Changes in the cytoskeleton accompanying infection-induced nuclear movements and the hypersensitive response in plant cells invaded by rust fungi

During the infection of cowpea (Vigna unguiculata) by the cowpea rust fungus (Uromyces vignae, race 1 ) the plant nucleus moves towards and away from the invading hypha and eventually moves close to the fungus in the susceptible cultivar while it remains away in two cultivars which subsequently respond by resistance gene-dependent plant cell death (the hypersensitive response, HR). The role of plant cytoskeleton in these responses was investigated by fluorescent microscopy and treatments with anticytoskeletal drugs. Observations of microtubule organization prior to cell death revealed that the sequence of events leading to protoplast collapse differed between the two resistant cultivars, suggesting a possibility of multiple pathways for cellular degradation during the HR. Different fixations produced two different microfilament patterns: a filament network and cables. Microfilament network remained visible even at later stages of cell death. Oryzalin and taxol reduced the incidence of autofluorescence that develops late in the death process, indicating a role of microtubules in the deposition of phenolics by adjacent living cells. Cell death and nuclear movements were not affected by oryzalin and taxol but were inhibited by cytochalasin E, suggesting that the microfilaments are required for the HR.     

Role of calcium in signal transduction during the hypersensitive response caused by basidiospore-derived infection of the cowpea rust fungus

The hypersensitive response (HR) of disease-resistant plant cells to fungal invasion is a rapid cell death that has some features in common with programmed cell death (apoptosis) in animals. We investigated the role of cytosolic free calcium ([Ca2+]i) in the HR of cowpea to the cowpea rust fungus. By using confocal laser scanning microscopy in conjunction with a calcium reporter dye, we found a slow, prolonged elevation of [Ca2+]i in epidermal cells of resistant but not susceptible plants as the fungus grew through the cell wall. [Ca2+]i levels declined to normal levels as the fungus entered and grew within the cell lumen. This elevation was related to the stage of fungal growth and not to the speed of initiation of subsequent cell death. Elevated [Ca2+]i levels also represent the first sign of the HR detectable in this cowpea-cowpea rust fungus system. The increase in [Ca2+]i was prevented by calcium channnel inhibitors. This effect was consistent with pharmacological tests in which these inhibitors delayed the HR. The data suggest that elevation of [Ca2+]i is involved in signal transduction leading to the HR during rust fungal infection.     

cDNAs generated from individual epidermal cells reveal that differential gene expression predicting subsequent resistance or susceptibility to rust fungal infection occurs prior to the fungus entering the cell lumen

As the cowpea rust fungus penetrates the wall of a cowpea epidermal cell, resistant and susceptible plants exhibit different ultrastructural and cytochemical changes within the epidermal protoplast. To examine plant gene expression at this stage of infection, cytoplasm was extracted from individual inoculated or uninoculated epidermal cells before the fungal penetration peg reached the cell lumen. Initial differential colony hybridization screening of an expressed sequence tag library constructed from globally amplified cDNAs generated from the inoculated resistant cells resulted in 80 clones (out of 835) with a differential hybridization pattern. Further slot-blot screening and screening of the amplified cDNAs generated from inoculated or uninoculated, resistant or susceptible cells revealed 28 separate genes, mostly with no matching sequences in the databases, that were up-regulated in response to the growth of the fungus through the wall of resistant or susceptible cells. Five genes, including those coding for beta- and alpha-tubulin, were found to be down-regulated specifically in inoculated, susceptible cells, and five were specifically up-regulated in inoculated, resistant cells, including a PR-10 homolog and a phenylalanine ammonia-lyase gene. Probing the amplified cDNAs from each cell type for the expression of cell death-related genes revealed that an LLS1 homolog (vuLLS1), cloned from cowpea, was up-regulated by infection in both resistant and susceptible cells and that a homolog of HSR203J was differentially up-regulated in resistant cells. These data show that changes in gene expression predicting the subsequent expression of susceptibility or hypersensitive resistance to fungal infection occur prior to the fungus entering the cell lumen.     

Defense Reactions in Host and Nonhost Plants Against the Soybean Rust Fungus (Phakopsora pachyrhizi Syd.)

Growth and development of two races of the soybean rust fungus (Phakopsora pachyrhizi Syd.) were compared on host and nonhost plants. Both groups had several lines of defense, each of which could stop a part of attacking uredospores. Germ tubes and appressoria were produced equally well on hosts and nonhosts. A reduced formation of penetration hyphae contributed to the resistance of nonhosts and resistant host genotypes. In the epidermal cells of wheat and barley leaves, lower frequencies of penetration hyphae coincided with the production of papillae-like structures which were not penetrated. The last line of defense of all nonhosts was localized in the epidermal cell where the growth of the penetration hyphae was arrested definitively. The colony development in these species was suppressed completely. In highly resistant host genotypes the last defense reaction occurred later as a hypersensitive cell collapse which interrupted the growth of the rust colony.     

Hypersensitive lignification response as the mechanism of non-host resistance of wheat against oat crown rust

Seven-day-old seedlings of the near-isogenic wheat ( Triticum aestivum L.) lines Prelude and Prelude-Sr5, susceptible and resistant to wheat stem rust, respectively, were inoculated with uredospores of the oat crown rust fungus Puccinia coronata Cda. f. sp. avenae Fraser & Led. Fluorescence microscopy revealed that the majority of colonies developed intercellular infection structures including haustorial mother cells and haustoria after penetration of wheat mesophyll cells. All penetrated cells became necrotic, and exhibited bright yellow autofluorescence. This autofluorescence was not extractable with alkali, and fluorescent cells stained positively with phloroglucinol/HCI, suggesting that hypersensitive cell death was correlated with cellular lignification. Accordingly, the lignin biosynthetic enzymes phenylalanine ammonia-lyase (EC4.3.1.5). 4-coumarate:CoA ligase (EC6.2.1.12), cinnamyl-alcohol dehydrogenase (EC1.1.1.149), and peroxidases (EC1.11.1.7) increased in activity during the expression of resistance. The induced pattern of peroxidase iso/ymes closely resembled that observed for highly incompatible wheat/wheat stem rust interactions. Furthermore, an elieitor was extracted from oat crown rust germlings. which induces lignification when injected into the intercellular space of wheat leaves. This elieitor appears to be functionally similar to that isolated from wheat stem rust germlings. The results suggest that the non-host resistance of wheat to the xenopara-site oat crown rust closely resembles the race/cullivar-speeific resistant mechanism of highly resistant wheat varieties to wheat stem rust.     

Cleavage of Nuclear DNA into Oligonucleosomal Fragments during Cell Death Induced by Fungal Infection or by Abiotic Treatments

It is often claimed that programmed cell death (pcd) exists in plants and that a form of pcd known as the hypersensitive response is triggered as a defense mechanism by microbial pathogens. However, in contrast to animals, no feature in plants universally identifies or defines pcd. We have looked for a hallmark of pcd in animal cells, namely, DNA cleavage, in plant cells killed by infection with incompatible fungi or by abiotic means. We found that cell death triggered in intact leaves of two resistant cowpea cultivars by the cowpea rust fungus is accompanied by the cleavage of nuclear DNA into oligonucleosomal fragments (DNA laddering). Terminal deoxynucleotidyl transferase-mediated dUTP nick end in situ labeling of leaf sections showed that fungus-induced DNA cleavage occurred only in haustorium-containing cells and was detectable early in the degeneration process. Such cytologically detectable DNA cleavage was also observed in vascular tissue of infected and uninfected plants, but no DNA laddering was detected in the latter. DNA laddering was triggered by [greater than or equal to]100 mM KCN, regardless of cowpea cultivar, but not by physical cell disruption or by concentrations of H2O2, NaN3, CuSO4, or ZnCl2 that killed cowpea cells at a rate similar to that of ladder-inducing KCN concentrations. These and other results suggest that the hypersensitive response to microbial pathogens may involve a pcd with some of the characteristics of animal apoptosis and that DNA cleavage is a potential indicator of pcd in plants.     

Accumulation of Autofluorogenic Compounds at the Penetration Site of Blumeria graminis f. sp. tritici is Associated with Both Benzothiadiazole-induced and Quantitative Resistance of Wheat

The effect of benzothiadiazole-7-carbothioic acid S-methyl ester (BTH; Bion^®) on the autofluorescence responses of adaxial epidermal cells, activity of phenylalanine ammonia-lyase (PAL) as well as fungal penetration efficiency were investigated after inoculation of the wheat cultivars Monopol (susceptible) and Zentos (resistant) with Blumeria graminis f. sp. tritici ( Bgt ). The frequency and intensity of autofluorescence at the Bgt -attempted penetration site were higher in epidermal cells of cv. Zentos than in those of the cv. Monopol. In both cultivars, foliar application of the resistance inducer BTH caused an intensification of the autofluorescent responses localized below the Bgt -appressoria (in papilla and halo). The frequency of Bgt -attacked epidermal cells showing whole-cell autofluorescence (hypersensitive cell death) was low in both cultivars and slightly enhanced by BTH only in cv. Monopol. Two peaks of PAL-activity were detected. The first occurred 4 hai coinciding with primary germ tube formation and the second at 12 hai during appressorium formation. BTH caused a significant increase of the PAL-activity at 12 and 18 hai in cv. Monopol. Increase in PAL-activity was closely associated with enhanced localized autofluorescence, suggesting that the phenomena are correlated. BTH-treatment markedly decreased the penetration efficiency of the powdery mildew fungus in cv. Monopol, but not in cv. Zentos which has high penetration resistance. The results suggest that enhanced PAL-activity and synthesis of autofluorogenic compounds, probably of phenolic nature, are involved in quantitative resistance and in BTH-induced defence mechanisms of wheat plants where they act to inhibit penetration of attacked cells.     

Microscopic Observation on the Development of Puccinia striiformis in the Spike and Stem of Wheat

The majority of germ tubes of the pathotype CYR32 of Puccinia striiformis f.sp. tritici formed on the surface of spike organs of the susceptible wheat cv. Suwon 11 penetrated through the stomatal pore, only a few germ tubes formed small appressoria over the stomata. In the lemma, palea and glume, the stripe rust fungus spread between the parenchyma cells close to the inner epidermal layer, but the fungus did not develop between the thick‐walled cells near the outer epidermal layer of these organs. In the awn and stem, spread of the stripe rust was confined to the intercellular spaces of the chlorophyll parenchyma, beneath the invaded stomatal pore of the epidermis and the urediniospores to be released disrupted the epidermis. In the caryopsis, the spread of hyphae was restricted to the intercellular spaces of the pericarp cells.     

Ultrastructural Study on the Interactions Between Three Respectively Different Disease- resistant Cucumber Cultivars and Phytophthora melonis

Ultrastructural changes during the process of interactions between three different diseaseresistant, susceptible, moderately resistant and resistant cucumber (Cucumis sativus L. ) cuhivars and Phytophthora melonis Katsura were respectively compared and the associated factors in the observed differences in colonization were determined. During the process of interaction in the susceptible cultivar, both inter- and intracellular growth of hyphae associated with extensive colonization of healthy hyphae and marked alteration of mesophyll cells, such as aggregation of cytoplasm and disintegration of cellular organelle were demonstrated. The general disorganization of host cell was observed in areas directly adjacent to the fungal hyphae and in cells several layers from the nearest visible hyphae. In the moderately resistant cultivar during interaction the host showed limited hypha growth with responses of resistance including 1 ) breakage of plasmodesmata to prevent the host cells to contact the hyphae, 2) increasing the quantity of endoplasmic reticulum and Golgi apparatus so as to increase the quantity of secretory protein, 3) a plasmalemma invagination containing granular material at the site in contact with the intercellular hyphae. The interaction in the resistant cuhivar was characterized as a hypersensitive reaction (HR) which means a rapid necrosis of the infected cells and the cells surrounding the invaded hyphae, resulting in death of the invaded hyphae. Formation of cell wall appositions right at the penetration sites of hyphae and haustorium-like structure was observed. The results indicate that the mechanism of host response to P. melonis invasion was differ- ent between the moderately resistant and the resistant cucumber cultivars.     

Cytological studies on rust fungi. (vi) fine structures of infection process of Kuehneola japonica (diet.) dietel

The behavior of rust fungi in their host plants has been elucidated by electron microscopy. However, most of the ultrastructural studies on rust fungi have focused on the uredial stage. In order to elucidate the features of the sporidial stage, we studied the fine structure of Kuehneola japonica, a short-cycle rust, in rose leaves. Infection pegs arising from appressoria penetrated the host walls. Papillae formed at the time of penetration against the outer epidermal cell walls. The papillae which had formed at the penetration sites grew extensively and partially surrounded the intracellular hyphae which were connected with the infection pegs. The intracellular hyphae in the epidermal cells developed further and entered adjacent parenchyma cells. Walls of parenchyma cells either invaginated or thin papillae formed at penetration sites and the invaginated walls or papillae surrounded the necks of the intracellular hyphae. Intracellular hyphae in both epidermal and parenchyma cells were not enveloped by the sheath before 20 days after inoculation. In specimens prepared 20 days after inoculation, some of the intracellular hyphae were enveloped by a sheath in both palisade and spongy parenchyma cells. The sheathed hyphae resembled haustoria of other rust fungi which had been described previously. Teliospore initials were formed in mycelial masses in intercellular spaces between the epidermal cells and palisade parenchyma cells 20 days after inoculation. Uninucleate teliospores developed from teliospore initials 30 days after inoculation.Contribution No. 32.     

水稻受稻瘟菌侵染后发病初期的细胞学反应

采用致病性不同的3个稻瘟菌株接种水稻IR64品种。结果显示：在抗性反应中,病菌接种后水稻细胞中形成原生质颗粒,逐渐向病菌侵入部位聚集;原生质浓缩及沉积的形成、细胞坏死与病菌侵染菌丝的受抑制在时间和空间上是一致的。在中度抗性反应中,原生质颗粒化的时间延迟。在感病反应中,尚未观察到水稻细胞质浓缩现象。病菌侵染后寄主细胞在蓝光激发下的自发荧光表明,在寄主细胞中有多酚类物质的产生和积累。抗性反应中稻瘟菌接种后多酚类物质产生早,荧光范围大而强;中度抗性反应中,多酚类物质产生迟,荧光范围小而弱;而在感病反应中,难以观察到寄主细胞的自发荧光。胼胝质、磷脂酶Dγ(phospholipase Dγ,PLDγ)产生和积累的趋势与多酚类积累的情况大致是相似的。不同互作类型寄主细胞中多酚类物质、胼胝质和PLDγ产生和积累的差异表明,这些物质在水稻的抗病性中起了重要作用。     

Nitric oxide and reactive oxygen species do not elicit hypersensitive cell death but induce apoptosis in the adjacent cells during the defense response of oat

Nitric oxide (NO) acts as a signaling molecule in many cellular responses in plants and animals. Oat plants (Avena sativa L.) evoke the hypersensitive response (HR), which shares morphological and biochemical features with mammalian apoptosis, such as DNA laddering and heterochromatin condensation, in response to the avirulent crown rust fungus (Puccinia coronata f. sp. avenae). We examined the role of NO and reactive oxygen species (ROS) in the initiation of hypersensitive cell death, which is induced by direct contact with the pathogen, and apoptotic cell death in the adjacent cells. Cytofluorimetric analysis using the fluorescent NO probe DAF and the H2O2 probe DCF demonstrated that NO and H2O2 were generated simultaneously in primary leaves at an early stage of the defense response. The NO scavenger 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (cPTIO) markedly enhanced H2O2 accumulation detected by 3,3-diaminobenzidine staining and DCF, whereas treatment with the NO donor S-nitroso-N-acetylpenicillamine (SNAP) strongly suppressed it. Superoxide dismutase (SOD) increased NO accumulation, suggesting that endogenous NO may modulate the level of H2O2 by interacting with O2- in the HR lesion. Cytological observation showed that administration of cPTIO, SNAP, or SOD had no effect on elicitation of hypersensitive cell death, but clearly reduced heterochromatin condensation in the nearby cells and DNA laddering. These findings indicate that NO and ROS are not essential mediators for the initiation of hypersensitive cell death. However, NO and O2- but not H2O2 are required for the onset of apoptotic cell death in the adjacent cells, where excess NO may exert its anti-apoptotic function by regulating cellular redox state.     

Histology of Disease Development in Resistant and Susceptible Cultivars of Chickpea (Cicer arietinum L.) Inoculated with Spores of Ascochyta rabiei

Abstract Histological studies were performed on a compatible and an incompatible interaction between chickpea ( Cicer arietinum L.) plants and the fungus Ascochyta rabiei (Pass.) Labr. The time course of infection, development on leaflets and stems of susceptible (ILC 1929) and resistant (ILC 3279) plants was monitored by light or scanning electron microscopy with the aim to compare histological changes as the basis for further work on biochemical changes in this plant-pathogen interaction.
Spores of A. rabiei began to germinate from 12 hpi on and developed a polar germ tube; fungal colonization, secretion of a mucilaginous exudate and appressoria formation (1–3 dpi) were identical on both cultivars. Leaves of susceptible plants were invaded by the fungus directly through the cuticle, the fungus then spread subepidermally followed by a rapid collapse of the leaf tissue (4–6 dpi). Development of leaf spots and fungal pycnidia could be observed 6–8 dpi. The resistant cultivarrapidly responded (24–48 hpi) to fungal infection and cells of the palisade parenchyma exhibited autofluorescence. In later stages of the infection (4–5 dpi) fluorescent areas developed to small necrotic spots all over the leaflet. These necrotic areas, were the result of cell death and a subsequent change in the leaf structure and were characterized by the accumulation of phenolic compounds. Leaves of the resistant cultivar were invaded by the fungus to less than 5%.     

PR-1 protein inhibits the differentiation of rust infection hyphae in leaves of acquired resistant broad bean

Treatment of broad bean leaves with salicylic acid (SA) or 2, 6-dichloro-isonicotinic acid (DCINA) induces resistance against the rust fungus Uromyces fabae resulting in reduced rust pustule density. Light-microscopy studies showed that in induced resistant plants the rust fungus is inhibited immediately after penetration through the stomatal pore. The differentiation of infection structures growing within the intercellular space of the leaf, i.e. infection hyphae and haustorial mother cells, is inhibited. Furthermore, low-temperature scanning electron microscopy studies of freeze fractures revealed protrusions at the tips of infection hyphae growing in induced resistant broad bean leaves. Treatment of in vitro-differentiating rust infection structures with intercellular fluids (IFs) from induced resistant plants confirmed that the fungus is sensitive towards an apoplastic anti-fungal activity only after having formed appressoria. Other legume rusts such as U. vignae and U. appendiculatus were likewise inhibited in the presence of IF from SA-treated broad bean leaves. Heterologous antibodies were used to study changes in the extracellular pathogenesis-related (PR) protein pattern after resistance induction. Western blots indicated that chitinases and beta-1,3-glucanases were present in both induced and control plants. In contrast, PR-1 proteins were newly synthesized in response to SA or DCINA application. The major induced PR-1 protein was purified and exhibited strong differentiation-inhibiting activity towards U. fabae infection structures. We conclude that the inhibition of rust infection hyphae in acquired resistant broad bean plants is mainly due to the anti-fungal activity of this induced basic PR-1 protein.     

Activation of Cysteine Proteases in Cowpea Plants during the Hypersensitive Response-A Form of Programmed Cell Death

There is increasing evidence that the hypersensitive response during plant–pathogen interactions is a form of programmed cell death. In an attempt to understand the biochemical nature of this form of programmed cell death in the cowpea–cowpea rust fungus system, proteolytic activity in extracts of fungus-infected and uninfected cowpea plants was investigated, using exogenously added poly(ADP-ribose) polymerase as a marker. Unlike the proteolytic cleavage pattern of endogenous poly(ADP-ribose) polymerase in apoptotic animal cells, exogenously added poly(ADP-ribose) polymerase in extracts of fungus-infected plants was proteolytically cleaved into fragments of molecular masses 77, 52, 47, and 45 kDa.In vitroandin vivoprotease inhibitor experiments revealed the activation of cysteine proteases, and possibly a regulatory role, during the hypersensitive response.     

Characterization of nonhost resistance of Arabidopsis to the Asian soybean rust

Asian soybean rust (ASR), caused by Phakopsora pachyrhizi, is a devastating disease of soybean. We report the use of the nonhost plant Arabidopsis thaliana to identify the genetic basis of resistance to P. pachyrhizi. Upon attack by P. pachyrhizi, epidermal cells of wild-type Arabidopsis accumulated H2O2, which likely orchestrates the frequently observed epidermal cell death. However, even when epidermal cell death occurred, fungal hyphae grew on and infection was terminated at the mesophyll boundary. These events were associated with expression of PDF1.2, suggesting that P. pachyrhizi, an ostensible biotroph, mimics aspects of a necrotroph. Extensive colonization of the mesophyll occurred in Arabidopsis pen mutants with defective penetration resistance. Although haustoria were found occasionally in mesophyll cells, the successful establishment of biotrophy failed, as evidenced by the cessation of fungal growth. Double mutants affected in either jasmonic acid or salicylic acid signaling in the pen3-1 background revealed the involvement of both pathways in nonhost resistance (NHR) of Arabidopsis to P. pachyrhizi. Interestingly, expression of AtNHL10, a gene that is expressed in tissue undergoing the hypersensitive response, was only triggered in infected pen3-1 mutants. Thus, a suppression of P. pachyrhizi-derived effectors by PEN3 can be inferred. Our results demonstrate that Arabidopsis can be used to study mechanisms of NHR to ASR.     

Endocytosis of 1,3-β-glucans by broad bean cells at the penetration site of the cowpea rust fungus (haploid stage)

Te penetration hypha of basidiospore-derived infection structures of the cowpea rust fungus (Uromyces vignae Barclay) in epidermal cells of the nonhost, broad bean (Vicia faba L.), was studied with the electron microscope after high-pressure freezing and freeze substitution. After fungal invasion of the epidermis, a plug in the penetration hypha separated the infection structures on the cuticle from the intraepidermal vesicle of the fungus. The plug and the fungal cell wall reacted with a polyclonal 1,3-β-glucan antibody. The plug in the haploid stage seems to have a task similar to the septum formed in the diploid stage of the fungus. Around the penetration hypha, the plant wall stained darkly and a papilla was deposited by the plant. In the papilla, 1,3-β-glucans were labelled by a monoclonal and a polyclonal antibody. In the infected epidermal cell, clathrin-coated pits, coated vesicles, partially coated reticula and multivesicular bodies were found. The contents of the coated pits, coated vesicles, partially coated reticula and multivesicular bodies bound to monoclonal and polyclonal 1,3-β-glucan antibodies. Accumulation and uptake of this paramural material into the plant cell by endocytosis is concentrated at the fungal penetration site. It may influence the host-parasite interaction.     

Transient over-expression of barley BAX Inhibitor-1 weakens oxidative defence and MLA12-mediated resistance to Blumeria graminis f.sp. hordei

BAX Inhibitor-1 (BI-1) is a conserved cell death suppressor protein. In barley, BI-1 ( HvBI-1 ) expression is induced upon powdery mildew infection and when over-expressed in epidermal cells of barley, HvBI-1 induces susceptibility to the biotrophic fungal pathogen Blumeria graminis . We co-expressed mammalian pro-apoptotic BAX together with HvBI-1, and the mammalian BAX antagonist BCL-X_L in barley epidermal cells. BAX expression led to cessation of cytoplasmic streaming and collapse of the cytoplasm while co-expression of HvBI-1 and BCL-X_L partially or completely, respectively, rescued cells from BAX lethality. When B. graminis was attacking epidermal cells, a green fluorescent protein fusion of HvBI-1 accumulated at the site of attempted penetration and was also present around haustoria. Over-expression of HvBI-1 in epidermal cells weakened a cell-wall-associated local hydrogen peroxide burst in a resistant mlo -mutant genotype and supported haustoria accommodation in race-specifically resistant MLA12 -barley. HvBI-1 is a cell death regulator protein of barley with the potential to suppress host defence reactions.     

Primary fluorescence (Autofluorescence) of fruiting bodies of the wood-rotting fungusFomes fomentarius

Autofluorescence of fruiting bodies of the wood-rotting fungus Fomes fomentarius has been observed and is described among native macrofungi for the first time. The strongest yellow autofluorescence with blue excitation was displayed by pith sets, a weaker yellow, yellow-green to yellow-red fluorescence was due to generative thin-walled hyphae while the weakest yellow-reddish fluorescence was emitted by thick-walled skeletal hyphae (though their parts may emit a more intensive yellow fluorescence). This yellow, yellow-green to yellow-red autofluorescence was assessed to be more intensive than the emission described so far in bacteria and fungi (except for lysed hyphae of the fungus Trametes versicolor). With green excitation all F. fomentarius cells emitted strong red autofluorescence.     

Effect of Host Plant Resistance on Haustorium Formation in Cereal Rust Fungi

Haustoria of Puccinia triticina (wheat leaf rust fungus) and P. hordei (barley leaf rust fungus) were isolated from susceptible and partially resistant wheat lines, and susceptible, hypersensitive and partially resistant barley lines. Haustoria were counted and measured. The size of haustoria was similar in the partially resistant and susceptible genotypes but haustoria were smaller in the hypersensitive barley line L94+Pa7. The number of haustoria was reduced in both partially and hypersensitive lines when compared with susceptible ones. Therefore it seems that the reduction in the number of haustoria is a consequence of the resistance that can be attributable either to early abortion of infection units or reduced colony growth. The reduction of the number of haustoria was more pronounced in the adult plant stage.