Enhanced pathogenicity of Leptosphaeria maculans Pycnidiospores from paired co-inoculation of Brassica napus cotyledons with ascospores

BACKGROUND AND AIMS: Blackleg, caused by Leptosphaeria maculans, is a major disease of oilseed rape (Brassica napus) worldwide, including Australia. In most cases, the severity of the disease in the field is related to infections caused by airborne ascospores. In contrast, pycnidiospores originating from leaf and stem lesions and stubble are widely assumed to play only a relatively minor role in the epidemiology of blackleg. It is not clear whether, under certain conditions, pycnidiospores can cause severe disease in the field. The aim of the work reported was to determine if the pathogenicity of pycnidiospores is enhanced by paired co-inoculation of B. napus cotyledons with ascospores. METHODS: Three investigations were carried out under controlled-environment conditions using various L. maculans isolates and B. napus cultivars with different levels of host resistance to blackleg. KEY RESULTS: In all three experiments, co-inoculation with ascospores increased the ability of pycnidiospores to cause more disease on B. napus than when inoculations consisted of pycnidiospores alone. This effect was significantly influenced by the host resistance of the cultivar, but overall was independent of the L. maculans isolate used in the different experiments. This effect was also independent of timing of inoculation with the ascospores, with increased disease from pycnidiospores occurring on the cotyledon of the seedling in situations where inoculations with ascospores were carried out 0, 1 or 2 d after pycnidiospore inoculation. This enhanced pathogenicity of pycnidiospores was evident even when low concentrations of pycnidiospores were applied to the other cotyledon of the same seedling. CONCLUSIONS: These results may explain continuing severe blackleg disease cycles throughout the cropping season even when ascospore fallout was low or constrained only to a brief period or phase of the cropping season, and suggest that disease epidemics may be polycyclic rather than monocyclic.     

Life-history ofNeurospora intermedia in a sugar cane field

The life-history ofNeurospora in nature has remained largely unknown. The present study attempts to remedy this. The following conclusions are based on observation ofNeurospora on fire-scorched sugar cane in agricultural fields, and reconstruction experiments using a colour mutant to inoculate sugar cane burned in the laboratory. The fungus persists in soil as heat- resistant dormant ascospores. These are activated by a chemical(s) released into soil from the burnt substrate. The chief diffusible activator of ascospores is furfural and the germinating ascospores infect the scorched substrate. An invasive mycelium grows progressively upwards inside the juicy sugar cane and produces copious macroconidia externally through fire- induced openings formed in the plant tissue, or by the mechanical rupturing of the plant epidermal tissue by the mass of mycelium. The loose conidia are dispersed by wind and/or foraged by microfauna. It is suggested that the constant production of macroconidia, and their ready dispersal, serve a physiological role: to drain the substrate of minerals and soluble sugars, thereby creating nutritional conditions which stimulate sexual reproduction by the fungus. Sexual reproduction in the sugar- depleted cellulosic substrate occurs after macroconidiation has ceased totally and is favoured by the humid conditions prevailing during the monsoon rains. Profuse micro-conidiophores and protoperithecia are produced simultaneously in the pockets below the loosened epidermal tissue. Presumably protoperithecia are fertilized by microconidia which are possibly transmitted by nematodes active in the dead plant tissue. Mature perithecia release ascospores in situ which are passively liberated in the soil by the disintegration of the plant material and are, apparently, distributed by rain or irrigation water.     

湖南地区茯砖茶中金花菌的分离鉴定

对湖南地区茯砖茶上＂金花菌＂的菌落特征、形态特征进行了研究,并运用扫描电镜观察了其子囊孢子和分生孢子的发育过程,鉴定其为冠突散囊菌（Eurotium cristatum）。     

昆明地区印度块菌子囊果的解剖结构研究

通过印度块菌子囊果石蜡切片的显微观察,对印度块菌子囊果包被及子实层的显微结构、子囊及子囊孢子的发育过程进行研究.结果表明:(1)印度块菌子囊果是由包被和子实层构成,子囊果的表面密被大量大小不一的疣状突起,包被由外皮层和内皮层构成;子实层由封闭的、大小不一的产孢组织构成,在产孢组织中包含有侧丝、产囊丝、子囊和子囊内的子囊孢子;(2)成熟印度块菌子囊果横切面上有明暗相间的迷宫状纹脉;(3)子囊卵形,由产囊丝顶端的细胞发育而来;(4)成熟子囊孢子红褐色,椭圆形至近球形不等,子囊孢子双层壁,外壁密布有刺状纹饰.子囊孢子在子囊内的发育过程中常出现败育现象,每个成熟子囊中含有1～5个子囊孢子(常见4个).     

Formation and Development of Pseudothecia of Venturia nashicola

Conidia are believed to be the main source of primary inoculum for pear scab, caused by Venturia nashicola, in northern China. Experiments were conducted to investigate the development and potential role of V. nashicola ascospores in northern China. Leaves with pear scab lesions were collected from commercial orchards in November 2003 and 2004 to monitor pseudothecia formation under various environments. Pseudothecium production was shown to occur readily in northern China. The key requirement for pseudothecium production is the occurrence of rain during the winter and early spring, although the exact timing of these rain events appeared not to affect their development. Excess water may lead to the accelerated leaf decay and hence lead to production of fewer pseudothecia. More than 80% scabbed leaves, placed in a pear orchard, produced pseudothecia. Leaves with only non‐sporulating scab lesions in autumn were also able to produce a large number of pseudothecia. Both airborne ascospores and conidia of V. nashicola were caught in a pear orchard. Most ascospores were released by late‐May, a month after pear blossom. These results suggest that ascospores may play an important role in the early stage of pear scab epidemics in spring in northern China.     

印度东北部白垩纪-第三纪Xylariaceae化石孢子

在印度东北部白垩纪-第三纪沉积中发现了各种类型单沟无隔壁的Xylariaceae化石孢子,例如:Hypoxylonites,Spirotremesporites.Hypaxylonites等共计15种,其中6新种,它们是Hypoxylonites bhubanensis,H.elsikii,H.minimus,H.neogenicus,H.subrotundus和H.thindii,Hypoxylonites在本地区一般出现于晚白垩世地层中,占化石微体植物群总数的3%-4%,而在始新世它们的含量上升到植物群总数的20%-25%,从中新世直到早上新世这类孢子类型最多,含量最高,达植物群总数的40%-45%,到晚上新世含量突然下降,而Spirotremesporites在白垩纪未发现,到晚始新世时才出现,仅占孢粉总数的5%-6%,中新世时达25%-30%,到上新世末衰落,该属含5新种,Spirotremespores ellipticus,S.longilentus,S.miocenicus,S.reniformis,S.tertiarus.考虑到和这些种共生的Xylaria,Hypoxylon,Rosellinia及Daldina的孢子以及它们的地层分布,这类孢子的演化历史可能是受沉积盆地附近的古气候控制的.     

Symptoms and Prepenetration Events Associated with the Infection of Common Bean by the Anamorph and Teleomorph of Glomerella cingulata f.sp. phaseoli

Glomerella cingulata f.sp. phaseoli and Colletotrichum lindemuthianum are the teleomorph and anamorph, respectively, of the pathogen causing anthracnose in common bean. The mechanisms relating to the sexual reproduction of this plant pathogen are still unclear, as are the infection structures involved and the symptoms produced. In the present study, bean plants were inoculated with ascospores and conidia, and the events taking place within the following 120 h were investigated using light microscopy and scanning electron microscopy. The symptoms exhibited by plants inoculated with the ascospores were milder than in those inoculated with conidia. Microscopy revealed that most of ascospores produced germ tubes and appressoria at an early stage (24 h after inoculation). From 48 h onwards, the formation of hyphae and the production of germ tubes and appressoria were great. In contrast, infections originating from conidia developed more slowly, and at 24 and 48 h, many non‐germinated conidia were present, whereas only few conidia developed germ tubes and appressoria. Ascospore germination and appressorium formation were similar on both resistant and susceptible cultivars. Hence, the symptoms and the temporal sequence of events associated with the infection of bean plants by the two fungal forms differed, although the structures produced were similar. This is the fist report comparing symptoms and prepenetration events between anamorph and teleomorph of G. cingulata f.sp. phaseoli in common bean.     

Dissection of Saccharomyces Cerevisiae Asci

Yeast is a highly tractable model system that is used to study many different cellular processes. The common laboratory strain Saccharomyces cerevisiae exists in either a haploid or diploid state. The ability to combine alleles from two haploids and the ability to introduce modifications to the genome requires the production and dissection of asci. Asci production from haploid cells begins with the mating of two yeast haploid strains with compatible mating types to produce a diploid strain. This can be accomplished in a number of ways either on solid medium or in liquid. It is advantageous to select for the diploids in medium that selectively promotes their growth compared to either of the haploid strains. The diploids are then allowed to sporulate on nutrient-poor medium to form asci, a bundle of four haploid daughter cells resulting from meiotic reproduction of the diploid. A mixture of vegetative cells and asci is then treated with the enzyme zymolyase to digest away the membrane sac surrounding the ascospores of the asci. Using micromanipulation with a microneedle under a dissection microscope one can pick up individual asci and separate and relocate the four ascopores. Dissected asci are grown for several days and tested for the markers or alleles of interest by replica plating onto appropriate selective media.     

Temperature and leaf wetness duration affect phenotypic expression of Rlm6-mediated resistance to Leptosphaeria maculans in Brassica napus

Near-isogenic Brassica napus lines carrying/lacking resistance gene Rlm6 were used to investigate the effects of temperature and leaf wetness duration on phenotypic expression of Rlm6-mediated resistance. Leaves were inoculated with ascospores or conidia of Leptosphaeria maculans carrying the effector gene AvrLm6. Incubation period to the onset of lesion development, number of lesions and lesion diameter were assessed. Symptomless growth of L. maculans from leaf lesions to stems was investigated using a green fluorescent protein (GFP) expressing isolate carrying AvrLm6. L. maculans produced large grey lesions on Darmor (lacking Rlm6) at 5-25 degrees C and DarmorMX (carrying Rlm6) at 25 degrees C, but small dark spots and 'green islands' on DarmorMX at 5-20 degrees C. With increasing temperature/wetness duration, numbers of lesions/spots generally increased. GFP-expressing L. maculans grew from leaf lesions down leaf petioles to stems on DarmorMX at 25 degrees C but not at 15 degrees C. We conclude that temperature and leaf wetness duration affect the phenotypic expression of Rlm6-mediated resistance in leaves and subsequent L. maculans spread down petioles to produce stem cankers.     

Two new species of Kazachstania that form ascospores connected by a belt-like intersporal body: Kazachstania zonata and Kazachstania gamospora

Four strains of ascomycetous yeasts were isolated from samples collected at two locations in southern Japan. The strains formed two warty ascospores that were joined together by an intersporal body appearing as a belt. Phylogenetic analysis of rRNA gene nucleotide sequences indicated that the strains represented two new and closely related species of the genus Kazachstania. Isolates of one of the species were from Miyazaki Prefecture and those of the other species were from the Iriomote Islands. Genetic separation of the two species was further confirmed by DNA-DNA reassociation, which gave values of 63.3-78.1%, and from interspecific crosses, which gave nonviable ascospores. On the basis of these data, the isolates from Miyazaki Prefecture are described as Kazachstania zonata sp. nov. [type strain NBRC 100504=CBS 10326, mating types NBRC 101821 (+), NBRC 101822 (-)], and the isolates from the Iriomote Islands are described as Kazachstania gamospora sp. nov. [type strain NBRC 11056=CBS 10328, mating types NBRC 101825 (+), NBRC 101826 (-)].