Spatial structure of plant cell wall polysaccharides and its functional significance

Plant polysaccharides comprise the major portion of organic matter in the biosphere. The cell wall built on the basis of polysaccharides is the key feature of a plant organism largely determining its biology. All together, around 10 types of polysaccharide backbones, which can be decorated by different substituents giving rise to endless diversity of carbohydrate structures, are present in cell walls of higher plants. Each of the numerous cell types present in plants has cell wall with specific parameters, the features of which mostly arise from the structure of polymeric components. The structure of polysaccharides is not directly encoded by the genome and has variability in many parameters (molecular weight, length, and location of side chains, presence of modifying groups, etc.). The extent of such variability is limited by the “functional fitting” of the polymer, which is largely based on spatial organization of the polysaccharide and its ability to form supramolecular complexes of an appropriate type. Consequently, the carrier of the functional specificity is not the certain molecular structure but the certain type of the molecules having a certain degree of heterogeneity. This review summarizes the data on structural features of plant cell wall polysaccharides, considers formation of supramolecular complexes, gives examples of tissue- and stage-specific polysaccharides and functionally significant carbohydrate-carbohydrate interactions in plant cell wall, and presents approaches to analyze the spatial structure of polysaccharides and their complexes.     

Expression of Cellulose Synthase Genes During the Gravistimulation of Flax (Linum usitatissimum) and Poplar (Populus alba × tremula) Plants

Russian Journal of Bioorganic Chemistry - Plant cellulose is synthesized on the plasma membrane by the cellulose synthase complex and a number of coenzymes. Different cellulose synthases are...     

A microsatellite-based consensus linkage map for species of Eucalyptus and a novel set of 230 microsatellite markers for the genus

Background  

Eucalypts are the most widely planted hardwood trees in the world occupying globally more than 18 million hectares as an important source of carbon neutral renewable energy and raw material for pulp, paper and solid wood. Quantitative Trait Loci (QTLs) in Eucalyptus have been localized on pedigree-specific RAPD or AFLP maps seriously limiting the value of such QTL mapping efforts for molecular breeding. The availability of a genus-wide genetic map with transferable microsatellite markers has become a must for the effective advancement of genomic undertakings. This report describes the development of a novel set of 230 EMBRA microsatellites, the construction of the first comprehensive microsatellite-based consensus linkage map for Eucalyptus and the consolidation of existing linkage information for other microsatellites and candidate genes mapped in other species of the genus.     

Pathogen‐induced conditioning of the primary xylem vessels – a prerequisite for the formation of bacterial emboli by Pectobacterium atrosepticum

Representatives of Pectobacterium genus are some of the most harmful phytopathogens in the world. In the present study, we have elucidated novel aspects of plant–Pectobacterium atrosepticum interactions. This bacterium was recently demonstrated to form specific ‘multicellular’ structures – bacterial emboli in the xylem vessels of infected plants. In our work, we showed that the process of formation of these structures includes the pathogen‐induced reactions of the plant. The colonisation of the plant by P. atrosepticum is coupled with the release of a pectic polysaccharide, rhamnogalacturonan I, into the vessel lumen from the plant cell wall. This polysaccharide gives rise to a gel that serves as a matrix for bacterial emboli. P. atrosepticum‐caused infection involves an increase of reactive oxygen species (ROS) levels in the vessels, creating the conditions for the scission of polysaccharides and modification of plant cell wall composition. Both the release of rhamnogalacturonan I and the increase in ROS precede colonisation of the vessels by bacteria and occur only in the primary xylem vessels, the same as the subsequent formation of bacterial emboli. Since the appearance of rhamnogalacturonan I and increase in ROS levels do not hamper the bacterial cells and form a basis for the assembly of bacterial emboli, these reactions may be regarded as part of the susceptible response of the plant. Bacterial emboli thus represent the products of host–pathogen integration, since the formation of these structures requires the action of both partners.     

Quantification of angiogenesis in estrogen receptor-positive and negative breast carcinoma

Background

The objective of this study was to evaluate angiogenesis according to CD34 antigen expression in estrogen receptor (ER)-positive and negative breast carcinomas.

Methods

This study comprised 64 cases of infiltrating ductal carcinoma in postmenopausal women divided into two groups: Group A: ER-positive, n = 35; and Group B: ER-negative, n = 29. The anti-CD34 monoclonal antibody was used as a marker for endothelial cells. Microvessel count was carried out in 10 fields per slide using a 40× objective lens (magnification 400×). Statistical analysis of the data was performed using Student's t-test (p < 0.05).

Results

The mean number of vessels stained with the anti-CD34 antibody in the estrogen receptor-positive and negative tumors was 23.51 ± 1.15 and 40.24 ± 0.42, respectively. The number of microvessels was significantly greater in the estrogen receptor-negative tumors (p < 0.001).

Conclusion

ER-negative tumors have significantly greater CD34 antigen expression compared to ER-positive tumors.

     

Comparative analysis of the zeta-crystallin/quinone reductase gene in guinea pig and mouse

zeta-Crystallin is a novel nicotinamide adenine dinucleotide phosphate:quinone reductase, present at enzymatic levels in various tissues of different species, which is highly expressed in the lens of some hystricomorph rodents and camelids. We report here the complementary DNA (cDNA) cloning of zeta-crystallin from liver libraries in guinea pig (Cavia porcellus), where zeta-crystallin is highly expressed in the lens, and in the laboratory mouse (Mus musculus), where expression in the lens occurs only at enzymatic levels. A 5' untranslated sequence different from the one previously reported for the guinea pig lens cDNA was found in these clones. We also report the isolation of genomic clones including the complete guinea pig zeta-crystallin gene and the 5' region of this gene in mouse. These results show the presence of two promoters in the guinea pig zeta-crystallin gene, one responsible for expression at enzymatic levels and the other responsible for the high expression in the lens. The guinea pig lens promoter is not present in the mouse gene. This is the first example in which the recruitment of an enzyme as a lens crystallin can be explained by the acquisition of an alternative lens- specific promoter.      

Quantification of the magnification and distortion effects of a pediatric flexible video-bronchoscope

Background

Flexible video bronchoscopes, in particular the Olympus BF Type 3C160, are commonly used in pediatric respiratory medicine. There is no data on the magnification and distortion effects of these bronchoscopes yet important clinical decisions are made from the images. The aim of this study was to systematically describe the magnification and distortion of flexible bronchoscope images taken at various distances from the object.

Methods

Using images of known objects and processing these by digital video and computer programs both magnification and distortion scales were derived.

Results

Magnification changes as a linear function between 100 mm (×1) and 10 mm (×9.55) and then as an exponential function between 10 mm and 3 mm (×40) from the object. Magnification depends on the axis of orientation of the object to the optic axis or geometrical axis of the bronchoscope. Magnification also varies across the field of view with the central magnification being 39% greater than at the periphery of the field of view at 15 mm from the object. However, in the paediatric situation the diameter of the orifices is usually less than 10 mm and thus this limits the exposure to these peripheral limits of magnification reduction. Intraclass correlations for measurements and repeatability studies between instruments are very high, r = 0.96. Distortion occurs as both barrel and geometric types but both types are heterogeneous across the field of view. Distortion of geometric type ranges up to 30% at 3 mm from the object but may be as low as 5% depending on the position of the object in relation to the optic axis.

Conclusion

We conclude that the optimal working distance range is between 40 and 10 mm from the object. However the clinician should be cognisant of both variations in magnification and distortion in clinical judgements.     

Aspen Tension Wood Fibers Contain β-(1→4)-Galactans and Acidic Arabinogalactans Retained by Cellulose Microfibrils in Gelatinous Walls

Contractile cell walls are found in various plant organs and tissues such as tendrils, contractile roots, and tension wood. The tension-generating mechanism is not known but is thought to involve special cell wall architecture. We previously postulated that tension could result from the entrapment of certain matrix polymers within cellulose microfibrils. As reported here, this hypothesis was corroborated by sequential extraction and analysis of cell wall polymers that are retained by cellulose microfibrils in tension wood and normal wood of hybrid aspen (Populus tremula × Populus tremuloides). β-(1→4)-Galactan and type II arabinogalactan were the main large matrix polymers retained by cellulose microfibrils that were specifically found in tension wood. Xyloglucan was detected mostly in oligomeric form in the alkali-labile fraction and was enriched in tension wood. β-(1→4)-Galactan and rhamnogalacturonan I backbone epitopes were localized in the gelatinous cell wall layer. Type II arabinogalactans retained by cellulose microfibrils had a higher content of (methyl)glucuronic acid and galactose in tension wood than in normal wood. Thus, β-(1→4)-galactan and a specialized form of type II arabinogalactan are trapped by cellulose microfibrils specifically in tension wood and, thus, are the main candidate polymers for the generation of tensional stresses by the entrapment mechanism. We also found high β-galactosidase activity accompanying tension wood differentiation and propose a testable hypothesis that such activity might regulate galactan entrapment and, thus, mechanical properties of cell walls in tension wood.Contractile cell walls found in plant organs and tissues such as tendrils, contractile roots, and tension wood (TW) have remarkable functions and properties. Their traits have been most intensely studied in TW of hardwoods, where they provide negative gravitropic response capacities to stems with secondary growth, as recently reviewed by Mellerowicz and Gorshkova (2012). These properties are conferred by TW fibers, which in many species contain a so-called gelatinous cell wall layer (G-layer; Norberg and Meier, 1966; Clair et al., 2008). G-layers are formed following the deposition of xylan-type secondary cell wall layer(s) and, thus, can be considered tertiary layers (Wardrop and Dadswell, 1948). They are almost or completely devoid of xylan and lignin and have very high cellulose contents (up to 85%). However, several other polymers appear to be present in TW G-layers, according to recent chemical analyses of isolated G-layers (Nishikubo et al., 2007; Kaku et al., 2009) and immunohistochemical labeling of TW sections (Arend, 2008; Bowling and Vaughn, 2008). Notably, xyloglucan (XG) has been found in G-layers of poplar (Populus spp.) TW (Nishikubo et al., 2007) and at the boundary between secondary cell wall layers (S-layers) and G-layers (Baba et al., 2009; Sandquist et al., 2010). It is also important for tension creation (Baba et al., 2009). However, it is not detectable in mature G-layers by monoclonal antibodies or XG-binding modules (Nishikubo et al., 2007; Baba et al., 2009; Sandquist et al., 2010).Structurally similar G-layers have been also identified in phloem fibers in many fibrous crops, such as flax (Linum usitatissimum), hemp (Cannabis sativa), and ramie (Boehmeria nivea; Gorshkova et al., 2012). These fibers occur in bundles that can be isolated for biochemical analysis. G-layers in fibers from diverse sources have a very similar structure, being largely composed of cellulose (with axial microfibril orientation, high degrees of crystallinity, and large crystallite sizes) lacking xylan and lignin (Mellerowicz et al., 2001; Pilate et al., 2004; Gorshkova et al., 2010, 2012) and having high water contents (Schreiber et al., 2010). In phloem fibers, the G-layers become very prominent, reaching thicknesses up to 15 µm and occupying over 90% of the cell wall’s total cross-sectional areas (Crônier et al., 2005). Pectic β-(1→4)-galactan with complex structures has been shown to be the major matrix polysaccharide of isolated phloem fibers in flax (Gorshkova et al., 2004; Gorshkova and Morvan, 2006; Gurjanov et al., 2007). Some of it is so strongly retained within cellulose that it cannot be extracted by concentrated alkali and can only be obtained after cellulose dissolution (Gurjanov et al., 2008). Such galactan, therefore, is a prime candidate for a polymer entrapped by cellulose microfibrils during crystallization that could substantially contribute to the contractile properties of cellulose in G-layers, according to recently formulated models (Mellerowicz et al., 2008; Mellerowicz and Gorshkova 2012). Furthermore, Roach et al. (2011) have shown that trimming of β-(1→4)-galactan by β-galactosidase is important for final cellulose crystallization, the formation of G-layer structure, and, hence, the stem’s mechanical properties.There is also immunocytochemical evidence for the presence of β-(1→4)-galactan and type II arabinogalactan (AG-II) in G-layers of TW fibers (Arend, 2008; Bowling and Vaughn, 2008). In addition, high-M_r branched galactans have been isolated from TW of Fagus sylvestris (Meier, 1962) and Fagus grandifolia (Kuo and Timell, 1969), with estimated degrees of polymerization (DP) of approximately 300 and complex structure, probably including both β-(1→4) and β-(1→6) linkages, although their exact nature remains unknown. Furthermore, Gal has been identified as one of the major sugars after Glc and Xyl in hydrolysates of isolated Populus spp. G-layers (Furuya et al., 1970; Nishikubo et al., 2007), and the Gal content of cell walls is a proposed indicator of the extent of TW development in beech (Fagus spp.; Ruel and Barnoud, 1978). However, subsequent linkage analyses identified only 2- and 3,6-linked Gal in poplar TW G-layers (Nishikubo et al., 2007), while in flax fibers, 4-linked Gal is the main component (Gorshkova et al., 1996, 2004; Gurjanov et al., 2007, 2008). Thus, the type(s) of galactans present in poplar TW remains unclear, and the galactans have not been shown previously either to have a rhamnogalacturonan-I (RG-I) backbone or to be strongly retained by cellulose microfibrils, as demonstrated for flax gelatinous fibers.To improve our understanding of cell wall properties in TW and their contraction mechanism, in the study presented here, we tested aspects of the recently proposed entrapment model (Mellerowicz et al., 2008; Mellerowicz and Gorshkova, 2012). According to this model, contraction is driven by the formation of larger cellulose structures, sometimes called macrofibrils, via interactions of cellulose microfibrils in the G-layer with each other and forming inclusions containing matrix polymers. This would induce tension within cellulose through the stretching of microfibrils required to surround the inclusions. The model is compatible with available data on the structure and action of gelatinous walls, but the main assumption, that polymers are trapped inside crystalline cellulose, such as that found in flax, has not been tested previously. Therefore, we compared matrix polymers retained by cellulose microfibrils in normal wood (NW) and TW of the model hardwood species hybrid aspen (Populus tremula × Populus tremuloides) that forms TW with gelatinous fibers. For this purpose, we used a combination of sequential cell wall extractions, similar to those used previously to characterize flax gelatinous fibers (Gurjanov et al., 2008), followed by fractionation of polymers by size-exclusion chromatography, immunological analyses, and oligosaccharide profiling by polysaccharide analysis using carbohydrate gel electrophoresis (PACE). The results reveal the main polymers of cellulose-retained fractions and key differences between NW and TW. Comparison of our results and previous findings also indicates that there are both similarities and differences in the constitution of gelatinous fibers in aspen and flax. An updated model of the contractile G-layer of TW fibers based on the data is presented.     

Evidence for independent recruitment of zeta-crystallin/quinone reductase (CRYZ) as a crystallin in camelids and hystricomorph rodents

Zeta-crystallin/quinone reductase (CRYZ) is an NADPH oxidoreductase expressed at very high levels in the lenses of two groups of mammals: camelids and some hystricomorph rodents. It is also expressed at very low levels in all other species tested. Comparative analysis of the mechanisms mediating the high expression of this enzyme/crystallin in the lens of the Ilama (Lama guanacoe) and the guinea pig (Cavia porcellus) provided evidence for independent recruitment of this enzyme as a lens crystallin in both species and allowed us to elucidate for the first time the mechanism of lens recruitment of an enzyme- crystallin. The data presented here show that in both species such recruitment most likely occurred through the generation of new lens promoters from nonfunctional intron sequences by the accumulation of point mutations and/or small deletions and insertions. These results further support the idea that recruitment of CRYZ resulted from an adaptive process in which the high expression of CRYZ in the lens provides some selective advantage rather than from a purely neutral evolutionary process.