Christine Andème-Onzighi

The reb1-1 Mutation of Arabidopsis. Effect on the Structure and Localization of Galactose-Containing Cell Wall Polysaccharides

The Arabidopsis (Arabidopsis thaliana) root epidermal bulger1-1 (reb1-1) mutant (allelic to root hair defective1 [rhd1]) is characterized by a reduced root elongation rate and by bulging of trichoblast cells. The REB1/RHD1 gene belongs to a family of UDP-d-Glucose 4-epimerases involved in the synthesis of d-Galactose (Gal). Our previous study showed that certain arabinogalactan protein epitopes were not expressed in bulging trichoblasts of the mutant. In this study, using a combination of microscopical and biochemical methods, we have investigated the occurrence and the structure of three major Gal-containing polysaccharides, namely, xyloglucan (XyG), rhamnogalacturonan (RG)-I, and RG-II in the mutant root cell walls. Our immunocytochemical data show that swollen trichoblasts were not stained with the monoclonal antibody CCRC-M1 specific for α-l-Fucp-(1→2)-β-d-Galp side chains of XyG, whereas they were stained with anti-XyG antibodies specific for XyG backbone. In addition, analysis of a hemicellulosic fraction from roots demonstrates the presence of two structurally different XyGs in reb1-1. One is structurally similar to wild-type XyG and the other is devoid of fuco-galactosylated side chains and has the characteristic of being insoluble. Similar to anti-XyG antibodies, anti-bupleuran 2IIC, a polyclonal antibody specific for galactosyl epitopes associated with pectins, stained all root epidermal cells of both wild type and reb1-1. Similarly, anti-RG-II antibodies also stained swollen trichoblasts in the mutant. In addition, structural analysis of pectic polymers revealed no change in the galactosylation of RG-I and RG-II isolated from reb1-1 root cells. These findings demonstrate that the reb1-1 mutation affects XyG structure, but not that of pectic polysaccharides, thus lending support to the hypothesis that biosynthesis of Gal as well as galactosylation of complex polysaccharides is regulated at the polymer level.

Immunocytochemical characterization of early-developing flax fiber cell walls

SummaryThe deposition and formation of a thick secondary wall is a major event in the differentiation of flax (Linum usitatissimum) fibers. This wall is cellulose-rich; but it also contains significant amounts of other matrix polymers which are noncellulosic such as pectins. We have used immunocytochemical techniques with antibodies specific for various epitopes associated with either pectins or arabinogalactan proteins (AGPs) to investigate the distribution of these polymers within the walls of differentiating young fibers of 1- and 2-week-old plants. Our results show that different epitopes exhibit distinct distribution patterns within fiber walls. Unesterified pectins recognized by polygalacturonic acid-rhamnogalacturonan I (PGA/RG-I) antibodies and rhamnogalacturonan II recognized by anti-RG-II-borate complex antibodies are localized all over the secondary wall of fibers. PGA/RG-I epitopes, but not RG-II epitopes, are also present in the middle lamellae and cell junctions. In marked contrast, β-(1→4) galactans recognized by the LM5 monoclonal antibody and AGP epitopes recognized by anti-β-(1→6) galactan and LM2 antibodies are primarily located in the half of the secondary wall nearest the plasma membrane. LM2 epitopes, present in 1-week-old fibers, are undetectable later in development, suggesting a regulation of the expression of certain AGP epitopes. In addition, localization of cellulose with the cellobiohydrolase I-gold probe reveals distinct subdomains within the secondary walls of young fibers. These findings indicate that, in addition to cellulose, early-developing flax fibers synthesize and secrete different pectin and AGP molecules.

Identification and partial characterization of proteins and proteoglycans encrusting the secondary cell walls of flax fibres

Abstract. Four proteins were isolated from depectinised elementary fibres of flax (Linum usitatissimum L.), using either alkali or cellulase digestion treatments. All the four proteins were characterized by a deficiency or low contents of hydroxyproline and by high levels of glutamic acid/glutamine and/or aspartic acid/asparagine. The two proteoglycans solubilized with cellulase strongly reacted with β-glucosyl Yariv reagent but not with α-glucosyl Yariv reagent and contained appreciable amounts of alanine, glycine, serine and threonine, suggesting a relationship with cell wall hydroxyproline-deficient arabinogalactan-proteins. The two alkali-extracted proteins did not show any reaction with β-glucosyl Yariv dye. Due to the harsh treatment, they might only partially represent the original proteins. Due to its high level of glycine (41%), one of these proteins might be classified as a glycine-rich protein. The latter polypeptide, of low molecular molar mass, contained 14.6% leucine and might consist of a domain related to leucine-rich proteins. The data show that these proteins and arabinogalactan-protein-like proteoglycans were strongly associated with the secondary walls of flax fibres. Their presence in small amounts (0.1–0.4%), raises the problem of their putative structural role.

Loss of pectin is an early event during infection of cocoyam roots by Pythium myriotylum

Cocoyam (Xanthosoma sagittifolium) is an important tuber crop in most tropical zones of Africa and America. In Cameroon, its cultivation is hampered by a soil-borne fungus Pythium myriotylum which is responsible for root rot disease. The mechanism of root colonisation by the fungus has yet to be elucidated. In this study, using microscopical and immunocytochemical methods, we provide a new evidence regarding the mode of action of the fungus and we describe the reaction of the plant to the early stages of fungal invasion. We show that the fungal attack begins with the colonisation of the peripheral and epidermal cells of the root apex. These cells are rapidly lost upon infection, while cortical and stele cells are not. Labelling with the cationic gold, which binds to negatively charged wall polymers such as pectins, is absent in cortical cells and in the interfacial zone of the infected roots while it is abundant in the cell walls of stele cells. A similar pattern of labelling is also found when using the anti-pectin monoclonal antibody JIM5, but not with anti-xyloglucan antibodies. This suggests that early during infection, the fungus causes a significant loss of pectin probably via degradation by hydrolytic enzymes that diffuse and act away from the site of attack. Additional support for pectin loss is the demonstration, via sugar analysis, that a significant decrease in galacturonic acid content occurred in infected root cell walls. In addition, we demonstrate that one of the early reactions of X. sagittifolium to the fungal invasion is the formation of wall appositions that are rich in callose and cellulose.

A (1→3,6)-β-d-galactosyl epitope containing uronic acids associated with bioactive pectins occurs in discrete cell wall domains in hypocotyl and root tissues of flax seedlings

Abstract We have used a well-characterized antibody specific for an epitope consisting of (1→3,6)-β-d-galactosyl residues with terminal glucuronic or 4-O-methylglucuronic acids of a bioactive pectin and immunocytochemistry to investigate its secretion and wall distribution in the hypocotyl and root tissues of flax seedlings. Our results show that this antigenic epitope is associated with flax pectins and is expressed by all the cells of the hypocotyl and root tissues. In the hypocotyl, it is abundant in the primary wall of epidermal cells as well as in the secondary wall of fiber cells, and is relatively less abundant in parenchyma cell walls. In contrast, the epitope is not detected in the middle lamellae and cell junction regions. In the root tip cells, immunogold electron microscopy shows that the cell walls of peripheral, columella, meristematic, cortical, and epidermal cells contain significant amounts of this epitope and that the distribution patterns are distinct. Together, these findings show that the antigenic epitope occurs in discrete domains of the wall implying a strict spatial regulation of the epitope-containing molecules. The results also show that, in root cells, the epitope is present within Golgi cisternae and is predominantly assembled in the trans and the trans-Golgi network compartments.

Differential Distribution of Callose and a (1→4)β‐D‐galactan Epitope in the Laticiferous Plant Euphorbia heterophylla L.

Euphorbia heterophylla L. produces latex in nonarticulated laticifers, which are giant, coenocytic cells that elongate indefinitely and grow intrusively between other cells. To identify characteristics that may determine the unusual growth patterns of nonarticulated laticifers, we have analyzed the composition of their cell walls using various antibodies against carbohydrate epitopes. These analyses revealed that the laticifer walls differ from those of their surrounding cells. The level of a (1→4)β‐D‐galactan epitope was much lower in laticifers than in other cells. Similarly, an anti‐(1→3)β‐D‐glucan antibody that recognizes callose did not label laticifer walls and walls immediately adjacent to laticifers, but it produced a punctuated labeling pattern in most other cells. In contrast to (1→4)β‐D‐galactan and callose, the (1→5)α‐arabinan epitope, the homogalacturonan epitopes recognized by the JIM5 and JIM7 antibodies, and xyloglucan were present at similar levels in laticifers and their surrounding cells. Furthermore, a broad homogalacturonan‐rich middle lamella was present between laticifers and adjacent cells. Comparison of the results in E. heterophylla with those previously reported for Asclepias speciosa indicate that the development of nonarticulated laticifers is associated with similar modifications in wall characteristics, even though laticifers in these species have presumably different evolutionary origins.

Composition of Flax Hypocotyl Fibres

Abstract Fibres in the middle part of the hypocotyl of young flax plantlets are organised in a circle of one hundred cells around the vascular cylinder. Apart from cellulose, their walls, of large thickness (2-5 μm), contain 30 to 50% of non-cellulosic polysaccharides (NCPs). NCPs consist mainly of β-(1-4)-galactan, together with rhamnogalacturonan of type I and polygalacturonic acid. Transmission electronic microscopy, coupled with immunocytochemical labellings shows that arabinogalactan proteins are also present and may contribute to the galactose and arabinose contents of cell walls. Mannose is one of the sugars tightly bound to cellulose residue, indicating that mannoseenriched polymers are good candidates to cross-link pectins with cellulose microfibrils.