节瓜抗枯萎病基因的分子标记研究

本研究利用人工接种及BSA法验证甜瓜抗枯萎病基因Fom-2的连锁分子标记SSR430和STS296应用于节瓜抗枯萎病鉴定的通用性。结果表明:(1)在12份抗病材料和27份感病材料的分子鉴定中,抗病材料均能找到SSR430标记,与高抗母本B-4带型一致,感病材料均无标记,准确率为100.00%,能用于节瓜抗枯萎病分子标记辅助育种;(2)利用STS296进行分子标记鉴定,只有B-4和3个抗性子代含有STS296标记,所有感病材料均不含此标记,表明STS296有可能可作为节瓜枯萎病的抗性标记。     

甜瓜抗枯萎病基因同源序列克隆与序列分析

目的:克隆甜瓜抗枯萎病基因同源序列并对其序列分析。方法:根据已发表的甜瓜抗枯萎病基因Fom-2设计引物,从高抗枯萎病甜瓜品种‘日本安农二号’基因组中扩增Fom-2同源序列R-Fom-2。结果:该基因长3307bp,包含一个完整的开放阅读框,编码1073个氨基酸,推测蛋白质分子量123.57kDa,等电点7.06。属于nonTIR-NBS-LRR类抗病基因,在LRR区存在一个可能的CC结构域。但在nonTIR类抗病蛋白中,CC结构域一般位于kin-1a前。氨基酸同源性分析显示,R-Fom-2同Fom-2全长序列具有96%的同源性,对不同甜瓜品种Fom-2的LRR区分析比较,同源性在91%以上。且LRR区的差异主要集中在β-strand/β-turn区域。结论:序列分析揭示Fom-2家族是一个活跃的基因,LRR区可能对Fom-2家族的功能起着重要作用,为进一步研究R-Fom-2基因的结构与生物学功能奠定了基础。     

3种外源诱导剂预处理对甜瓜抗病特征及其Fom 2和CHT基因表达的影响

该研究选用水杨酸(SA)、茉莉酸甲酯(MeJA)、Ca~(2+)、无菌水(对照)作为外源预处理诱导剂,以抗、感枯萎病甜瓜品种为材料,分别于诱导预处理2d后接种甜瓜枯萎菌,并于接种5、7、9d时观察发病情况,进行病情调查;在接种后1、3、5、7、9d取甜瓜叶片,分析抗病甜瓜(MR-1)和感病甜瓜(M1-15)叶片中甜瓜抗枯萎病基因(Fom-2)、几丁质酶基因(CHT)的表达变化,以探寻提高防治甜瓜枯萎病菌侵染的技术途径。结果显示:(1)外源MeJA和SA预处理接种后2品种的病情指数显著低于对照,但Ca~(2+)处理后的病情指数与对照无显著差异。(2)经外源诱导预处理接种后,MR-1和M1-15品种叶片的Fom-2和CHT基因均出现差异表达,但Ca~(2+)诱导其上调表达的效果微弱。(3)经SA、MeJA诱导预处理接种后,2品种叶片的Fom-2和CHT基因表达总体均显著高于对照;Fom-2基因的表达抗病甜瓜MR-1分别在接种后5d、7d时达到峰值,而感病甜瓜M1-15则均在接种9d时达到峰值;CHT基因的表达抗病甜瓜MR-1则均在接种后7d时达到峰值,而感病甜瓜M1-15分别在接种后7d、9d时达到峰值。(4)Ca~(2+)处理对抗、感甜瓜叶片的Fom-2和CHT基因的表达均无显著影响。(5)相关分析表明,经SA、MeJA诱导预处理接种后,甜瓜枯萎病病情指数与Fom-2和CHT基因表达量有显著的相关性;而Ca~(2+)处理效果不显著。研究表明:SA、MeJA通过诱导Fom-2、CHT基因上调表达,进而使甜瓜的抗病性提高,而Ca~(2+)处理对两基因表达和甜瓜抗病性均无显著影响。     

新疆甜瓜Fom-2基因同源序列的克隆及分析

近年来甜瓜枯萎病蔓延迅速,危害严重,分离克隆甜瓜抗病基因,利用转基因技术改良甜瓜抗病品性是一种从根本上解决甜瓜枯萎病危害的新途径。根据已知Fom-2基因序列设计特异引物,采用RT-PCR技术从新疆甜瓜抗病性品种黄旦子中扩增出580bp的cDNA片段,序列分析表明它与已发表Fom-2基因具有高度同源性基因片段,命名为X-Fom-2。以X-Fom-2为探针对新疆甜瓜黄旦子、伽什瓜、红心脆、金丽-2号进行Southem blot和Northem blot,结果表明,X-Fom-2以多拷贝形式存在。X-Fom-2在抗病品种黄旦子、金丽2号有表达且在病原菌诱导后增强,而在感病品种伽什瓜、红心脆中没有表达。     

人工合成小麦抗白粉病未知基因的SSR标记

YAV-2/TEZ//A.SQ(895)是硬粒小麦与粗山羊草杂交获得的抗白粉病人工合成小麦。本研究利用人工合成小麦YAV-2/TEZ//A.SQ(895)与感白粉病的普通小麦品系品资50098杂交和自交获得的F2代群体及F3家系,在温室条件下鉴定群体的白粉病抗性。遗传分析结果表明,该抗白粉病基因为显性单基因遗传。利用647对小麦SSR引物进行了白粉病抗性基因的分子标记分析,结果表明该白粉病抗性基因与2A染色体的6个SSR标记连锁,与标记Xcfa2086的遗传距离最近,为11.8cM。     

大豆品种早熟18抗疫霉根腐病基因的SSR分子标记

大豆品种早熟18是抗疫霉根腐病的有效抗源。本研究鉴定和分子标记早熟18的抗疫霉根腐病基因,以期为该品种的有效利用及分子辅助育种奠定基础。以感病大豆品种Williams与早熟18杂交建立分离群体。抗性遗传分析表明,早熟18对大豆疫霉菌抗性由1个显性单基因控制,该基因被定名为RpsZS18。SSR标记连锁分析表明,RpsZS18位于大豆分子遗传连锁群D1b上的SSR标记Sat_069和Sat_183之间,与这两个标记的遗传距离分别为10．0cM和8．3cM。RpsZS18是D1b连锁群上鉴定的第一个抗疫霉根腐病基因。     

精细定位甜瓜白粉病抗性基因Pm-M

以抗白粉病甜瓜品种MR1与感白粉病新疆地方品种新密1号为亲本,构建BC1P2和F2群体,研究白粉病菌Px1B(P.xanthii race 1B)的抗性遗传规律.以BC1P2与F2群体为试验材料,利用BSA(Bulked segregation analysis)结合分子标记技术发掘多态性信息,并开发分子标记进行抗性基...     

SSR分子标记在作物遗传育种中的应用

SSR(simple sequence repeat)是建立在PCR技术上的一种广泛应用的分子标记,具有含量丰富、多态性高、共显性等优点。本文简要介绍了SSR分子标记技术的原理和特点,重点介绍了SSR分子标记技术在作物遗传育种中的应用,主要在作物遗传多样性、基因定位、分子辅助标记、遗传图谱构建、品种鉴定和纯度鉴定等方面进行阐述。     

PRPS2基因启动子区的单核苷酸多态性(英文)

人类基因组变异主要以单核苷酸多态性 (SNPs)为主 .采用多荧光标记的PCR单链构象多态性分析法 (MF PCR SSCP)对磷酰核糖焦磷酸合成酶亚基Ⅱ (PRPS2 )基因启动子区的序列进行了SNP的筛选 ,对筛选到的阳性片段进行序列分析以确定SNP的类型及位置 .在 1 5kb的启动子区发现了 2个SNP (- 10 79t c ,- 1110a g) .研究结果为PRPS2基因SNPs的数据库提供了新的信息 .     

分子标记技术的发展及应用

介绍了几种应用前景较广的分子标记,如基于DNA杂交技术的分子标记:限制性片段长度多态性(RFLP)和DNA可变串联重复数标记(VNRT);基于PCR技术的分子标记:随机扩增多态性 DNA(RAPD)、酶切扩增多态性(CAPS)、扩增片段长度多态性(AFLP)、微卫星DNA(SSR)和DNA单链构象多态性(SSCP);以及新兴的第3代分子标记,即基于DNA芯片技术的分子标记:单核苷酸多态性(SNP)等。分别阐述了它们的原理、方法步骤与优缺点、应用注意事项和适用范围,同时概述了它们在生物学研究中的应用和进展。     

Genetic mapping of a fusarium wilt resistance gene (Fom-2) in melon (Cucumis melo L.)

Fusarium wilt caused by Fusarium oxysporum f.sp. melonis is one of the most devastating diseases in melon production worldwide. The most effective control measure available is the use of resistant varieties. Identifying molecular markers linked to resistance genes can serve as a valuable tool for the selection of resistant genotypes. Bulked segregant analysis was used to identify markers linked to the Fom-2 genes, which confers resistance to races 0 and 1 of the fungal pathogen. Pooled DNA from homozygous resistant or homozygous susceptible progeny of F₂ cross between MR-1 and AY was screened using 240 PstI/MseI and 200 EcoRI/MseI primer combinations to identify AFLP markers linked to Fom-2. Fifteen markers potentially linked to Fom-2 were identified, all with EcoRI/MseI primer pairs. These were mapped relative to Fom-2 in a backcross (BC) population of 60 progeny derived from MR-1 × AY with AY as recurrent parent. Two AFLP markers (ACT/CAT1 and AAC/CAT1) flanked the gene at 1.7 and 3.3 cM, respectively. Moreover, AFLP marker AGG/CCC and the previously identified RAPD marker 596-1 cosegregated with Fom-2. These two dominant markers were converted to co-dominant markers by designing specific PCR primers that produced product length polymorphisms between the parents. A survey of 45 melon genotypes from diverse geographic origins with the co-dominant markers demonstrated a high correlation between fragment size and the resistance phenotype. These markers may therefore be useful in marker-assisted breeding programs.     

抗白粉病基因PmCH1302的遗传分析及染色体定位

CH1302是以来源于中间偃麦草的八倍体小偃麦TAI7047为桥梁亲本选育的高抗白粉病的小麦新品系,对白粉菌多个流行小种均表现出良好抗性。为了解其抗白粉病基因来源及其在染色体上的位置,对绵阳11×CH1302的F_1、F_2及F_(2∶3)家系进行了遗传分析,推断其抗白粉病基因可能来源于中间偃麦草,暂将其命名为PmCH1302。利用i Select 90K SNP芯片对抗、感病池进行扫描,发现位于2AL染色体上的多态性位点最多,为313个,占全部多态性位点的9.79%,且集中于2AL染色体100~105 c M和150~155 cM两个区域附近。在上述位点选取SSR标记,筛选出3对与Pm CH1302连锁的分子标记,Xwmc522、Xgwm356和Xgwm526,其中Xgwm356和Xgwm526位于Pm CH1302两侧,连锁距离分别为3.1 c M和7.8 cM。利用遗传图谱以及中国春缺体、双端体将PmCH1302定位于小麦2AL染色体上。进一步与位于2AL上的Pm4、Pm50比较发现,PmCH1302可能是位于2AL上的一个新基因或等位基因。     

Developments of functional markers for <Emphasis Type="Italic">Fom</Emphasis>-<Emphasis Type="Italic">2</Emphasis>-mediated fusarium wilt resistance based on single nucleotide polymorphism in melon (<Emphasis Type="Italic">Cucumis melo</Emphasis> L.)

Three single nucleotide polymorphism (SNP) sites in which amino acids had changed were detected by sequence analysis within the leucine-rich repeat (LRR) region of the Fom-2 gene. Cleaved amplified polymorphic sequence (CAPS) and allele-specific PCR (AS-PCR) methods were employed to explore the SNP validation linked to fusarium wilt resistance in the F₁ and F₂ generations simultaneously. Homozygous- and heterozygous-resistant genotypes and homozygous-susceptible genotype could be clearly distinguished using the CAPS method, and three detected SNP sites were observed to be linked to fusarium wilt resistance, with a segregation ratio of 1:2:1 in the F₂ generation. In addition, heterozygous-resistant and homozygous-susceptible genotypes could be clearly distinguished in the F₁ generation using the AS-PCR method, showing a 3:1 segregation in terms of resistant and susceptible genotypes in the F₂ generation. We therefore developed SNP-based functional markers (FMs) and identified some melon germplasm resistant to fusarium wilt by FM analysis within melon species. In conclusion, the SNP-based FMs originating from the SNP site of the Fom-2 LRR region were determined to be linked to fusarium wilt resistance and showed promise in the enhancement of breeding in melon.     

Cloning of disease-resistance homologues in end sequences of BAC clones linked to Fom-2, a gene conferring resistance to Fusarium wilt in melon (Cucumis melo L.).

Disease resistance has not yet been characterized at the molecular level in cucurbits, a group of high-value, nutritious, horticultural plants. Previously, we genetically mapped the Fom-2 gene that confers resistance to Fusarium wilt races 0 and I of melon. In this paper, two cosegregating codominant markers (AM, AFLP marker; FM, Fusarium marker) were used to screen a melon bacterial artificial chromosome (BAC) library. Identified clones were fingerprinted and end sequenced. Fingerprinting analysis showed that clones identified by each marker assembled into two separate contigs at high stringency. GenBank searches produced matches to leucine-rich repeats (LRRs) of resistance genes (R genes); to retroelements and to cellulose synthase in clones identified by FM; and to nucleotide-binding sites (NBSs) of R genes, retroelements, and cytochrome P-450 in clones identified by AM. A 6.5-kb fragment containing both NBS and LRR sequences was found to share high homology to TIR (Toll-interleukin-1 receptor)-NBS-LRR R genes, such as N, with 42% identity and 58% similarity in the TIR-NBS and LRR regions. The sequence information may be useful for identifying NBS-LRR class of R genes in other cucurbits.     

A SNP haplotype associated with a gene resistant to Xanthomonas axonopodis pv. malvacearum in upland cotton (Gossypium hirsutum L.)

An F_4:5 population of 285 families with each tracing back to a different F₂ plant, derived from a cotton bacterial blight resistant line ‘DeltaOpal’ and a susceptible line ‘DP388’, was artificially inoculated with bacterial blight race 18 (Xanthomonas axonopodis pv. malvacearum) to assay their resistance or susceptibility to the disease. The segregation in the F_4:5 population indicates that the resistance was conditioned by a single dominant gene designated B _12. Simple sequence repeat (SSR) markers identified as putatively linked to the resistance gene by bulked segregant analysis were confirmed on the entire F_4:5 population. Three SSR markers, CIR246, BNL3545 and BNL3644 on chromosome 14, were found closely linked to B ₁₂ . The association between CIR246 and B ₁₂ was validated among 354 plants of 16 diverse varieties. Based on Monsanto SSR/single nucleotide polymorphism (SNP) consensus map, SNP markers closely linked to CIR246 were used to screen ‘DeltaOpal’ and ‘DP388’ for polymorphism. The polymorphic SNP markers were run on the F_4:5 population and the four SNP markers spanning 3.4 cM were found to flank the resistance gene on chromosome 14. The linkage between B ₁₂ and the 4-SNP marker haplotype was validated using 18 elite cotton lines. This 4-SNP marker haplotype can be used for marker assisted selection for bacterial blight resistance breeding programs or for screening germplasm collections for this locus rapidly.     

Genetic mapping of the powdery mildew resistance gene in soybean PI 567301B

Powdery mildew (PMD) of soybean [Glycine max (L.) Merr.] is caused by the fungus Microsphaera diffusa. Severe infection of PMD on susceptible varieties often causes premature defoliation and chlorosis of the leaves, which can result in considerable yield losses under favorable environmental conditions for disease development in the field. A total of 334 F(7)-derived recombinant inbred lines (RILs) from a cross of a PMD susceptible soybean cultivar Wyandot and PMD-resistant PI 567301B were used for genetic mapping of PMD resistance in PI 567301B and for development of molecular markers tightly linked to the gene. The result of the PMD screening for each line in the field was in agreement with that in the greenhouse test. The genetic map containing the PMD resistance gene was constructed in a 3.3?cM interval flanked by two simple sequence repeat (SSR) markers on chromosome 16. The PMD resistance gene was mapped at the same location with SSR marker BARCSOYSSR_16_1291, indicating that there was no recombination between the 334 RILs and this marker. In addition, a single nucleotide polymorphism (SNP) marker developed by high-resolution melting curve analysis and a cleaved amplified polymorphic sequence (CAPS) marker with Rsa1 recognition site were used for the genetic mapping. These two markers were also mapped to the same genomic location with the PMD resistance gene. We validated three tightly linked markers to the PMD resistance gene using 38 BC(6)F(2) lines and corresponding BC(6)F(2:3) families. The three marker genotypes of the backcross lines predicted the observed PMD phenotypes of the lines with complete accuracy. We have mapped a putatively novel single dominant PMD resistance gene in PI 567301B and developed three new molecular markers closely linked to the gene. Molecular markers developed from this study may be used for high-throughput marker-assisted breeding for PMD resistance with the gene from PI 567301B.     

设施用厚皮甜瓜品种SSR标记遗传多样性分析

使用分布于甜瓜12条染色体上的72对SSR引物,对我国中东部设施内栽培的30个厚皮甜瓜品种进行分析;56对SSR引物在30个品种间表现为多态性。共检测到138个等位变异,每对引物的等位变异数变幅为2～6个,平均为2.6个。有效等位变异为86.16个,平均为2.25。每个SSR位点的多态性信息量(PIC)变化范围为0.045～0.725,平均为0.390。30个品种间遗传相似系数变幅为0.274～0.974之间,平均值为0.665,且90.4%的供试品种其遗传相似系数在0.474～0.824之间,亲缘关系较近;以遗传相似系数为原始数据,按UPGMA方法将30个品种划分为3大类群,结合系谱分析结果表明,我国中东部设施适宜种植的甜瓜品种遗传多样性不够丰富,多数品种间的亲缘关系较近,欲进一步提高中东部地区设施甜瓜产量和品质还需要拓宽亲本选择范围,扩大遗传背景。     

Fine mapping of the yellow seed locus in Brassica juncea L

The yellow mustard plant in Northern Shaanxi is a precious germplasm, and the yellow seed trait is controlled by a single recessive gene. In this report, amplified fragment length polymorphism (AFLP) and simple sequence repeat (SSR) techniques were used to identify markers linked to the brown seed locus in an F(2) population consisting of 1258 plants. After screening 256 AFLP primer combinations and 456 pairs of SSR primers, we found 14 AFLP and 2 SSR markers that were closely linked to the brown seed locus. Among these markers, the SSR marker CB1022 showed codominant inheritance. By integrating markers previously found to be linked to the brown seed locus into the genetic map of the F(2) population, 23 markers were linked to the brown seed locus. The two closest markers, EA02MC08 and P03MC08, were located on either side of the brown seed locus at a distance of 0.3 and 0.5 cM, respectively. To use the markers for the breeding of yellow-seeded mustard plants, two AFLP markers (EA06MC11 and EA08MC13) were converted into sequence-characterized amplified region (SCAR) markers, SC1 and SC2, with the latter as the codominant marker. The two SSR markers were subsequently mapped to the A9/N9 linkage group of Brassica napus L. by comparing common SSR markers with the published genetic map of B. napus. A BLAST analysis indicated that the sequences of seven markers showed good colinearity with those of Arabidopsis chromosome 3 and that the homolog of the brown seed locus might exist between At3g14120 and At3g29615 on this same chromosome. To develop closer markers, we could make use of the sequence information of this region to design primers for future studies. Regardless, the close markers obtained in the present study will lay a solid foundation for cloning the yellow seed gene using a map-based cloning strategy.     

Inter-simple-sequence-repeat (ISSR) polymorphisms are useful for finding markers associated with disease resistance gene clusters

 We describe a simple and new approach, based on inter-simple sequence repeats (ISSRs), for finding markers linked to clusters of disease resistance genes. In this approach, simple sequence repeats (SSR) are used directly in PCR reactions, and markers found to be linked to disease resistance genes provide important information for the selection of other sequences which can be used with PCR to find other linked markers. Based on an ISSR marker linked to a gene of interest, many new markers can be identified in the same region. We previously demonstrated that ISSR markers are useful in gene tagging and identified a marker, UBC-855₅₀₀, linked to the gene for resistance to fusarium wilt race 4 in chickpea. This ISSR marker provided the information used in the present study for selecting other primers which amplified a region linked to the gene for resistance to fusarium wilt race 4. The primers were based on homology with the (AC)_n sequence and were used for PCR amplifications. Changes in the sequence were at the anchor region of the primers. The repeat (AC)₈T amplified a marker, UBC-825₁₂₀₀, which was located 5.0 cM from the gene for resistance to fusarium wilt race 4 and was closer than other markers. These results indicated that ISSR markers can provide important information for the design of other primers and that by making changes at the 3′ and 5′ anchors close linkage to the desired gene can be found. The approach allows rapid scanning of the targeted region and may provide important information for genome analysis of plant species. Received: 20 January 1998 / Accepted: 19 March 1998