Regulation of loblolly pine (Pinus taeda L.) arginase in developing seedling tissue during germination and post-germinative growth

After seed germination, hydrolysis of storage proteins provides a nitrogen source for the developing seedling. In conifers the majority of these reserves are located in the living haploid megagametophyte tissue. In the developing loblolly pine (Pinus taeda L.) seedling an influx of free amino acids from the megagametophyte accompanies germination and early seedling growth. The major component of this amino acid pool is arginine, which is transported rapidly and efficiently to the seedling without prior conversion. This arginine accounts for nearly half of the total nitrogen entering the cotyledons and is likely a defining factor in early seedling nitrogen metabolism. In the seedling, the enzyme arginase is responsible for liberating nitrogen, in the form of ornithine and urea, from free arginine supplied by the megagametophyte. In this report we investigate how the seedling uses arginase to cope with the large arginine influx. As part of this work we have cloned an arginase cDNA from a loblolly pine expression library. Analysis of enzyme activity data, accumulation of arginase protein and mRNA abundance indicates that increased arginase activity after seed germination is due to de novo synthesis of the enzyme. Our results suggest that arginase is primarily regulated at the RNA level during loblolly pine seed germination and post-germinative growth.     

Loblolly pine arginase responds to arginine in vitro

Following germination of loblolly pine (Pinus taeda L.) seeds, storage proteins in the embryo and megagametophyte are broken down to provide nitrogen, in the form of amino acids, to the developing seedling. A substantial portion of the free amino acids released in this process is arginine. Arginine is hydrolyzed in the cotyledons of the seedling by the enzyme arginase (EC 3.5.3.1), which is under developmental control. It has been shown previously that the seedling is able to initiate arginase gene expression in vitro in the absence of the megagametophyte, however, presence of the megagametophyte causes a greater accumulation of arginase protein and mRNA. Using an in vitro culture system we show that arginine itself may be responsible for up-regulating arginase activity. Application of exogenous arginine to cotyledons of seedlings germinated in the absence of the megagametophyte caused an increase in total shoot pole arginase activity as well as arginase specific activity. Arginine was also able to induce arginase mRNA accumulation in the same tissue.     

The role of the megagametophyte in maintaining loblolly pine (Pinus taeda L.) seedling arginase gene expression in vitro

Following loblolly pine (Pinus taeda L.) seed germination, storage-protein breakdown in the megagametophyte and in the seedling results in a large increase in the seedling's free amino acid pool. A substantial portion of both the storage proteins and the amino acid pool is arginine, a very efficient nitrogen-storage compound. Free arginine is hydrolyzed in the seedling by the enzyme arginase (EC 3.5.3.1), which is under strong developmental control. At present, regulation of arginase in conifers is not well understood. Here we report the utilization of an in vitro culture system to address the separate impacts of the seedling and megagametophyte tissues on arginase enzyme activity, protein levels and patterns of gene expression. We also describe the generation of an anti-arginase antibody prepared from a histidine-tagged loblolly pine arginase fusion protein expressed in Escherichia coli. Our results indicate that arginase gene expression in the seedling is initiated by the seedling itself and then maintained or up-regulated by the megagametophyte. The contribution of storage-protein breakdown and the free amino acid pool, particularly arginine, in this regulation is also addressed.     

Levels of sulfhydryls and disulfides in proteins from Neurospora crassa conidia and mycelia

Proteins extracted with 6 M guanidine at 90 degrees C from conidia (asexual spores) of Neurospora crassa contained ca. 25% more total protein thiol and a fivefold-higher content of disulfide bonds than proteins extracted from mycelia, as determined by labeling with iodo[14C]acetic acid. The total thiol content was 88 mumol/g of protein in conidia and 70 mumol/g of protein in mycelia. The level of protein disulfide was 18.5 mumol/g of protein in conidia and 3.5 mumol/g of protein in mycelia, by the iodo[14C]acetic acid labeling method. Confirmatory results were obtained with 5'5-dithio-bis-2-nitrobenzoic acid titration of protein thiol groups in 1% sodium dodecyl sulfate as well as by amino acid analysis of cysteic acid derivatives. Buffer-extracted proteins from conidia, but not mycelia, were found to contain enriched levels of protein thiols and disulfides per gram of protein as compared with guanidine hydrochloride extracts. It was demonstrated that the high disulfide content of crude conidial extracts was not due to measurable levels of mixed disulfides formed between protein sulfhydryl groups and cysteine. During germination of the conidia, the high disulfide levels of the conidial proteins remained constant. These data suggest that, unlike the disulfides of glutathione, the bulk of conidial protein disulfides were not reduced, excreted, or extensively degraded during germination.     

Purification and characterization of a 40.8-kDa cutinase in ungerminated conidia of Botrytis cinerea Pers.: Fr

Cytoplasmic soluble proteins from ungerminated conidia of Botrytis cinerea exhibited cutinase activity. A 40.8-kDa cutinase was purified to homogeneity from this crude conidial protein extract. This cutinase does not correspond either to constitutive or to induced lytic cutin enzymes already described by other authors. The possible role of this constitutive cutinase in the induction of other cutinolytic proteins in the early stages of infection of plants by B. cinerea is discussed.     

Production of Chlamydospores and Conidia in Submerged Culture by Rhynchosporium alismatis, a Mycoherbicide of Alismataceae in Rice Crops

The objective of this work was to evaluate the production of chlamydospores and conidia of Rhynchosporium alismatis in a liquid Czapex-Dox based medium supplemented with increasing concentrations of sodium nitrate and malt extract. In addition, the germination of chlamydospores was evaluated. A high concentration of malt extract (4.4 g L^-1) as the sole carbon source and a high level of sodium nitrate as the sole nitrogen source (3.3 g L^-1) were shown to increase chlamydospore production while agitation (150 rpm) enhanced conidial yields. Maximum chlamydospore production (2.03×10⁵±0.7 total chlamydospores mg DW^-1) was achieved in cultures grown in a medium supplemented with 8.8 g L^-1 malt extract and 5.74 g L^-1 sodium nitrate. Two days growth was required for maximum chlamydospore and conidial production, while 6 days was necessary to obtain maximum dry weight accumulation (350 mg per flask). Germination of chlamydospores (90%) was significantly higher than germination of conidia (47%) after 2 days growth.     

Nitrogen transport in the xylem sap of Quercus ilex: the role of ornithine

The storage and remobilization of nitrogen in deciduous and evergreen species is a major source of N, supporting the seasonal growth of trees. In evergreens, in addition to wood and roots, older leaves are important reservoirs of N used in the growth of new foliage. Just before bud burst, when transpiration is inactive or low, and when uptake of nitrogen by the roots may be restricted due to low temperatures, levels of organic N in the xylem are high. Amino acids usually comprise the bulk of this organic N. Changes in amino acid concentrations in early spring are thought to result mainly from hydrolysis of N reserves, and not from current N uptake. The seasonal profiles of amino acids in the xylem sap of Quercus ilex, an evergreen Mediterranean tree, were investigated. The first amino acid detected in the xylem sap before spring was ornithine, which may result from the breakdown of arginine present in storage proteins. Arginine is one of the main amino acids present in storage proteins because each arginine molecule has four nitrogen atoms. When protein degradation increases the free arginine pool, the arginase activity is enhanced and, consequently, the conversion of arginine to ornithine. It seems that ornithine has an important role in N transport early in the growth season of Q. ilex.     

Conidium formation and germination inNeurospora crassa: Glutamic acid metabolism

In order to assess the role of the large (200 μmol/g) pool of glutamic acid normally found in wild-typeNeurospora crassa conidia, the levels of glutamic acid and other amino acids were manipulated by employing a strain blocked in glutamate synthesis. The double mutant strainen(am)-2;am, which has a lesion in NADP-glutamate dehydrogenase (am) and is auxotrophic for glutamate, was employed in order to obtain conidia with a decreased level of glutamic acid. When cultures of this strain were grown in the presence of 50 or 20 mM glutamate as sole nitrogen source, conidia were obtained with a glutamate pool of 97 and 47 μmole/g, respectively, which represents approximately 57 and 28% of the control values obtained from a prototrophic strain. These observations are interpreted to indicate that conidiation can occur even without the accumulation of the entire pool of glutamate in the conidia. However, when conidia of this double mutant strain were incubated in a minimal medium lacking glutamate, germ tube formation was greatly delayed. Germ tube formation was normal in the presence of glutamate or alanine. During germination of conidia in minimal medium, the levels of glutamate, glutamine, aspartic acid, and γ-aminobutyric acid (GABA) were measured at different times. The results obtained support the view that glutamic acid was catabolized through the GABA pathway during the very early stages of germination.     

The effects of some storage conditions on viability of Lecanicillium lecanii conidia to whitefly (Homoptera: Trialeurodes vaporariorum)

A study on the survival of Lecanicillium lecanii conidia in storage at room temperature was carried out. Firstly, drying methods of conidia powder were compared. Vacuum-freeze drying (VFD) was more suitable for drying conidia as compared to vacuum drying (VD) at room temperature. Vacuum-freeze drying for 24-h resulted in a water content of 5.4%, and a viability, determined as germination of conidia in 2% glucose solution after16 h, was 90.3% and the infection in greenhouse whitefly, Trialeurodes vaporariorum was about 94.7% at a dose of 1×10⁸ conidia/mL. Secondly, the factors influencing viability of conidia stored at room temperature were evaluated in the laboratory. Temperature was the most critical factor influencing conidial storage stability, among the tested factors affecting survival of conidia stored at room temperature for 6 months. Both conidial germination and infection of hosts decreased with storage temperature increasing from 15 to 35°C, and at 35°C the survival of stored conidia for 6 months was near zero. The moisture content of the conidial powder was another major factor influencing viability of stored conidia at room temperature. Conidial powder dried to about 5% moisture content showed higher viability than non-dried conidial powder. For the carriers, clay and charcoal were more suitable for storage of L. lecanii conidia at room temperature. At a room temperature of 25°C, L. lecanii conidia which were dried to 5% water content and mixed with clay or charcoal could retain about 50% survival after 6 months' storage.     

The potential biocontrol agent Pseudomonas antimicrobica inhibits germination of conidia and outgrowth of Botrytis cinerea

AIMS: Antifungal metabolites of Pseudomonas antimicrobica have previously been shown to inhibit conidial germination of the grey mould pathogen Botrytis cinerea. In this study, metabolites of the bacterium have been tested at different stages of Botrytis germination to determine their effects on germ tube production and extension. METHODS AND RESULTS: Metabolites were added to conidia that had been pre-incubated for either 120 or 255 min. Pseudomonas antimicrobica inhibited B. cinerea conidial germination and caused a significant reduction in germ tube extension, irrespective of the stage of germination. Abnormal germination and a reduction in the frequency of lateral branching of the germ tubes in the presence of the metabolites were also reported, suggesting interference with normal hyphal development. CONCLUSION: The bacterium can inhibit germination of conidia and extension of germ tubes at different stages of Botrytis development. SIGNIFICANCE AND IMPACT OF THE STUDY: The antagonistic activity of the bacterium has promising implications for its use as a biocontrol agent.     

Comparison between gene expression of conidia and germinating phase in Trichophyton rubrum

Trichophyton rubrum is a dominating superficial dermatophyte, whose conidial germination is correlated to pathopoiesis and a highly important developmental process. To investigate the changes of physiology, biochemistry and cytology during the germination, we selected 3364 function identified ESTs from T. rubrum cDNA library to construct cDNA microarrays, and compared the gene expression levels of conidia and germinating phase. Data analysis indicated that 335 genes were up-regulated during the germination, which mainly encoded translated, modified proteins and structural proteins.The constituents of cell wall and cell membrane were synthetized abundantly, suggesting that they are the foundation of cell morphogenesis. The ingredients of the two-component signal transduction system were up-regulated, presuming that they were important for the conidial germination. Genes of various metabolic pathways were expressed prosperously, especially the genes that participated in glycolysis and oxidative phosphorylation were up-regulated on the whole, demonstrating that in the environment with sufficient oxygen and glucose, conidia obtained energy through aerobic respiration.This paper provides important clues which are helpful to understanding the changes in gene expression, signal conduction and metabolism characteristics during T. rubrum conidial germination, and possess significant meaning to the study of other superficial dermatophytes.     

Functional analysis of the ATG8 homologue Aoatg8 and role of autophagy in differentiation and germination in Aspergillus oryzae

Autophagy is a well-known degradation system, induced by nutrient starvation, in which cytoplasmic components and organelles are digested via vacuoles/lysosomes. Recently, it was reported that autophagy is involved in the turnover of cellular components, development, differentiation, immune responses, protection against pathogens, and cell death. In this study, we isolated the ATG8 gene homologue Aoatg8 from the filamentous fungus Aspergillus oryzae and visualized autophagy by the expression of DsRed2-AoAtg8 and enhanced green fluorescent protein-AoAtg8 fusion proteins in this fungus. While the fusion proteins were localized in dot structures which are preautophagosomal structure-like structures under normal growth conditions, starvation or rapamycin treatment caused their accumulation in vacuoles. DsRed2 expressed in the cytoplasm was also taken up into vacuoles under starvation conditions or during the differentiation of conidiophores and conidial germination. Deletion mutants of Aoatg8 did not form aerial hyphae and conidia, and DsRed2 was not localized in vacuoles under starvation conditions, indicating that Aoatg8 is essential for autophagy. Furthermore, Aoatg8 conditional mutants showed delayed conidial germination in the absence of nitrogen sources. These results suggest that autophagy functions in both the differentiation of aerial hyphae and in conidial germination in A. oryzae.     

EglD, a putative endoglucanase, with an expansin like domain is localized in the conidial cell wall of Aspergillus nidulans

Although the process of conidial germination in filamentous fungi has been extensively studied, many aspects remain to be elucidated since the asexual spore or conidium is vital in their life cycle. Breakage and reformation of cell wall polymer bonds along with the maintenance of cell wall plasticity during conidia germination depend upon a range of hydrolytic enzymes whose activity is analogous to that of expansins, a highly conserved group of plant cell wall proteins with characteristic wall loosening activity. In the current study, we identified and characterized the eglD gene in Aspergillus nidulans, an expansin-like gene the product of which shows strong similarities with bacterial and fungal endo-beta1,4-glucanases. However, we failed to show such activity in vitro. The eglD gene is constitutively expressed in all developmental stages and compartments of A. nidulans asexual life cycle. However, the EglD protein is exclusively present in conidial cell walls. The role of the EglD protein in morphogenesis, growth and germination rate of conidia was investigated. Our results show that EglD is a conidial cell wall localized expansin-like protein, which could be involved in cell wall remodeling during germination.     

Early Expression of the Calmodulin Gene, Which Precedes Appressorium Formation in Magnaporthe grisea, Is Inhibited by Self-Inhibitors and Requires Surface Attachment

Fungal conidia contain chemicals that inhibit germination and appressorium formation until they are well dispersed in a favorable environment. Recently, such self-inhibitors were found to be present on the conidia of Magnaporthe grisea, and plant surface waxes were found to relieve this self-inhibition. To determine whether the self-inhibitors suppress the expression of early genes involved in the germination and differentiation of conidia, the calmodulin gene was chosen as a representative early gene, because it was found to be expressed early in Colletotrichum gloeosporioides and Colletotrichum trifolii differentiation. After calmodulin cDNA and genomic DNA from M. grisea were cloned, the promoter of the calmodulin gene was fused to a reporter gene, that for green fluorescent protein (GFP), and transformed into the M. grisea genome. Confocal microscopic examination and quantitation of expression of GFP green fluorescence showed (i) that the expression of the calmodulin gene decreased significantly when self-inhibition of M. grisea appressorium formation occurred because of high conidial density or addition of exogenous self-inhibitors and (ii) that the expression level of this gene was restored when self-inhibition was relieved by the addition of plant surface waxes. The increase in fluorescence correlated with the percentage of conidia that formed appressoria. The induction of calmodulin was also confirmed by RNA blotting. Concanavalin A inhibited surface attachment of conidia, GFP expression, and appressorium formation without affecting germination. The high correlation between GFP expression and appressorium formation strongly suggests that calmodulin gene expression and appressorium formation require surface attachment.