Sugar-specific Attachment of Pseudomonas syringae pv. glycinea to Isolated Single Leaf Cells of Resistant Soybean Cultivars

Phase-contrast and scanning electron microscopy showed races of P. synngae pv. glycinea uniformly distributed over and attached to the whole surface of isolated single leaf cells of resistant soybean cultivars, as early as 30 to 180 min after inoculation. On the contrary, attachment in the compatible interaction did not occur within 10—15 h. In a later period, compatibility was characterized by the formation of adherent bacterial clusters. Early attachment of races 1 and 6 to cv. Harosoy and that of race 5 to cv. Flambeau leaf cells, each representing incompatible interaction, could be inhibited by L-rhamnose and D-glucose, respectively. Furthermore, the lack of Mn²⁺ and Fe²⁺ and heat-treatment of plant cells also affected the early attachment in incompatible combinations and resulted in cluster formation, suggesting incompatibility rather than compatibility to be the active phenomenon. Pre-inoculation of cells with an incompatible race induced changes that caused compatible bacteria also to distributively attach to plant cell surface indicating that a transfer of information or surface alterations occur upon attachment in incompatible interaction.     

Host-Pathogen Interactions : XX. BIOLOGICAL VARIATION IN THE PROTECTION OF SOYBEANS FROM INFECTION BY PHYTOPHTHORA MEGASPERMA F. SP. GLYCINEA

Phytophthora megasperma f.sp. glycinea, which causes soybean (Glycine max) root and stem rot, exists as several races which differ in their ability to infect a range of soybean cultivars. A glycoprotein-rich fraction (Fraction I) isolated from fungal culture fluid protects soybean seedlings from infection with compatible races. In an early study (13), seedlings were protected only by Fraction I purified from incompatible races. In 1979, seedlings were better protected by Fraction I isolated from incompatible races than by Fraction I isolated from compatible races. In 1980, seedlings were protected equally well by Fraction I from incompatible and compatible races. Materials similar in composition to Fraction I did not protect seedlings from infection. No cause could be identified for the apparent change, during the 3-year period, in the race specificity of the protection assay. Variability in the bioassay prohibited further purification or characterization of Fraction I components that protect seedlings from infection.     

Genes required for pathogenicity and hypersensitivity are conserved and interchangeable among pathovars of Pseudomonas syringae

Summary A group of pathogenicity genes was previously identified in Pseudomonas syringae pv. phaseolicola which controls the ability of the pathogen to cause disease on bean and to elicit the hypersensitive response on non-host plants. These genes, designated hrp, are located in a ca. 20 kb region which was referred to as the hrp cluster. Homologous sequences to DNA segments derived from this region were detected in several pathovars of P. syringae but not in symbiotic, saprophytic or other phytopathogenic bacteria. A Tn5-induced Hrp^- mutation was transferred from P. syringae pv. phaseolicola to P. syringae pv. tabaci and to three races of P. syringae pv. glycinea by marker exchange mutagenesis. The resulting progeny were phenotypically Hrp^-, i.e. no longer pathogenic on their respective hosts and unable to elicit the hypersensitive response on non-host plants. These mutants were restored to wild-type phenotype upon introduction of a recombinant plasmid carrying the corresponding wild-type locus from P. syringae pv. phaseolicola. The marker exchange mutants of P. syringae pv. glycinea psg0 and Psg5 which carry different avr genes for race specific avirulence did not elicit a hypersensitive response on incompatible soybean cultivars. It appears, therefore, that P. syringae pathovars possess common genes for pathogenicity which also control their interaction with non-host plants. Furthermore, the expression of race/cultivar specific incompatibility of P. syringae pv. glycinea requires a fully functional hrp region in addition to the avr genes which determine avirulence on single-gene differential cultivars of soybean.     

Virulence of Phytophthora sojae in the Pampeana Subregion of Argentina from 1998 to 2004

Phytophthora root rot is one of the most serious diseases of soybeans in Argentina. Surveys of commercial fields and trial plots of soybean were conducted throughout the northern Pampeana subregion (Argentina) between 1998 and 2004. A total of 193 isolates of Phytophthora sojae were collected and classified into races or virulence formulae. Among the 173 isolates tested on 8 differentials, 42 different pathotypes were detected, including 18 described races. Races 1, 4, 5, 7, 9, 13, 23 and 24 were found in both plants and soils, whereas races 2, 3, 6, 8, 11, 14, 15, 17, 43 and 44 were only isolated from plants. An additional 19 pathotypes were described from 20 isolates tested in Canada on the expanded set of 14 differential cultivars. Currently, all Rps genes/alleles associated with resistance have been defeated, indicating an increased complexity of virulence within the P. sojae populations in the region. The great increase in virulence complexity found in this study is most likely a result of a long period of continuous production of soybean cultivars with Rps genes and the extensive adoption of the no‐tillage system.     

Races of Phytophthora megasperma f.sp. glycinea (Phytophthora Rot) Affecting Soybeans in North Alabama

Phytophthora megasperma Drechs. f. sp. glycinea Kuan and Erwin (Pmg) was isolated for the first time from the northern counties of Alabama (MORGAN and MADISON). TWO predominant Pmg races, R₂ and R₁₁, were identified by the reactions of standard soybean differential cultivars. Other soil-borne pathogens isolated from the soil and suspected Pmg-affected root samples in Morgan, Adadison, and Limestone counties were Pytbium spp., Fusarium ssp., Sclerotium rolfsii, and Rbizoctonia solani. Further study is in progress to obtain a proper assessment of Pmg races in Alabama.     

Variation in Resistance of Soybean Lines to Races of Heterodera glycines

The objective of this study was to determine the interrelationships of Heterodera glycines races based on their resistance to soybean (Glycine max) cultivars and lines against which they were tested. Greenhouse tests determined the numbers of females of each of eight races of H. glycines that developed on 277 to 522 soybean cultivars and lines. A Female Index (number of females on a test cultivar as a percentage of the number on ''Lee 74'') was calculated and used in frequency distributions, correlations, and duster analyses of the resistance reactions to the different races in an attempt to determine relationships among cultivars. Frequency distribution patterns of all cultivars and lines tested against each race were skewed in favor of resistance, and in some cases bimodality was observed. The majority of correlations between pairs of races were highly significant. Cluster analyses based on the correlations divided eight races into four clusters that explained 73% of the variation in resistance. Cluster 1 was comprised of races 2, 4, and 14; Cluster 2 was comprised of races 6 and 9; Cluster 3 was comprised of races 1 and 3; and Cluster 4 was comprised of race 5. The information obtained in this study could increase the efficiency of testing resistant soybean breeding lines for resistance to H. glycines.     

Complete Characterization of the Race Scheme for Heterodera glycines

One hundred thirty-eight isolates of Heterodera glycines from nine states in the United States, People''s Republic of China, and Indonesia were tested on the four standard soybean race differentials. A total of 12 variants were found, including the five races described previously. The seven variants that did not correspond to one of the described races and reports from other areas of populations that could not be classified are evidence that the present race classification system needs to be fully characterized. Eleven additional races are described; this expands the total to 16 races, the maximum possible using the four prescribed differentials and a + or - rating for each. The seven new races are designated as 6, 9, 10, 13, 14, 15, and 16. This complete characterization of the race scheme will allow for immediate communication of the discovery of the remaining four races plus the identification of previous undescribed races.     

Pathogenic Variability in Colletotrichum lindemuthianum and Evaluation of Resistance in Phaseolus vulgaris in the North-Western Himalayan Region of India

Eightyfive isolates of Colletotrichum lindemuthianum (bean anthracnose) collected from different kidney bean growing areas of a hilly state (Himachal Pradesh) of India, were characterized on the basis of their reaction types on International and CIAT differentials. On international differentials, 12 races viz., Alpha-Brazil, Beta, Gamma and Ind I to Ind IX were characterized. The races designated as Ind I to Ind IX were different from those identified in Europe and USA, thus forming a new race group from the Indian subcontinent. On the CIAT differential set the 85 isolates have been grouped into 19 races. Of these, only races 65 and 73 resembled the North American races. Exotic accessions AB 136 and G 2333 were resistant to all the Indian races. However, race specific resistance has been found in a number of indigenous and exotic genotypes of Phaseolus vulgaris.     

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.     

Identification of a New Race of Sporisorium reilianum and Characterization of the Reaction of Sorghum Lines to Four Races of the Head Smut Pathogen

Sporisorium reilianum is the causal agent of head smut on sorghum and maize. In order to effectively utilize host resistance to control this important disease in crops, it is necessary to monitor changes in disease dynamics and virulence of the pathogen. An outbreak of head smut was recently observed in a sorghum field, near Gaoping, Shanxi, China, and research was undertaken to characterize a putative new race of S. reilianum. A set of differential sorghum lines with resistance to several conventional races was used to characterize the newly collected isolate of S. reilianum. The reactions of differential cultivars/germplasm lines to the new isolate indicate that it is a new physiological race of S. reilianum. The new race is highly virulent on sorghum line A₂V4 and its hybrid, Jinza 12, that are known as resistant to all existing Chinese races of S. reilianum, including races 1, 2, and 3. The new isolate of S. reilianum is different from all of the described races of the pathogen; thus, it is designated as race 4 of S. reilianum. Furthermore, a collection of 34 sorghum genotypes including commercial cultivars and germplasm lines was evaluated for disease reaction to the newly described race and the three known races of the pathogen.     

Effects of temperature on germination and mitochondrial dehydrogenases in two soybean (Glycine max) cultivars

The effects of eight germination temperatures from 10°C to 35°C on germination and dehydrogenase activities of two soybean (Glycine max [L.] Merr.) cultivars were investigated after 48 h of seedling growth. Axis fresh weights of cv. Chippewa increased as germination temperature increased from 10°C to 35°C. In contrast, axis fresh weights for the cv. Wells increased more slowly with increasing temperature and reached a maximum at c. 25°C. In general, in vitro activities of glutamate dehydrogenase (GDH), NADP-isocitrate dehydrogenase (NADP-ICDH), and malate dehydrogenase (MDH) from the axes of cv. Chippewa correlated well with increases in axis fresh weights. GDH and MDH activities from axes of the cv. Wells also reflected increases in axis fresh weights although the correlation was not as evident as for the cv. Chippewa. NADP-ICDH activity from ‘Wells’ axes was highest at 35°C even though germination was poor at this temperature. GDH and MDH activities from cotyledons of both cultivars were not correlated with axis weight increases. No GDH activity was detected in ‘Wells’ cotyledons from seeds germinated at 35°C.     

New Races of Sunflower Downy Mildew (Plasmopara Halstedii) in Germany

Plasmopara halstedii, the causal agent of downy mildew of cultivated sunflower (Helianthus annuus), was documented in Germany for the first time in commercial fields. The pathogen was first observed in the Württemberg area, where races 1 and 4 were identified using a set of differential lines. Later, commercial fields near Baden were found to be infected by race 5, which is the first occurrence of that race outside of North America. With the discovery of race 5, there are now eight races of the sunflower downy mildew fungus that have been found in Europe. The sunflower cultivars most frequently grown in Germany were investigated for resistance to race 1, 4 and 5; while all were resistant to race 1, none were resistant to either race 4 or 5.     

Characterization of the Virulence Phenotypes of Heterodera glycines in Minnesota

Knowledge of the virulence phenotypes of soybean cyst nematode, Heterodera glycines populations is important in choosing appropriate sources for breeding resistant cultivars and managing the nematode. We investigated races of 59 H. glycines populations collected from 1997 to 1998 and races and HG Types of 94 populations collected in 2002 from soybean fields across southern and central Minnesota. In the 1997 to 1998 samples, race 3 was predominant and represented 78% of the populations. The remaining populations were 11.9% race 1, 1.7% race 4, 6.8% race 6, and 1.7% race 14. In the 2002 samples, the populations were classified as 15.3% race 1, 77.6% race 3, 2.4% race 5, 3.5% race 6 and 1.2% race 9. Percentage of 1997 to 1998 populations with female indices (FI) higher than 10 were 10.2% on Pickett 71, 3.4% on Peking, 13.6% on PI 88788, 3.4% on PI 90763, 1.7% on PI 209332, and 1.7% on PI 437654. Percentage of 2002 populations with FI >10 was 1.1% on Peking, 17.0% on PI88788, 14.9% on PI 209332, 33.0% on PI 548316, 11.7% on Pickett 71, and 0% on the other three indicators, PI 90763, PI 437654, and PI 89772. The line PI 548316 was relatively susceptible to the Minnesota H. glycines populations and may not be recommended for breeding resistant cultivars in the state. There was no noticeable change of frequencies of virulence phenotypes in response to the use of resistant cultivars during 1997 to 2002 in Minnesota except that FI increased on the PI 209332.     

New Races of Sunflower Downy Mildew (Plasmopara Halstedii) in Germany

Plasmopara halstedii, the causal agent of downy mildew of cultivated sunflower (Helianthus annuus), was documented in Germany for the first time in commercial fields. The pathogen was first observed in the Württemberg area, where races 1 and 4 were identified using a set of differential lines. Later, commericial fields near Baden were found to be infected by race 5, which is the first occurrence of that race outside of North America. Withthe discovery of race 5, there are now eight races of the sunflower downy mildew fungus that have been found in Europe. The sunflower cultivars most frequently grown in Germany were investigated for resistance to race 1, 4 and 5; while all were resistant to race 1, none were resistant to either race, 4 or 5.     

Gaps and perspectives of pathotype and race determination in <Emphasis Type="Italic">Golovinomyces cichoracearum</Emphasis> and <Emphasis Type="Italic">Podosphaera xanthii</Emphasis>

Golovinomyces cichoracearum and Podosphaera xanthii (family Erysiphaceae) are the most important species causing cucurbit powdery mildew (CPM), a serious disease of field and greenhouse cucurbits. Both species are highly variable in their pathogenicity and virulence, as indicated by the existence of large number of different pathotypes and races. Various independent systems of CPM pathotype and race determinations and denominations are used worldwide. CPM pathotype identification is based on intergeneric and interspecific differences in host-CPM interactions. The most commonly used set of CPM pathotype differentials includes one genotype from four species representing three agriculturally important cucurbit genera plus two genotypes from a fifth species, melon Cucumis melo L. CPM races are characterized by specialization on different cultivars or lines of one host species and have, to date, been differentiated only on melon (C. melo L.). The most frequently used set of melon differentials includes 11 genotypes that can differentiate CPM races originating from melon and other cucurbits, e.g., cucumber, Cucurbita spp., and watermelon. In this paper, we critically review the current state, gaps, and perspectives in our understanding of pathogenicity variation in these two CPM pathogens at the pathotype and race levels.     

Races and virulence of Fusarium oxysporum f.sp. cubense on local banana cultivars in Kenya

Virulence of 31 Kenyan isolates of Fusarium oxysporum obtained from bananas showing symptoms of Panama disease was tested against the differential banana cvs Bluggoe, Gros Michel, Dwarf Cavendish, and two other local cvs Muraru and Wang'ae. Seventeen isolates were assigned to either race 1 or race 2 of F. oxysporum f.sp. cubense (FOC). Race 4 was not apparent in this sample of 31 isolates from Kenya as none were pathogenic to cv. Cavendish, and no wilted Cavendish have been observed in field surveys in Kenya. Races could not be assigned to 12 isolates as they were virulent on more than one differential cultivar, and two were apparently not pathogenic. All isolates assigned to races 1 and 2 belonged to the VCG bridging complex 0124/5/8/20, but some other isolates belonging to this VCG complex could not be assigned to race. All five isolates assigned to VCG 01212 could not be assigned to known races. Considerable variability thus exists within FOC isolates within this region. Local cultivars of banana showed differential resistance to the pathogen. The interaction of cultivars and isolates on the level of disease was significant. Overall, cv. Wang'ae was the most susceptible to most of the isolates tested, regardless of their race, and could therefore be used as a reference cultivar in pathogenicity tests of isolates of FOC in the East African region. Of the cultivars tested that are widely grown on smallholder farms in Kenya, Muraru was the least susceptible.     

Genetic dissection of the resistance to nine anthracnose races in the common bean differential cultivars MDRK and TU

Resistance to nine races of the pathogenic fungus Colletotrichum lindemuthianum, causal agent of anthracnose, was evaluated in F₃ families derived from the cross between the anthracnose differential bean cultivars TU (resistant to races, 3, 6, 7, 31, 38, 39, 102, and 449) and MDRK (resistant to races, 449, and 1545). Molecular marker analyses were carried out in the F₂ individuals in order to map and characterize the anthracnose resistance genes or gene clusters present in these two differential cultivars. The results of the combined segregation indicate that at least three independent loci conferring resistance to anthracnose are present in TU. One of them, corresponding to the previously described anthracnose resistance locus Co-5, is located in linkage group B7, and is formed by a cluster of different genes conferring specific resistance to races, 3, 6, 7, 31, 38, 39, 102, and 449. Evidence of intra-cluster recombination between these specific resistance genes was found. The second locus present in TU confers specific resistance to races 31 and 102, and the third locus confers specific resistance to race 102, the location of these two loci remains unknown. The resistance to race 1545 present in MDRK is due to two independent dominant genes. The results of the combined segregation of two F₄ families showing monogenic segregation for resistance to race 1545 indicates that one of these two genes is linked to marker OF10₅₃₀, located in linkage group B1, and corresponds to the previously described anthracnose resistance locus Co-1. The second gene conferring resistance to race 1545 in MDRK is linked to marker Pv-ctt001, located in linkage group B4, and corresponds to the Co-3/Co-9 cluster. The resistance to race 449 present in MDRK is conferred by a single gene, located in linkage group B4, probably included in the same Co-3/Co-9 cluster. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Molecular characterization of cloned avirulence genes from race 0 and race 1 of Pseudomonas syringae pv. glycinea.

A wide-host-range cosmid cloning vector, pLAFR3, was constructed and used to make cosmid libraries of partially digested Sau3A DNA from race 0 and race 1 of Pseudomonas syringae pv. glycinea. Two avirulence genes, avrB0 and avrC, cloned from race 0, elicited the hypersensitivity reaction (HR) on specific cultivars of soybean. Race 4 transconjugants containing avrB0 induced a dark brown necrotic HR within 24 h on the soybean cultivars Harosoy and Norchief, whereas race 4 transconjugants containing avrC induced a light brown necrotic HR within 48 h on the soybean cultivars Acme, Peking, Norchief, and Flambeau. An additional avirulence gene, avrB1, cloned from race 1, appeared to be identical to avrB0 from race 0. The avrB0 and avrC genes from race 0 were characterized by restriction enzyme mapping, Southern blot analysis, Tn5 transposon mutagenesis, and site-directed gene replacements. The effects of these three genes on the in planta bacterial growth of race 4 transconjugants have also been examined. The identification and cloning of avrB1 provides genetic evidence for a gene-for-gene interaction in the bacterial blight disease of soybean, as avrB1 from race 1 interacts with the soybean disease resistance locus, Rpg1.     

Distribution and Races of Xanthomonas axonopodis pv. malvacearum on Cotton (Gossypium hirsutum) in Uganda

Surveys in 1995 and 1996 showed that bacterial blight caused by Xanthomonas axonopodis pv. malvacearum occurs throughout the main cotton growing areas of Uganda, causing seedling blight, angular leaf spot and bacterial boll rot. During the vegetative and early fruiting stages of crop growth, severe symptoms of `blackarm' spread from leaves to the stem, causing loss of fruiting branches. A set of Upland cotton cultivars ( Gossypium hirsutum ) were then used to determine the races of the blight bacterium present in Uganda. Many of the isolates induced moderate to severe symptoms on all the test hosts except 101–102B, indicating infection with race 10 or 18. The next most common isolate was race 7. Races 16 and 6 were also identified and 23% of isolates caused symptoms on all the differential cultivars including 101–102B, results indicating the presence of a race of the pathogen which may be the same as that identified in countries neighbouring Uganda and designated as race 20.     

Resistance to recombinant stem rust race TPPKC in hard red spring wheat

The wheat (Triticum aestivum L.) stem rust (Puccinia graminis Pers.:Pers. f.sp. tritici Eriks. and Henn.) resistance gene SrWld1 conditions resistance to all North American stem rust races and is an important gene in hard red spring (HRS) wheat cultivars. A sexually recombined race having virulence to SrWld1 was isolated in the 1980s. Our objective was to determine the genetics of resistance to the race. The recombinant race was tested with the set of stem rust differentials and with a set of 36 HRS and 6 durum cultivars. Chromosomal location studies in cultivars Len, Coteau, and Stoa were completed using aneuploid analysis, molecular markers, and allelism tests. Stem rust differential tests coded the race as TPPKC, indicating it differed from TPMKC by having added virulence on Sr30 as well as SrWld1. Genes effective against TPPKC were Sr6, Sr9a, Sr9b, Sr13, Sr24, Sr31, and Sr38. Genetic studies of resistance to TPPKC indicated that Len, Coteau, and Stoa likely carried Sr9b, that Coteau and Stoa carried Sr6, and Stoa carried Sr24. Tests of HRS and durum cultivars indicated that five HRS and one durum cultivar were susceptible to TPPKC. Susceptible HRS cultivars were postulated to have SrWld1 as their major stem rust resistance gene. Divide, the susceptible durum cultivar, was postulated to lack Sr13. We concluded that although TPPKC does not constitute a threat similar to TTKSK and its variants, some cultivars would be lost from production if TPPKC became established in the field.