Transcript Document
CLASS REVIEW 2009 Lectures Summary of first class • Undertanding of nature, an essential part of culture • Forests essential for life on the planet • Fungi essential for survival of forests Summary of second class • DNA mutates, evolves, and different DNA sequences can be assigned to different individuals, populations from different provenances, closely related species, different species, different microbial pathovars • DNA-based phylogeography allowed to discover pine pathogen in Italy was of North American origin • DNA based genealogies allowed to identify hybridization between native and exotic pathogen • DNA allows to identify new species and to determine whether they are exotic or not Definitions • Propagule= structure used by an organism to spread or survive • Locus= a physical portion of a chromosome,a gene • Intron= a portion of DNA , a locus that does not code for a protein • Exon= a coding gene Definitions-2 • Alleles= different DNA sequences at the same locus • If a locus has variation in sequence it is polymorphic (many forms) • Polymorphisms are differences in DNA among organisms, the more polymorphisms the easier it is to differentiate organisms • There are more polymorphisms in introns Definitions-3 • Invasive organisms: exotic organism that reproduces and occupies progressively a larger area: – – – – – – – – – Fast reproductive cycle Vectored Hardy Occupy unoccupied niches Different drain on natural resources Make environment favorable for itself and other invaders Linked to disturbances If pathogen , more changes because top of pyramid May hybridize with native species: new taxon is created Summary of third lesson • DNA polymorphisms can be diagnostic – Mutations/Sex/Barriers to mating • Plant Diseases can be biotic (interaction between host and causal agent ), or abiotic • Many organisms can cause plant diseases, but fungi are the No.1 cause • Diversity of fungi, but all have ideal structure for plant infection: – hypha/cord/rhizomorph/infection peg/appressorium – Sexual vs. asexual reproduction: can do both Definitions • Alternatively fixed alleles • Dominant vs. co-dominant markers • Genotype Summary of previous lesson • Dominant vs. codominant genetic markers • Concept of “genotype” • Alternatively fixed allele vs.difference in frequencies • PLANT HOST INTERACTION: timing, physical/chemical interaction, basic genetic compatibility leads to virulence, gene for gene hypothesis, pathogenicity Categories of wild plant diseases • • • • • • • • Seed decay Seedling diseases Foliage diseases Systemic infections Parasitic plants Cankers, wilts , and diebacks Root and butt rots Floral diseases Summary of previous lesson • Janzen-Connol hypothesis; explanation of why diseases lead to spatial heterogeneity • Diseases also lead to heterogeneity or changes through time – Driving succession – The Red Queen Hypothesis: selection pressure will increase number of resistant plant genotypes • Co-evolution: pathogen increase virulence in short term, but in long term balance between host and pathogen • Density dependance The biology of the organism drives an epidemic • Autoinfection vs. alloinfection • Primary spread=by spores • Secondary spread=vegetative, clonal spread, same genotype . Completely different scales (from small to gigantic) Coriolus Heterobasidion Armillaria Phellinus OUR ABILITY TO: • Differentiate among different individuals (genotypes) • Determine gene flow among different areas • Determine allelic distribution in an area WILL ALLOW US TO DETERMINE: • How often primary infection occurs or is disease mostly chronic • How far can the pathogen move on its own • Is the organism reproducing sexually? is the source of infection local or does it need input from the outside Important fungal genetic systems: • Intersterility genes • Somatic (vegetative) compatibility • Mating system Summary • • • • AFLP, RAPDs, RFLPs, microsatellites Repeatability Test for power (PID and test progeny) Have we sampled enough? Rarefaction curves, resampling, need to be ob flat portion of curve Summary • • • • • From raw data to genetic distance Distance distribution AMOVA Distance based trees Number of polymorphic alleles The “scale” of disease • Dispersal gradients dependent on propagule size, resilience, ability to dessicate, NOTE: not linear • Important interaction with environment, habitat, and niche availability. Examples: Heterobasidion in Western Alps, Matsutake mushrooms that offer example of habitat tracking • Scale of dispersal (implicitely correlated to metapopulation structure)--- The scale of disease • Curves of spore dispersal (rapid dilution effect, e.g most spores fall near source, but a long low tail, a few spores will travel long distances • Genetic structure of species: the more structure the more fragmented the less dispersal • Mantel tests, spatial autocorrelation: plot the genetic distance against the geographic distance 8 y = 0.2452x + 0.5655 r 2 = 0.0266 7 6 Φ ST/(1-Φ ST) 5 4 3 2 1 0 1.5 2 2.5 3 3.5 4 4.5 Ln Geographic Distance (m) 5 5.5 6 6.5 1 0.6 0.5 0.4 Moran's I 0.3 0.2 0.1 0 -0.1 -0.2 1 10 100 1000 10000 Mean Geographical Distance (m) 2 100000 1000000 Using DNA sequences • Obtain sequence • Align sequences, number of parsimony informative sites • Gap handling • Picking sequences (order) • Analyze sequences (similarity/parsimony/exhaustive/bayesian • Analyze output; CI, HI Bootstrap/decay indices Population genetics concepts • Gene flow, migration • Lack of gene flow, genetic substructuring=differentiation • Hardy Weinberg= for diploid or dikaryotic organims predicts levels of heterozygosity • Inbreeding coefficient • Fst CLASS REVIEW 2008 Research papers Key points • • • • Organism is exotic, why? How does it kill oaks? How does it spread? What ecological conditions are necessary? • What can be done? Key points • Native fungus, host specialized • How does it infest stands? Does it need stumps? • How was research done? Sampling and analysis • What type of forests will enhance secondary spread? • Is source of inoculum local or not? • How was it shown that nuclei can rearrange themselves Key points • Wood decay fungus, generalist • Sexually reproducing hence lots of local diversity • Easily airborne, easy to find hosts, no genetic structure within Sweden • Structure between Sweden and Finland • Methods: RAPDS and AMOVA Key points Pathogen, very host-specific • Infection is mostly primary by airborne meiospores • Method: AFLP analysis on haploid meiospores • AMOVA indicated significant genetic diversity both within and among populations • Lack of host= barrier to migration Key points • Mycorrhizal fungus, obligate symbiont • Symbiont with most conifers, air dispersed • Japanese market buys some species, rejects others • Species accepted by market are monophyletic • At least 3 species: circumboreal, mexican, and west coast • North America= center of diversity • Oldest species is in North America • Methods: DNA sequencing and AFLPs • Isolation by distance: distant populations more different genetically Key points • Specific mycorrhizal symbiont, underground mushrooms, animal dispersed • Islands in islands • Compare genetics of fruitbodies and of seed banks • Genetic structure indicate low gene flow among sites, but similar genetic structure between two islands