Ultrastructure,differentiation and cell wall texture of trichoblasts and root hairs of ceratopteris thalictroides (L.) brongn. (Parkeriaceae)

Trichoblasts and root hairs of Ceratopteris thalictroides (L.) Brongn. were studied by different techniques to survey their morphological features. Trichoblasts could be identified at an early stage by an intra-vacuolar precipitate appearing during fixation. Special attention was paid to root-hair initiation. No structures or changes were observed that play a role in the initiation of papilla formation. When the papilla is formed, vesicles and periplasmic membranes can be observed which may play a role in the weakening of the cell wall during the papilla outgrowth.During root-hair growth, the nucleus of the trichoblast moves from the trichoblast to a subapical position in the root hair. The nuclei of all root cells contain 2 types of nuclear inclusions, one of which is proteinaceous.The cell wall of the Ceratopteris root hair has a helicoidal texture and because the cortical microtubules run longitudinally in the root hair, no correlation can be made between the directions of microtubules and microfibrils in these root hairs.     

AtCSLD3, a cellulose synthase-like gene important for root hair growth in arabidopsis

A member of the cellulose synthase-like (subfamily D) gene family of Arabidopsis, AtCSLD3, has been identified by T-DNA tagging. The analysis of the corresponding mutant, csld3-1, showed that the AtCSLD3 gene plays a role in root hair growth in plants. Root hairs grow in phases: First a bulge is formed and then the root hair elongates by polarized growth, the so-called "tip growth." In the mutant, root hairs were initiated at the correct position and grew into a bulge, but their elongation was severely reduced. The tips of the csld3-1 root hairs easily leaked cytoplasm, indicating that the tensile strength of the cell wall had changed at the site of the tip. Based on the mutant phenotype and the functional conservation between CSLD3 and the genuine cellulose synthase proteins, we hypothesized that the CSLD3 protein is essential for the synthesis of polymers for the fast-growing primary cell wall at the root hair tip. The distinct mutant phenotype and the ubiquitous expression pattern indicate that the CSLD3 gene product is only limiting at the zone of the root hair tip, suggesting particular physical properties of the cell wall at this specific site of the root hair cell.     

Morphology, developmental ultrastructure and ultracytochemistry of staminal hairs in Bulbine inflata (Asphodelaceae) in relation to function

Results of light and electron microscopy and preliminary ultracytochemical studies of the staminal hairs of Bulbine inflata at different stages of development are reported here. The staminal filaments are covered with yellow, unicellular, linear, erecto-patent hairs. These staminal hairs arise directly as single cell outgrowths from epidermal cells of the filament. The surface of each hair is patterned with helical wall thickenings in an anticlockwise direction. This wall is covered by a thick folded cuticle, and formed of a loosely fibrillar cellulose layer. The hair cell possesses a cytoplasm rich in organelles. Especially ribosomes are abundant. Plastids contain large starch grains and peripheral lipid droplets. The smooth endoplasmic reticulum cisternae (SER) encircle the plastids and mitochondria; it is extended in the cytoplasm along the hair length. These hairs have functions in flower pollination attracting pollinators visually, secreting specific substances, providing increased surface area, protecting the filaments and being involved in their movement and vibration.     

Scanning Electron Microscopy of Plant Roots

A glycol methacrylate infiltration and polymerization techniquewas used to prepare clover roots inoculated with Rhizobium forscanning reflection electron microscopy. Root hairs and epidermalcells were coated with many bacteria; some bacteria seemed tobe embedded in the wall surface. Root hair tips were often smoothbut some older root hair surfaces showed a fibrillar meshworkpattern. Small granules c. 0.18 µm diameter were presenton the root hair and epidermal cell walls. The root cap, someroot hairs, and some epidermal cells were covered by an amorphousfilm thought to be the mucigel.     

Disruption of cellulose synthesis by 2,6‐dichlorobenzonitrile affects the structure of the cytoskeleton and cell wall construction in Arabidopsis

Cellulose is the major component of plant cell walls and is an important source of industrial raw material. Although cellulose biosynthesis is one of the most important biochemical processes in plant biology, the regulatory mechanisms of cellulose synthesis are still unclear. Here, we report that 2,6‐dichlorobenzonitrile (DCB), an inhibitor of cellulose synthesis, inhibits Arabidopsis root development in a dose‐ and time‐dependent manner. When treated with DCB, the plant cell wall showed altered cellulose distribution and intensity, as shown by calcofluor white and S4B staining. Moreover, pectin deposition was reduced in the presence of DCB when immunostained with the monoclonal antibody JIM5, which was raised against pectin epitopes. This result was confirmed using Fourier transform infrared (FTIR) analysis. Confocal microscopy revealed that the organisation of the microtubule cytoskeleton was significantly disrupted in the presence of low concentrations of DCB, whereas the actin cytoskeleton only showed changes with the application of high DCB concentrations. In addition, the subcellular dynamics of Golgi bodies labelled with N‐ST‐YFP and TGN labelled with VHA‐a1‐GFP were both partially blocked by DCB. Transmission electron microscopy indicated that the cell wall structure was affected by DCB, as were the Golgi bodies. Scanning electron microscopy showed changes in the organisation of cellulose microfibrils. These results suggest that the inhibition of cellulose synthesis by DCB not only induced changes in the chemical composition of the root cell wall and cytoskeleton structure, but also changed the distribution of cellulose microfibrils, implying that cellulose plays an important role in root development in Arabidopsis.     

Time Course of Cell Biological Events Evoked in Legume Root Hairs by Rhizobium Nod Factors: State of the Art

In many common legumes, when host-specific nodule bacteria meettheir legume root they attach to it and enter through root hairs.The bacteria can intrude these cells because they instigatein the hairs the formation of an inward growing tube, the infectionthread, which consists of wall material. Prior to infectionthread formation, the bacteria exploit the cell machinery forwall deposition by inducing the hairs to form a curl, in whichthe dividing bacteria become entrapped. In most species, Nodfactor alone (a lipochito-oligosaccharide excreted by bacteria)induces root hair deformation, though without curling, thusmost aspects of the initial effects of Nod factor can be elucidatedby studying root hair deformation. In this review we discussthe cellular events that host-specific Nod factors induce intheir host legume root hairs. The first event, detectable onlya few seconds after Nod factor application, is a Ca²⁺influxat the root hair tip, followed by a transient depolarizationof the plasma membrane potential, causing an increase in cytosolic[Ca²⁺] at the root hair tip. Also within minutes, Nod factorschange the cell organization by acting on the actin cytoskeleton,enhancing tip cell wall deposition so that root hairs becomelonger than normal for their species. Since the remodellingof the actin cytoskeleton precedes the second calcium event,Ca²⁺spiking, which is observed in the perinuclear area, we proposethat the initial cytoskeleton events taking place at the hairtip are related to Ca²⁺influx in the hair tip and that Ca²⁺spikingserves later events involving gene expression. Copyright 2001Annals of Botany Company Review, Nod factor, tip growth, root hair, Rhizobium, legume, cytoskeleton, calcium, symbiosis     

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.     

Root hair-specific disruption of cellulose and xyloglucan in <Emphasis Type="Italic">AtCSLD3</Emphasis> mutants,and factors affecting the post-rupture resumption of mutant root hair growth

The glycosyl transferase encoded by the cellulose synthase-like gene CSLD3/KJK/RHD7 (At3g03050) is required for cell wall integrity during root hair formation in Arabidopsis thaliana but it remains unclear whether it contributes to the synthesis of cellulose or hemicellulose. We identified two new alleles, root hair-defective (rhd) 7-1 and rhd7-4, which affect the C-terminal end of the encoded protein. Like root hairs in the previously characterized kjk-2 putative null mutant, rhd7-1 and rhd7-4 hairs rupture before tip growth but, depending on the growth medium and temperature, hairs are able to survive rupture and initiate tip growth, indicating that these alleles retain some function. At 21°C, the rhd7 tip-growing root hairs continued to rupture but at 5oC, rupture was inhibited, resulting in long, wild type-like root hairs. At both temperatures, the expression of another root hair-specific CSLD gene, CSLD2, was increased in the rhd7-4 mutant but reduced in the kjk-2 mutant, suggesting that CSLD2 expression is CSLD3-dependent, and that CSLD2 could partially compensate for CSLD3 defects to prevent rupture at 5°C. Using a fluorescent brightener (FB 28) to detect cell wall (1 → 4)-β-glucans (primarily cellulose) and CCRC-M1 antibody to detect fucosylated xyloglucans revealed a patchy distribution of both in the mutant root hair cell walls. Cell wall thickness varied, and immunogold electron microscopy indicated that xyloglucan distribution was altered throughout the root hair cell walls. These cell wall defects indicate that CSLD3 is required for the normal organization of both cellulose and xyloglucan in root hair cell walls.     

Some Observations on Root-hair Infection by Nodule Bacteria

The infection by nodule bacteria of the root hairs of Viciahirsuta and of twelve species of Trifolium described. The proportion of root hairs deformed by bacterial secretionsvaries between host species and form point to point along theroot but is unaffected by bacterial strain. Infection is morefrequent in regions of maximum curling. Infection threads differin their place of origin in the hair (apical or lateral), theirmode of development and detailed morphology; some of these differencesare characteristic of host species. The growth of infectionthreads is often arrested in the root hair. Least arrested growthoccurs on 2-week-old seedlings infected at about twenty sites.The proportion of lateral infections increases with seedlingage. Root-hair curling, infection-thread initiation and growth areassociated with the near presence of the host cell nucleus. The observational data support the hypothesis of formation ofthe infection thread by invagination of the root-hair wall. No infections were observed in the root hairs of nodulated plantsof Lotus hispida, Lotus angustissimus, and Anthyllis vulneraria.     

Rhizobium-stimulated Callose Formation in Clover Root Hairs and its Relation to Infection

Callose was detected in the cell walls of the tips of growingroot hairs of Trifolium species and the non-legume Phleum pratenseusing u.v. fluorescence of fresh material stained with 0·005%aniline blue. Inoculation of the roots with Rhizobium trifolii,R. leguminosarum, R. meliloti, and R. japonicum, or additionof 10^–7 and 10^–8 M indole-3-acetic acid (IAA) increasedtip callose formation. Most tip callose was formed at 12 °C, and amounts declinedprogressively at 18, 24, and 30 °C, with very little formedat 36 °C. Tip calloso usually became less and disappearedin individual root hairs as they aged. Callose which appeared prominently in the host cell walls atthe points of initiation of infection threads did not usuallydisappear as the hairs matured. There was little or no extensionof callose along the infection thread and none in the threadtip or in the cell nucleus. Presumptive regions of callose hadsimilar structure and electron density as root hair wall materialand were sometimes related to arrays of vesicles in the hostcytoplasm. The external surface of the hair wall bore smallpegs or papillae (0·1–0·2 µm) continuouswith the outer layer of the wall and possibly associated withattachment of bacteria. Bacteria were usually umboriate at thepoint of attachment and their polyphosphate granules were muchlarger near the root hair than at the distal end.     

Root Hairs as a Model System for Studying Plant Cell Growth

Root hairs are tip-growing projections that form on specializedepidermal cells. Physiological studies are identifying key transportersrequired for hair growth, and drug studies have been instructivein defining the role of the cytoskeleton in cell morphogenesis.Genetic analysis is identifying proteins involved in cell growthand the phenotypes of the mutants are instructive in definingthe precise function of these proteins in cellular morphogenesis.Recent progress in our understandings of cell growth using thearabidopsis root hair as a model system is reviewed. Copyright2001 Annals of Botany Company Arabidopsis, root hair, trichoblast, actin, microtubules, cell wall, genetics, calcium, potassium, phosphorus     

Ultrastructure of infection-thread development during the infection of soybean by Rhizobium japonicum

The location and topography of infection sites in soybean (Glycine max (L.) Merr.) root hairs spot-inoculated with Rhizobium japonicum have been studied at the ultrastructural level. Infections commonly developed at sites created when the induced deformation of an emerging root hair caused a portion of the root-hair cell wall to press against an adjacent epidermal cell, entrapping rhizobia within the pocket between the two host cells. Infections were initiated by bacteria which became embedded in the mucigel in the enclosed groove. Infection-thread formation in soybean appears to involve degradation of mucigel material and localized disruption of the outer layer of the folded hair cell wall by one or more entrapped rhizobia. Rhizobia at the site of penetration are separated from the host cytoplasm by the host plasmalemma and by a layer of wall material that appears similar or identical to the normal inner layer of the hair cell wall. Proliferation of the bacteria results in an irregular, wall-bound sac near the site of penetration. Tubular infection threads, bounded by wall material of the same appearance as that surrounding the sac, emerge from the sac to carry rhizobia roughly single-file into the hair cell. Growing regions of the infection sac or thread are surrounded by host cytoplasm with high concentrations of organelles associated with synthesis and deposition of membrane and cell-wall material. The threads follow a highly irregular path toward the base of the hair cell. Threads commonly run along the base of the hair cell for some distance, and may branch and penetrate into subjacent cortical cells at several points in a manner analagous to the initial penetration of the root hair.     

LIGHT AND ELECTRON MICROSCOPE STUDIES OF THE CELL WALL STRUCTURE OF THE ROOT HAIRS OF RAPHANUS SATIVUS

Dawes , Clinton J., and Edwin Bowler . (U. of California, Los Angeles.) Light and electron microscope studies of the cell wall structure of the root hairs of Raphanus sativus. Amer. Jour. Bot. 46(8): 561–565. Illus. 1959.—The structure and development of the cell wall of the root hair of Raphanus sativus were studied under the light and electron microscopes. The outer layer of the root hair consists of mucilage which covers the entire hair and forms a thick cap at the tip. Beneath the mucilage a thin cuticle covers the inner layers of the cell wall. These layers consist of cellulose microfibrils, varying in pattern, in a granular matrix, presumably pectic in nature. The microfibrils of the outer layer, apparently laid down at the tip, are reticulate in arrangement. In mature regions of the root hair, the wall is thickened by an inner layer of parallel and longitudinally orientated microfibrils. Pores in the cellulose wall are evident and increase in number and size near the base of the hair.     

2, 6-dichlorobenzonitrile Causes Multiple Effects on Pollen Tube Growth beyond Altering Cellulose Synthesis in Pinus bungeana Zucc

Cellulose is an important component of cell wall, yet its location and function in pollen tubes remain speculative. In this paper, we studied the role of cellulose synthesis in pollen tube elongation in Pinus bungeana Zucc. by using the specific inhibitor, 2, 6-dichlorobenzonitrile (DCB). In the presence of DCB, the growth rate and morphology of pollen tubes were distinctly changed. The organization of cytoskeleton and vesicle trafficking were also disturbed. Ultrastructure of pollen tubes treated with DCB was characterized by the loose tube wall and damaged organelles. DCB treatment induced distinct changes in tube wall components. Fluorescence labeling results showed that callose, and acidic pectin accumulated in the tip regions, whereas there was less cellulose when treated with DCB. These results were confirmed by FTIR microspectroscopic analysis. In summary, our findings showed that inhibition of cellulose synthesis by DCB affected the organization of cytoskeleton and vesicle trafficking in pollen tubes, and induced changes in the tube wall chemical composition in a dose-dependent manner. These results confirm that cellulose is involved in the establishment of growth direction of pollen tubes, and plays important role in the cell wall construction during pollen tube development despite its lower quantity.     

Root hairs: Specialized tubular cells extending root surfaces

Root hairs are tubular extensions of epidermal cells that have their origin either in any protoderm cell or in specialized protoderm cells called trichoblasts. These latter cells are the result of an asymmetric cytokinesis determined by the positioning of a pre-prophase band of microtubules. The smaller sibling cell is the trichoblast and specializes physiologically and structurally prior to root hair outgrowth. Several genes are involved in the initiation and outgrowth of root hairs. Elongation of root hairs is by tip growth, and, correlated with this, cytoplasmic organelles and cytoskeletal elements show a polarized distribution; the apical dome consists of numerous vesicles, many associated with cell wall synthesis. The relationship between cellulose microfibril deposition and the pattern of cortical microtubules has received considerable attention, as has the role of the cytoskeleton and calcium in controlling cytoplasmic streaming. Root hairs extend the absorbing surface of the root and therefore have been studied in terms both of physiological characteristics of the plasma membrane and uptake of water and of various ions in the soil solution. Many plant species develop soil sheaths (rhizosheaths) which protect the root surface from desiccation and harbour various microorganisms; root hairs are intimately involved in these sheaths. Various growth regulators have been studied in terms of their effect on the structure and function of root hairs. Root hairs play a significant role in the interaction between plants and nitrogen-fixing microorganisms (e.g.,Rhizobium, Frankia) and symbiotic mycorrhizal fungi.     

Plasmolysis and cell wall deposition in wheat root hairs under osmotic stress

We analysed cell wall formation in rapidly growing root hairs of Triticum aestivum under reduced turgor pressure by application of iso- and hypertonic mannitol solutions. Our experimental series revealed an osmotic value of wheat root hairs of 150 mOsm. In higher concentrations (200–650 mOsm), exocytosis of wall material and its deposition, as well as callose synthesis, still occurred, but the elongation of root hairs was stopped. Even after strong plasmolysis when the protoplast retreated from the cell wall, deposits of wall components were observed. Labelling with DiOC₆(3) and FM1-43 revealed numerous Hechtian strands that spanned the plasmolytic space. Interestingly, the Hechtian strands also led towards the very tip of the root hair suggesting strong anchoring sites that are readily incorporated into the new cell wall. Long-term treatments of over 24 h in mannitol solutions (150–450 mOsm) resulted in reduced growth and concentration-dependent shortening of root hairs. However, the formation of new root hairs does occur in all concentrations used. This reflects the extraordinary potential of wheat root cells to adapt to environmental stress situations.     

Growth and ultrastructure ofArabidopsis root hairs: therhd3 mutation alters vacuole enlargement and tip growth

The root hairs of plants are tubular projections of root epidermal cells and are suitable for investigating the control of cellular morphogenesis. In wild-typeArabidopsis thaliana (L.) Heynh, growing root hairs were found to exhibit cellular expansion limited to the apical end of the cell, a polarized distribution of organelles in the cytoplasm, and vesicles of several types located near the growing tip. Therhd3 mutant produces short and wavy root hairs with an average volume less than one-third of the wild-type hairs, indicating abnormal cell expansion. The mutant hairs display a striking reduction in vacuole size and a corresponding increase in the relative proportion of cytoplasm throughout hair development. Bead-labeling experiments and ultrastructural analyses indicate that the wavy-hair phenotype of the mutant is caused by asymmetric tip growth, possibly due to abnormally distributed vesicles in cortical areas flanking the hair tips. It is suggested that a major effect of therhd3 mutation is to inhibit vacuole enlargement which normally accompanies root hair cell expansion.     

The phenolic profile of maize primary cell wall changes in cellulose-deficient cell cultures

Cultured maize cells habituated to grow in the presence of the cellulose synthesis inhibitor dichlobenil (DCB) have a modified cell wall in which the amounts of cellulose are reduced and the amounts of arabinoxylan increased. This paper examines the contribution of cell wall-esterified hydroxycinnamates to the mechanism of DCB habituation. For this purpose, differences in the phenolic composition of DCB-habituated and non-habituated cell walls, throughout the cell culture cycle and the habituation process were characterized by HPLC. DCB habituation was accompanied by a net enrichment in cell wall phenolics irrespective of the cell culture phase. The amount of monomeric phenolics was 2-fold higher in habituated cell walls. Moreover, habituated cell walls were notably enriched in p-coumaric acid. Dehydrodimers were 5–6-fold enhanced as a result of DCB habituation and the steep increase in 8,5′-diferulic acid in habituated cell walls would suggest that this dehydrodimer plays a role in DCB habituation. In summary, the results obtained indicate that cell wall phenolics increased as a consequence of DCB habituation, and suggest that they would play a role in maintaining the functionality of a cellulose impoverished cell wall.     

Cortical microtubules and microfibril deposition in the cell wall of root hairs ofEquisetum hyemale

Summary The cell wall of root hairs ofEquisetum hyemale is shown to be composed of three different cell wall textures. The growing cell wall at the tip of the hair is composed of a dispersed texture of microfibrils, which continues along the outside of the whole hair. With increasing distance from the tip an increasing number of helicoidally arranged lamellae is deposited. These findings correspond with the observed isotropism of young hairs in polarized light.Hairs of approximately 4 days old become positive birefringent, indicating that longitudinally oriented layers prevail over layers with a transverse direction. This phenomenon starts at the base of the hair. Full-grown hairs are positive birefringent up to the tip and concordantly show a thick additional inner cell wall layer which forms a helical pattern the length of the hair, with a mean microfibril angle of 25 with the cell axis.Cortical microtubules, subjacent to the dispersed, the helicoidal and the helical wall texture are axially aligned and, thus, not in coalignment with the last deposited microfibrils.Coated and smooth vesicles are present in the cortical cytoplasm of both growing and full-grown hairs. Electron-dense profiles (20 nm in diameter), surrounded by a halo (of 50 nm) were observed on the wall-plasmalemma interface in full-grown hairs only. A relation of these structures with microfibril deposition could not be demonstrated. They might represent channels transporting material to the wall, which, in full-grown hairs, is heavily impregnated with a tawny brown substance.The general hypothesis that cortical microtubule orientation directs microfibril deposition is disputed.