部分中国栽培稻资源对稻瘟病的抗性分析

以苗期16个稻瘟病生理小种的抗谱测定以及成株期叶瘟、穗颈瘟鉴定结果为依据,分析了75份中国栽培稻稻瘟病抗性资源的抗瘟性。结果显示,不同抗性品种的抗谱以及对成株期叶瘟和穗颈瘟的抗性反应差异较大。相关分析表明,苗期抗谱测定结果与成株期叶瘟抗性显著相关,而与穗颈瘟,以及叶瘟与穗颈瘟间相关不显著。根据聚类分析结果,抗性资源可分成9个类群,其中以第6类群包含品种最多,抗谱最广(81.3%～100%),并高抗A、B、E、G群生理小种和抗穗颈瘟,可作为水稻稻瘟病抗性育种优先利用的种质资源。     

浙江省水稻新品种(系)对稻瘟病的抗性研究

用4个稻瘟病菌小种对浙江省280份水稻新品种(系)进行稻瘟病抗性分析,结果表明:浙江省水稻新品种(系)对稻瘟病菌具有较好的抗性,籼稻和粳稻对参试菌株的全抗率分别为21.62%和39.05%,说明粳稻具有较籼稻更广的抗谱;浙江省新品种(系)对ZB13小种具有较高的感病率,籼稻和粳稻的感病率分别为69.37%和52.07%。     

稻瘟病菌生理小种变化与水稻品种抗瘟性丧失之间的关系

本文根据近年稻瘟病菌生理小种鉴定研究结果,对生理小种变化与水稻品种抗瘟性丧失之间的关系进行了初步分析。(1)我省稻瘟病菌生理小种组成发生了变化。优势小种由1979—1982年的G群变为1983年后的B群小种;(1)品种的抗性随潜在致病力强的生理小种出现频率上升而降低;(3)伴随抗病品种种植面积比率的扩大,潜在致病小种迅速增殖,丧失抗性的危险性加大;(4)品种抗性随抗优势种群频率下降而降低。     

我国水稻当家品种对稻瘟病、白叶枯病的兼抗反应初探

用多个致病力不同的白叶枯病菌株,和全国10省12个研究单位提供的稻瘟病混合菌以及10个生产上常见的生理小种,于1987、1988年对全国种植面积达10万亩以上的145个水稻品种进行了抗白叶枯病谱、抗稻瘟病混合菌和生理小种测定。结果表明国际稻26、金早6号、金早7号、扬稻1号(BG910)、青华矮6号等21个品种能抗多个白叶枯病菌株和抗多个稻瘟病小种混合菌。对10个生理小种的抗谱率相差较大。     

黑龙江省部分育成大豆新品系抗大豆灰斑病鉴定

2004年采用混合生理小种,人工喷雾接种方法,对黑龙江省大豆新品系进行灰斑病鉴定筛选研究,从中鉴定出钢9491-2、九三97-40、绥98-6074等22份抗灰斑病资源材料,并建立了比较全面的抗性调查评价体系。     

黑龙江省不同来源稻瘟病菌致病性分析

将从黑龙江‘龙粳17’、‘吉特639’和‘垦稻10’病田中分离的9、8、8个稻瘟病菌菌株喷雾接种到4套鉴别寄主上,结果表明,中国稻瘟病菌生理小种鉴别寄主将这3个来源的菌株分别划分成8、7和4个生理小种,日本清泽鉴别品种则将其分别划分成9、8和8个生理小种,以黑龙江本地水稻品种作为鉴别品种,则可将其分别划分成8、7和5个致病型,以24个水稻抗稻瘟病单基因系为鉴别品种,则将上述菌株分别划分为9、7和8个致病型。     

水稻品种对稻瘟病菌不同小种的抗谱测定

 7群16个小种的20个稻瘟病菌株,对261份主要水稻栽培品种和新品系以及部份抗原进行了抗谱测定,结果如下。     

转基因水稻对稻瘟病的抗性研究

 采用苗期初筛、复筛、抗谱测定和田间自然诱发试验等不同鉴定方法,对经分子检测证明已整合有碱性几丁质酶基因和β-1,3-葡聚精酶基因的22个转化系的转基因水稻植株进行稻瘟病抗性鉴定研究,筛选出对稻瘟病的抗性比原种对照七丝软占有明显提高的一系列转基因水稻品系,其中表现高抗的有来自F4-9转化株系的7个品系。高抗材料的R7代品系,经室内抗谱测定及田间病圃试验结果,仍然表现高抗稻瘟病。本研究通过转基因技术,成功地将优质感病品种改良成高抗品系,研究结果证明了利用基因工程手段培育抗病水稻新品种是一个非常有希望的育种途径。     

水稻空间诱变育种抗稻瘟病研究

粤香占和青华占2个水稻品种的种子经过高空气球搭载后,选育出株型好、分蘖力强,产量提高的空间诱变高代(6代以上)品系.为了解空间诱变品系对稻瘟病的抗性变异情况,采用36个广东省稻瘟病菌不同致病型的代表菌株分别对粤香占和青华占及其空间诱变品系进行抗谱测定.研究结果表明:①空间诱变能使水稻品种产生稻瘟病抗性变异,有的诱变品系比原种抗病,有的则比原种感病.②空间诱变产生的抗病性变异比较复杂,不同品种的抗病性变异不一样.③空间诱变引起的稻瘟病抗性变异有可能是由多个抗病基因引起的.④空间诱变可以获得抗稻瘟病的特异种质.粤香占是感病品种,本研究测定的抗谱为25%,从其空间诱变品系中,获得高抗稻瘟病的2个品系YX-8和YX-9,抗谱达到94.4%.空间诱变抗病品系的穗颈瘟鉴定试验正在进行中.     

水稻稻瘟病菌小种间相对生存力研究

选用水稻稻瘟病菌ZA_(49)、ZD_3和ZE_3 3个小种,各2个小种为一组合,以等孢子量混合,于相同条件下在秀水620和秀水48两个感病品种上进行继代接种,经5个世代的转接结果表明:在秀水620上ZA_(49)小种较ZD_3和ZE_3小种具更强的致病力,在秀水48上,ZE_3小种较ZA_(49)和ZD_3小种具更强的致病力,同样其相对生存力也强,两者呈正相关。病菌小种间相对生存力的强弱与病菌小种在品种上单独接种时产生的病斑数、病斑大小和产孢量有关。相对生存力强的小种在病菌群体中易取得优势,从而导致寄主品种的病害量增加。因此认为小种间相对生存力差异也是影响水稻稻瘟病菌群体小种组成发生变化的因素之一。     

水稻纹枯病寄主-病原物互作鉴别品种与菌株的筛选

 经过近十年的病原菌接种试验,从国内外数百份水稻种质中,筛选出了抗病水平不同的5个代表品种Lemont、武育粳3号、Jasmine85、C418和YSBR1,作为水稻纹枯病菌致病力的鉴别品种。从江苏、广东、广西、海南、云南、湖南、福建等省采集、分离的水稻纹枯病菌中,初步筛选出致病力有差异的30个菌株,于温室苗期接种上述5个品种,确定了不同致病力的5个代表菌株C30、GD-118、E67、YN-7和YN-3。将选出的品种和菌株在江苏扬州和浙江富阳进行大田成株期抗性和致病力分析,结果表明:品种的抗病性和菌株的致病力都存在极显著差异,分别属于5个和3个不同的显著性级别,均可暂时作为鉴定材料使用。据以上结果,初步建立了一套可供水稻纹枯病菌致病力检测和寄主抗病性鉴定的鉴别体系。本文还讨论了建立水稻纹枯病鉴别体系的必要性、可行性和需要进一步开展的工作。     

Genetic distribution of the avirulence gene AVRPiz-t in Thai rice blast isolates and their pathogenicity to the broad-spectrum resistant rice variety Toride 1

Rice blast disease, caused by the filamentous fungus Pyricularia oryzae, is one of the most destructive diseases in rice worldwide. Breeding of resistant rice cultivars remains a cost-effective and environment-friendly means for controlling blast disease, but the resistance tends to break down over time because of the pathogen's rapid adaptation. In this study, AVRPiz-t gene sequences of 46 rice blast isolates were evaluated using a Southern blot analysis. The AVRPiz-t gene was present in 24 of 46 (52.2%) rice blast isolates. The pathogenicity assay showed that all blast isolates were avirulent against Japanese rice cv. Toride 1, which carries several rice blast resistance genes including Piz-t, Pii, Pi37, and Pi-ta. Screening for the Piz-t gene in Thai rice germplasm revealed that less than 20% of rice varieties harbour the Piz-t gene. Therefore, the Toride 1 rice variety could serve as an effective donor of rice blast resistance to be used in rice breeding programmes in Thailand. This study provides evidence for co-evolution between the rice blast resistance gene Piz-t and the rice blast fungal avirulence gene AVRPiz-t. Understanding this relationship will facilitate the sustainable development of breeding for rice blast resistance in the future.     

黑龙江省水稻种质抗瘟性及稻瘟病菌致病性分析

为明确黑龙江省水稻种质抗性及稻瘟病菌的致病性,以黑龙江省8个水稻品种、24个单基因系作为供试材料,120株稻瘟病菌株作为接种体,采用喷雾接种法测定了各供试水稻的抗瘟性及稻瘟病菌的致病性。结果表明,水稻品种对2010年和2011年菌株的抗性频率分别在31.67%~68.33%和21.67%~55.00%之间,2010年最好的抗性品种为松粳12,2011年最好的抗性品种为五优稻4和东农425;松粳12东农425组合联合抗病性最好。水稻单基因系对2010年和2011年菌株的抗性频率分别在10.00%~90.00%和5.00%~86.67%之间,抗性最好的单基因系分别为IRBLzt-T(Pi-zt)和IRBLz5-CA(Pi-z5);松粳12、东农425和龙粳22的基因聚合效果最好。2010年和2011年菌株对抗瘟基因群的致病率分别在8.33%~95.83%和25.00%~95.83%之间;无毒基因总出现频率分别为461和412次。研究表明,水稻种质抗性受菌株致病性影响较大,但高抗种质相对稳定,基因聚合方式更适宜当地品种抗性改良。     

乙烯信号参与调控水稻纹枯病抗性的研究

 乙烯(ET)信号在植物抵抗各种逆境反应中具有重要作用,但目前关于乙烯信号在调控水稻纹枯病抗性中的作用仍缺乏系统研究。本研究以感纹枯病水稻品种Lemont和抗纹枯病水稻品种YSBR1为材料,分析了纹枯病菌接种后乙烯合成关键基因及信号传导途径中标志基因的表达水平,结果显示,纹枯病菌侵染可显著诱导相关基因的表达、激活乙烯信号。进一步采用乙烯合成抑制剂和信号激活剂处理水稻并进行接种鉴定,结果显示,两种化学剂分别可抑制或激活乙烯信号;无论是Lemont还是YSBR1,激活其乙烯信号均可显著增强抗病性,而抑制该信号均显著降低抗病性。对3个乙烯受体突变体(ethylene response2, etr2; ethylene response3, etr3; ethylene response sensor2, ers2)进行温室接种鉴定,发现突变体的病斑长度均极显著高于野生型对照。以上研究表明乙烯信号在水稻对纹枯病菌的防卫反应或基础抗性中具有十分重要的作用,结果将为进一步解析“水稻-纹枯病菌”间的互作机制、制定合适的病害综合防控策略提供理论基础。     

侵染优质稻美香占2号的稻瘟病菌生理小种鉴定及无毒基因分析

为明确优质稻种美香占2号的抗瘟性,并为其合理布局以及与不同品种的轮换种植提供科学依据,利用7个中国鉴别品种和11个抗稻瘟病单基因系,对2013—2017年自广东省美香占2号品种上分离获得的50株稻瘟病菌Magnaporthe oryzae菌株进行生理小种鉴定和无毒基因型分析。结果显示,50株稻瘟病菌菌株被鉴定为11个生理小种,其中优势小种分别为C13、B13、B01、B05和C05;50株稻瘟病菌菌株对IRBLkh-K3(仅含Pik-h基因)、NIL-e1(仅含Pi50基因)、IRBL9-W(仅含Pi9基因)和IRBLzt-T(仅含Piz-t基因)4个抗稻瘟病单基因系表现出极低的毒性,频率分别为4%、6%、6%和8%;对IRBLz-Fu(仅含Piz基因)、IRBLkp-K60(仅含Pik-p基因)和IRBLi-F5(仅含Pii基因)3个抗稻瘟病单基因系表现出相对较高的毒性,频率分别为88%、86%和80%;自美香占2号以及其它4个主栽品种上获得的70株稻瘟病菌菌株被聚为不同类群;2003—2007年供试菌株中无毒基因AvrPi9、AvrPiz-t、AvrPi50和AvrPik-h的出现频率较高,无毒基因AvrPi1、AvrPita2、AvrPi2和AvrPish的出现频率中等,无毒基因AvrPii、AvrPik-p和AvrPiz的出现频率较低。     

水直播条件下黑龙江省不同稻区稻瘟病菌致病性分析

为明确水直播条件下黑龙江省不同稻区稻瘟病菌Magnaporthe oryzae的致病性分化情况，以24个抗瘟单基因系品种为寄主，来源于2017—2018年黑龙江省水直播稻田的242株稻瘟病菌菌株为接种体，采用离体划伤方法接种，记录病斑反应型，计算有效致病菌株率和抗性频率，并进行聚类分析。结果显示，在水直播条件下，2017年，黑龙江省南部和中东部稻区稻瘟病菌菌株对抗瘟单基因系品种的有效致病菌株率介于8.33%~95.83%和20.83%~95.83%之间，无毒基因出现频率分别为575次和622次；2018年，南部和中东部稻区稻瘟病菌菌株对鉴别体系的有效致病菌株率介于29.17%~95.83%和20.83%~91.67%之间，无毒基因出现频率分别为536次和571次。2017年，黑龙江省南部和中东部稻区稻瘟病菌菌株的致病性相似系数介于0.15~1.00和0.14~1.00之间，以致病性相似系数0.40为阈值，可将菌株分别划分为5个类群和6个类群；2018年，南部和中东部稻区菌株的致病性相似系数介于0.15~0.93和0.26~1.00之间，以致病性相似系数0.40为阈值，可将菌株分别划分为5个类群和4个类群。2017年，抗瘟单基因系品种对黑龙江省南部和中东部稻区稻瘟病菌菌株的抗性频率介于11.29%~88.71%和10.77%~86.15%之间，其中抗瘟单基因系品种IRBL9-W（Pi-9）和IRBLz5-CA（Pi-z5）抗性表现最好；2018年，抗瘟单基因系品种对南部和中东部稻区菌株的抗性频率介于10.34%~82.67%和15.79%~85.96%之间，其中抗瘟单基因系品种IRBL9-W（Pi-9）和IRBLz5-CA（Pi-z5）抗性表现最好。表明水直播条件下黑龙江省稻瘟病菌致病性分化剧烈，稻瘟病菌整体致病力较强，但仍有部分水稻种质抗性较好且相对稳定，基因聚合后抗性会得到进一步提升。     

Management of rice blast (Pyricularia oryzae): implications of alternative hosts

Rice blast (Pyricularia oryzae) has become a serious disease on commercial rice (Oryza sativa) crops in northern Australia and is present there on wild rice (O. australiensis). Characterisation of the host range of P. oryzae is fundamental to both reducing disease spread and to preventing development of epidemics via better management of Poaceae inoculum reservoirs in Australia. Studies on response of three different wild O. australiensis sources toward four isolates of P. oryzae showed all genotypes very susceptible to three isolates [WAC13466 (race IA-1), BRIP53376 (race IB-3), NT2014a (race unknown)], but resistant to isolate BRIP39772 (race IA-3). Studies to investigate levels of blast disease development following inoculation on a range of Poaceae hosts showed both P. oryzae isolates (WAC13466, BRIP53376) were highly virulent on barley (disease index, DI?=?100%), and on Phalaris and O. australiensis (DI?=?70%). However, isolate BRIP53376 showed a significantly higher level of aggressiveness (DI ~80%) on ryegrass, wild oat and rice. Of the two wheat cultivars tested, only one cultivar showed disease and only from WAC13466 (DI ~30%). Sweet corn and goosegrass were also susceptible to both blast isolates, but DI was <50%. That P. oryzae was virulent across these diverse Poaceae hosts, highlights, for Australia, the possibility for these species in, first, harbouring P. oryzae isolates highly virulent to commercial rice, second, fostering spread of rice-attacking P. oryzae strains into regions currently free of rice blast, and third, potential for these alternative host species to encourage development of more virulent host-specific strains of P. oryzae. The current study is an important step towards facilitating improved crop protection in the medium and long term from reducing P. oryzae disease epidemics via a better understanding and management of inoculum reservoirs in Australia.

     

Effects of panicle development stage and temperature on rice panicle blast infection by Magnaporthe oryzae and visualization of its infection process

Panicle blast, caused by the fungus Magnaporthe oryzae (syn. Pyricularia oryzae), directly contributes to yield loss in the field. The effects of panicle development stage and temperature on panicle blast were studied and the infection process of M. oryzae in panicles was visualized. Rice panicles at different development stages from three rice cultivars were inoculated with a conidial suspension in vitro. The rice cultivar Lijiangxintuanheigu was highly susceptible to panicle blast at 5 days postinoculation (dpi) when the pulvinus distance was 15–20 cm. Nanjing 9108 was moderately susceptible to panicle blast when the pulvinus distance was 8–10 cm, but Yliangyou 800 was resistant. The effect of temperature on panicle blast was determined under 22–35 °C temperature treatments. Inoculated panicles placed at temperatures of 28 and 30 °C showed the highest lesion grade based on lesion length at 5 dpi. The infection process of M. oryzae in rice panicles was observed by confocal laser scanning microscopy (CLSM) and transmission electron microscopy (TEM). M. oryzae initially formed the appressorium to invade through the epidermis of rice panicles at 24 hours postinoculation (hpi). As the disease progressed, the invasive hyphae formed dense mycelial networks in the inner parenchyma cells at 60 hpi. Our results will contribute to the understanding of panicle development stage and temperature effects on panicle blast and improve resistance evaluation methods. Additionally, visualization of the infection process by CLSM and TEM are valuable methods to observe M. oryzae invasive hyphae inside rice panicle cells.     

Reaction of <Emphasis Type="Italic">Leersia</Emphasis> grasses to <Emphasis Type="Italic">Xanthomonas oryzae</Emphasis> pv. <Emphasis Type="Italic">oryzae</Emphasis> collected from Japan and Asian countries

The present study was conducted to determine if there is specificity in the host-pathogen relationship between the isolates of Xanthomonas oryzae pv. oryzae, the causal bacterium for rice blight and Leersia grasses, the alternative weed hosts of the disease. Plants of three species of Leersia, namely, L. sayanuka, L. oryzoides and L. japonica, were collected from various parts of Japan and were inoculated with the X. oryzae pv. oryzae isolates obtained from various locations in Japan and from 11 Asian countries. Four L. sayanuka plants were found susceptible to all Race II isolates and some Race I isolates, but were resistant to all Race III isolates. Race III is known to have a wider range pathogenicity to rice cultivar groups compared with Race I and II. Although the reactions of two L. oryzoides plants to Race I and II isolates were similar to that of L. sayanuka, the L. oryzoides plant collected from Niigata Prefecture showed a susceptible reaction to some Race III isolates. On the other hand, L. japonica plants gave reactions different those of L. sayanuka and L. oryzoides, with two plants of L. japonica found to be resistant to all test isolates collected from Japan. The Asian isolates exhibited a wide host range against the international differential rice cultivars, but almost all of them were avirulent to Leersia plants. These results indicate that the relationship between the pathogenicity of the causal bacterium and the resistance of host plants is very complex, and suggest that pathogenic diversity of X. oryzae pv. oryzae might be related to the resistance of Leersia spp.