Biosynthesis of β-glucans in fungi

Glucans are the most abundant polysaccharides present in fungi. The present review provides updated information on the structure and synthesis of -glucans in fungal cells. Synthesis of these polymers made up of B1,3 chains with a variable degree of B1,6 branching involves several reactions: initiation, chain elongation and branching, of which the most studied one is the elongation step. This reaction, catalyzed by the so-called glucan synthetases, utilizes UDPG as sugar donor. Properties of glucan synthetases are extremely variable depending on the fungal species, and their developmental stage. Because of the importance of these polysaccharides it is anticipated that comprehension of their mechanism of synthesis, is important for the understanding of cell wall assembly and cell growth and morphogenesis, as well as for the design of specific antifungal drugs.Abreviations UDPG uridine-diphospho-glucose - GDPG guanosine-diphospho-glucose - ADPG adenosine-diphospho-glucose - MW molecular weight - mic minimal inhibitory concentration - d.p. degree of polymerization - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulfate     

Chemical characterization, antiproliferative and antiadhesive properties of polysaccharides extracted from Pleurotus pulmonarius mycelium and fruiting bodies

Mushroom polysaccharides are potent substances that exhibit antitumor and immunomodulatory properties. Studies comparing the chemical composition and antitumor-related activities of polysaccharides released by fungal strains under different growth conditions are not available. Thus, the present study compared polysaccharides extracts produced by Pleurotus pulmonarius from mycelium grown in liquid culture (ME) or fruiting bodies (FBE). Polysaccharides of both ME and FBE had a relatively high molecular mass. NMR spectroscopy indicated that ME glucan is an α-glucan whereas FBE glucan is a mixture of both α- and β-glucans. Glucose and galactose where the most prominent monosaccharide in both glucans. Treatment of several colon cancer cell lines expressing varying amounts of galectin-3 with the two fungal glucans inhibited their viability and significantly reduced their ability to adhere to the key component of the extracellular matrix, fibronectin, and to a human umbilical vein endothelial cell monolayer, in a time- and dose-dependent manner mainly in those cell lines expressing high amounts of galectin-3. We conclude that ME and FBE glucans may exert a direct antiproliferative effect on cancer cells expressing high galectin-3 concentrations and concomitantly downregulate tumor cell adherence, the latter being directly related to cancer progression and metastasis.     

Total synthesis and antifungal evaluation of cyclic aminohexapeptides

The need for new therapies to treat systemic fungal infections continues to rise. Naturally occurring hexapeptide echinocandin B (1) has shown potent antifungal activity via its inhibition of the synthesis of beta-1,3 glucan, a key fungal cell wall component. Although this series of agents has been limited thus far based on their physicochemical characteristics, we have found that the synthesis of analogues bearing an aminoproline residue in the 'northwest' position imparts greatly improved water solubility (> 5 mg/mL). The synthesis and structure-activity relationships (SAR) based on whole cell and upon in vivo activity of the series of compounds are reported.     

Properties of the Glucan Branching Enzyme of the Hyperthermophilic Bacterium Aquifex aeolicus

Abstract

Glucan branching enzymes are responsible for the synthesis of α(1→6) glycosidic bonds in glycogen and amylopectin. The glucan branching enzyme of the hyperthermophile Aquifex aeolicus is the most thermoactive and thermostable glucan branching enzyme described. The gene encoding this glucan branching enzyme was overexpressed in E. coli and purified using γ-cyclodextrin affinity chromatography. Subsequently, the enzyme was stable up to 90°C. Its thermostability may be explained by the relatively high number of aromatic amino acid residues present, in combination with a relatively low number glutamine/asparagine residues. The Km for amylose was 4µM and the Vmax was 4.9 U/mg of protein (at optimal pH and temperature). The side-chain distribution of the branched glucan formed from amylose was determined.     

Characterization of Aspergillus nidulans α‐glucan synthesis: roles for two synthases and two amylases

Cell walls are essential for fungal survival and growth. Fungal walls are ～ 90% carbohydrate, mostly types not found in humans, making them promising targets for anti‐fungal drug development. Echinocandins, which inhibit the essential β‐glucan synthase, are already clinically available. In contrast, α‐glucan, another abundant fungal cell wall component has attracted relatively little research attention because it is not essential for most fungi. Aspergillus nidulans has two α‐glucan synthases (AgsA and AgsB) and two α‐amylases (AmyD and AmyG), all of which affect α‐glucan synthesis. Gene deletion showed that AgsB was the major synthase. In addition, AmyG promoted α‐glucan synthesis whereas AmyD had a repressive effect. The lack of α‐glucan had no phenotypic impact on solid medium, but reduced conidial adhesion during germination in shaken liquid. Moreover, α‐glucan level correlated with resistance to Calcofluor White. Intriguingly, overexpression of agsA could compensate for the loss of agsB at the α‐glucan level, but not for phenotypic defects. Thus, products of AgsA and AgsB have different roles in the cell wall, consistent with agsA being mainly expressed at conidiation. These results suggest that α‐glucan contributes to drug sensitivity and conidia adhesion in A. nidulans, and is differentially regulated by two synthases and two amylases.     

Changes in the rate of synthesis of wall polysaccharides during the cell cycle of yeast

Reevaluation and comparison of seemingly contradictory literature data on the mode of synthesis of wall polysaccharides during the cell cycle ofSaccharomyces cerevisiae explained the source of discrepancies and demonstrated their general consonance in the following points: 1. The rate of synthesis of glucan and mannan is not constant and does not increase continuously throughout the entire cell cycle. 2. The rate of synthesis of both polysaccharides is considerably reduced at the time of cell division and in the prebudding phase.     

Recent advances in the understanding of the <Emphasis Type="Italic">Aspergillus fumigatus</Emphasis> cell wall

Over the past several decades, research on the synthesis and organization of the cell wall polysaccharides of Aspergillus fumigatus has expanded our knowledge of this important fungal structure. Besides protecting the fungus from environmental stresses and maintaining structural integrity of the organism, the cell wall is also the primary site for interaction with host tissues during infection. Cell wall polysaccharides are important ligands for the recognition of fungi by the innate immune system and they can mediate potent immunomodulatory effects. The synthesis of cell wall polysaccharides is a complicated process that requires coordinated regulation of many biosynthetic and metabolic pathways. Continuous synthesis and remodeling of the polysaccharides of the cell wall is essential for the survival of the fungus during development, reproduction, colonization and invasion. As these polysaccharides are absent from the human host, these biosynthetic pathways are attractive targets for antifungal development. In this review, we present recent advances in our understanding of Aspergillus fumigatus cell wall polysaccharides, including the emerging role of cell wall polysaccharides in the host-pathogen interaction.     

抗真菌感染新药研究进展

随着免疫功能缺陷人群的增多,侵袭性真菌感染（invasive fungal infections,IFIs）的发病率和死亡率逐年上升,严重威胁人类健康。目前临床常用抗侵袭性真菌感染药物有三唑类（氟康唑）、多烯类（两性霉素B）、棘白菌素类（卡泊芬净）等,然而这些药物并不能满足临床需要,侵袭性真菌感染的死亡率仍居高不下。因此,本文着重于目前处于临床研究阶段的抗真菌感染新药,根据作用靶点不同依次介绍：作用于细胞壁的新型葡聚糖合成酶抑制剂CD101和SCY-078、几丁质合成酶抑制剂尼可霉素Z、GPI锚定蛋白抑制剂APX001;作用于细胞膜的CYP51抑制剂VT-1161和VT-1129、破坏细胞膜通透性药物CAmB;影响细胞代谢的嘧啶合成抑制剂F901318,以及生物制剂包括细胞表面凝集素样序列3蛋白疫苗（NDV-3）和抗真菌感染抗体Mycograb。本文主要综述了上述新药的研究进展,包括作用机制、体内外活性、临床研究结果等,为相关药物的研发与未来的临床应用提供参考。     

Update on the possible mode of action of the jasmonates: Focus on the metabolism of cell wall polysaccharides in relation to growth and development

Jasmonic acid (JA) and its related compounds (jasmonates) applied to plant tissues exert either inhibitory or promotive effects in growth and developmental processes, which in some ways are similar to abscisic acid. However, little is known about the mode of action of the jamonates at the tissue or organ levels. Here, we review partial evidence for the physiological action of the jasmonates on cell elongation and abscission.
Jasmonates inhibit the IAA-induced cell elongation of oat coleoptile segments not by affecting energy production, osmoregulation and cell wall loosening, but by inhibiting the synthesis of cell wall polysaccharides. The inhibition is partially reversed by simultaneous application of sucrose. Inhibition of IAA-induced elongation by JA is only observed in monocotyledons, not in dicotyledons. These effects suggest that jasmonates exert their inhibitory effect on cell elongation by affecting the metabolism of the cell wall polysaccharides in monocotyledons.
Jasmonates promote the abscission of bean petiole explants without enhancing ethylene production. Cells in the petiole adjacent to the abscission zone expand during abscission. In the abscission zone, jasmonates decrease the amount of cellulosic but not that of noncellulosic polysaccharides. Jasmonates increase the activities of cellulase and decrease the levels of UDP-sugars, which are important intermediates for the synthesis of cell wall polysaccharides in the abscission zone, probably resulting in the decreased level of cellulose and the mechanical weakness of cell walls.
Thus, it is suggested that jasmonates exert their multiple physiological effects by affecting the metabolic processes of cell wall polysaccharides.     

Role of Enzymes in Growth and Morphology of Neurospora crassa: Cell-Wall-Bound Enzymes and Their Possible Role in Branching

The cell wall of Neurospora crassa contains bound enzymes that can digest its structural polymers. These enzymes are not present at the same levels at all stages of growth. The levels of these autolytic enzymes vary and generally show some relationship to the process of branching. These enzymes were removed from the cell wall by β-mercaptoethanol extraction and were tested for activity against isolated cell wall fractions. Such studies, as well as autolytic studies, showed that enzymes acting on the protein portion of the cell wall (proteases) are more prominent than enzymes that act on the glucan portion (glucanases) of the cell wall. Comparative studies between the wild type and a spreading colonial mutant spco-1 showed that earlier and higher frequency of branching in spco-1 was correlated with a greater amount of these enzymes bound to the cell walls. It is concluded from these observations that autolytic enzymes acting on the protein and glucan portion of the cell walls occur as wall-bound and participate in the process of branching in Neurospora.     

The molecular mechanism of stipe cell wall extension for mushroom stipe elongation growth

Stipe elongation growth is one of the remarkable characteristics of the growth and development of basidiomycete fruiting bodies. Stipe elongation is resulting from the lateral extension of stipe cells. The stipe cell is enclosed within a thin cell wall which must be loosened to expand the wall surface area for accommodation of the enlarged protoplast as the stipe cell elongates. In fungal cell walls, chitin molecules associate with each other by interchain hydrogen bonds to form chitin microfibrils which are cross-linked covalently to matrix polysaccharides. Early, some scientists proposed that stipe elongation was the result of enzymatic degradation of wall polysaccharides, whereas other researchers suggested that stipe elongation resulted from nonhydrolytic disruption of the hydrogen bonds by turgor pressure between wall polysaccharides. Recently, an extensometer was used to determine stipe wall extension for elucidation of the molecular mechanism of stipe elongation. In Coprinopsis cinerea, the native stipe cell wall is induced to extend by acidic buffers and the acid-induced native wall extension activity is located in the growing apical stipe region. A series of current experiments indicate that chitinases play a key role in the stipe wall extension, and β-glucanases mainly function in the wall remodeling for regulation of stipe wall expansibility to cooperate with chitinase to induce stipe wall extension. In addition, fungal expansin-like proteins can bind to chitin to enhance chitin hydrolysis, and their expression pattern is consistent with the stipe elongation growth, which is suggested to play an auxiliary role in the stipe wall extension.     

Antibodies as probes for the study of location and metabolism of (1→3), (1→4)-β-D-glucans

Polyclonal antibodies, raised against ((1→3), (1→4)-β-D-glucans from oat ( Avena sativa L.) caryopsis, were used to investigate the location and the metabolism of mixed-linked β-D-glucans. The binding of these antibodies to the cell walls of oat coleoptiles was shown by an indirect fluorescence method. Distinct fluorescent regions were observed along the inner layers of the walls of each cell. The preimmune serum or antibodies pretreated with oat caryopsis β-D-glucans did not react with the cell walls. Glucan antibodies were bound to the walls of other Poaceae coleoptiles as well as to those from oat mesocotyls and roots, whereas they were not bound to the walls of some dicotyledons tested. The relative glucan content of the cell walls of oat coleoptiles as determined by β-D-glucanase (EC 3.2.1.73) treatment was maximum between day 3 and 4 after soaking, but it declined during further elongation. A rapid decrease in glucan content was observed in excised coleoptiles when auxin or β-D-glucanase was present. There was a clear correlation between the glucan content expressed on a basis of cell wall polysaccharides and the amount of the antibodies bound to the cell walls. These results indicate that the antibodies are useful probes to detect and determine (1→3), (1→4)-β-D-glucans of cell walls.     

Use of RAPD-PCR to isolate a species specific DNA probe for Phytophthora cinnamomi

Abstract Aculeacin A and papulacandin B block cell wall regeneration in Candida albicans protoplasts at an intermediate step in which the protoplasts have not yet synthesized the rigid structure of the cell wall and are therefore still osmotically sensitive. In the presence of the antibiotics, total synthesis of glucan is not significantly lowered with respect to control cells, although most of it appears either in the culture medium or in the regenerating wall as alkali-soluble glucan. Thus, it is proposed that echinocandins (such as aculeacin A) and papulacandins may not inhibit glucan synthesis per se but instead inhibit its incorporation into the supramolecular organization of the cell wall.     

The influence of mutanase and dextranase on the production and structure of glucans synthesized by streptococcal glucosyltransferases

Glucanohydrolases, especially mutanase [alpha-(1-->3) glucanase; EC 3.2.1.59] and dextranase [alpha-(1-->6) glucanase; EC 3.2.1.11], which are present in the biofilm known as dental plaque, may affect the synthesis and structure of glucans formed by glucosyltransferases (GTFs) from sucrose within dental plaque. We examined the production and the structure of glucans synthesized by GTFs B (synthesis of alpha-(1-->3)-linked glucans) or C [synthesis of alpha-(1-->6)- and alpha-(1-->3)-linked glucans] in the presence of mutanase and dextranase, alone or in combination, in solution phase and on saliva-coated hydroxyapatite beads (surface phase). The ability of Streptococcus sobrinus 6715 to adhere to the glucan, which was formed in the presence of the glucanohydrolases was also explored. The presence of mutanase and/or dextranase during the synthesis of glucans by GTF B and C altered the proportions of soluble to insoluble glucan. The presence of either dextranase or mutanase alone had a modest effect on total amount of glucan formed, especially in the surface phase; the glucanohydrolases in combination reduced the total amount of glucan. The amount of (1-->6)-linked glucan was reduced in presence of dextranase. In contrast, mutanase enhanced the formation of soluble glucan, and reduced the percentage of 3-linked glucose of GTF B and C glucans whereas dextranase was mostly without effect. Glucan formed in the presence of dextranase provided fewer binding sites for S. sobrinus; mutanase was devoid of any effect. We also noted that the GTFs bind to dextranase and mutanase. Glucanohydrolases, even in the presence of GTFs, influence glucan synthesis, linkage remodeling, and branching, which may have an impact on the formation, maturation, physical properties, and bacterial binding sites of the polysaccharide matrix in dental plaque. Our data have relevance for the formation of polysaccharide matrix of other biofilms.     

Biochemical requirements for PCBCK1 kinase activity, the Pneumocystis carinii MEKK involved in cell wall integrity

Fungal cell wall assembly is a complicated process involving multiple enzymes and coordinated signaling pathways. The cell wall integrity MAPK pathway acts to stabilize the fungal cell wall during conditions of elevated temperature by regulation of glucan synthesis. The upstream kinase, BCK1, is a critical component of this pathway. Pneumonia is a significant cause of death from the fungal opportunistic pathogen Pneumocystis in immunocompromised states, especially with HIV infection. We have previously shown that PCBCK1 functions in the cell wall integrity pathway in yeast as a functional protein kinase. Kinases have specific requirements for enzymatic function which have not been investigated in fungi. Here we examine the biochemical requirements for PCBCK1 kinase activity expressed in Saccharomyces cerevisiae bck1Delta yeast. PCBCK1 requires 10 mM MgCl(2), pH 6, temperature 30 degrees C, and 10 microM ATP for kinase activity. Interference of the Pneumocystis cell wall integrity pathway is an attractive target for drug development since glucan synthesis machinery is not present in humans.     

Die Zellwand der Pilze als Korsett

Form follows function: The fungal cell wall as a support structure Within the domain of Eukarya, the fungi form a seperate kingdom. The typical formation of branched mycelia from single hyphae is based on cell wall production at the growing hyphal tip. There, excretory vesicle fuse with the membrane releasing cell wall synthesis enzymes like chitin synthase forming the polymer of N‐acetyl glucosamin, the backbone of fungal cell walls. In addition, glucan synthases form the structural component β‐1.3‐glucan. Via β‐1,6‐glucan, cell wall proteins can be linked to the maturing cell wall, and α‐1,3‐glucan can form a matrix within the cell wall, but also a slimy matrix secreted into the medium. A layer of hydrophobins allows for growth into the air, but also facilitates formation of macroscopic structures like mushrooms.     

Specificity of starch synthase isoforms from potato.

In higher plants several isoforms of starch synthase contribute to the extension of glucan chains in the synthesis of starch. Different isoforms are responsible for the synthesis of essentially linear amylose chains and branched, amylopectin chains. The activity of granule-bound starch synthase I from potato has been compared with that of starch synthase II from potato following expression of both isoforms in Escherichia coli. Significant differences in their activities are apparent which may be important in determining their specificities in vivo. These differences include affinities for ADPglucose and glucan substrates, activation by amylopectin, response to citrate, thermosensitivity and the processivity of glucan chain extension. To define regions of the isoforms determining these characteristic traits, chimeric proteins have been produced by expression in E. coli. These experiments reveal that the C-terminal region of granule-bound starch synthase I confers most of the specific properties of this isoform, except its processive elongation of glucan chains. This region of granule-bound starch synthase I is distinct from the C-terminal region of other starch synthases. The specific properties it confers may be important in defining the specificity of granule-bound starch synthase I in producing amylose in vivo.     

Fractionation of the beta-Linked Glucans of Bradyrhizobium japonicum and Their Response to Osmotic Potential

Bradyrhizobium japonicum USDA 110 synthesized both extracellular and periplasmic polysaccharides when grown on mannitol minimal medium. The extracellular polysaccharides were separated into a high-molecular-weight acidic capsular extracellular polysaccharide fraction (90% of total hexose) and three lower-molecular-weight glucan fractions by liquid chromatography. Periplasmic glucans, extracted from washed cells with 1% trichloroacetic acid, gave a similar pattern on liquid chromatography. Linkage analysis of the major periplasmic glucan fractions demonstrated mainly 6-linked glucose (63 to 68%), along with some 3,6- (8 to 18%), 3- (9 to 11%), and terminal (7 to 8%) linkages. The glucose residues were beta-linked as shown by H-nuclear magnetic resonance analysis. Glucan synthesis by B. japonicum cells grown on mannitol medium with 0 to 350 mM fructose as osmolyte was measured. Fructose at 150 mM or higher inhibited synthesis of periplasmic and extracellular 3- and 6-linked glucans but had no effect on the synthesis of capsular acidic extracellular polysaccharides.     

Study of supramolecular structures released from the cell wall of Candida albicans by ethylenediamine treatment

Candida albicans cell wall components were analyzed by ethylenediamine (EDA) treatment. Based on their different solubility properties, the cell wall components produced three fractions (A, B, and C). Fractions B (EDA-soluble, water-insoluble) and C (EDA-insoluble) contained glucan, chitin, and protein in different proportions. After zymolyase (mainly a β-glucanase complex) or chitinase treatment of fractions B and C, more polysaccharides and proteins were solubilized by a second EDA treatment, suggesting that the solubility of the polymers in EDA depends on the degree of polymer interactions. Western blot analysis using two monoclonal antibodies (1B12 and 4C12) revealed electrophoretic patterns that were similar in mycelial and yeast morphologies, except that in material obtained from mycelial walls, an additional band was detected with MAb 1B12. Fluorescence microscopy of cell wall fractions treated with FITC-labeled Con-A, Calcofluor white, and FITC-labeled agglutinin showed that glucan and mannoproteins are uniformly distributed in fractions B and C, while chitin is restricted to distinct patches. Transmission electron microscopy demonstrated that fraction C maintained the original shape of the cells, with an irregular thickness generally wider than the walls. When fraction C was treated with chitinase, the morphology was still present and was maintained by an external glucan layer, with an internal expanded fibrillar material covering the entire cellular lumen. Degradation of the glucan skeleton of fraction C with zymolyase resulted in the loss of the morphology. Received: 1 April 1996 / Accepted: 2 September 1996     

Identification and Functional Ascertainment of the Pneumocystis jirovecii Potential Drug Targets Gsc1 and Kre6 Involved in Glucan Synthesis

The most efficient drug against the human pathogenic fungus Pneumocystis jirovecii is cotrimoxazole targeting the folate biosynthesis. However, resistance toward it is emerging and adverse effects occur in some patients. Studies in rodent models suggested that echinocandins could be useful to treat Pneumocystis pneumonia. Echinocandins inhibit the catalytic subunit Gsc1 of the enzymatic complex ensuring the synthesis of 1,3‐β glucan, an essential constituent of cell walls of most fungi. Besides, inhibitors of the enzyme Kre6 involved in the synthesis of 1,6‐β glucan, another essential component of fungal walls, were recently described. We identified and functionally characterized these two potential drug targets in the human pathogen P. jirovecii by rescue of the null allele of the orthologous gene in Saccharomyces cerevisiae. The P. jirovecii proteins Gsc1 and Kre6 identified using those of the relative Pneumocystis carinii as the query sequence showed high sequence identity to the putative fungal orthologs (53–97% in conserved functional domains). The expression of their encoding genes on plasmid rescued the increased sensitivity to, respectively, caspofungin or calcofluor white of the corresponding S. cerevisiae null allele. The uniqueness and likely essentiality of these proteins suggest that they are potential good drug targets.