Tropic failure of Phyllactinia corylea contributes to the mildew resistance of mulberry genotypes

Different mulberry genotypes show great variation in their resistance to the powdery mildew Phyllactinia corylea. Conidial germination and hyphal growth of P. corylea on the leaf surface of two susceptible mulberry genotypes, viz., Kanva 2 (K2) and Victory 1 (V1) varieties of Morus indica, and on two resistant species, viz., M. laevigata and M. serrata were studied by scanning electron microscopy. Conidial germination and growth of germ tubes were normal on all the leaves. The hyphae of P. coryleaidentify stomata on host leaves by their topographical features to produce the stomatopodia precisely over them. The holes and/or the grooves of stomata appear to provide the signals for the initiation of stomatopodia and similar structures are erratically developed over many local depressions or grooves on leaf surface. The abaxial surface of K2 leaf is smooth without prominent undulations of epidermal cell surface, and the stomata are flush with the leaf surface. Although successful penetration is also achieved on V1 leaf, its slightly undulated surface occasionally provides inaccurate tropic signals to the hyphae, inducing the development of stomatopodia away from the stomata. The leaf surfaces of M. laevigata and M. serrata are very rough with highly sculptured cuticle and abundant epidermal outgrowths. Stomata mostly remain sunken or hidden amidst the cuticular ornamentations and the hyphae fail to recognise the precise signals from them. As the surface architecture of the leaves provides many immense sources of tropic signals, stomatopodia are often produced over local depressions or grooves. In these cases the fungus fails to penetrate the leaf, does not develop beyond 24 h and penetration is rarely achieved on the leaves of the resistant plants. The study indicates that the stimulatory effect of the leaf surface topography of resistant varieties misleads the pathogen from successful penetration, thus contributing to the plant's resistance.This revised version was published online in October 2005 with corrections to the Cover Date.     

Development of special hyphal branches of Phyllactinia corylea on host and non-host surfaces

Hyphae of Phyllactinia corylea produce two kinds of special branches on the host surface: adhesion bodies which serve as fungal attachment and stomatopodia which enter the leaf through stomata. Conidial germination on host and non-host surfaces was examined with a scanning electron microscope to explain the stimuli responsible for development of the special branches, and the involvement of host recognition in the process. Conidia germinated within 4 h on host and non-host surfaces, but on non-host surfaces the emergence of the germ tube was not always directed towards the substratum. Adhesion bodies were formed from the tips of germ tubes at the first contact point on host and non-host surfaces. Development of stomatopodia was more specific and they were formed precisely over stomata on the host surface. Stomatopodia-like structures were occasionally formed over finely ridged leaf veins on the host surface and over some fine scratches on synthetic surfaces. The experiments showed that while conidial germination and development of adhesion bodies are in response to contact stimuli, the development of stomatopodia is a response to precise topographical signals, and the directional emergence and attached growth of germ tubes involve host recognition.This revised version was published online in October 2005 with corrections to the Cover Date.     

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 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.     

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.     

Mode of Infection of Phyllosticta maculata on Banana as Revealed by Scanning Electron Microscopy

The initial infection stages of Phyllosticta maculata on banana were studied using scanning electron microscopy. Conidial germination on the banana leaf surface commenced within 3 h postinoculation to produce a long and slender germ tube. The hyphae developed secondary branches and mostly grew randomly across the leaf surface. Appressoria were formed at the apex of the germ tubes within 18 h postinoculation and were variable in shape. A layer of an extracellular matrix surrounded the appressoria at the pathogen–host interface. On the fruit surface, conidia germinated to produce predominantly swollen germ tubes which functioned as lateral appressoria together with some slender ones. These germ tubes were formed within 3 h postinoculation. There was no stomatal penetration apparent on the leaf; instead, direct penetration through the cuticle with and without the formation of appressoria was observed. Cuticular degradation on the leaf surface was evident with a circular, darkened area around the point of penetration by hyphae or appressoria. The significant role of pycnidia and conidia in the epidemiology of the disease was further demonstrated in naturally infected leaf samples.     

Studies on turfgrass snow mold caused byTyphula ishikariensis. II. Microscopical observation of infected bentgrass leaves

Light and transmission electron microscopy revealed thatTyphula ishikariensis penetrated into bentgrass leaves either through cuticles or stomata either by single hyphae or infection cushions formed on host surfaces. Time course study on infected leaves showed that penetration through stomatal subsidiary cells and their adjacent cells seemed to occur earlier than that through epidermal cells located farther from stomata. More than 30% of epidermal cells were infected by 10 days after inoculation. When hyphae penetrated through an intact cuticle of epidermal cells, they seemed to dissolve host cell walls enzymatically at penetration sites. Physical pressure also seemed to be involved in penetration.     

Host-Parasite Relationship in a Susceptible and a Resistant Rose Cultivar Inoculated with Sphaerotheca pannosa: I. Fungal Growth, Mechanical Barriers and Hypersensitive Reaction

Conidial germination and development of Sphaerotheca pannosa were studied on a susceptible and a resistant cultivar (rose Cardinal and rose Queen Elisabeth, respectively) in relation to the morphology of the leaf surface which was examined by scanning and transmission electron microscopy. Conidial germination was completed within 24 h in both cultivars and seemed to be higher in the resistant cultivar; fungal development, however, was stopped when the haustoria containing cells became necrotic. The only morphological difference between the leaves of the two cultivars is a thinner cuticle in rose Cardinal. Wax deposits on the leaf surface are similar; a layer of substances reacting to rhutenium red, most likely glycoproteins or protein-polysaccharide complexes, also are similar.     

Quantification of Fungal Hyphae in Leaves of Deciduous Trees by Automated Image Analysis

An optical method to quantify the fungal hyphae within decomposing leaves of deciduous trees was developed. The plant matrix was partially destroyed under hydrolytic conditions, and fungal hyphae and cellulose residues within the leaves were stained with Calcofluor M2R. Cellulose residues were subsequently depolymerized by cellulase, and fungal hyphae were separated from the remaining plant matrix with a pressurized air-water mixture. An image analysis program to quantify the fungal hyphae was written. The program included the recognition of fungal hyphae, the elimination of stomata from the images, and the measuring of lengths of fungal hyphae. The optical method was verified by a chemical method relying on glucosamine as an indicator of fungal biomass. The fungal biomass in leaves of Fagus silvatica and Quercus petraea at early states of decomposition was 0.2 to 0.4% of the leaf weight. The biomass reached a maximum within 2 to 4 weeks (optical method, 0.5 to 0.7%; chemical method, 1 to 1.4% of the initial leaf weight) and decreased thereafter.     

A Histological Evaluation of Induced Resistance to Phytophthora infestans (Mont.) de Bary in Potato Leaves

Systemically induced resistance against Phytophthora infestans in the potato cultivar ‘Bintje’ was studied histologically at the light microscopy level on the leaf surface, in the epidermis and in the mesophyll of challenged potato leaves. Systemic disease resistance was induced by a local pre-infection with the same fungus. On the leaf surface of induced plants, the germination of cysts was enhanced. In the epidermis of induced plants, papilla deposition increased and penetration decreased, whereas in the mesophyll of induced plants the spread of hyphae was reduced. It is suggested that the reduction of disease severity in induced plants is the result of the combined action of several successive defence reactions.     

Scanning Electron Microscopy of the Infection Process of Cercospora henningsii on Cassava Leaves

Germination, penetration and sporulation of Cercospora henningsii (Allesch.) on cassava leaves were studied by scanning electron microscopy. Conidia started to germinate 9 h postinoculation producing one to two germ tubes. The germ tubes entered the leaf tissue through the abaxial surface by direct penetration of the epidermis without forming appressoria. The cassava leaf is characterized by its papillose epidermis on the abaxial surface. The penetrations occurred at smooth areas of the leaf epidermis between the papillae. The germ tubes did not enter stomata even when they passed over stomatal openings. Leaf spots started to appear 9 days after the inoculation (dpi), and the emergence of conidia occurred 14 dpi. The symptoms appeared first on the abaxial leaf surface, followed 2 days later on the adaxial. Conidia emerged in clusters through ruptured epidermis on both sides of the leaves. Conidia emerged also through the epidermal papillae and the leaf veins. Even though small groups of conidia emerged through stomata also, emergence through stomata appeared to be random rather than a preferred route. Each conidium was born on a short conidiophore with a swollen base.     

Pre-exposure to ozone predisposes oak leaves to attacks by Diplodia corticola and Biscogniauxia mediterranea

One-year-old cork oak (Quercus suber) and turkey oak (Q. cerris) seedlings were exposed to ozone (110 ppb, 5 h day(-1), for 30 days) and were inoculated with Diplodia corticola and Biscogniauxia mediterranea, respectively, by spraying a suspension of spores on the leaves. Both fungi are endophytic and may act as weak parasites, contributing to oak decline. Ozone exposure stimulated leaf attacks after inoculation, although the physiological, visible, and structural responses of both oaks to O3 exposure were weak. In fact, steady-state gas exchange, leaf waxes, and wettability were not significantly affected by O3. In Q. cerris, O3 altered the structure of stomata, as observed by scanning microscopy, and reduced the leaf relative water content. No hyphal entry through stomata or growth towards stomata was, however, observed. Inoculations were performed in a humid chamber at low light; stomata were likely to be closed. When Q. cerris was inoculated in natural conditions, i.e., in a forest infected by B. mediterranea, seedlings pre-exposed to the enhanced O3 regime had a higher number of B. mediterranea isolates than the controls. This suggests that pre-exposure to O3 predisposed Q. cerris leaves to attacks by B. mediterranea independent of stomata. The hyphae of both fungi were able to enter the leaf through the cuticle, either by gradual in-growth into the cuticle or erosion of a hollow in the cuticle at the point of contact. The primary cause of increased leaf injury in O3-exposed seedlings appeared to be higher germination of spores than on control leaves.     

Light and sem studies on the life stages of illeis indica (TIMB.) and its predatism on phyllactinia corylea (PERS.) karst. infecting mulberry

The fungivonis insect Illeis indica is a potential biocontrol agent of Phyllactinia corylea which causes powdery mildew in mulberry. The present study by light and scanning electron microscopy explains the life stages of I. indica and its feeding behaviour on P. corylea borne on infected mulberry leaves. The eggs are laid in clusters of 5–23 on the abaxial surface of infected leaves. Each egg has 16–18 aeropyles circularly arranged at its distal end around a micropylar plate. Total larval period of I. indica is about 15.60 days with four instars and its life cycle is completed in 38.50 days. The grubs feed only on conidia during first instar, on conidia and conidiophores during second instar, and also on parts of mycelia during third instar. The final instar grubs feed on entire aerial mycelial mass leaving only stomatopodia and hyphal remnants attached to them. Pupation is for 6–7 days and the pupae remain motionless and attached to the abaxial leaf surface. Adults also feed voraciously on the fungal mass and the fertilized females lay eggs after about 7.03 ±0.144 days. The grubs and adults clear off the fungal mass from the infected leaves without leaving any mycelial patch and the fungus does not regenerate on such cleared leaves. Field observations indicated a drastic fall in the incidence of powdery mildew disease in mulberry even in the usual peak disease period, with the increased population of I. indica in the mulberry garden.     

Screening of mulberry germplasm lines against Powdery mildew,Myrothecium leaf spot and Pseudocercospora leaf spot disease complex

Abstract

Fifty-six indigenous and 29 exotic mulberry varieties were screened against powdery mildew, Myrothecium leaf spot, Pseudocercospora leaf spot for a period of three years under field conditions. The percent disease index (PDI) was recorded during the peak season of the diseases. Out of 85 germplasm lines studied four-germplasm lines viz. Thailand lobed (0.43), M. multicaulis (2.63), Italian (2.83) and M. australis (4.56) were found highly resistant; nine lines were resistant; 43 lines were moderately resistant and 29 were susceptible to the disease complex. Powdery mildew showed significant positive correlation with Pseudocercospora leaf spot. Highly resistant varieties may be utilized for future disease resistance breeding programme to evolve multiple disease resistant mulberry varieties.     

Analysis of phylogenetic relationship among five mulberry (Morus) species using molecular markers.

Species identification in mulberry (Morus) continues to be a point of great debate among scientists despite the number of criteria such as floral characters, wood, and leaf anatomical and biochemical characters used to identify the species within this genus. However, no consensus system of classification has emerged. Hence, an investigation was undertaken with inter-simple sequence repeat (ISSR) and random amplified polymorphic DNA (RAPD) markers to find out the possibility of using these DNA markers to confirm the identity of genotypes in a particular species. Fifteen ISSR and 15 RAPD primers generated 86% and 78% polymorphism, respectively, among 19 mulberry genotypes. The polymorphism among the species varied from 50% to 57% in ISSR markers and 31% to 53% in RAPD markers. Similarity coefficients were higher among the genotypes of M. latifolia, M. bombycis and M. alba. Cluster analyses separated genotypes of M. laevigata and M. indica from those of the other species. Population structure analysis of these species further showed high genetic differentiation coefficients (GST), high heterozygosity between two species (DST), and total heterozygosity among populations (Ht) coupled with considerably low gene flow (Nm) when M. laevigata was paired with other species. Based on these parameters and the result of cluster analysis it is concluded that M. laevigata can be considered as a separate species of mulberry, whereas the other four species may be grouped together and treated as subspecies.     

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).     

Effects of soil water level on the development of adult plant resistance to powdery mildew in barley

Barley grown in dry soil developed greater adult plant resistance (APR) to powdery mildew (Erysiphe graminis DC. f. sp. hordei Mérat) than barley grown in wet soil. Conidial germination and appressorium formation were less, and fungal development between formation of appressoria and elongating secondary hyphae on upper leaves was inhibited, when adult plants were grown in dry soil. Mildew colonies expanded more slowly on leaves of adult plants than on leaves of seedlings, especially if adult plants had grown in dry soil. APR was reduced if plants, previously grown in dry soil, were well watered more than 32 h before inoculation. Conidia originating from plants grown in dry soil had a lower solute potential and greater ability to infect plants grown in dry but not wet soil than conidia originating from plants grown in wet soil. APR could not be attributed simply to increased cell wall or cuticle thickness, nor to lowered leaf solute potentials, as has sometimes been suggested for powdery mildew diseases. Increasing plant age and water stress induced increases in cell wall and cuticle thickness, but these changes did not always coincide with changes in disease resistance. Increasing plant age and water stress also lowered leaf solute potentials but fungal solute potentials were lower than leaf solute potentials and, more importantly, were lower than leaf water potentials. Thus, fungal growth was not limited by the availability of water from the host during penetration and hyphal establishment. It is suggested that resistance levels may be determined not by the thickness of epidermal structures, nor by lowering of solute potential per se, but by specific substances harmful to the fungus which accumulate in either cell wall, cuticle or sap, and whose concentration is dependent on the age and water stress of leaves.     

Surface ultrastructure of the uredinial stage ofCerotelium fici and its infection process on mulberry

Surface morphology of uredinia and urediniospores ofCerotelium fici (Cast.) Arth., and its infection process in mulberry (Morus alba L.) have been described using the scanning electron microscope. The uredinia ofC. fici are paraphysate and bear pedicellate urediniospores. The surface morphology of urediniospore is similar to most of the rust fungi which have pedicellate urediniospores. The infection process ofC. fici on mulberry leaves differs from other rust fungi in not forming appressoria over the stomates. Further, the germ tube of the urediniospore crosses over the stomata, and sometimes forms an appressorium close to the stoma rather than forming over it. Thus, the present study indicates that the formation of appressoria byC. fici on mulberry leaves is not site specific but an independent, specialized and inherent mechanism required byC. fici to penetrate the mulberry leaf cuticle and epidermis.     

落叶松-杨栅锈菌在感病杨树寄主上发育过程的组织学研究

采用荧光染色技术、光学显微镜和电子显微镜技术,系统研究了落叶松-杨栅锈菌在感病杨树叶片上的发育过程。结果表明,在侵染前期（接种12h以内）,锈菌夏孢子在杨树叶片上萌发,利用芽管或附着胞穿透叶表气孔后形成气孔下囊,进而在胞间产生侵染菌丝。进入活体营养生长阶段（接种后24-96h）,锈菌不断产生大量吸器来满足营养需求的同时,侵染菌丝在叶肉细胞间隙蔓延分枝生长至形成菌落结构。最终在产孢阶段（接种120h之后）产孢菌丝分化形成的夏孢子在表皮下聚集成堆,待成熟后突破表皮显露出来。     

黄瓜对霜霉病抗性的显微和超微结构的研究

利用显微及透射和扫描电镜方法,研究了黄瓜对霜霉菌[Pseudoperonosporacubensis(Berk.et Curt.)Rostow.]的抗性机理,结果如下:抗病与感病品种叶表面的气孔密度和大小无明显区别,而病菌分生孢子在叶表面萌发情况有差异。抗病品种被病菌侵染后,细胞迅速颗粒化,与病菌一起死亡,两个侵染点之间的叶肉细胞大量繁殖,细胞中叶绿体减少,膜系统受到破坏,壁增厚,叶表面出现少量很小的病斑;中抗品种表现为少量菌丝蔓延,并产生分生孢子囊梗和孢子,受侵细胞的线粒体和叶绿体膜系统被破坏,随后内细胞和菌丝死亡,但比抗病品种慢,在叶表面形成很多病斑;感病品种表现为叶肉细胞内有大量菌丝蔓延,并产生分生孢子囊梗和孢子,受侵细胞被破坏、解体成碎片,最后与菌丝一起死亡,在叶表面联成大量的病斑。