Establishment, Structure and Morphology of the Tuber of Balanophora

During germination of the ‘seed’ of Balanophora,endosperm cells at the radicular pole grow out as tubular structuresand anchor the ‘seed’ to the host rootlet. The radiculartier of cells of the embryo elongate as primary haustorial tubesand establish contact with the host root vasculature. A secondaryhaustorium arises from a meristem adjoining the primary haustorium.The remainder of the embryo contributes to the tuber proper. Host parenchyma in the immediate vicinity of the primary haustoriumreverts to meristematic activity. Some of the derivatives matureas perforate tracheary cells. The remainder, retaining meristematicactivity, squeeze themselves between secondary haustorial cellsand together initiate a composite conducting strand, which repeatedlydichotomizes as the tuber grows. The conducting strand of Balanophora is looked upon as the equivalentof combined adventitious root system of parasite and host. Theremaining part of the tuber is equivalent to the shoot. Balanophora, tuber, morphology, host-parasite relations, parasite     

Interactions Between Physical and Biological Constraints in the Structure of the Inflorescences of the Araceae

A study of the inflorescences ofMonsteraandAnthuriumwas usedto establish a relationship between biological and physicalconstraints for the structure of plant organs. The physicalconstraint between flowers in the compact inflorescences ofAnthuriumandMonsteraisexpressed by Aboav-Weaire's law. The application of this lawto inflorescences indicates a linear relationship between thenumber of sides of a flower and the number of sides of neighbouringflowers. However, the slope of this straight line is significantlyhigher forAnthuriumandMonsterathan that expected in theory.This deviation from the law is attributable to a biologicalcause that can be estimated using Aboav-Weaire's law. Actingalone, the biological constraint tends to produce four-sidedflowers. The equilibrium between biological and physical constraintsreduces the number of sides per flower from six (theoreticalvalue) to 5.9 (inAnthurium) or 5.8 (inMonstera) with a varianceof the measures less than that expected in theory. Furthermore,when flower density in an inflorescence increases (towards themiddle of the inflorescence inMonsteraand towards the lowersection forAnthurium) the number of sides approaches six (i.e.the physical constraint dominates). When flower density decreases(towards the top of the inflorescence) the number of sides approaches5.5 (i.e. the biological constraint dominates). The geometryof the inflorescences ofAnthuriumandMonsterais the result ofthe joint action of biological and physical constraints.Copyright1998 Annals of Botany Company Monstera,Anthurium, Araceae, Aboav-Weaire, inflorescence, constraint, flower.     

Pithiness and Growth of Radish Tubers as Affected by Irradiance and Plant Density

Pithiness in radish tubers (Raphanus sativus L.) is a syndromewhere xylem parenchyma cells die and are filled with air. Featuresassociated with rapid tuber growth such as large cells, greatdistances between strands of vascular tissue and rupture ofxylem vessels have been suggested to induce pithiness. The objectiveof this study was to analyse the extent to which pithiness inradish was related to tuber growth. Growth rates were variedby altering irradiance and plant density. In addition, the relationshipbetween pithiness and tuber growth (length, diameter, freshmass) was investigated in batches of plants grown under identicalconditions. The growth rates of shoot and tuber strongly increased withincreasing inter-plant distance and irradiance. Our resultssuggest a ‘true’ effect of assimilate supply ondry matter partitioning, as not only the ratio between shootand root dry mass, but also the slope of this relationship decreasedwith increasing irradiance and inter-plant distance. Withina treatment the ratio between tuber growth and shoot growthremained constant with plant age. Increase in length of thetuber did not appear to be an important factor in inducing pithiness.Within a batch of plants, a positive correlation between tuberdiameter and pithiness was observed only for tubers smallerthan 14 mm. An increase in both irradiance and inter-plant distanceincreased tuber size (diameter, mass) and pithiness, but theeffects on pithiness could not be ascribed only to differenttuber sizes. Pithiness strongly increased with plant age andit was concluded that pithiness occurred, to a great extent,according to genetic programming. The data showed that for treatmentswhich affect tuber growth, conclusions about their effects onpithiness depend on whether comparisons were made at the sametuber size or the same time, explaining apparent contradictionsin the literature. Raphanus sativus L.; radish; pithiness; genetic programming; cell death; light; plant density; growth rate; dry matter partitioning; shoot; tuber     

Water Deficit and Inflorescence Development in Zea mays L.--The Role of the Developing Tassel

In the normal pattern of development of Zea mays (cv. Iochief)a single mature female inflorescence is produced at node 7.A brief episode of water deficit at the time of terminal maleinflorescence initiation induced the subsequent developmentof two to three mature female inflorescences at nodes 5–7.This growth of the inflorescences at lower nodes was accompaniedby a marked inhibition of the growth of the terminal male inflorescence.Removal of either the developing terminal inflorescence or ofthe axillary inflorescence at node 7 at this time also promotedthe growth of the lower axillary inflorescences. The growthof these inflorescences was further stimulated by a period ofwater deficit when only the inflorescence at node 7 was removed,but removal of the male inflorescence abolished the capacityof these inflorescences to respond to the water deficit Excisionof the male inflorescence immediately before or immediatelyafter the period of water deficit produced the same response.It is concluded that this response of the lower axillary inflorescencesto water deficit is mediated through an effect on the developingterminal male inflorescence. Zea mays, water deficit, inflorescence development, tassel, correlative inhibition     

Interrelation Between Growth Rate of Individual Potato (Solanum tuberosum L.) Tubers and Their Cell Number

In potato plants fast and slow growing tubers develop on thesame plant. A hypothetical causality between tuber growth rateand tuber cell number was investigated by determining the tubercell number with the aid of an automatic counting procedure.Our data show a close correlation between tuber size and cellnumber over the whole range of tuber volumes considered (3–28cm³). If the influence of tuber size on cell number is eliminatedby means of a partial correlation analysis, the cell numberof the entire tuber is not significantly correlated with itsgrowth rate. An exclusive consideration of the smaller cells(10–30 µm) in the apical tuber region, where thecell division rate in potato tubers is highest, reveals a loosebut significant partial correlation to tuber growth rate (r= 0.383, P < 0.05). The growth rate of the slow growing tubers of any potato plantmay be enhanced by removing the fast growing tubers. In thefirst few days this enhanced growth rate is not due to a stimulationof cell division rate, but rather due to cell expansion. Potato, Solanum tuberosum L., tuber growth rate, tuber cell number     

Assimilation of 14CO2 by the Inflorescence of Poa annua L. and Lolium perenne L.

The relative assimilatory activity of the inflorescence, itsindividual components, and the leaves of flowering tillers ofPoa annua L. and Lolium perenneL. was determined over the periodfrom inflorescence emergence to seed shedding. The pattern of¹⁴CO₂ fixation was similar for both species and the inflorescencewas by far the most important assimilatory organ of the reproductivetiller, particularly over the latter period of seed developmentas leaf senescence progressed. With the exception of the seedsall parts of the inflorescence showed significant assimilatoryactivity and the lemmas and paleas accounted for 40–50per cent of the total ¹⁴C fixed by the inflorescence in bothspecies. The importance of the grass inflorescence as a photosyntheticstructure is discussed in relation to similar studies on cereals. Poa annua, Lolium perenne, carbon dioxide assimilation, inflorescence     

ATP Sulphurylase and O-Acetylserine Sulphydrylase in Isolated Mesophyll Protoplasts and Bundle Sheath Strands of S-deprived Maize Leaves

In Zea mays L. (cv. XL 72 A) leaves sulphur deficiency causedreduction of soluble protein and chlorophyll contents, whereasATP sulphurylase (EC 2.7.7.4 [EC] ) and O-acetylserine sulphydrylase(EC 4.2.95.9 [EC] ) activities increased with the increasing of S-deprivationtime. The two enzymes exhibited the maximum activity after 5d (ATP sulphurylase) and 3 d (O-acetylserine sulphydrylase)from the beginning of deprivation period. The activities weredifferently distributed between mesophyll protoplasts and bundlesheath strands. The results suggest that the activity of thetwo enzymes may be induced sequentially and differently regulatedin the two types of cells. Key words: ATP sulphurylase, Bundle sheath strands, Mesophyll protoplasts, O-acetylserine sulphydrylase, Sulphur deprivation, Zea     

Organs and Plantlets Regeneration of Gladiolus through Tissue Culture

Explants from inflorescence stalks of Gladiolus when culturedin vitro regenerated new plantlets within 6–7 weeks. Regenerationwas started by the formation on the basal end of a thin layerof callus and root primordia. This was followed by formationof buds and cormlets, on the distal end. The regeneration ofthe various organs from the explants was found to be polarizedand depended on the levels of growth substances added to thebasal medium, best combination for organ initiation being 10ppm naphthalene-acetic acid and 0.5 ppm of kinetin.     

Interrelationship between Meristematic Regions of Developing Inflorescences of Four Cereal Species

A cultivar from each of four cereal species (Avena sativa L.,cv. Swan, Hordeum vulgare, L., cv. Clipper, Triticum aestivumL., cv. Gabo, and Secale cereale L., cv. South Australian Rye)was grown in controlled environment chambers in a 10-h photoperiod(short days) or 10-h photoperiod supplemented with a 6-h extensionby incandescent light. The developmental morphology of the inflorescenceswas followed to ascertain whether there were any common developmentalinterrelationships between the species. Inflorescence internodeelongation was initiated when the floret initial first appeared,irrespective of whether it occurred on the most advanced lateralspikelet or on the terminal spikelet of the rachis. The glumes(infertile bracts) of the terminal spikelet of the rachis wereinitiated when the first second-order inflorescence branch appeared,irrespective of whether the second-order inflorescence branchwas a floret initial or a lateral spikelet, as in Triticum sp.,or an inflorescence (panicle) branch, as in Avena sp. Cessationof the activity of the apical meristem, as measured by primordiumformation, was not correlated with any particular stage of floraldevelopment but appeared to be due to a lack of nutrients causedby an increasing competitiveness for the available nutrientsfrom the developing spikelets which are situated closer to thevascular system than the apical meristem.     

Biological Nitrogen Fixation in Pachyrhizus ahipa (Wedd.) Parodi

The patterns of plant growth and N₂ fixation capability in Pachyrhizusahipa (Wedd) Parodi inoculated with Bradyrhizobium ‘PachyrhizusSpec 1’ strains (Lipha Tech) were investigated in a zero-Nculture system under greenhouse conditions The P ahipa plantis day-neutral with respect to reproductive development Competitionoccurred between the two storage organs (legume and tuber) andprevented high tuber yield in P ahipa The symbiotic effectivenessof the association was high, as the profuse nodulation providedthe inoculated plants with adequate amounts of N Nodules werepresent throughout the cycle of P ahipa The change in rate ofN₂ fixation (RNF) and relative growth rate (RGR) was almostparallel during ontogenesis The developmental pattern of N₂fixation activity revealed that 65% of total N₂ fixation occurredafter N began to accumulate in the reproductive (pod wall plusseed) tissue During pod filling allocation of N compounds tothe seeds exceeded N₂ fixation, the pod walls being the primarysource of redistributed N, followed by the leaves. Pachyrhizus ahipa (Wedd) Parodi, ahipa, tuber crop, dinitrogen fixation, dry matter, N partitioning, reproductive growth     

Size of the Chrysanthemum Shoot Apex in Relation to Inflorescence Initiation and Development

The size of the apical dome of Chrysanthemum morifolium Ramat.at the transition to inflorescence initiation in continuouslight (long days) was not systematically influenced by eitherthe temperature or the irradiance under which the plants weregrown. It was generally 0.26 mm in diameter and c. 3.6 x 10^–3mm³ in volume when the first bract was initiated. The dimensionsof the apical dome of plants in short days were only slightlysmaller at this stage. Similarly, each step in the further developmentof the chrysanthemum inflorescence was associated with a narrowrange of apex sizes, indicating that inflorescence initiationand development are closely related to apex size. Chrysanthemum morifolium Ramat, shoot apex, inflorescence initiation     

A Developmental Pattern of Flowering in Colored <Emphasis Type="Italic">Zantedeschia</Emphasis> spp.: Effects of Bud Position and Gibberellin

The restricted flowering of colored cultivars ofZantedeschia is a consequence of developmental constraints imposed by apical dominance of the primary bud on secondary buds in the tuber, and by the sympodial growth of individual shoots. GA₃ enhances flowering inZantedeschia by increasing the number of flowering shoots per tuber and inflorescences per shoot. The effects of gibberellin on the pattern of flowering and on the developmental fate of differentiated inflorescences along the tuber axis and individual shoot axes were studied in GA₃ and Uniconazole-treated tubers. Inflorescence primordia and fully developed (emerged) floral stems produced during tuber storage and the plant growth period were recorded. Days to flowering, percent of flowering shoots and floral stem length decreased basipetally along the shoot and tuber axes. GA₃ prolonged the flowering period and increased both the number of flowering shoots per tuber and the differentiated inflorescences per shoot. Activated buds were GA₃ responsive regardless of meristem size or age. Uniconazole did not inhibit inflorescence differentiation but inhibited floral stem elongation. The results suggest that GA₃ has a dual action in the flowering process: induction of inflorescence differentiation and promotion of floral stem elongation. The flowering pattern could be a result of a gradient in the distribution of endogenous factors involved in inflorescence differentialtion (possibly GAs) and in floral stem growth. This gradient along the tuber and shoot axes is probably controlled by apical dominance of the primary bud. Online publication: 7 April 2005     

An Analysis of the Relation between Dry Matter Allocation to the Tuber and Earliness of a Potato Crop

Compared with late cultivars, early potato cultivars allocatea larger part of the available assimilates to the tubers earlyin the growing season, leading to shorter growing periods andlower yields. A dynamic simulation model, integrating effectivetemperature and source –sink relationships of the crop,was used to analyse this relation, using data from experimentsin the Netherlands carried out over 5 years. Dry matter allocationto the tuber in these field experiments was simulated well whenthe tuber was considered as a dominant sink that affects earlinessof a potato crop in two ways: early allocation of assimilatesto the tubers stops foliage growth early in the season and reducesthe longevity of individual leaves. In a sensitivity analysisthe influence of tuber initiation, leaf longevity and the maximumrelative tuber growth rate (R_tb) on assimilate allocation andcrop earliness was evaluated. It was found that the maximumrelative tuber growth rate can influence crop earliness morethan the other two factors, but when conditions for tuber growthare optimal, the leaf longevity is most important. Solanum tuberosumL.; simulation model; source –sink relationships; cultivars     

Allocation of Photosynthate to Individual Tubers of Solanum tuberosum L.: III. RELATIONSHIP BETWEEN GROWTH RATE OF INDIVIDUAL TUBERS, TUBER WEIGHT AND STOLON GROWTH PRIOR TO TUBER INITIATION

Potato plants (Solanum tuberosum L.) were grown in water culture.About 14 d after tuber initiation no significant differenceswere found between apical and basal tuber parts in ¹⁴C-uptakeand partitioning into various fractions from ¹⁴C-labelled photosynthate.Thus, the fresh weight of these tubers could be used as a parameterfor the sink size. The ¹⁴C-content per tuber (sink strength)20 h after ¹⁴CO₂-supply to the foliage was significantly correlatedwith the tuber fresh weight. No correlation was found betweenthe ¹⁴C-concentration of the tuber (sink activity; ct. min^–g^– fr. wt.) and tuber fresh weight. Consequently, tuberfresh weight (sink size) per se must have been a factor whichinfluenced sink strength. Stolon parameters characterizing theirgrowth prior to tuber initiation (e.g. stolon volume) and theircapacity for photosynthate transport (diameter, length) weremeasured at the time of tuber initiation. Significant correlationswere found between these stolon parameters and subsequent growthof individual tubers. Anatomical studies on the proportion ofvarious tissues in the cross sectional area of stolons supportthe idea of a negative relation between growth of individualtubers and transport resistance in the phloem of the stolons.It is concluded that in the initial phase of tuber growth, mainlyfactors outside of the tuber determine its growth rate. In laterstages of tuber growth, when the sink strength increases, thecompeting strength of individual tubers for photosynthate isdominated mainly by factors within the tuber itself, such astheir sink size and sink activity. Key words: Potato tuber, sink size, tuber initiation, transport resistance     

The Importance of Phellogen Cells and their Structural Characteristics in Susceptibility and Resistance to Excoriation in Immature and Mature Potato Tuber (Solanum tuberosum L.) Periderm

Potato tuber (Solanum tuberosum L.) periderm maturation is animportant physiological process that directly affects the susceptibilityand development of resistance to costly excoriation (skinning-typewounds) at harvest. The objectives of this research were toidentify the specific types of cells and the cellular changesassociated with susceptibility and resistance to tuber excoriationin immature and mature tubers respectively. Epifluorescent microscopicexamination of immature tuber periderm (phellem, phellogen andphelloderm cells) from several genetically diverse cultivarshas shown that the cellular damage resulting from excoriationoccurs within the phellogen (cork cambium), a meristematic layerof cells that gives rise to neighbouring phellem and phellodermcells. Tuber excoriation is the result of the fracture of radialphellogen cell walls linking the skin (phellem) to the phelloderm.As the tuber periderm matures, phellogen cells become inactiveand the radial walls of these cells become more resistant tofracture; resistance to excoriation develops. Ultrastructuralstudies of immature tuber periderm show that radial walls ofactive phellogen cells are thin and fragile. During peridermmaturation, both radial and tangential phellogen cell wallsthicken as they strengthen and become resistant to fracture,thereby providing resistance to excoriation. These results refuteprevious theories of the physiological changes responsible forthe onset of resistance to tuber skinning injury. The combinedresults establish a paradigm whereby the thickening and strengtheningof tuber phellogen cell walls upon periderm maturation are thedeterminant for resistance to tuber excoriation. Copyright 2001Annals of Botany Company Cambium, meristematic, periderm, phellem, phelloderm, phellogen, potato, skinning, Solanum tuberosum L., 0tuber     

Translocation of Assimilates Within and Between Potato Stems

Three aspects of translocation in potato were examined: (i)translocation within stems (ii) translocation between individualstems of a plant (iii) translocation between tubers followinginjection of ¹⁴C sucrose into a single daughter tuber. Assimilatesexported from single leaves of evenly illuminated potato stemsremained confined to the same side of the stem as the sourceleaf in a pattern consistent with the internal arrangement ofvascular bundles in the stem, and tubers borne on stolons verticallybelow the source leaf contained higher concentrations of ¹⁴Cthan those on the opposite side. Consequently ¹⁴C import intothe tubers bore little relationship to tuber growth rates. However,alteration of source/sink relations by pruning stems to a singlesouce leaf resulted in an even distribution of ¹⁴C throughoutthe vascular bundles of the stem and ¹⁴C import into the tubersbore a stronger relationship to tuber growth rates than to thephyllotactic relationship of the tubers with the source leaf. Labelling one stem of a potato plant resulted in little or nomovement of ¹⁴C into tubers on other unlabelled stems. However,removal of the unlabelled stems at ground level induced a significantmovement of ¹⁴C from the labelled stem to the tubers on unlabelledstems, this movement occurring via the mother tuber. Shadingthe unlabelled stems had less effect than stem removal. ¹⁴C sucrose injected into single daughter tubers was translocatedto other tubers on the same stem and also to tubers on a secondstem at the opposite end of the mother tuber. The sucrose wasconverted to starch in these tubers. The results favour the view that each potato stem functionsas an independent unit with potential for assimilate redistributionwithin a stem but with little or no carbon exchange occurringbetween stems, unless under severely altered source/sink patterns. Assimilates, ¹⁴C, autoradiography, potato (Solanum tuberosum L.), tuber growth     

Initiation of Procambial Strands in Leaf Primordia of Dactylis glomerata L. as an Example of a Temperate Herbage Grass

This study is concerned with the examination of shoots of herbagegrasses, particularly Dactylis glomerata L., for comparisonwith earlier investigations on this species and on the cerealTriticum aestivum L. The main features of procambial strandinitiation are found to be the same in all the herbage grassesexamined and to be very similar to those in Triticum. Thus,in a vegetative shoot, all the procambial strands originatein the leaf primordia independently of the vascular system ofthe older parts of the plant, and extend downwards from theirfirst point of origin. For the median strands, the first pointof origin is in the disc of insertion of the primordium, butfor later strands it is progressively higher, so that the laststrands are initiated well up in the free portion of the primordium.The course of the median and first and second lateral strands,in the first two discs of insertion that they penetrate, isvery regular and predictable. However, two discs of insertionbelow the point of initiation of strands, their course is interruptedby the strands of the primordium directly below (there is onealternating primordium between them), and from this point downwardsvariations, both specific and between individual plants andprimordia, occur. This is the region where connexion with thevascular supply of the rest of the plant is first established.The timing of the arrival of young strands from above and ofthe development of successive nodal plexi from below, via whichmost interconnexions are established, will give some variationto the early development of this region.     

Ontogenetic Anatomy of Streptocarpus grandis(Gesneriaceae) with Implications for Evolution of Monophylly

The monophylly of Streptocarpus grandis was examined ontogeneticallyand anatomically. When the seed is shed, the embryo is composedof a hypocotyl and two equal-sized cotyledons, lacking rootand shoot apices. During germination, cell division and subsequentcell enlargement occur in the hypocotyl and cotyledons. Thehypocotyl soon produces a primary root from its distal tip;this involves surface and subsurface cells at the point of attachmentof the suspensor remnant. In the cotyledons, cell enlargementand differentiation occur basipetally, leaving small meristematiccells at the bases. These small cells give rise to the basalmeristem in one of the two cotyledons, which contributes toan accrescent cotyledon. The groove meristem, which later differentiatesinto an inflorescence, arises in place of shoot apices whenthe cotyledons become visibly unequal in size. It later exhibitsa tunica-corpus like configuration and differentiates directlyinto an inflorescence meristem. The evolution of this uniquegrowth of one-leaved Streptocarpus is discussed with regardto morphogenetic data.Copyright 2000 Annals of Botany Company Anisocotyly, developmental anatomy, evolution, Gesneriaceae, one-leaf plant, ontogeny, Streptocarpus grandis