Modification of cell wall polysaccharides during cell elongation in Phaseolus vulgaris hypocotyls

The effect of gibberellic acid (GA) and naphthylacetic acid (NAA) on hypocotyl elongation and cell wall polysaccharides was studied using Phaseolus vulgaris seedlings grown in light condition. The hypocotyl was demarcated into two segments — one near the root was called lower and the one near the cotyledon was called upper. The upper segment showed a typical sigmoidal growth curve while lower segment did not show any growth at all. GA promoted the growth of upper segment while NAA showed clear inhibition in both the segments. Xyloglucan content showed a clear inverse correlation with growth. Pectic polysaccharides did not show a clear trend, though showed an initial inverse correlation with growth. It is concluded that degradation of low and high molecular weight xyloglucans are involved in cell wall loosening which in turn may be responsible for the elongation growth of Phaseolus hypocotyls in light.     

Boron in Plant Biology

Abstract: The interest of biologists in boron (B) has largely been focused on its role in plants for which B was established as essential in 1923 (Warington, 1923^[296]). Evidence that B has a biological role in other organisms was first indicated by the establishment of essentiality of B for diatoms (Smyth and Dugger, 1981^[296]) and cyanobacteria (Bonilla et al., 1990^[296]; Garcia‐Gonzalez et al., 1991^[296]; Bonilla et al., 1997^[296]). Recently, B was shown to stimulate growth in yeast (Bennett et al., 1999^[296]) and to be essential for zebrafish (Danio rerio) (Eckhert and Rowe, 1999^[296]; Rowe and Eckhert, 1999^[296]) and possibly for trout (Oncorhynchus mykiss) (Eckhert, 1998^[296]; Rowe et al., 1998^[296]), frogs (Xenopus laevis) (Fort et al., 1998^[296]) and mouse (Lanoue et al., 2000^[296]). There is also preliminary evidence to suggest that B has at least a beneficial role in humans (Nielsen, 2000^[296]). While research into the role of B in plants has been ongoing for 80 years it has only been in the past 5 years that the first function of B in plants has been defined. Boron is now known to be essential for cell wall structure and function, likely through its role as a stabilizer of the cell wall pectic network and subsequent regulation of cell wall pore size. A role for B in plant cell walls, however, is inadequate to explain all of the effects of B deficiency seen in plants. The suggestion that B plays a broader role in biology is supported by the discovery that B is essential for animals where a cellulose‐rich cell wall is not present. Careful consideration of the physical and chemical properties of B in biological systems, and of the experimental data from both plants and animals suggests that B plays a critical role in membrane structure and hence function. Verification of B association with membranes would represent an important advance in modern biology. For several decades there has been uncertainty as to the mechanisms of B uptake and transport within plants. This uncertainty has been driven by a lack of adequate methodology to measure membrane fluxes of B at physiologically relevant concentrations. Recent experimentation provides the first direct measurement of membrane permeability of B and illustrates that passive B permeation contributes sufficient B at adequate levels of B supply, but would be inadequate at conditions of marginal B supply. The hypothesis that an active, carrier mediated process is involved in B uptake at low B supply is supported by research demonstrating that B uptake can be stimulated by B deprivation, that uptake rates follow a Michaelis‐Menton kinetics, and can be inhibited by application of metabolic inhibitors. Since the mechanisms of element uptake are generally conserved between species, an understanding of the processes of B uptake is relevant to studies in both plants and animals. The study of B in plant biology has progressed markedly in the last decade and we are clearly on the cusp of additional, significant discoveries. Research in this field will be greatly stimulated by the discovery that B is essential for animals, a discovery that will not only encourage the participation of a wider cadre of scientists but will refocus the efforts of plant biologists toward a determination of roles for B outside the plant cell wall. Determination of the function of B in biology and of the mechanisms of B uptake in biological systems, is essential to our understanding and management of B deficiency and toxicity in plants and animals in both agricultural and natural environments. Through an analysis of existing data and the development of new hypotheses, this review aims to provide a vision of the future of research into the biology of boron.     

Changes in growth,proteins and free amino acids of developing seed and pod of fenugreek

The growth and development under field conditions of the pods and seeds of two cvs of Trigonella foenum graecum are described. Samples were harvested at different stages of ripeness for the determination of dry matter, protein and free amino acid content. During maturation, reserves of solutes are established in the pod wall before the seeds begin their exponential phase of growth. Later, these reserves disappear, providing about 20% of the seed's requirements for nitrogen. SDS-electrophoresis was used to follow the formation of proteins and it was shown that the synthesis of storage proteins takes place prior to dehydration of the seed. Production soluble nitrogenous compounds precedes protein accumulation. Free amino acids follow the same pattern. 4-Hydroxyisoleucine represents nearly 80% of free amino acid of dry seeds. The concentration does not decrease in the later stages of maturation of the seed but this unusual amino acid is absent in the storage proteins of the seeds.     

The evaluation of liquid-based ''Cyto-SEDTM'' cytology of bronchioalveolar lavage specimens in the diagnosis of pulmonary neoplasia against conventional direct smears

Historically, bronchioalveolar lavage (BAL) samples have been prepared by a direct smear (DS) technique. Recent advances in liquid-based cytology have led to a revolution in cytological specimen preparation. Cyto-SED system (CS) is a manual liquid-based cytology system, designed for small-scale use. A total of 137 samples from patients with radiographically detectable lesions underwent BAL procedures at Papworth Hospital NHS Trust over a 4-month period. After preparation for diagnostic purposes with the DS method, the remaining sample was prepared using the CS system. The slides produced were allocated a blind study number and screened by three independent screeners. The cellular morphology was well preserved and comparable between both techniques. Of the 137 patients, 38% were confirmed as malignant by cytology or histology; 71% of these malignant diagnosis were confirmed by the DS technique and 91% confirmed by the CS. The results demonstrate that the CS is a viable alternative to the DS technique. The cytological detail is clearly defined without a loss of three-dimensional information, thus aiding the differential diagnosis of malignancy. Cyto-SED cytology system yields a higher diagnostic accuracy than the conventional direct smear technique without compromising on cytological detail.     

A GLYCOPROTEIN NONCOVALENTLY ASSOCIATED WITH CELL‐WALL POLYSACCHARIDE OF THE RED MICROALGA PORPHYRIDIUM SP. (RHODOPHYTA)1

The cells of the red microalga Porphyridium sp. (UTEX 637) are encapsulated in a cell wall of a negatively charged mucilaginous polysaccharide complex composed of 10 different sugars, sulfate, and proteins. In this work, we studied the proteins associated with the cell‐wall polysaccharide. A number of noncovalently associated proteins were resolved by SDS‐PAGE, but no covalently bound proteins were detected. The most prominent protein detected was a 66‐kDa glycoprotein consisting of a polypeptide of approximately 58 kDa and a glycan moiety of approximately 8 kDa containing N‐linked terminal mannose. In size‐exclusion chromatography, the 66‐kDa protein was coeluted with the polysaccharide and could be separated from the polysaccharide only after denaturation of the protein, indicating that the 66‐kDa protein was tightly bound to the polysaccharide. Western blot analysis revealed that the 66‐kDa protein was specific to Porphyridium sp. and P. cruentum, because it was not detected in the other species of red microalgae examined. Indirect immunofluorescence assay confirmed the location of the protein in the algal cell wall. The sequence of cDNA clone encoding the 66‐kDa glycoprotein, detected in our in‐house expressed sequence tag database of Porphyridium sp., revealed that this is a novel protein with no similarity to any protein in the public domain databases and our in‐house expressed sequence tag database of the red microalga Rhodella reticulata. The 66‐kDa protein bound polysaccharides from red algae but not from those of other origins tested. Possible roles of the 66‐kDa protein in the biosynthesis of the polysaccharide are discussed.     

COMPOSITION AND SYNTHESIS OF THE PECTIN AND PROTEIN COMPONENTS OF THE CELL WALL OF CLOSTERIUM ACEROSUM (CHLOROPHYTA)

Closterium acerosum Ehrenberg (Chlorophyta) possesses a trilayered cell wall consisting of an outer tri-laminate stratum, a fibrous middle layer, and a thick inner fibrous layer. The outermost layer has a series of external parallel ridges and valleys. At the bases of the valleys are the wall pores, the site of mucilage release. Pure fractions of cell walls were isolated and inclusive pectin and wall protein fractions were extracted and characterized. Two pectin-like fractions were isolated: a CDTA-extracted polymer consisting of 60.1% galacturonic acid and a Na₂CO₃-extracted fraction consisting of 39.9% galacturonic acid. Two major protein fractions, one with a molecular mass of 23.5 kDa and one with a molecular mass of 28.5 kDa, were isolated by preparative gel electrophoresis. The former was glycine-rich, whereas the latter contained both significant amounts of glycine and hydroxyproline. Antibodies were raised to both the pectin fractions and the 23.5-kDa wall protein fraction. Immunocytochemical labeling of whole cells and wall fragments using antibodies raised against CDTA and Na₂CO₃ extracts showed that these pectin-like components were found throughout the wall strata and were more concentrated at the polar tips, the site of new wall synthesis in growing semicells. Immunogold labeling showed that their production was focused on the trans- Golgi network of the Golgi apparatus. Immunolabeling with an antibody raised against the 23.5-kDa glycine-rich wall protein showed close association of the protein with the wall pores. Similarly, immunogold labeling revealed that the protein was processed throughout the entire Golgi body even when large mucilage-containing vesicles were being processed. The roles of the secretory apparatus and putative spitzenkorper-like regions of the cell are discussed.     

BIOMECHANICS AND ALGINIC ACID COMPOSITION DURING HYDRODYNAMIC ADAPTATION BY EGREGIA MENZIESII (PHAEOPHYTA) JUVENILES1

To investigate the possible link between cell wall alginic acid composition and tissue mechanics, juveniles of Egregia menziesii (Turn.) Aresch. were grown under controlled conditions in an outdoor flowing seawater system under three different force regimes. After 6–10 weeks of growth, tissue strength, breaking strain, modulus, toughness, work of fracture, and the percentage of polymannuronate, polyguluronate, and alternating sequences in the cell wall alginic acid were examined. The force regime had significant effects on all mechanical indices except toughness. Juveniles grown under high energy conditions (water velocity = 1.2 m · s^?1) were about two times stronger, two times stiffer, and had a 1.5 times greater work of fracture than those from low energy conditions (<1 cm ·^?1). Treatment effects on thallus strength and modulus were predicted from alginic acid composition data to test for the importance of this cell wall material in whole plant adaptation to hydrodynamic stress. However, the prediction that differences in alginic acid composition were responsible for differences in tissue mechanical properties was inconsistent with observations. Therefore, the hypothesis that alginates play a central role in structural adaptation could not be accepted.     

CHEMICAL COMPOSITION OF THE CELL WALLS OF THE FRESHWATER RED ALGA LEMANEA ANNULATA (BATRACHOSPERMALES)1

Cell walls of the generic phase of the freshwater red alga Lemanea annulata Kütz were mechanically isolated and chemically characterized. Walls consisted mainly of polysaccharide with lesser quantities of associated protein and lipid. The major wall component was alkali-soluble xylan, comprised mainly of 4-linked β-xylopyranosyl residues and small amounts of 3-O-substituted β-xylopyranosyl residues. Hot water extracts yielded non-sulfated polymers, with 3- or 3,4-linked β-galactosyl residues alternating with 4-linked α-glucuronosyl residues as the predominant structural features. This acid polysaccharide shares many characteristics of the mucilage previously described from the freshwater genus Batrachospermum. Isolated cell walls of L. annulata contained approximately 6% cellulose. Cellobiohydrolase/colloidal gold labelling of cell walls revealed β-4-glycan throughout the fibrillar portion of the wall. Wall protein consisted of at least 17 amino acids, of which threonine and alanine were the most abundant. Polysaccharides of the cell walls of L. annulata differ from those of marine red algae and are similar to those described for other Batrachospermales.     

Partial purification of cell wall α-galactosidases and α-arabinosidases from Cicer arietinum epicotyls. Relationship with cell wall autolytic processes

Two protein fractions with activity as α-galactosidase (EC 3.2.1.22) and α-arabinosidase (EC 3.2.1.55), respectively, were identified in the proteins of cell wall of Cicer arietinum L. cv. Castellana extracted with 3 M LiCl. These fractions were partially purified by gel filtration chromatography (Bio Gel P-150), increasing the specific arabinosidase activity 57-fold and the α-galactosidase activity 6-fold. Other protein fractions with glucosidase (EC 3.2.1.21) and glucanase (EC 3.2.1.6) activity also appeared. According to earlier authors, α-arabinosidases and α-galactosidases are related to alterations in linkages occurring in cell walls, since the enzymes are able to hydrolyze isolated wall polymers. However, our preparations hydrolyze intact cell walls only to a very limited extent, such that their participation in the autolytic processes of cell walls can be ruled out.