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Daphne Sudden Death Syndrome (DSDS): pathogen identification, characterization and screening for disease resistanceNoshad, David 05 1900 (has links)
Daphne is a widely dispersed genus with large variation in morphology, native habitats, and use. Unfortunately, broader acceptance of Daphne in the ornamental trade has been limited due to Daphne Sudden Death Syndrome (DSDS), a disease that kills the plant without warning. The results of this research identified Thielaviopsis basicola (Berk. etBr.) Ferr. as the causal agent for this disease. Pure cultures of the pathogen were developed and used in a germ plasm screen.
To evaluate Daphne germ plasm in vitro, species-specific protocols were developed that alleviated two common problems in Daphne micropropagation, browning and hyperhydricity. Optimizing the concentrations of both PGRs and charcoal was able to control these problems. Selected species were evaluated for resistance against Thielavipsis basicola in both, in vivo and in vitro, conditions. The results of both methods displayed a strong correlation and indicated significant differences among the taxa. However, there were differences in disease progression rates. Typically, the in vitro challenge produced a comparable level of disease as the in vivo challenge but in two to three weeks less time. Across both screening methods, the most resistant species evaluated were D. tangutica and D. retusa, while D. cneroum was the most susceptible.
Based on ITS sequences, phylogenetic relationships among selected Daphne species were established and associated with their resistance against T basicola. The phylogeny indicated that Daphne is possibly a monophyletic group. However, placement of D.genkwa remained problematic. The analysis of ITS sequences data resulted in a parsimony consensus tree with two well-supported major clades and one Glade with less support. In general, the evolutionary tree for resistance, inferred from the phylogenetic data and the results of the screening project, indicate that resistance is a derived character and that plants recently evolved this ability.
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MENDELIZING QUANTITATIVE TRAIT LOCI THAT UNDERLIE RESISTANCE TO SOYBEAN SUDDEN DEATH SYNDROMELee, Yi-Chen 01 August 2016 (has links)
Soybean (Glycine max [L.] Merr.) cultivars differ in their resistance to sudden death syndrome (SDS). The syndrome is caused by root colonization by Fusarium virguliforme (ex. F. solani f. sp. glycines). Breeding for improve SDS response has proven challenging, possible due to interactions among the 18 known loci for resistance. Four loci for resistance to SDS (cqRfs to cqRfs3) were found clustered within 20 cM of the rhg1 locus underlying resistance to soybean cyst nematode (SCN) on chromosome 18. Another locus on chromosome 20 (cqRfs5) was reported to interact with this cluster. The aims of this study were to compare the inheritance of resistance to SDS in a near isogenic line (NIL) population that was fixed for resistance to SCN but still segregated at 2 of the 4 loci (cqRfs1 and cqRfs) for resistance to SDS on chromosome 18; to examine the interaction with the locus on chromosome 20; and to identify candidate regions underlying quantitative trait loci (QTL). Used were a near isogenic line population derived from residual heterozygosity in an F5:7 recombinant inbred line EF60 1-40; SDS response data from 2 locations and years; four microsatellite markers and six thousand SNP markers. Polymorphic regions were found from 2,788 to 8,938 Kbp on chromosome 18 and 33,100 to 34,943 Kbp on chromosome 20. Both regions were significantly (0.005 < P > 0.0001) associated with resistance to SDS. A fine map was constructed that Mendelized the three loci. Substitution maps suggested the two loci on chromosome 18 were actually 3 loci (cqRfs, cqRfs1 and cqRfs19). Candidate genes for cqRfs19 were identified in a small region of the genome sequence of soybean. An epistatic interaction was inferred where the allele of loci on chromosome 18 determined the value of the locus on chromosome 20. It was concluded that SDS loci are both complex and interacting which may explain the slow progress in breeding for resistance to SDS.
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EVALUATION OF SOYBEAN DISEASES AND PESTS USING TWO ADVANCED BREEDING POPULATIONSLee, Yi-Chen 01 September 2021 (has links) (PDF)
Soybean (Glycine max [L.] Merr.) is one of the most important crops in the world. The average annual yield losses due to soybean diseases and pests are estimated to be around 11% in the United States. Soybean yield losses due to sudden death syndrome (SDS), caused by the fungus Fusarium virguliforme O'Donnell & T. Aoki have been problematic in majority of the soybean producing states. In recent years, reniform nematode (RN, Rotylenchulus reniformis Linford and Oliveira) and frogeye leaf spot (FLS), caused by the fungus Cercospora sojina K. Hara have emerged as a major problem in the southern soybean producing states. Planting resistant cultivars is one of the most cost-efficient methods in managing SDS, RN, and FLS, therefore it would be critical to identify and map the quantitative trait loci (QTL) that underlie their resistances. Two soybean populations were evaluated in this study. The ‘Essex’ × ‘Forrest’ 77 near-isogenic lines were screened in the field to evaluate the disease index of SDS. The Essex × Forrest and ‘Flyer’ × ‘Hartwig’ recombinant inbred lines were screened in the greenhouse to assess the reproduction index of RN and the disease severity of FLS. The BARCSoySNP6k chip was used to genotype the two populations. Four QTL that underlie SDS resistances were mapped in the same region as Rfv06-01, Rfv06-02, Rfv13-01, and Rfv19-01. The Rfv06-02 interval in this study was smaller than the one previously reported. Rrr08-01, Rrr13-01, Rrr15-01, Rrr18-01, and Rrr18-02 were reported to confer resistances to RN. Rrr08-01, Rrr13-01 and Rrr15-01 were novel whereas Rrr18-01, and Rrr18-02 were mapped in previous studies. cqSCN-001 (soybean cyst nematode, Heterodera glycines Ichinohe) was identified in the same region as Rrr18-01, and Rrr18-02 whereas cqSCN-006 was identified in the same region as Rrr15-01. These findings provide further evidence that there are common sources of genetic resistances to RN and SCN. Rcs15-01 and Rcs15-02 were reported to confer resistances to FLS. Rcs15-01 was novel and Rcs15-02 was mapped at the same region as an Rcs mapped in a previous study. This indicated that Rcs15-02 has dual resistances to C. sojina races. Candidate genes were inferred in this study. The QTL mapped in this study could potentially be used in soybean breeding programs that aim to introgress genetic resources that confer resistances to SDS, RN, and FLS.
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ASSESSMENT OF SUDDEN DEATH SYNDROME BY UTILIZING UNMANNED AERIAL VEHICLES AND MULTISPECTRAL IMAGERYMcKinzie, Lindsey 01 May 2022 (has links)
Fusarium virguliforme is a soil-borne pathogen that is the causal agent of sudden death syndrome (SDS). This disease is one of the top contributors to major yield losses in soybean across the United States. Characteristic symptoms of the disease include interveinal chlorosis and/or necrosis of trifoliate leaves and defoliation. In some cases, the foliar symptoms may not be present, but yield loss still occurs. This disease is evaluated using an incidence rating, the percent of plants in the plot that are expressing symptoms, and a severity rating, using a one to nine scale based on varying levels of chlorosis, necrosis, and defoliation. Using remote sensing provides an alternate approach to identify and evaluate plant diseases. It provides a non-destructive method to assess the severity of foliar symptoms and their distribution across production fields. SDS was chosen as the disease to use for this system due to the unique disease symptomology and yield loss. In 2019 and 2020, SDS trials were established in a production field location that has a history of SDS in Valmeyer, IL. This seed treatment study had different chemicals with varying levels of efficacy against SDS. Disease ratings were collected at the first sign of symptoms, and aerial imagery was collected on the same day. There were multiple dates across both years when this data was collected. ArcGIS was used to analyze the multispectral imagery and do a plot by plot analysis for each of the plots. A regression analysis was performed to test the relationship between the foliar disease ratings and the plot data collected from the multispectral imagery. Multiple vegetation indices were tested, and the results showed that overall, in 2019, GNDVI had the strongest relationship with foliar ratings. In 2020, NDRE had the strongest overall relationship with foliar ratings. The relationship between NDVI and the ratings was the most consistent at the last rating of the season.
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Effect of Fusarium virguliforme and Heterodera glycines on soybeanBrzostowski, Lillian Frances January 1900 (has links)
Master of Science / Department of Agronomy / William T. Schapaugh Jr / Fusarium virguliforme, the soilborne fungus which causes sudden death syndrome (SDS) of soybean, and Heterodera glycines Ichinohe, soybean cyst nematode (SCN), are two economically important pathogens in the Midwest. The pathogens are often found together in soybean (Glycine max (L.) Merr.) fields. This study was conducted to determine the effect of soybean genotype, F. virguliforme populations, and H. glycines populations have upon yield and to examine the interaction between the two pathogens. In 2008 and 2009, four genotypes with different levels of resistance to SDS and H. glycines were planted at seven environments. F. virguliforme and H. glycines soil populations were quantified at planting, midseason, and harvest. At the end of the growing season, area under the disease progress curves of SDS, F. virguliforme root populations, and H. glycines reproductive indices were determined and plots harvested for seed yield. Soil populations of F. virguliforme and H. glycines at planting, midseason, and harvest varied across environments. Within environments, generally, they were not significantly different. Seed yield varied within and across environments. As disease pressure increased, the performance of resistant genotypes increased compared to susceptible genotypes. Genotypes resistant to SDS yielded higher than susceptible genotypes. There were negative correlations between yield and disease rating and F. virguliforme root populations. F. virguliforme soil populations and H. glycines populations at planting were positively correlated. It is important to manage both SDS and H. glycines in fields with a history of the two diseases. This can be achieved through genetic resistance. Information in this study will improve decisions regarding genotype selection to minimize losses to SDS and H. glycines.
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Use of small unmanned aerial system for validation of sudden death syndrome in soybean through multispectral and thermal remote sensingHatton, Nicholle January 1900 (has links)
Master of Science / Department of Biological & Agricultural Engineering / Ajay Sharda / Discovered in 1971, sudden death syndrome (SDS), caused by the fungus Fusarium virguliforme, has spread from the US to South American and European countries. It has potential to infect soybean crops worldwide, causing yield losses of 10% to 15% and even 70% in extreme cases. There is a need for rapid spatial assessment of SDS. Currently, the extent and severity of SDS are scored using visual symptoms as indicators. This method can take hours to collect and is subject to human bias and changing environmental conditions. Color infrared (CIR) and thermal infrared (TIR) imagery detect changes in light reflectance (visible and near-infrared bands) and emittance (canopy temperature), respectively. Stressed crops may show deviations in light reflectiveness, as well as elevated canopy temperatures. The use of CIR and TIR imagery and flexible aerial remote sensing platforms offer an alternative for SDS detection and diagnosis compared to hand scoring methods.
Crop stress and diseases have been detected using manned and unmanned aerial systems previously. Yet, to date, SDS has not been remotely assessed using CIR or TIR imagery collected with aerial platforms. The following research utilizes high throughput CIR and TIR imagery collected using a small unmanned aerial system (sUAS) to detect and assess SDS. A comparative evaluation of ground-based and aerial CIR methods for assessing SDS was conducted to understand the effectiveness of novel aerial SDS detection methods. Furthermore, a TIR case study investigating the use of potential thermal canopy changes for SDS detection was conducted to investigate the possibility of using TIR as an SDS indicator.
CIR reflectance measured from a ground-based spectrometer and sUAS was collected data over a two-year period. Ground-based spectrometer data were collected weekly, while a sUAS collected aerial imagery late in the growing season each year before plant maturity. Pigment index (PI) values were derived from ground-based and aerial data. Results showed a strong negative correlation between SDS score and PI values. Aerial and ground-based data both showed strong correlations to SDS score, however, aerial data displayed a stronger relationship possibly due to minimal changes in environmental conditions. High SDS scores correlated strongly to aerial derived PI (R2 = 0.8359). Rapidly assessed high SDS allows for accurate screening of SDS critical for soybean breeding. The second year of the study investigated each component of SDS score, severity, and incidence. PI proved to have the best correlation with severity (R2 = 0.6313 and ρ = -0.8016) rather than incidence or SDS score. PI also correlated to SDS scores with R2 = 0.6159 and ρ = -0.7916.
A sUAS mounted TIR camera collected imagery four times during the growing season when SDS foliar symptoms were just starting to appear. At the start of the study period, the correlation between canopy temperature and SDS is low (ρ = -0.2907), but increases over the growing season as SDS prevalence increases ending with a strong correlation (ρ = -0.7158). Early identification of SDS leads to the implementation of mitigation practices and changes in irrigation scheduling before the disease reaches severe symptoms. Early mitigation of SDS reduces yield loses for farmers.
The use of both CIR and TIR aerial imagery captured using sUAS can provide rapid spatial assessments of SDS, which is required by both producers and plant breeders. PI derived from CIR imagery showing strong correlations to SDS score reinforce the idea of replacing the time-consuming traditional ground-based systems with the more flexible, faster, sUAS methods. TIR imagery was shown to be reliable in assessing SDS in soybeans further establishing another possible aerial method for early detection of SDS.
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IDENTIFICATION AND CHARACTERIZATIONS OF PATHOGENICITY GENES IN FUSARIUM VIRGULIFORME, THE CAUSAL AGENT OF SOYBEAN SUDDEN DEATH SYNDROME (SDS)Islam, Kazi Tariqul 01 December 2015 (has links) (PDF)
Fusarium virguliforme (Aoki, O’Donnell, Homma & Lattanzi), the causal agent of sudden death syndrome (SDS) of soybean (Glycine max [L.] Merrill), is responsible for major soybean yield losses in North America and South America. Despite the importance of SDS, few agronomic practices have been used to manage SDS successfully. Understanding the pathogen and the mechanisms it uses to cause disease is vital to devise effective disease control strategies. However, our knowledge of the pathogenicity mechanisms used by F. virguliforme is limited. The identification of pathogenic genes will shed light on the molecular basis of the interaction between F.virguliforme and soybean, which may ultimately lead to better management of SDS. Therefore, the studies presented in this thesis were aimed at identifying and characterizing candidate pathogenicity genes in F. virguliforme.To fulfill this objective, 40 candidate pathogenicity genes of F. virguliforme were identified based on a combined approach, which included hands-on literature and database mining, functional genomics as well as transcriptome analyses. From these genes, the FvSNF1gene (a sucrose non-fermenting protein kinase 1 ortholog), the Fvstr1 gene (a striatin protein ortholog) were functionally characterized through a gene knock-out strategy. Targeted disruption of the FvSNF1 locus in wild type F. virguliforme strain reduced virulence significantly on soybean and abolished galactose utilization. In addition, the FvΔSNF1 mutant displayed significant reduction in expression of several CWDEs genes and was defective in colonizing the vascular system of the roots. To identify putative target genes regulated by FvSNF1, transcriptome analyses were performed in the FvSNF1 deletion mutant and in the wild-type. Disruption of FvSNF1 affected the level of transcription of 393 genes and a majority of the genes were involved in carbohydrate metabolism, lignin degradation, and cellular signaling pathway. The disruption of Fvstr1, a striatin ortholog in F. virguliforme, resulted in a complete loss of virulence as well as impaired conidiation, conidiophore development and pigmentation in the fungus. The FvΔstr1 mutant also failed to colonize the vascular tissues of roots of inoculated soybean plants. The results suggest that FvSNF1and Fvstr1 have critical roles in pathogenicity. Another part of the study was to investigate the efficacy of ILeVO®, a succinate dehydrogenase inhibitor fungicide from Bayer CropScience, against F. virguliforme. Our results showed that ILeVO® was very active against F. virguliforme in vitro and was very effective in minimizing F. virguliforme infection thus providing yet another tool to combat SDS.
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Caracterização, toxicidade e patogenicidade de fusarium spp. em genótipos de soja em sistema plantio direto / Characterization, toxicity and pathogenicity of fusarium spp. in soybean genotypes under no tillageMilanesi, Paola Mendes 27 February 2009 (has links)
Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / The sudden death syndrome (SDS), caused by species of Fusarium, is a disease difficult to control and there are no management techniques and resistant cultivars that give long-term positive results. This study aimed to assess populations of Fusarium spp. and Trichoderma spp. associated to eight soybean genotypes, cultivated under no tillage; to determine if the control of Fusarium varies among isolates of Trichoderma; to identify isolates of Fusarium spp. obtained from different genotypes, and to determine their toxicity and pathogenicity to two genotypes of soybean. Soil and roots were collected from experimental plots located at the Fundação Centro de Experimentação e Pesquisa (FUNDACEP), obtaining isolates of
Fusarium spp. and Trichoderma spp. There were no differences in the population of Fusarium spp. in plants with symptoms of SDS among the different genotypes. For
Trichoderma spp. there was a significant difference among genotypes from plants with and without symptoms of SDS and the genotype CEPS 06006 RR had the biggest population of
the antagonist. In the direct confrontation test, eight isolates of Trichoderma spp. obtained the highest score (1) in relation to the control of Fusarium spp. and isolates of Trichoderma spp. from soil of areas with the SDS symptom were more aggressive. Nine species of
Fusarium: F. avenaceum, F. solani, F. equiseti, F. Acuminatum, F. kyushuense, F. graminum, F. subglutinans, F. verticillioides and F. lateritium were identified. All isolates promoted internerval chlorosis, necrosis and death of seedlings in the toxicity test. In the
pathogenicity test in plants inoculated with the pathogen there was an increase in leaves and roots dry weight and in the number of pods, indicating that there may be species specificity of the species studied in relation to genotype. / A Podridão Vermelha da Raiz da soja (PVR), causada por espécies de Fusarium, é uma doença de difícil controle, não existindo técnicas de manejo e cultivares resistentes que
tenham resultados positivos a longo prazo. Assim, este trabalho objetivou quantificar populações de Fusarium spp. e Trichoderma spp. associadas à oito genótipos de soja,
cultivados em sistema plantio direto, observar se o biocontrole de Fusarium spp. difere entre isolados de Trichoderma spp., identificar isolados de Fusarium spp. obtidos de diferentes genótipos e verificar sua toxicidade e patogenicidade a dois genótipos de soja. Amostras de
solo e raízes foram coletadas em parcelas experimentais na Fundação Centro de Experimentação e Pesquisa (FUNDACEP), obtendo-se isolados de Fusarium spp. e Trichoderma spp. Não houve diferença na população de Fusarium spp. em plantas com sintomas de PVR entre os diferentes genótipos. Para Trichoderma spp., houve diferença entre as populações nos genótipos de plantas com e sem sintomas de PVR, tendo o
genótipo CEPS 06006 RR apresentado maior população do antagonista. No teste de confronto direto, oito isolados de Trichoderma spp. obtiveram a melhor nota (um), em
relação a Fusarium spp. e isolados de Trichoderma spp. oriundos de solo em áreas com o sintoma de PVR foram mais eficientes. Foram identificadas nove espécies de Fusarium: F.
avenaceum, F. solani, F. equiseti, F. acuminatum, F. kyushuense, F. graminum, F. subglutinans, F. verticillioides e F. lateritium. Todos os isolados de Fusarium spp.
provocaram clorose internerval, necrose e morte de plântulas no teste de toxicidade. No teste de patogenicidade, em plantas inoculadas com o patógeno houve aumento na massa
seca de parte aérea e de raízes, no número de vagens, indicando que pode haver especificidade das espécies estudadas em relação ao genótipo.
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Multiple Tactics to Improve our Understanding of Soybean DiseasesMariama Tricuonia Brown (15295693) 14 April 2023 (has links)
<p> </p>
<p>Sudden death syndrome (SDS) caused by <em>Fusarium virguliforme</em> is one of the top yield-reducing diseases of soybean. This disease results in a two-stage symptom development, root rot followed by foliar interveinal chlorosis and necrosis. Foliar symptoms typically appear late in the growing season [full pod to full seed (R4 to R6) reproductive growth stages]. Prior to foliar symptoms, a destructive technique is usually carried out to identify the root rot phase of SDS. This technique requires intensive crop scouting and an expert for accurate diagnosis. Therefore, a nondestructive technique is needed to diagnose SDS disease in the absence of visible foliar symptoms. Additionally, no soybean cultivar is completely resistant to SDS and no single method can completely manage this disease. So, an improved integrated approach is needed for SDS disease management. </p>
<p>Foliar fungal diseases such as frogeye leaf spot (<em>Cercospora sojina</em> Hara), Septoria brown spot (<em>Septoria glycines</em> Hemmi), and Cercospora leaf blight (<em>Cercospora</em> spp.) are also economically important diseases of soybean. To limit the losses caused by these diseases, several management methods can be used including the application of foliar fungicide. However, due to the low foliar disease pressure that is observed most years, fungicide applications may not be warranted to be applied annually in Indiana. </p>
<p>The objectives of this research were: 1) to assess the effectiveness and economic impact of integrated management strategies that include cultivar selection, seed treatment, and seeding rate on SDS in Indiana; 2) to pre-symptomatically and non-destructively detect SDS disease using hyperspectral measurements; and 3) to evaluate foliar fungicides on soybean foliar diseases and yield in Indiana. </p>
<p>Results from this research support the use of a seed treatment to protect soybean roots from SDS infection and the use of a moderately resistant cultivar planted at a seeding rate of 346,535 seeds/ha to protect yield and maximize on net returns. This research also demonstrated the ability of hyperspectral reflectance to discriminate healthy from <em>F. virguliforme</em> infected soybean roots in the absence of foliar symptoms. In addition, results show that fungicide applications can reduce foliar disease over the nontreated control, but under low foliar disease risk, these fungicides did not significantly increase yield over the nontreated control. Altogether, these results will contribute to improved soybean disease management approaches in Indiana.</p>
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Estratégias de seleção de genótipos de soja para resistência à podridão vermelha das raízes / Selection strategies of soybean genotypes resistant to sudden death syndromeBernardi, Walter Fernando 01 September 2008 (has links)
Nas últimas décadas, a podridão vermelha das raízes da soja (PVR), causada pelo Fusarium solani f.sp. glycines (FSG), tornou-se uma doença séria nas regiões brasileiras onde já foi constatada, sendo a utilização de cultivares resistentes um componente fundamental de um sistema integrado de controle. Este trabalho teve por objetivo pesquisar estratégias de seleção de genótipos resistentes a PVR. Várias metodologias foram implementadas: avanço de progênies até a geração F7:2 e seleção em campo infestado, de progênies selecionadas em F2. Avaliou-se o cruzamento IAC 4 x Conquista em casa de vegetação (geração F3:2) e em campo infestado (gerações F3:2, F4:2 e F5:2), através de estudo de estabilidade e adaptabilidade das progênies. As metodologias de infecção em vasos de barro e bandejas de isopor em casa de vegetação foram comparadas para melhorar a eficiência de seleção; também foi feita análise de repetibilidade dos sintomas foliares da PVR, para otimização do número de avaliações necessárias para classificar o genótipo de soja quanto à reação ao FSG. Cultivares brasileiras de soja foram avaliadas em campo infestado. Em campo, as plantas foram avaliadas no estádio R5-6, com notas variando de 1 (ausência de sintomas) a 5 (100% da raiz principal com sintomas). Em casa de vegetação, as plantas foram avaliadas aos 35 dias pós-semeadura para sintomas radiculares e da parte aérea. Houve eficiência da seleção para resistência a PVR tanto em F2 (sintomas foliares em casa de vegetação) quanto em F7:2 (sintomas radiculares em campo naturalmente infestado). A seleção praticada nas gerações intermediárias também foi eficiente para aumentar a produtividade de grãos das progênies. Para o cruzamento IAC 4 x Conquista nas gerações F3:2, F4:2 e F5:2 em campo naturalmente infestado e na F3:2 em casa de vegetação, a metodologia de Annicchiarico possibilitou a seleção de genótipos com maior estabilidade e adaptabilidade para os diferentes ambientes; com o estudo genético destas gerações, demonstrou que há efeitos gênicos aditivos e dominantes no controle genético da PVR. Além disso, constatou-se que os genes responsáveis pela resistência estão dispersos nos genitores, provavelmente agrupados em blocos gênicos. A presença de dominância indica que a seleção deve ser postergada para gerações com maior homozigose (linhagem pura); esta idéia foi reforçada pela baixa herdabilidade ao nível de plantas. O uso de bandejas de isopor foi significativamente mais eficiente do que vasos de barro para inoculação de FSG em casa de vegetação. Pela análise de repetibilidade, detectou-se que quatro avaliações foram suficientes para discriminar se o genótipo era realmente suscetível ao FSG. A correlação da geração F3:2 (IAC 4 x Conquista) entre campo infestado e casa de vegetação foi praticamente nula; no entanto, 54% das progênies selecionadas em campo também foram selecionadas em casa de vegetação. A seleção de genótipos superiores para resistência ao FSG não é tarefa fácil, mas pode ser aprimorada pelo uso conjugado de metodologias suplementares que aumentem a eficiência de seleção. / During the last decades, soybean sudden death syndrome (SDS), caused by Fusarium solani f.sp. glycines (FSG), has become a serious disease in the regions where it was encountered. The use of resistant soybean cultivars has been an important component of an integrated management system. The aim of this work was to research selection strategies of SDS-resistant genotypes. A number of methodologies were used: self pollination up to generation F7:2 and progeny selection in infested field of selected F2. The crossing IAC 4 x Conquista was studied in greenhouse (generation F3:2) and in a naturally infested field (generations F3:2, F4:2 and F5:2), where the progeny stability and adaptability study was carried out. The methodologies of infection in clay pots and polystyrene trays in greenhouse were compared to improve selection efficiency. An analysis of the repeatability of foliar SDS symptoms was also performed in order to optimize the number of evaluations needed to classify a soybean genotypes reaction to FSG. Brazilian soybean cultivars were evaluated in a naturally infested field, where plants were evaluated at stage R5-6 with scores varying from 1 (absence of symptoms) to 5 (main root 100% symptoms). In the greenhouse, the plants were evaluated 35 days after sowing for root symptoms, while the leaf symptoms was only evaluated after the appearance of symptoms. The selection done in F2 (leaf symptoms in greenhouse) as well as F7:2 (root symptoms in infested field) for FSG were efficient. The selections performed in intermediary generations were efficient in increasing the grain yield of the progeny. Studies of the F3:2, F4:2 and F5:2 generations of the IAC 4 x Conquista cross in an infested field and F3:2 in greenhouse, enabled through Annicchiaricos methodology, the selection of genotypes with greater stability and adaptability to different environments. The genetic study of these generations demonstrated there are additive and dominant genetic effects on the genetic control of SDS. Moreover, it was noted that the genes responsible for resistance are dispersed on the genitors, probably grouped into genic blocks. The presence of dominance indicates that the selection should be passed onto generations with greater homozygosity. There is also a clear indication that breeders should work with progeny lines in order to assist selection due to the low inheritability at the individual plant level. For the experiments with different FSG inoculation methodologies (clay pots and polystyrene trays) in greenhouse the use of trays was significantly more efficient; by studying the repeatability analysis, it was found that four evaluations is enough to discriminate if the genotype is really susceptible to FSG. The correlation of the F3:2 generation (IAC 4 x Conquista) between infested field and greenhouse was practically null; however, 54% of the progeny selected in the field were selected in greenhouse. As observed, the selection of superior genotypes for FSG resistance is not an easy task, but may be improved by means of new methodologies and the conjugated use of methodologies which improve selection efficiency.
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