Genetic structure of Mycosphaerella graminicola populations in Iran

To provide insight into the genetic structure of Mycosphaerella graminicola populations in Iran, a total of 221 isolates were collected from naturally infected wheat fields of five major wheat‐growing provinces and analysed using AFLP markers and mating‐type loci. All populations showed intermediate to high genotypic diversity. In the Golestan and Ardabil populations two mating types were found at near‐equal frequencies, whilst all populations were in gametic disequilibrium. Moreover, clonal haplotypes were identified in different sampling sites within a field in both the Khuzestan and Fars provinces, demonstrating that pycnidia are probably the primary source of inoculum. All five populations had low levels of gene diversity and had private bands. Low levels of gene flow and high genetic differentiation were observed among populations and different clustering methods revealed five genetically distinct groups in accordance with the sampling areas. The Golestan and East Azarbaijan populations were more genetically differentiated than the others. Random genetic drift, selection and geographic barriers may account for the differentiation of the populations. The results of this study indicate a population structure of M. graminicola in Iran contrasting to that of most other countries studied.     

Frequency of mutations associated with fungicide resistance and population structure of <Emphasis Type="Italic">Mycosphaerella graminicola</Emphasis> in Tunisia

The occurrence of fungicide resistance in Mycosphaerella graminicola populations from Tunisia was investigated by examining mutations known to be associated with strobilurin and azole resistance. Few mutations associated with fungicide resistance were detected. No evidence for strobilurin resistance was found among 357 Tunisian isolates and only two among 80 sequenced isolates carried mutations associated with azole resistance. A network analysis suggested that these mutations emerged independently from mutations found in previously described European populations. The population genetic structure of M. graminicola in Tunisia was analyzed using variation at 11 microsatellite loci. Populations in Tunisia were characterized by high gene and genotype diversity. All populations were in gametic equilibrium and mating type proportions did not deviate from the 1:1 ratio expected under random mating, consistent with regular cycles of sexual reproduction. In combination with a high degree of gene flow among sampling sites, M. graminicola must be considered a pathogens with high evolutionary potential. Thus, control strategies against Septoria blotch in Tunisia should be optimized to reduce the emergence and spread of resistant isolates.     

Genotypic Diversity of the Wheat Leaf Blotch Pathogen Mycosphaerella Graminicola (anamorph) Septoria Tritici in Germany

The population structure and genotypic diversity of Mycosphaerella graminicola from six natural field populations in Germany were studied with molecular markers. To reveal the potential effects of plant host resistance on the pathogen population, hierarchical samples were taken from susceptible and resistant cultivars. A total of 203 single spore isolates was subjected to molecular marker analysis using the amplified fragment length polymorphism technique (AFLP). Among the 203 isolates analyzed, 142 different multilocus haplotypes (MLH) were identified revealing a high degree of genotypic diversity of the M. graminicola population. On average, a F _ST value of 0.04 was found, indicating a low genetic differentiation with only 4% of the genetic variation between the local populations but leaving 96% of the genetic variation within the populations. According to the low F _ST value, a high migration rate of Nm 12 was found. The observed high within-population diversity, and the significant migration between populations, prevented genetic isolation and differentiation of putative geographically separated populations. Furthermore, plant host resistance had no obvious effect on the population structure and diversity of M. graminicola. Genotypic variability can be attributed to sexual recombination which appears to have a considerably larger influence on the population structure. Gene flow on this scale could have significant implications for plant breeding and fungicide spraying programmes.     

福建省烟粉虱不同地理种群遗传结构特征

为明确福建省烟粉虱种群遗传结构特征,基于福建省烟粉虱不同地理种群中40个代表性的线粒体COI基因序列,分析了种群遗传多样性、遗传分化及分子变异情况,并构建了单倍型系统发育树与网络图。结果显示:在590 bp长度的mt COI基因序列中有效位点558个,其中187个核苷酸位点存在变异;序列核苷酸中A、T、C、G含量分别为42.32%、24.36%、20.25%、13.06%,其中A+T的含量为66.68%,表现出明显的A+T偏向性;共检测出11个单倍型,其中Hap3、4、7、9、11为特殊单倍型;种群多样性指数为0.838,核苷酸多样性指数为0.093,表明遗传多样性水平较高;AMOVA分析表明种群遗传变异主要来自种群内,总种群遗传分化系数仅为0.027,种群遗传分化较低。表明福建烟粉虱种群基因交流未受地理距离明显影响,种群遗传分化不显著。     

Genetic structure of <Emphasis Type="Italic">Fusarium verticillioides</Emphasis> populations isolated from maize in Argentina

Fusarium verticillioides (sexual stage Gibberella moniliformis) is a common fungal pathogen of maize worldwide that also produces fumonisin mycotoxins. Populations of this fungus can be diverse with respect to neutral and selectable genetic markers. We used vegetative compatibility groups (VCGs) and amplified fragment length polymorphisms (AFLPs) to evaluate the genetic structure of three F. verticillioides populations from commercial maize fields in Argentina. Based on work with similar populations from outside South America, we expected individuals within the populations to be genetically diverse, that genotypic variation would be distributed in a manner consistent with random mating, and that populations from different locations would be genetically indistinguishable from one another. We analysed 62 AFLP loci for 133 fungal isolates. All three populations were genotypically diverse but genetically similar and potentially part of a larger, randomly mating population, with significant genetic exchange occurring between the three subpopulations. There was no evidence for linkage disequilibrium at P = 0.05. The low values of G _ST , the lack of frequent private alleles, and the lack of a systemic pattern of linkage disequilibrium all suggest that sexual reproduction is sufficiently common in F. verticillioides and that the dispersal of strains is sufficiently efficient for the population of F. verticillioides in the main maize growing region to be a single randomly mating population with no detectable genetic subdivision. Thus differences in disease and/or toxin production observed in this region are best attributed to differences other than the genetic composition of the population.     

Population genetic structure of Mycosphaerella graminicola and Quinone Outside Inhibitor (QoI) resistance in the Czech Republic

Damage caused by the wheat pathogen Mycosphaerella graminicola increased rapidly during the last two decades in the Czech Republic. We collected isolates from naturally infected fields in seven wheat-growing locations and analysed these using eight microsatellite markers. All markers were highly polymorphic. We found a high degree of genetic diversity and low clonality within all sampled Czech populations. We identified 158 unique multilocus haplotypes among 184 isolates. Field populations showed weak genetic structure but we detected more differentiation between climatic regions within the Czech Republic. We compared the Czech field populations to populations from the United Kingdom, Germany and Switzerland and found a marked differentiation between Czech populations and Western European populations. We hypothesize that decades of different agricultural practices, including the use of different wheat cultivars, may explain this genetic differentiation. We detected a rapid increase in QoI fungicide resistance during the sampling period from 2005 to 2011, coinciding with the widespread application of this class of fungicides in the Czech Republic. M. graminicola populations in the Czech Republic underwent a rapid adaptive evolution from sensitivity to resistance similar to what was described earlier in Western Europe.     

Genetic Structure and Variation in Aggressiveness in European and Australian Populations of the Grapevine Dieback Fungus, Eutypa lata

Eutypa lata is an ascomycete fungus causing a severe dieback in grapevine. The genetic structure of populations of E. lata from seven regions in Australia, France, Italy and Spain was examined using 20 random amplified polymorphic DNA (RAPD) markers. In some regions, populations were subdivided and a total of 14 samples were analysed. A total of 231 RAPD haplotypes were found among the 240 isolates. Vegetative compatibility testing further demonstrated that isolates of the same haplotype were genetically distinct. Gene diversity was the highest in the population from northern Italy and lowest in the Alsace region in France. Linkage disequilibrium between pairs of putative loci was very low and most of the multilocus analyses were consistent with the hypothesis of random association of the loci. This suggests that random mating occurred in every population and that the sexual stage shapes the genetic structure of E. lata populations in the regions sampled. Only 6% of the total variability was attributable to differences between populations. Nevertheless, significant differences in allele frequency appeared with respect to six RAPD markers indicating some genetic differentiation between populations. This differentiation appeared attributable to differences between the Italian and Spanish populations and the other populations. We thus hypothesize that a restriction of gene flow exists within Europe. The population from Australia was genetically closer to the French and Spanish populations than to that from Italy. Genetic diversity is associated with considerable variation in aggressiveness, which was assessed on cuttings in the greenhouse in six populations. All populations included a range of isolates differing in aggressiveness, but the Italian population seemed to have more isolates with low aggressiveness.     

Genetic Structure of Rhynchosporium secalis in Australia

ABSTRACT Restriction fragment length polymorphism (RFLP) markers were used to determine the genetic structure of Australian field populations of the barley scald pathogen Rhynchosporium secalis. Fungal isolates were collected by hierarchical sampling from five naturally infected barley fields in different geographic locations during a single growing season. Genetic variation was high in Australian R. secalis populations. Among the 265 fungal isolates analyzed, 214 distinct genotypes were identified. Average genotype diversity within a field population was 65% of its theoretical maximum. Nei's average gene diversity across seven RFLP loci was 0.54. The majority (76%) of gene diversity was distributed within sampling site areas measuring 1 m(2); 19% of gene diversity was distributed among sampling sites within fields; and 5% of gene diversity was distributed among fields. Fungal populations from different locations differed significantly both in allele frequencies and genotype diversities. The degree of genetic differentiation was significantly correlated with geographic distance between populations. Our results suggest that the R. secalis population in Western Australia has a different genetic structure than populations in Victoria and South Australia.     

Comparison of natural populations of Mycosphaerella graminicola from single fields in Kansas and California

Kansas and California wheat-growing regions differ dramatically in soils, climate, wheat cultivars, crop rotation patterns, and cultural practices, which could select for different fungal populations of Mycosphaerella graminicola. Our objective in this study was to use amplified fragment length polymorphism (AFLP) loci to assess the genetic diversity of M. graminicola populations within single fields in two widely separated, and geographically isolated sites in Kansas and California. Three primer-pair combinations were used to resolve polymorphism at 177 loci in 67 and 63 isolates from Kansas and California, respectively. Genotypic variability was high, which is consistent with a genetically diverse initial inoculum. There was no evidence of genetic disequilibrium in either population, with only 4.6% of the locus pairs in Kansas, and 5.4% of the locus pairs in California in detectable disequilibrium. The migration rate calculated between the two sites was as low as 1.8 individuals per generation, and significant differences in allele frequencies were observed. Therefore, these two populations do not represent mere subsamples of a larger, randomly mating population. This is a rare report of isolation by distance occurring between two North American populations of M. graminicola, indicating that at least some of these populations may be differentiating. Although genetic isolation by distance may occur, we cannot exclude movement of new gene combinations such as fungicide resistance or virulence between these two locations.     

The Genetic Structure of Australian Populations of Mycosphaerella musicola Suggests Restricted Gene Flow at the Continental Scale

ABSTRACT Mycosphaerella musicola causes Sigatoka disease of banana and is endemic to Australia. The population genetic structure of M. musicola in Australia was examined by applying single-copy restriction fragment length polymorphism probes to hierarchically sampled populations collected along the Australian east coast. The 363 isolates studied were from 16 plantations at 12 sites in four different regions, and comprised 11 populations. These populations displayed moderate levels of gene diversity (H = 0.142 to 0.369) and similar levels of genotypic richness and evenness. Populations were dominated by unique genotypes, but isolates sharing the same genotype (putative clones) were detected. Genotype distribution was highly localized within each population, and the majority of putative clones were detected for isolates sampled from different sporodochia in the same lesion or different lesions on a plant. Multilocus gametic disequilibrium tests provided further evidence of a degree of clonality within the populations at the plant scale. A complex pattern of population differentiation was detected for M. musicola in Australia. Populations sampled from plantations outside the two major production areas were genetically very different to all other populations. Differentiation was much lower between populations of the two major production areas, despite their geographic separation of over 1,000 km. These results suggest low gene flow at the continental scale due to limited spore dispersal and the movement of infected plant material.     

Genetic diversity of the weed species,Stellera chamaejasme,in China inferred from amplified fragment length polymorphism analysis

Stellera chamaejasme is a perennial weed with a wide geographic range that is found from the Altai of eastern Russia, northern China and Mongolia southwards as far as the western Himalayas of the Qinghai–Tibet and Yungui Plateaus. The genetic diversity and population structure of 17 populations of S. chamaejasme, represented by 349 individuals, were assessed by using amplified fragment length polymorphism markers. The results showed a relatively high level of genetic variation at the species level. The proportion of total diversity among populations was 0.4370, suggesting significant genetic differentiation and a low gene flow among the populations of this species. The Mantel test indicated that genetic differentiation among populations was significantly correlated with geographic distance. Genetic drift through range expansion and a low gene flow among populations might result in a lower diversity in peripheral populations, compared to central populations. A Bayesian analysis revealed two potential gene pools in S. chamaejasme, which was confirmed by neighbor‐joining clustering and principal coordinate analysis. These results demonstrate that it is necessary to develop suitable biocontrol agents for populations with different gene pools.     

北京及周边地区九个地理种群的亚洲小车蝗mtDNA ND6基因及其部分侧翼序列分析

为明确北京地区亚洲小车蝗Oedaleus asiaticus Bey-Bienko的迁飞来源,选取包含完整线粒体DNA的ND6、tRNA-Thr基因及侧翼ND4L、CYTB基因部分序列作为目的片段,采用DNA序列法分析来自北京及周边省市9个地理种群155个亚洲小车蝗样本的序列碱基组成、种群遗传多样性、种群结构及单倍型网络进化等。结果表明:在目的序列中共检测到多态性位点16个,鉴定出单倍型20种,分别占碱基总数和总样品量的1.88%和12.90%;核苷酸多样性为0.0012,单倍型多样性为0.66,种群间遗传分化系数绝对值≤0.51,种群内个体间遗传变异占总变异的86.88%,各种群遗传变异与空间距离间无显著相关性,供试样本总体上遗传变异程度相对较低。北京密云种群鉴定出的独享单倍型H14由单倍型H10经2次突变获得,H10被锡林郭勒和乌兰察布种群共享;北京密云与河北滦平、围场及内蒙古乌兰察布种群间基因流Nm绝对值分别为3.749、1.387和0.912,均高于密云种群与其它种群间的Nm绝对值;结合亚洲小车蝗在北京及周边地区出现的先后时序可知,内蒙古锡林郭勒、乌兰察布及河北滦平、围场是北京地区亚洲小车蝗的最主要迁飞来源。     

Genetic variation and structure of Solanum elaeagnifolium in Australia analysed by amplified fragment length polymorphism markers

Solanum elaeagnifolium is a weed of national significance in Australia. However, the genetic diversity of S. elaeagnifolium is poorly understood. Four amplified fragment length polymorphism primer combinations were utilised to investigate the genetic variation and structure of 187 S. elaeagnifolium individuals collected from 94 locations in Australia. High genetic diversity was found, with an average Jaccard's genetic similarity at 0.26. Individuals were assigned to two genetic clusters or considered as admixed according to their membership coefficient value (q) calculated by Bayesian model‐based genetic structure analysis. This suggested that Australian S. elaeagnifolium may have originated from two distinct gene pools. These results were further supported by principal co‐ordinates analysis. Large spatial groups of individuals assigning to these two gene pools were found in western Victoria and south‐western New South Wales (NSW) and northern NSW, which correlated well with the early records of S. elaeagnifolium in both regions. The high genetic diversity found here could add difficulties to effective control of S. elaeagnifolium across regions.     

Microsatellite DNA variation within and among invasive populations of Ambrosia artemisiifolia from the southern Pannonian Plain

Although the Pannonian Plain presents one of the areas in Europe most highly infested by Ambrosia artemisiifolia, previously reported population genetic studies of the invasive species have included only a few populations from this region. Our goal was to determine the level of genetic diversity and genetic structure of A. artemisiifolia populations from the southern Pannonian Plain using microsatellite DNA markers. We documented a high level of genetic diversity within the Pannonian populations, as compared with the genetic diversity parameters previously published for the other invasive populations of A. artemisiifolia in Europe. The mean number of alleles per locus (N_A) ranged between 6.8 and 9.4, allelic richness (r) between 6.59 and 8.53 and mean number of rare alleles per locus (N_R) ranged between 3.4 and 6.4 per analysed population. A low level of among‐population differentiation was detected, with percentage of variation between populations of 3.3%, generally low pairwise F_ST values (ranged from ?0.007 to 0.152) and also according to principal coordinate analysis. A Bayesian approach revealed that most individuals did not strongly associate with any single genetic cluster, confirming a lack of genetic structuring in the analysed region. Together with the results of quantification of the level of gene flow (N_m = 5.671), these observations indicated a presence of extensive gene exchange and admixture between the populations. Therefore, A. artemisiifolia in the Pannonian Plain region has the potential for rapid expansion.     

SnToxA,SnTox1, and SnTox3 originated in Parastagonospora nodorum in the Fertile Crescent

The centre of origin of the globally distributed wheat pathogen Parastagonospora nodorum has remained uncertain because only a small number of isolates from the Fertile Crescent were included in earlier population genetic and phylogeographic studies. We isolated and genetically analysed 193 P. nodorum strains from three naturally infected wheat fields distributed across Iran using 11 neutral microsatellite loci. Compared to previous studies that included populations from North America, Europe, Africa, Australia, and China, the populations from Iran had the highest genetic diversity globally and also exhibited greater population structure over smaller spatial scales, patterns typically associated with the centre of origin of a species. Genes encoding the necrotrophic effectors SnToxA, SnTox1, and SnTox3 were found at a high frequency in the Iranian population. By sequencing 96 randomly chosen Iranian strains, we detected new alleles for all three effector genes. Analysis of allele diversity showed that all three effector genes had higher diversity in Iran than in any population included in previous studies, with Iran acting as a hub for the effector diversity that was found in other global populations. Taken together, these findings support the hypothesis that P. nodorum originated either within or nearby the Fertile Crescent with a genome that already encoded all three necrotrophic effectors during its emergence as a pathogen on wheat. Our findings also suggest that P. nodorum was the original source of the ToxA genes discovered in the wheat pathogens Phaeosphaeria avenaria f. sp. tritici 1, Pyrenophora tritici-repentis, and Bipolaris sorokiniana.     

Genetic variation,vegetative compatibility,and aggressiveness diversity of Diplodia bulgarica isolates from apple orchards in West Azarbaijan province of Iran

This study investigated inter-simple sequence repeat (ISSR), vegetative compatibility, and aggressiveness diversity in 101 isolates of Diplodia bulgarica recovered from apple trees displaying symptoms of canker and decline in West Azarbaijan province of Iran. Marker analyses revealed high within population diversity, low genetic differentiation, high gene flow, and sharing of multilocus genotypes (MLGs) among geographic populations. Moreover, clustering and multivariate analyses identified two highly differentiated genetic clusters with limited admixture between them. These findings may suggest that the pathogen has been introduced from two genetically divergent sources and has been moved within the region through infected materials. The large number of MLGs, low clonal fraction, and absence of a widely distributed dominant genotype may explain the occurrence of recombination in this pathogen. However, significant linkage disequilibrium in the populations and limited admixture between genetic clusters may indicate the rare occurrence of recombination in D. bulgarica populations in West Azarbaijan, and that the pathogen has not been in the province long enough to reach equilibrium. Vegetative compatibility analyses revealed the occurrence of anastomosis between nonself pairings and high vegetative compatibility group diversity within populations. All studied MLGs produced necrotic lesions on detached shoots of Red Delicious apple but differed in their aggressiveness levels. Our results provide new insights into genetic and phenotypic variation of D. bulgarica that can assist in developing management strategies. Our findings also highlight the vital need for quarantine measures and the production of healthy plant materials to prevent the introduction and spread of the pathogen in Iran.     

云南省小麦条锈菌不同地理亚群体的遗传结构分析

为明确云南省小麦条锈菌（Puccinia striiformis f. sp. tritici,Pst）在不同地理环境下的群体遗传结构,通过3种不同地理亚群体划分方式,即以县域（Group C）、区域（Group R）和海拔（Group E）对云南省537个Pst单孢系进行不同层次的群体划分,并利用12对SSR引物对其进行遗传多样性和群体遗传结构分析。结果显示,云南省Pst的遗传多样性水平在Group C的亚群体之间差异最大,且来自滇中及滇东北地区的Pst群体的遗传多样性较高。Group R和Group E的亚群体基因流及遗传分化结果表明,云南省Pst菌源交流频繁、遗传分化较小。系统进化树分析结果显示,滇东北与滇中Pst群体类似,滇东南与滇西Pst群体类似。Pst遗传组分呈现出由东向西、由北向南和自低海拔向高海拔变化的趋势,与云南省自东南向西北逐渐攀升的地形及地势吻合。Mantel检验结果表明地理距离与遗传距离不存在相关性,在8个县域亚群体、2个区域亚群体检测到有性生殖。表明来自滇中和滇东北地区的Pst群体具有更高的遗传多样性,地理隔离可能是滇西地区遗传多样性较低的成因,遗传分化发生在...     

甘肃中部及周边地区小麦条锈菌种群的遗传结构分析

为明确甘肃中部与周边地区小麦条锈菌种群的遗传结构及关系,利用SSR分子标记技术对采自甘肃、陕南、青海及新疆等7个地区共369份小麦条锈病菌标样的群体遗传结构进行了分析。结果表明,小麦条锈菌群体Nei’s基因多样性指数为0.39、Shannon信息指数为0.57,各地区条锈菌群体遗传多样性较为丰富,且在不同地区之间存在明显差异,7个条锈菌群体中以天水种群的遗传多样性相对较高,其Nei’s基因多样性指数为0.42、Shannon信息指数为0.61。该地区小麦条锈菌群体间和群体内都存在着一定的遗传分化,群体间遗传变异占总变异的2.24%,群体内遗传变异占总变异的97.76%。表明甘肃中部及周边地区小麦条锈菌群体存在一定的遗传分化,但遗传变异主要发生在群体内部;甘肃中部、陇南及陕南3地的小麦条锈菌种群遗传相似度较高,菌源交流密切。     

内蒙古亚洲小车蝗种群遗传多样性和遗传分化的ISSR分析

亚洲小车蝗Oedaleus asiaticus Bei-Bienko是我国北方草原和农牧交错区的主要害虫。为评价内蒙古地区亚洲小车蝗种群的遗传多样性和遗传分化,应用ISSR标记方法对内蒙古15个亚洲小车蝗种群遗传多样性及遗传分化进行了分析。结果表明,7条引物扩增出85条ISSR条带,均为多态性条带。多态性比例（P）、Nei''s遗传多样性指数（H）和香农多样性指数（I）分别为82.59%、0.2319和0.3421,表明亚洲小车蝗种群具有较高的遗传多样性。基因流（Nm）和基因分化系数（Gst）分别为1.2298和0.3352,表明亚洲小车蝗不同地理种群具有明显的遗传分化。遗传距离与地理距离呈极显著正相关关系。表明地理距离和地形差异可能是形成亚洲小车蝗种群遗传分化的主要原因。     

山东省不同地理种群棉铃虫的遗传结构

为明确棉铃虫Helicoverpa armigera（Hübner）在山东省不同地理种群的遗传分化及遗传多样性，对采集得到的山东省14个棉铃虫种群共109个样本进行线粒体细胞色素氧化酶亚基（I mito‐chondrial cytochrome oxidase I，mt COI）及亚基II (mitochondrial cytochrome oxidase I，mt COII）基因片段测序，并进行遗传多样性分析，探究其在山东省的种群遗传变异情况。结果表明，棉铃虫mt COI及mt COII基因拼接（1 306 bp）共有18个单倍型Hap1~Hap18，其中Hap2和Hap3单倍型包含的个体数量最多，分别为37个和20个。莱阳种群的单倍型多样性最高，为1.000，莱西种群的核苷酸多态性最高，为0.004 5，14个棉铃虫种群的总体固定系数F_ST值为0.028，说明棉铃虫种群之间几乎没有遗传分化。GENEPOP分析表明种群间遗传距离和地理距离无显著相关性。表明山东省不同地区棉铃虫遗传分化较低，各地区种群间没有显著的遗传差异。