TheAspergillus nidulans geneschsA andchsD encode chitin synthases which have redundant functions in conidia formation

We previously isolated three chitin synthase genes (chsA, chsB, andchsC) fromAspergillus nidulans. In the present work, we describe the isolation and characterization of another chitin synthase gene, namedchsD, fromA. nidulans. Its deduced amino acid sequence shows 56.7% and 55.9% amino acid identity, respectively, with Cal1 ofSaccharomyces cerevisiae and Chs3 ofCandida albicans. Disruption ofchsD caused no defect in cell growth or morphology during the asexual cycle and caused no decrease in chitin content in hyphae. However, double disruption ofchsA andchsD caused a remarkable decrease in the efficiency of conidia formation, while double disruption ofchsC andchsD caused no defect. Thus it appears thatchsA andchsD serve redundant functions in conidia formation.     

Bioelectric and biosynthetic aspects of cell polarity inAllomyces macrogynus

Summary In contrast to all filamentous fungi examined to date, vegetative hyphae ofAllomyces macrogynus, whether extending or not, produced an outward flow of positive electrical current, at a maximum of 0.16 A cm^–2 around 40 m behind the apex, as measured with a vibrating probe. Inward currents of up to 0.55 A cm^–2 were recorded around the rhizoids. Increases in outward current were observed in hyphae pre-grown under oxygen deficiency and then allowed to widen backwards to the hyphal base in sufficient oxygen. When spores were germinated in an applied electrical field they produced rhizoids predominantly towards the anode. Hyphae were produced initially towards the cathode but later bent around towards the anode. Experiments with a range of chemicals provided no evidence for the involvement of calcium in vegetative growth and development inA. macrogynus. Polyoxin and nikkomycin, inhibitors of chitin synthesis, had no effect on swimming zoospores, but inhibited wall formation of cysts, rhizoids and forward and backward growing hyphae.     

Enhanced phytate dephosphorylation by using Candida melibiosica yeast-based biofuel cell

We report for the first time that Candida melibiosica expresses enhanced phytase activity when grown under biofuel cell polarization in a nutrient-poor medium, containing only fructose as a carbohydrate source. Phytase activity during the cultivation under polarization reached up to 25 U per g dry biomass, exceeding with 20 ± 3 % those of the control. A participation of the enzyme in the adaptation processes to the stress conditions is proposed. In addition, steady-state electrical outputs were achieved during biofuel cell operation at continuous polarization under constant load. The obtained results show that C. melibiosica yeast-based biofuel cell could be used for simultaneous electricity generation and phytate bioremediation.     

Effects of nitrogen delivery on chitin nanofiber production during batch cultivation of the diatom <Emphasis Type="Italic">Cyclotella</Emphasis> sp. in a bubble column photobioreactor

The photosynthetic diatom Cyclotella sp. extrudes chitin nanofibers following cell division. This diatom requires silicon for cell wall biosynthesis and division, as well as nitrogen for biosynthesis of intracellular material and extracellular chitin, an N-acetyl glucosamine biopolymer. The initial nitrogen/silicon molar ratio was the critical parameter for assessing the limits of nitrogen delivery on cell number and chitin production during batch cultivation of Cyclotella in a bubble column photobioreactor under silicon-limited growth conditions, using nitrate as the nitrogen source. The peak rate of volumetric chitin production increased linearly, from 3.0 to 46 mg chitin L^?1 day^?1, with increasing N/Si ratio over the range studied (0.82 to 8.6 mol N mol^?1 Si). However, the cell number yield and the chitin yield per cell increased asymptotically with increasing N/Si ratio, achieving a final cell number yield of 5.3?×?10⁹?±?2.6?×?10⁸ cells mol^?1 Si and chitin yield of 28.7?±?1.2 mg chitin per 10⁹ cells (1.0 S.E.). An N/Si ratio of at least 4.0 mol N mol^?1 Si achieved 90% of the asymptotic chitin yield. This study has shown that scalable cultivation systems for maximizing chitin nanofiber production will require delivery of both silicon and optimal nitrogen under silicon-limiting growth conditions to promote cell division and subsequent chitin formation.     

Chitin contents in different morphological forms ofRhizopus nigricans

Chitin (one of the major cell wall constituents ofZygomycetes) was determined in different morphological forms ofRhizopus nigricans mycelia grown at different cultivating conditions. Microscopic observation and chemical analysis has revealed that at the phase of active growth, long and sparsely branched hyphae of dispersed mycelia contain 2.3% of dry cell mass of this structural polysaccharide, which is higher than the value found in pellets of the same age. A large increase in chitin content up to 9.0% of cell dry mass was determined in older, partially autolyzed mycelia in the form of pellets.     

Influence of applied electrical fields on yeast and hyphal growth of Candida albicans

Yeast cells of Candida albicans which had been attached to polylysine-coated microscope slides were induced to form buds or germ tubes in the presence of external electrical fields. The sites of budding and germ tube formation and the growth of germ tubes and hyphal branches were polarized preferentially towards the cathode. Buds were not converted to pseudohyphae or germ tubes by the field and the field had no effect on the positioning of nuclei or septa in the yeast cell or germ tube. Buds were less polarized than germ tubes at any given applied voltage. The polarization of buds reached a peak at an electrical field of 12 mV per cell. Polarization of germ tubes was biphasic, increasing rapidly with increasing field strengths up to 5 mV per cell, and then more slowly in stronger fields. An electrical field was only required for a fraction of the time taken for germ tubes to start to form, so cells retained a memory of experiencing an electrical field which influenced the selection of sites of evagination. Increasing the electrical field delayed the time of germ tube evagination and inhibited the rate of germ tube extension. Unlike previous findings with other filamentous fungi, germ tubes grew unidirectionally towards the cathode for extended periods and did not deviate to a perpendicular orientation. This result suggests that the septal pore of the filamentous form may have high electrical resistance and would act as an effective barrier to solute transport between intercalary compartments.     

Induced production of chitinase to enhance entomotoxicity of Bacillus thuringiensis employing starch industry wastewater as a substrate

Induced production of chitinase during bioconversion of starch industry wastewater (SIW) to Bacillus thuringiensis var. kurstaki HD-1 (Btk) based biopesticides was studied in shake flask as well as in computer-controlled fermentors. SIW was fortified with different concentrations (0%; 0.05%; 0.1%; 0.2%; 0.3% w/v) of colloidal chitin and its consequences were ascertained in terms of Btk growth (total cell count and viable spore count), chitinase, protease and amylase activities and entomotoxicity. At optimum concentration of 0.2% w/v colloidal chitin, the entomotoxicity of fermented broth and suspended pellet was enhanced from 12.4 × 10⁹ (without chitin) to 14.4 × 10⁹ SBU/L and from 18.2 × 10⁹ (without chitin) to 25.1 × 10⁹ SBU/L, respectively. Further, experiments were conducted for Btk growth in a computer-controlled 15 L bioreactor using SIW as a raw material with (0.2% w/v chitin, to induce chitinase) and without fortification of colloidal chitin. It was found that the total cell count, spore count, delta-endotoxin concentration (alkaline solubilised insecticidal crystal proteins), amylase and protease activities were reduced whereas the entomotoxicity and chitinase activity was increased with chitin fortification. The chitinase activity attained a maximum value at 24 h (15 mU/ml) and entomotoxicity of suspended pellet reached highest (26.7 × 10⁹ SBU/L) at 36 h of fermentation with chitin supplementation of SIW. In control (without chitin), the highest value of entomotoxicity of suspended pellet (20.5 × 10⁹ SBU/L) reached at 48 h of fermentation. A quantitative synergistic action of delta-endotoxin concentration, spore concentration and chitinase activity on the entomotoxicity against spruce budworm larvae was observed.     

Surface charge and hydrophobicity of wild and mutantCrithidia fasciculata

Surface charge of wild-typeCrithidia fasciculata and three drug-resistant mutants (T^R3, TFR^R1, and FU^R11) was studied by direct zeta-potential determination and ultrastructural cytochemistry. Surface tension was also investigated by measurements of the advancing contact angle formed by the protozoa monolayers with drops of liquids of different polarities. The individual zeta potential varies markedly among theC. fasciculata cells. The wild and FU^R11 mutant strains displayed lower negative surface charge (?12.5 and ?9.5 mV, respectively), as compared with the T^R3 (?14.8 mV) and TFR^R1 (?14.7 mV) mutant strains. Binding of cationized ferritin (CF) was observed at the cell surface of wild and mutant strains ofC. fasciculata. Neuraminidase treatment reduced the negative surface charge in the TFR^R1 and T^R3 mutants in about 37 and 29%, respectively, whereas no significant change was observed with the wild and FU^R11 mutant strains. These findings suggest that sialic acid residues are the major anionogenic groups on the surface ofC. fasciculata. The density of sialic acid residues per cell in wild and mutant strains ofC. fasciculata falls in a range of 1.4×10⁴ to 3.6×10⁴. Marked differences of hydrophobicity were also observed. For example, the TFR^R1, FU^R11, and T^R3 drug-resistant mutant strains showed higher contact angle values (55.4, 54.2, and 49.3, respectively) than the wild-type (35.6), as assessed by α-bromonaphtalene.     

Conservation of two predator species for biological control ofChrysophtharta bimaculata (Col.: Chrysomelidae) in tasmanian forests

Chrysophtharta bimaculata (Olivier) (Coleoptera: Chrysomelidae) is a major defoliator of regeneration eucalypt trees in Tasmania causing a significant reduction in height and diameter increment of trees which reduces wood volume per hectare. A study to conserve and enhance the efficiency of coccinellid species chieflyCleobora mellyi (Mulsant) (Coleoptera: Coccinellidae), and the cantharid,Chauliognathus pulchellus (Macleay) (Coleoptera: Cantharidae), for the biological control ofC. bimaculata was conducted in young regeneration forests in southern Tasmania from 1991–92. Cantharid adults and coccinellid adults and larvae feed onC. bimaculata eggs and, to a lesser extent, young larvae. The study found that coccinellids were more active throughout the egg and early (1^st and 2^nd) stage ofC. bimaculata. The cantharid, however was active only during the egg stage of the prey and then disappeared from the plantation. The coccinellids were therefore the most useful predators, but their population declined when the prey reached the 3^rd and 4^th stages. As shortage of food may account for this decline, supplementary food was provided in the form of sucrose sprays or sugar granules at a feeding station. This resulted in the retention of both predators and particularly the coccinellids and enhanced their efficacy.     

Phenotypic characterization of a trifluoperazine-resistant mutant ofMucor rouxii

A trifluoperazine-resistant (TFP¹) mutant (strain G5) ofMucor rouxii was isolated and some biochemical and physiological parameters were studied. It resisted up to 250 μM TFP compared to 100 μM observed for the wild-type strain. At this drug concentration the mutant strain G5 germinated, grew, exhibited yeast-mycelium transition, and chitin synthesisin vivo. The mutant strain presentedin vitro levels of calmodulin activity similar to those of the wild-type, but with less sensitivity to inhibition by TFP. Also, with regard to spore germination and cell growth, mutant G5 presented cross-resistance to calmidazolium, another potent anticalmodulin drug. Partially purified chitin synthetase preparations of mutant G5 exhibited a diminished enzymatic activity, compared to the wild-type. The results presented in this work suggest the participation of a Ca²⁺-calmodulin complex in growth and differentiative processes ofMucor and substantiate the role of this complex in chitin synthesis.     

Pea saponins in the pea-Fusarium solani interaction

Saponin-like compounds isolated fromPisum sativum were tested for antifungal activity, effect on pea tissue, and effect on chitin and chitosan synthesis inFusarium solani. Growth ofFusarium solani f. sp.phaseoli and f. sp.pisi macroconidia was inhibited by saponins at concentrations of 150 and 300 μg/ml, respectively. Pod endocarp tissue treated with saponins showed temporary reduction in cell viability (esterase activity); however, there was no significant reduction in resistance toF. solani f. sp.phaseoli, normally incompatible on peas. Macroconidia germinated in the presence of saponin showed decreased incorporation ofN-[³H]acetylglucosamine into chitin and chitosan at concentrations as low as 32 μg/ml. Thus, a reduction in chitin and chitosan synthesis may be associated with inhibition of fungal growth. Saponins may contribute to the disease resistance of peas     

TheAspergillus nidulans geneschsA andchsD encode chitin synthases which have redundant functions in conidia formation

We previously isolated three chitin synthase genes (chsA, chsB, andchsC) fromAspergillus nidulans. In the present work, we describe the isolation and characterization of another chitin synthase gene, namedchsD, fromA. nidulans. Its deduced amino acid sequence shows 56.7% and 55.9% amino acid identity, respectively, with Cal1 ofSaccharomyces cerevisiae and Chs3 ofCandida albicans. Disruption ofchsD caused no defect in cell growth or morphology during the asexual cycle and caused no decrease in chitin content in hyphae. However, double disruption ofchsA andchsD caused a remarkable decrease in the efficiency of conidia formation, while double disruption ofchsC andchsD caused no defect. Thus it appears thatchsA andchsD serve redundant functions in conidia formation.     

Ultrastructural differences between wall apices of growing and non-growing hyphae ofSchizophyllum commune

Summary Newly synthesized chitin at the hyphal apex ofSchizophyllum commune was shown to be highly susceptible to chitinase degradation and solubilization by dilute mineral acid. With time this chitin became gradually more resistant to these treatments. With a combination of the shadow-cast technique and electron microscopic autoradiography it could be shown that this process occurred as the newly synthesized chitin moved into subapical parts of growing hyphae but also in non-growing apices which had ceased growth after incorporation of theN-acetyl[6-³H]glucosamine. These results are in agreement with a model which explains apical morphogenesis by assuming that the newly synthesized wall material at the apex is plastic due to the presence of individual polymer chains but becomes rigidified because of subsequent physical and chemical changes involving these polymers.Dedicated to Dr. A.Quispel, Professor of Botany at the University of Leiden, on occasion of his retirement.     

Morphology engineering of Penicillium chrysogenum by RNA silencing of chitin synthase gene

Chitin synthases, that catalyze the formation of chitin the major component of cell walls in most filamentous fungi, play crucial roles in the growth and morphogenesis. To investigate the roles of chitin synthase in Penicillium chrysogenum, we developed an RNAi system to silence the class III chitin synthase gene chs4. After transformation, mutants had a slow growth rate and shorter but highly branched hyphae. All transformants either were unable to form conidia or could form only a few. Changes in chs4 expression could lead to a completely different morphology and eventually cause distinct penicillin yields. In particular, the yield of one transformant was 41 % higher than that of the original strain.     

An electrogenic Na+/K+ pump in the choroid plexus

Intracellular electrical potential and potassium activity was measured by means of microelectrodes in the epithelial cells of choroid plexus from bullfrogs (Rana catesbeiana). Ouabain applied from the ventricular side caused an abrupt depolarisation of 10 mV but only a gradual loss of potassium from the cells. Readministration of potassium to the ventricular solution of plexuses which were previously depleted of potassium, caused a hyperpolarisation of about 4 mV. These two experiments are consistent with the notion of an electrogenic Na⁺/K⁺ pump situated at the ventricular membrane and which pumps potassium into the cell and sodium into the ventricle. The numerical values obtained suggest that 3 sodium ions are pumped for 2 potassium ions. The permeability coefficient for potassium exit from the cell is calculated to be 1.24 · 10^?5 cm^?1 · s^?1 expressed per cm² of flat epithelium.     

Polarization of fucoid eggs by steady electrical fields.

Pelvetia eggs were exposed to steady electric fields from 5 hr after fertilization until their rhizoids began to grow out some 6 to 10 hr later. Eleven batches of eggs responded by initiating rhizoids towards the positive electrode; two batches responded by growing towards the negative electrode; and three grew towards the negative one in small fields and towards the positive one in higher fields. Polarization, defined as the average cosine of the outgrowth directions, was proportional to field strength up to polarization values of 50% for the positive responses and 75% for the negative ones. A voltage drop of 6 mV/cell induced 10% polarization in the positively galvanotropic batches, while 3 mV/cell did this in the negative ones. We reason that both responses are mediated by faster calcium entry at the future growth point. It is supposed to be faster there in positively galvanotropic eggs because the membrane potential, hence the driving force, is highest; in negatively galvanotropic eggs because depolarization induces an overbalancing increase in calcium permeability there.     

Chemical and ultrastructural studies on the cell walls of the yeastlike and mycelial forms of Histoplasma capsulatum

Chemical and ultrastructural studies of the cell walls of the yeastlike (Y) and mycelial (M) forms ofHistoplasma capsulatum G-184B revealed that the Y form contained about 46.5% ofα-glucan, 31.0% ofβ-glucan, 7.7% of galactomannan and 11.5% of chitin, whereas the M form cell wall contained about 18.8% ofβ-glucan, 24.7% of galactomannan, 25.8% of chitin, and essentially noα-glucan. Theα-glucan of the Y form contained mainly anα-(1 → 3)-linkage. Theβ-glucans of both forms may have mainly aβ-(1 → 3)-linkage. Chitin microfibrils were located mainly in the inner portion of the cell walls of the Y and M forms, whereas theα-glucan fibers were observed only in the outer portion of the Y form cell wall.     

Characterization of Dimorphism in Cladosporium werneckii

Yeast forms of the dimorphic fungus Cladosporium werneckii grow by polar budding and yield a homogeneous yeast phase when cultured at 21 C in an agitated sucrose-salts medium (Czapek-Dox broth). Yeast extract enrichment of such a yeast phase consisting of 10⁴ yeasts per ml induces a quantitative conversion of the yeasts to true hyphae. This conversion is not mediated by a transition cell and is often attended by capsule formation. When 10⁵ or 10⁶ yeasts per ml receive enrichment, a nonquantitative conversion to moniliform hyphae is effected and no capsule formation is observed. Rapid agitation compared to slow agitation or stationary incubation of the nutritionally mediated conversion cultures greatly accelerates the production of lateral hyphal buds or their yeast progenies. These cells appear incapable of undergoing nutritional conversion to hyphae, but instead must grow for several generations in the unenriched sucrose-salts medium to restore conversion competence. Temperature shifts affect directly the morphology and morphogenesis of the yeast in unenriched medium; at 17 C yeasts are smaller and more ovoid than at 21 C, and at 30 C marked conversion of yeasts to moniliform hyphae occurs. A methodology employing the Coulter counter and Coulter channelizer provides evidence that direct correlations do not always exist between the optimum conditions for the growth of C. werneckii and the optimum conditions for its yeast-to-mold conversion.     

A model of the hyphal septum ofCandida albicans

Observations of chitin preparations from hyphae ofCandida albicans suggest that the septum is made of two juxtaposed plates rich in chitin microfibrils. Thus the trilaminate appearance of sections of septa seen in electron micrographs can be interpreted as two plates of densely staining chitin-rich material separated by a lightly staining area. This model may be applicable to septa of other fungi.