Induced Resistance by the Toxin Filtrate of Bipolaris maydis Race T Cultivation

Resistance to maize southern leaf spot disease was induced by the low-concentration filtrate of Bipolaris maydis race T cultivation in an experiment. The nuclear neterogeny corn C103 was used as the test material. The lesion area on the leaves was significant difference by connalysis. The lesion areas on pretreated leaves were （0.3±0.05）- （0.9±0.5） mm^2, but those on the control were （23.1±8.7） mm^2. At the same time, the changes in peroxidase, phenylalanine, ammonialyase, and malondialdehvde activities were determined. During 0-96 h of inspection, phenylalanine and ammonialyase （PAL） activities increased by 64.2%, peroxidase （POD） activities increased by 41.2%, but the malondialdenvde （MDA） content decreased by 29.7% compared with the control. It seems that the low-concentration filtrate of Bipolaris maydis race T cultivation itself can be used as an elicitor to enhance the induced resistance.

Ambient Stresses Regulate the Development of the Maize Late Wilt Causing Agent, <i>Harpophora maydis</i>

Late wilt, a severe vascular disease of maize caused by the fungus Harpophora maydis, is characterized by relatively rapid wilting of maize plants before tasseling and until shortly before maturity. In Egypt and Israel, the disease is considered to be a major problem. The pathogen is currently controlled using cultivars of maize having reduced sensitivity, but the fungi can undergo pathogenic variations and become a threat to resistance cultivars as well. The abiotic and biotic factors influencing the infection and disease development are not fully determined. To impose stress in a uniform and chronic manner, we expose the Israeli H. maydis isolates colonies or spores to light, different pH, ionic and hyperosmotic pressures (induced with KCl or sorbitol) or oxygen-related stresses (induced with oxygen enrichment, menadione or peroxide). The optimum pH for both hyphal development and spore germination was pH = 5 - 6, similar to reports for the Egyptian, Indian and Hungarian isolates of H. maydis. In the hyperosmotic regime, hyphal growth was affected in a dosage-dependent curve. Although inoculation under high salt stress also inhibited spore germination, the spores were relatively resistant to this stress in comparison to the hypha. An opposite picture was revealed under menadione/peroxide stress: under high dosage of these compounds, the spore germination was virtually abolished while the colony growth was moderately affected. A daily oxygen enrichment of liquid medium cultures caused an increased growth in the pathogen wet and dry biomass, but daily double treatments led to growth suppression. These findings are a preliminary step towards the inspection of the fungal-host interaction under these different stressful environments. This is important for the future development of new strategies to restrict the disease burst and to protect field corps.

Diagnosis and Control of <i>Harpophora maydis</i>, the Cause of Late Wilt in Maize

Late wilt, a severe vascular disease of maize caused by the fungus Harpophora maydis, is characterized by relatively rapid wilting of maize plants, before tasseling and until shortly before maturity. In Israel, the disease becomes a major problem in recent years. The pathogen currently controlled using varieties of maize has reduced sensitivity. In earlier work, we modified a molecular method for use as a diagnostic tool to evaluate the disease progress in field infested plants. Several fungicides suppressed H. maydis in vitro and in a detached root pathogenicity assay. Seedling pathogenicity assay enables us to identified H. maydis DNA in the host root and stem tissues 18 days after sowing in both susceptible and tolerant maize plants. Although the infested plants exhibited no wilt symptoms, their roots were significantly shorter in length. This seedling assay was used to demonstrate the suppressive effect of the fungicide Flutriafol on H. maydis virulence. The method of assaying the pathogen in a series of trials starting in a plate assay, followed by a detached root and resulting in a seedlings pathogenicity assay, using molecular and morphological approaches could be generalized to other plant pathogens.

<i>Ustilago maydis</i>, a Delicacy of the Aztec Cuisine and a Model for Research

Ustilago maydis is the causal agent of the disease known as corn smut or Huitlacohe;their natural hosts are maize (Zea mays L.) and its putative ancestor teocintle (Zea mays ssp. parviglumis and ssp. mexicana). In México there is an evidence of its use as human food since pre-hispanic times. Huitlacoche is a typical Mexican food with interesting nutritional properties and distinctive flavor. Its use in cuisine is considered as a culinary delicacy in Mexico and several parts of the world and the current consumption is increasing markedly, mainly due to its exclusive flavor different from any other known food. Huitlacoche contains proteins, carbohydrates, fats, minerals and vitamins that contribute to its nutritional value, also it has been reported that it contains proteins with balanced levels of essential amino acids, something which does not occur in corn having a deficiency mostly in lysine. The fungus also contains compounds with antioxidant properties, consequently it can be included in what are now known as nutraceutical foods. Besides its use in the food, this fungus has been used in different kinds of basic investigation, such as DNA recombination, signaling, cell biology, biotrophic plant-pathogen interactions and others. Its characteristics of dimorphism, and the detailed knowledge we have on its pathogenic development, that we describe in detail, make it an ideal subject for the analysis of fungal differentiation, and for the knowledge of the behavior of the highly aggressive plant pathogens that are members of its taxonomic group, the Ustilaginales. In the present communication we make a thorough review of the nutritional characteristics of U. maydis, its life cycle, and the molecular bases of its differentiation, morpohogenesis and pathogenicity.

cDNA-AFLP analysis reveals that maize resistance to Bipolaris maydis is associated with the induction of multiple defense-related genes

The fungal pathogen Bipolaris maydis invades by direct penetration into maize leaf veins. In order to understand the resistance mechanism of maize to B. maydis strain 523, cDNA-AFLP (amplified fragment length polymorphism) analysis was conducted to compare the changes in mRNA transcripts hi response to B. maydis infection between a highly disease-resistant (HDR) line and a susceptible (S) line. 13 cDNA fragments derived from the genes showing enhanced expression after fungal infection, named HDR genes, were isolated from the HDR line. Northern blot analysis showed that 5 HDR genes were induced by fungal infection in the HDR, but not the S lines. The 5 HDR genes showed homology to previously characterized genes involved in disease resistance. A full-length HDR10 cDNA was isolated. It had a capacity to encode a protein of 284 amino acids. The deduced amino acid sequence of the HDR10 gene was homologous to a fungal infection-induced protein from Cicer arietinum and a hypersensitive response protein from

The pathogenic site of the C-toxin derived from Bipolaris maydis race C in maize (Zea mays)

Bipolaris maydis race C strain 523 (C523) induces severer leaf blight on cytoplasmic male sterility (CMS)-C maize than on normal (N) maize. Previously, a pathotoxin isolated from C523 (C-toxin) was shown to be responsible for the disease. To understand the basis of the differential responses between CMS-C and N maizes to this fungus, protein synthesis in vitro by mitochondria from N and CMS-C cytoplasms was monitored after their incubation in a solution containing the toxin (0.3%). Similar protein products were detected between the two alloplasmic lines, indicating that the toxin does not directly act on the mitochondrial membrane, nor inhibits the expression of mitochondrial genes. To further locate the action site of the toxin, intact leaves from both N and several subtypes of CMS-C lines were treated by 0.3% toxin. Analysis of electrolyte leakage of leaf cells showed that the leakage rates were similar to one another among the alloplasmic maize lines. In contrast, at a lower concentration of the

玉米须绞股蓝复合提取总黄酮工艺及其降压片的制备

以玉米须(stigma maydis)、绞股蓝(Gynostemma pentaphyllum)(1∶1)为提取原料,总黄酮含量为考察指标,通过提取溶剂、乙醇体积分数、提取温度、提取时间、料液比和提取次数等单因素考察对复合总黄酮含量的影响,再通过正交试验优化总黄酮的提取工艺,最后将优化提取的总黄酮过D101大孔吸附树脂精制后制备成降压片。结果表明,复方总黄酮的最佳提取工艺为乙醇体积分数50%,料液比1∶10,50℃下提取3.5 h。制备的片剂质量(片重差异±5.1%,脆碎度0.83%,崩解时限2.41 min)符合《中华人民共和国药典》(2020版)片剂的有关规定,并且降压片能降低SHR大鼠血压。

脱乙酰壳多糖抑制真菌生长的构效关系

本研究目标是研究脱乙酰壳多糖的化学结构(乙酰化程度DA和聚合程度DP)与它的抑制真菌生长能力之间的构效关系.选用了12个分属于3个系列、化学结构相关而又不同的、结构清晰的脱乙酰壳多糖和3种不同的真菌(Fusariumsolani,Fusariumgraminearum和Ustilagomaydis).通过分别测定每个脱乙酰壳多糖对3种真菌的生长曲线和最低抑制浓度(MIC,minimuminhibitoryconcentration);比较各个系列脱乙酰壳多糖的MIC和它的化学结构(DA和DP)之间的关系.结果显示对同一种真菌,不同脱乙酰壳多糖的抑制真菌生长曲线形态和MIC是各不相同的;同样同一脱乙酰壳多糖,对不同真菌也有其特殊的生长曲线和MIC;通常随着脱乙酰壳多糖中DA的递增,MIC是增加的,其抑制真菌的活性是降低的;在DA相同的条件下,随着DP的递增,MIC也是增加的,其抑制真菌的活性是减低的.所以可以说,脱乙酰壳多糖抑制真菌生长的能力与其化学结构紧密相关,在本实验的条件下,脱乙酰壳多糖分子越小,分子中的自由氨基越多,抑制真菌的活性越大.

河南省玉米小斑病菌生理小种鉴定及致病力分化

2013年从河南省4个地区采集玉米小斑病标样,对分离出的140个玉米小斑病菌菌株进行了生理小种鉴定和群体结构分析。结果表明,河南省玉米小斑病菌有T、C、S、O等4种生理小种,但各小种在地区间的分布存在差异,其中,O小种是河南省各玉米产区小斑病菌的优势小种,且在豫南分布最广泛,其次是C小种和S小种,T小种的比例最小。O小种具有不同致病力,强致病力菌株的出现频率较弱致病力菌株高,强致病力菌株主要分布在豫南地区,弱致病力菌株主要分布在豫北地区。

Identification of Antifungal Substance (Iturin A_2) Produced by Bacillus subtilis B47 and Its Effect on Southern Corn Leaf Blight

Bacillus subtilis B47 is an endophytic bacterium of tomato, and produces substance that strongly inhibits the growth of Bipolaris maydis, the pathogen of southern corn leaf blight （SCLB）, as well as several other phytopathogenic fungi. The antifungal substance was purified from the broth culture of the bacterium using acid precipitation, methanol extraction, and three-step chromatography. Based on FT-IR spectrometry, amino acid composition, and MALDI-TOF-MS/MS CID analyses, the antifungal substance was identified as iturin A2, a cyclic lipopeptide antibiotic. To evaluate the efficacy of iturin A2 for control of SCLB, partially purified iturin A2 （75%, w/v） was applied under different conditions. At the concentration of 300 mg kg-1, iturin A2 showed efficacy ranging from 100 to 53.1% under in vitro, in plot and in field conditions. This efficacy was higher than or similar to that of the fungicide chlorothalonil. When the concentration of iturin A2 was increased to 500 mg kg-1, the control efficacy was enhanced to 64.2% in field, which was significantly higher than that of chlorothalonil. These results indicate that iturin A2 has potential for SCLB control and could be a substitute to synthetic fungicides. To our knowledge, this is the first report on using partially purified iturin A for control of SCLB under field conditions.

Study on anti-fungal activity of nitrogen-doped TiO_2 nanophotocatalyst under visible light irradiation

Nitrogen-doped TiO_2 nanophotocatalysts were prepared,and characterized by XRD patterns and UV-vis spectroscopy.The results indicated that nitrogen was doped effectively and the shift of the absorption edge to a lower energy and a stronger absorption in the visible light region were observed.The calcinations temperature is a key factor to narrow the band gap of titania,and consequently affects the response to visible light of nitrogen-doped TiO_2 nanocrystals.This photocatalyst can effectively inhibit the g...

Interaction Between Heficoverpa zea Damage with Corncob Diseases on Genetically Modified Corn in Sinaloa, México

GM （genetically modified） corn with the CrylAb, mCry3A and Vip3Aa20 protein of Bt （Bacillus thuringiensis） and its respective isoline as control with and without chemical control for corn earworm were used in this research. Fusarium corncob damage was lower on GM corn with （12.5%） and without （25.7%） insecticide treatment as compared with the isoline that had 48.3% and 83.1% of damaged corncobs with and without chemical control, respectively. Corn smut cob damage was also lower on GM corn with （3.2%） and without （6.3%） insect control compared with 15.5% and 49.7% damage with and without insecticide treatment, respectively. Fusarium sp. corncob rot was also lower on GM corn with 5.7% and 9.5% whereas a 24.6% and 63% rot was observed on the isoline with and without insecticide control, respectively. Ustilago maydis severity was also lower on Bt corn finding 0.07% and 0.25% damage on treatments with and without insect control as compared with the isoline that showed an 11.6% and a 41.4% smut rot with and without insecticide treatment, respectively. The authors conclude that GM corn resistant to Helicoverpa zea prevents damage by the pest, eliminating the entrance pathway for Fusarium sp. and Ustilago maydis.

First Report on the Presence of Phyllachora sp. in Corn Crops at Toluca, Estado de Mexico

Symptoms of Tar Spot Complex (TSC) in corn appear in the form of black spots surrounded by a chlorotic halo known as fish-eye. The crop with these symptoms was found at San Pablo Autopan, Estado de Mexico. The stromal region of foliar lesions was cut longitudinally, showing perithecia, asci and ascospores typical of Phyllachora maydis. The results were confirmed by PCR-ITS with ITS 1 and ITS4 initiators, cloned by pJET, before being sequenced and compared against NCBI’s data base. Phyllachora identity was confirmed. This is the first report where TSC pathogen has been detected under conditions that had not been previously reported, for instance, at 2600 meters above the sea level.

玉米瘤黑粉菌的寄生策略及其调控机制

玉米瘤黑粉病是由担子菌Ustilago maydis对玉米的活体寄生所引起的真菌病害。该病原菌为双相型真菌,需要寄生于玉米植株来完成其有性生殖过程。综合相关研究报道,本文把U.maydis对寄主植物的寄生过程划分为7个阶段,包括形成致病性双核菌丝体、附着寄主植物表面、穿透寄主表皮、消减寄主防御反应、在寄主体内菌丝增殖、使寄主瘤变和生成厚垣孢子等。围绕寄生进程特点和关键基因,分别阐述了各个阶段的相关调控机制以及对寄主植物的致病性;展现了U.maydis为达到有性生殖目的而实施步步为营的寄生策略。本文对U.maydis寄生过程的阶段划分,有助于人们深入了解U.maydis与寄主植物之间互作机制、提供相关病害防控新思路。

玉米小斑病菌中一种维多利亚病毒的分离及其基因组全序列分析

从玉米小斑病菌(Bipolaris maydis)中检测发现一种dsRNA(double-stranded RNA)病毒,暂命名为Bipolaris maydis victorivirus 2(BmV2)。电子显微镜下观察到病毒粒子为二十面体球状,直径为40 nm左右、无包膜;病毒基因组为单条dsRNA核酸分子,长度为5222 bp,其基因组结构与其他维多利亚病毒相似,包含两个开放阅读框(ORFs)。序列BLASTx分析发现,BmV2的基因组核酸序列与Coniothyrium minitans RNA virus Illinois isolate(CmRV-IL)具有较高的同源性(78.15%),后者CmRV-IL是单分体病毒科(Totiviridae)维多利亚病毒属(Victorivirus)的暂定种,两者的外壳蛋白(CP)和RNA依赖性RNA聚合酶(RdRp)的氨基酸序列之间的同源性分别为88.02%和89.87%,说明BmV2、CmRV-IL是同一种病毒的不同分离物。基于BmV2和选择的单分体病毒的RdRp氨基酸序列的系统发育分析表明,BmV2与单分体病毒科维多利亚病毒属中的病毒形成了一个单系进化支。

Identification and Fine Mapping of rhm1 Locus for Resistance to Southern Corn Leaf Blight in Maize

rhml is a major recessive disease resistance locus for Southern corn leaf blight （SCLB）. To further narrow down its genetic position, F2 population and BCIFI population derived from the cross between resistant （H95rhm） and susceptible parents （H95） of maize （Zea mays） were constructed. Using newly developed markers, rhml was initially delimited within an interval of 2.5 Mb, and then finally mapped to a 8.56 kb interval between InDel marker IDP961-503 and simple sequence repeat （SSR） marker A194149--1. Three polymorphic markers IDP961-504, IDP B2-3 and A194149-2 were shown to be co-segregated with the rhml locus. Sequence analysis of the 8.56 kb DNA fragment revealed that it contained only one putative gene with a predicted amino acid sequence identical to lysine histidine transporter 1 （LHT1）. Comparative sequence analysis indicated that the LHT1 in H95rhrn harbors a 354 bp insertion in its third exon as compared with that of susceptible alleles in B73, H95 and Mo17. The 354 bp insertion resulted in a truncation of the predicted protein of candidate resistance allele （LHT1-H95rhm）. Our results strongly suggest LHTI as the candidate gene for rhml against SCLB. The tightly linked molecular markers developed in this study can be directly used for molecular breeding of resistance to Southern corn leaf blight in maize.

TOPLESS promotes plant immunity by repressing auxin signaling and is targeted by the fungal effector Naked1

In plants,the antagonism between growth and defense is hardwired by hormonal signaling.The perception of pathogen-associatedmolecularpatterns(PAMPs)frominvadingmicroorganismsinhibits auxin signalingand plant growth.Conversely,pathogens manipulate auxin signaling to promote disease,but how this hormone inhibits immunity is not fully understood.Ustilago maydis is a maize pathogen that induces auxin signaling in its host.We characterized a U.maydis effector protein,Naked1(Nkd1),that is translocated into the host nucleus.Through its native ethylene-responsive element binding factor-associated amphiphilic repression(EAR)motif,Nkd1 binds to the transcriptional co-repressors TOPLESS/TOPLESS-related(TPL/TPRs)and prevents the recruitment of a transcriptional repressor involved in hormonal signaling,leading to the derepression of auxin and jasmonate signaling and thereby promoting susceptibility to(hemi)biotrophic pathogens.A moderate upregulation of auxin signaling inhibits the PAMP-triggered reactive oxygen species(ROS)burst,an early defense response.Thus,our findings establish a clear mechanism for auxin-induced pathogen susceptibility.Engineered Nkd1 variants with increased expression or increased EAR-mediated TPL/TPR binding trigger typical salicylic-acid-mediated defense reactions,leading to pathogen resistance.This implies that moderate binding of Nkd1 to TPL is a result of a balancing evolutionary selection process to enable TPL manipulation while avoiding host recognition.

Influence of brown stink bug feeding, planting date and sampling time on common smut infection of maize

Phytopathogen infections are frequently influenced by both biotic and abiotic factors in a crop field. The effect of brown stink bug, Euschistus servus （Hemiptera： Pentatomidae）, feeding and planting date and sampling time on common smut （Ustilago maydis） infection percentage of maize plants was examined in 2005 and 2006, and 2010 and 2011, respectively. Brown stink bug adult feeding on maize hybrid ＂DKC6971＂ at flowering in 2005 and 2006 did not influence smut infection percentage when examined using 3 treatments （i.e., 0 adult, 5 adults, and 5 adults mixed with the smut spores）. The smut infection percentages were 〈 3% （n =12） in the 3 treatments. The smut infection percentage among the 4 weekly samplings was the same, so was natural aflatoxin contamination at harvest among the treatments. The 2nd experiment showed that planting date did not affect the smut infection percentage in either 2010 or 2011. But, the smut infection percentage from the postflowering sampling was greater than preflowering sampling in both years. The smut infection percentage varied among the germplasm lines in 2010, but not in 2011. This study demonstrated that brown stink bug feeding at flowering had no effect on smut infection in maize, and the best time for smut evaluation would be after flowering. The temperature and precipitation might have also influenced the percentage of smut-infected maize plants during the 4 years when the experiments were conducted. The similarity between kernel-colonizing U. maydis and Aspergillus flavus infections and genotype × environment interaction were also discussed.