内生真菌司氏角担子菌B6对尖孢镰刀菌西瓜专化型菌株的拮抗作用

近年来,尽管西瓜产业不断发展壮大,但轮作土壤种植西瓜易产生枯萎病害导致世界范围内的西瓜严重减产。通过对峙培养实验和抑菌实验探讨了重阳木内生真菌司氏角担子菌(Ceratobasidum stevensii)B6菌株对西瓜枯萎病病原菌尖孢镰刀菌西瓜专化型(Fusarium oxysporum f. sp.Niveum,FON)的拮抗作用,并初步分析了其作用机制。平板拮抗试验的结果表明,内生真菌B6生长过程中不是通过产生抑菌带来抑制FON菌丝,而是利用自身的生长优势将FON完全覆盖。显微观察B6与FON菌丝的接触部位,发现FON菌丝外侧附着B6顶端菌丝形成的胞样结构,表明FON菌丝生长仅受到B6菌丝的抑制。抑菌试验结果显示,B6产生的挥发性物质可以抑制FON的生长和产孢,并使其菌丝分枝明显减少;B6的发酵液对FON的生长和产孢没有抑制作用。因此,推测B6主要通过释放某些挥发性物质产生拮抗作用而抑制FON的生长。     

Development of a bioassay to assess resistance to Fusarium oxysporum (Schlecht.) in asparagus (Asparagus officinalis L.)

Fusarium oxysporum is one of the major pathogens causing root and crown rot in asparagus. Breeding of cultivars resistant to F. oxysporum would be the most efficient strategy for pathogen control. In this study, a bioassay was developed for screening seedling resistance. The non‐destructive bioassay comprises inoculation with a highly aggressive F. oxysporum isolate, incubation in a climate chamber and quantification of disease symptoms by a digital image analysing system and a PTA‐ELISA. This bioassay is simple to implement and demonstrated high reproducibility. Subsequently, it was used to determine the resistance behaviour of 16 asparagus genotypes to F. oxysporum. The asparagus cultivars revealed different levels of susceptibility, whereas the wild relative A. densiflorus was confirmed to be resistant.     

Irrigation and its effect on polyphagous shot hole borer attack

Polyphagous shot hole borer (PSHB), Euwallacea whitfordiodendrus (Schedl) (Coleoptera: Curculionidae, Scolytinae), is an ambrosia beetle that has recently invaded southern California, USA. This beetle successfully attacks and reproduces in a multitude of tree species. As direct control methods are limited, we investigated cultural management options, and sought to determine whether irrigation affects the number of attacks host trees experienced. If irrigation plays a role, cultural control methods could be recommended to managers and growers. Three separate experiments were conducted that monitored the number of attacks on trees with different levels of irrigation. Two experiments examined PSHB attacks in established landscape trees where irrigation was either present or absent. A third experiment used young potted box elder with irrigation controlled with timed emitters. In all three experiments, the level of irrigation received by the trees did not affect the number of attacks. The results suggest that changes in irrigation practices do not affect risk from PSHB attack.     

贵州玉米籽粒镰刀菌污染情况调查

【背景】镰刀菌引起的作物病害在贵州省内时有发生,由于该地区低温高湿的气候特征并不适宜镰刀菌生长,之前未系统开展镰刀菌侵染和分布情况调查。【目的】调查贵州省玉米籽粒中镰刀菌病害的污染情况。【方法】收集贵州省58个县/县级市的玉米籽粒样品78份,利用原核表达的可用于检测镰刀菌的Fv SG7-AP融合蛋白对样品进行快速免疫学检测,并对部分样品进行生物学培养鉴定。【结果】共有67份样品检测结果为阳性,污染率高达85.90%,生物学培养后显微镜观察到镰刀菌菌丝和孢子。检测出镰刀菌污染的玉米样品分布在贵州省51个县/县级市,其中19个地区检测到轻度污染样品,20个地区检测到中度污染样品,12个地区检测到重度污染样品。【结论】贵州省绝大部分地区存在不同程度的镰刀菌污染,有必要在作物耕种、收获及贮藏期间采取有效的防控措施,以保障食品安全与人畜健康。     

Weed species within cereal crop rotations can serve as alternative hosts for Fusarium graminearum causing Fusarium head blight of wheat

Fusarium graminearum is the main causal agent of Fusarium head blight (FHB) of small grain cereals, but the importance of weeds in the FHB disease cycle and the establishment of F. graminearum in agroecosystems are still not fully understood. The objective of this study was to determine the potential role of weeds present within cereal crop rotations as alternative hosts. F. graminearum was isolated from different organs of asymptomatic weeds sampled from six fields with cereal-crop rotations in Lithuania for two consecutive years (2015 and 2016). The fungi were identified using morphological and molecular methods. Out of 57 weed species that were investigated, 41 (71.9%) harboured F. graminearum isolates. Twenty five weed species were identified as new, previously undocumented, hosts. The majority (73.3%) of the isolates of F. graminearum from this study belonged to the 15ADON genotype while a smaller proportion (23.4%) belonged to the 3ADON genotype. All F. graminearum isolates that were assessed induced FHB symptoms on artificially inoculated spring wheat tested in the field.     

The plasma membrane H+-ATPase FgPMA1 regulates the development,pathogenicity, and phenamacril sensitivity of Fusarium graminearum by interacting with FgMyo-5 and FgBmh2

Fusarium graminearum, as the causal agent of Fusarium head blight (FHB), not only causes yield loss, but also contaminates the quality of wheat by producing mycotoxins, such as deoxynivalenol (DON). The plasma membrane H⁺-ATPases play important roles in many growth stages in plants and yeasts, but their functions and regulation in phytopathogenic fungi remain largely unknown. Here we characterized two plasma membrane H⁺-ATPases: FgPMA1 and FgPMA2 in F. graminearum. The FgPMA1 deletion mutant (∆FgPMA1), but not FgPMA2 deletion mutant (∆FgPMA2), was impaired in vegetative growth, pathogenicity, and sexual and asexual development. FgPMA1 was localized to the plasma membrane, and ∆FgPMA1 displayed reduced integrity of plasma membrane. ∆FgPMA1 not only impaired the formation of the toxisome, which is a compartment where DON is produced, but also suppressed the expression level of DON biosynthetic enzymes, decreased DON production, and decreased the amount of mycelial invasion, leading to impaired pathogenicity by exclusively developing disease on inoculation sites of wheat ears and coleoptiles. ∆FgPMA1 exhibited decreased sensitivity to some osmotic stresses, a cell wall-damaging agent (Congo red), a cell membrane-damaging agent (sodium dodecyl sulphate), and heat shock stress. FgMyo-5 is the target of phenamacril used for controlling FHB. We found FgPMA1 interacted with FgMyo-5, and ∆FgPMA1 showed an increased expression level of FgMyo-5, resulting in increased sensitivity to phenamacril, but not to other fungicides. Furthermore, co-immunoprecipitation confirmed that FgPMA1, FgMyo-5, and FgBmh2 (a 14-3-3 protein) form a complex to regulate the sensitivity to phenamacril and biological functions. Collectively, this study identified a novel regulating mechanism of FgPMA1 in pathogenicity and phenamacril sensitivity of F. graminearum.     

丛枝菌根真菌防治尖孢镰孢枯萎病的效应、机制及其应用研究进展

尖孢镰孢(Fusarium oxysporum)所引起的植物枯萎病是农业生产中广泛存在且难以防治的一种土传病害,严重影响作物的产量和品质。丛枝菌根(arbuscular mycorrhiza,AM)真菌能够与大部分陆生植物形成互惠共生关系,在促进植物生长、增强宿主植物抗病性等方面具有重要作用。本文收集整理了2001-2021年期间发表的相关文献,评述了AM真菌防治尖孢镰孢枯萎病的研究进展,并分析了AM真菌菌剂组成及应用方式对病害发生情况和尖孢镰孢丰度的影响。根据AM真菌在土壤-植物连续体的空间位置及其影响范围,从土壤、根系、植株等作用层面对AM真菌增强植物抵抗尖孢镰孢的直接和间接作用机制进行总结,包括影响土壤微环境、调节植物根际微生物群落结构、与病原菌竞争生态位、强化根系机械保护屏障、促进宿主植物养分吸收和生长、诱导植物系统性抗性等。此外,综合讨论了AM真菌与其他手段联合应用防治尖孢镰孢枯萎病的应用研究进展。本文可为推进AM真菌生物防治病害相关基础与应用研究的发展提供借鉴和参考。     

尖孢镰刀菌亚麻专化型Folprp4基因参与调控菌丝生长和分生孢子发生

目的: 通过对尖孢镰刀菌中Folprp4基因的鉴定,揭示其在尖孢镰刀菌中的功能及致病相关性。方法: 基于同源重组原理,根据测定出的Folprp4基因序列,应用Split-Marker重组技术构建含有潮霉素抗性基因(hph)的基因缺失盒。将基因缺失盒经PEG介导转化到野生型原生质体中,在含有潮霉素B的TCC培养基上筛选转化子,通过PCR正负筛查获得Folprp4基因缺失突变株(ΔFolprp4)。构建含有Folprp4基因的载体pZDH1,并将其转化到敲除突变体中进行互补测验。结果: 与野生型(hm)和异位插入突变体(ecFolprp4)相比,敲除突变体菌丝生长受到严重阻碍,当野生型和异位插入突变体长满整个平板时,敲除突变体菌落呈小点状。敲除突变体的另一个显著变化是ΔFolprp4的分生孢子产量显著下降。侵染实验表明,ΔFolprp4对亚麻幼苗的毒力显著降低。互补实验表明,该互补载体的回复子(Folprp4-C)在菌落形态、生长速率、分生孢子产量和毒力方面均恢复到了野生型菌株。结论: Folprp4基因与尖孢镰刀菌的菌丝生长、分生孢子发生和致病性有关。