explorative and exploitive components of growth was underpinned and the performance of species in particular niches optimised as a result.     

Chemodifferentiation of diosgenin in Dioscorea composita

Diosgenin was isolated from different parts of a three-year-old plant of Dioscorea composite. The amounts (% on a dry wt basis) present were: tubers, 3.6; vine internodes and nodes with their leaves from first 20 nodes from the tubers, 1.6; similarly from intermediate 20 nodes, 0.039 and from upper 20 nodes, 0.03. The amounts (% on a dry wt basis) from tissue culture of nodal explants were: 30-day-old callus, 0.89; 90-day-old callus, 1.61; emergent shoots, 2.5; regenerated roots, 0.08.     

Expression of several genes encoding chaperone proteins in response to mechanical perturbation inBryonia dioica internodes

Mechanical stress exerted on youngBryonia dioica internodes which resulted in reduced elongation and increased radial expansion induced a rapid and transient increase in specific mRNAs. Hybridizations were performed using ubiquitin, cyclophilin and heat-shock protein cDNAs as probes on RNA extracted at successive time intervals in control and rubbed internodes. Changes in ubiquitin and cyclophilin were rapidly enhanced after mechanical perturbation. Levels of mRNAs reached a maximum 0.5 h and 1.5 h after rubbing and then decreased. The heat shock protein gene was constitutively expressed; it was however slightly stimulated following the rubbing treatment. All the three genes encoded for molecular chaperones and they were regulated in response to environmental stimuli. The role of chaperones was discussed with regard to the plant response to several natural stresses.     

Transduction of pressure signal to electrical signal upon sudden increase in turgor pressure in Chara corallina

By taking advantage of large cell size of Chara corallina, we analyzed the membrane depolarization induced by decreased turgor pressure (Shimmen in J Plant Res 124:639–644, 2011). In the present study, the response to increased turgor pressure was analyzed. When internodes were incubated in media containing 200 mM dimethyl sulfoxide, their intracellular osmolality gradually increased and reached a steady level after about 3 h. Upon removal of dimethyl sulfoxide, turgor pressure quickly increased. In response to the increase in turgor pressure, the internodes generated a transient membrane depolarization at its nodal end. The refractory period was very long and it took about 2 h for full recovery after the depolarizing response. Involvement of protein synthesis in recovery from refractoriness was suggested, based on experiments using inhibitors.     

Effects of light and low temperature on the reciprocal style curvature of Flexistylous Alpinia Species (Zingiberaceae)

The style curvature (flexistyly) of Alpinia species in ginger family is a unique plant organ movement because the style of each flower curves twice during its 1-day anthesis and styles of two phenotypes of each Alpinia species in the same population synchronously curve in opposite directions at the same time. In this study, we investigated the effects of low temperature and light conditions on these reciprocal style movements. Our results indicate that low temperature cannot change the direction of each curvature movement, but can slow down these movements and decrease the curve degrees. Light did not affect the upward curvature of the cataflexistylous morph, but the degrees of downward curvature decreased in darkness. For the anaflexistylous morph, the downward curvature only occurred in darkness, but curved directly upward in light condition; after the first (downward) curvature, the second (upward) movement only occurred in light, but did not occur if styles maintained in darkness. These results suggest that low temperature does not stimulate style curvature; light is the necessary condition for the upward movement of the anaflexistylous morph. The stimuli that induced curvature movements in the two morphs were different. Both two curvatures of the cataflexistylous style and downward movement of the anaflexistylous style were controlled via an endogenous program, while the upward movement of the anaflexistylous style was controlled by light.     

Induction and expression of peroxidase in tomato is age-dependent

Peroxidases (POXs) are actively synthesised under stress conditions and induced by biotic/abiotic elicitors. Their age-regulated expression in plants has been a matter of investigation during recent times. The present study focuses on studying the expression of POX at different stages of growth and variation in its inducibility by aqueous extract of Azadirachta indica (neem) fruits. Tomato plants at 6, 8, 10 and 12 weeks were chosen for the study. The third nodal leaf of each plant was treated with neem fruit extract alone or in combination with Pseudomonas syringae pv. tomato. Sampling was performed at an interval of 24 h up to five days and after two weeks of treatment, from both the treated and distal untreated nodes of the plants. POX activity and its isoforms were analysed. The results demonstrated that POX expression and its inducibility by the biotic inducer (neem fruit extract) varies with age of the plant.     

Impacts of environmental factors on the climbing behaviors of herbaceous stem‐twiners

The curvature of the helical trajectory formed by herbaceous stem‐twiners has been hypothesized to be constant on uniformly sized cylindrical supports and remains constant on different supports varying in diameter. However, experimental studies on the constant curvature hypothesis have been very limited. Here, we tested the hypothesis in a series of experiments on five herbaceous stem‐twiners (Ipomoea triloba, Ipomoea nil, Phaseolus vulgaris, Vigna unguiculata, and Mikania micrantha). We investigated how internode characteristics (curvature [β], diameter [d], and length [L]) and success rate (SR) of twining shoots would be affected by support thickness (D), temperature (T), illumination, and support inclination. The results showed that: (1) the SR of tested species decreased, but d increased with increasing support thickness. The β of the twining shoots on erect cylindrical poles was not constant, but it decreased with increasing d or support thickness. (2) The SR of tested species was not obviously reduced under low‐temperature conditions, but their β was significantly higher and d significantly lower when temperature was more than 5°C lower. (3) The SR, d, and L of two tested Ipomoea species significantly declined, but β increased under 50% shading stress. (4) The curvatures of upper semicycles of I. triloba shoots on 45° inclined supports were not significantly different from curvatures of those shoots climb on erect supports, whereas the curvatures of lower semicycles were 40%–72% higher than curvatures of upper semicycles. Synthesis: Our study illustrates that stem curvatures of a certain herbaceous stem‐twiners are not constant, but rather vary in response to external support, temperature, and illumination conditions. We speculate that herbaceous stem‐twiners positively adapt to wide‐diameter supports by thickening their stems and by reducing their twining curvatures. This insight helps us better understand climbing processes and dynamics of stem‐twiners in forest communities and ecosystems.     

Modes of Mechanical Failure of Hollow, Septate Stems

Three general modes of mechanical failure were observed whenhollow, septate stem segments ofArundinaria técta(Poaceae)were axially compressed and caused to fail: (1) rupture of tissuesat the opposing ends of the nodal transverse diaphragm parallelto the plane of stem flexure; (2) localized catastrophic transverseinvagination of internodes (Brazier buckling); and (3) longitudinalrupture of internodal walls along the convex surface of stemflexure attended by nodal tissue shearing. The frequencies ofoccurrence of these three modes were not equivalent among the100 stem segments examined; stem failure was dominated by nodaltissue shearing (i.e. 67% of the nodes failed by shearing; 52%of the internodes longitudinally invaginated; 27% of the internodesfailed in Brazier buckling; 21% of the internodes failed byrupturing). Computer simulations of axially compressed stemsegments consisting of one node and one internode composed ofnon-linearly elastic, anisotropic materials (tissues) successfullypredicted observed strain patterns and revealed that the pathwayto stem failure contains a bifurcation point below which deformationpatterns coalesce on a single configuration, and above whichstem failure by Brazier buckling or nodal tissue shearing areessentially mutually exclusive responses to excessive stem flexure.The patterns of actual and simulated stem flexure were consistentwith the hypothesis that nodes store strain energy as stemsflex, and release this energy to restore stem shape when bendingforces abate (i.e. nodes operate as spring-like joints). However,strain energy ‘sinks’ identified by simulationswere also located in bending internodal walls which can storeelastic strain energy to do work. Nodal diaphragms and internodalwalls likely comprise a complex and global rather than a simpleand local elastic system for the recovery of stem shape.Copyright1998 Annals of Botany Company Stem flexure; mechanical failure; stem nodes; internodes; plants; biomechanics; finite element analyses; Brazier buckling.     

Thigmomorphogenesis: Evidence for a translocatable thigmomorphogenetic factor induced by mechanical perturbation of beans (Phaseolus vulgaris)

Mechanical perturbation of bean (Phaseolus vulgaris L.) internodes results in reduced elongation and increased diameter of the internodes (thigmomorphogenesis). Perturbation of a single lower internode results in thigmorphogenesis in that internode and all of those internodes above it, the degree of which depends on the age (size) of the internodes and the frequency of perturbation. Application of ethephon to the internodes mimics mechanical perturbation. Early removal of the shoot tip or the cotyledons does not effect thigmomorphogenesis, indicating that those organs do not exert control over the response. Mechanical perturbation of one plant of a pair grafted together at the first internodes results in thigmomorphogenesis in both plants. This indicates the transport of some factor from the mechanically perturbed donor to the non-treated receiver. Evidence is presented to support the contention that ethylene is not this transportable factor.     

Effects of ACC (1-aminocyclopropane-1-carboxylic acid) applied through the roots of maize seedlings on vegetative and early reproductive development of the shoots

Maize plants, grown in aerated solution cultures, were exposed, at different growth stages, to ACC (1-aminocyclopropane-1-carboxylic acid) applied through the roots for up to 9 d. Total uptake of ACC increased with seedling size. During ACC treatment, ethylene evolution, by the shoots, proceeded at an almost constant rate per unit fresh weight that was up to 40-fold faster than that of untreated plants. This stimulation extended several days beyond the period of ACC uptake. The effects on growth and development were assessed when plants were 50–52-d old. ACC application shortened certain stem internodes, leaf-sheaths and laminae. The location of these effects depended on the time of application. The greatest shortening was induced by application, at the 4-leaf stage (10 d-old), prior to elongation of the cone of the shoot apex. This is ascribed to effects on meristematic tissue, in addition to those on elongating cells. An unexpected response to ACC treatment, at the 4-leaf stage, was an increase of up to four leaf-bearing stem nodes compared to untreated plants. This resulted in a parallel elevation of the uppermost ear-bearing axillary shoot to higher nodal positions. The length of leaves high in the canopy (nodes 11–16) was promoted by treating seedlings with ACC. The only clear effect of the ACC treatments on emergent axillary shoots per se was a retardation of silk elongation.     

The influence of season on adenine nucleotide concentrations and energy charge in four marsh plant species

Unilateral pulse ultraviolet irradiation caused positively phototropic coiling (> 180°) and curvature (≤ 180°) in the growth zone of dark-grown broom sorghum ( Sorghum bicolor Moench, cv. Acme Broomcorn and Sekishokuzairai Fukuyama) first internodes. Coiling was induced by irradiation at 257 to 302 nm, and proceeded to develop almost linearly during 72 h or more involving new tissue produced after irradiation. Curvature, caused at 308 to 413 nm and by red light, developed rapidly during the first several hours then slowly to cease by about 24 h, and did not surpass 120° even at the optimum photon fluences. Action spectra were higher towards shorter wavelengths, having a shoulder at about 287 nm, and could not separate the two photoresponses. The curvature was partially but markedly suppressed by far-red following the ultraviolet irradiation, whereas the coiling was not affected. Possible involvement of a specific UV-B photoreceptor and phytochrome in curvature and of a UV-C photoreceptor in coiling is discussed.     

Correlations between proton-efflux patterns and growth patterns during geotropism and phototropism in maize and sunflower

By placing seedlings of sunflower (Helianthus annuus L.) or maize (Zea mays L.) on agar plates containing a pH indicator dye it is possible to observe surface pH patterns along the growing seedling by observing color changes of the indicator dye. Using this method we find that in geotropically stimulated sunflower hypocotyls or maize coleoptiles there is enhanced proton efflux on the lower surface of the organ prior to the initiation of curvature. As curvature develops the pattern of differential acid efflux becomes more intense. A similar phenomenon is observed when these organs are exposed to unilateral illumination, i.e. enhanced acid efflux occurs on the dark side of the organ prior to the initiation of phototropic curvature and the pattern of differential acid efflux intensifies as phototropic curvature develops. These observations indicate that differential acid efflux occurs in response to tropistic stimuli and that the acid efflux pattern may mediate the development of tropistic curvatures.     

Shoot atmospheric contact is of little importance to aeration of deeper portions of the wetland plant Meionectes brownii; submerged organs mainly acquire O2 from the water column or produce it endogenously in underwater photosynthesis

Partial shoot submergence is considered less stressful than complete submergence of plants, as aerial contact allows gas exchange with the atmosphere. In situ microelectrode studies of the wetland plant Meionectes brownii showed that O₂ dynamics in the submerged stems and aquatic roots of partially submerged plants were similar to those of completely submerged plants, with internal O₂ concentrations in both organs dropping to less than 5 kPa by dawn regardless of submergence level. The anatomy at the nodes and the relationship between tissue porosity and rates of O₂ diffusion through stems were studied. Stem internodes contained aerenchyma and had mean gas space area of 17.7% per cross section, whereas nodes had 8.2%, but nodal porosity was highly variable, some nodes had very low porosity or were completely occluded (ca. 23% of nodes sampled). The cumulative effect of these low porosity nodes would have impeded internal O₂ movement down stems. Therefore, regardless of the presence of an aerial connection, the deeper portions of submerged organs sourced most of their O₂ via inwards diffusion from the water column during the night, and endogenous production in underwater photosynthesis during the daytime.     

Interconversion of free sugars in relation to activities of enzymes catalyzing synthesis and cleavage of sucrose in growing stem tissues of sorghum

Free sugar interconversion and activities of soluble acidic (pH 4.8) and neutral (pH 7.5) invertases, sucrose synthase (synthesis) and sucrose phosphate synthase were investigated in the growing nodes and internodes of sorghum (Sorghum vulgare). The results were substantiated with incorporation of 14C from supplied sucrose and hexoses into endogenous sugars of these stem tissues. With the advancement in plant growth, the content of total free sugars in apical nodes and internodes increased till 70 DAS (flowering stage) followed by a decline. In the corresponding basal tissues, the sugar build-up continued even beyond this stage of plant growth. Compared with basal stem tissues, the apical ones contained high activities of soluble invertases and a low proportion amongst free sugars of sucrose. The activities of sucrose-hydrolyzing enzymes were higher as compared with those of sucrose-synthesizing ones in both nodes and internodes and with the growth of plant, the activity of neutral invertase increased in these tissues. More 14C from supplied sucrose and hexoses appeared in extracted sugars from cut discs of apical nodes and internodes in comparison with their basal counterparts. 14C from supplied sucrose appeared in glucose, fructose and from supplied hexoses appeared in sucrose. The results suggest that in apical nodes and internodes, where a rapid cell division and cell expansion occur, sucrose is obligatorily inverted to meet the increased requirement of hexoses and there is a compartmentalized synthesis and cleavage of sucrose in the nodes and internodes of growing sorghum plant.