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Fungal relationships with plants. Obligate and facultative parasitism/pathogenicity. Why is plant pathology important?. Food quantity Food quality Agrinomic practices – tillage, pesticide use Diversity and stability of ecosystems Beauty.
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Fungal relationships with plants Obligate and facultative parasitism/pathogenicity
Why is plant pathology important? • Food quantity • Food quality • Agrinomic practices – tillage, pesticide use • Diversity and stability of ecosystems • Beauty
Better understanding of disease processes – examples of use • Disease control through life cycle management • Puccinia graminis tritici on wheat and barberry • Orchard management practice in Venturia inaequalis • Optimizing pesticide application • Disease forecasting • Pesticide design • Breeding for resistance
Fungal pathogenicity on plants • Plant pathogens can be biotrophic (rusts and smuts) or hemibiotrophic/necrotrophic (opportunistic) • Necrotrophs can display high levels of host specificity, e. g. Magnaporthe grisea Increasing specialization Increasing host range Biotroph Obligate parasite Necrotroph “Strong” Facultative parasite Saprotroph “Weak” Facultative parasite
Symptom types -- necrosis Blumeriella on plum Alternaria solani – early blight of potato
Symptom types – wilt Ophiostoma novo-ulmi Panama disease: Fusarium oxysporum f.sp. cubense
Symptom types – hormone induced Hypertrophy auxin Taphrina deformans Synchytrium endobioticum http://www.maff.gov.uk/planth/pestnote/pwd.htm
Symptom types – hormone induced Etiolation Bakanae of rice Fusarium moniliforme = Gibberella fujikuroi gibberellins
Symptom types – abscission Hemileia vastatrix rust.lbl.gov
Symptom types – sterilization Ustilago maydis Claviceps purpurea – ergot
Obligate parasites – e. g. Uredinales • Rust fungi may have as many as five different • spore-producing stages in their life cycles • Heteroecism – e.g. wheat stem rust • two taxonomically different host plants in order to • complete life cycle • ‘alternate’ host: stages (haploid) • primary host: stages (diploid) • Autoecism – e.g. bean rust • - entire life cycle completed on a single host species • Microcyclic rusts ≤ 3 spore types
Life Cycle of Puccinia graminis I SUMMER aecia on barberry (n+n) urediniospores (n+n) airborne spermatia (n) insect transported to receptive hyphae (n) heterothallic II aeciospores (n+n) airborne O F A L L uredinia on grass from infection by aeciospores or urediniospores spermagonia on barberry from infection by basidiospores basidiospore (n) airborne meiosis III SPRING telia on grass IV teliospore on straw (n+n) karyogamy (2n) teliospore (2n) germinating on straw with promycelium and basidiospores (n) WINTER
ploidy host Puccinia graminis f.sp. tritici life cycle Overwintering and transport of urediospores
Stage IV Basidia bearing basidiospores (n) • in the spring teliospore germinates a promycelium • diploid nucleus migrates into the promycelium and • undergoes meiosis • four haploid nuclei migrate into developing sterigmata • & are incorporated into basidiospores • basidiospores reinfect alternate host
teliospore germinates, gives rise to a short germ tube of determinate growth known as the promycelium. Promycelium: site of meiosis & formation of sterigmata and basidiospores
Stage 0 and I produced on “alternate” host Stage 0: Spermogonia bearing spermatia (n) and receptive hyphae (n) helios.bto.ed.ac.uk/bto/microbes/biotroph.htm • fertilization of the receptive hyphae by spermatia initiates • the dikaryon and the formation of aecia
Puccinia plasmogamy www.apsnet.org/education/LessonsPlantPath/StemRustWheat
Stage II: Uredinia bearing urediniospores (n+n) helios.bto.ed.ac.uk/bto/microbes/biotroph.htm • reinfect primary host • amplifies disease within primary host • uredinia can eventually develop into telia
Teliospore: site of karyogamy technically part of the basidium Stage III: Telia bearing teliospores (n+n2n) • final stage on primary host • overwinters as dikaryon
Magnaporthe grisea / Oryza sativa Some non pathogenic M. grisea strains can grow in host plants if wound inoculated
Host resistance and basic compatibility • Most plants are not attacked by the vast majority of potential pathogens • Preformed defenses • Potential pathogens secrete chemicals during growth that can be detected
What is a pathogenicity gene? • A gene whose product contributes to successful fungal establishment in the host • Examples • Hydrolytic enzymes (especially for necrotrophs) • Compatibility determinants (especially for biotrophs) • Defense avoidance/detoxification
What is a resistance gene? • A gene whose product enables the host to detect a pathogen and/or mount a defense • The fungal product that is detected • does not have to be directly involved in pathogenesis • is defined as being produced by an avirulence gene
Heath – host pathogen interactions • Ann Bot 80, 713
Fungal pathogenicity on plants • Fungal pathogens of plants include opportunists, necrotrophs and biotrophs • Resistance is seen at several levels • Non-host resistance – • Widespread, early onset, effective • Passive – attachment/germination • Active – initial colonization, e. g. wall apposition • Hypersensitivity • Durable
Varietal resistance • Superimposed on basic compatibility • Often based on a single resistance gene • Typically not durable
Gene for gene interactions • Host R r • Pathogen A resist susc • a susc susc • basic compatibility overcomes nonhost defense • pressure on host to detect pathogen leads to (temporary) resistance • pressure on pathogen to overcome/evade resistance
Breeding for resistance • Identify likely targets, disrupt, look for attenuation of pathogenicity • Cross commercial susceptible strains to wild relatives, backcross to retain yield and desireable characters in resistant strain • 8-10 years; resistance may last 3-5 years • Pyramid strategies • Horizontal resistance