An investigation into the detection, identification, differentiation and pathogenicity of Fusarium oxysporum f.sp. narcissi

Linfield, Christine A.

January 1994

Basal rot of Narcissus caused by Fusarium oxysporum f.sp. narcissi is the major limiting factor for the increased export of ornamental bulbs from the United Kingdom. There is no known resistance to the disease amongst commercial cultivars. The purpose of this study was to develop techniques for the rapid detection and identification of the pathogen in bulbs, culture and soil, and to develop serological and biochemical tests to investigate differences amongst isolates of this forma specialis from a range of countries. Significant differences in virulence were observed between the isolates tested, two being identified as avirulent. Results suggest that there is wider morphological variation within this forma specialis than previously recorded. Isolates stored at -80°C have remained viable over a three year period. Thirty three species and varieties of Narcissus and seventeen cultivars were screened for resistance to the pathogen. Accessions were either wholly resistant, partially resistant (a variable portion of the bulbs infected) or susceptible. Accessions identified as resistant are now being used as parents in a resistance breeding programme. F. oxysporum Esp. narcissi isolates of low virulence and avirulence showed greater agglutination of microconidia with Narcissus pseudonarcissus lectin. In addition increased lectin levels were found in cultivars showing greater disease resistance; this suggests a possible host pathogen interaction. Polyclonal antisera were elicited against extracts of isolates and a specific and sensitive enzyme-linked immunosorbent assay was developed for the detection of the pathogen in bulbs. Little cross-reactivity was shown by other bulb-rotting fungi. A direct correlation was observed between positive results in the ELISA and recovery of the pathogen on selective media. The ELISA which was developed will be field evaluated with growers during the coming season. In indirect ELISA and Western blotting of fungal extracts, all fungi outside the genus Fusariwn showed consistently low binding. Isolates of F. oxysporum f.sp. narcissi could be discriminated from other Fusarium species and further split into a series of sub-groups. Avirulent isolates or isolates of low virulence showed differential binding to the PAbs. Other sub-groups were not related to virulence. Western blotting allowed greater differentiation of isolates and bands specific to F. oxysporwn f.sp. narcissi were identified. Serological detection of the pathogen in soil proved possible through the inclusion of a soil enrichment stage with a selective medium.

630

Basal rot; Bulbs

Evolution and detection of Fusarium oxysporum f. sp. cepae in onion in South Africa

Southwood, Michael J.

03 1900

Thesis (PhDAgric (Plant Pathology))--Stellenbosch University, 2010. / ENGLISH ABSTRACT: In the Western Cape onion industry in South Africa, Fusarium oxysporum Schlechtend.:Fr. f.sp. cepae (H.N. Hans.) W.C. Snyder & H.N. Hans. (Focep) has been identified as the leading cause of harvest and storage losses. This pathogen is of world-wide importance and causes Fusarium basal rot of onions (Allium cepa), affecting all onion growth stages. No information is available on the evolution, genetic diversity, molecular detection and inoculum sources of the South African Focep population. Similar to what is the case for South Africa, limited information is available on Focep in other regions of the world. World-wide, four vegetative compatibility groups (VCGs) and two single-member VCGs (SMVs) have been identified among two Japanese and 19 Colorado (USA) isolates. This polyphyletic origin of Focep suggested by VCG analyses was confirmed through molecular analyses of isolates from a few countries. Only the mating type (MAT)1-1 idiomorph has been reported for Focep isolates from Welsh onion (Allium fistulosum). The development of sustainable management strategies of Focep is dependent on knowledge of (i) the genetic diversity and evolution of Focep, (ii) whether high throughput molecular methods can be developed for identifying the most virulent and widespread Focep genotypes and (iii) the role of seedlings and seeds as primary inoculum sources, and the Focep genotypes associated with these growth stages. Therefore, the three main aims of the current study were to investigate the aforementioned three aspects. In the first aim of the study, the genetic diversity and evolution of Focep was investigated using a collection of 79 F. oxysporum isolates from South Africa (27 Focep and 33 non-pathogenic isolates) and Colorado (19 Focep isolates). VCG analyses revealed the presence of six VCGs, four among the Colorado Focep isolates (VCGs 0421, 0422, 0423 and 0424) and two among the South African bulb-associated isolates (VCGs 0425 and 0426). VCG 0421 and VCG 0425 were the two main VCGs in Colorado and South Africa, respectively. Four SMVs and one heterokaryon selfincompatible (HSI) isolate were also identified. The polyphyletic nature of Focep in South Africa and Colorado was shown through a combined translation elongation factor 1α (EF-1α) and mitochondrial small-subunit (mtSSU) phylogeny. The phylogeny divided the Focep isolates into two main clades, of which one contained the two main VCGs (0421 and 0425), SMVs and non-pathogenic isolates. The second, ancestral clade contained the HSI isolate, VCGs 0422, 0423 and 0424, and non-pathogenic isolates. Unlike the clade containing the two main VCGs, which were highly virulent toward onion bulbs, the ancestral clade contained isolates that were mostly moderately virulent. The incongruence of the EF-1α and mtSSU datasets with an intergenic spacer (IGS) region data set, and the presence of both MAT idiomorphs within the same isolate for some isolates, suggested possible exchange of genetic material between isolates. The second aim of the study was to develop molecular methods for identifying the two main Focep VCGs (0425 and 0421), using DNA fingerprinting methods and sequence-characterized amplified region (SCAR) markers. These techniques were first developed using the F. oxysporum isolates from the first aim, and were then used to investigate the prevalence of VCG 0425 among 88 uncharacterized F. oxysporum isolates from onion bulbs in South Africa. Two random amplified polymorphic DNA primers provided two diagnostic amplicons for VCG 0425, but attempts to develop SCAR markers from these amplicons were unsuccessful. In contrast, an interretrotransposon amplified polymorphism (IRAP) fingerprinting method enabled the developed of a multiplex IR-SCAR polymerase chain reaction method that detected the VCG 0421, 0425 and SMV 4 isolates as a group. Fingerprinting and SCAR marker testing of the 88 uncharacterized F. oxysporum isolates from South Africa (65 Focep and 23 non-pathogenic) confirmed that VCG 0425 is the main VCG in South Africa associated with mature onion bulbs, since 63 of the Focep isolates had the molecular characteristics of VCG 0425. The third aim of the study was to determine whether seed and seedling transplants are inoculum sources of Focep, and whether the same genotype (VCG 0425) that dominated on mature bulbs could be detected from these sources. Focep isolates were obtained from seven of the 13 investigated onion seed lots, as well as from onion seedling transplants that were collected from all five onion nurseries in the Western Cape. Focep seedling infection more than doubled from the 6-week growth stage to the 14-week growth stage. Seed infections by Focep were low, but the seedborne nature of Focep was confirmed by showing that a green fluorescent protein labelled Focep transformant could be transmitted from infected soil to onion seed via the onion bulbs and seedstalks. It is thus clear that commercial seed and seedlings are inoculum sources of Focep. However, the Focep genotypes on seed and seedlings are different from those in mature bulbs and were not dominated by VCG 0425. Furthermore, most (≤ 60%) of the seed and seedling isolates were moderately virulent, as compared to the mostly highly virulent isolates from mature bulbs. / AFRIKAANSE OPSOMMING: In die Wes-Kaapse uiebedryf in Suid-Afrika is Fusarium oxysporum Schlechtend.:Fr. f.sp. cepae (H.N. Hans.) W.C. Snyder & H.N. Hans. (Focep) geïdentifiseer as die vernaamste oorsaak van oes- en opbergingsverliese. Hierdie patogeen is van wêreldwye belang; dit veroorsaak Fusarium-bolvrot van uie (Allium cepa) en affekteer alle plantgroeistadia. In Suid-Afrika is daar geen inligting beskikbaar oor die evolusie, genetiese diversiteit, molekulêre opsporing en inokulumbronne van die Focep-populasie nie. Soortgelyk aan wat die geval in Suid-Afrika is, is daar beperkte inligting beskikbaar oor Focep in ander wêrelddele. Wêreldwyd is daar vier vegetatiewe versoenbaarheidsgroepe (VVGe) en twee enkellid VVGe (ELVe) geïdentifiseer onder twee Japannese en 19 Colorado (VSA) isolate. Hierdie veelvuldige oorsprong van Focep wat deur VVG-analise voorgestel was, is deur die molekulêre analises van isolate uit ’n paar ander lande bevestig. Slegs die paringstipe (PT)1-1 idiomorf is vir Focep-isolate uit Walliese-tipe uie (ook bekend as ‘lenteuie’ in Suid Africa) (Allium fistulosum) berig. Die ontwikkeling van volhoubare bestuurstrategieë vir Focep steun op kennis van (i) die genetiese diversiteit en evolusie van Focep, (ii) of hoë-deurset molekulêre metodes ontwikkel kan word vir die identifisering van die mees virulente en wydverspreide Focep-genotipes en (iii) die rol van saailinge en saad as primêre inokulumbronne, en die Focep-genotipes wat met hierdie groeistadia geassosieer word. Daarom was die hoof doelstellings van hierdie studie om die bogenoemde drie aspekte te bestudeer. Om die eerste doel van die studie te bereik is die genetiese diversiteit en evolusie van Focep bestudeer deur gebruik te maak van ‘n versameling van 79 F. oxysporum-isolate uit Suid-Afrika (27 Focep en 33 nie-patogeniese isolate) en uit Colorado (19 Focep-isolate). VVG-analises het die teenwoordigheid van ses VVGe aangetoon – vier onder die Colorado Focep-isolate (VVGe 0421, 0422, 0423 en 0424) en twee onder die Suid-Afrikaanse bol-geassosieerde isolate (VVGe 0425 en 0426). VVG 0421 en VVG 0425 was die twee hoof VVGe in onderskeidelik Colorado en Suid-Afrika. Vier ELVe en een meerkernige self-onversoenbare (MSO) isolaat is ook geïdentifiseer. Die veelvuldige oorsprong van Focep in Suid-Afrika en Colorado is ook aangetoon deur ‘n gekombineerde translasie verlengings faktor 1α (VF-1α) en mitokondriale klein-subeenheid (mtKSE) filogenie. Dié filogenie het die Focepisolate in twee groepe verdeel, waarvan die een groep die twee hoof VVGe (0421 en 0425), ELVe en nie-patogeniese isolate bevat het. Die tweede, basal groepering het die MSO-isolaat, VVGe 0422, 0423 en 0424, en nie-patogeniese isolate bevat. In teenstelling met die eersgenoemde groepering wat hoogs virulente isolate van uiebolle bevat het, het die basale groepering isolate bevat wat meestal matig virulent was. Die inkongruensie van die VF-1α en mtKSE-datastelle met ‘n intergeen-gespasieerde (IGS) area datastel – asook die teenwoordigheid van beide PT-idiomorwe binne dieselfde isolaat by sommige isolate – het op ’n moontlike uitruiling van genetiese materiaal tussen isolate gedui. Die tweede doel van die studie was om molekulêre metodes te ontwikkel vir die identifisering van die twee hoof Focep VVGe (0425 en 0421) deur gebruik te maak van DNA-vingerafdrukke en nukleotied-gekarakteriseerde geamplifiseerde area (NKAA) merkers. Hierdie tegnieke is ontwikkel deur van die F. oxysporum-isolate van die eerste doelstelling gebruik te maak en is daarna gebruik om die frekwensie van VVG 0425 onder 88 ongekarakteriseerde F. oxysporum-isolate van uiebolle in Suid-Afrika te ondersoek. Twee gerandomiseerde geamplifiseerde polimorfiese DNS (RAPD) merkers het twee diagnostiese nukleotiedbasis-areas vir VVG 0425 gelewer, maar pogings om NKAA-merkers uit hierdie geamplifiseerde nukleotiedbasis-areas te onwikkel was onsuksesvol. In teenstelling hiermee het ‘n inter-retrotransposon geamplifiseerde polimorfisme (IRAP) vingerafdrukmetode die ontwikkeling van ‘n multipleks IR-NKAA polimerase kettingreaksiemetode moontlik gemaak wat die VVG 0421-, VVG 0425- en ELV 4-isolate as ’n groep aangedui het. Vingerafdruktoetsing en NKAA-merkertoetsing van die 88 ongekaraktariseerde F. oxysporum isolate van Suid-Afrika (65 Focep en 23 nie-patogenies) het bevestig dat VVG 0425 die hoof VVG in Suid-Afrika is wat met volwasse bolle geassosieer word, aangesien 63 van die Focep-isolate die molekulêre eienskappe van VVG 0425 gehad het. Die derde doel van die studie was om vas te stel of saad en saailinge inokulumbronne van Focep is, en of dieselfde genotipe (VVG 0425) wat op volwasse bolle dominant is, waargeneem kon word op hierdie bronne. Focep-isolate is verkry van sewe van die 13 uiesaadlotte asook van uiesaailinge wat in al vyf uiesaailingkwekerye in die Wes-Kaap versamel is. Focep-saailinginfeksie was meer as dubbel in die 14-week groeistadium as wat dit in die 6-week stadium was. Saadinfeksies deur Focep was laag, maar die saadgedraagde aard van Focep is bevestig deur aan te toon dat ’n Focep-transformant wat met ‘n groen fluoreserende proteïen geëtiketeer is, van geïnfekteerde grond na uiesaad oorgedra kon word via die uiebolle en -saadstele. Dit is dus duidelik dat kommersiële saad en saailinge as inokulumbronne van Focep dien. Die Focep-genotipes op saad en saailinge verskil egter van dié in volwasse bolle en is nie deur VVG 0425 gedomineer nie. Verder was die meeste (≤ 60%) saad- en saailingisolate matig virulent, in teenstelling met die meestal hoogs virulente isolate uit volwasse bolle.

Seed borne

Basal rot

Fusarium oxysporum

Inoculum

Dissertations -- Plant pathology

Theses -- Plant pathology

Plant pathogens