细胞和分子技术在甘薯茎线虫病抗病育种中的应用

甘薯茎线虫病是我国北方甘薯薯区的重要病害之一。为进一步研究甘薯茎线虫病育种中线虫和甘薯的抗感关系,利用细胞培养技术建立发根农杆菌转化甘薯发根,用该发根培养马铃薯腐烂线虫,构建植物寄生线虫培养和抗性鉴定的技术平台;用聚合酶链式反应(polymerase chain reaction,PCR)分子标记技术筛选甘薯茎线虫病抗感品种的分子标记,并对发根培养马铃薯腐烂线虫体系和分子标记辅助选择抗甘薯茎线虫病品种技术进行了展望。     

RNA干扰在植物抗根结线虫病基因工程应用中的研究进展

植物根结线虫病对农业生产的危害连年加重,以轮作和化学农药为主的传统防治难以满足现代农业生产的需要.以常规的抗性育种和表达外源蛋白为主的抗线虫转基因育种主要受限于抗性基因的匮乏.而近来RNA干扰技术的应用为抗线虫基因工程带来新的突破,通过构建RNA干扰载体,在转基因植物中表达寄生线虫重要基因的dsRNA或siRNA,并经口针取食被导入线虫体内,并引发线虫的系统性RNA干扰反应,导致其出现寄生、发育、代谢、运动等障碍甚至致死,从而使转基因植物实现对寄生线虫的抗性.本文综述了RNAi介导的抗根结线虫基因工程方面的研究进展,分析探讨了这种新的策略的特点并展望了它的应用前景.     

番木瓜和西番莲根结线虫病记述

本文对番木瓜根结线虫病和西番莲根结线虫病的症状作了描述。病原线虫经鉴定确认,侵染番木瓜的虫种为南方根结线虫(Meloidogneincognita),侵染西番莲的根结线虫是由南方根结线虫、高弓根结线虫(M. acrita)和花生根结线虫(M. arenaria)3个种组成的混合群体,南方根结线虫为优势种。     

水稻茎线虫病研究进展

水稻茎线虫病是水稻主要病害之一,能造成水稻严重减产。在我国水稻茎线虫属于检疫对象。该病害在孟加拉国、印度及缅甸等危害严重。本文结合国内外研究现状,从水稻茎线虫病原、形态、分布、症状等方面综述了水稻茎线虫病的研究进展,以期为我国开展检疫和防治提供参考。     

植物内生真菌防治根结线虫研究进展

根结线虫病是对农作物危害严重且难以防治的病害，并随着我国设施农业的发展日趋严重。常规的化学防治方法因毒性大、破坏生态环境而不适应农业的可持续发展。作为一种能稳定寄生在作物体内的生物防治真菌，内生真菌通过抑制卵的孵化、降低J2期线虫幼虫活力、抑制线虫的入侵、延缓雌虫发育、减少产卵数目、降低作物根中根结和卵块数量，来实现稳定、高效、安全地防治根结线虫病害。近年来，内生真菌的作用机制得到广泛关注和研究，取得了显著进展。本文综述近年来内生真菌生物防治根结线虫机制的研究进展，总结了内生真菌直接攻击、资源竞争、代谢物胁迫、防御激活等4种主要机制，探讨其存在的问题，以期为进一步开发、应用植物内生真菌进行生物防治提供帮助。     

湖南省平江县水稻根结线虫病发生及危害评价

[目的]进一步明确湖南省平江县水稻根结线虫病发生危害情况、病原线虫种类及影响水稻发病的因素。[方法]2020年4—6月,采用5点取样法对湖南省平江县24个乡镇400块田块的水稻根结线虫病发生危害情况进行再调查及病原种类鉴定,并对水稻根结线虫病的病情指数与水稻的栽培方式、土壤类型之间的关系进行了分析。[结果]平江县水稻根结线虫病的发生较为普遍,发现病害的乡镇已由2018年的5个增加到2020年的15个,其中15个乡镇的病田率为10%~100%,病株率为2%~55%,根结指数为0.4~15.4。分离获得的病原线虫种类均为拟禾本科根结线虫。调查还发现,发病水稻在砂壤、中壤、重壤稻田的根结指数明显高于在黏土和轻壤稻田的根结指数,直播、抛秧栽培方式下发病水稻的根结指数明显高于移栽方式下的根结指数。[结论]平江县水稻根结线虫病呈蔓延趋势。本研究为有效防控平江县水稻根结线虫病提供了依据。     

蓖麻提取物和淡紫拟青霉对南方根结线虫的防治作用

通过杀线活性测定及盆栽试验,研究了蓖麻提取物和淡紫拟青霉(Paecilomyces lilacinus)对南方根结线虫(Meloidogyne incognita)的杀线活性及防治效果.结果表明:蓖麻碱不影响淡紫拟青霉孢子的萌发.蓖麻碱和淡紫拟青霉均具有较强杀线活性,蓖麻碱处理对南方根结线虫的卵孵化抑制率和二龄幼虫死亡率分别达61.7%和59.2%,显著高于对照处理;蓖麻碱和孢子液复合处理接种南方根结线虫的番茄苗后,植株平均根结数为15±3,显著低于对照的平均根结数37±2,株高、鲜重和根长增长率分别比对照提高38.5%、44.0%和57.0%.说明蓖麻提取物和淡紫拟青霉能减轻线虫危害,对番茄南方根结线虫病控制效果明显.     

丛枝菌根真菌对不同番茄品种抗根结线虫病的影响

【背景】根结线虫病害严重制约我国设施蔬菜的生产。丛枝菌根真菌(Arbuscular Mycorrhizal Fungi,AMF)作为土壤中最重要的有益真菌之一,可以促进植物生长,提高植物抗病性,减轻土传真菌和线虫病害的发生。在蔬菜保护地栽培中,AMF对于植物线虫病防治作用的研究受到了广泛关注。【目的】针对番茄生产中危害最严重的南方根结线虫(Meliodogyne incognita)病害问题,研究AMF和番茄品种不同组合的抗线虫效应,以期为菌根真菌作为生物防治剂和生物菌肥应用于实际生产提供技术基础。【方法】在灭菌土壤中,人工接种根结线虫,比较不同菌种Rhizophagus intraradices(Ri)、Acaulosporamellea(Am)及菌种组合Rhizophagusintraradices+Acaulosporamellea(Ri+Am)在不同番茄品种(感病品种蒙特卡罗和抗线虫品种仙客1号)上对南方根结线虫侵染和繁殖的影响,研究AMF对根结线虫的拮抗效应。另外,采用南方根结线虫连作发病的土壤,在感病品种蒙特卡洛上接种AMF混合菌种Ri+Am,番茄苗移栽入连作土壤中,测定各生长指标和调查根结和卵块数量,评价接种AMF处理对根结线虫病的防治效果。【结果】在灭菌土壤中,普通番茄品种蒙特卡罗的菌根效应显著优于抗线虫番茄品种仙客1号,表现为前者单位根重的根结和卵块的数量均比对照显著降低,而后者仅降低了卵块数量;蒙特卡罗上接种Ri+Am混合菌种的效果优于接种单一菌种Am和Ri;而仙客1号上接种Ri的效果更好。接种线虫也显著影响了AMF的侵染,而且对抗性品种仙客1号的影响更为明显。但除了接种Am的处理,大多数处理收获时菌根侵染率仍维持较高的水平(70%以上)。在连作土壤中,感病品种蒙特卡罗接种混合菌种Ri+Am具有较好的抗/耐线虫效应,主要表现为促进植株生长,显著降低根结和卵块数量,但菌根侵染率较灭菌土壤低,约为40%。【结论】综合以上结果,表明菌根化苗能够在一定程度上减轻根结线虫病的危害。土壤灭菌条件下,在感病和抗线虫番茄品种上接种AMF能够减轻线虫的侵染和繁殖,而且在感病品种上的防治效果更加显著。在连作土壤中,在番茄感病品种上接种AMF也表现较好的抗线虫效果。     

根结线虫毒性群体及其遗传变异机理研究进展

根结线虫是危害农业生产的主要病原物,应用抗性品种控制根结线虫是有效而安全的策略。然而,新的毒性线虫群体能够克服其抗性,对农业生产具有巨大潜在威胁。现分析了根结线虫的毒性种群的多样性、适应性代价及侵染特性,并从基因组可塑性、基因水平转移、转座子、表观遗传及效应子方面分析了遗传变异机制,最后论述了毒性根结线虫检测技术及防治策略,将为抗性品种的选育、抗性基因的持久利用提供重要理论依据。     

杨梅根结线虫病及其病原鉴定

本文报道对杨梅根结线虫病的研究及病原鉴定结果。该病症状为:病树根部形成大小不一的根结,内有乳白色囊状雌虫及棕色卵囊;后期根结腐烂,病树叶片黄化脱落,梢枯乃至死亡。病原鉴定确认,引起该病的根结线虫有3个种:爪哇根结线虫(Meloidogyne javanica)、南方根结线虫(M.incognita)和北方根结线虫(M. hapla)。爪哇根结线虫为优势种。     

亚低温条件下防控番茄南方根结线虫生防菌株的筛选与鉴定

【目的】筛选亚低温条件下抗线虫和促进植物生长发育的菌株。【方法】采用线虫击倒率测定、室内耐低温测定、拮抗测试和盆栽生物测定相结合的方法进行功能菌株的筛选;采用表型特征、生理生化特征、16S r RNA基因序列测定相结合的多相分类技术对筛选的菌株进行鉴定。【结果】从根结线虫多发的设施黄瓜和番茄病土中分离出细菌和放线菌297株;经对根结线虫击倒率的初步筛选,得到校正击倒率大于70%的活性菌株9株;通过复筛获得1株在亚低温条件下同时具有防线虫、防土传病原菌病、促生特性的生防菌株S205;菌株S205被鉴定为抗生素链霉菌(Streptomyces antibioticus)。【结论】获得一株在亚低温条件下同时具有抗线虫活性和促进植物生长发育的生防菌株S205,该研究对解决亚低温条件下根结线虫的防治具有重要意义。     

Response of Resistant and Susceptible Bell Pepper (Capsicum annuum) to a Southern California Meloidogyne incognita Population from a Commercial Bell Pepper Field

To determine the presence and level of root-knot nematode (Meloidogyne spp.) infestation in Southern California bell pepper (Capsicum annuum) fields, soil and root samples were collected in April and May 2012 and analyzed for the presence of root-knot nematodes. The earlier samples were virtually free of root-knot nematodes, but the later samples all contained, sometimes very high numbers, of root-knot nematodes. Nematodes were all identified as M. incognita. A nematode population from one of these fields was multiplied in a greenhouse and used as inoculum for two repeated pot experiments with three susceptible and two resistant bell pepper varieties. Fruit yields of the resistant peppers were not affected by the nematodes, whereas yields of two of the three susceptible pepper cultivars decreased as a result of nematode inoculation. Nematode-induced root galling and nematode multiplication was low but different between the two resistant cultivars. Root galling and nematode reproduction was much higher on the three susceptible cultivars. One of these susceptible cultivars exhibited tolerance, as yields were not affected by the nematodes, but nematode multiplication was high. It is concluded that M. incognita is common in Southern California bell pepper production, and that resistant cultivars may provide a useful tool in a nonchemical management strategy.     

南方根结线虫对不同砧木嫁接番茄苗活性氧清除系统的影响

采用盆栽人工接种方法,对番茄嫁接苗进行了抗性评价,研究了番茄嫁接苗叶片中抗氧化酶活性和活性氧代谢的动态变化。结果表明,接种南方根结线虫(J2)后,砧木嫁接苗表现为高抗,自根嫁接苗为高感。通过嫁接换根,与自根嫁接苗相比,砧木嫁接苗明显提高了接穗叶片的超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)和抗坏血酸过氧化物酶(APX)活性,降低了超氧阴离子(O.2-)产生速率以及过氧化氢(H2O2)和丙二醛(MDA)含量。表明番茄植株体内的活性氧水平和抗氧化酶活性的高低与其抗根结线虫的能力密切相关,较低的活性氧水平和较高的抗氧化酶活性有利于减轻对膜系统的伤害,提高番茄植株的抗根结线虫能力。     

红麻种质资源根结线虫病抗性鉴定

为鉴定我国红麻种质资源对根结线虫病的抗病性,在对120份红麻遗传资源进行田间自然发病鉴定的基础上,选择25份有代表性(22份高抗和3份感病)的种质进行盆栽根结线虫病接种鉴定。田间自然发病鉴定结果:120份红麻遗传资源中5个高感、19个中感、25个中抗、71个高抗;其侵染的根结线虫主要为南方根结线虫(Meloidogyne incognita)、爪哇根结线虫(Meloidogyne javanica)和花生根结线虫(Meloidogyne arenria)的混合种群。进行盆栽接种鉴定的25份遗传资源中,7份为中抗,其余分别为中感和高感品种,未发现高抗或免疫品种。本研究可为红麻种质资源发掘利用提供科学依据。     

Differential expression of root-knot nematode resistance genes in tomato and pepper: evidence with Meloidogyne incognita virulent and avirulent near-isogenic lineages

Reproduction of artificially selected near isogenic Meloidogyne incognita lineages virulent and avirulent against the Mi resistance gene of tomato was assessed on host and resistant lines and cultivars of pepper. Egg mass production following inoculation of individual potted seedlings with second-stage juveniles was studied in experiments conducted in controlled environment. Artificially selected Mi-virulent nematode populations were unable to develop on resistant pepper lines PM 217 and PM 687. This suggests that the genetic systems governing resistance to root-knot nematodes are differently expressed in tomato and pepper, in spite of the very close phylogenetic relationships and structural genomic homologies occurring between these two vegetable crops. Moreover, these artificially selected nematode populations were also found unable to develop on the susceptible pepper cultivars California Wonder and Doux Long des Landes, while their pathogenicity was not significantly affected on susceptible tomatoes. Due to the existence of naturally virulent Meloidogyne populations, these results enhance the need for a better understanding of the mechanisms involved, in order to develop new forms of management of plant resistance to root-knot nematodes.     

Heterologous expression of the Mi-1.2 gene from tomato confers resistance against nematodes but not aphids in eggplant

The Mi-1.2 gene in tomato (Solanum lycopersicum) is a member of the nucleotide-binding leucine-rich repeat (NBLRR) class of plant resistance genes, and confers resistance against root-knot nematodes (Meloidogyne spp.), the potato aphid (Macrosiphum euphorbiae), and the sweet potato whitefly (Bemisia tabaci). Mi-1.2 mediates a rapid local defensive response at the site of infection, although the signaling and defensive pathways required for resistance are largely unknown. In this study, eggplant (S. melongena) was transformed with Mi-1.2 to determine whether this gene can function in a genetic background other than tomato. Eggplants that carried Mi-1.2 displayed resistance to the root-knot nematode Meloidogyne javanica but were fully susceptible to the potato aphid, whereas a susceptible tomato line transformed with the same transgene was resistant to nematodes and aphids. This study shows that Mi-1.2 can confer nematode resistance in another Solanaceous species. It also indicates that the requirements for Mi-mediated aphid and nematode resistance differ. Potentially, aphid resistance requires additional genes that are not conserved between tomato and eggplant.     

<Emphasis Type="Italic">CaMi</Emphasis>, a root-knot nematode resistance gene from hot pepper (<Emphasis Type="Italic">Capsium annuum</Emphasis> L.) confers nematode resistance in tomato

Several root-knot nematode (Meloidogyne spp.) resistance genes have been discovered in different pepper (Capsium annuum L.) lines; however, none of them has yet been cloned. In this study, a candidate root-knot nematode resistance gene (designated as CaMi) was isolated from the resistant pepper line PR 205 by degenerate PCR amplification combined with the RACE technique. Expression profiling analysis revealed that this gene was highly expressed in roots, leaves, and flowers and expressed at a lower level in stems and was not detectable in fruits. To verify the function of CaMi, a sense vector containing the genomic DNA spanning the full coding region of CaMi was constructed and transferred into root-knot nematode susceptible tomato plants. Sixteen transgenic plants carrying one to five copies of T-DNA inserts were generated from two nematode susceptible tomato cultivars. RT-PCR analysis revealed that the expression levels of CaMi gene varied in different transgenic plants. Nematode assays showed that the resistance to root-knot nematodes was significantly improved in some transgenic lines compared to untransformed susceptible plants, and that the resistance was inheritable. Ultrastructure analysis showed that nematodes led to the formation of galls or root knots in the susceptible lines while in the resistant transgenic plants, the CaMi gene triggered a hypersensitive response (HR) as well as many necrotic cells around nematodes. Rugang Chen and Hanxia Li are contributed equally to this work.     

Characterization of Root-Knot Nematode Resistance in Medicago truncatula

Root knot (Meloidogyne spp.) and cyst (Heterodera and Globodera spp.) nematodes infect all important crop species, and the annual economic loss due to these pathogens exceeds $90 billion. We screened the worldwide accession collection with the root-knot nematodes Meloidogyne incognita, M. arenaria and M. hapla, soybean cyst nematode (SCN-Heterodera glycines), sugar beet cyst nematode (SBCN-Heterodera schachtii) and clover cyst nematode (CLCN-Heterodera trifolii), revealing resistant and susceptible accessions. In the over 100 accessions evaluated, we observed a range of responses to the root-knot nematode species, and a non-host response was observed for SCN and SBCN infection. However, variation was observed with respect to infection by CLCN. While many cultivars including Jemalong A17 were resistant to H. trifolii, cultivar Paraggio was highly susceptible. Identification of M. truncatula as a host for root-knot nematodes and H. trifolii and the differential host response to both RKN and CLCN provide the opportunity to genetically and molecularly characterize genes involved in plant-nematode interaction. Accession DZA045, obtained from an Algerian population, was resistant to all three root-knot nematode species and was used for further studies. The mechanism of resistance in DZA045 appears different from Mi-mediated root-knot nematode resistance in tomato. Temporal analysis of nematode infection showed that there is no difference in nematode penetration between the resistant and susceptible accessions, and no hypersensitive response was observed in the resistant accession even several days after infection. However, less than 5% of the nematode population completed the life cycle as females in the resistant accession. The remainder emigrated from the roots, developed as males, or died inside the roots as undeveloped larvae. Genetic analyses carried out by crossing DZA045 with a susceptible French accession, {"type":"entrez-protein","attrs":{"text":"F83005","term_id":"11352626","term_text":"pir||F83005"}}F83005, suggest that one gene controls resistance in DZA045.     

Problems and Strategies Associated with Long-term Use of Nematode Resistant Cultivars

Plant-parasitic nematodes are obligate parasites, and planting cultivars that are highly resistant to these organisms places extensive selection pressure on the target species and affects nontarget nematodes as well. Problems encountered with long-term planting of cultivars resistant to nematodes include shifts in nematode races or species and the occurrence of multiple species of nematodes within the same field. These problems can be alleviated to some extent when crop management is used to lessen the selection pressure for change on the nematode populations. Race shifts within populations and possibly shifts between nematode species can be delayed by rotating susceptible cultivars and nonhost crops with resistant cultivars. Nematicides in conjunction with resistant cultivars may be used to limit damage by multiple species of nematodes. Some cultivars have resistance to multiple species of nematodes, but greatly increased research effort is needed in this area. More intensive plant breeding effort will be required to make nematode resistant cultivars competitive in quality and yield with more productive, susceptible cultivars.     

The tomato Rme1 locus is required for Mi-1-mediated resistance to root-knot nematodes and the potato aphid

The tomato Mi-1 gene confers resistance against root-knot nematodes (Meloidogyne spp.) and a biotype of the potato aphid (Macrosiphum euphorbiae). Four mutagenized Mi-1/Mi-1 tomato populations were generated and screened for altered root-knot nematode resistance. Four independent mutants belonging to two phenotypic classes were isolated. One mutant was chosen for further analyzes; rme1 (for resistance to Meloidogyne) exhibited levels of infection comparable with those found on susceptible controls. Molecular and genetic data confirmed that rme1 has a single recessive mutation in a locus different from Mi-1. Cross-sections through galls formed by feeding nematodes on rme1 roots were identical to sections from galls of susceptible tomato roots. In addition to nematode susceptibility, infestation of rme1 plants with the potato aphid showed that this mutation also abolished aphid resistance. To determine whether Rme1 functions in a general disease-resistance pathway, the response against Fusarium oxysporum f.sp. lycopersici race 2, mediated by the I-2 resistance gene, was studied. Both rme1 and the wild type plants were equally resistant to the fungal pathogen. These results indicate that Rme1 does not play a general role in disease resistance but may be specific for Mi-1-mediated resistance.