An improved test for evaluating the pathogenicity of isolates of Fusarium solani f.sp. pisi on pea

An improved in vitro test is described for determining the pathogenicity of Fusarium solani f.sp. pisi isolates on pea. This technique involves the use of polypropylene fibre Milcap plugs to suspend peas in boiling tubes containing spore suspensions in 0.1% water agar. Results were available after 14 days of incubation at 25°C. Four levels of pathogenicity were detected on pea cultivars Little Marvel and Dark Skinned Perfection using a total of eight isolates and strains of F. solani f.sp. pisi.     

Leaf Spots Induced by Ascochyta pisi and Mycosphaerella pinodes

The leaf-spot pathogens, Ascochyta pisi and Mycosphaerella pinodes,both cause limited, necrotic lesions in detached pea leafletssuspended above water. When leaflets were floated on water A.pisi lesions were still limited, but those caused by M. pinodesspread rapidly to occupy all the leaflet tissue. Increasing the numbers of spores in inocula decreased numbersof mature lesions caused by A. pisi, but increased numbers ofspreading lesions caused by M. pinodes. Older leaflets weremore susceptible to both pathogens. Studies of penetration and colonization of leaves with the aidof light and electron microscopy showed that cell-wall-degradingenzymes were involved in the formation of A. pisi lesions andin spreading lesions caused by M. pinodes. There was littleevidence of cell-wall degradation in limited M. pinodes lesionsin which penetration of walls by hyphae seemed to be mechanicalin nature. No physical barriers developed in tissues surrounding limitedlesions. Nevertheless, A. pisi was rarely found beyond the necroticarea. This suggested that tissues beyond the lesion had becomeresistant to the parasite. In contrast, M. pinodes often grewoutside the necrotic area, sometimes many days after this hadstopped growing, but when it did so it caused no more necrosisunless leaflets were placed in conditions in which the spreadingtype of lesion could develop.     

Collection of highly germinative pseudochain conidia of Oidium neolycopersici from conidiophores by electrostatic attraction

A population of simultaneously germinating conidia is an ideal inoculum of the powdery mildew pathogen, Oidium neolycopersici. In conditions of no or low wind velocity, O. neolycopersici successively stacks mature conidia on conidiophores in a chain formation (pseudochain), without releasing the precedent mature conidia. These pseudochain conidia represent a perfect inoculum, in which all conidia used for inoculation germinate simultaneously. However, we found that conidia must be collected before they fall to the leaf surface, because the germination rate was lower among conidia deposited on the leaf surface. We used an electrostatic spore collector to collect the pseudochain conidia, and their high germination rate was not affected by this treatment. The spore collector consisted of an electrified insulator probe, which created an electrostatic field around its pointed tip, and attracted conidia within its electric field. The attractive force created by the probe tip was directly proportional to voltage, and was inversely proportional to the distance between the tip and a target colony on a leaf. Pseudochain conidia were successfully collected by bringing the electrified probe tip close to target colonies on leaves. In this way, conidia were collected from colonies at 3-d intervals. This effectively collected all conidia from conidiophores before they dropped to the leaf surface. A high germination rate was observed among conidia attracted to the probe tip (95.5 ± 0.6 %). Conidia were easily suspended in water with added surfactant, and retained their germination ability. These conidia were infective and produced conidia in pseudochains on conidiophores after inoculation. The electrostatic spore collection method can be used to collect conidia as they form on conidiophores, thus obtaining an inoculum population in which all of the conidia germinate simultaneously.     

Effects of Leaf Age, Inoculum Dose and Freezing on Development of Chocolate Spot (Botrytis fabae) Lesions on Field Bean (Vicia faba) Leaves

Botrytis fabae spore suspensions containing c. 1, 10, 10², 10³, 10⁴, 10⁵, or 10⁶ spores/ml were used to inoculate 5, 17 or 30-day-old field bean leaves. The percentages of the leaf areas covered by, chocolate spot lesions and the percentages of the leaf areas bearing conidiophores were assessed 1, 6, 12, 14, and 19 days after inoculation. The percentage of the area covered by lesions and the percentage of the area bearing conidiophores (logit-transformed) increased linearly with increasing spore concentration (log₁₀-transformed). The proportions of leaf areas covered by lesions and bearing conidiophores were both greater on 17 and 30-day-old leaves than on 5-day-old leaves. The rate of lesion growth increased with both increasing inoculum dose and increasing leaf age. Generally there was no interaction between the effects of leaf age and the effects of inoculum dose on either lesion growth or sporulation. Two days after inoculation with suspensions of either 10⁴ or 10⁶ spores/ml, 7-day-old leaves grown at 15°C were transferred to –16°C or 2.5°C or kept at 15°C for 4 days. Two days later more spores had been produced on leaves which had been frozen (–16°C) than on, leaves kept at 2.5°C.     

Infection Process of Plectosporium tabacinum on False Cleavers (Galium spurium)

A native fungus, Plectosporium tabacinum (van Beyma) M. E. Palm, W. Gams et Nirenberg, has potential as a bioherbicide for the control of both herbicide-resistant and herbicide-susceptible false cleavers. Limited information is available on the infection process of P. tabacinum. P. tabacinum spore distribution pattern, germination, penetration, and colonization on false cleavers leaves were examined using confocal, light, and scanning electron microscopy. The results demonstrated that conidia were distributed over the entire surface of leaves and cotyledons. More than 90% of the conidia germinated on the leaf surface 6-8 h after inoculation. Penetration of the leaf epidermis by conidia started 8-10 h after inoculation. Histological observation showed that no appressoria were formed by P. tabacinum, but its hyphae produced appressed club-like structures that penetrated the cuticle and epidermal layers. No stomata or other natural openings were observed on the upper leaf surface of false cleavers seedlings. Penetration occurs directly on epidermal cells with more frequent intercellular penetrations. Hyphal penetration was visualized at a depth of 30 and 40 üm after 8 and 16 h of incubation, respectively. Secondary hyphae colonized mesophyll cells 16 h after inoculation. Even spore distribution, short spore germination time, club-like infection structure formation, direct penetration, quick colonization, and mucous secretion on false cleavers leaves may contribute to the kill of false cleavers by P. tabacinum. Slow spore germination and germ tube growth, low spore germination numbers, and no infection structure formation on Brassica napus leaves may be factors affecting the host selectivity of P. tabacinum.     

In vitro spore germination and infection of cultivars of Rubus and Rosa by downy mildews from both hosts

The cardinal temperatures for in vitro germination of conidia of imported and indigenous isolates of downy mildew from hosts in the genera Rubus and Rosa were similar. A high percentage of conidia germinated above 2°C and germination remained between 80% and 90% up to 15°C or 20°C, depending on the isolate. The highest incidence of disease on leaf disks of Tummelberry (blackberry × red raspberry) inoculated with an isolate of Peronospora rubi occurred at c. 15°C, with infection over a range from 2°C to 28°C. Tests on leaf disks in vitro, and leaflets of primocane and lateral shoots in plastic tunnels, with three hybrid berry (blackberry x red raspberry), six blackberry and nine red raspberry cultivars showed the hybrid berries to be most susceptible. In a plastic tunnel infected drupelets of red raspberry fruits developed more slowly and failed to ripen evenly compared with uninfected drupelets. Similar malformation of infected fruits occurred in a plantation of Tummelberry. An isolate of P. rubi attacked severely both Tummelberry and rose cv. Can Can. Fluorescence microscopy after staining with aniline blue showed that leaf disks of Tummelberry were extensively colonised by intercellular mycelium of P. sparsa isolated from rose, even though sporulation was sparse or absent. This supports the view that P. rubi and P. sparsa may be conspecific. Oospores of P. rubi were found routinely within leaf disks of Rubus cultivars inoculated in vitro and once in naturally infected leaflets of Tummelberry.     

Influence of pea-root exudates on germination of conidia and chlamydospores of physiologic races of Fusarium oxysporum f. pisi

Sterile root exudates from wilt susceptible and wilt resistant pea cultivars showed no differential effects on spore germination of Fusarium oxysporum Schl. f.pisi (Linf.) Snyd. & Hans, races 1 and 2 which could be correlated with the pathogenicity of a particular isolate to a given cultivar. Uniformly high percentages of germination were obtained with conidia of the two races in aseptic shake culture with exudates collected from resistant or susceptible plants of various ages. Chlamydospores of the two races incubated with exudates under sterile conditions germinated to uniformly high levels irrespective of exudate origin. Conidia and chlamydospores of Fusarium solani (Mart.) Sacc. f. pisi (Jones) Snyd. & Hans., used for comparative purposes, also germinated to high levels in the presence of exudate solutions of all cultivars. Non-specific germination of the two races of F. oxysporum f. pisi occurred in soil when the exudates were supplied to populations of chlamydospores via diffusion units. Germination was lower than that recorded under sterile conditions and was rapidly followed by germling lysis.     

In vivo control of Mycosphaerella pinodes on pea leaves by a crude bulb extract of Eucomis autumnalis

We previously reported on the in vitro antifungal activity of a crude whole plant extract from Eucomis autumnalis against seven economically important plant pathogenic fungi. A crude extract of the bulb showed similar in vitro mycelial growth inhibition of the same plant pathogenic fungi as well as that of an eighth fungus, Mycosphaerella pinodes, the cause of black spot or Ascochyta blight, in peas. Subsequently, fourth internode leaves were removed from 4 wk old pea plants, placed on moist filter paper in Petri dishes and inoculated with an M. pinodes spore suspension before and after treatment with the extract. The control of Ascochyta blight by different concentrations of the crude E. autumnalis extract was followed in vivo by leaf symptoms over a 6 day period at 20°C in a growth cabinet. The crude extract prevented M. pinodes spore infection of the leaves when the leaves were inoculated with spores both before or after treatment with the extract, confirming complete inhibition of spore germination. The crude E. autumnalis extract showed no phytotoxic reaction on the leaves even at the highest concentration applied.     

Effect of Mannich bases on some plant pathogenic fungi

3-(2-Pyridyl)-3-iminoisatin, 1-piperidinomethyl-3-(2-pyridyl)-3-iminoisatin, and 1-acetyl-3-(2-pyridyl)-3-iminoisatin affect spore germination ofAlternaria alternata, A. carthemi, Curvularia lunata, Fusarium oxysporum f.sp.cieri andF. udum and influence the development of powdery mildew (Erysiphe pisi) on pea under glasshouse condition as well as conidial germination ofE. pisi on excised pea leaves. Spore germination was inhibited in the sequence 1-acetyl-3-(2-pyridyl)-3-iminoisatin > 1-piperidinomethyl-3-(2-pyridyl)-3-iminoisatin > 3-(2-pyridyl)-3-iminoisatin followed the order accordingly. The powdery mildew development and conidial germination ofE. pisi 1-piperidinomethyl-3-(2-pyridyl)-3-iminoisatin > 1-acetyl-3-(2-pyridyl)-3-iminoisatin > 3-(2-pyridyl)-3-iminoisatin. The chemicals were compared with commonly used antifungal fungicides.     

Infection process of Colletotrichum dematium on mulberry leaves: An unusual method of sporulation

Abstract

The pre-penetration and infection process of Colletotrichum dematium on mulberry leaf was investigated by scanning electron microscope. Conidia produced on germination appressoria directly or at the end of short germ tubes. Appressoria were formed mostly over cuticle, but sometimes over stomata also. At 72 h post-inoculation, an extensive network of sub-cuticular runner hyphae (RH) was produced. The RH were traceable by the cuticular bulgings on leaf surface. The RH emerged to leaf surface through ruptured cuticle to form secondary infection hyphae (SIH). The SIH re-entered the leaf tissue by sending penetration branches through stomata. Conidia were formed singly on short conidiophores from the RH and SIH, at short intervals. The conidia developed on RH were exposed to leaf surface through ruptured cuticle. Some times conidia were released through stomata also. The RH and SIH had thick knots from which hyphal branches and conidia were developed. Definite acervuli were not developed.     

Infection Process of Botrytis cinerea on Eucalypt Leaves

This study aimed to elucidate the infection process of Botrytis cinerea on eucalypt leaves. Tests were conducted to evaluate the influence of leaf side (adaxial or abaxial), leaf age and luminosity on conidial germination, appressorium formation and grey mould (GM) severity. The adaxial and abaxial surfaces of detached eucalypt leaves were inoculated with a conidial suspension of B. cinerea and kept under constant light or dark. Subsequently, the adaxial surface of young and old leaves was inoculated and kept in the dark. To evaluate the percentage of conidia germination and appressorium formation, leaf samples were collected 6 hours after inoculation (hai), clarified (alcohol and chloral hydrate) and evaluated under a light microscope. The severity of GM was assessed 10 days after inoculation. For scanning electron microscopy analysis, samples were collected from 2 to 168 hai. A higher percentage of conidia germination (92%) and GM severity (21%) occurred on the adaxial surfaces of leaves kept in the dark. There was no statistical difference between the surfaces of young and old leaves for conidia germination. No appressorium was formed by B. cinerea. The GM severity on young leaves (17.3%) was 34 times higher than on old leaves (0.5%). The micrographs showed germinating conidia emitting 1–4 germ tubes in samples at 4 hai. The fungus penetration occurred through intact leaf surfaces, and both extra‐ and intracellular colonization of the mesophyll cells by the hyphae of the pathogen were observed at 120 hai. Sporulation occurred on the adaxial and abaxial surfaces (macronematous conidiophores) and below the epidermis (micronematous conidiophores).     

Factors affecting incidence and severity of leaf spot disease on lettuce caused by Septoria birgitae

In the 1990s during wet seasons a new disease causing brown leaf spots on lettuce (Lactuca sativa) was found for the first time in many lettuce‐growing areas of Austria and Germany. The causal agent, a new pathogenic species called Septoria birgitae, may be responsible for total crop loss. To study how temperature, inoculum density and leaf wetness period influence disease incidence and severity of leaf spot on lettuce caused by S. birgitae, we carried out in vivo experiments in growth chambers and in the field. Additionally, we evaluated the relevance of infected plant debris acting as a primary inoculum source in soil for subsequent crops. S. birgitae produces spores over a wide temperature range between 5°C and 30°C, and can infect plants at temperatures between 10°C and 30°C, with an optimum between 20°C and 30°C. Spores of S. birgitae at a density of at least 10³ conidia mL^–1 are essential for disease outbreak on lettuce. Because leaf wetness is crucial for releasing conidia from pycnidia, we studied the impact of leaf wetness duration on disease development under various temperature conditions. For relevant leaf spot disease development on lettuce in vivo, a leaf wetness duration of at least 24 h and temperatures higher than 10°C were necessary. Leaf spot disease development in the field required several leaf wetness periods longer than 20 h at approximately 15°C at the beginning of crop cultivation. Incorporating S. birgitae infected plant debris in soil as a primary inoculum was not relevant for leaf spot disease outbreak in the next year. However, in cases of continuous cropping of lettuce on the same field and in the same season, Septoria‐infected lettuce debris may become more relevant.     

Influence of Plant Root Exudates, Germ Tube Orientation and Passive Conidia Transport on Biological Control of Fusarium Wilt by Strains of Nonpathogenic Fusarium oxysporum

In earlier studies, biological control of Fusarium wilt of cucumber induced by Fusarium oxysporum f. sp. cucumerinum was demonstrated using nonpathogenic strains C5 and C14 of Fusarium oxysporum. Strain C14 induced resistance and competed for infection sites whether roots were wounded or intact, whereas strain C5 required wounds to achieve biocontrol. In the current work, additional attributes involved in enhanced resistance by nonpathogenic biocontrol agents strains to Fusarium wilt of cucumber and pea were further investigated. In pre-penetration assays, pathogenic formae specials exhibited a significantly higher percentage of spore germination in 4-day-old root exudates of cucumber and pea than nonpathogens. Also, strain C5 exhibited the lowest significant reduction in spore germination in contrast to strain C14 or control. One-day-old cucumber roots injected with strain C14 resulted in significant reduction in germ tube orientation towards the root surface, 48–96 h after inoculation with F. o. cucumerinum spores, whereas strain C5 induced significantly lower spore orientation of the pathogen and only at 72 and 96 h after inoculation. In post-penetration tests, passive transport of microconidia of pathogenic and nonpathogens in stems from base to apex were examined when severed plant roots were immersed in spore suspension. In repeated trials, strain C5, F. o. cucumerinum and F. o. pisi were consistently isolated from stem tissues of both cucumber and pea at increasing heights over a 17 days incubation period. Strain C14 however, was recovered at a maximum translocation distance of 4.6 cm at day 6 and later height of isolation significantly declined thereafter to 1.2 cm at day 17. In pea stem, the decline was even less. Significant induction of resistance to challenge inoculation by the pathogen in cucumber occurred 72 and 96 h after pre-inoculation with biocontrol agents. Nonetheless, strain C14 induced protection as early as 48 h and the maximum resistance was reached at 96 h. The presented data confirm the previous findings that attributes important for nonpathogenic fusaria to induce resistant are: rapid spore germination and orientation in response to root exudate; active root penetration and passive conidia transport in stem to initiate defence reaction without pathogenicity and enough lag period between induction and challenge inoculation. Strain C14 possesses all these qualifications and hence its ability to enhance host resistance is superior than strain C5.     

Non-Specific Induction of Pisatin and Local Resistance in Pea Leaves by Elicitors from Mycosphaerella pinodes, M. melonis and M. ligulicola and the Effect of Suppressor from M. pinodes

The accumulation of pisatin was induced non-specifically by elicitors prepared from the high molecular weight fraction (molecular weight: more than 10,000 daltons) of the spore germination fluid of three species of Mycosphaerella-plant pathogens in pea leaves with epidermis removed, regardless of the pathogenicity of the fungi to pea. Before the elicitation of pisatin synthesis, local resistance to infection by Mycosphaerella pinodes was induced by elicitors again non-specifically inpea leaves in which wax had been removed from the leaf surface. The substance responsible for local resistance could be extracted with ethylacetate from the elicitor-containing drop diffusate which was placed on pea leaves. The substance prevented the penetration of M. pinodes through heat-killed pea epidermis, but did not affect spore germination. The suppressor prepared from the low molecular weight fraction (molecular weight: less than 10,000 daltons) of the spore germination fluid of M.pinodes counteracted the ability of elicitors to induce both phases of resistance mechanisms.     

Evaluation of the potential role of water in spread of conidia of the Neotyphodium endophyte of Poa ampla

Neotyphodium endophytes are asexual, filamentous fungi, mutualistically associated with diverse cool season grasses. Infected seeds and vegetative organs of infected host plants are the only known modes of propagation of the asexual endophytes. In the last decade certain Epichloë and Neotyphodium-infected grass species have been shown to have epiphyllous structures of the endophytes, hyphae, conidiophores, and conidia, growing on leaf blades. The production of epiphyllous conidia suggests the possibility that some of these endophytes may have the ability for plant-to-plant spread. The objective of this study was to determine the possible mechanisms involved in liberation and dispersal of asexual spores of Neotyphodium growing in vitro and epiphyllously on leaves of Poa ampla. Our results indicate that water dispersal is the most likely means of dissemination of conidia of the Neotyphodium sp. Wind generated by dry compressed air does not dislodge the conidia from slide cultures or from P. ampla leaves.     

Elution Profiles of Pisatin Elicitor Activity from Extracts of Monilinia fructicola,Pisum sativum and Diffusates from their Interaction*

Pisatin elicitor activity was examined in diffusate of the M. fructicola–pea endocarp interaction, leachate of pea endocarp, extracts of ungerminated conidia and filtrates of conidia germinated in vitro in a simple nutrient broth, or in filter–sterilized diffusate or pea leachate. Extracts were made after 18 h incubations which represents the half–time of the primary phase of pisatin accumulation in the M. fructicola–pea model system. These were chromatographed on a Bio–Gel, P–2 column and elicitor activity in eluate fractions was located by bioassay for the ability to induce pisatin accumulation. A characteristic elution profile of pisatin elicitor activity was obtained from diffusate of the pea–M. fructicola interaction. Other preparations obtained from pea leachate, ungerminated conidial extracts or culture filtrates of the fungus germinated in a simple nutrient broth or pea leachate (6 h) did not contain the same profile of elicitor components. No further production of elicitor was detected in early diffusate (6 h) filtrates when they were incubated in vitro alone or withM. fructicola. Elicitor activity was significant in some conidial germination filtrates in vitro. The elution profiles of elicitor activity obtained from these filtrates were shown to be dependent on the physical conditions of culture used (still or shaken). Incubation of the pea leachates with M. fructicola in vitro resulted in the formation of a high molecular weight elicitor which did not correspond with that of the diffusate preparations. Its reapplication to pod tissue did not suggest that it was significantly metabolized by pea tissue to produce the same elicitors found in diffusate preparations. The results emphasize the importance of in vivo studies in the search for elicitors of phytoalexins where two living systems, the plant and the fungus are intimately involved.     

Hyperparasitic Attack of Trichothecium roseum on Conidia of Pestalotiopsis funerea

Trichothecium roseum (Tr) has been shown to be a highly effective hyperparasite on conidia of Pestalotiopsis funerea (Pf) in vivo and in vitro. The stages of this spore parasitism are: positive tropism of Tr towards Pf conidia, contact between Tr and Pf, formation of simple or lobed appressoria of Tr on the host conidial surface, penetration of the attacked host cells from the base of the appressoria, development of host-internal, mostly branching parasitic hyphae by Tr, desintegration, lysis and death of the parasitized host cells, exit of Tr from the destroyed host cells and its intensive sporulation over Pf remnants. Pf did not show any defence reactions against the attack by Tr. In addition to the antagonistic activities of Tr against Pf reported previously, which are due to extracellular toxins released by Tr, direct hyperparasitism is a second mechanism of antagonism, which contributes to the successful competitive ability of Tr in this fungal interaction.     

Conidia of the tomato powdery mildew <Emphasis Type="Italic">Oidium neolycopersici</Emphasis> initiate germ tubes at a predetermined site

The emergence of germ tubes from the conidia of powdery mildew fungi is the first morphological event of the infection process, preceding appressoria formation, peg penetration and primary haustoria formation. Germination patterns of the conidia are specific in powdery mildew fungi and therefore considered useful for identification. In the present study, we examined conidial germination of the tomato powdery mildew Oidium neolycopersici KTP-01 in order to clarify whether germ tube emergence site in KTP-01 conidia is determined by the first contact of the conidia to leaves (as found for the conidia of barley powdery mildew), or alternatively is predetermined and is unrelated to contact stimulus. Highly germinative conidia of KTP-01 were collected from conidial pseudochains on conidiophores in colonies on tomato leaves using two methods involving an electrostatic spore attractor and a blower. In the electrostatic spore attraction method, the conidia were attracted to the electrified insulator probe of the spore collector—this being the first contact stimulus for the conidia. In addition, the blowing method was used as a model of natural infection; pseudochain conidia were transferred to detached leaves by air (1 m/s) from a blower. Thus, landing on the leaves was the first contact for the conidia. Furthermore, conidia were also blown onto an artificial membrane (Parafilm-coated glass slides forming a hydrophobic surface) or solidified agar plates in Petri dishes (hydrophilic surface). Eventually, almost all conidia on the probe and on tomato leaves or artificial hydrophobic and hydrophilic surfaces synchronously germinated within 6 h of incubation, indicating that the first contact of the conidia with any of the aforementioned substrata was an effective germination induction signal. Germ tube emergence sites were exclusively subterminal on the conidia. Moreover, the germ tubes emerged without any relation to the sites touched first on the conidia. Thus, the present study strongly indicates that conidia of O. neolycopersici produce germ tubes at a predetermined site.     

An unusual method of development and sporulation of Colletotrichum gloeosporioides on castor leaf – an SEM account

Development and sporogenesis of Colletotrichum gloeosporioides on castor leaf differed from that on other known host plants. C. gloeosporioides had three kinds of hyphae on castor leaf: primary infection hyphae (PIH), runner hyphae (RH) and secondary infection hyphae (SIH). The PIH originated from conidia, grew on leaf surface and entered the leaf by direct penetration of the cuticle without forming appressoria. The RH were sub-cuticular hyphae, the track of which was traceable by the bulgings on the leaf surface, and the SIH were the hyphae that emerged to leaf surface from RH through the cuticle or stomata. Conidia were initiated as small protrusions along the lengths of RH and SIH that got differentiated into distinct conidia, each born on a short stumpy conidiophore without forming any congregation. The protrusions from RH emerged to the leaf surface by piercing the cuticle, and they developed into distinct conidia on the leaf surface. The conidia developed from RH and SIH were identical in size and shape. Even though conidia were occasionally found emerged through stomata, that appeared to be random than a preferred route for the discharge of conidia. The penetration and sporogenesis of C. gloeosporioides on castor leaf differed from that reported on mulberry leaf.     

Infection of Barley by <Emphasis Type="Italic">Ramularia</Emphasis> <Emphasis Type="Italic">collo-cygni</Emphasis>: Scanning Electron Microscopic Investigations

Ramularia collo-cygni causes leaf spots on barley (Hordeum vulgare), a disease of growing economical importance. Scanning electron microscopy was used to study the life cycle of the fungus on barley during the vegetation period and in winter. The infectious stage started with conidium germination on the surface and the penetration into the leaf via the stomatal pore where the hyphae grew within the cells that became necrotic. The conidiophores emerged through the stomatal pore. On older leaves, however, they frequently emerged apart from it and the results suggested a pushing apart of adjacent cell walls of the epidermal cells. An assessment of the amount of conidium formation of one heavily infested barley plant resulted in 4.05 × 10⁶ conidia per plant. For the first time, conidiophores, conidium production and germination of conidia were also observed in winter on barley and on maize leaves.