On-line study of fungal morphology during submerged growth in a small flow-through cell

A flow-through cell is designed to measure the growth kinetics of hyphae of Aspergillus oryzae grown submerged in a well controlled environment. The different stages of the growth process are characterized, from the spore to the fully developed hyphal element with up to 60 branches and a total length lt up to 10,000 micrometer. Spore swelling is found to occur without change in the form of the spore (circularity index constant at about 1.06) and the spore volume probably increases exponentially. The germ tube appears after about 4 h. The branching frequency and the rate of germ tube extension is determined. After about 10 h growth at a glucose concentration of 250 mg L-1, 6-7 branches have been set, and both the total hyphal length lt and the number of tips increase exponentially with time. The specific growth rate of the hyphae is 0. 33 h-1 while the average rate of the extension of the growing tips approaches 55 micrometer h-1. The growth kinetics for all the branches on the main hypha have also been found. The main hypha and all the branches grow at a rate which can be modeled by saturation kinetics with respect to the branch length and with nearly equal final tip speeds (160 micrometer h-1). Branches set near the apical tip of the main hypha attain their final tip speed in the shortest time, i.e., the value of the saturation parameter is small. Finally, the influence of substrate (glucose) concentration cs on the values of the morphological parameters has been determined. It is found that saturation type kinetics can be used to describe the influence of cs on the growth. Experiments with recirculation of effluent from the cell back to the inlet strongly suggest that the fungus secretes an inducer for growth and branching.     

A Model for Growth of a Single Fungal Hypha Based on Well-Mixed Tanks in Series: Simulation of Nutrient and Vesicle Transport in Aerial Reproductive Hyphae

Current models that describe the extension of fungal hyphae and development of a mycelium either do not describe the role of vesicles in hyphal extension or do not correctly describe the experimentally observed profile for distribution of vesicles along the hypha. The present work uses the n-tanks-in-series approach to develop a model for hyphal extension that describes the intracellular transport of nutrient to a sub-apical zone where vesicles are formed and then transported to the tip, where tip extension occurs. The model was calibrated using experimental data from the literature for the extension of reproductive aerial hyphae of three different fungi, and was able to describe different profiles involving acceleration and deceleration of the extension rate. A sensitivity analysis showed that the supply of nutrient to the sub-apical vesicle-producing zone is a key factor influencing the rate of extension of the hypha. Although this model was used to describe the extension of a single reproductive aerial hypha, the use of the n-tanks-in-series approach to representing the hypha means that the model has the flexibility to be extended to describe the growth of other types of hyphae and the branching of hyphae to form a complete mycelium.     

A model for hyphal growth and branching.

A mathematical model for hyphal growth and branching is described which relates cytological events within hyphae to mycelial growth kinetics. Essentially the model quantifies qualitative theories of hyphal growth in which it is proposed that vesicles containing wall precursors and/or enzymes required for wall synthesis are generated at a constant rate throughout a mycelium and travel to the tips of hyphae where they fuse with the plasma membrane, liberating their contents into the wall and increasing the surface area of the hypha to give elongation. The hypothesis that there is a duplication cycle in hyphae which is equivalent to the cell cycle observed in unicellular micro-organisms is also included in the model. Predictions from the model are compared with experimentally observed growth kinetics of mycelia of Geotrichum candidum and Aspergillus nidulans. The finite difference model which was constructed is capable of predicting changes in hyphal length and in the number and positions of branches and septa on the basis of changes in vesicle and nuclear concentration. Predictions were obtained using the model which were in good agreement with experimentally observed data.     

Morphology of Trichoderma reesei QM 9414 in submerged cultures

The microscopic morphology of Trichoderma reesei QM 9414, growing in submerged culture, was studied by image analysis. The morphology was characterized by the total hyphal length, the total number of tips, the number of actively growing tips, and the length of the main hypha. To describe the growth of a single mycelium a simple model is set-up. The main features of the model are: (1) saturation type kinetics for the tip extension of the individual branches within the mycelium; and (2) random branching with a frequency function, which is proportional to the total hyphal length. The model is used to simulate a population of mycelia, where spore germination is described with a log-normal distribution. From the simulation of the population, the average properties of the mycelia, e.g., the average total hyphal length, are calculated, and by fitting the model to experimental data the model parameters are estimated. Finally, the distribution function with respect to the mycelia properties, that is, number of tips and total hyphal length, is calculated, and it corresponds well with the experimental determination of the distribution function. (c) 1995 John Wiley & Sons Inc.     

Transmission of the eect of an antifungal agent within a single hypha

A micro-compartment culture method was devised in which a single hypha of Rhizopus stolonifer growing on an agar section traversed an antifungal non-diffusible barrier to another agar section; thus the local environment of the distal or proximal part of the hypha could be controlled independently. The responses in terms of hyphal extension of the test fungus to local application of amphotericin B in this culture system were estimated by using an automatic analysing system. After hyphae had traversed the barrier, distal application of amphotericin B caused no appreciable effect on the proximal hyphae. In contrast, proximal application of amphotericin B caused inhibition of the extension of distal hyphae. The reversal of polarized cytoplasmic streaming also occured during the inhibition of distal hyphal extension. The extents of inhibition of the distal hyphal extension and the cytoplasmic streaming were dependent upon the hyphal distance between the amphotericin B application site and the hyphal tip. These results show that the effect of an antifungal agent on a hypha depends on the region of the hypha exposed. Cytoplasmic streaming may play key role in the transmission of antifungal effects within a single hypha.     

Model for Branch Initiation in Aspergillus nidulans Based on Measurements of Growth Parameters

The rate of hyphal elongation and the number of branches per hypha were measured on short sporelings of Aspergillus nidulans growing at different rates. The rate of elongation was proportional to total length in unbranched and branched hyphae. At each growth rate, the number of branches per hypha increased with increasing length and gave approximately straight-line graphs when plotted against length. The average number of branches per unit of hyphal length was quite different for the various growth rates and increased in direct proportion to the growth rate. The results are interpreted to mean that (i) growing tips have a maximum rate at which they can elongate and which is reached at hyphal lengths characteristic of the particular growth rate and (ii) a new branch is formed when the capacity of the hypha to elongate exceeds that of the existing tips.     

Hyphal tip growth in Achlya bisexualis. II. Distribution of cellulose in elongating and non-elongating regions of the wall

Cellulose has been localized in the hyphal wall of elongating and non-elongating hyphae of Achlya bisexualis using a direct enzyme-colloidal-gold method. A number of controls, including several different types of fixation, support the idea that this labeling is specific for cellulose. Both TEM and SEM were used and they gave similar results. The apical area of an elongating hypha lacks cellulose, but the same area of a non-elongating hypha contains cellulose. We have used specific culture media and light microscopic measurements to ensure that we could distinguish between elongating and non-elongating hyphae. The lack of cellulose at the apex of elongating hyphae seems to require a reevaluation of the current concepts of hyphal tip growth in Achlya and related genera. A major question now is to determine whether or not the lack of a microfibrillar component is a universal pattern among all organisms having tip growth.     

NUCLEAR BEHAVIOR,SEPTATION, AND HYPHAL GROWTH OF ALTERNARIA SOLANI

Nuclei of multinucleate hyphal tip cells divided almost synchronously. Nuclear division was followed by multiple septation during which the elongated hyphal tip cell was divided into several, generally multinucleate, cells. Within the same hypha a distinct growth pattern was not observed with respect to number, length, and nuclear number of cells formed with each successive nuclear division-septation cycle. Hyphal branches originated and received nuclei from hyphal tip cells.     

Effect of restrictive conditions on the growth and morphology of a temperature-sensitive mannose-requiring mutant of Aspergillus nidulans

When incubated at 45 degrees C in the absence of added mannose, pregrown hyphae of a temperature-sensitive, mannose-relief mutant (mnrA455) of Aspergillus nidulans grew normally for a short time (4-5 h) before exhibiting an abnormal morphology consisting of the production by hyphae of discrete spherical swellings called balloons. These swellings could be up to 10 microns in diameter and were produced either at or behind the hyphal apex. Often only one swelling was produced in association with each hyphal tip, but in a significant minority of cases (approximately 19.6%) a second balloon was produced in close association with the first. Hyphal tip extension slowed before and during balloon formation, but growth at individual tips did not usually stop when a balloon began to be formed in the same hypha. All tip extension ceased after approximately 8 h in cultures maintained at 45 degrees C. However, normal growth resumed 45-60 min after transfer of such a culture to the permissive temperature of 37 degrees C even after 48 h at 45 degrees C. Electron microscopic examination indicated that balloons consistently had thicker walls than the surrounding hyphae but that no accumulation of cytoplasmic vesicles was apparent within them. This indicates that a modification of wall structure, probably including deposition of new wall material, was caused by a mannose deficiency, but that this altered wall synthesis and attendant hyphal swelling was not due to diversion of the normal vesicle-mediated tip-extension system to the side walls of hyphae.     

The relation between turgor and tip growth inSaprolegnia ferax: Turgor is necessary,but not sufficient to explain apical extension rates

Linear growth rate ofSaprolegnia was reduced in direct proportion to increased osmotic pressure (II) of the medium, when sorbitol or PEG-400 was used as osmotica. However, increasing medium II reduced hyphal turgor only to a minimum positive level, which was maintained while extension rates continued to decline. TPA, a K⁺-channel agonist effective onSaprolegnia protoplasts, also caused dose-dependent linear growth rate reductions but did not substantially affect turgor. When turgor was compared with linear growth rate in the osmoticum experiments, there was a positive correlation only for hyphae growing faster than 12 μm/min; below this, there was a twofold range in extension rate despite essentially constant turgor. As well, TPA-treatments produced a twofold reduction in hyphal extension rate without substantially affecting turgor. Turgor should be consistent within a coenocyte, and is steady under constant growth conditions. However, under such conditions, we found average variations of fivefold in extension rate between hyphae, and twofold for hyphae over time. These results suggest that turgor is not the prime determinant of tip extension rate, and they are consistent with cytoskeletal regulation of that rate. Linear growth rates ofSaprolegnia colonies were similar on basal medium containing 1% (w/v) glucose, sorbitol, or PEG and only slightly faster than without added carbohydrate. Increasing medium II with glucose also reduced hyphal extension rate.     

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.     

Morphology and physiology of an alpha-amylase producing strain of Aspergillus oryzae during batch cultivations

The microscopic morphology, that is, total hyphal length and total number of tips, has been characterized during batch cultivations of Aspergillus oryzae. The specific growth rate estimated by measuring the total hyphal length (mu(h)) corresponds well with the specific growth rate estimated from dry weight measurements during cultures grown as free hyphal elements. The average tip extension rate can be described with a saturation type kinetics with respect to the average total hyphal length, and the branching frequency is closely related to the total hyphal length. For the applied strain of A. oryzae, pellet formation occurs by coagulation of spores. The agglomeration process is pH dependent and pellets are formed at pH values higher than 5, whereas low pH (<3.5) results in growth as freely dispersed hyphal elements. The maximum specific growth rate has a broad pH optimum between 3 and 7, whereas the alpha-amylase production has a sharper maximum at about pH 6. During batch cultivation with pellets the growth is described well by the cube-root law when pellet fragmentation can be neglected. The kinetic parameter k in the cube-root law is derived from the growth kinetics with no mass transfer limitation, k = mu(h)/3. Based on an oxygen balance, the active growth layer in the pellet is estimated to be 200 to 325 mum and, consequently, up to 50% of the biomass is limited by oxygen for large pellets. Ethanol production (up to 1 g L(-1)) was observed during batch cultivations with pellets, suggesting that ethanol is produced in the oxygen limited part of the biomass. A constitutive, low alpha-amylase production was observed at high glucose concentration. The specific alpha-amylase production was significantly higher for filamentous growth than for pellets and oxygen appears to be necessary for production of alpha-amylase. (c) 1996 John Wiley & Sons, Inc.     

Growth of Hyphal Branching Systems in Coprinus disseminatus

Apical portions of hyphal branching systems of Coprinus disseminatuswere observed at the margins of colonies extending at a constantrate under one set of environmental conditions. Growth was consistentlymonopodial, the main hyphae continuing to extend in the colonymargin at a constant rate. Primary branch initiation occurredat regular intervals, closely associated with cell divisionof the parent hypha, and initiation of secondary branches tookplace in the older parts of the system. Extension rates of main,primary branch, and secondary branch hyphae were distinct, beingin the proportions 100: 66: 18. In the majority of systems successivebranches of the same category closely resembled one anotherand changes in extension rate of primary branches were smallfrom soon after initiation up to a length of 750µ. Ina minority of systems branch behaviour was less regular, somebranches increasing in extension rate whilst others decreased.Changes in older parts of the systems were not followed. young primary branch hyphae were consistently narrower thanmain hyphae. Although extension rate was correlated with hyphaldiameter for main and for branch hyphae separately, the extensionrate of equally wide hyphae was significantly higher for mainas compared with branch hyphae. Furthermore the wider, faster-extendingbranch hyphse temded tp arise from the wider, faster-extendingmain hyphae. The significance of these findings is discussed.     

Immunofluorescence microscopy of the microtubule cytoskeleton during conjugate division in the dikaryon Pleurotus ostreatus N001

Fluorescence microscopy was used to describe the distribution of nuclei and the organization of the microtubule network in hyphae of Pleurotus ostreatus. Dikaryotic hyphae of P. ostreatus N001 grow by tip extension with two closely spaced nuclei moving slowly forward with the growing hyphal tip. During vegetative growth of the hyphae, cytoplasmic microtubules are found as long filaments oriented longitudinally within fungal hyphae. When the apical cell reaches a length of approximately 150 μm, the two nuclei divide synchronously. Mitosis occurs in association with clamp connection formation, with one of the nuclei dividing in the hook of the developing clamp connection and the other in the main hypha. After mitosis, two daughter nuclei move forward to approximately the center of the apical cell, while the other two move backward to a central position in the subapical cell. Two septa are formed, one in the clamp and the other across the main axis of the hypha to delimit the apical cell. The use of fluorescence microscopy made it possible to examine the changes in the cytoplasmic microtubules, the configuration of the mitotic apparatus, the site of septation and the post-mitotic nuclear migrations during conjugate division in P. ostreatus dikaryotic hyphae.     

Morphology and growth kinetics of hyphae of differentiated and undifferentiated mycelia of Neurospora crassa.

A comparison was made of the morphology and growth kinetics of hyphae of differentiated and undifferentiated mycelia of Neurospora crassa. Undifferentiated mycelia were formed during exponential growth on solid media or submerged culture. Hyphae at the margin of differentiated mycelia (colonies) differed from undifferentiated mycelia in diameter, extension rate, extension zone length, and intercalary and apical compartment length. The mean hyphal extension rate (E) of an undifferentiated mycelium was a function of the length of the mycelium's hyphal growth unit (G) and the organism's specific growth rate (alpha). Thus, E=Galpha.     

Monitoring of morphological development of the arachidonic-acid-producing filamentous microorganism Mortierella alpina

Morphological parameters, such as hyphal growth rate, tip formation rate, tip extension rate and branch formation rate, of Mortierella alpina have been measured using a flow-through chamber under 25 different combinations of carbon and nitrogen concentrations. Morphological parameters were influenced not by C/N ratio but by carbon concentration in the medium. Specific rates of hyphal growth and tip formation both remained constant at a low carbon concentration of 5 g/l. Tip extension rate from one tip was 60 microm tip(-1) h(-1) at a carbon concentration below 15 g/l, and the branching formation rate was independent of carbon concentration. Tip extension rate was a function of specific hyphal growth rate, which in turn was linearly proportional to the specific tip formation rate, demonstrating that tip extension rate was exponentially proportional to the specific tip formation rate. Branch formation rate per hyphal element remained unchanged even at tip extension rates lower than 60 microm tip(-1) h(-1) and at specific hyphal growth rates lower than 0.83 h(-1), but decreased drastically at higher rates of tip extension and hyphal growth.     

Effect of temperature and temperature shifts on growth and branching of a wild type and a temperature sensitive colonial mutant (Cot 1) of Neurospora crassa

Growth of a temperature sensitive colonial mutant (cot 1) of Neurospora crassa was compared with a wild type strain. The hyphal growth unit (the ratio between mycelial length and number of branches) of the wild type was not appreciably altered by temperature and there was a direct relationship between the specific growth rate () of these mycelia and their mean hyphal extension rate (E). The specific growth rate of cot 1 increased by about the same relative amount as the wild type between 15° and 30°C. Cot 1 grew and branched normally at 15° and 25°C but at 30°C the hyphal growth unit and mean hyphal extension rate of the mutant mycelia were reduced. Thus, between 15–30°C the ratio, E/ was constant for the wild type but not for cot 1.The effect of temperature and temperature shifts on extension zone length (Z), extension zone expansion time (Z _i ) and branching of leading hyphae of mature colonies were also studies.It is suggested that branching is governed by a mechanism which regulates the linear growth rate of hyphae; the cot 1 mutation may have a direct effect on wall extension or affect linear growth rate indirectly due to an influence on the transport of precursors to the tip.     

Branching is coordinated with mitosis in growing hyphae of Aspergillus nidulans

Filamentous fungi like Aspergillus nidulans can effectively colonize their surroundings by the formation of new branches along the existing hyphae. While growth conditions, chemical perturbations, and mutations affecting branch formation have received great attention during the last decades, the mechanisms that regulates branching is still poorly understood. In this study, a possible relation between cell cycle progression and branching was studied by testing the effect of a nuclei distribution mutation, cell cycle inhibitors, and conditional cell cycle mutations in combination with tip-growth inhibitors and varying substrate concentrations on branch initiation. Formation of branches was blocked after inhibition of nuclear division, which was not caused by a reduced growth rate. In hyphae of a nuclei distribution mutant branching was severely reduced in anucleated hyphae whereas the number of branches per hyphal length was linearly correlated to the concentration of nuclei, in the nucleated hyphae. In wild type cells, branching intensity was increased when the tip extension was reduced, and reduced when growing on poor substrates. In these situations, the hyphal concentration of nuclei was maintained and it is suggested that branching is correlated to cell cycle progression in order to maintain a minimum required cytoplasmic volume per nucleus and to avoid the formation of anucleated hyphae in the absence of nuclear divisions. The presented results further suggest the hyphal diameter as a key point through which the hyphal element regulates its branching intensity in response to the surrounding substrate concentrations.