Transcript Ph. ramosa
AGRICULTURAL UNIVERSITY OF ATHENS HOST-PARASITE INTERACTION REVEALS INTER- AND INTRASPECIFIC VARIATION FOR PHELIPANCHE SPECIES Lyra1, D., Economou1, G. and Kotoula-Syka2, E. 1. Agricultural University of Athens Hellas 2. Democritus University of Thrace Orestiada Hellas E-mail: [email protected] 2nd International Conference on «Novel and Sustainable Weed Management in arid and semi-arid agro-ecosystems» 7-10 September Santorini Hellas Introduction Material & Methods Results Discussion & Conclusions O. cumana Ph. aegyptiaca O. crenata O. minor (Gianniantonio Domina 2005) Ph. ramosa Introduction Material & Methods Results Broomrapes as holoparasites depend on their host-plants for resources in order to secure their survival and perpetuation Discussion & Conclusions Introduction O. cumana Results Material & Methods Discussion & Conclusions O. crenata Ph. ramosa Orobanche and Phelipanche Ph. aegyptiaca species A varying degree of host-plant specificity O. minor Introduction Material & Methods Results Discussion & Conclusions Introduction Material & Methods Results Hosts Broomrapes HOST Root system H3C CH3 O SPECIFICITY O H3C CH3 O O H O OH H3C CH3 O O H O O O O CH3 H OH O Discussion & Conclusions O O O CH3 CH3 5-Deoxystrigol Orobanchol 2‘-epi-Orobanchol Seeds Introduction Material & Methods Results Discussion & Conclusions During host-parasite interaction, A VARIATION has been observed from both sides which has to do with……… Introduction Material & Methods Results Discussion & Conclusions 1st case Hosts Solanaceae Cannabidaceae Compositae Cruciferae Cucurbitaceae …stimulants HOST SPECIFICITY Broomrape species Introduction Host Results Material & Methods Discussion & Conclusions 2nd case Broomrape populations … variable response HOST SPECIFICITY Pop. 1 Pop. 3 Pop. 2 Pop. 4 Introduction Results Material & Methods Discussion & Conclusions Hosts Not all host plants do they exude substances with the same chemical composition Broomrapes HOST SPECIFICITY Broomrape seeds demonstrate different sensitivity in the biochemical stimulus derived from planthost roots The main research objective of our study Introduction Material & Methods Results Discussion & Conclusions Why are we interested in studying population diversity? Populations are categorized according to the level of divergence between them Variability (morphological, genetical, physiological, spatial heterogeneity) Hybrids / Subspecies (Ph. ramosa / Ph. aegyptiaca) Races (O. cumana) Host-specificity is one of the driver of genetic divergence Impact on decision-making processes for Orobanche control Introduction Material & Methods Results Discussion & Conclusions Broomrape plants were collected from naturally parasitized tobacco and tomato crops Introduction Material & Methods Results Discussion & Conclusions Ph. aegyptiaca Ph. ramosa / Ph. aegyptiaca Ph. ramosa Introduction Material & Methods Results Discussion & Conclusions Ph. ramosa Introduction Material & Methods 20 Phelipanche ramosa populations Results Discussion & Conclusions 28 Phelipanche aegyptiaca populations Introduction Material & Methods Results Discussion & Conclusions 1st experiment • Hosts: 2 rapeseed varieties (EXACT, CALIFORNIA) - tobacco 3 Phelipanche ramosa populations 4 Phelipanche aegyptiaca populations 2nd experiment •Host: tobacco 13 Phelipanche ramosa populations 6 Phelipanche aegyptiaca populations 3rd experiment •Host: tomato 18 Phelipanche ramosa populations 9 Phelipanche aegyptiaca populations Introduction Material & Methods Results Discussion & Conclusions MEASUREMENTS • Germinated seeds • Formed tubercles Plastic bag assays were used to study hosts and holoparasite interactions in vivo Introduction Results Material & Methods Discussion & Conclusions Statistical analysis * Data did not follow Normal Distribution * Kruskal – Wallis test / Nemenyi test ? * Box-Whisker plot Median AEG Data range Outliers RAM 0 4 Mean Interquartile range 8 12 16 20 24 Introduction Material & Methods st 1 Results Discussion & Conclusions experiment C a n o l a – To b a c c o Interspecific variability Germination (%) 100 Formed tubercles b 80 5 60 4 b 3 40 a 20 2 a 1 0 CALIFORNIA EXACT TOBACCO 100 a 0 CALIFORNIA EXACT 24 c b TOBACCO b 20 80 60 a a 16 b 12 40 8 20 a 4 0 CALIFORNIA EXACT TOBACCO 0 CALIFORNIA EXACT TOBACCO Intraspecific variability Germination (%) (Phelipanche populations collected on tobacco same region-same year) 100 e O. ramosa 100 100 O. ramosa O. aegyptiaca O. ramosa 80 80 80 d d d 60 60 60 c 40 40 c 20 a b a c 20 LA1 LA2 LA3 LA4 LA5 LA6 b a LA2 Broomrape populatIons 8 O. ramosa c b 4 ab ab a O. aegyptiaca LA3 LA4 LA5 LA6 LA7 0 LA1 15 O. ramosa O. aegyptiaca LA2 LA3 LA4 LA5 LA6 LA7 Broomrape populatIons e 36 O. ramosa O. aegyptiaca 30 12 6 bc c Broomrape populatIons O. aegyptiaca d 20 a LA1 LA7 O. aegyptiaca 40 0 0 Formed tubercles f e 9 b 6 d 24 d 18 c 12 2 3 a a a LA1 LA2 0 LA3 LA4 a a LA5 LA6 Broomrape populatIons CALIFORNIA 0 LA7 6 a a a LA1 LA2 LA3 c bc a LA4 LA5 LA6 Broomrape populatIons EXACT LA7 ab a a LA4 LA5 0 LA1 LA2 LA3 LA6 Broomrape populatIons TOBACCO LA7 results • Ph. ramosa‘s seeds germinated more by tobacco • More host-specific • Ph. aegyptiaca’s seeds germinated more by canola • • • Less host-specific Less tubercles on canola root system More tubercles on tobacco root system Introduction Material & Methods nd 2 Results Discussion & Conclusions experiment Tobacco Interspecific Variability ? a AEG Ph. aegyptiaca b Ph. ramosa RAM 0 20 40 60 80 100 6 9 12 15 Germination (%) ? a AEG Ph. aegyptiaca a RAM Ph. ramosa 0 3 Formed tubercles Germination (%) 100 O. aegyptiaca O. ramosa Region 2 2004 80 60 Region 2 2004 Region 1 Collection year 2002 Region 1 2003 Intraspecific variability 40 20 Ph. ramosa 0 ? A1A2A3A4A5RARBRCRDRERFRGRHRI RJRKRLRM Formed tubercles 15 O. ramosa O. aegyptiaca Region 2 2004 12 Region 2 2004 9 Region 1 Collection year 2002 Region 1 2003 6 3 0 ?1 A1 A2 A3 A4 Phelipanche populations A5 RA RB RC RD RE RF RG RH RI RJ RK RL RM populations collected on tobacco different regionsdifferent years results • • • • Ph. ramosa‘s seeds germinated more compared to Ph. aegyptiaca’s seeds The number of tubercles was not statistical different for both species High variability among and within regions High variability among and within collective years Introduction Material & Methods rd 3 Results Discussion & Conclusions experiment Tomato Interspecific Variability ? a Ph. aegyptiaca AEG b Ph. ramosa RAM 0 20 40 60 Germination (%) 80 100 ? a Ph. aegyptiaca AEG b RAM Ph. ramosa 0 4 8 12 Formed tubercles 16 20 24 Germination (%) 100 Region 2 2004 Region 3 2003 Region 4 2004 80 60 Intraspecific variability Region 3 Collection year 2002 40 20 0 24 Formed tubercles Region 1 2004 20 16 O. aegyptiaca Ph. ramosa O. ramosa ? ?1 ?2 ?3 A 4 1O. A2aegyptiaca A3A4A5A6A7A8AR 9A RB RC RD RERF RG RHRI RR JK RL RM RN RORP RQ RR O. ramosa Region 1 2004 Region 2 2004 Region 3 2003 Region 3 Collection year 2002 Region 4 2004 12 8 4 0 ? ?1 ?2 ?3 A1 4 A2A3A4 A5APhelipanche 6A7A8 AR 9A RB RC RD RE RF RG RHRIRR JK RL RM RN RO RP RQ RR populations populations collected on tobacco different regionsdifferent years results • • Ph. ramosa‘s seeds germinated more compared to Ph. aegyptiaca’s seeds The number of tubercles was statistical different for both species • High variability among and within regions High variability among and within collective years • Ph. ramosa seems to be more host-specific • Introduction Results Material & Methods Discussion & Conclusions Why were not many tubercles formed on canola root system by Ph. ramosa (1st experiment)? Tobacco – a traditional crop Canola – a newly introduced cultivation • • Why were not many tubercles formed on tobacco root system by Ph. ramosa, although germination was high (1st experiment)? Tobacco variety Second level of resistance • • Are Ph. aegyptiaca/Ph. ramosa highly host-specified species ? No Introduction Material & Methods Results Discussion & Conclusions Where can population variability be attributed? Massive collections of seeds Weight Shape Size Seed coat Genetic material Physiological age Dormancy Introduction Material & Methods Results Discussion & Conclusions Spatial heterogeneity Climate Landscape Topography Soil