Direct root tip conversion ofCatasetum into protocorm-like bodies. Effects of auxin and cytokinin

Root apex conversion ofCatasetum fimbriatum into protocorm-like bodies (PLBs) can occur in the absence of any added plant growth regulator. The presence of exogenous auxins in media drastically reduced the number of PLBs formed; on the other hand the concentrations of these auxins used greatly increased the process of callus formation. No effect on the mean number of root tip conversions into PLBs was observed with chlorogenic acid. However, this process was significantly increased in one of the concentrations used of p-coumaric acid. BA did not have any effect on callus formation, but caused marked acceleration in the process of root tip conversion and on the mean number of PLBs formed. PLB formation observed in the absence of any exogenous growth substance seemed to reflect a disruption in the interactions between the excised roots and the rest of the plants. The presence of light decreased the process of conversion.     

Morphogenesis in Yucca schidigera Roezl. Root Organ Cultures

Root development in suspension cultures of Yucca schidigerawas light-mediated. The green cultures consisted of roots, smalltissue aggregates and suspension cells. Roots possessed an apicalmeristem with a root cap, meristematic region and region ofdifferentiating tissues. Phloem, xylem vessels and tracheidsoccurred in discrete polyarch vascular bundles. Xylary wallthickening was reticulate, and endodermis and pericycle werepresent. Roots of intact Y. schidigera plants had a similardistribution of vascular tissues. Dark-grown cultures were cream-colouredand contained only lobed tissue aggregates and suspension cells. Yucca schidigera Roezl., tissue cultures, morphogenesis, root organ, light/dark     

Anatomy and Histochemistry of the Root System of the Kiwifruit Vine, Actinidia deliciosa var. deliciosa.

The kiwifruit vine is a species which has been newly introducedinto cultivation and little is known of its comparative physiologyand anatomy. In this study we found that fibrous, 'magnolioid'roots, which have undergone secondary vascular development butwhich retain the cortex and develop a suberized epidermis, comprisethe greater part of the root system (95% of total length). Newlyinitiated roots with primary development conform to norms establishedin other woody plant species. However, the structural roots,like the fibrous roots, also retain a cortex and phellodermwhich is initiated by hypodermal cells within the cortex andnot by the pericycle which is the common progenitor tissue inother species. This phellogen produces new cells centrifugallyonly. The cortex is a relatively small component of the structuralroot and the bulk of the tissue is vascular in origin, as inthe roots of other plant species. The endodermis is retainedand continues to divide periclinally to accommodate the increasein circumference with growth.Copyright 1993, 1999 Academic Press Actinidia deliciosa, root anatomy, ontogony, histochemistry, exodermis, endodermis     

Anatomical Changes Which Occur in Cuttings of Agathis australis (D. Don) Lindl 1. Wounding Responses

The basal and sub-basal regions in cuttings of Agathis australisundergo a complex series of anatomical changes. Many of theseare categorized as wound responses and include cell divisionsassociated with the cut base and the proliferation of tracheidsand phloem which arise in the interfascicular region about 4mm above the cut base. The vascular tissue arcs outwards anddownwards through the cortex. It may develop as isolated strandsonly a few cells wide or as sheets involving a number of cells.The precise pattern of vascular development appears to be determinedby its extent at the point of origin and by the presence ofobstacles such as primary and secondary resin canals which arelocated to the outside of the vascular bundles in the stem.Secondary resin canals are produced only in the rooting zonein cuttings that show extensive cell division. They arise schizogenouslyand do not form an interlinking network. Root primordia arise in the cortex at the end of isolated strandsof newly developed vascular tissue. Primordia never form inassociation with sheets of tracheids or after the convergenceof strands. In some cases virtually the entire sub-base is filledwith vascular tissue as a result of cell division and the differentiationof parenchymatous tissue. Root primordia never appear in thissituation. Agathis australis (D. Don) Lindl, kauri, cuttings, wound responses, vascular development, resin canals, root primordia, cellular differentiation     

Haustorial Structure and Functioning of the Root Hemiparastic Tree Nuytsia floribunda(Labill.) R.Br. and Water Relationships with its Hosts

Observations on the origin and mature structure of the haustoriumof the Western Australian Christmas tree (Nuytsia floribunda)corroborate and extend the findings of earlier workers. We showthat the previously described sclerenchymatous ‘horn’or ‘prong’ formed within the haustorium acts asa sickle-like cutting device which transversely severs the hostroot and then becomes lodged in haustorial collar tissue directlyopposite to that where it originated. The cutting process isdeduced to be rapid and the gland-like fluid filled structurein the haustorium is suggested to generate a hydrostatic forcedriving the device through the host root. The haustorial parenchymacells at the tight junction between the endophytic part of thehaustorium and the cut face of the host root develop balloon-likeoutgrowths which intrude into the lumina of severed xylem vesselsof the host. Experiments feeding 0.05% (w/v) basic fuchsin tofreshly cut ends of host root segments distal to terminally-attachedmature haustoria demonstrate an apoplastic pathway from hostxylem elements fractured at the interface into haustorial parenchyma,and thence through vascular tissue to the haustorium into thetranspiring plant of Nuytsia. Application of labelled water(D₂O) to uncut basal roots of potted plants ofAcacia acuminataparasitized by Nuytsia results in labelling of leafy shootsof parasite and host, indicative of haustorial uptake of waterby Nuytsia from host root xylem in the intact association. Measurementsof xylem water potentials of pot-cultured seedling Nuytsia associatedwith a range of hosts, or of mature trees of Nuytsia and partnerwoody hosts in the native habitat, demonstrate consistentlymore negative potentials in the parasite than host, suggestingthat the parasite may regularly obtain xylem water through itshaustorial apparatus. Copyright 2000 Annals of Botany Company Root hemiparasite, Nuytsia floribunda, Loranthaceae, haustorial structure, host–parasite water relations     

The Vascular Pattern of a Rhizomatous Ginger (Alpinia speciosa L. Zingiberaceae). 2. The Rhizome

The vascular system in the underground rhizome of Alpinia speciosaL. (Zingiberaceae) is seen to be arranged in three distinctzones. (1) An inner system of ‘scattered’ vascularbundles which serial cinematography reveals to have an axialpattern conforming to the basic ‘palm’ configuration(a system of upwardly branching leaf traces with interconnections).(2) An intermediate zone comprising a thin perforated cylinderof anastomosing vascular strands having direct contact withboth roots and inner system bundles. (3) An outer system offreely-anastomosing vascular bundles. Connexion of outer andinner system occurs in the form of extensive bridging from innersystem leaf traces as they depart obliquely between the outersystem network. The interrelation of the three systems, plus root and branchinsertion, is illustrated by means of diagrammatic three-dimensionalreconstructions. The intermediate zone is intimately associatedwith root insertions and with the inner system, and is shownto obliviate potential bottlenecks at the point of lateral branchinsertion in this sympodial rhizome system. A comparison ismade with other monocotyle-donous vascular systems. Alpinia speciosa L., shell ginger, rhizome, vascular anatomy     

Stomata on the Primary Root of Pisum sativum L.

The first record of stomata on a non-specialized root was obtainedby scanning electron microscopy of 4-d-old Pisum sativum L.In some cases subsidiary cells were trichoblasts. Stomata andthe root triarch vascular structure were simultaneously presentin transverse sections through the root. Pisum sativum, pea, root stomata, guard cells, trichoblasts     

Transport and Metabolism of Kinetin-8-14C in Zea mays L. Roots

The movement of kinetin has been investigated in roots of Zeaseedlings, grown in the dark, using kinetin-8-¹⁴C. Segments (10 and 11 mm) with and without an apex were used andthe following results obtained: The transport of kinetin is polarized basipetally. Kinetin-8-¹⁴C is transported in roots without vascular tissue,but the amount transported is always lower than in roots withvascular tissue. Thin-layer chromatography showed that the molecule of kinetinis metabolized in the root segments, adenine being one of theproducts.     

Influence of Divalent Cations and Chelators on the Structure of Prolamellar Bodies of Avena sativa

The influence of the cations Ca²⁺ and Mg²⁺ on the structureof oat prolamellar bodies (PLB), set free from etioplasts andinside intact etioplasts, was examined. The results presentedgive evidence for a relation between PLB-structure, its transformationand the presence of divalent cations, especially Ca²⁺. Underin vitro conditions the structure of isolated PLBs and of PLBsin intact etioplasts is stabilised by calcium. Deprivation ofdivalent cations by ethylenedi-aminetetraacetic acid (EDTA)or ethyleneglycol-bis(ß-aminoethyl ether)-N,N,N',N'-tetraaceticacid (EGTA) led to a breakdown of PLBs to structures very similarto those found in plastids after short time illumination ofetiolated leaves. Thus it seems reasonable, that Ca²⁺ is animportant factor in stabilising PLBs and in the regulation ofthe in vivo light triggered transformation of PLBs. (Received June 6, 1989; Accepted August 30, 1989)     

Water Pathways in Leaves of Hedera helix L. and Tradescantia virginiana L.

Hydraulic conductances of leaf tissues of Hedera helix and Tradescantiavirginiana leaves were measured. It was found that water couldflow most easily through the veins, but that the cell wallsof at least the ventral epidermis were more efficient at resupplyingwater lost from the epidermal tissue than was the mesophyllat rehydrating itself. Vein and bundle-sheath extensions, whichare characteristic of mesomorphic leaves (e.g. T. virginiana),seem to be important in maintaining a close hydraulic connectionbetween the epidermis and the vascular tissue. In leaves notcontaining vein and bundle-sheath extensions, typically xeromorphicleaves (e.g. H. helix), there is not such a close connectionbetween the epidermis and vascular tissue. This was shown inexperiments involving the sudden application of a reduced pressurepotential to either the epidermis or the other tissues of leaves,and the measurement of transient stomatal opening.     

Naturally Occurring Regenerative Differentiation of Xylem Around Adventitious Roots in Luffa cylindrica Seedlings

Regeneration of xylem induced by adventitious root formationin the hypocotyl of Luffa cylindrica Roem. seedlings is described.This naturally occurring form of xylem regeneration involvesthe formation of a bypass of regenerated tracheary elementsaround a root without external severance of the vascular strands.The regeneration of xylem around an adventitious root is polarand is very similar in its developmental pattern to the well-knownxylem regeneration induced by wounding vascular strands. Adventitious root formation, Luffa cylindrica Roem, regenerated tracheary elements, vascular differentiation, xylem regeneration     

Strcture of the Mature Embryo of Theobroma cacao L.

The mature embryo of Theobroma cacao L. consists of an embryonicaxis and two cotyledons. The cotyledonary tissue comprises thebulk of the embryo and contains mature and maturing vasculartissue surrounded by a bundle sheath. The cells of the groundtissue are filled with starch grains, anthocyanin pigments,or mucilage. The embryonic axis consists of epicotyl, hypocotyl,and root meristem. Maturation of the vascular tissue has begunin the procambium, where xylem maturation is ahead of phloemmaturation. Mucilage cells are found throughout the tissue of the axis.Most of the cells of the embryonic tissue contain starch grains.     

Naturally Occurring Regenerative Differentiation of Xylem Around Adventitious Roots in Luffa cylindrica Seedlings

Regeneration of xylem induced by adventitious root formationin the hypocotyl of Luff a cylindrica Roem. seedlings is described.This naturally occurring form of xylem regeneration involvesthe formation of a bypass of regenerated tracheary elementsaround a root without external severance of the vascular strands.The regeneration of xylem around an adventitious root is polarand is very similar in its developmental pattern to the well-knownxylem regeneration induced by wounding vascular strands. Adventitious root formation, Luffa cylindrica Roem, regenerated tracheary elements, vascular differentiation, xylem regeneration.     

Root Cell Ultrastructure in Developing Aerenchyma Tissue of Three Wetland Species

Patterns of root cortex cell development and ultrastructurewere analysed in Sagittaria lancifolia L., Thalia geniculataL. and Pontederia cordata L. using scanning and transmissionelectron microscopy (SEM, TEM). In all three species, cortexcells were arranged in radial columns extending from the endodermisto the hypodermis/epidermis. During gas space formation, thecortex cells elongated parallel to the root radius and shrankin the plane perpendicular to the radius leaving long and thinrows of cortex cells extending from the endodermis to the epidermis.Although the cortex cells appeared collapsed in tissue withwell-developed gas spaces, TEM revealed that the cortical cellsas well as the epidermal cells maintained intact membranes andmany normal organelles. Formation of root cortex tissue withwell-developed gas spaces does not require cell death in thesespecies. Living cortex cells in root tissue with mature gasspaces could provide a symplastic pathway for transport betweenthe root stele and the living epidermal cells. Copyright 2000Annals of Botany Company Sagittaria lancifolia, Thalia geniculata, Pontederia cordata, aerenchyma, root, wetland, development     

A Maize Mutant with an Altered Vascular Pattern

A recessive maize mutant with disrupted seedling developmentwas isolated following transpositional mutagenesis with Mutator.This mutant, initially identified during germination on thebasis of abnormal growth of the scutellar node, was designatedlsn1 (l arge s cutellar n ode). The mutant seedling exhibitsan enlarged primary root with a longitudinal groove and multipleseparate root tips. The mutant root is shorter than normal,because of defective cell elongation, and lacks lateral roots.The mutant plant shows defective leaves and reduced internodeelongation. Histological analyses on primary root, shoot, scutellarnode and juvenile leaves revealed a series of defects, all relatedto an irregular differentiation of vascular elements. In addition,in situ hybridization of mutant leaves demonstrates an abnormalpattern of expression of Knotted-1, a marker of meristem function.The presence of multiple roots fused together can be interpretedas suppression of the negative control responsible for the differentiationof only one root primordium. Therefore, the data obtained onseedlings of lsn1 point to a relationship between meristem activity,vascular differentiation and auxin polar transport, and mayallow the identification of a gene which is active during embryogenesis.Copyright2000 Annals of Botany Company Auxin, defective seedling, maize, meristem activity, vascular differentiation, Zea mays.     

Radial Hydraulic Conductivity of Individual Root Tissues of Opuntia ficus-indica (L.) Miller as Soil Moisture Varies

The constraints on water uptake imposed by individual root tissueswere examined forOpuntia ficus-indicaunder wet, drying, andrewetted soil conditions. Root hydraulic conductivity (L_P) andaxial conductance (K_h) were measured for intact root segmentsfrom the distal region with an endodermis and from midroot witha periderm;L_Pwas then measured for each segment with successivetissues removed by dissection. Radial conductivity (L_R) wascalculated fromL_PandK_hfor the intact segment and for the individualtissues by considering the tissue conductivities in series.Under wet conditions,L_Rfor intact distal root segments was lowestfor the cortex; at midroot, where cortical cells are dead,L_Rforthe cortex was higher and no single tissue was the predominantlimiter ofL_R.L_Rfor the endodermis and the periderm were similarunder wet conditions. During 30d of soil drying,L_Rfor the distalcortex increased almost three-fold due to the death of corticalcells, whereasL_Rfor the midroot cortex was unaffected;L_Rforthe endodermis and the periderm decreased by 40 and 90%, respectively,during drying. For both root regions under wet conditions, thevascular cylinder had the highestL_R, which decreased by 50–70%during 30d of soil drying. After 3d of rewetting, new lateralroots emerged, increasingL_Rfor the tissues outside the vascularcylinder as well as increasing uptake of an apoplastic tracerinto the xylem of both the roots and the shoot. The averageL_Rforintact root segments was similar under wet and rewetted conditions,but the conductivity of the tissues outside the vascular cylinderincreased after rewetting, as did the contribution of the apoplasticpathway to water uptake. Opuntia ficus-indica; prickly pear; root hydraulic conductivity; endodermis; periderm; apoplast; lateral root emergence     

Regeneration of the Root Cap of Zea mays L. and Pisum sativum L.: A Study with the Scanning Electron Microscope

Removal of the root cap from a root apex initiates regenerationof a new cap. The process has been followed using scanning electronmicroscopy. Quantitative data have been obtained for the growthin area of the exposed acroscopic surface of the quiescent centre(QC) and the increase in volume of the regenerating cap tissue.In Zea the surface of the QC shows an initial rapid increasein area followed by a slower increase. In Pisum the surfacearea increases uniformly, a rapid initial phase being absent.Together with observations on the behaviour of an incision atthe exposed surface, the results indicate that in Zea the capnormally imposes a constraint upon radial growth at the acroscopicsurface of the QC; in Pisum the QC appears not to be so constrained.The different responses may be related to the different arrangementsof cells at the apex of the meristem of these two species. Zea mays, Pisum sativum, maize, peao, scanning electron microscopy, root apex, regeneration     

Studies on the Roots of Musa acuminata cv. Gros Michel: 1. The Anatomy and Development of Main Roots

The anatomy of the adventitious roots of Musa acuminata cv.Gros Michel is described. Interesting anatomical features arethe occurrence of lysigenous lacunae in the cortex and the presenceof very large metaxylem vessels and internal phloem strandsin the stele. The organization of the root meristem is consideredin terms of present concepts. Histological preparations andautoradiographs suggest the existence of an area of relativequiescence in the meristem. The use of modified histogen terminologyin describing the apex is recommended. The development of thetissue systems is also described with emphasis on the differentiationof the vascular tissue.     

Identification of Shoot Apical Meristem Cells Committed to Form Vascular Elements in Pisum sativum L. and Vicia faba L.

A cytochemical study of naphthol AS-D esterases in vegetativeshoot apices of Pisum sativum and Vicia faba L. has shown thepresence of carboxyl esterases (E.C. 3.1.1.1 [EC] .) in those meristemcells already committed to form vascular elements. These cellsform a sequence linking the morphologically identifiable procambiumto the cells of the tunica layers at a site either already identifiableas the next primordium or which will form the next primordium.The implications of this result are briefly discussed in relationto the control of primordia formation and procambial cell development. Pisum sativum, Vicia faba, determination, vascular tissue, shoot apex, cytochemistry     

Some Observations on Infection of Arachis hypogaea L. by Rhizobium

The infection process in Arachis hypogaea by rhizobia differsfrom that normally found in Trifolium spp. in that no infectionthreads are formed. The root hairs, which are long (up to 4mm), septate, and often with large basal cells, occur only atthe sites of emerging lateral roots. Infection occurs only wherethe root hairs have large basal cells. Rhizobia cause curlingand deformation of the root hairs (as in Trifolium spp.) butenter the root at the junction of the root hair and the epidermaland cortical cells. The bacteria are distributed intercellularlyvia the middle lamellae and enter the cortical cells throughthe structurally altered cell wall, often close to the hostcell nucleus. The root hairs and large basal cells become infectedin the same way. Within the cortical cells of the emerging lateralroot the rhizobia multiply rapidly and the invaded cells dividerepeatedly to form the nodule tissue. Bacteriod formation occursonly when the host cell ceases to divide.