The Cell Wall of the Arabidopsis Pollen Tube��Spatial Distribution, Recycling, and Network Formation of Polysaccharides

The pollen tube is a cellular protuberance formed by the pollen grain, or male gametophyte, in flowering plants. Its principal metabolic activity is the synthesis and assembly of cell wall material, which must be precisely coordinated to sustain the characteristic rapid growth rate and to ensure geometrically correct and efficient cellular morphogenesis. Unlike other model species, the cell wall of the Arabidopsis (Arabidopsis thaliana) pollen tube has not been described in detail. We used immunohistochemistry and quantitative image analysis to provide a detailed profile of the spatial distribution of the major cell wall polymers composing the Arabidopsis pollen tube cell wall. Comparison with predictions made by a mechanical model for pollen tube growth revealed the importance of pectin deesterification in determining the cell diameter. Scanning electron microscopy demonstrated that cellulose microfibrils are oriented in near longitudinal orientation in the Arabidopsis pollen tube cell wall, consistent with a linear arrangement of cellulose synthase CESA6 in the plasma membrane. The cellulose label was also found inside cytoplasmic vesicles and might originate from an early activation of cellulose synthases prior to their insertion into the plasma membrane or from recycling of short cellulose polymers by endocytosis. A series of strategic enzymatic treatments also suggests that pectins, cellulose, and callose are highly cross linked to each other.Upon contact with the stigma, the pollen grain swells through water uptake and develops a cellular protrusion, the pollen tube. During its growth in planta, the pollen tube invades the transmitting tissue of the pistil and finds its way to the ovary to deliver the male gametes for double fertilization to happen (Heslop-Harrison, 1987). Depending on the species, pollen tubes can grow extremely rapidly both in planta and in in vitro conditions. To fulfill its biological function, the pollen tube has to (1) adhere to and invade transmitting tissues (Hill and Lord, 1987; Lennon et al., 1998), (2) provide physical protection to the sperm cells, and (3) control its own shape and invasive behavior (Parre and Geitmann, 2005b; Geitmann and Steer, 2006). For all of these functions, the pollen tube cell wall plays an important regulatory and structural role. Although the pollen tube does not form a conventional secondary cell wall layer, its wall is assembled in two phases. The “primary layer” is mainly formed of pectins and other matrix components secreted at the apical end of the cell. The “secondary layer” is assembled by the deposition of callose in more distal regions of the cell (Heslop-Harrison, 1987). Depending on the species, cellulose microfibrils have been found to be associated either with the outer pectic or with the inner callosic layer. Unlike most other plant cells, cellulose is not very abundant representing only 10% of total neutral polysaccharides in Nicotiana alata pollen tubes, whereas callose accounts for more than 80% in this species (Schlüpmann et al., 1994).The biochemical composition of the pollen tube cell wall has been well characterized in many species such as Lilium longiflorum (Lancelle and Hepler, 1992; Jauh and Lord, 1996), tobacco (Nicotiana tabacum; Kroh and Knuiman, 1982; Geitmann et al., 1995; Ferguson et al., 1998; Derksen et al., 2011), Petunia hybrida (Derksen et al., 1999), Pinus sylvestris (Derksen et al., 1999), and Solanum chacoense (Parre and Geitmann, 2005a). But for Arabidopsis (Arabidopsis thaliana), the model for plant molecular biology studies (Arabidopsis Genome Initiative, 2000), there is a striking lack of quantitative information concerning the composition of the pollen tube cell wall as well as the spatial distribution of its components. This is all the more surprising because numerous mutants defective in enzymes involved in cell wall synthesis exhibit a pollen tube phenotype (for example, Jiang et al., 2005; Nishikawa et al., 2005; Wang et al., 2011). Two studies have characterized the Arabidopsis pollen germinating in vitro (Derksen et al., 2002) and in vivo (Lennon and Lord, 2000), but both are qualitative rather than quantitative. A biochemical study by Dardelle and coworkers investigated the cell wall sugar composition in a more quantitative way but does not provide any detailed spatial information (Dardelle et al., 2010; Lehner et al., 2010). This lack of information is not surprising given that until recently Arabidopsis pollen was known to be rather challenging to germinate reproducibly in vitro and more difficult to manipulate than the pollen of many other plant species (Bou Daher et al., 2009). With the publication of optimized methods for in vitro germination (Boavida and McCormick, 2007; Bou Daher et al., 2009), it has become much more feasible to germinate healthy-looking Arabidopsis pollen tubes in vitro in a highly reproducible way.The precisely controlled spatial distribution of biochemical components in the pollen tube cell wall is crucial for shape generation and maintenance of this perfectly cylindrical cell (Geitmann and Parre, 2004; Aouar et al., 2010; Fayant et al., 2010; Geitmann, 2010). The pollen tube, therefore, represents an ideal model system to study the link between intracellular signaling, biochemistry, cell mechanical properties, and morphogenesis in plant cells. Because of its typically fast growth rates, it responds quickly to any environmental triggers such as pharmacological, hormone, or enzymatic treatments. Adding Arabidopsis to the group of commonly studied pollen tube species is particularly timely, because one-third of the approximately 800 cell wall synthesis genes identified in this species are expressed in or are specific to its pollen (Pina et al., 2005). Therefore, the Arabidopsis pollen tube has become a valuable system for cell wall studies, especially with the increasing availability of cell wall mutant lines (Liepman et al., 2010).Here we describe the biochemical composition of the Arabidopsis pollen tube cell wall grown in in vitro conditions using immunocytochemical labeling coupled with epifluorescence and electron microscopic techniques. Rather than relying on imaging alone, we developed a quantitative strategy to assess the precise spatial distribution of cell wall components. This quantitative approach will provide an important tool and baseline dataset for the investigation of mutant phenotypes and for the interpretation of pharmacological studies. Furthermore, we used selective and strategically combined enzymatic digestions to determine the degree of connectivity between the individual types of cell wall polysaccharide networks.     

Complex Intramolecular Mechanics of G-actin — An Elastic Network Study

Systematic numerical investigations of conformational motions in single actin molecules were performed by employing a simple elastic-network (EN) model of this protein. Similar to previous investigations for myosin, we found that G-actin essentially behaves as a strain sensor, responding by well-defined domain motions to mechanical perturbations. Several sensitive residues within the nucleotide-binding pocket (NBP) could be identified, such that the perturbation of any of them can induce characteristic flattening of actin molecules and closing of the cleft between their two mobile domains. Extending the EN model by introduction of a set of breakable links which become effective only when two domains approach one another, it was observed that G-actin can possess a metastable state corresponding to a closed conformation and that a transition to this state can be induced by appropriate perturbations in the NBP region. The ligands were roughly modeled as a single particle (ADP) or a dimer (ATP), which were placed inside the NBP and connected by elastic links to the neighbors. Our approximate analysis suggests that, when ATP is present, it stabilizes the closed conformation of actin. This may play an important role in the explanation why, in the presence of ATP, the polymerization process is highly accelerated.     

Studies on the Cell Wall of Piricularia oryzae†

The chemical constituents of the cell wall of Piricularia oryzae, the pathogenic fungus of rice blast disease, were studied with the aids of chemical analysis, X-ray diffraction, infra-red absorption and enzymatic degradation. The sugar constituents were identified by chromatography as glucose (62%), mannose (4%), galactose (0.5%), and hexosamine (13%). The acidic amino acid rich protein was comprised 4.6% in the cell wall. The cell wall consists of at least three different polysaccharide complexes: a) α-Heteropolysaccharide protein complex containing mannose, glucose and galactose, b) β-1,3-Glucan containing β-1, 6-linked branch, c) Chitin like substance.     

Project Head Start—An Evaluation of the Medical Components in California

Half of 1,135 children medically examined as a part of Project Head Start in California had one or more conditions that warranted referral to a physician or dentist, and only one-fifth of these were under care. In the judgment of the examining physicians, one-third of the referable medical conditions were described as “major.” Follow-up procedures were variable and not very successful.Increased local medical society participation in planning the health services for these children is recommended as an especially important step in securing care for the problems that are identified.     

Mechanical Cell–Cell Communication in Fibrous Networks: The Importance of Network Geometry

Cells contracting in extracellular matrix (ECM) can transmit stress over long distances, communicating their position and orientation to cells many tens of micrometres away. Such phenomena are not observed when cells are seeded on substrates with linear elastic properties, such as polyacrylamide (PA) gel. The ability for fibrous substrates to support far reaching stress and strain fields has implications for many physiological processes, while the mechanical properties of ECM are central to several pathological processes, including tumour invasion and fibrosis. Theoretical models have investigated the properties of ECM in a variety of network geometries. However, the effects of network architecture on mechanical cell–cell communication have received little attention. This work investigates the effects of geometry on network mechanics, and thus the ability for cells to communicate mechanically through different networks. Cell-derived displacement fields are quantified for various network geometries while controlling for network topology, cross-link density and micromechanical properties. We find that the heterogeneity of response, fibre alignment, and substrate displacement fields are sensitive to network choice. Further, we show that certain geometries support mechanical communication over longer distances than others. As such, we predict that the choice of network geometry is important in fundamental modelling of cell–cell interactions in fibrous substrates, as well as in experimental settings, where mechanical signalling at the cellular scale plays an important role. This work thus informs the construction of theoretical models for substrate mechanics and experimental explorations of mechanical cell–cell communication.     

Cell Wall Galactofuranan of “Paenarthrobacter pyridinovorans” VKM Ac-1098D

Microbiology - The structure of the cell wall glycopolymer and the taxonomic position of the pyridine-degrading strain VKM Ac-1098D were established. By using chemical and NMR spectroscopic...     

Cell Wall Lysin as a Component of the Bacteriophage ?6 Virion

Cell wall lytic activity was found in particles of the lipid-containing bacteriophage ø6. The activity can be extracted from the virion with Triton X-100 in the presence of salt. This treatment removes the membrane-like envelope of the virion which includes five proteins. The lysin requires detergent for in vitro activity. Virus particles formed in nonsuppressor cells by several classes of ø6 nonsense mutants contained the lysin activity; however, particles formed by a mutant (unable to make proteins P5 and P11) had very low activity; high activity was produced when particles were formed in a suppressor host. A study of the time course of the appearance of the lysin during infection showed that it appeared and increased in cells infected with wild-type virus and in suppressor cells infected with a mutant of class 511, but it did not increase in nonsuppressor cells infected with the class 511 mutant. It is concluded that protein P5 is a component of the lysin and that the role of its activity is in both early and late stages of infection. In particular, the lysin may be necessary for the passage of the infecting core of the virion through the cell wall of the bacterium, as well as in the final lysis necessary for the liberation of progeny phage. A mutant of the virus that produces a larger-than-normal protein P10 does not induce normal lysin activity in host Pseudomonas phaseolicola HB10Y, although it does in strain ERA Pseudomonas pseudoalcaligenes. This indicates that protein P5 is probably not sufficient for lysin activity, but the nature of the interaction between P5 and P10 is unknown.     

Aβ Mediated Diminution of MTT Reduction—An Artefact of Single Cell Culture?

The 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-tetrazoliumbromide (MTT) reduction assay is a frequently used and easily reproducible method to measure beta-amyloid (Aβ) toxicity in different types of single cell culture. To our knowledge, the influence of Aβ on MTT reduction has never been tested in more complex tissue. Initially, we reproduced the disturbed MTT reduction in neuron and astroglia primary cell cultures from rats as well as in the BV2 microglia cell line, utilizing four different Aβ species, namely freshly dissolved Aβ (25-35), fibrillar Aβ (1-40), oligomeric Aβ (1-42) and oligomeric Aβ (1-40). In contrast to the findings in single cell cultures, none of these Aβ species altered MTT reduction in rat organotypic hippocampal slice cultures (OHC). Moreover, application of Aβ to acutely isolated hippocampal slices from adult rats and in vivo intracerebroventricular injection of Aβ also did not influence the MTT reduction in the respective tissue. Failure of Aβ penetration into the tissue cannot explain the differences between single cells and the more complex brain tissue. Thus electrophysiological investigations disclosed an impairment of long-term potentiation (LTP) in the CA1 region of hippocampal slices from rat by application of oligomeric Aβ (1-40), but not by freshly dissolved Aβ (25-35) or fibrillar Aβ (1-40). In conclusion, the experiments revealed a glaring discrepancy between single cell cultures and complex brain tissue regarding the effect of different Aβ species on MTT reduction. Particularly, the differential effect of oligomeric versus other Aβ forms on LTP was not reflected in the MTT reduction assay. This may indicate that the Aβ oligomer effect on synaptic function reflected by LTP impairment precedes changes in formazane formation rate or that cells embedded in a more natural environment in the tissue are less susceptible to damage by Aβ, raising cautions against the consideration of single cell MTT reduction activity as a reliable assay in Alzheimer''s drug discovery studies.     

Degradation of Cell Wall of Mucor mucedo by Chitosanase from Bacillus R–4

To broaden our understanding of extracellular proteins of Aspergillus oryzae at the conidial germination stage, analyses of the secreted proteins during germination were carried out. Taka-amylase A (TAA), glucoamylase (GLAA), and aspergillopepsin A (PEPA) were identified as the main products by peptide mass fingerprinting. TAA and PEPA were detected simultaneously with the formation of germ tubes. With the development of germination, the pH of the medium fell from 5.5 to 3.5. The secreted PEPA had a pro-sequence and likely shifted from 42 kDa to 41 kDa below pH 4.6, indicating that the precursor of PEPA was secreted and underwent pH-dependent processing. Furthermore, the 41 kDa protein was trapped by the addition of pepstatin A, the specific inhibitor of PEPA, suggesting that the maturation of pro-PEPA was a stepwise autoprocessing upon acidification of the medium and itself was an intermediate of the processing. It was implied that PEPA plays an important role at the early germination stage.     

Golgi-associated cPLA2α Regulates Endothelial Cell–Cell Junction Integrity by Controlling the Trafficking of Transmembrane Junction Proteins

In endothelial cells specifically, cPLA2α translocates from the cytoplasm to the Golgi complex in response to cell confluence. Considering the link between confluence and cell–cell junction formation, and the emerging role of cPLA2α in intracellular trafficking, we tested whether Golgi-associated cPLA2α is involved in the trafficking of junction proteins. Here, we show that the redistribution of cPLA2α from the cytoplasm to the Golgi correlates with adherens junction maturation and occurs before tight junction formation. Disruption of adherens junctions using a blocking anti-VE-cadherin antibody reverses the association of cPLA2α with the Golgi. Silencing of cPLA2α and inhibition of cPLA2α enzymatic activity using various inhibitors result in the diminished presence of the transmembrane junction proteins VE-cadherin, occludin, and claudin-5 at cell–cell contacts, and in their accumulation at the Golgi. Altogether, our data support the idea that VE-cadherin triggers the relocation of cPLA2α to the Golgi and that in turn, Golgi-associated cPLA2α regulates the transport of transmembrane junction proteins through or from the Golgi, thereby controlling the integrity of endothelial cell–cell junctions.     

Induction of β-Glucosidase in Botrytis cinerea by Cell Wall Fractions of the Host Plant

The pathogenicity of Botrytis cinerea has been found to correlate positively with the β-glucosidase activity. In this report, the relationship between the induction of β-glucosidase and the components of host plant tissues was studied by the use of tissue fractions and cellulose-related compounds.

The most active enzyme induced by the crude fiber fraction and Avicel was β-glucosidase, among the cell wall degrading enzymes tested. The β-glucosidase was very inducible in the strains with strong pathogenicity, and intensively degraded the fiber fraction made from apple fruit tissues. The same degradation of the cell wall fraction was demonstrated with the purified enzyme.     

The Development of Activity of Cell Wall Bound β-Fructofuranosidase with Ripening and Senescence of Tomato Fruit

Optically active trisubstituted and tetrasubstituted cyclopentanes, with proper functional groups of proper stereochemistry as precursors for chiral synthesis of brefeldin A and prostaglandins, were prepared stereoselectively from carbohydrate.     

α-1,6-Mannosylation of N-Linked Oligosaccharide Present on Cell Wall Proteins Is Required for Their Incorporation into the Cell Wall in the Filamentous Fungus Neurospora crassa

The enzyme α-1,6-mannosyltransferase (OCH-1) is required for the synthesis of galactomannans attached to the N-linked oligosaccharides of Neurospora crassa cell wall proteins. The Neurospora crassa och-1 mutant has a tight colonial phenotype and a defective cell wall. A carbohydrate analysis of the och-1 mutant cell wall revealed a 10-fold reduction in the levels of mannose and galactose and a total lack of 1,6-linked mannose residues. Analysis of the integral cell wall protein from wild-type and och-1 mutant cells showed that the mutant cell wall had reduced protein content. The och-1 mutant was found to secrete 18-fold more protein than wild-type cells. Proteomic analysis of the proteins released by the mutant into the growth medium identified seven of the major cell wall proteins. Western blot analysis of ACW-1 and GEL-1 (two glycosylphosphatidylinositol [GPI]-anchored proteins that are covalently integrated into the wild-type cell wall) showed that high levels of these proteins were being released into the medium by the och-1 mutant. High levels of ACW-1 and GEL-1 were also released from the och-1 mutant cell wall by subjecting the wall to boiling in a 1% SDS solution, indicating that these proteins are not being covalently integrated into the mutant cell wall. From these results, we conclude that N-linked mannosylation of cell wall proteins by OCH-1 is required for their efficient covalent incorporation into the cell wall.The fungal cell wall is an important organelle that protects the cell from various environmental stresses. It is a dynamic structure that interacts with the environment and is modified to accommodate growth, cell division, and development. Fungal cell walls have been shown to contain β-1,3-glucan, α-1,3-glucan, β-1,6-glucan, mixed β-1,3/β-1,4-glucans, chitin, and mannan/galactomannan (6, 19). These polysaccharide polymers constitute 80 to 85% of the cell wall mass, while glycoproteins constitute the remaining 15 to 20% (6). The cell wall glycoproteins are required for vital functions, like structural support, signal transduction, biofilm formation, and cell wall biosynthesis. In the case of pathogenic fungi, the cell wall is critical for the invasion of host tissues (8). Because of their accessibility and the crucial functions they perform, cell wall proteins could be important targets for the development of antifungal therapeutics.The glucan and chitin cell wall polymers are synthesized by enzyme complexes (glucan synthases and chitin synthases) that are associated with the plasma membrane. Glucan and chitin are vectorially passed into the cell wall space during synthesis and cross-linked together in the cell wall space. The mannan and galactomannan present in the cell wall are found as glycoconjugates on cell wall proteins. Mannosylation of cell wall proteins occurs in the endoplasmic reticulum (ER) and Golgi apparatus at O-linked and N-linked glycosylation sites. In Saccharomyces cerevisiae, mannosylation of N-linked glycosylation is initiated by the addition of an α-1,6-linked mannose residue by Och1p (33). In the filamentous fungus Neurospora crassa, the structure of the galactomannan associated with N-linked sites has not been definitively determined, but N. crassa has most of the enzymes defined in yeast for the mannosylation of N-linked oligosaccharides (14). An analysis of N-linked oligosaccharides from N. crassa glycoproteins showed that the glycoproteins are modified by the addition of short α-1,6-mannans with short α-1,2-mannose branches that are terminated by galactofuranose residues (31, 32). The N. crassa posttranslational modifications appear to differ from those found in S. cerevisiae by having shorter mannan chains and by the presence of terminal galactofuranose residues.Mannosylation of glycoproteins has been extensively studied in yeast. In S. cerevisiae, OCH1 encodes the α-1,6-mannosyltransferase enzyme that mediates the addition of the initial α-1,6-mannose in the synthesis of long mannans which are attached to the N-linked oligosaccharides (22, 33). Knockout mutants of OCH1 are viable but exhibit a temperature-sensitive growth pattern and are sensitive to cell wall perturbation reagents (34). Mutants for Candida albicans homologs of OCH1 had near-normal growth rates but were much less virulent (3). Mass spectrometry analysis of glycoproteins from the S. cerevisiae och1 and C. albicans och1 mutants showed that the α-1,6-mannose core was absent (3, 33). In Kluyveromyces lactis, the KlOCH1 gene has been shown to be important for cell wall organization and to give a hypersecretion phenotype (37). OCH1 mutants have also been identified in Pichia angusta, Yarrowia lipolytica, Pichia pastoris, and Schizosaccharomyces pombe, and these mutants have cell wall-related phenotypes (2, 9, 17, 38). However, a recent report of OCH1 knockout mutants of Aspergillus fumigatus indicates that these mutants do not have a cell wall-defective phenotype (18).Mannosylation of cell wall proteins has not been extensively studied in filamentous fungi. We report on the characterization of the N. crassa knockout mutant of the α-1,6-mannosyltransferase, och-1. The mutant was generated by the Neurospora genome knockout project (10). The N. crassa och-1 mutant has a severe growth defect and exhibits a tight colonial phenotype. We demonstrate that the och-1 mutant exhibits a defect in cell wall biosynthesis. A carbohydrate analysis of the mutant cell wall showed a drastic reduction in mannose and galactose content with a compensatory increase in the glucose content. The och-1 cell wall also showed a reduced cell wall protein content as assessed by a Coomassie brilliant blue dye binding assay and by proteomic analysis. Protein secretion assays showed that the mutant releases large amounts of cell wall protein into the growth medium. We demonstrate that the och-1 mutant is defective in covalently cross-linking known cell wall proteins into the cell wall matrix. Our data demonstrate that the N-linked galactomannan, which is built upon the mannose residue added by OCH-1, is required for the incorporation of cell wall proteins into the cell wall matrix.     

The Cell Wall Teichoic Acids of Streptomycetes from the “Streptomyces cyaneus” Cluster

The cell wall anionic polymers of the 13 species of the Streptomyces cyaneus cluster have a similar structure and contain -glucosylated 1,5-poly(ribitol phosphate) and 1,3-poly(glycerol phosphate). In the degree of glucosylation of the ribitol phosphate units of their teichoic acids, the cluster members can be divided into two groups. The streptomycetes of the first group (S. afghaniensis, S. janthinus, S. purpurascens, S. roseoviolaceus, and S. violatus) are characterized by a very similar structure of their cell walls, the completely glucosylated 1,5-poly(ribitol phosphate) chains, and a high degree of DNA homology (67–88% according to literature data). The cell wall teichoic acids of the second group (S. azureus, S. bellus, S. caelestis, S. coeruleorubidus, S. curacoi, and S. violarus) differ in the degree of -glucosylation of their 1,5-poly(ribitol phosphate) chains and have a lower level of DNA homology (54–76% according to literature data). Two streptomycetes of the cluster (S. cyaneus and S. hawaiiensis) are genetically distant from the other cluster members but have the same composition and structure of the cell wall teichoic acids as the second-group streptomycetes. The data obtained confirm the genetic relatedness of the S. cyaneus cluster members and suggest that the structure of the cell wall teichoic acids may serve as one of the taxonomic criteria of the species-level status of streptomycetes.     

Essential Roles of Cell Surface Protein and Carbohydrate Components in Flocculation of a Brewer’s Yeast

Co-flocculation between cells of beer yeast IFO 2018, a flocculent strain, and non-flocculent strains was investigated by means of a chemical modification method. Treatment with periodate deprived non-flocculent cells, but not flocculent cells, of the ability to co-flocculate. Treatment with mercaptoethanol or photo-irradiation in the presence of methylene blue deprived flocculent cells, but not non-flocculent cells, of the co-flocculating ability. Mercaptoethanol-treated or photoirradiated flocculent cells (beer yeast IFO 2018) co-flocculated with periodate-treated flocculent cells, but periodate-treated cells subsequently subjected to mercaptoethanol treatment or photoirradiation neither flocculated by themselves nor co-flocculated with other cells. Thus, it is likely that both protein and carbohydrate components of the yeast cell surface play important roles in the mutual recognition and intercellular interaction involved in flocculation. It is strongly suggested that the essential carbohydrate which is widely distributed among Saccharomyces species is the mannan fraction on the cell wall, and that a flocculent yeast strain produces surface protein component(s) which recognize and bind the mannan component of adjacent cells.     

Regulation of β-Adrenergic Receptor Trafficking and Lung Microvascular Endothelial Cell Permeability by Rab5 GTPase

Rab5 GTPase modulates the trafficking of the cell surface receptors, including G protein-coupled β-adrenergic receptors (β-ARs). Here, we have determined the role of Rab5 in regulating the internalization of β-ARs in lung microvascular endothelial cells (LMECs) and in maintaining the integrity and permeability of endothelial cell barrier. Our data demonstrate that lipopolysaccharide (LPS) treatment disrupts LMEC barrier function and reduces the cell surface expression of β-ARs. Furthermore, the activation of β-ARs, particularly β2-AR, is able to protect the LMEC permeability from LPS injury. Moreover, siRNA-mediated knockdown of Rab5 inhibits both the basal and agonist-provoked internalization of β-ARs, therefore, enhancing the cell surface expression of the receptors and receptor-mediated ERK1/2 activation. Importantly, knockdown of Rab5 not only inhibits the LPS-induced effects on β-ARs but also protects the LMEC monolayer permeability. All together, these data provide strong evidence indicating a crucial role of Rab5-mediated internalization of β-ARs in functional regulation of LMECs.     

Change of the Structure of Cell Wall β-l,3-d-Glucan with the Growth of Neurospora crassa Cells

The chemical structure of cell wall β-d-glucans as well as the activities of lytic enzymes such as β-1,3-d-glucanase and β-1,6-d-glucanase changed during the growth of Neurospora crassa.

A dramatic change in the cell wall β-d-glucan structure was observed between cells of the middle logarithmic phase and ones of the late logarithmic phase. The ratio of 1,3-linked glucose residues to non reducing terminal glucose residues decreased from 85 to 55 and the ratio of gentiobiose as a hydrolysis product with exo-β-1,3-d-glucanase increased significantly between the two phases.

Two prominent peaks of β-1,3-d-glucanase as well as the β-1,6-d-glucanase activities appeared in the culture filtrate at different growth stages, the early logarithmic phase and the stationary phase. In the cell wall, β-d-glucosidase activity instead of the β-l,6-d-glucanase and β-1,3-d-glucanase activities was observed in the late logarithmic phase.     

Plant Cell Wall Remodelling in the Rhizobium–Legume Symbiosis

Colonization of host cells by rhizobium bacteria involves the progressive remodelling of the plant–microbial interface. Following induction of nodulation genes by legume-derived flavonoid signals, rhizobium secretes Nod-factors (lipochitin oligosaccharides) that cause root hair deformations by perturbing the growth of the plant cell wall. The infection thread arises as a tubular ingrowth bounded by plant cell wall. This serves as a conduit for colonizing bacterial cells that grow and divide in its lumen. The transcellular orientation of thread growth is controlled by the cytoskeleton and is coupled to cell cycle reactivation and cell division processes. In response to rhizobium infection, host cells synthesize several new components (early nodulins) that modify the properties of the cell wall and extracellular matrix. Root nodule extensins are a legume-specific family of hydroxyproline-rich glycoproteins targeted into the lumen of the infection thread. They have alternating extensin and arabinogalactan (AGP) glycosylation motifs. The structural characteristics of these glycoproteins suggest that they may serve to regulate fluid-to-solid transitions in the extracellular matrix. Extensibility of the infection thread is apparently controlled by peroxide-driven protein cross-linking and perhaps also by modification of the pectic matrix. Endocytosis of rhizobia from unwalled infection droplets into the host cell cytoplasm depends on physical contact between glycocalyx components of the plant and bacterial membrane surfaces. As endosymbionts, bacteroids remain enclosed within a plant-derived membrane that is topologically equivalent to the plasma membrane. This membrane acquires specialist functions that regulate metabolite exchanges between bacterial cells and the host cytoplasm. Ultimately, however, the fate of the symbiosome is to become a lysosome, causing the eventual senescence of the symbiotic interaction.