Physiology and fine structure of sporangiospore germination in Piptocephalis unispora prior to infection

Germination of the sporangiospore of Piptocephalis unispora Benjamin, observed by means of light and electron microscopy, involved the formation of a new inner wall which became continous with the inner layer of the wall of the germ tube. The outer wall layer of the germ tube was continous with the original inner wall layer of the dormant spore. Preliminary details of appressorium structure were noted. Nutritional experiments indicated that sporangiospores required external sources of utilisable nitrogen and carbon compounds for maximal swelling and germ tube production. Limited development occurred when either nutrient was supplied singly. Comparison of germination of the asexual spore with that in other Mucorales, especially the Kickxellaceae, has been made, and the merosporangial status in P. unispora discussed.Non-Standard Abbreviations CH casein hydrolysate - Q spore quotient     

Fine structure of germinatingPenicillium megasporum conidia

Summary Penicillium megasporum conidia have spore walls consisting of several layers. There is no visible change in the outer wall layers during spore germination, but the inner layers increases in thickness on only one side of the spore, resulting in a rupture of the outer wall layers and subsequently in germ tube formation. Invaginations in the plasma membrane disappear as the germ tube forms and emerges, and the nucleus migrates into the developing germ tube. Mitochondria gather at the base of the germ tube during its formation. During germination, the amount of lipid in the spore decreases and portions migrate into the germ tube. Membrane-bound, electron dense bodies are present in resting spores. These bodies decrease in size as germination proceeds, and the cytoplasm in the developing germ tube appears much more electron dense than the cytoplasm within the spore.     

中国水蕨属孢子形态及其系统学意义的研究

利用扫描电镜和透射电镜技术对我国产水蕨属2种的孢子形态进行了观察,对2种的形态结构进行了描述。本属孢子是同型孢子蕨类植物中最大的孢子,三裂缝,肋状纹饰,由外壁形成纹饰的轮廓;具较薄的周壁,在高倍放大的情况下呈颗粒或杆状,我们从孢子形态角度,支持水蕨作为一个独立的科,它与海金沙科的非洲蕨属（Mohria)的亲缘关系较近,是介于海金沙科和裸子蕨科之间蕨群。     

Electron microscopy of spore germination and cell wall formation in Mucor rouxii

Summary The fine structure of ungerminated and aerobically germinated sporangiospores of Mucor rouxii was compared. The germination process may be divided into two stages: I, spherical growth; II, emergence of a germ tube. In both stages, germination is growth in its strictest sense with overall increases in cell organelles; e.g., the increase in mitochondria is commensurate with the overall increase in protoplasmic mass. Noticeable changes occurring during germination are the disappearance of electron-dense lipoid bodies, formation of a large central vacuole and, most strikingly, formation of a new cell wall. Unlike many other fungi, M. rouxii does not germinate by converting the spore wall into a vegetative wall. Instead, as in other Mucorales, a vegetative wall is formed de novo under the spore wall during germination stage I. This new wall grows out, rupturing the spore wall, to become the germ tube wall. Associated with the apical wall of the germ tube is an apical corpuscle previously described. The vegetative wall exhibits a nonlayered, uniformly microfibrillar appearance in marked distinction to the spore wall which is triple-layered, with two thin electron dense outer layers, and a thick transparent inner stratum. The lack of continuity between the spore and vegetative walls is correlated with marked differences in wall chemistry previously reported. A separate new wall is also formed under the spore wall during anaerobic germination leading to yeast cell formation. On the other hand, in the development of one vegetative cell from another, such as in the formation of hyphae from yeast cells, the cell wall is structurally continuous. This continuity is correlated with a similarity in chemical composition of the cell wall reported earlier.     

Adhesion and development of the root rot fungus (Heterobasidion annosum) on conifer tissues: effects of spore and host surface constituents

The objective of this study was to correlate the occurrence of particular root and woody stump surface components with the ability of spores of the root rot fungus (Heterobasidion annosum) to adhere, germinate and establish on conifer tissues. With the aid of high performance liquid chromatography, several sugars (pinitol, xylitol, dulcitol, mannitol, D-glucose, mannose, fructose) were detected on both stump and fine root surfaces of Scots pine and Norway spruce. Of all the sugars observed, xylose and arabinose were poorly utilized for initiation of germ tube growth whereas spore germination was enhanced in the presence of D-glucose, mannose or fructose. Oxidation of these sugars by pretreatment of wood discs or roots with periodic acid abolished the ability of the spores to germinate. Non-sugar components such as long chain fatty acids on spores and root surfaces as detected with nuclear magnetic resonance were found to have a significant influence on adhesion and initiation of germ tube development. Removal of these aliphatic compounds from the root surface increased spore germination by 2-fold, whereas similar treatment on spores led to a 5-fold decrease in adhesiveness to root material. In vitro studies revealed that the di-ethyl ether extract from the roots had no long term adverse effect on spore germination which suggests that the fungus may possess the capability to detoxify this substance. Similarly, adhesion of spores was affected by low and freezing temperatures. The role of significant levels of mannitol and trehalose accumulated in spores and hyphae of the fungi on viability, survival and tolerance to adverse conditions such as oxidative stress, freezing and desiccation are discussed.     

Ultrastructure and chemical composition of the ballistospore wall ofConidiobolus obscurus

The ballistospores of the entomopathogenConidiobolus obscurus are spheroidal cells with a papilla corresponding to the zone of attachment on the sporophore. They are covered by a mucus responsible for the attachment of the spore to the insect. Chemical and cytochemical investigations of the nature of the wall components have been undertaken to better understand fungus-insect interactions in entomopathology. β(1→3)-Glucans and chitin together represented the main components of the wall which did not contain chitosan and uronic acids. Transmission electron microscopy revealed that the spore wall was composed of a thick electron-lucent inner layer and a thin outer electron-dense layer, the latter being absent at the papilla region. The spore is covered by a mucilaginous layer that upon spore impact on a substratum, is dispersed and forms a halo around the spore. Shadow replicas of the discharged spores showed that they are covered by rodlets except on the papilla which displayed a chitinous, microfibrillar structure. The ontogeny of the rodlets deposited on the surface of young spores was characterized by a progressive organization of separate rodlets and then a clustering of the rodlets in fascicles. Shadow replicas and chemical and enzymatic investigations of the halo surrounding discharged spores showed that the mucus was composed of long β(1→3)-glucan microfibrils embedded in amorphous proteins partly covered by rodlets discharged from the spore surface.     

Iron and temperature as sporangiospore germination factors of Pilobolus longipes

Sporangiospores of Pilobclus longipes germinated on a medium containing ascorbate and FeSO₄, but neither ascorbate nor FeSO₄ alone caused spores to germinate. The iron chelates (hemin, coprogen, and ferrichrome) that are known to promote mycelial growth of this and other species of Pilobolus had little or no effect on spore germination, suggesting that under these conditions dormant spores are unable to reduce iron III.Regardless of the medium used, maximum germination required treatment at two temperatures. The early stage of germination, spherical growth, was favored by treatment for several hours at about 38°C while optimum germ tube formation required incubation at lower temperatures (25°C). Under most conditions the requirement for a heat treatment was nearly absolute.When the iron-ascorbate and the heat treatments were separated it was found that they need not be applied simultaneously provided that iron and ascorbate are given first. Spores that were heated first and then given iron and ascorbate at lower temperatures did not germinate. Apparently dormancy of these spores is broken by available iron but a heat treatment is usually required to complete the germination process.     

Wall fibrils ingerminating sporangiospores of Gilbertella persicaria (Mucorales)

Summary In germinated sporangiospores of Gilbertella persicaria, negatively contrasted fibrils, 20–70 Å diam, are seen in thin sections of the inner vegetative wall that is continuous with the germ tube wall. The fibrils are randomly oriented in a loose network in this wall and in the germ tube wall. Germ tubes have an additional surface layer of fine, positively contrasted fibrils which appear as a nap-like coating on the hyphae. Patterns of wall fibril orientation are not revealed by transverse sections of spore and germ tube walls, whereas oblique and tangential sections are favorable for examining cell wall architecture in situ. Staining patterns show textural and compositional differences among various wall layers.     

Untersuchungen über den chemischen Aufbau von Sporen- und Keimschlauchwänden der Uredosporen des Weizenrostes (Puccinia graminis var. tritici)

Zusammenfassung Zellwände und Keimschläuche von Uredosporen des Weizenrostes (Puccinia graminis var. tritici) wurden isoliert, und ihre chemische Zusammensetzung wurde quantitativ untersucht. Als gemeinsame Bausteine enthalten Sporenwände und Keimschlauchwände Proteine, Lipide und die Neutralzucker Galaktose, Glucose und Mannose. Die einzelnen Komponenten liegen in unterschiedlicher Menge vor. Auch qualitativ unterscheiden sich die Sporenwände und die Keimschlauchwände: Melanin ist nur in den Sporenwänden vorhanden, in den Keimschlauchwänden dagegen nicht. Der polymer gebundene Aminozucker der Keimschlauchwände ist N-Acetylglucosamin, das mit großer Wahrscheinlichkeit als Chitin vorliegt. Die Sporenwände enthalten dagegen polymeres Glucosamin (vermutlich Chitosan).Sporenwände sind in 3% iger NaOH löslich. Aus diesem Extrakt läßt sich mit Fehlingscher Lösung ein Galaktoglucomannan fällen, das überwiegend aus Mannose besteht. Aus der entsprechenden Fraktion der Keimschlauchwände, in der ebenfalls Mannose überwiegt, kann mit Fehlingscher Lösung kein Mannan gewonnen werden. Der in NaOH unlösliche Satz der Keimschlauchwände ist zum größten Teil aus Glucose und N-Acetylglucosamin aufgebaut. Es gibt keine identischen Polysaccharidfraktionen von Sporen- und Keimschlauchwänden. Sie sind heteropolymer und setzen sich jeweils aus Galaktose, Glucose und Mannose zusammen.

---

Investigations on the chemical composition of spore walls and germ tube walls of wheat rust (Puccinia graminis var. tritici) uredospores

Summary Spore walls and germ tube walls from uredospores of wheat stem rust (Puccinia graminis var. tritici) were isolated and their chemical compositions determined quantitatively. The spore and germ tube walls are commonly composed of proteins, lipids, and the neutral sugars mannose, glucose and galactose. Carbon and nitrogen content, total lipids, composition of bound amino acids, total glucosamine and chitin content, and neutral sugars of spore and germ tube walls were compared. While the carbon content of the germ tube walls is only slightly higher than that of the spore walls, the germ tube walls contain twice as much nitrogen and lipids as the spore walls. The higher nitrogen content of the germ tube walls is due to higher amounts of bound amino acids and hexosamine. The polymeric germ tube wall hexosamine is insoluble in 3% NaOH, while the bulk of the polymeric spore wall hexosamine will go into solution when treated with 3% NaOH. The polymeric amino sugar of the germ tube wall is N-acetylglucosamine, which in all probability is present as chitin. In comparison, spore walls contain polymeric glucosamine (probably chitosan).The predominant neutral sugar of the spore walls is polymeric mannose (90%) while the germ tube walls contain polymeric glucose and mannose in nearly equal amounts. Galactose occurs in both wall types as a minor constituent.From spore walls completely dissolved in 3% NaOH we were able to precipitate a galactoglucomannan with fehling's solution. This galactoglucomannan was composed mainly of mannose. The corresponding fraction of the germ tube wall gave no precipitate with Fehling's solution. An alkali insoluble fraction of the germ tube wall consists mainly of glucose and N-acetylglucosamine. There are no identical polysaccharide fractions in spore walls and germ tube walls. They are always heteropolymers. Melanine is found in spore walls but not in germ tube walls.

     

cAMP regulation of "pathogenic" and "saprophytic" fungal spore germination

We report on the elucidation of two separate pathways of spore germination in a plant pathogenic fungus Colletotrichum gloeosporioides f. sp. aeschynomene. Conidia of the fungus can germinate either from one side or from both sides, depending on external conditions. In shake culture that includes an extract made up from fresh peas, the unicellular conidium divides and one of the two cells develops a germ tube. On a solid surface this germ tube differentiates an appressorium. In rich medium without pea extract, germination is highly similar to Aspergillus spore germination: the conidium swells, forms a single germ tube and then divides and forms a second germ tube. Conidia that germinate in a rich medium do not form appressoria even on a solid surface and are non-pathogenic. In rich medium, cAMP stimulates germination in rich liquid cultures and induces appressoria formation on a hard surface. In pea extract cAMP induces swelling and formation of irregular germ tubes and appressoria. Our results suggest that plant surface signals induce pathogenic-specific spore germination in a cAMP-independent manner. cAMP is required for saprophytic germination and for appressorium formation.     

Spore morphology and ultrastructure of Cyathea (Cyatheaceae,Pteridophyta) species from southern South America

Spore sculpture and wall structure of eight Cyathea (Cyatheaceae) species from southern South America were studied using light microscopy (LM), scanning electron microscopy (SEM) and transmission electron microscopy (TEM) techniques. Two layers, i.e. an inner and an outer layer, were observed in the perispore. The inner layer has two strata: the inner stratum is attached to the exospore and composed of rodlets tangentially oriented to the spore surface and randomly intermixed; the outer stratum consists of a three-dimensional network of rodlets with either free or fused distal edges forming spinules. The outer layer is thin, darkly contrasted and covers the rodlets. In most cases, the exospore has two layers and a pitted surface. In Cyathea atrovirens, the exospore surface is smooth, while in C. delgadii and C. myriotricha it is verrucate. The homogeneity of perispore features within the genus Cyathea is evident, while exospore features are heterogeneous. The exospore has different kinds of surface-structures that are of potential interest for assessing evolutionary trends within the group.     

Characteristics of Streptomyces coelicolor A3(2) aerial spore rodlet mosaic

Cytochemical analysis of Streptomyces coelicolor (A3(2) indicated that the aerial growth rodlet mosaic is a polysaccharide. Statistical analysis of frequency distributions of individual rodlet lengths from control and ether-reoriented spore mosaics indicated that the rodlet fibrillar image is the result of individual particulates, rather than evaginations in a continuous sheet of material. A model of the mature sport envelope was developed from freeze-etch-replicated, thin-sectioned, and critical point dried S. coelicolor A3(2) mature spores. The rodlet mosaic was situated between the outer spore wall and an external granuloma matrix. Mixture spore envelope layers from the inner surface to the external surface are plasma membrane, inner spore wall, outer spore wall, rodlet mosaic, an undefined granular matrix, and the sheath. The granular matrix had an uneven thickness and much of the matrix was frequently absent from the interspore spaces of mature spore chains. Streptomyces coelicolor A3(2) mosaic rodlets were isolated by acetic acid refluxing, then ethanol precipitation. Complete acid hydrolysis of rodlets released on sugar which cochromatographed with D-glucosamine-HCl and released acetic acid at 139% of the expected level. Cell associated rodlet mosaics and isolated mosaic rodlets were hydrolyzed with chitinase. Infrared spectra of isolated rodlets were similar to crab chitin spectra.     

COMPARATIVE DEVELOPMENT OF THE RED ALGAL PARASITES BOSTRYCHIOCOLAX AUSTRALIS GEN. ET SP. NOV. AND DAWSONIOCOLAX BOSTRYCHIAE (CHOREOCOLACACEAE,RHODOPHYTA)1

The development of two red algal parasites was examined in laboratory culture. The red algal parasite Bostrychiocolax australis gen. et sp. nov., from Australia, originally misidentified as Dawsoniocolax bostrychiae (Joly et Yamaguishi-Tomita) Joly et Yamaguishi-Tomita, completes its life history in 6 weeks on its host Bostrychia radicans (Montagne) Montagne. Initially the spores divide to form a small lenticular cell, and then a germ tube grows from the opposite pole. Upon contact with the host cuticle, the germ tube penetrates the host cell wall. The tip of the germ tube expands, and the spore cytoplasm moves into this expanded tip. The expanded germ tube tip becomes the first endophytic cell from which a parasite cell is cut off that fuses with a host tier cell. The nuclei of this infected host cell enlarge. As parasite development continues, other host-parasite cell fusions are formed, transferring more parasite nuclei into host cells. The erumpent colorless multicellular parasite develops externally on the host, and reproductive structures are visible within 2 weeks. Tetrasporangia are superficial and cruciately or tetra-hedrally divided. Spermatia are formed in clusters. The carpogonial branches are four-celled, and the carpogonium fuses directly with the auxiliary (support) cell. The mature carposporophyte has a large central fusion cell and sympodially branched gonimoblast filaments. Early stages of development differ markedly in Dawsoniocolax bostrychiae from Brazil. Upon contact with the host, the spore undergoes a nearly equal division, and a germ tube elongates from the more basal of the two spore cells, penetrates the host cell wall, and fuses with a host tier cell. Subsequent development involves enlargement of the original spore body and division to form a multicellular cushion, from which descending rhizoidal filaments form that fuse with underlying host cells. This radically different development is in marked contrast to the final reproductive morphology, which is similar to B. australis and has lead to taxonomic confusion between these two entities. The different spore germination patterns and early germ-ling development of B. australis and D. bostrychiae warrant the formation of a new genus for the Australian parasite.     

Appressorium formation and nuclear division in Colletotrichum truncatum

Conidia of the soybean anthracnose fungus, Colletotrichum truncatum differentiate to form appressoria required for host invasion when the germ tube touches a hard surface. This thigmotrophic stimulus appears to be translated by the fungus during the second round of nuclear division. Inhibiting the second round of DNA synthesis by fluorodeoxyuridine or hydroxyurea blocked appearance of appressoria but not emergence of the germ tube. DNA synthesis and mitosis resumed upon removal of FUdR but only mycelia formed, and infection structures did not appear. In addition, actinomycin D reversibly blocked development of appressoria and synthesis of polyadenylate, but nuclear division was not affected. The data suggest that anthracnose conidia produce appressoria in response to germ tube contact by altering the messenger program of its germ tube nucleus. This study has also shown that mitochondrial DNA had an unusual bimodal distribution in CsCl at 1.690 and 1.719 g/cm³, respectively.Non-Standard Abbreviations FUdR 5-fluorodeoxyuridine - polyA polyadenylic acid     

Light germination ofAnthoceros miyabeanus spores

The effects of light on the spore germination of a hornwort species,Anthoceros miyabeanus Steph., were investigated. Spores of this species were photoblastic, but their sensitivities to light quality were different. Under either continuous white, red or diffused daylight, more than 80% of the spores germinated, but under blue light none or a few of them germinated. Under continuous far-red light or in total darkness, the spores did not germinate at all.Anthoceros spores required red light irradiation for a very long duration, i.e., over 12–24 hr of red light for saturated germination. However, the spore germination showed clear photo-reversibility by repeated irradiation of red and far-red light. The germination pattern clearly varied with the light quality. There were two fundamental patterns; (1) cell mass type in white or blue light: spores divide before germination, and the sporelings divide frequently and form 1–2 rhizoids soon after germination, and (2) germ tube type in red light: spores germinate without cell division, and the single-cell sporelings elongate without cell division and rhizoid formation.     

Electron microscopy of the rodlet layer of Neurospora crassa conidia.

Neurospora crassa macroconidia possess a regularly arranged layer of small fibers (rodlets) near the spore surface. The structure and location of this layer were studied by making surface replicas, by negative staining, by freeze-fracturing and deep-etching, and by thin sectioning. When conidia were shaken vigorously in water, the layer fragmented and became separated from the surface in sheets. Negative staining of such sheets showed that the individual rodlets have a hollow central core. When conidia were shaken gently in water or fixative, large fragments of the rodlet layer often remained on the conidial surface. The fragments tended to fold back on each other such that multiple layers were sometimes seen in thin sections. It is concluded that in dry conidia the rodlets are located on the extreme outside of the spore where they form a monolayer with only occasional regions of overlap.     

Effect of liming on spore germination,germ tube growth and root colonization by vesicular-arbuscular mycorrhizal fungi

Summary The effect of soil acidity on spore germination, germ tube growth and root colonization of vesicular-arbuscular mycorrhizal (VAM) fungi was examined using a Florida Ultisol. Soil samples were treated with 0, 4, 8 and 12 meq Ca/MgCO₃/100 g soil and each lime level received 0, 240, and 720 ppm P as superphosphate. Corn (Zea mays L.) was planted in the soil treatments, inoculated with eitherGlomus mosseae orGigaspora margarita spores and grown for 31 days. Acid soil inhibits mycorrhizal formation byG. mosseae through its strong fungistatic effect against the spores. The dolomitic lime increased mycorrhizal formation by both fungal species.G. margarita is much less sensitive to acidic conditions thanG. mosseae. Al ions are a very important component of the fungistatic property against the VAM symbiosis. VAM fungus adaptation may be important for plants growing on infertile acid soils if soil inoculation with these fungi is to contribute significantly to low-input technology for tropical agricultural systems.     

Ultrastructure of the Wall of the Germinating Sporangiospore of Linderina pennispora (Mucorales)

Carbon replicas of germinating sporangiospores of Linderinapennispora show the outer wall complex to break open basally,during the phase of swelling, and the surface of the germ tubeto be smooth. Chemical treatment reveal the microfibrillar wallof the germ tube to be continuous with the microfibrillar innerwall complex of the spore. Microfibrils of the germ tube arerandornly arranged and appear to be finer than those of thespore wall. Ultra-thin sections reveal the wall of the germtube to consist of an outer electron-dense layer and an innermicrofibrillar electron-transparent layer and both layers originatein the basal region of the spore between the plasmalemma andthe inner wall complex of the spore.     

Dry mass of Fusarium roseum spores before and after germination

The total dry mass of Fusarium roseum spores and contained lipid bodies were determined before and after spores germinated using quantitative interference microscopy. The mean for spore dry mass before germination was about 57 pg. Lipid bodies accounted for about 61% of that. Areas of lipid bodies in spores before and after germination were about 23 % but the contents of the lipid bodies accounted for only 10% of the spore dry mass after germination. The total dry mass of the spore and germ tube(s) greatly exceeded that of the spore before germination. We infer that nutrients for germ tube growth are derived from within the germinating spore and from the medium which must contain nutrients leached from non-germinating spores.     

Toxicity of diesel fuel to germination,growth and colonization of <Emphasis Type="Italic">Glomus intraradices</Emphasis> in soil and <Emphasis Type="Italic">in vitro</Emphasis> transformed carrot root cultures

Phytoremediation is the use of selected plants to decontaminate polluted environments. Arbuscular mycorrhizal fungi (AMF) may potentially be useful for phytoremediation, but it is not known how petroleum hydrocarbons influence AMF spore germination and hyphal growth. To address this question, germination of spores and germ tube growth of Glomus intraradices Schenck and Smith and Glomus aggregatum Schenck and Smith were assessed in soil contaminated with up to 3% (w/v) of F2 diesel oil or HAGO reference oil. Hyphal growth, colonization and progeny spore production were assessed in vitro using transformed root cultures of Daucus carota and G. intraradices spores in a F2 diesel contaminated medium. In addition, extraradical hyphal growth of G. intraradices colonizing Daucus carota in the presence of F2 diesel was studied. Neither F2 diesel nor HAGO reference oil affected spore germination or germ tube growth in soil. However, in the presence of plant roots, germ tube growth of G. intraradices was reduced and delayed in the presence of F2 diesel and root colonization was not detected. Hyphal growth of pre-colonized carrot roots by G. intraradices was reduced and delayed in F2 contaminated medium compared to controls. F2 diesel did not inhibit spore germination of these AMF species but did reduce colonization, germ tube and hyphal growth. These results suggest that AMF inoculum can be established in petroleum-contaminated sites. However, it may prove beneficial to plant pre-colonized plants to increase the probability of sufficient AMF colonization and growth. The likely mechanism(s) of petroleum toxicity in this plant-microbe system was discussed.