Distribution of cell-wall xylans in bryophytes and tracheophytes: new insights into basal interrelationships of land plants

Xylans are known to be major cellulose-linking polysaccharides in secondary cell walls in higher plants. We used two monoclonal antibodies (LM10 and LM11) for a comparative immunocytochemical analysis of tissue and cell distribution of xylans in a number of taxa representative of all major tracheophyte and bryophyte lineages. The results show that xylans containing the epitopes recognized by LM10 and LM11 are ubiquitous components of secondary cell walls in vascular and mechanical tissues in all present-living tracheophytes. In contrast, among the three bryophyte lineages, LM11 binding was detected in specific cell-wall layers in pseudoelaters and spores in the sporophyte of hornworts, while no binding was observed with either antibody in the gametophyte or sporophyte of liverworts and mosses. The ubiquitous occurrence of xylans containing LM10 and LM11 epitopes in tracheophytes suggests that the appearance of these polysaccharides has been a pivotal event for the evolution of highly efficient vascular and mechanical tissues. LM11 binding in the sporophyte of hornworts, indicating the presence of relatively highly substituted xylans (possibly arabinoxylans), separates these from the other bryophytes and is consistent with recent molecular data indicating a sister relationship of the hornworts with tracheophytes.     

Monoclonal antibodies as molecular probes for cell wall antigens of the brown alga,Fucus

Monoclonal antibodies to cell wall carbohydrates were produced against carbohydrates extracted from the brown alga, Fucus distichus ssp. edentatus (de la Pyl.) Powell. Mouse spleen cells were immunized in vitro with alginate and fucans, and hybridoma cultures were screened by enzyme immunoassay. Most antibodies were immunoglobulin (Ig)M and one was IgA. Antigens were localized on methacrylate sections of Fucus tissues by indirect immunofluorescence. Each antibody labelled tissues with a distinctive distribution pattern in cell walls and extracellular matrix regions, demonstrating that each antibody was specific for a different extracellular epitope (i.e., antigenic determinant). Most antibodies also labelled intracellularly on at least one cell type. Punctate, fibrous or clumped labelling was characteristic of individual antibodies and provided information related to carbohydrate structure and solubility. These antibodies are molecular probes for small regions on cell wall polymers and should be valuable in studies of cell wall synthesis, secretion, assembly and modification as well as carbohydrate fine structure and function.Abbreviations EDTA ethylenediaminetetraacetic acid - EIA enzyme immunoassay - Ig immunoglobulin (IgG, IgM and IgA are immunoglobulin types)     

A cladistic approach to the phylogeny of the “Bryophytes”

The importance of a cladistic approach in reconstructing the phylogeny of bryophytes is discussed and illustrated by an analysis of the major groups of bryophytes with respect to the tracheophytes and the green algae. The cladistic analysis, using 51 characters taken from the literature, gives the following tentative results: (1) the embryophytes as a whole are monophyletic; (2) the bryophytes (sensu lato) are paraphyletic; (3) the mosses share a more recent common ancestor with the tracheophytes than do the liverworts or hornworts; (4) the hornworts appear to share a more recent common ancestor with the moss-tracheophyte lineage than with the liverworts; however, the existence of several homoplasies makes this placement more problematical; (5) the origin of alternation of generations in the embryophytes, based on out-group comparison with their oogamous, haplontic, algal sister groups, was by progressive elaboration of the primitively epiphytic sporophyte generation; and (6) the presence of vascular tissue (xylem and phloem) can best be interpreted as a synapomorphy of the moss-tracheophyte clade, and tracheids (xylem with ornamented walls) as a synapomorphy of the tracheophytes; therefore, the prevailing designation of “vascular plants” for the tracheophytes alone is inaccurate.     

Immunocytochemical localization of glutamine synthetase in Rhodobacter capsulatus E1F1 and Rhodopseudomonas acidophila

Intracellular localization of glutamine synthetase has been studied by immunochemical techniques with cryosections and London Resin sections of Rhodobacter capsulatus E1F1 and Rhodopseudomonas acidophila. For immunostaining, sections were sequentially incubated with monospecific anti-glutamine synthetase antibodies (R. capsulatus) and gold labelled goat anti-rabbit antibodies. Gold label was present in the cytoplasm but not in the cell walls. The antigen is not associated with the cell membrane or with photosynthetic vesicle whether these are round and randomly distributed (R. capsulatus) or flattened and organized in well defined stacks (R. acidophila). Our results also indicate that glutamine synthetase is absent from the central, nucleoid part of the cell. The enzyme is present in dense cytoplasmic patches, which appear to be RNA-ribosome-containing areas.Abbreviations GS glutamine synthetase - LR London Resin White     

Characterization of cell surface carbohydrates on asexual spores of the water moldSaprolegnia ferax

Summary In asexual reproduction of the water mold,Saprolegnia ferax, four distinct and sequentially produced spores are involved in dispersal, two of which are motile and two of which are nonmotile. Composition of cell surface glycoproteins may be important in dispersal strategies for each of these stages. Binding patterns of fluorescently labelled lectins were investigated to identify differences in glycoproteins of asexually produced dispersal stages. The pattern of lectin binding to zoospores was diverse. FITC-Con A bound to surfaces of zoospores and membranes of the water expulsion vacuole system, indicating the prescence of mannosyl and glucosyl residues. In zoospores incubated for more than 30 min in FITC-WGA and FITC-GS II. which bind N-acetyl glucosamine, fluorescence was sometimes localized in peripheral, intracellular patches. In shorter incubations, secondary zoospores bound these lectins along the groove region where K-bodies were located. Surfaces of cystospores typically bound FITC-WGA, but not FITC-GS II. FITC-GS II, however, bound to empty cystospore walls, probably because reactive sugars were available at the inner surface of the wall. Germ tubes emerging from cystospores bound labelled WGA and GS II, but not Con A. The same lectin binding pattern was found along discharge papilla of primary cystospores, indicating that modifications in cystospore walls associated with direct germination and zoospore discharge were similar. Thus, glycoproteins involved in early establishment of the hyphal system differ from those forming the cell surface of cystospores. Differences in the binding pattern of lectins to zoospores and cystospores highlight differences between cell surface carbohydrates of motile and nonmotile asexual stages.Abbreviations BPA lectin fromBauhinia purpurea - C₁ primary cystospore - C₂ secondary cystospore - Con A concanavalin A, lectin fromCanavalia ensiformis - DBA lectin fromDolichos biflorus - DIC Nomarski differential interference contrast optics - DS dilute salts - FITC fluorescein isothiocyanate - FUC fucose - Gal galactose - GalNAc N-acetyl galactosamine - Glc glucose - GlcNAc N-acetyl glucosamine - GS I Griffonia simplicifolia lectin I - GS II G. simplicifolia lectin II - Man mannose - MPA lectin fromMaclura pomifera - PC phase contrast optics - PNA lectin fromArachis hypogaea - SBA soybean agglutinin, lectin fromGlycine max - UEA-1 lectin fromUlex europaeus - WGA wheat germ agglutinin fromTriticum vulgare - WV water expulsion vacuole     

A 45 kDa protein isolated from the nodal walls of Chara corallina is localised to plasmodesmata

The cellular anatomy of the green alga, Chara corallina, was exploited to isolate putative plasmodesmataassociated proteins. In C. corallina , large internodal cells are symplastically connected via intervening nodal complexes of smaller cells which have plasmodesmata in their cell walls. Comparison of proteins extracted from walls with plasmodesmata (nodal complexes) with those from walls without plasmodesmata (external internodal walls) identified four putative plasmodesmata-associated proteins. These putative plasmodesmata-associated proteins were approximately 95, 45, 44 and 33 kDa. A monoclonal antibody (MAB45/22) was raised against the 45 kDa putative plasmodesmata-associated protein (CPAP45). Using immunofluorescence, this antibody co-localised with aniline blue induced fluorescence of callose in the source cell walls. MAB45/22 was localised to the plasmodesmata of C. corallina and, in particular, to the central cavity using immunogold cytochemistry. In contrast, a monoclonal antibody to callose specifically labelled the mouth of C. corallina plasmodesmata. MAB45/22 also labelled higher plant plasmodesmata.     

Use of monoclonal antibodies to detect Mn(II)-peroxidase in birch wood degraded by Phanerochaete chrysosporium

Summary A monoclonal antibody (Mab) produced to purified Mn(II)-peroxidase was visualized on and within cell corners of birch wood degraded by Phanerochaete chrysosporium using colloidal gold immuno-transmission electron microscopy techniques. Labelling of the fungal cell membrane and cell wall was also observed. The same Mab was used to visualize the penetration of extracellular fungal metabolite extracts, infiltrated into previously decayed wood. Binding of antibodies to the lignin-rich cell corner region of the middle lamella in wood decayed by P. chrysosporium was observed in sectioned wood blocks and in wood infiltrated with crude extracellular extracts from P. chrysospirium liquid cultures. When a control monoclonal antiserum, produced to extracellular metabolites of Postia (Poria) placenta and cross-reactive with fungal cellulase, was used in labelling, the cellulose rich region of the wood cell walls were labelled. Labelling in the middle lamella cell corners was only noted in what has been described as nonor poorly lignified cell corner regions. Offprint requests to: G. Daniel     

An alternative model for the earliest evolution of vascular plants

Land plants comprise the bryophytes and the polysporangiophytes. All extant polysporangiophytes are vascular plants (tracheophytes), but to date, some basalmost polysporangiophytes (also called protracheophytes) are considered non‐vascular. Protracheophytes include the Horneophytopsida and Aglaophyton/Teruelia. They are most generally considered phylogenetically intermediate between bryophytes and vascular plants and are therefore essential to elucidate the origins of current vascular floras. Here, we propose an alternative evolutionary framework for the earliest tracheophytes. The supporting evidence comes from the study of the Rhynie chert historical slides from the Natural History Museum of Lille (France). From this, we emphasize that Horneophyton has a particular type of tracheid characterized by narrow, irregular, annular and/or, possibly spiral wall thickenings of putative secondary origin, and hence that it cannot be considered non‐vascular anymore. Accordingly, our phylogenetic analysis resolves Horneophyton and allies (i.e. Horneophytopsida) within tracheophytes, but as sister to eutracheophytes (i.e. extant vascular plants). Together, horneophytes and eutracheophytes form a new clade called herein supereutracheophytes. The thin, irregular, annular to helical thickenings of Horneophyton clearly point to a sequential acquisition of the characters of water‐conducting cells. Because of their simple conducting cells and morphology, the horneophytophytes may be seen as the precursors of all extant vascular plant biodiversity.     

Polygalacturonase isozyme 2 binding and catalysis in cell walls from tomato fruit: pH and β-subunit effects

The catalytic activity of endopolygalacturonase (PG, EC 3.2.1.15) against pectic polymers in vitro is typically not expressed in vivo. In the present study, the binding and catalytic properties of PG isozyme 2 and the influence of the β-subunit protein were investigated in cell walls prepared from tomato fruit expressing an antisense gene to the β-subunit protein. Cell walls prepared from mature-green fruit were employed for binding and assay of PG2. Walls were provided with rate-limiting quantities of purified PG2 and incubated at 100 mM KCl, pH 4.5, or 25 mM KCl, pH 6.0. Cell walls of both β-subunit antisense and wild-type fruit retained comparable quantities of added PG2. The release of pectin from PG2-loaded walls was proportional to the quantity of added enzyme, consistent with a finite catalytic capacity of individual PG proteins. β-Subunit-antisense cell walls released 2- to 3-fold higher levels of pectin in response to PG2 than did wild-type walls. Cell walls incubated at pH 6.0 released lower quantities and showed less extensive depolymerization of pectins than did walls incubated at pH 4.5. Pectins recovered from ripe fruit were similar in size distribution to polymers released by PG2 at pH 6.0, indicating that pH can influence both quantitative and qualitative aspects of pectin metabolism and may be responsible for the restricted hydrolysis of pectins in vivo. Molecular mass differences were not evident in the polymers rendered freely soluble in response to PG2-mediated hydrolysis of β-subunit-antisense compared with wild-type cell walls. The solubilization of pectin from cell walls was not the sole indicator of the extent of PG-mediated cell wall hydrolysis. Hydrolytic modifications were also evident in a pectic fraction extracted from postcatalytic cell walls with 50 mM CDTA (trans-1,2-cyclohexanediamine-N,N,N′,N′-tetraacetic acid), and were more extensive for the β-subunit-antisense cell walls compared with the wild-type walls. Pectic polymers derived from ethanol insoluble-powders showed molecular mass downshifts during ripening but differences between the β-subunit-antisense and wild-type fruits were not observed.     

Structure and distribution of lignin in primary and secondary cell walls of maize coleoptiles analyzed by chemical and immunological probes

Lignin is an integral constituent of the primary cell walls of the dark-grown maize (Zea mays L.) coleoptile, a juvenile organ that is still in the developmental state of rapid cell extension. Coleoptile lignin was characterized by (i) conversion to lignothiolglycolate derivative, (ii) isolation of polymeric fragments after alkaline hydrolysis, (iii) reactivity to antibodies against dehydrogenative polymers prepared from monolignols, and (iv) identification of thioacidolysis products typical of lignins. Substantial amounts of lignin could be solubilized from the coleoptile cell walls by mild alkali treatments. Thioacidolysis analyses of cell walls from coleoptiles and various mesocotyl tissues demonstrated the presence of guaiacyl-, syringyl- and (traces of)p-hydroxyphenyl units besidesp-coumaric and ferulic acids. There are tissue-specific differences in amount and composition of lignins from different parts of the maize seedling. Electron-microscopic immunogold labeling of epitopes recognized by a specific anti-guaiacyl/syringyl antibody demonstrated the presence of lignin in all cell walls of the 4-d-old coleoptile. The primary walls of parenchyma and epidermis were more weakly labeled than the secondary wall thickenings of tracheary elements. No label was found in middle lamellae and cell corners. Lignin epitopes appeared first in the tracheary elements on day 2 and in the parenchyma on day 3 after sowing. Incubation of coleoptile segments in H₂O₂ increased the amount of extractable lignin and the abundance of lignin epitopes in the parenchyma cell walls. Lignin deposition was temporally and spatially correlated with the appearance of epitopes for prolinerich proteins, but not for hydroxyproline-rich proteins, in the cell walls. The lignin content of coleoptiles was increased by irradiating the seedlings with white or farred light, correlated with the inhibition of elongation growth, while growth promotion by auxin had no effect. It is concluded that wall stiffness, and thus extension growth, of the coleoptile can be controlled by lignification of the primary cell walls. Primary-wall lignin may represent part of an extended polysaccharide-polyphenol network that limits the extensibility of the cell walls.Abbreviations G, S, H guaiacyl, syringyl andp-hydroxyphenyl constituents of lignin - HRGP hydroxyproline-rich glycoprotein - LTGA lignothioglycolic acid - PRP proline-rich protein Dedicated to Professor Benno Parthier on occasion of his 65th birthdayDeceased 7 November 1996     

Localization of cell wall polysaccharides in nonarticulated laticifers ofAsclepias speciosa Torr.

Summary Asclepias speciosa Torr, has latex-containing cells known as nonarticulated laticifers. In stem sections of this species, we have analyzed the cell walls of nonarticulated laticifers and surrounding cells with various stains, lectins, and monoclonal antibodies. These analyses revealed that laticifer walls are rich in (1→4) β-D-glucans and pectin polymers. Immunolocalization of pectic epitopes with the antihomogalacturonan antibodies JIM5 and JIM7 produced distinct labeling patterns. JIM7 labeled all cells including laticifers, while JIM5 only labeled mature epidermal cells and xylem elements. Two antibodies, LM5 and LM6, which recognize rhamnogalacturonan I epitopes distinctly labeled laticifer walls. LM6, which binds to a (l→5) α-arabinan epitope, labeled laticifer walls more intensely than walls of other cells. LM5, which recognizes a (1→4) β-D-galac-tan epitope, did not label laticifer segments at the shoot apex but labeled more mature portions of laticifers. Also the LM5 antibody did not label cells at the shoot apical meristem, but as cells grew and matured the LM5 epitope was expressed in all cells. LM2, a monoclonal antibody that binds to β-D-glucuronic acid residues in arabinogalactan proteins, did not label laticifers but specifically labeled sieve tubes. Sieve tubes were also specifically labeled byRicinus communis agglutinin, a lectin that binds to terminal β-D-galactosyl residues. Taken together, the analyses conducted showed that laticifer walls have distinctive cytochemical properties and that these properties change along the length of laticifers. In addition, this study revealed differences in the expression of pectin and arabinogalactan protein epitopes during shoot development or among different cell types.     

Comparison between tracheary element lignin formation and extracellular lignin-like substance formation during the culture of isolated <Emphasis Type="Italic">Zinnia elegans</Emphasis> mesophyll cells

Lignin is synthesized not only during morphogenesis of vascular plants but also in response to various stresses. Isolated Zinnia elegans mesophyll cells can differentiate into tracheary elements (TEs), and deposit lignin into cell walls in TE-inductive medium (D medium). Meanwhile isolated mesophyll cells cultured in hormone-free medium (Co medium) accumulate stress lignin-like substance during culture. Therefore this culture system is suitable for study of lignin and lignin-like substance formation.     

Occurrence and evolutionary significance of RESISTANT CELL WALLS IN CHAROPHYTES AND BRYOPHYTES

A survey of charophycean green algal and bryophyte taxa revealed the frequent occurrence of vegetative cell walls that were characterized by a specific form of autofluorescence and resistance to high temperature acid treatment (acetolysis). The time of production and the location of resistant, autofluorescent cell walls varied among charophyte and bryophyte taxa in patterns that suggest that bryophytes inherited the capacity to produce such walls from charophyte ancestors. A number of charophytes produced resistant walls in response to desiccation stress, suggesting an evolutionarily early adaptive response. Coleochaete was unique among charophytes, but similar to all bryophytes tested in that sexual reproduction induced autofluorescence in cell walls of well-hydrated tissues at the placental junction. Maternal tissues in apical portions of the pseudoseta bearing Sphagnum sporophytes were characterized by autofluorescent, acetolysis-resistant cell walls similar to those observed in maternal cells adjacent to Coleochaete zygotes. These observations suggest that cell–cell stimulus–response interactions regulate deposition of autofluorescent compounds in placental cell walls, and that this characteristic may have been shared by the earliest embryophytes and their charophyte ancestors. Various bryophytes deposit autofluorescent, acid-resistant compounds at other adaptively significant sites including sporangial epidermis, spiral thickenings of elaters, rhizoids, and leaves in the special case of Sphagnum moss. Sphagnum and liverwort sporangial epidermis, which had been subjected to acetolysis or strong acid procedures commonly used to release microfossils from rock matrices, resembled published photographs of Ordovician–Devonian microfossils consisting of cellular scraps that have been attributed to earliest land plants. Our work suggests that at least some of these fossils, previously thought to represent “dispersed cuticles,” could be reinterpreted as earliest known remains of plant sporophytic tissues, and that they may be homologous with resistant sporangial epidermis of modern bryophytes. In general, the patterns of occurrence of resistant, autofluorescent cell walls in charophytes and bryophytes suggest repeated exaptation. Regulation of deposition appears to have been modified through time, so that resistant wall compounds have had a sequence of functions: desiccation resistance and/or microbial resistance in lower charophytes, a role in embryogenesis in Coleochaete and embryophytes, and finally, decay resistance in innovative structures that characterize bryophytes, such as rhizoids, sporangial epidermis, and elaters.     

Distribution of cell wall components in<Emphasis Type="Italic"> Sphagnum</Emphasis> hyaline cells and in liverwort and hornwort elaters

Spiral secondary walls are found in hyaline cells of Sphagnum, in the elaters of most liverworts, and in elaters of the hornwort Megaceros. Recent studies on these cells suggest that cytoskeletal and ultrastructural processes involved in cell differentiation and secondary wall formation are similar in bryophytes and vascular plant tracheary elements. To examine differences in wall structure, primary and secondary wall constituents of the hyaline cells of Sphagnum novo-zelandicum and elaters of the liverwort Radula buccinifera and the hornwort Megaceros gracilis were analyzed by immunohistochemical and chemical methods. Anti-arabinogalactan–protein antibodies, JIM8 and JIM13, labeled the central fibrillar secondary wall layer of Megaceros elaters and the walls of Sphagnum leaf cells, but did not label the walls of Radula elaters. The CCRC-M7 antibody, which detects an arabinosylated (16)-linked -galactan epitope, exclusively labeled hyaline cells in Sphagnum leaves and the secondary walls of Radula elaters. Anti-pectin antibodies, LM5 and JIM5, labeled the primary wall in Megaceros elaters. LM5 also labeled the central layer of the secondary wall but only during formation. In Radula elaters, JIM5 and another anti-pectin antibody, JIM7, labeled the primary wall. The distribution of arabinogalactan–proteins and pectic polysaccharides restricted to specific wall types and stages of development provides evidence for the developmental and functional regulation of cell wall composition in bryophytes. Monosaccharide-linkage analysis of Sphagnum leaf cell walls suggests they contain polysaccharides similar to those of higher plants. The most abundant linkage was 4-Glc, typical of cellulose, but there was also evidence for xyloglucans, 4-linked mannans, 4-linked xylans and rhamnogalacturonan-type polysaccharides.Abbreviations AGP Arabinogalactan–protein - Araf Arabinofuranose - Fucp Fucopyranose - GalAp Galacturonopyranose - Galp Galactopyranose - GlcAp Glucuronopyranose - HGA Homogalacturonan - Manp Mannopyranose - RG Rhamnogalacturonan - Rhap Rhamnopyranose - XG Xyloglucan - Xylp Xylopyranose     

Enzymatic treatments reveal differential capacities for xylan recognition and degradation in primary and secondary plant cell walls

The capacity of four xylan-directed probes (carbohydrate-binding modules Cf CBM2b-1-2 and Cj CBM15; monoclonal antibodies LM10 and LM11) to recognize xylan polysaccharides in primary and secondary cell walls of tobacco stem sections has been determined. Enzymatic removal of pectic homogalacturonan revealed differential recognition of xylans in restricted regions of cortical primary cell walls. Monoclonal antibody binding to these exposed xylans was more sensitive to xylanase action than carbohydrate-binding module (CBM) binding. In contrast, the recognition of xylans by CBMs in secondary cell walls of the same organ was more sensitive to xylanase action than the recognition of xylans by the monoclonal antibodies. A methodology was developed to quantify indirect immunofluorescence intensities, and to evaluate xylanase impacts. The four xylan probes were also used to detect xylan populations in chromatographic separations of solubilized cell wall materials from tobacco stems. Altogether, these observations reveal the heterogeneity of the xylans in plant cell walls. They indicate that although CBM and antibody probes can exhibit similar specificities against solubilized polymers, they can have differential capacities for xylan recognition in muro , and that the access of molecular probes and enzymes to xylan epitopes/ligands also varies between primary and secondary cell walls that are present in the same organ.     

Lectin binding sites on head structures of the spermatid and spermatozoon of the mosquito Culex quinquefasciatus (Diptera,Culicidae)

The presence of intranuclear and acrosomal lectin binding sites in spermatids and spermatozoa of the mosquito Culex quinquefasciatus was analysed. Direct and indirect lectin-gold techniques were used on LR White-embedded cells. The nuclear compartment was the structure most intensely labelled. Early spermatid nucleus showed moderate labelling for peanut agglutinin (PNA), Griffonia simplicifolia IB4 (GS-IB4) and Ricinus communis agglutinin (RCA), and light labelling for the other lectins tested. The sperm nucleus was intensely labelled by all lectins. The acrosome, an enzyme-containing structure, was labelled by some lectins. The anterior acrosomal region was labelled by PNA, while the proximal acrosomal region was labelled by PNA and G. simplicifolia II (GS II) lectins, and showed the presence of fucose residues with the use of Ulex europaeus I (UEA-I) lectin. The spermatozoa stored in the spermatheca showed the same pattern of labelling as that observed in spermatozoa localized in testis and seminal vesicles for all lectins tested. Carbohydrate residues in the nuclear compartment may be involved with the process of chromatin condensation. In the acrosomal region these residues may play a role in the process of spermoocyte interaction.     

Altered matrix polysaccharides in cell walls of pocket galls formed by an aphid on Distylium racemosum leaves

The present work reports the results of a study on the isolation and characterization of matrix polysaccharides in the cell walls of galls formed by an aphid (Neothoracaphis yanonis) on Distylium racemosum leaves. Cell walls were isolated from both healthy Distylium leaf and gall tissues and then extracted sequentially with cyclohexane‐trans‐1,2‐diaminetetra‐acetate (CDTA), Na₂CO₃, 1 m KOH, and 4 m KOH. The amount of pectin solubilized from gall cell walls was approximately 2.6‐fold higher than the pectin solubilized from leaf cell walls, whereas the amount of hemicellulose solubilized from gall cell walls was 1.4‐fold higher than that from normal leaf cell walls. When the polysaccharides were fractionated by anion‐exchange chromatography, considerable increases in arabinose and galactose were observed in CDTA‐soluble pectic polymer (fraction PI‐1) from gall cell walls, whereas the gall cell walls had less xylose in 1 m KOH‐soluble hemicellulosic polymers (fractions HI‐2, HI‐3, and HI‐4) than did the cell walls from the healthy leaf. The hemicellulosic polymers of the gall cell walls exhibited distinctly different patterns of molecular mass, compared with the healthy leaf cell walls. These results suggest that an extensive change occurs in the matrix polysaccharide structure of the cell walls of Distylium galls formed by an aphid. In addition, many glycosylhydrolase activities were detected in the protein fraction solubilized with strong saline solution from the gall cell walls, and the activities of β‐galactosidase, β‐xylosidase and α‐l ‐arabinofuranosidase were considerably increased under gall formation.     

Assessment of the biochemical composition of oilseed rape (Brassica napus L.) 13C-labelled residues by global methods,FTIR and 13C NMR CP/MAS

The biochemical composition of stems, pod walls and roots of oilseed rape (Brassica napus L.) plants, grown in a growth chamber with two levels of N fertiliser, was assessed by two global methods, i.e., serial extraction with the Van Soest's technique and temperature-programmed pyroanalysis (TP-Py). Statistical analysis of the effect of various parameters on the proportion of soluble components, hemicellulose, cellulose and lignin-like components in oilseed rape organs showed that the composition of plant materials depended on the N nutrition conditions during plant growth. Contents of soluble and hemicellulose fractions were affected by the technique used. Elsewhere, both global techniques resulted in similar proportions of skeletal cellulose (respectively 41 and 36% in low and high N stems, 37 and 30% in low and high N pod walls, 32 and 29% in low and high N roots) and of lignin-like components which ranged from about 7% in high N stems and pod walls to 16% in low N roots. Spectroscopy by FTIR showed a significant band at 1650 cm^–1 (amide I in proteins) in the root material (organ with the lowest C/N ratio) and the absence of lignin-specific bands. Carbon distribution by ¹³C NMR CP/MAS of labelled plants indicated that 60–64% was (cellulose + hemicellulose)-C, close to the values obtained by global methods. The proportion of aromatic-C (110–160 ppm) and phenolic ether was higher in roots than in stems and pod walls. Organs from oilseed rape plants with higher N contents exhibited a larger proportion of C in the 171 ppm chemical shift attributed to the peptide bond. The concomitance of a high level of aromatic and proteinaceous components in roots would reveal the presence of tannin–protein complexes in addition with true lignin.     

Common components of the infection thread matrix and the intercellular space identified by immunocytochemical analysis of pea nodules and uninfected roots

Three rat hybridoma cell lines have been isolated which produce monoclonal antibodies identifying a noduleenhanced, soluble component of Pisum sativum root nodules. These antibodies each recognized a protease-sensitive band (M_r 95K) on SDS-polyacrylamide gels. The 95K antigen was resolved by isoelectric focusing into acidic and neutral components which were separately detected by AFRC MAC 236 and MAC 265 respectively. The third antibody (MAC 204) reacted with both acidic and neutral components through an epitope that was sensitive to periodate oxidation. These monoclonal antibodies were used for immunogold localizations at light and electron microscopic levels. In each case, the antigen was shown to be present in the matrix that surrounds the invading rhizobia in infection threads and infection droplets, as well as in the intercellular spaces between plant cell walls of nodules and also of uninfected roots. By contrast, a fourth monoclonal antibody, AFRC JIM 5, labelled a pectic component in the walls of infection threads, and JIM 5 was also found to label the middle lamella of plant cell walls, especially at three-way junctions between cells. The composition and structure of the infection thread lumen is thus comparable to that of an intercellular space.     

Relationship between epitope density and immunoprecipitation of multivalent antigens by bivalent antibody: immunoprecipitation of adenylylated glutamine synthetase by anti-AMP antibodies

Escherichia coli glutamine synthetase (GS) preparations composed of 12 adenylylated subunits (GS₁₂^?) are almost completely precipitated by sheep Anti-AMP immunoglobulin G (IgG), whereas glutamine synthetase preparations containing 6 adenylylated subunits (GS₆^?) are only partially precipitated by the antibodies (R.J. Hohman, S.G. Rhee, and E.R. Stadtman, 1980, Proc. Nat. Acad. Sci. USA77, 7410–7414). By means of ¹²⁵I-labeled anti-AMP antibodies and double immunoprecipitation techniques, in which rabbit antiserum to sheep IgG or anti-GS antibodies were used to precipitate soluble immune complexes, it was demonstrated that under optimal conditions, both the soluble and insoluble immune complexes obtained with either GS₆^? or GS₁₂^? contain 0.5 mol antibody/mol adenylylated subunit. In agreement with the lattice theory of immuno-precipitation, soluble immune complexes are formed in antibody excess. Scatchard plots of binding data indicate that under conditions of antibody excess, one antibody molecule is bound to each AMP moiety of GS₁₂^?, whereas GS₆^? binds a maximum of only 0.68 antibody molecule/adenylylated subunit. We propose that with some species of GS₆^?, the distribution of adenylylated subunits favors monogamous interactions of the bivalent antibody with two subunits within the same GS molecule and thereby leads to the formation of small, soluble, immune complexes. Other explanations are considered. Only 30% of the antibody population that recognizes unconjugated 5′-AMP binds to the AMP moiety of adenylylated GS. Anti-AMP antiserum can be fractionated on a GS₁₂^?-Sepharose matrix into two subpopulations of antibody with strikingly different immunoprecipitation characteristics. Conversely, species of GS with various states of adenylylation ranging from 0 to 8 were separated from a GS₆^? preparation by means of affinity chromatography on an anti-AMP antibody-Sepharose matrix. Under optimal conditions, antibodies purified by affinity chromatography precipitated a smaller fraction of a GS₆^? preparation than did unfractionated antiserum. Competence of the purified antibody was nearly restored to that of the unfractionated serum by the addition of an enhancement factor present in the IgG fraction of nonimmune serum. The enhancement factor was not required for complete precipitation of GS^?₁₂ by purified antibodies. Contrary to most antibody-antigen reactions, immunoprecipitation of GS₆^? with anti-AMP antibodies is greater at 30 °C than at 4 °C.