Storage Organ Development in Radish (Raphanus sativus L.). 2. Effects of Growth Promoters on Cambial Activity in Cultured Roots, Decapitated Seedlings and Intact Plants

The radish varieties Cherry Belle and Long White Icicle wereused to investigate the role of the shoot and the effects ofsynthetic growth promoters in controlling cambial activity inthe seedling axis. Development was compared in excised roots, roots with hypocotylsattached and intact seedlings cultured aseptically on a nutrientmedium. No cambial divisions were seen in isolated radicleswhich had been cultured for ten days following excision butretention of hypocotyl tissue or the entire shoot resulted incambial activity and the production of secondary vascular tissues.Enriching the culture medium by raising the sucrose conantrationto 8% and including 10^–5 M indol-3yl acetic acid (IAA)5 x 10^–6 M 6-benzylaminopurine (BA) and 5 x 10^–4Minositol enhanced root thickening, increasing stele and xylemdiameters in roots cultured both with and without attached shoottissues. The effects of shoot tissues and enrichment of themedium were additive. The effects of auxin, cytokinin and gibberellin (gibberellicacid, GA²) were also studied on daxpitated seedlings. BA wasmuch more effective in inducing cell divisions in the hypocotylthan either IAA or GA supplied separately but a mixture of IAA+GAalso produced clearly defined arcs of cambial tissue. Littlesecondary tissue had been produced after seven days' treatment,and stelar enlargement was due to the development of a cambialzone and cell expansion in the primary tissues. Only minor differencesin response were observed between the two varieties. No stimulation of storage organ development occurred when auxin,cytokinin or inositol was inwrporated into the inorganic culturesolution in which plants of Cherry Belle were grown. Rnphanus sarivus, radish, storage organ, cambial activity, growth promoters, indol-3-ylacetic acid, 6-benzylaminopurine, gibberellic acid     

Development of Sink Capacity of the "Storage Root" in a Radish Variety with a Low Ratio of "Storage Root" to Shoot

Controling mechanisms of sink capacity are poorly understood.Previously we suggested that sucrose synthase (SuSy), but notinvertase, plays an important role for sink capacity of theradish "storage root" in a variety, Raphanus sativus L. (cv.White Cherish) [plant Cell Physiol. (1999) 40: 369]. With thisvariety about 50% of the total dry weight (DW) was in the "storageroot" at 21 d after sowing (DAS). We investigated the sink capacityof another radish variety, R. sativus L. (cv. Kosena) with alow ratio of "storage root" to shoot. With the latter varietyonly 3% of the total DW was in the "storage root" at 21 DAS.Sink activity (increase in DW of the "storage root" per unitof DW present per unit of time) of the "storage root" in Kosenaas well as White Cherish was strongly related to the level andactivity of SuSy but not to the activity of invertase. Theseresults confirmed that SuSy rather than invertase may be criticalfor the development of the sink activity of the radish "storageroot" and that the reaction products of UDP-glucose and fructoseare utilized for sink growth including biosynthesis of the cellwall. In Kosena photosynthates seemed to be partitioned mainlyinto developing leaves and fibrous roots. Differences in partitioningof photosynthates among various sinks with these two varietiesare discussed including anatomical considerations. (Received July 19, 1999; Accepted September 30, 1999)     

Spatial and temporal distribution of sucrose synthase in the radish hypocotyl in relation to thickening growth.

Sucrose synthase (SuSy) is a key enzyme in the development of storage root of radish. Clarification of its spatial and temporal expression during the thickening growth of radish hypocotyl, which later develops into storage root, was carried out immunologically using light microscopy. Sequential harvests at 3, 7, 11 and 13 d after sowing (DAS) were performed on two radish cultivars having different sink capacity. A very low level of SuSy was observed 3 DAS for both cultivars. White Cherrish (WC; strong storage root) showed the maximum level of SuSy between 7 and 11 DAS with increased cell development (thickening), while in Kosena (K; low storage root) the level remained high after 13 d of growth. A high level of SuSy was found in companion cells, which was consistent with previous observations, but SuSy was also found in the xylem parenchyma and in some cortical cells. The level of SuSy differed according to the localization and depended highly on cell development. Both cell division and cell enlargement were stimulated in WC compared with K. The role of SuSy during thickening growth of radish hypocotyl is discussed in terms of utilizing photosynthates.     

Growth and Development of Radish (Raphanus sativus, L.) Under Selected Light Environments

Plants of radish (Raphanus sativus L.) were grown under selectedlight conditions in controlled environmental chambers in orderto monitor the role of photoperiod, irradiance level and inputlight energy in plant development. Results indicated that thedaily input of light energy was the most important light factoraffecting leaf development while photoperiod and irradiancelevel had the major influences on storage organ development.Distribution of assimilates to leaves and storage organs variedunder different light regimes with long photoperiods and highirradiances producing the largest storage organs. Once initiated,the rate of storage organ growth was similar under all testedlight environments. Raphanus sativus L., radish, growth, development, light, photoperiod, assimilate distribution, storage organ     

Root Development and Source-Sink Relations in Carrot, Daucus carota L.

Growth analysis and ¹⁴CO₂ feeding experiments have shown thatthe developing storage organ became an increasingly importantsink for assimilates, accumulating 40% of the dry matter producedby the carrot plant within 9 weeks of sowing. The relative importanceof each leaf in fixing and exporting ¹⁴C was assessed at twostages of development. Morphogenetic responses indicated thatan absence of thickening in the lateral roots was associatedwith continued meristematic activity in the tap root, in theform of an elongating apex or a vascular cambium. Source-sink relations were examined by observing plant growthfollowing the removal of part of the tap root and/or lateralroots. Pruning the roots at 35 d reduced the subsequent growthof the plant by reducing the AGR of the remaining root systemand the shoot. The reduction in leaf growth was associated witha loss of fibrous roots, removal of part of the tap root havingvery little additional effect on shoot growth although the AGRof the root system was reduced by a further 78%. Increased fibrousroot RGRs following pruning soon re-established the normal fibrousroot/shoot ratio. These experiments demonstrated the importanceof the root system in controlling dry matter production in thecarrot plant, but suggested that the sink activity of the developingstorage organ was less significant than other root functions.     

Changes in the Cytokinins of Radish Roots during Maturation

The cytokinins of developing radish roots were extracted, partially purified, and separated by thin-layer chromatography into three distinct bands of activity. One band was identified chromatographically as zeatin ribonucleotide and another was indistinguishable from a mixture of zeatin and zeatin ribonucleoside. The third band was not identified, but it was not a derivative of zeatin or of isopentenyladenine. The unidentified cytokinin had physiological properties quite different from those of the zeatin derivatives. The zeatin-based cytokinins increased in radish roots with the onset of cambial activity, and reapplication of these cytokinins to cultured primary roots stimulated cambial activity. The unidentified cytokinin became abundant only after extensive secondary thickening had occurred, and it was localized almost entirely in the xylem. It did not stimulate cambial activity in cultured roots. The evidence indicates that zeatin and its derivatives regulate cambial activity in radish, and that the unidentified cytokinin may be synthesized in the roots and transported to the shoot.     

Homology of plant peroxidases: Relationships among acidic isoenzymes

Antisera specific for two commercial acidic peroxidases from horseradish ( Amoracea rusticana L.) were used to determine the degree of homology between isoperoxidases from horseradish, turnip ( Brassica rapa L. cv. Purple White Top Globe) and radish ( Raphanus sativus L. cv. Cherry Belle). Ouchterlony agar diffusion, precipitin tests and anticatalaytic assays were used to show that acidic horseradish peroxidases could be distinguished by immunological methods but were closely related. Antisera specific for either horseradish acidic isoperoxidase gave a lesser degree of cross reaction with the basic isoenzyme from this plant. Acidic isoperoxidases from turnip and radish were more closely related to acidic horseradish peroxidases than the basic isoperoxidase from horseradish as assessed by immunological cross-reaction. Basic isoperoxidases from carrot ( Daucus carota L. cv. Danvers), radish or turnip did not react with antisera prepared against acidic horseradish peroxidases. Finally, acidic horseradish peroxidases were shown to be poor immnnogens in rabbits in contrast to the basic horseradish isoenzyme.     

The Micronutrient Boron Causes the Development of Adventitious Roots in Sunflower Cuttings

Three-day-old light-grown sunflower seedlings were de-rootedand incubated in nutrient solutions that either contained orlacked boric acid (B). In the absence of B, in the majorityof the seedlings, no adventitious roots were formed. The micronutrientB caused the development of numerous roots in the lower partof the hypocotyl. The effect of B occurred without the supplyof any phytohormones. A dose-response curve of B-induced rootingyielded an optimum concentration of 0.1 mM boric acid. Histologicalstudies revealed that cell divisions occurred in the controlbut no root primordia developed. In cuttings that were incubatedin B (0.1 m M) root primordia were observed that rapidly developedinto well-differentiated adventitious roots. Sunflower cuttingsthat were planted with their cut end in vermiculite that wasmoistened with nutrient solutions without B degenerated afterseveral weeks. In the presence of B the cuttings formed numerousadventitious roots that entirely replaced the tap root systemof intact seedlings. The rooted cuttings developed into sturdyadult sunflower plants. Our results are discussed with respectto the possible role of B in the evolution of vascular fromprevascular plants.Copyright 1999 Annals of Botany Company Adventitious roots, boron, cuttings, organogenesis, sunflower seedlings.     

The Anatomical Relationship Between Cambial Regeneration and Root Initiation in Wounded Winter Cuttings of the Apple Rootstock M.26

Root primordia differentiate remote from the existing vasculartissue of split- or incision- wounded winter cuttings. Thisis preceded by heavy callusing of the wounds and basal cut surface.Most of the callus is cortical in origin but callus is alsoformed as a result of damage to the cambium. In the incisiontreatment a new cambium differentiates within the cambial callusfrom the undamaged cambium on either side so as to form an outward-pointingsalient enclosing randomly orientated xylem. Two such salientsare formed in the split base treatment since each resultanthalf behaves like a separate cutting. The salients are subdividedhorizontally into finger-like projections due to the dispositionof the rays at the edges of the wound. Once a root primordiumforms, differentiation of procambium-like tissue between itand one or more projections proceeds rapidly, followed by outgrowthof the root. Roots emerge from the basal callus and in verticalfiles from the wound callus. The split base treatment increases16-fold the number of rooted cuttings over controls, while incisionwounds increase rooting four-fold; this is associated with thefact that more rhizogenic (salient-forming) sites are formedby splitting the base. The physical and anatomical factors involvedin cambial regeneration are discussed. Anatomy, apple, callus, cambium, cambial regeneration, M.26 rootstock, Malus pumila L., rooting, root initiation, wound response     

Homology of Plant Peroxidases: AN IMMUNOCHEMICAL APPROACH

Antisera specific for the basic peroxidase from horseradish (Amoracea rusticana) were used to examine homology among horseradish peroxidase isoenzymes and among basic peroxidases from root plants. The antisera cross-reacted with all tested isoperoxidases when measured by both agar diffusion and quantitative precipitin reactions. Precipitin analyses provided quantitative measurements of homology among these plant peroxidases. The basic radish (Raphanus sativus L. cv. Cherry Belle) peroxidase had a high degree of homology (73 to 81%) with the basic peroxidase from horseradish. Turnip (Brassica rapa L. cv. Purple White Top Globe) and carrot (Daucus carota L. cv. Danvers) basic peroxidases showed less cross-reaction (49 to 54% and 41 to 46%, respectively). However, the cross-reactions of antisera with basic peroxidases from different plants were greater than were those observed with acidic horseradish isoenzymes (30 to 35%). These experiments suggest that basic peroxidase isoenzymes are strongly conserved during evolution and may indicate that the basic peroxidases catalyze reactions involved in specialized cellular functions. Anticatalytic assays were poor indicators of homology. Even though homology among isoperoxidases was detected by other immunological methods, antibodies inhibited only the catalytic activity of the basic peroxidase from radish.     

Changes in the Distribution of Plasmodesmata in Developing Fibre-tracheid Pit Membranes of Sorbus aucuparia L.

The distribution of plasmodesmata in cambial pit fields anddeveloping fibre-tracheid pit membranes in Sorbus aucupariaL. has been studied using conventional and high voltage transmissionelectron microscopy. In cambial pit fields, plasmodesmata arewidely separated while, during cell enlargement and the stageof secondary wall formation, they occur exclusively in a denselypacked cluster, eccentrically located on the pit membrane ina thickening of primary wall material. It is not clear at themoment whether the cluster arises by aggregation of the cambialpit field plasmodesmata, or by de novo formation in a localizedregion coupled with loss of plasmodesmata outside this region.The significance of these changes is discussed. Sorbus aucuparia L., plasmodesmata, pit membranes, xylem differentiation     

Accumulation of di-n-butylphthalate in plants and its effect on pigment and protein content

Seedlings of radish ( Raphanus salivas L. cv. Cherry Belle) and wheat ( Triticum aestivum L. cv. Starke II, Weibull) placed in air containing vapour of di- n -butyl-phthalate accumulate phthalate to a concentration that is 10⁶ times that of the surrounding air within 3 days. Particularly high accumulation is found in the cuticular and wax layers. Plants earlier found not to respond to di- n -butylphthalate (wheat) show toxic symptoms (carotenoid and chlorophyll deficiency in strong light, conco-mittant with chloroplast destruction and swollen mitochondria) when the phthalate concentration is further increased by addition to the nutrient medium. Phthalate-affected, white leaves lack the protein moieties normally belonging to the light harvesting complex.     

The Anatomy of Root Initiation in Cuttings of Griselinia littoralis and Griselinia lucida

The initiation of root primordia in Griselinia littoralis andG. lucida occurred a few millimeters above the cut base. Inall cases the first cellular event was the activation of specificregions of the cambium which were associated with traces fromleaves which themselves were particularly vigorous root-formersif detached. In cuttings from seedlings, the first cells cutoff continued to divide and gave rise to root primordia in situ,whereas those from mature plants produced files of six to 22rows of cells and it was only when the cells first cut off hadbeen displaced outwards towards the fibre caps that the cambiumstopped dividing. Primordium development may then occur at theadvancing front, possibly as a result of a stimulus originatingfrom damaged cells. Thus the same cells were involved in organizedprimordium formation both in seedling and mature cutting, butthe location differed. The reduced rooting and the long lag phase in cuttings frommature plants of G. lucida may be due to the presence of a completering of fibres. This does not seem to present a mechanical barrierto emergence - since elongating primordia can force throughthe ring - nor can it affect the receipt of any root-inducingstimulus by the target cells since it is considered that thisarrives via the vascular tissues. However, evidence suggeststhat it is the initial phase of cambial activation which isprevented in cuttings from mature plants. This suggested eitherthat the initial stimulus was less effective or that the targetcells were less responsive than those of seedlings, which havevery few fibres, or of mature G. littoralis, which only hasfibm associated with the vascular bundles. Griselinia littoralis Raoul Choix, Griselinia licida Forst. f. Prodr., adventitious roots, cuttings, primordium initiation and location     

Integrative Analysis of mRNA and miRNA Expression Profiles of the Tuberous Root Development at Seedling Stages in Turnips

The tuberous root of Brassica rapa L. (turnip) is an important modified organ for nutrition storage. A better understanding of the molecular mechanisms involved in the process of tuberous root development is of great value in both economic and biological context. In this study, we analyzed the expression profiles of both mRNAs and miRNAs in tuberous roots at an early stage before cortex splitting (ES), cortex splitting stage (CSS), and secondary root thickening stage (RTS) in turnip based on high-throughput sequencing technology. A large number of differentially expressed genes (DEGs) and several differentially expressed miRNAs (DEMs) were identified. Based on the DEG analysis, we propose that metabolism is the dominant pathway in both tuberous root initiation and secondary thickening process. The plant hormone signal transduction pathway may play a predominant role in regulating tuberous root initiation, while the starch and sucrose metabolism may be more important for the secondary thickening process. These hypotheses were partially supported by sequential DEM analyses. Of all DEMs, miR156a, miR157a, and miR172a exhibited relatively high expression levels, and were differentially expressed in both tuberous root initiation and the secondary thickening process with the expression profiles negatively correlated with those of their target genes. Our results suggest that these miRNAs play important roles in tuberous root development in turnips.     

Seasonal Changes in the Effects of Auxin on Rooting in Stem Cuttings of Ficus infectoria

Ficus infectoria stem cuttings were treated with 10 and 100 μg/ml each of IAA, IBA, 2,4, -D and NAA at monthly intervals and planted to study their rooting response after recording morphophysiological status and cambial activty of the parent branches. Attempts were also made to surgically expose the cambium before auxin treatment to determine the relationship of seasonal variation in auxin effectivity to cambial activity. The results show that: (1) there are two distinct phases in the sensitivity of Ficus infectoria stem cuttings to auxin-induced rooting; (2) the high rooting phase coincides with renovation of growth and high cambial activity starting in March and lasting through August and the low rooting phase coincides with winter dormancy and low cambial activity; (3) roots emerge in longitudinal rows in slitted auxin-treated cuttings; (4) slitted auxin-treated cuttings root profusely in June when cambial activity is high but not in October when cambial activity is low suggesting a close correspondence of seasonal variation between the rooting activity of auxin and cambial activity.     

Investigation of Quantitative Relationships in Dry Matter Distribution Between Tops and Storage Roots in Sugarbeet

Data from both controlled environment and field experimentson sugarbeet are used to support the concept that dry matterdistribution between top and storage root growth can be adequatelyquantified by over a large part of the growing season. Very young plants,prior to cambial ring development, had higher slopes for thelog-log relationship at each harvest. Estimates of the slopesbecame relatively constant about 30 d after emergence indicatingthat the pattern for dry matter distribution was determinedat an earlier stage of growth than is apparent from considerationof linear growth scales. Estimates of and are similar to thosereported for other storage root crops with differences in reflectingrelative size differences. Differences in applied N in the fieldwere detected as a shift in the intercept of the relationshipfor dry matter distribution. In general, the results with sugarbeetare agreement with the Barnes' model, which relates assimilatepartitioning to relative sink activities, respiration rates,and initial weights of plant parts. Beta vulgaris L., sugarbeet, dry matter distribution, assimilate partitioning, storage root, growth pattern, nitrogen, root/shoot weight     

Phytotoxicity of Phthalate Plasticisers: 2. SITE AND MODE OF ACTION

The effects of phthalate esters on chlorophyll a₂ fluorescencein radish plants (Raphanus sativus L. cv. Cherry Belle) wereexamined Fluorescence yield was increased in those plants exposedto an aerial concentration of 120 ng dm^–3 dibutyl phthaiatc(DBP) at a rate of 3.0 dm³ min^–1 for 13 d. Comparisonof fluorescence enhancement ratios and F_red/F_ox, suggests thatDBP inhibits photosynthesis in radish plants at a site afterQ_A. Both DBP and diisobutyl phthalate (DIBP) strongly inhibiteduncoupled (PS2+PS1) electron transport rates in thylakoids isolatedfrom spinach. At a chlorophyll concentration of 10 µgcm^–3 the concentrations of DBP and DIBP exhibiting 50%inhibition were 44 mmol m^–3 and 42 mmol m^–3 respectively.Basal electron transport rates were also inhibited, with 87mmol m^–3 of DBP or DIBP producing 50% inhibition. Measurementof photosystcm 1 activity suggested that the main site of actionof these phthalates was localized at a site near the reducingside of photosystem 2. Key words: Phthalate, plasticiser, chlorophyll, fluorescence, photosynthesis, inhibition     

Interactions between elicitins and radish Raphanus sativus

Two responses to elicitins are described in cultivars of radish (Raphanus sativus L.). Type I, exhibited by the cultivar Daikon, is characterised by wilting and desiccation within 24 h of elicitin application and was previously reported as the sensitive response (S. Kamoun et al. 1993, Mol Plant-Microbe Interact 6: 15–25). At 1 μg elicitin · g⁻¹ FW radish tissue, symptoms appeared after 8 h, a sensitivity comparable to that shown by tobacco to β elicitins (J.-C. Pernollet et al., 1993, Physiol Mol Plant Pathol 42: 53–67; S. Kamoun et al., 1993, Mol Plant-Microbe Interact 6: 15–25). Elicitin failed to induce these symptoms in the cultivar White Icicle, even at 100 μg · g⁻¹ FW of tissue. However, a different response (Type II) with symptoms resembling senescence appeared in White Icicle after 48 h and were fully developed by 72 h. The Type II response was induced at levels of elicitin above 0.3 μg · g⁻¹ FW. Elicitin-treated Daikon leaves held at 100% relative humidity, rather than ambient (50–60%) did not wilt and by 72 h displayed Type II symptoms. When treated Daikon leaves were removed to ambient humidity at any time during the latent period, they developed Type I symptoms within 2 h. Although Type I symptoms were suppressed in Daikon at high humidity, there was no indication that leaf diffusion resistance or plant water conductance were affected. Protoplasts from the cultivar Daikon responded to elicitin by H⁺ uptake and K⁺ release, with maximal response at 300 pM. The response was eliminated by K252a or staurosporine. Daikon protoplasts also showed transient uptake/secretion of Ca²⁺ on elicitin addition. Protoplasts from White Icicle gave neither of these responses. Both Daikon and White Icicle phenotypes could be transferred to progeny of Daikon-White Icicle crosses and in the F2 generation three phenotypes, including a null, segregated. Only those F2 plants which exhibited the Daikon phenotype produced protoplasts which responded to elicitin. Received: 13 May 1997 / Accepted: 27 August 1997     

Anchorage Mechanics of the Tap Root System of Winter-sown Oilseed Rape (Brassica napus L.)

The anchorage mechanics of mature winter-sown oilseed rape (‘Envol’)were investigated by combining a morphological and mechanicalstudy of the root system with anchorage tests on real and modelplants. Oilseed rape plants were anchored by a rigid tap root;the few laterals all emerged below the centre of rotation ofthe root system (approx. 30 mm below the soil surface). Whenplants were pulled over, the tap root bent and the top 30 mmmoved in the soil towards the direction of pull, creating acrevice on the opposite side. The maximum anchorage moment was2.9 ± 0.36 N m. Two main components of anchorage wereidentified: the bending resistance of the tap root and the resistanceof the soil on the near side to compression. The relative importanceof these components was determined by measuring both the bendingresistance of the tap root, and the resistance of metal tubesof varying diameter, inserted to various depths in the soil,to being pulled over. These tests showed that the tap root bendingmoment at failure could account for around 40% of anchoragemoment, while soil resistance could account for around 60%.The model tests on the tubes also help to shed light on theway in which the dimensions of tap roots will influence theiranchorage capability. Copyright 2001 Annals of Botany Company Anchorage, lodging, root bending resistance, mechanical properties, oilseed rape, Brassica napus L     

Anomalous secondary thickening in roots of Daviesia (Fabaceae) and its taxonomic significance

PATE, J. S. KUO, J., DIXON, K. W. & CRISP, M. D., 1988. Anomalous secondary thickening in roots of Daviesia (Fabaceae) and its taxonomic significance . Investigations of 55 species of Daviesia show 24 to have anomalous secondary vascular development in their roots and the remainder to be of conventional root anatomy. Species showing the trait exhibit early cessation of cambial activity in the central stele of the seedling followed by differentiation of a series of concentric layers of inter-connecting vascular strands, each layer derived from new cambial activity in pericycle tissue outside the existing vasculature. The ontogeny and mature structure of the anomalously thickened roots of certain species is described and the findings compared with published data for other genera of dicotyledons. A cladogram is presented to portray the phylogeny of the species of Daviesia included in the study, using 36 morphological features and the parsimony method to derive minimum length Wagner-type trees from a matrix of taxa character states. Evolution of the character of anomalous root thickening is concluded to have occurred early and possibly on two independent occasions during specialion of the genus.