Mycophenolic Acid Production by Penicillium brevicompactum on Solid Media

When grown on Czapek-Dox agar, Penicillium brevicompactum produced mycophenolic acid after a vegetative mycelium had been formed and as aerial hyphae were developing. Nutrients were still plenteous in the agar when the synthesis began. If aerial hyphal development was prevented by placing a dialysis membrane over the growing fungus, no mycophenolic acid was produced. When the dialysis membrane was peeled back and, as a consequence, production of aerial hyphae began, mycophenolic acid biosynthesis was observed. We concluded that mycophenolic acid was produced only by P. brevicompactum colonies that possessed an aerial mycelium.     

Live-cell imaging of vegetative hyphal fusion in Neurospora crassa

The process of hyphal fusion (anastomosis) in growing colonies of Neurospora crassa, stained with the membrane-selective dyes FM1-43 and FM4-64, was visualized by confocal microscopy. Time-lapse, live-cell imaging illustrated the dynamics of hyphal growth and anastomosis during its pre-contact, contact and post-contact, and post-fusion stages. Fusion-competent hyphae were morphologically distinct and exhibited remote sensing, resulting in branch initiation and/or re-direction of growth to facilitate contact between participating hyphae. A stained Spitzenk?rper was often observed where fusion-competent hyphae met. It is suggested that this structure contains secretory vesicles responsible for the delivery of cell adhesion molecules at the point of contact, cell wall synthesizing enzymes for the swelling growth of fused hyphal tips, and digestive enzymes required for fusion pore formation. Dramatic changes in cytoplasmic flow frequently occurred between the participating hyphae following fusion. After anastomosis has taken place, septa commonly formed close to the fusion site. The live-cell imaging reported here has clearly shown the complexity of the hyphal homing and fusion process. The control and consequences of repeated anastomoses within a mycelium must be as complex as the process itself.     

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.     

Demonstration of dihydro-orotate dehydrogenase in Neurospora crassa hyphae with a cytochemical procedure

Synopsis Dihydro-orotate dehydrogenase activity was demonstrated in the hyphae of the fungusNeurospora crassa by a cytochemical technique. The activity was slightly stronger in the hyphal tips thus demonstrating the more intense metabolic activity in these parts of the mycelium. Several control reactions showed that the staining reaction was specific.     

The Development and Behaviour of Mycelial Strands in Merulius lacrymans (Wulf.) Fr.: II. Hyphal Behaviour during Strand Formation

The system of hyphal branching by Merulius lacrymans was observedin mycelium which had grown from a wood food-base on to glassslides during incubation in sterile moist chambers. A hierarchyof branches and sub-branches arose from the region of clampconnexions, or nodes, of relatively wide main hyphae. Therewas evidence that the sequence of branches occurring at nodesin basipetal succession represented the time sequence of branchdevelopment at any one node. Later-formed branches at any nodewere smaller than earlier branches, but such earlier branchesusually became smaller towards the tip as growth continued.Mycelial strands were built up by growth and branching of thigmo-tropicallysensitive ‘tendril’ hyphae in association with thewide main hyphae. Tendril hyphae were characteristically narrow,thin-walled hyphae arising both as later-formed branches fromthe nodes of the main hyphae and as the narrowed tips of earlierbranches. Although this branching behaviour could be seen amongstaerial hyphae growing over agar media, hyphae growing in contactwith or within the agar behaved differently and did not formstrands.     

Heterotrimeric G protein β subunit GPB1 and MAP kinase MPK1 regulate hyphal growth and female fertility in Fusarium sacchari

Heterotrimeric GTP-binding proteins (G proteins) and mitogen-activated protein kinase (MAPK) cascades involve vegetative hyphal growth, development of infection-related structure, colonization in host plant and female fertility in phytopathogenic ascomycete fungi. In this study, a heterotrimeric G protein β subunit (Gβ), GPB1, and MAPK, MPK1, were characterized from Fusarium sacchari (= Gibberella sacchari; mating population B of the G. fujikuroi-species complex). GPB1 and MPK1 showed high homology to known Gβ and Fus3/Kss1 MAP kinases of other filamentous ascomycetes, respectively. Disruption (Δ) of gpb1 suppressed hyphal branching and accelerated aerial hyphae formation in F. sacchari. Oppositely, disruption of mpk1 caused delayed aerial hyphae formation. These indicated that GPB1 regulates vegetative hyphal growth negatively, and MPK1 does positively in F. sacchari. Both Δgpb1 and Δmpk1 showed female sterility. Level of intracellular cAMP in Δgpb1 was lower than wild type. Exogenous cyclic AMP (cAMP) partially restored enhanced aerial hyphae formation. These suggested that abnormal hyphal growth was caused by depletion of intracellular cAMP in Δgpb1. cAMP has been reported to suppress development of perithecia in crossing between wild type strains. Thus, precise regulation of intracellular cAMP level via Gβ/MAPK is essential for normal hyphal growth and fertility.     

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.     

Cardiolipin synthase is required for Streptomyces coelicolor morphogenesis

The fluid mosaic model has recently been amended to account for the existence of membrane domains enriched in certain phospholipids. In rod-shaped bacteria, the anionic phospholipid cardiolipin is enriched at the cell poles but its role in the morphogenesis of the filamentous bacterium Streptomyces coelicolor is unknown. It was impossible to delete clsA (cardiolipin synthase; SCO1389) unless complemented by a second copy of clsA elsewhere in the chromosome. When placed under the control of an inducible promoter, clsA expression, phospholipid profile and morphogenesis became inducer dependent. TLC analysis of phospholipid showed altered profiles upon depletion of clsA expression. Analysis of cardiolipin by mass spectrometry showed two distinct cardiolipin envelopes that reflected differences in acyl chain length; the level of the larger cardiolipin envelope was reduced in concert with clsA expression. ClsA-EGFP did not localize to specific locations, but cardiolipin itself showed enrichment at hyphal tips, branch points and anucleate regions. Quantitative analysis of hyphal dimensions showed that the mycelial architecture and the erection of aerial hyphae were affected by the expression of clsA. Overexpression of clsA resulted in weakened hyphal tips, misshaped aerial hyphae and anucleate spores and demonstrates that cardiolipin synthesis is a requirement for morphogenesis in Streptomyces.     

The Paxillin-like protein AgPxl1 is required for apical branching and maximal hyphal growth in A.gossypii

The development from young, slowly growing hyphae to fast growing hyphae in filamentous fungi is referred to as hyphal maturation. We have identified the Paxillin-like protein AgPxl1 in Ashbyagossypii as a developmental protein that is specifically required for hyphal maturation. The early development of A.gossypii strains lacking AgPxl1 is indistinguishable from wild-type. However, at later developmental stages the maximal hyphal extension rate is less than half compared to wild-type and apical branching is affected. Apical branching is characterised as the symmetric division of fast growing hyphal tips resulting in two sister hyphae. In Agpxl1Delta strains two thirds of the apical branching events lead to asymmetric sister hyphae where growth of one branch is either completely aborted or slowed down while extension of the other branch is not affected. This suggests that AgPxl1 plays a role in the organisation of growth and efficient division of growth upon apical branching in mature mycelia. The conserved C-terminal LIM domains are necessary for AgPxl1 function and also contribute to tip localisation. AgCLA4, a PAK-like kinase, is epistatic to AgPXL1 and robust localisation of AgPxl1 depends on AgCla4. This suggests that AgCla4 acts upstream of AgPxl1.     

Time-Lapse Microscopy of Streptomyces coelicolor Growth and Sporulation

Bacteria from the genus Streptomyces are among the most complex of all prokaryotes; not only do they grow as a complex mycelium, they also differentiate to form aerial hyphae before developing further to form spore chains. This developmental heterogeneity of streptomycete microcolonies makes studying the dynamic processes that contribute to growth and development a challenging procedure. As a result, in order to study the mechanisms that underpin streptomycete growth, we have developed a system for studying hyphal extension, protein trafficking, and sporulation by time-lapse microscopy. Through the use of time-lapse microscopy we have demonstrated that Streptomyces coelicolor germ tubes undergo a temporary arrest in their growth when in close proximity to sibling extension sites. Following germination, in this system, hyphae extended at a rate of ~20 μm h⁻¹, which was not significantly different from the rate at which the apical ring of the cytokinetic protein FtsZ progressed along extending hyphae through a spiraling movement. Although we were able to generate movies for streptomycete sporulation, we were unable to do so for either the erection of aerial hyphae or the early stages of sporulation. Despite this, it was possible to demonstrate an arrest of aerial hyphal development that we suggest is through the depolymerization of FtsZ-enhanced green fluorescent protein (GFP). Consequently, the imaging system reported here provides a system that allows the dynamic movement of GFP-tagged proteins involved in growth and development of S. coelicolor to be tracked and their role in cytokinesis to be characterized during the streptomycete life cycle.     

Tip growth of <Emphasis Type="Italic">Neurospora crassa</Emphasis> upon resource shortage: Disturbances of the coordination of elongation,branching, and septation

The characteristics of elongation, branching, septation, and nuclear morphology in hyphal tips (of ~400 μm in length) of the mycelial fungus Neurospora crassa isolated from the mycelium and cultivated for several hours have been investigated using intracellular fluorescent markers. The newly formed branches had the following characteristic features: (1) the predefined orientation was conserved, whereas the diameter decreased (from 10–20 to 6.5 ± 0.4 μm), as did the elongation rate (from 24 ± 1 to 6.7 ± 0.5 μm/min); (2) a disturbed branching pattern with abnormally large internodal distances (up to 1471 μm) and developmental arrest of part of the buds of lateral branches; and (3) a conserved septation pattern and a relatively constant length of hyphal segments (68 ± 2 μm). The size of the nucleus-free zone at the tip (5–33 μm) and the distance between the first septum and the growth point (210 ± 15 μm) in the daughter branches of the isolated fragments were almost the same as in hyphae connected to the mycelium, whereas the average distance between the growth point and the first lateral branch (492 ± 127 μm) and the variability of this parameter were higher in the isolated fragments. The morphology of the nuclei and the size of the nucleus-free zone near the growth point did not differ from those reported for normal vegetative hyphae of N. crassa. The experimental model developed may be used for the elucidation of details of molecular genetic mechanisms that underlie the regulation of interactions between the intracellular structures that provide tip growth of the hyphae in N. crassa.     

Cellular Events Involved in Survival of Individual Arbuscular Mycorrhizal Symbionts Growing in the Absence of the Host

A survival strategy operating in the absence of the host was shown in obligately biotrophic arbuscular mycorrhizal (AM) symbionts. When no host-derived signals from the surrounding environment were perceived by germinating spores, fungal hyphae underwent a programmed growth arrest and resource reallocation, allowing long-term maintenance of viability and host infection capability. The early stages of mycelial growth of AM fungi were studied by a combination of time-lapse and video-enhanced light microscopy, image analysis, and immunodetection, with the aim of acquiring knowledge of cell events leading to the arrest of mycelial growth. The time-course of growth arrest was resolved by precisely timing the growth rate and magnitude of the mycelium originating from individual spores of Glomus caledonium. Extensive mycelial growth was observed during the first 15 days; thereafter, fungal hyphae showed retraction of protoplasm from the tips, with formation of retraction septa separating viable from empty hyphal segments. This active process involved migration of nuclei and cellular organelles and appeared to be functional in the ability of the fungus to survive in the absence of a host. Immunodetection of cytoskeletal proteins, metabolic activity, and the retention of infectivity of germinated spores confirmed the developmental data. The highest amounts of tubulins were detected when hyphal growth had ceased but when retraction of protoplasm was most active. This was consistent with the role of the cytoskeleton during protoplasm retraction. Succinate dehydrogenase activity in hyphae proximal to the mother spore was still detectable in 6-month-old mycelium, which remained viable and able to form appressoria and produce symbiotic structures.     

Structural and functional organization of growing tips of Neurospora crassa hyphae

Data are presented on a variety of intracellular structures of the vegetative hyphae of the filamentous fungus Neurospora crassa and the involvement of these structures in the tip growth of the hyphae. Current ideas on the molecular and genetic mechanisms of tip growth and regulation of this process are considered. On the basis of comparison of data on behaviors of mitochondria and microtubules and data on the electrical heterogeneity of the hyphal apex, a hypothesis is proposed about a possible supervisory role of the longitudinal electric field in the structural and functional organization of growing tips of the N. crassa hyphae.     

GROWTH AND DIFFERENTIATION OF NEUROSPORA HYPHAE

Zalokar , Marko . (Yale U., New Haven, Conn.) Growth and differentiation of Neurospora hyphae. Amer. Jour. Bot. 46(8): 602–610. Illus. 1959.—Neurospora hyphae grow only at their tips. New protoplasm is formed throughout the hyphae and transported to the tips by active cytoplasmic streaming. This enables the fungus to grow at a prodigious rate. The use of radioactive precursors demonstrated that the rate of protein and ribonucleic acid formation does not decrease substantially in hyphal regions distant from the growing point. Apical growth of hyphae results in a morphological differentiation into young regions filled with cytoplasm and dense with nuclei and old regions, vacuolated and laden with fat droplets. Cytochemical methods were used to study the biochemical differentiation of hyphae and attention was focused on the growing region. It was found that hyphal tips, i.e., the first 50–100 μ of the growing end of the hypha, differed substantially from the rest of the young hyphae. Hyphal tips were slightly richer in proteins and significantly richer in protein-bound sulfhydryl groups and ribonucleic acid. Glycogen was absent at the tips. Peroxidase increased at the tips, while cytochrome oxidase and succinic dehydrogenase decreased. Alkaline phosphatase exhibited strong activity in a short region behind the extreme tip. β-galactosidase, in a few cases, was more active at the tips than in the rest of the hyphae. The results of cytological and cytochemical investigations are discussed in connection with the problem of cellular differentiation.     

Localization of α-Mannan in the Hyphal Wall of Phytophthora megasperma f. sp. glycinea and it's Possible Relevance to the Host-Pathogen Interaction of the Fungus With Soybeans (Glycine max)

At the apices of growing hyphae of Phytophthora megasperma f. sp. glycinea (Pmg) distinctly more fluorescein-isothiocyanate labelled Concanavalin A was bound than else-where in the mycelium. In combination with some other analytical evidence this observation conclusively indicates that the α-mannan in the cell wall of the fungus is predominantly concentrated or exposed at the hyphal tips. The possible relevance of this fact to the host-pathogene interaction between Pmg and soybean is discussed.     

Dynamic interplay of ParA with the polarity protein,Scy, coordinates the growth with chromosome segregation in Streptomyces coelicolor

Prior to bacterial cell division, the ATP-dependent polymerization of the cytoskeletal protein, ParA, positions the newly replicated origin-proximal region of the chromosome by interacting with ParB complexes assembled on parS sites located close to the origin. During the formation of unigenomic spores from multi-genomic aerial hyphae compartments of Streptomyces coelicolor, ParA is developmentally triggered to form filaments along the hyphae; this promotes the accurate and synchronized segregation of tens of chromosomes into prespore compartments. Here, we show that in addition to being a segregation protein, ParA also interacts with the polarity protein, Scy, which is a component of the tip-organizing centre that controls tip growth. Scy recruits ParA to the hyphal tips and regulates ParA polymerization. These results are supported by the phenotype of a strain with a mutant form of ParA that uncouples ParA polymerization from Scy. We suggest that the ParA–Scy interaction coordinates the transition from hyphal elongation to sporulation.     

Enviromentally Induced Changes in Clamp Connection Incidence in Hyphal Branching Systems of Coprinus disseminatus

The incidence of clamp connections among surface hyphae at thecolony margin of apparent dikaryons from four stocks of Coprinusdisseminatus has been investigated under several environmentalconditions. On 2 per cent malt agar, clamp connections are formed at allnodes of the main leader hyphae, but they are absent from theearlier-formed nodes of primary branch hyphae. Most primarybranches have begun to form clamp connections by their fifthcell division, and continue to do so subsequently. Onset ofclamp connection formation in primary branches is delayed whenthe concentration of malt in the medium is reduced. The occurrenceof clamp connections on main leader hyphae is reduced or preventedwhen nutrient supply in the medium is reduced, or when the mediumis ‘pre-staled’ by previous growth of C. disseminatus.Clamp-free main hyphal tips revert to formation of clamp connectionswhen the intact hyphal system is transferred to more favourableenvironmental conditions. Presence of clamp connections on bothmain and branch hyphae is associated with high hyphal diameter,and in some instances, also with high hyphal extension rate. The significance of these observations to mechanisms of growthof hyphal branching systems and their relevance to other speciesthat form clamp connections intermittently, are discussed.     

Hyphal death during colony development in Streptomyces antibioticus: morphological evidence for the existence of a process of cell deletion in a multicellular prokaryote

During the life cycle of the streptomycetes, large numbers of hyphae die; the surviving ones undergo cellular differentiation and appear as chains of spores in the mature colony. Here we report that the hyphae of Streptomyces antibioticus die through an orderly process of internal cell dismantling that permits the doomed hyphae to be eliminated with minimum disruption of the colony architecture. Morphological and biochemical approaches revealed progressive disorganization of the nucleoid substructure, followed by degradation of DNA and cytoplasmic constituents with transient maintenance of plasma membrane integrity. Then the hyphae collapsed and appeared empty of cellular contents but retained an apparently intact cell wall. In addition, hyphal death occurred at specific regions and times during colony development. Analysis of DNA degradation carried out by gel electrophoresis and studies on the presence of dying hyphae within the mycelium carried out by electron microscopy revealed two rounds of hyphal death: in the substrate mycelium during emergence of the aerial hyphae, and in the aerial mycelium during formation of the spores. This suggests that hyphal death in S. antibioticus is somehow included in the developmental program of the organism.     

Asexual development is increased in Neurospora crassa cat-3-null mutant strains

We use asexual development of Neurospora crassa as a model system with which to determine the causes of cell differentiation. Air exposure of a mycelial mat induces hyphal adhesion, and adherent hyphae grow aerial hyphae that, in turn, form conidia. Previous work indicated the development of a hyperoxidant state at the start of these morphogenetic transitions and a large increase in catalase activity during conidiation. Catalase 3 (CAT-3) increases at the end of exponential growth and is induced by different stress conditions. Here we analyzed the effects of cat-3-null strains on growth and asexual development. The lack of CAT-3 was not compensated by other catalases, even under oxidative stress conditions, and cat-3^RIP colonies were sensitive to H₂O₂, indicating that wild-type (Wt) resistance to external H₂O₂ was due to CAT-3. cat-3^RIP colonies grown in the dark produced high levels of carotenes as a consequence of oxidative stress. Light exacerbated oxidative stress and further increased carotene synthesis. In the cat-3^RIP mutant strain, increased aeration in liquid cultures led to increased hyphal adhesion and protein oxidation. Compared to the Wt, the cat-3^RIP mutant strain produced six times more aerial hyphae and conidia in air-exposed mycelial mats, as a result of longer and more densely packed aerial hyphae. Protein oxidation in colonies was threefold higher and showed more aerial hyphae and conidia in mutant strains than did the Wt. Results indicate that oxidative stress due to lack of CAT-3 induces carotene synthesis, hyphal adhesion, and more aerial hyphae and conidia.