中国稻瘟病菌的致病性和其DNA指纹图谱间关系的研究

通过在稻瘟病菌Pyricularia oryza。基因组文库中的筛选,找到一个散布的并具有基因组特异性的层重复顺序POR6。本文报道用这一株针对6个日本菌株和26个中国北方菌株进行DNA指纹作图的结果。其中22个中国北方菌株按其杂交带型百分相似率被分成8个株系。一些在我们实验室保存的菌株用传统方法鉴定发现在转管过程中会发生致病性变异。当用POR6作探针与这些菌株NNA的EcoRV酶切片段杂交时,检测出它们的无性世代中出现数条EcoRV多态性片段。     

橡胶树暹罗炭疽菌Zn2Cys6型转录因子CsGcc1的生物学功能

【背景】暹罗炭疽菌（Colletotrichum siamense）是一种重要的病原真菌,可以引起炭疽病,给全球橡胶产业带来巨大的经济损失。Zn₂Cys₆型转录因子是真菌特有的锌指类转录因子,通常参与调控真菌的生长发育过程。【目的】在暹罗炭疽菌中鉴定了一个与稻瘟病菌Gcc1同源的Zn₂Cys₆型转录因子CsGcc1,并研究其功能。【方法】根据同源重组原理构建CsGCC1的基因敲除突变体,并通过营养生长、H₂O₂敏感性、分生孢子产生及萌发、玻璃纸试验和致病性分析,明确CsGcc1的功能。【结果】CsGcc1编码一个含有646个氨基酸的蛋白,而且含有一个GAL4结构域。CsGCC1基因在培养36 h的菌丝及分生孢子中具有较高的表达量。CsGCC1基因敲除突变株营养生长速率降低且对H₂O₂更加敏感。相较于野生型菌株,突变株的分生孢子产量、萌发率及附着胞形成率均降低。此外,CsGCC1的敲除可以明显降低分生孢子的穿透能力,突变株对橡胶叶片的致病力减弱。【结论】Zn₂Cys₆型转录因子CsGcc1参与调控暹罗炭疽菌的营养生长、氧化应激、分生孢子发育及致病性等过程。     

2017–2019年中国南方五省规模化养猪场副猪格拉菌血清型、耐药性及β-内酰胺类耐药基因bla-TEM分子特征分析

【目的】旨在分析当前规模化养殖场副猪格拉菌(Glaesserella parasuis)优势血清型、耐药特性、耐药基因与分子特征。【方法】对源自规模化养猪场21株副猪格拉菌临床分离株,采用PCR鉴定血清型;利用K-B纸片扩散法鉴定其对25种抗生素的耐药表型;采用PCR检测bla-_TEM、bla-_NDM和bla-_CTX等7种耐药基因,并采用Chi-square test和Fisher exact test分析耐药表型和耐药基因型的相关性;耐药基因目的条带测序,并应用CLC Sequence Viewer软件分析β-内酰胺类耐药基因(bla-_TEM)编码蛋白氨基酸关键位点差异与耐药性的关系。【结果】21株副猪格拉菌临床分离株的优势血清型为4和12型;对β-内酰胺类药物苯唑西林的耐药性较强,耐药菌占比达61.9%(13/21);多重耐药菌株占比高达90.5%(19/21);β-内酰胺类耐药基因bla-_TEM携带率较高(52.4%,11/21),且bla-_TEM与β-内酰胺类药物青霉素G、苯唑西林和头孢拉定的耐药性显著相关,部分bla-_TEM编码氨基酸存在可能与副猪格拉菌耐药能力有关的差异位点。【结论】本研究表明,规模化养猪场的副猪格拉菌多重耐药情况仍很严重,并明确了被调查区域β-内酰胺类药物耐药率高的主要原因是携带耐药基因bla-_TEM,为加强对规模化养猪场副猪格拉菌耐药性监测提供理论依据。     

加州鲈源鰤鱼诺卡氏菌的分离鉴定及致病性

[背景] 鰤鱼诺卡氏菌（Nocardia seriolae）是一种严重危害水产养殖业的病原菌,可引起以体表溃疡、出血及组织器官形成结节为特征的鱼类慢性肉芽肿疾病,目前尚无有效的防治方法。[目的] 明确引起安徽省临泉县某养殖场加州鲈（Micropterus salmonoides）结节病的病原菌,探讨其致病性,为该病的有效防治提供科学依据。[方法] 取肝脏结节病灶接种于TSB培养基分离优势细菌,利用表型检查结合分子生物学方法鉴定分离菌株。进一步通过检测分离菌株的毒力基因、测定其对加州鲈的半数致死量（LD₅₀）以及所感染加州鲈的组织病理学变化与组织载菌量,分析其致病性。[结果] 从病鱼体内分离到一株优势菌株NI,综合NI分离株的表型特性、16S rRNA基因序列与鰤鱼诺卡氏菌参考株相应序列的一致性以及特异性PCR扩增结果,确定其为鰤鱼诺卡氏菌。鰤鱼诺卡氏菌NI分离株携带毒力基因gapA、ibeA和mip,人工回归感染后加州鲈出现与自然病例相似的症状,其对加州鲈的LD₅₀为2.58×10⁶ CFU/尾。组织病理学观察到头肾、心脏、肝脏、胃和脾脏均出现慢性肉芽肿病变,肠管肌层疏松、肠绒毛脱落,肌肉组织中肌纤维疏松、间隙增宽。qPCR检测结果显示,组织中鰤鱼诺卡氏菌载量由高到低依次为头肾、心、肝、胃、脾、肠和肌肉。[结论] 鰤鱼诺卡氏菌是引起此次加州鲈结节病的病原菌,对该菌致病性的研究为加州鲈诺卡氏菌病的防控提供了理论依据。     

不同苹果砧穗组合的生长及光合特性

以‘垂丝海棠’（Malus halliana）和‘平邑甜茶’（Malus hupehensis）为基砧,分别嫁接品种‘烟富6号’和‘长富2号’接穗,测定4种砧穗组合的嫁接亲和性、接穗生长量、光合与荧光参数及叶绿素含量（SPAD）,并用主成分分析法综合评价砧穗组合的优劣,探讨不同苹果砧穗组合嫁接苗的生长及光合特性,为西北盐碱地选择适宜的苹果砧木提供理论依据。结果表明：（1）4种砧穗组合中‘垂丝海棠/烟富6号’的上下口粗度比最接近1,嫁接亲和性最好。（2）整个生长期内,以‘垂丝海棠’为基砧的2个组合嫁接苗的生长量、净光合速率（P_n）、最大荧光（F_m）、PSⅡ最大光能转化率（F_v/F_m）均显著大于‘平邑甜茶’为基砧的组合,但其胞间CO₂浓度（C_i）及初始荧光（F₀）显著低于‘平邑甜茶’为基砧的组合;光化学猝灭系数（qP）在4种砧穗组合中无显著差异。（3）在8月份光照强度较高时,‘垂丝海棠/烟富6号’ 嫁接苗的气孔导度（G_s）高于其他砧穗组合;以‘垂丝海棠’为基砧的2个组合嫁接苗叶片的蒸腾速率（T_r）和相对叶绿素含量（SPAD）显著高于‘平邑甜茶’ 基砧组合。（4）根据主成分分析对各项指标进行综合评价,按照4个砧穗组合的综合得分由高到低依次为：‘垂丝海棠/烟富6号’、‘垂丝海棠/长富2号’、‘平邑甜茶/长富2号’、‘平邑甜茶/烟富6号’。研究发现,基砧‘垂丝海棠’的适应性优于‘平邑甜茶’,且‘垂丝海棠/烟富6号’砧穗组合的嫁接亲和性高,长势强,光合能力优,为甘肃中部地区适宜的砧穗组合。     

焦化废水O/H/O生物处理工艺二级好氧生物反应器的微生物结构和功能

【背景】焦化废水O/H/O生物处理工艺的二级好氧生物反应器O₂具有剩余污染物矿化和完全硝化功能,对废水的达标排放有重要作用。【目的】阐明O₂生物反应器的微生物结构和功能。【方法】利用16S rRNA基因测序,研究O₂生物反应器的微生物多样性和组成并进行功能预测,揭示其共现性特征和环境影响因子。【结果】O₂的优势菌门以变形菌门(Proteobacteria)、拟杆菌门(Bacteroidetes)、绿菌门(Chlorobi)为主。主要菌属中红游动菌属(Rhodoplanes)、溶杆菌属(Lysobacter)、硫杆菌属(Thiobacillus)等参与化学需氧量(chemical oxygen demand,COD)、酚类(phenols)和硫氰酸盐(thiocyanate,SCN^-)等剩余污染物的去除,亚硝化弧菌属(Nitrosovibrio)和硝化螺菌属(Nitrospira)分别作为氨氧化细菌(ammonia-oxidizing bacteria,AOB)和主要的亚硝酸盐氧化细菌(nitrite-oxidizing bacteria,NOB)。功能预测结果显示苯甲酸酯降解、氨基苯甲酸酯降解、氯烷烃和氯烯烃的降解、氟代苯甲酸酯降解和硝基甲苯降解是外源物质生物降解和代谢的前五大通路,广泛分布在主要菌属中,验证了微生物降解剩余污染物的作用。基因pmoA/B/C-amoA/B/C、hao和nxrA/B编码相关的酶,组成了完整的硝化途径。共现网络结果揭示溶杆菌属、Candidatus Solibacter和红游动菌属在O₂生态中的重要地位。通过冗余分析(redundancy analysis,RDA)表明COD和NH₃是影响O₂微生物群落的主要因素。【结论】红游动菌属和溶杆菌属是O₂中最核心的功能菌属,在污染物矿化和维持群落生态稳定上有重要作用。亚硝化弧菌属和硝化螺菌属是硝化作用的核心菌属。O₂中的代谢通路以剩余污染物矿化和完全硝化为主,微生物群落主要受COD和NH₃的影响。本研究阐明了O₂的微生物结构与功能,为焦化废水O/H/O生物处理工艺的改进提供了微生物学上的依据。     

单核细胞增多性李斯特菌硫氧还蛋白Lmo1609的应激生物学功能研究

[目的]本研究旨在构建单核细胞增多性李斯特菌(Listeria monocytogenes)硫氧还蛋白Lmo1609的基因缺失株,分析Lmo1609的氧化还原酶学活性,及其在细菌生长、运动过程中发挥的作用,并探究了Lmo1609参与细菌抗氧化应激和致病的生物学基础。为阐明其抗应激生物学作用以及完善李斯特菌的感染机制奠定分子基础。[方法]利用同源重组原理构建lmo1609基因缺失株及回补株。通过分子生物学、应激生物学和感染生物学等手段,对Lmo1609的生物学功能进行探索。以胰岛素为底物分析其氧化还原酶学活性;通过构建lmo1609缺失株和回补株,比较野生株和突变株在运动性、生长能力、抗氧化应激、细胞黏附、侵袭和增殖能力等方面的差异,进而鉴定Lmo1609的生物学功能。[结果]缺失lmo1609后,单增李斯特菌在生长能力上无明显变化,而运动能力明显减弱;对H₂O₂的敏感性增强;对细胞的黏附侵袭能力没有差异;对小鼠的致病力没有显著影响。[结论]本研究首次证实了单增李斯特菌硫氧还蛋白Lmo1609具有还原酶学活性,参与调控细菌的运动和对H₂O₂的氧化应激耐受,不介导单增李斯特菌的致病性。     

基于双重芯片式数字PCR快速鉴定KPC型碳青霉烯耐药肺炎克雷伯菌的方法

【背景】由于碳青霉烯类药物的泛用和滥用,致使肺炎克雷伯菌碳青霉烯耐药株与日俱增,产碳青霉烯酶是肺炎克雷伯菌对碳青霉烯类药物耐药的主要原因。目前对肺炎克雷伯菌碳青霉烯耐药株的检测方法存在费时费力、特异性差、灵敏度低等问题。【目的】建立一种能同时检测肺炎克雷伯菌和碳青霉烯酶基因bla_KPC的双重芯片式数字PCR方法。【方法】依据肺炎克雷伯菌的特有基因yhaI和碳青霉烯耐药基因bla_KPC保守序列设计特异性引物和探针,确定双重芯片式数字PCR同时对yhaI和bla_KPC两个基因核酸浓度绝对定量的检测范围、检出限和最佳实验体系,并进行方法特异性、灵敏度、重复性分析及临床菌株的检测。【结果】双重芯片式数字PCR检测灵敏度比双重实时荧光定量PCR提高了约1.5个数量级,在两基因同时检出的情况下,最低检出限分别为3.74 copies/μL (yhaI基因)和1.93 copies/μL (bla_KPC基因);优化后的双重芯片式数字PCR对参考菌株检测特异性的结果与双重实时荧光定量PCR结果一致;利用优化后的双重芯片式数字PCR方法共检测58株临床菌株,其中肺炎克雷伯菌43株,属肺炎克雷伯菌且含有bla_KPC基因的菌株13株,这与质谱及耐药谱检测结果一致。【结论】利用双重芯片式数字PCR技术建立了产KPC型碳青霉烯酶肺炎克雷伯菌的绝对定量检测方法。该方法特异性强、灵敏度高、准确度好,可用于检测具有碳青霉烯酶基因bla_KPC的肺炎克雷伯菌的核酸检测和定量分析,也为产其他类型碳青霉烯酶的病原菌检测提供了新的技术参考。     

氨基多糖生物降解转化模型的建立

以Beauveria-bassiana LB₉₅₀菌作为氨基多糖降解菌,以Candidasp. LB₅₀菌作为氨基糖转化菌,建立的氨基多糖生物降解及转化模型,与纯培养比较,粘度下降比率提高23．0％,可溶性糖含量增加167.7μg／mh。二菌混合生长时呈互生关系。     

遮阴和施氮对黄檗幼苗叶片光合特性和碳氮计量特征的影响

选取大田环境下3年生黄檗幼苗,采用人工控制双因素随机区组试验,在不同光照［全光照(S₀)、轻度遮光21.4%(S₁)和重度遮光8.7%(S₂)］和不同氮添加［无添加对照(F₀)、轻度添加(F₁)和重度添加(F₂)］条件下,测定黄檗幼苗叶片的相对叶绿素含量(SPAD值)、气体交换参数及碳氮化学计量特征,探讨黄檗幼苗对遮阴和施氮的响应机制。结果表明：(1)随着遮光程度增强,黄檗幼苗叶片的SPAD值、蒸腾速率(T_r)、气孔导度(G_s)、碳氮比(C∶N)和瞬时光合氮利用率(PNUE)均呈现先增后降的趋势,两种遮光条件下SPAD均显著高于全光照环境;黄檗幼苗叶片的净光合速率(P_n)、水分利用率(WUE)和气孔限制值(L_s)逐渐降低;而叶片氮(N)和碳(C)含量均呈先降后升的趋势。(2)随氮添加量增加,黄檗幼苗叶片的P_n、WUE、L_s、N和C含量均呈先增后降趋势,T_r、G_s和PNUE则逐渐下降,而C∶N逐渐增加。(3)黄檗幼苗叶片的P_n在各光氮组合处理间均无显著差异;SPAD含量以S₁F₀、S₂F₀和S₁F₂处理组合显著较高,而以全光照(S₀)处理组合显著最低;T_r和G_s以轻度遮光(S₁)处理组合明显较高,而以S₂F₁、S₀F₂、S₂F₂明显较低;WUE和L_s均以S₀F₂显著最高,S₂F₂处理组合显著最低。黄檗幼苗叶片N和C含量在重度遮光/轻度氮添加(S₂F₁)时具有较大值,而其C∶N和PNUE在轻度遮光/无氮添加(S₁F₀)时具有较大值。(4)隶属函数综合评价认为,黄檗幼苗对光氮复合作用总体属中等耐受型,轻度遮光时不添加氮肥(S₁F₀)和轻度氮添加(S₁F₁)及全光照时轻度氮添加(S₀F₁)为适于幼苗生长的光氮组合。研究发现,光环境是影响黄檗幼苗光合作用和更新的主导因子,但黄檗苗期能耐受一定的遮阴胁迫;光照不受限制时,适当增加氮肥有利于黄檗幼苗生长;光照受限(重度遮光)时,施氮则抑制叶片叶绿素合成,降低了幼苗光能利用率,不利于其生长。     

DNA Fingerprinting with a Dispersed Repeated Sequence Resolves Pathotype Diversity in the Rice Blast Fungus

The poor definition of pathotype variation in the rice blast fungus has historically handicapped strategies for reducing blast disease damage to the world's rice crop. We have employed a probe for a dispersed repeated DNA sequence called MGR [Hamer et al. (1989). Proc. Natl. Acad. Sci. USA 86, 9981-9985] to construct genotype-specific, EcoRl restriction fragment length profiles (MGR-DNA fingerprints) from United States field isolates of this fungus. By using a blind-test design, we demonstrated that MGR-DNA fingerprints distinguished the major pathotypes in the United States, accurately identified the pathotypes of isolates collected over a 30-year period, and defined the organization of clonal lineages within and among pathotype groups. These results resolved a lingering controversy regarding rice blast pathotype stability and illustrated new opportunities for tracking the population dynamics and evolution of this important crop pathogen.     

DNA fingerprinting of Indian isolates of Xanthomonas oryzae pv. oryzae

 A high level of genetic polymorphism was detected among Indian isolates of Xanthomonas oryzae pv. oryzae using hypervariable probes such as a microsatellite oligonucleotide, probe (TG)₁₀, a human minisatellite probe, pV47, an avirulence gene probe, avrXa10 and a repeat clone, pBS101. These DNA probes detected multiple loci in the bacterial genome generating complex DNA fingerprints and differentiated all of the bacterial isolates. Analysis of fingerprints indicated that pV47, (TG)₁₀ and pBS101 have a lower probability of identical match than avrXa10 and therefore are potential probes for DNA fingerprinting and variability analysis of Xanthomonas oryzae pv. oryzae pathogen populations. Cluster analysis based on hybridization patterns using all of the above probes showed five groups at 56% similarity. Studies on the methylation patterns of isolates representing the three important races of X. oryzae pv. oryzae indicated more methylation in the most virulent isolate, suggesting a possible role of methylation in pathogenicity. Received: 8 December 1996 / Accepted: 20 December 1996     

SSRs for Marker-Assisted Selection for Blast Resistance in Rice (Oryza sativa L.)

Rice blast caused by the fungus Magnaporthe oryzae is one of the most devastating diseases of rice in nearly all rice growing areas of the world including Malaysia. To develop cultivars with resistance against different races of M. oryzae, availability of molecular markers along with marker-assisted selection strategies are essential. In this study, 11 polymorphic simple sequence repeat (SSR) markers with good fit of 1:2:1 ratio for single gene model in F₂ population derived from the cross of Pongsu seribu 2 (Resistant) and Mahsuri (Susceptible) rice cultivars were analysed in 296 F₃ families derived from individual F₂ plants to investigate association with Pi gene conferring resistance to M. oryzae pathotype. Parents and progeny were grouped into two phenotypic classes based on their blast reactions. Chi-square test for the segregation of resistance and susceptibility in F₃ generation fitted a ratio of approximately 3:1. Association of SSR markers with phenotypic trait in F₃ families was identified by statistical analysis. Four SSR markers (RM413, RM5961, RM1233 and RM8225) were significantly associated with blast resistance to pathotype 7.2 of M. oryzae in rice (p ≤ 0.01). These four markers accounted for about 20% of total phenotypic variation. So, these markers were confirmed as suitable markers for use in marker-assisted selection and confirmation of blast resistance genes to develop rice cultivars with durable blast resistance in Malaysian rice breeding programmes.     

Rice varieties with resistance to multiple races of Magnaporthe oryzae offer opportunities to manage rice blast in Australia

Rice blast caused by Magnaporthe oryzae is the most destructive disease of rice worldwide. Development of resistant varieties is considered as the most cost‐effective and sustainable way to manage rice blast. However, there remains a lack of knowledge about the resistance of rice varieties to blast disease in Australia. This study was conducted to determine if there was any resistance existing among the rice varieties grown in Australia to M. oryzae isolates from this country that belong to different races. There was a resistant reaction of the variety SHZ‐2 to all the five races of IA‐1, IA‐3, IA‐63, IB‐3 and IB‐59, with a percent disease index (%DI) less than 40. Varieties NTR587, BR‐IRGA‐409, Ceysvoni and Rikuto Norin 20 showed a resistant reaction to races IA‐3, IA‐63, IB‐3 and IB‐59; and the variety Kyeema exhibited a resistant reaction to races IA‐3, IB‐3 and IB‐59. For the races IA‐1 and IB‐59 with more than one isolate, varieties with differential disease reactions across different isolates belonging to the same race were also revealed: five varieties, Langi, Opus, Sherpa, Viet 1 and Topaz, exhibited differential disease reactions to the three IA‐1 isolates; 10 varieties showed differential disease reactions to the four IB‐59 isolates; in addition, the varieties that had differential disease reactions to the IA‐1 isolates also exhibited differential disease reactions to the IB‐59 isolates of race. This study provides valuable resistance sources for breeding programmes to develop rice varieties with resistance to multiple races of M. oryzae in Australia.     

Sequence variation of avirulence gene AVR-Pita1 in rice blast fungus, Magnaporthe oryzae

The interaction between rice, Oryza sativa, and rice blast fungus, Magnaporthe oryzae, is triggered by an interaction between the protein products of the host resistant gene, and the pathogen avirulence gene. This interaction follows the ‘gene-for-gene' concept. The resistant gene has effectively protected rice plants from rice blast infection. However, the resistant genes usually break down several years after the release of the resistant rice varieties because the fungus has evolved to new races. The objective of this study is to investigate the nucleotide sequence variation of the AVR-Pita1 gene that influences the adaption of rice blast fungus to overcome the resistant gene, Pi-ta. Thirty rice blast fungus isolates were collected in 2005 and 2010 from infected rice plants in northern and northeastern Thailand. The nucleotide sequences of AVR-Pita1 were amplified and analyzed. Phylogenetic analysis was conducted using the MEGA 5.0 program. The results showed a high level of nucleotide sequence polymorphisms and the positive genetic selection pressure in Thai rice blast isolates. The details of sequence variation analysis were described in this article. The information from this study can be used for rice blast resistant breeding program in the future.     

Differentiation of Physiologic Races of the Rice Blast Fungus, Pyricularia oryzae Cav. by PAGE-electrophoresis

Eighty-three isolates of the rice blast fungus (Pyricularia oryzae) were tested with respect to genetic diversity and the possibility of race differentiation by electrophoresis. The fungus was genetically very heterogeneous. The isolates were differentiated into 6 races by pathogenicity on race differential varieties. There was little correlation between pathogenicity and zymogram types of one particular enzyme such as esterase, phosphatase or catalase. The isolates were divided into 14 groups by the combination of the zymogram types of the three enzymes. The isolates in the same group showed similar pathogenicity. A new method is proposed which differentiates the blast fungus races by the combination of zymogram type of enzymes. The details, are discussed.     

Virulence Analysis and Race Classification of Xanthomonas oryzae pv. oryzae in China

Two hundred and eighty‐five isolates of Xanthomonas oryzae pv. oryzae were randomly collected from 22 rice‐growing provinces in China. Ninety‐one representative isolates were chosen to assess the differential characteristics of 24 near‐isogenic rice lines containing a single resistance gene or two to four genes. Most isolates were avirulent on pyramided lines, except IRBB51, and hence, the pyramided lines cannot be used as differentials for the virulence analysis of X. oryzae pv. oryzae in China. The 13 rice lines with a single gene were used further to establish a system of races classification of X. oryzae pv. oryzae in China. IR24 and IRBB10 were susceptible to the isolates with several exceptions, whereas IRBB5, IRBB7 and IRBB21 were resistant. Based on the interactions between the isolates of X. oryzae pv. oryzae and the 13 near‐isogenic rice lines, six single‐gene rice cultivars (IRBB5, IRBB13, IRBB3, IRBB14, IRBB2 and IR24) were chosen as differentials, and the 285 tested isolates were classified into nine races. The reaction patterns of the nine races in order were: RRRRRR, RRRRRS, RRRRSS, RRRSSS, RRSSSS, RSRRRS, RSSRRS, RSSSSS and SSSSSS. The race frequencies were 10.18%, 10.53%, 4.91%, 10.18%, 24.21%, 5.96%, 11.23%, 22.46% and 0.35% respectively. The virulence of representative strains of eight Philippine races on 13 rice lines with a single gene was determined and compared with the Chinese races. The frequency distributions of X. oryzae pv. oryzae races were primarily described for the different regions in China.     

Characterization of Rice Blast Isolates by the Differential System and their Application for Mapping a Resistance Gene,Pi19(t)

To facilitate resistance gene characterization in the present study, the pathogenicities of newly collected blast isolates from rice fields in the Philippines were characterized using international blast differential varieties consisting of 31 monogenic lines that target 24 resistance genes. To classify and designate the blast isolates, we used a new international blast designation system, which has been proposed as a suitable naming system for comparing blast races among different studies. A total of 23 rice blast isolates collected from the Philippines were classified into 16 pathotypes, which showed reaction patterns different from those seen in the standard isolates. Among the blast pathotypes, 11 had differentiating ability for four Pik alleles (Pik, Pik‐m, Pik‐h, and Pik‐p) and Pi1, whereas the standard blast isolates from the Philippines were not able to differentiate these genes. In addition, several blast isolates were avirulent to IRBLt‐K59, IRBL19‐A, and Lijiangxintuanheigu, although the standard differential blast isolates were virulent to these lines. Moreover, two blast isolates were virulent to a monogenic line, IRBL9‐W, which harbours Pi9 and was resistant to all standard differential blast isolates. By using the isolates avirulent to IRBL19‐A, Pi19(t) was successfully mapped in the centromeric region on chromosome 12 with simple sequence repeat markers RM27937 and RM1337. These markers are useful for marker‐assisted Pi19(t) introgression worldwide.     

Analysis of the Relationship between Blast Resistance Genes and Disease Resistance of Rice Germplasm via Functional Molecular Markers

Rice blast disease is one of the most devastating diseases of rice (Oryza sativa L.) caused by the fungus Magnaporthe oryzae (M. oryzae), and neck blast is the most destructive phase of this illness. The underlying molecular mechanisms of rice blast resistance are not well known. Thus, we collected 150 rice varieties from different ecotypes in China and assessed the rice blast resistances under the natural conditions that favoured disease development in Jining, Shandong Province, China in 2017. Results showed that 92 (61.3%) and 58 (38.7%) rice varieties were resistant and susceptible to M. oryzae, respectively. Among the 150 rice varieties screened for the presence of 13 major blast resistance (R) genes against M. oryzae by using functional markers, 147 contained one to eight R genes. The relationship between R genes and disease response was discussed by analysing the phenotype and genotype of functional markers. The results showed that the rice blast resistance gene Pita was significantly correlated with rice blast resistance. Our results provided a basis for the further understanding of the distribution of 13 major R genes of rice blast in the germplasm resources of the tested rice varieties, and were meaningful for rice disease resistance breeding.