Autolysis and aging of Penicillium chrysogenum cultures under carbon starvation: Chitinase production and antifungal effect of allosamidin

In carbon-depleted cultures of Penicillium chrysogenum, age-related chitinases were shown to play a crucial role in both autolysis and fragmentation as indicated by in vivo enzyme inhibition experiments using allosamidin. This pseudotrisaccharide even hindered significantly the outgrowth of new hyphal tips from the surviving yeastlike fragments after glucose supplementation. The antifungal effect of allosamidin on autolyzing P. chrysogenum mycelia was fungistatic rather than fungicidal. In growing hyphae, membrane-bound microsomal chitinase zymogen(s) were detected, which may be indicative of some compartmentalization of these hydrolases. Later, during autolysis, no zymogenic chitinase was detected in any enzyme fraction studied, including microsomes. These observations may explain the different sensitivity of growing and autolyzing mycelia to allosamidin. Chitinases taking part in the age-related fragmentation of hyphae and the outgrowth of surviving hyphal fragments seem to be potent targets for future antifungal drug research.     

Cell wall autolysis in log phase cells of Micrococcus lysodeikticus (luteus).

Log phase cells of Micrococcus lysodeikticus (luteus) IFO 3333 autolyzed when incubated at 37 C in 0.01 M sodium-phosphate buffer pH 7.5. The enzyme involved in the autolysis was recovered mainly in an aqueous phase from cytoplasmic membranes and cytoplasmic materials treated with n-butanol, and proved to be an N-acetylmuramyl-L-alanine amidase. The autolysis of log phase cells suspended in autolyzing buffer was depressed by the addition of trypsin to the buffer.     

Effect of phenylacetic acid feeding on the process of cellular autolysis in submerged batch cultures of Penicillium chrysogenum.

The effects of feeding the 'toxic' penicillin precursor, phenylacetic acid (PAA) at varying rates, upon the process of cellular autolysis, was assessed in batch bioreactor cultures of an industrial strain of Penicillium chrysogenum. Five processes were fed at rates which resulted in extracellular concentrations of PAA ranging from zero (the control) to approximately ten times levels said to be optimal for penicillin biosynthesis. The culture response was assessed chemically and morphologically, using computerised image analysis. High concentrations of PAA reduced biomass and penicillin production, and were associated with increased cellular autolysis. However, the values of classical morphological indices (branch length, main hyphal length and hyphal growth unit) varied little in cultures which showed extensive autolysis and biomass loss. Lower precursor concentrations (0.01 to 1.0 g l-1) had little effect on biomass, penicillin, or upon the levels of autolysis compared with the control process. Therefore, precursor concentration controlled within the optimal range for penicillin production, has little impact upon differentiation or degradation within an industrial culture of P. chrysogenum. By contrast, exploitation of the toxicity of PAA is proposed as a means to bring forward or enhance autolysis, providing a reliable method of 'induction' with which to study the phenomenon in P. chrysogenum.     

菌丝形态分化与头孢菌素C合成的关系

利用显微图像分析法对顶头孢霉菌的菌丝形态进行了定量研究,并统计分析了头孢菌素C发酵过程中的菌丝形态的变化规律,具体对菌丝长度、菌丝宽度和菌丝生长单位进行了定量分析,分析了菌丝形态分化与头孢菌素C合成的关系。研究表明头孢菌素C的合成是在细长菌丝分化成膨大菌丝片段后才启动的,头孢菌素C可能主要是在膨大菌丝分化成节孢子的过程中被合成。     

Effect of oxygen enrichment on morphology, growth, and heterologous protein production in chemostat cultures of Aspergillus niger B1-D.

The response of steady state chemostat cultures of a recombinant Aspergillus niger (B1-D), secreting both a heterologous enzyme (Hen Egg White Lysozyme [HEWL]) and a native enzyme (Glucoamylase), to varying levels of O2 enrichment of the process gas was evaluated. Formation of both the native and the foreign enzyme increased with increasing O2 supply. Conversely, biomass levels and total extracellular protein levels were generally not increased under O2 enriched conditions. Two distinct micromorphologies were apparent in these cultures, one, typically seen under O2 limiting conditions (i. e. at 0 and 10% enrichment levels), tended to be represented by long, sparsely branched hyphal elements, with low percentages of "active" length (i. e. how much of the hypha is cytoplasm filled); whilst, a second micromorphology, typical of O2 enriched cultures at 30 and 50% O2 enrichment, was represented by shorter hyphal elements, with more branching and a higher % "active" length. At these higher O2 levels, formation of a yellow pigment occurred, and signs of culture autolysis were noted. At 50% enrichment, a "stranded" aggregate morphology was apparent, possibly as a response to a hyperoxidant state. Production of both the native enzyme and HEWL correlated well with a simple morphological measure (tip number) or, with % "active" length. It is proposed the morphological changes noted in the cultures were associated with the increased production of both HEWL and glucoamylase.     

Temperature-stress tolerance of the fungal strain Aspergillus niger 26: physiological and ultrastructural changes

The study focuses on the morphological and physiological cell responses to oxidative stress induced by high temperature treatment in the industrially relevant fungus Aspergillus niger 26. Temperatures above 30 °C lead to growth suppression and changes in morphological characteristics: decrease in the size of hyphal elements and increase in “active length” by switching from slightly branched long filaments to a multitude of branched forms containing active cytoplasm. Transmission electron microscopy of fungal cultures heated at 40 °C demonstrated abnormal wavy septation with reduced amount of chitin (as shown by WGA-gold labelling), intrahyphal hyphae development, disintegration of mitochondria and extensive autolysis. Temperature-dependent decrease in the total intracellular protein content and a sharp increase (six to tenfold) in oxidatively damaged proteins were also demonstrated. Elevated temperatures caused a two and threefold increase in catalase and superoxide dismutase activities, respectively.     

Degradation of phospholipids and triacylglycerol,and accumulation of fatty acids in anoxic myocardial tissue,disrupted by freeze-thawing

Summary The degradation of lipids by endogenous hydrolytic activity has been studied in rat cardiac tissue deliberately damaged by freezing and thawing prior to storage under anoxic conditions.Aliquots of the freeze-thawed material were kept at 37°C under an atmosphere of N₂ up to 120 minutes. Triacylglycerol was hydrolyzed at a rate of 0.14 mol fatty acids per minute per gram dry weight of tissue. Hydrolysis of phosphatidylcholine (PC) and phosphatidylethanolamine (PE) was associated with proportional production of lyso PC and lyso PE, respectively. This finding indicates that the activity of lysophospholipase is negligible in autolyzing cardiac tissue. The rate of hydrolysis of PC and PE was found to be 0.10 and 0.06 mol per minute per gram dry weight of tissue. The observation that lyso PC and lyso PE mainly contained saturated and mono-unsaturated fatty acids indicates that phospholipase A₂ rather than A₁ is active in autolyzing cardiac tissue. The accumulation of fatty acids corresponded with the loss of triacylglycerol and phospholipids from the tissue during 120 minutes of autolysis.     

Changes in the shape and size of vacuoles during autolysis of Neurospora crassa

We have studied some of the changes in the vacuolar shape and size during autolysis of Neurospora crassa mycelium. The fungus was grown in the Vogel's medium in a small fermenter. Microscopic examination of the periodically taken samples was carried out and the measurement of the size of vacuoles and of the hyphal and vacuolar areas were made on camera lucida drawings.Before autolysis the vacuolar radius increased 44%. In the non-circular vacuoles there is an increase in the mean length of the major vacuolar axis from 5.4±3.3 to 9.1±4.8 m (70% increase) before autolysis, and a little more than 50% during autolysis. The minor vacuolar axis undergoes a steady increase in length throughout the whole period of autolysis. About 39% of the total vacuolar area is formed before autolysis sets in, whereas the vacuolar area produced during autolysis amounts to 30%. Adopting as a criterion for autolysis the loss in mycelial dry weight, we can conclude that the process of vacuolation, measured as the increase in vacuolar area in mycelium of Neurospora crassa, takes place at a similar rate before and during autolysis.     

Food-protein enzymatic hydrolysates possess both antimicrobial and immunostimulatory activities: a "cause and effect" theory of bifunctionality

The antimicrobial activity (the ability to activate the microbial autolytic system) and immunostimulatory activity (the ability to improve the phagocytic cell functioning) of 20 food-protein hydrolysates [five food proteins (casein, alpha-lactalbumin, beta-lactoglobulin, ovalbumin and serum albumin) hydrolyzed with four gastrointestinal proteinases (trypsin, alpha-chymotrypsin, pepsin and pancreatin)] were examined. All the food-protein hydrolysates acted antimicrobially in vitro towards all 24 microbial strains tested: autolysis of 20 naturally autolyzing strains was activated, with the autolysis activation index (K(A)) ranging from 1.04 to 22.0, while autolysis was induced to values of 2.81-56.7% in four naturally nonautolyzing strains. When given to mice per os, all the food-protein hydrolysates enhanced the phagocytosing capacity of peritoneal macrophages, with the enhancement index (K(I)) ranging from 1.02 to 1.41. A direct correlation between K(A) and K(I) was observed. We make the presumption that K(I) is a function of K(A).     

Tip growth of <Emphasis Type="Italic">Neurospora crassa</Emphasis> under glucose deprivation

Growth parameters of vegetative hyphae and isolated tip fragments of the mycelial fungus N. crassa were studied after complete substitution of an easily metabolized carbon source (glucose) for a non-metabolized one (sorbitol). The images of growing tips were recorded at 20–30-min intervals. Using original image processing software, geometrical parameters of the hyphal trees (length and number of branches, area of convex polygons circumscribed about the hyphal trees, etc.) were determined and growth characteristics, such as rate of tip elongation (V) and the ratio of the total hyphal length to the number of growing tips (termed “hyphal growth unit”, HGU), were calculated. It is shown that after 4–5-h growth in sorbitol-enriched media growth characteristics of intact hyphae did not differ significantly from the corresponding parameters of hyphae growing in glucose-enriched media. In isolated tip fragments (about 800-μ m long), the values of V were lower than those in intact hyphae but did not depend on the carbon source in the nutrient media. However, in such fragments growing in sorbitol-enriched media the number of branches decreased, while the HGU value and the number of large intracellular vacuoles increased. Staining of cells with a standard chitin probe, Calcofluor White (10 μg/ml), did not reveal any considerable differences in hyphal cell walls and septa in tip fragments grown in the presence of different carbon sources. Possible mechanisms of the dependence of the tip growth parameters on the glucose deficiency are discussed.     

The autolysis of industrial filamentous fungi

Fungal autolysis is the natural process of self-digestion of aged hyphal cultures, occurring as a result of hydrolase activity, causing vacuolation and disruption of organelle and cell wall structure. Previously, authors have considered individual aspects of fungal lysis, in terms of either an enzyme, a process or an organism. This review considers both the physiology and morphology of fungal autolysis, with an emphasis on correlations between enzymological profiles and the morphological changes occurring during culture degeneration. The involvement of the main groups of autolytic hydrolases is examined (i.e., proteases, glucanases, and chitinases), in addition to the effects of autolysis on the morphology and products of industrial bioprocesses. We call for a concerted approach to the study of autolysis, as this will be fundamental for research to progress in this field. Increased understanding will allow for greater control of the prevention, or induction of fungal autolysis. Such advances will be applicable in the development of antifungal medicines and enable increased productivity and yields in industrial bioprocesses. Using paradigms in existing model systems, including mammalian cell death and aging in yeast, areas for future study are suggested in order to advance the study of fungal cell death.     

Neem secretory cells: developmental cytology and indications of cell autotoxicity

The neem tree (Azadirachta indica A.Juss.) contains a range of biologically active compounds—mainly triterpenoids produced in single secretory cells, which are distributed among all plant parts. Neem secretions are toxic to animal cells, triggering autolytic mechanisms that culminate in cell disruption. However, little is known about the self-toxicity of these secretions to the cells that produce them. We carried out an anatomical, histochemical, and ultrastructural investigation of neem’s single secretory cells in the shoot apex and in young leaves. We evaluated the morphological changes as possible evidences of stress reactions to their own secretions. The subcellular apparatus involved in synthesis and compartmentation was consistent with hydrophilic and lipophilic secretions. Polymorphic plastids devoid of thylakoids and abundant smooth endoplasmic reticulum in the later stages of differentiation are comparable with previous reports on neem cotyledons with regard to terpenoid synthesis. However, secretions were compartmentalized within autophagic vacuoles and periplasmic spaces instead of in terpenoid vesicles. Cellular swelling, increased vesiculation, dilatation of endoplasmic reticulum cisternae, mitochondrial hypertrophy in the cristolysis process, autolytic vacuoles, and vacuolar degeneration culminating in protoplast autolysis are all consistent with early indications of autotoxicity. The signaling stress reaction mechanism was expressed as cytoplasmic deposits of calcium salt and by the expression of a 70-kDa heat-shock protein. The morphological and histochemical changes in the secreting cells are comparable with those described in animal cells exposed to neem oil. Our data provide evidence of cell damage and signaling reactions linked to these cells’ own secretions before autolysis.

     

Role of hydrolytic enzymes and oxidative stress in autolysis and morphology of <Emphasis Type="Italic">Blakeslea trispora</Emphasis> during β-carotene production in submerged fermentation

The role of hydrolytic enzymes (proteases and chitinase) and oxidative stress in the autolysis and morphology of Blakeslea trispora during β-carotene production from a chemically defined medium in shake flask culture was investigated. The process of cellular autolysis was studied by measuring the changes in biomass dry weight, pH, concentration of β-carotene, specific activity of the hydrolytic enzymes and micromorphology of the fungus using a computerized image analysis system. In addition, the phenomenon of autolysis was associated with high concentrations of reactive oxygen species (ROS). The accumulation of ROS produced during fermentation causes oxidative stress in B. trispora. Oxidative stress was examined in terms of the activities of two key defensive enzymes: catalase (CAT) and superoxide dismutase (SOD). The profile of the specific activities of the above enzymes appeared to correlate with the oxidative stress of the fungus. The high activities of CAT and SOD showed that B. trispora is found under oxidative stress during β-carotene production. The culture began to show signs of autolysis nearly in the growth phase and autolysis increased significantly during the production phase. The morphological differentiation of the fungus was a result of the degradation of the cell membrane by hydrolytic enzymes and oxidative stress. Increased β-carotene production is correlated with intense autolysis of clumps, which has as a consequence the increase of the freely dispersed mycelia.     

Further observations on hydrolysis of the cell wall in the xylem

Summary Hydrolyzed walls (birefringent, Periodic acid/Schiff negative, remnants of primary walls that also lack polyuronides with free carboxyl groups) are demonstrated in the primary xylem of wheat and bean leaves. Walls with similar properties have been found in the primary xylem of a variety of tissues from different species, and are believed to be ubiquitous. It is shown that the pit membrane of intervessel pits between tracheary elements of willow is also a hydrolyzed wall. Combined with the observation byLiese (1965) it seems likely that the removal of non-cellulosic polysaccharides from primary walls unprotected by lignin is a general phenomenon that occurs late in the autolysis of all tracheary elements. Parenchyma cells that abut autolyzing tracheary elements appear to react to hydrolytic attack in a number of ways that are illustrated and discussed.     

Autolysis of Neisseria gonorrhoeae.

Physiological conditions that would provide maximal rates of autolysis of Neisseria gonorrhoeae were examined. Autolysis was found to occur over a broad pH range with the optimum at pH 9.0 IN 0.05 M tris(hydroxymethyl)amino-methane-maleate buffer. The temperature optimum was found to be 40 C. Potassium ions greatly stimulated autolysis at a concentration of 0.01 M. Exposure of growing N. gonorrhoeae cells to penicillin, vancomycin, or D-cycloserine influenced the susceptibility to the autolysis, whereas chloramphenicol afforded some protection against autolysis. The primary structure of the peptidoglycan is composed of muramic acid/glutamic acid/alanine/diaminopimelic acid/glucosamine in approximate molar ratios of 1:1:2:1:1, respectively. Exogenous radioactive diaminopimelic acid, D-glucosamine, and D-alanine were incorporated into peptidoglycan. During autolysis these radioactive fragments were released from cells.     

Stress-induced morphological and physiological changes in γ-linolenic acid production by Mucor fragilis in batch and continuous cultures

Batch and continuous cultures conditions were studied in order to increase γ-linolenic acid production by Mucor fragilis CCMI 142, in response to the presence of ethanol. Continuous cultures were used to add ethanol pulses to steady state pellet cultures. It was demonstrated that pellet size, which allowed homogeneous fungal cultures, can be obtained by means of pH adjustment, thus enabling steady state continuous growth at 2.90±0.05.

The 5 and 2% (v/v) ethanol pulses induced hyphal morphological changes with arthrospore formation. A 1% (v/v) pulse of ethanol did not immediately affect growth, but induced morphological changes, which led to autolysis at the pellet core. A 0.5% (v/v) pulse of ethanol did not affect neither the morphology nor the physiology of the microorganism to any significant extent. The 0.5 and 1% (v/v) ethanol pulses resulted in an increase in the proportion of γ-linolenic acid production up to 11%. Data from batch cultures showed a higher enhancement of ethanol, attaining 30% of γ-linolenic acid.

The increase of γ-linolenic acid content observed in batch and continuous conditions appears to be a response associated with stress induced by the ethanol which seems to be of value as an industrial medium component.     

Differential Roles of the ChiB Chitinase in Autolysis and Cell Death of Aspergillus nidulans

Autolysis is a natural event that occurs in most filamentous fungi. Such self-degradation of fungal cells becomes a predominant phenomenon in the absence of the regulator of G protein signaling FlbA in Aspergillus nidulans. Among a number of potential hydrolytic enzymes in the A. nidulans genome, the secreted endochitinase ChiB was shown to play a major role in autolysis. In this report, we investigate the roles of ChiB in fungal autolysis and cell death processes through genetic, biochemical, and cellular analyses using a set of critical mutants. Determination of mycelial mass revealed that, while the flbA deletion (ΔflbA) mutant autolyzed completely after a 3-day incubation, the ΔflbA ΔchiB double mutant escaped from hyphal disintegration. These results indicate that ChiB is necessary for the ΔflbA-induced autolysis. However, importantly, both ΔflbA and ΔflbA ΔchiB strains displayed dramatically reduced cell viability compared to the wild type. These imply that ChiB is dispensable for cell death and that autolysis and cell death are separate processes. Liquid chromatography-tandem mass spectrometry analyses of the proteins that accumulate at high levels in the ΔflbA and ΔflbA ΔchiB mutants identify chitinase (ChiB), dipeptidyl peptidase V (DppV), O-glycosyl compound hydrolase, β-N-acetylhexosaminidase (NagA), and myo-inositol-1-phosphate synthase (InoB). Functional characterization of these four genes reveals that the deletion of nagA results in reduced cell death. A working model bridging G protein signaling and players in autolysis/cell death is proposed.Autolysis can be described as enzymatic self-degradation of the cells. It involves the activation of several key enzyme classes, resulting in the catabolism of macromolecules within the cell (11, 12, 23). Autolysis is observed in most filamentous fungi at the late stages of cultures and is affected by aging, programmed cell death, development, nutrient limitation, and numerous other factors (39). Despite its fundamental importance in growth, differentiation, secondary metabolism, and heterologous protein production, autolysis is a poorly understood feature of fungal biology (26, 39). It is anticipated that the elucidation of the molecular mechanisms governing fungal autolysis would have great impacts on both fundamental and applied aspects of filamentous fungi.The Aspergillus nidulans ΔflbA mutant exhibits autolysis as a predominant phenotype (18). FlbA is a regulator of G protein signaling (RGS) that negatively controls vegetative growth signaling, primarily mediated by a heterotrimeric G protein composed of FadA (Gα) and SfaD::GpgA (Gβγ) (31, 33, 34, 42, 43). Loss of flbA function causes prolonged activation of G protein signaling, which results in uncontrolled proliferation of hyphal mass, the blockage of sporulation, and hyphal disintegration (autolysis). Because nearly the entire mycelium disappears during autolysis of ΔflbA mutant strains, some component of this phenomenon is hypothesized to involve enzymatic degradation as observed during autolysis of aging fungal cultures (11, 12, 23).In A. nidulans, the last step of autolysis is thought to be the degradation of the cell wall of empty hyphae, which is associated with increased proteinase and chitinase activities (10). There are 15 potential chitinase open reading frames (ORFs) in the genome of A. nidulans. Among these, the class V endochitinase ChiB was shown to play an important role in autolysis. The deletion of chiB considerably reduced the intracellular and extracellular chitinase activities, and the levels of ChiB significantly increased when the fungal cells were starved for carbon sources, an induced condition for hyphal autolysis of A. nidulans (41).In the present study we addressed two primary questions: (i) does ChiB function in the accelerated autolysis and/or cell death caused by loss of FlbA and (ii) are there other hydrolytic enzymes involved in autolysis and/or cell death in A. nidulans? In order to investigate a hypothetical connection between FlbA-controlled autolysis and the ChiB activity, we carried out genetic, biochemical, and cellular studies using the ΔchiB, ΔflbA, ΔflbA ΔchiB (double deletion), and chiB overexpression mutants. We found that, while ChiB plays a crucial role in ΔflbA-induced autolysis, ChiB is dispensable for cell death, corroborating the idea that cell death and autolysis are independent processes in A. nidulans (8). We further present the identification and partial functional characterization of four gene encoding the proteins accumulate at high level in ΔflbA and/or ΔflbA ΔchiB strains and propose a working model linking G protein signaling and autolysis.     

Mitochondrial behaviour during the yeast-hypha transition of Candida albicans

Yeast cells of Candida albicans were brought to germ tube formation and hyphal growth in liquid synthetic medium. The behaviour of mitochondria and mitochondrial nucleoids (mt-nucleoids) during morphological conversion was examined by fluorescence staining with 2-(4-dimethylaminostyryl)-1-methylpyridinium iodide (DASPMI) and 4',6-diamidino-2-phenylindole (DAPI). Parent yeast cells possessed one or very few branched giant mitochondria which were stained intensely with DASPMI. When a germ tube emerged from the parent cell, one end of a giant mitochondrion extended into the germ tube and developed into the elongated form. In mycelia, apical hyphal cells contained giant mitochondria, whereas older hyphal compartments near the parent cells were vacuolated and possessed small, peripherally located mitochondria. The vacuolated hyphal compartments resynthesized cytoplasm before producing branches and contained giant mitochondria. The cytological model for germ tube formation and hyphal growth proposed by Gow and Gooday (1984) is discussed.     

Influence of autolysis on rat gastric endocrine cells

Summary In the present study histochemical parameters of the rat gastric endocrine cells were followed up in the course of 24-h autolysis, and their ultrastructure was studied during autolysis lasting for 60 min. The autolysis occurred at 37°C.In the light microscope, with the histochemical methods applied, only EC, ECL and G cells could be identified during the one-hour autolysis. With the autolysis proceeding for 6 and 12 h, only argyrophil method according to Grimelius (1968) enabled visualization of gastric argyrophilic cells. After 24 h of autolysis, none of the methods applied (not even the Grimelius method) proved to be adequate for successful demonstration of the gastric endocrine cells.In the course of 60-min autolysis, electron microscopic examination provided identification of the EC, ECL, AL, D₁, and G cells with the characteristical ultrastructural appearance of granules. The granules of the endocrine cells (G cells included) were found to be considerably resistant to autolysis. The effect of 60-min autolysis did not induce granule emiocytosis or dissolution of granule content. Autolysis exceeding five minutes resulted in damage of the mitochondria of different degrees and in dilatation of the profiles of endoplasmic reticulum (particularly in G and AL cells).The results obtained in the present study demonstrate the feasibility of in vitro experimental stimulation since the endocrine granules have proved to be resistant to the effects of simultaneously developing autolysis.