Investigation of the Cell Surface Structures of Agrobacteria Involved in Bacterial and Plant Interactions

Agrobacterial cells produced straight microfibrils not only when in contact with wheat seedling roots, but also when in contact with each other. After 2 h of incubation, agrobacterial cells were found to form aggregates, in which the cells were in contact either directly or through thick straight microfibrils (bridges) of an unknown composition. The majority of the microfibrils were susceptible to attack by cellulase, although some of them showed resistance to this enzyme. Like the wild-type flagellated agrobacteria, their bald mutants produced long straight microfibrils. The cell surface structures of agrobacteria were examined by labeling them immunocytochemically with colloidal gold–conjugated antibodies against O-specific lipopolysaccharides, Vir proteins, and cellulase. Agrobacterial cells treated with acetosyringone and brought into contact were found to contain subpolar and polar cell surface structures. Antibodies against the VirB2 protein were able to interact with a tuft of thin microfibrils located on one pole of the agrobacterial cell whose virgenes were induced by acetosyringone but were unable to interact with the surface structures of the agrobacterial cells aggregated in liquid medium in the absence of wheat seedlings.     

Colonization of Wheat Root Hairs and Roots by Agrobacteria

Formation of extracellular structures in pure culture and in interaction with wheat root surface was studied by scanning and transmission electron microscopy. The effects of various factors (growth temperature as well as pretreatment of agrobacteria with kalanchoe extract, acetosyringone, and centrifugation) on formation of extracellular structures was tested. The data on Agrobacterium tumefaciens (wild-type strain C58 and mutants LBA2525 (virB2::lacZ) and LBA288 (without the Ti plasmid)) adhesion to wheat root surface and root hairs after pretreatment of agrobacteria with inducer of virulence genes (vir) acetosyringone were obtained. Formation of agrobacterial cell aggregates on wheat root hair tips was demonstrated. The proportion of root hairs with agrobacterial aggregates on the root hair tip insignificantly changed after pretreatment with acetosyringone but considerably increased after treatment of A. tumefaciens C58 and LBA2525 with kalanchoe leaf extract. The most active colonization of root hairs and formation of agrobacterial aggregates on hair root tips was observed at 22°C. The capacity of agrobacteria for adhesion on monocotyledon surface could be changed by pretreatment of bacteria with various surface-active substances. Bacterial cells subjected to centrifugation had a decreased capacity for attachment to both wheat root surface and root hairs. The relationship between the capacity for adhesion and pilus production in agrobacteria was considered.     

Formation of extracellular structures in conjugated cultures of agrobacteria

Electron microscopy of noncentrifugated agrobacterial cells on a nitrocellulose membrane labeled with colloid gold-conjugated antibodies to VirB1 showed that the labeled complex bound to acetosyringone (AS)-induced cells but failed to form red-colored stains during incubation with Ti aplasmid cells. Supramembrane structures of AS-treated A. tumefaciens cells were for the first time visualized by transmission electron microscopy. Colloid gold labeling of VirB2-specific antibodies showed that VirB2 proteins produce long thin pilus structures emerging at the poles of AS-induced agrobacterial cells but never on the surface untreated with AS and Ti-plasmid-free agrobacterial cells. As a rule, one (or rarely two) thread-like connections and bridges were observed between the cells at the primary contact stage. The bridges were not destroyed by SDS, did not react with VirB2-specific antibodies, and remained visible at 30 degrees C. Visible close contacts between mating bacteria did not cease after SDS treatment. SDS pretreatment of donor cells or a mating cell suspension significantly modified the efficiency of pTd33 plasmid transfer from donor to recipient agrobacterial cells. In the presence of AS the optimal temperature for transfer was 25 degrees C. The frequency of plasmid pTd33 transfer from A. tumefaciens via vir-dependent pathway decreased 2-4-fold due to increase of temperature from 19.25 to 31 degrees C.     

Localization of VirB1 protein on the agrobacterial cell surface.

Using colloidal gold-labelled VirB1-specific antibodies, it was found that VirB1 proteins are included into the composition of short pilus-like structures, which emerge at the poles of acetosyringone (AS)-induced agrobacterial cells.     

Conjugative transfer of pTd33-plasmid between strains of Agrobacterium

Supramembrane structures that connect conjugating agrobacterial cells were visualized for the first time by transmission electron microscopy. The primary contact of cells during conjugation was shown to occur through the formation of long pili containing no VirB1 protein. Pretreatment of agrobacterial cells with acetosyringone resulted in a six- to tenfold increase in the transfer frequency of the plasmid pTd33 at 19-25 degrees C and had almost no effect at 30 degrees C. The transfer of the plasmid pTd33 from A. tumefaciens strain GV3101 to plasmid-free A. tumefaciens strain UBAPF-2 was 16 times decreased after the centrifugation of cells. The transfer efficiency of the plasmid pTd33 from A. tumefaciens strain LBA2525 (virB2::lacZ) to plasmid-free A. tumefaciens strain UBAPF-2 was one order of magnitude lower than the transfer from the wild-type A. tumefaciens strain GV3101. Treatment of donor cells with 0.01% SDS before mating decreased the transfer efficiency by a factor of 26. The role of pili in the establishment of contact between conjugating cells of agrobacteria is discussed.     

Structure of the rigid-layer of Rhizobium cell wall. III. Electron microscopic evidence for the cellulose microfibrils association with peptidoglycan sacculi

The morphology of peptidoglycan layer of Rhizobium cell wall was examined by transmission electron microscopy. Peptidoglycans were isolated from intact cells after treatment with sodium dodecyl sulfate, extraction with aqueous 45% phenol and then with a mixture of chloroform-methanol. Finally rigid layers were digested with trypsin and chymotrypsin. The results indicate the presence of lump or bar-like structures on the surface of the cell shaped peptidoglycan sacculi. Evidence is provided suggesting that the cellulose microfibrils arise directly from these excrescences found on the peptidoglycan surface. Digestion with cellulase removed all cellulose microfibrils whereas the lumps and bars remained as an integral part of the Rhizobium peptidoglycan.     

Transfer of genetic information from agrobacteria to bacterial and plant cells: membrane and supramembrane structures involved in transfer

The review deals with the supramembrane and membrane structures involved in the initial contact (attachment) of an agrobacterial cell with a bacterial or plant cell during the transfer of the agrobacterial genetic information. The relationships between the donor cell attachment to the recipient cell surface and the infection and conjugation processes are discussed. Experimental data on the recently found agrobacterial pili and surface protein rhicadhesin, which are involved in the conjugative transfer of the plasmid between agrobacteria, are considered. The role of adhesive and conjugative pili of E. coli in the initial and tight contacts is analyzed in the context of the recently proved similarity between the mechanisms of agrobacterial transformation in plants and conjugative transfer in bacteria. Possible involvement of the pilus in the conjugative transfer of agrobacterial DNA across the membranes of donor and recipient (bacterial and plant) cells is discussed.     

Conjugative transfer of plasmid pTd33 in agrobacteria

Supramembrane structures that connect conjugating agrobacterial cells were visualized for the first time by transmission electron microscopy. The primary contact of cells during conjugation was shown to occur through the formation of long pili containing no VirB1 protein. Pretreatment of agrobacterial cells with acetosyringone resulted in a six-to tenfold increase in the transfer frequency of plasmid pTd33 at 19–25°C and had almost no effect at 30°C. The transfer of plasmid pTd33 fromA. tumefaciens strain GV3101 to plasmid-freeA. tumefaciens strain UBAPF-2 was 16 times decreased after the centrifugation of cells. The transfer efficiency of plasmid pTd33 fromA. tumefaciens strain LBA2525 (virB2::lacZ) to plasmid-freeA. tumefaciens strain UBAPF-2 was one order of magnitude lower than the transfer from the wild-typeA. tumefaciens strain GV3101. Treatment of donor cells with 0.01% SDS before mating decreased the transfer efficiency by a factor of 26. The role of pili in the establishment of contact between conjugating cells of agrobacteria is discussed.     

Transfer of T-DNA from agrobacteria into plant cells through cell walls and membranes

Discusses probable routes of agrobacterial penetration through the plant integumental tissues, cell wall, and plant cell plasmodesma. Analyzes the contribution of extracellular structures of agrobacteria in penetration through barriers of a plant cell, primary contact (adhesion), and during DNA transfer from bacterial (E. coli, A. tumefaciens) to recipient (bacterial or plant) cells. Discusses the relationship between donor cell adhesion to recipient cell surface and the infectious and conjugation processes. Considers the probable role of piles in conjugative transfer of agrobacterial DNA through membranes of donor and recipient (bacterial and plant) cells. Analyzes the contribution of the plant cell cytoskeleton to T-DNA transfer. Suggests a model of transport of T-DNA-VirD2 complex and VirE2 proteins through independent channels consisting of vir-coded proteins.     

Formation of TRA-dependent surface structures in Agrobacterium tumefaciens and their absence in R1 (deltatraR) mutant

Agrobacteria have Ti plasmid DNA delivering systems for the transfer to recipient cells by the conjugation mechanism. This transfer is absolutely dependent on induction tra genes. It is not clear which tra-dependent surface (extracellular) proteins (structures) are involved in the transport mechanism and whether these proteins also play a role in the contact formation. SDS-PAGE electrophoresis of proteins released from the cell showed disappearance of 63 and 67 kD proteins in R1(delta traR) strain, which were found in the growth medium and triton extract from the outer membrane of Ti plasmid-harboring A. tumefaciens R10 strains. The traR defective mutant did not express these proteins and had a higher hemagglutination and flocculation capacity than the wild strain. On the other hand, the wild strain showed D-galactose and N-acetyl-galactosamine specific hemagglutination which was not shown by traR mutant. Motility and chemotactic behavior of traR mutant in semisolid medium were defective. As a rule, one (or rarely two) thread-like connections in vir(-) and tra(+) conditions were observed on the agrobacterial cell surface. SDS pretreatment of agrobacterial cells had a significant effect on the expression of tra-dependent surface structures.     

Action of exo- and endo-type cellulases from Irpex lacteus on Valonia cellulose

Cellulolytic mode of action of the two highly purified exo- and endo-type cellulases from Irpex lacteus on pure Valonia cellulose was investigated. Electron microscopy substantiated that both cellulases are adsorbed preferentially into the internal parts of microfibrils in the network structure of the cellulose at initial stages before enzymatic hydrolysis, and that the adsorption ratio of both cellulases onto the external surfaces of microfibrils increased with incubation time although this tendency was less remarkable with the exo-type cellulase than with the endo-type one. The exo-type cellulase exhibited relatively high activity producing cellobiose throughout 12-h incubation, while the endo-type cellulase produced small amounts of cellooligosaccharides. The degree of polymerization was far more suppressed by the endo-type cellulase than by the exo-type one. Degradation by the cellulases in typical exo- and endo-fashions yielded quite different morphological patterns in the microfibrils. Exo-type cellulase loosened the network structure of microfibrils and made them slightly thinner, while endo-type cellulase caused conspicuous swelling and dissolution of individual microfibrils.     

Subcellular localization of cellulases in auxin-treated pea

Two forms of cellulase, buffer soluble (BS) and buffer insoluble (BI), are induced as a result of auxin treatment of dark-grown pea epicotyls. These two cellulases have been purified to homogeneity. Antibodies raised against the purified cellulases were conjugated with ferritin and were used to localize the two cellulases. Tissue sections were fixed in cold paraformaldehyde-glutaraldehyde and incubated for 1 h in the ferritin conjugates. The sections were washed with continuous shaking for 18 h and subsequently postfixed in osmium tetroxide. Tissue incubated in unconjugated ferritin was used as a control. A major part of BI cellulase is localized at the inner surface of the cell wall in close association with microfibrils. BS cellulase is localized mainly within the distended endoplasmic reticulum. Gogli complex and plasma membrane appear to be completely devoid of any cellulase activity. These observations are consistent with cytochemical localization and biochemical data on the distribution of these two cellulases among various cell and membrane fractions.     

Protein apparatus for horizontal transfer of agrobacterial T-DNA to eukaryotic cells

This review analyzes agrobacterial virulence proteins and recipient cell proteins involved in horizontal transfer of a T-DNA-protein complex. Specifically, it considers the early stages of the interactions of partners (signal exchange, attachment, close contact); T-DNA release from bacterial cells; channel formation for the transfer of ssDNA between the partners; transfer of agrobacterial T-DNA through the membrane, cytoplasm, and nuclear membrane of the recipient cell and its incorporation into the recipient cell genome. It further discusses possible pathways of agrobacterial ssDNA transfer to the recipient cells. In particular, the possible role of T-pili and VirE2 protein during conjugative transfer of agrobacterial ssDNA between donor and recipient cells is discussed.     

Visualization of enzymatic hydrolysis of cellulose using AFM phase imaging

Complete cellulase, an endoglucanase (EGV) with cellulose-binding domain (CBD) and a mutant endoglucanase without CBD (EGI) were utilized for the hydrolysis of a fully bleached reed Kraft pulp sample. The changes of microfibrils on the fiber surface were examined with tapping mode atomic force microscopy (TM–AFM) phase imaging. The results indicated that complete cellulase could either peel the fibrillar bundles along the microfibrils (peeling) or cut microfibrils into short length across the length direction (cutting) during the process. After 24 h treatment, most orientated microfibrils on the cellulose fiber surface were degraded into fragments by the complete cellulase. Incubation with endoglucanase (EGV or EGI) also caused peeling action. But no significant size reduction of microfibrils length was observed, which was probably due to the absence of cellobiohydrolase. The AFM phase imaging clearly revealed that individual EGV particles were adsorbed onto the surface of a cellulose fiber and may be bound to several microfibrils.     

Enhancement of growth by expression of poplar cellulase in Arabidopsis thaliana

To study the role of cellulose and cellulase in plant growth, we expressed poplar cellulase (PaPopCel1) constitutively in Arabidopsis thaliana. Expression increased the size of the rosettes due to increased cell size. The change in growth was accompanied by changes in biomechanical properties due to cell wall structure indicative of decrease in xyloglucan cross-linked with cellulose microfibrils by chemical analysis and nuclear magnetic resonance (NMR) spectra. The result supports the concept that the paracrystalline sites of cellulose microfibrils are attacked by poplar cellulase to loosen xyloglucan intercalation and this irreversible wall modification promotes the enlargement of plant cells.     

Fine structure of cell wall surfaces in the giant-cellular xanthophycean alga <Emphasis Type="Italic">Vaucheria terrestris</Emphasis>

The mechanical strength of cell walls in the tip-growing cells of Vaucheria terrestris is weakened by treatment with proteolytic enzymes. To clarify the morphological characteristics of the components maintaining cell wall strength, the fine structures of the cell walls, with and without protease treatment, were observed by transmission electron microscopy (TEM) and atomic force microscopy (AFM). Observations indicated that cellulose microfibrils were arranged in random directions and overlapped each other. Most of the microfibrils observed in the inner surface of the cell wall were embedded in amorphous materials, whereas in the outer surface of the cell wall, microfibrils were partially covered by amorphous materials. The matrix components embedding and covering microfibrils were almost completely removed by protease treatment, revealing layers of naked microfibrils deposited deeply in the cell wall. Topographic data taken from AFM observations provided some additional information that could not be obtained by TEM, including more detailed images of the granular surface textures of the matrix components and the detection of microfibrils in the interior of the cell wall. In addition, quantitative AFM data of local surface heights enabled us to draw three-dimensional renderings and to quantitatively estimate the extent of the exposure of microfibrils by the enzymatic treatment.     

Regeneration of the cell wall of protoplasts of the fission yeastSchizosaccharomyces versatilis in liquid media and their reversion to cells

Regeneration of the cell wall and reversion of protoplasts with a completely regenerated cell wall to cells were studied by light and electron microscopy in protoplasts of the fission yeastsSchizosaccharomyces versatilis. On their surface the protoplasts regenerated a complete new wall even m liquid media The wall regeneration began with the formation of a thin irregular net of flat bundles of long microfibrils and the net was gradually filled with aggregates of short straight microfibrils and small piles of amorphous material. Osmotically resistant organisms with regenerated walls were detected after a 4–6 h cultivation Depending on the nutrient medium used 10–80 % of protoplasts with the regenerated wall were obtained that reverted subsequently to cells. The high percentage of the wall regeneration and reversion to cells was reached by combining cultivation in a poor medium with that in a rich medium Reversion to cells could only occur after the protoplasts had regenerated rigid cell walls These walled protoplasts underwent septation, and, by polar growth, produced cylindrical cells, further dividing by fission.     

The tissue distribution of microfibrils reacting with a monospecific antibody to MAGP, the major glycoprotein antigen of elastin-associated microfibrils

Elastic tissue, when viewed in the electron microscope, consists of an amorphous component that is immunoreactive with anti-tropoelastin (TE) antibodies and microfibrils, that react with monospecific antibodies against a 31 kDa microfibrillar glycoprotein constituent, called MAGP. A detailed study of the tissue distribution of microfibrils and of the two elastic tissue antibodies has been carried out, using single and double-labeled immunogold techniques in high resolution electron microscopy. Microfibrils similar in appearance to those associated with elastic tissue and immunoreactive with the anti-MAGP antibody, have been demonstrated in many tissues in the absence of amorphous elastic tissue. In the majority of these tissues, specific anti-TE antibody localization was demonstrated in the immediate vicinity of the microfibrils, or alternatively, the microfibrils were shown to be in direct continuity with microfibrils of similar morphology, which were associated with material immunoreactive with anti-TE antibody. The diameter of these microfibrils varied between 8 nm and 16 nm. They were unbranched structures of indefinite length, with a tubular profile on cross section and periodic staining in longitudinal section. In some tissues, notably in the ciliary zonule and in the mesangial region of the renal glomerulus, microfibrils of similar morphology were demonstrated which were immunoreactive with anti-MAGP antibody, but which were unrelated to amorphous elastic tissue and with which anti-TE antibody localization could not be demonstrated. The evidence available supports the conclusion that all these microfibrils are members of a single class of structures, which are widely distributed in the tissues and which are secreted by a range of cell types. Attention is directed to the close relationship between these microfibrils and the basement membrane of the glomerulus, of uterine smooth muscle, of the basal cells of the epidermis and of the reticulum cells of the spleen.     

Evidence for an intramembrane component associated with a cellulose microfibril-synthesizing complex in higher plants

Freeze-fracture of rapidly frozen, untreated plant cells reveals terminal complexes on E-fracture faces and intramembrane particle rosettes on P-fracture faces. Terminal complexes and rosettes are associated with the ends of individual microfibril impressions on the plasma membrane. In addition, terminal complexes and rosettes are associated with the impressions of new orientations of microfibrils. These structures are sparse within pit fields where few microfibril impressions are observed, but are abundant over adjacent impressions of microfibrils. It is proposed that intramembrane rosettes function in association with terminal complexes to synthesize microfibrils. The presence of a cellulosic microfibril system in Zea mays root segments is confirmed by degradation experiments with Trichoderma cellulase.     

Cell-type-dependent enzymatic hydrolysis of palm residues: chemical and surface characterization of fibers and parenchyma cells

Chemical and surface characteristics of sulfite-pretreated royal palm sheath (RPS) fibers and parenchyma cells were investigated in order to study cell-type-dependent biomass hydrolysis by cellulase. Size, chemical composition, cellulose crystallinity and the exposure of cellulose microfibrils in pretreated RPS biomass affected the enzymatic accessibility and digestibility of different cell-type substrates.