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A G R I C U L T U R A L U N I V E R S I T Y O F A T H E N S. Lyra 1 , D., Economou 1 , G. and Kotoula-Syka 2 , E. 1. Agricultural University of Athens Hellas 2. Democritus University of Thrace Orestiada Hellas E-mail: dionyssialyra@yahoo.com.
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A G R I C U L T U R A L U N I V E R S I T Y O F A T H E N S Lyra1, D., Economou1, G. and Kotoula-Syka2, E.1. Agricultural University of Athens Hellas2. Democritus University of Thrace Orestiada HellasE-mail: dionyssialyra@yahoo.com Host-parasiteinteractionrevealsinter- andintraspecificvariationfor Phelipanchespecies 2nd International Conference on«Novel and Sustainable Weed Managementin arid and semi-arid agro-ecosystems» 7-10 September Santorini Hellas
Introduction Results Material & Methods Discussion & Conclusions O. cumana Ph. aegyptiaca Theory building (Gianniantonio Domina 2005) Ph. ramosa O. crenata O. minor
Introduction Results Material & Methods Discussion & Conclusions Theory building Broomrapes as holoparasites depend on their host-plants for resources in order to secure their survival and perpetuation
Introduction Results Material & Methods Discussion & Conclusions O. crenata Ph. ramosa O. cumana Orobanche and Phelipanche species A varying degree of host-plant specificity Ph. aegyptiaca O. minor
Introduction Results Material & Methods Discussion & Conclusions What is host specificity?
Introduction Results Material & Methods Discussion & Conclusions Hosts Broomrapes HOST SPECIFICITY Seeds Root system 5-Deoxystrigol Stimulants Orobanchol 2‘-epi-Orobanchol
Introduction Results Material & Methods Discussion & Conclusions During host-parasite interaction, A VARIATION has been observed from both sides which has to do with………
Introduction Results Material & Methods Discussion & Conclusions 1st case …stimulants Broomrape species Hosts Solanaceae Cannabidaceae Compositae Cruciferae Cucurbitaceae HOST SPECIFICITY
Introduction Results Material & Methods Discussion & Conclusions 2nd case … variable response Broomrape populations Host HOST SPECIFICITY Pop. 1 Pop. 3 Pop. 2 Pop. 4
Introduction Results Material & Methods Discussion & Conclusions Hosts Broomrapes Broomrape seeds demonstrate different sensitivity in the biochemical stimulus derived from plant-host roots HOST SPECIFICITY Not all host plants do they exude substances with the same chemical composition The main research objective of our study
Results Introduction Material & Methods 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
Results Introduction Material & Methods Discussion & Conclusions Sampling 2002-2004 Broomrape plants were collected from naturally parasitized tobacco and tomato crops
Results Introduction Material & Methods Discussion & Conclusions Tobacco Ph. aegyptiaca Ph. ramosa / Ph. aegyptiaca Ph. ramosa
Introduction Results Material & Methods Discussion & Conclusions Tomato Ph. ramosa
Introduction Results Material & Methods Discussion & Conclusions 20 Phelipanche ramosa populations 28 Phelipanche aegyptiaca populations
Introduction Results Material & Methods 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 Results Material & Methods 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 Data range Outliers Mean Interquartile range
Results Introduction Material & Methods Discussion & Conclusions 1st experiment C a n o l a – To b a c c o
Interspecific variability Germination (%) Formed tubercles b Ph. ramosa Ph. ramosa b a a a a Ph. aegyptiaca Ph. aegyptiaca c b b a b a
Intraspecific variability (Phelipanche populations collected on tobacco same region-same year) f e e O. ramosa O. ramosa O. ramosa O. aegyptiaca O. aegyptiaca d d d d bc Germination (%) c c ab ab a c c b b a a a a O. aegyptiaca B r o o m r a p e p o p u l a t I o n s B r o o m r a p e p o p u l a t I o n s B r o o m r a p e p o p u l a t I o n s O. ramosa O. aegyptiaca c e O. ramosa O. ramosa O. aegyptiaca O. aegyptiaca d d b Formed tubercles b c c a ab bc a a a a a a a a a a B r o o m r a p e p o p u l a t I o n s B r o o m r a p e p o p u l a t I o n s B r o o m r a p e p o p u l a t I o n s CALIFORNIA EXACT TOBACCO
Ph. ramosa‘s seeds germinated more by tobacco • More host-specific • Ph. aegyptiaca’sseeds germinated more by canola • Less host-specific • Less tubercles on canola root system • More tubercles on tobacco root system results
Results Introduction Material & Methods Discussion & Conclusions 2nd experiment Tobacco
Interspecific Variability Ph. aegyptiaca Ph. ramosa a Phelipanchespecies b Germination (%) Ph. aegyptiaca Ph. ramosa a Phelipanchespecies a Formed tubercles
Intraspecific variability O. aegyptiaca O. ramosa Region 2 2004 Region 1 Collection year 2002 Region 2 2004 Region 1 2003 Germination (%) Ph. ramosa populations collected on tobacco different regions-different years O. ramosa O. aegyptiaca Region 2 2004 Region 1 Collection year 2002 Region 2 2004 Region 1 2003 Formed tubercles Phelipanche populations
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
Results Introduction Material & Methods Discussion & Conclusions 3rd experiment Tomato
Interspecific Variability Ph. aegyptiaca Ph. ramosa a Phelipanchespecies b Germination (%) Ph. aegyptiaca Ph. ramosa a Phelipanchespecies b Formed tubercles
Intraspecific variability Region 1 2004 Region 2 2004 Region 3 2003 Region 4 2004 Region 3 Collection year 2002 Germination (%) Ph. ramosa populations collected on tobacco different regions-different years O. aegyptiaca O. ramosa O. aegyptiaca O. ramosa Region 3 Collection year 2002 Region 4 2004 Region 1 2004 Region 2 2004 Region 3 2003 Formed tubercles Phelipanche populations
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
Results Introduction 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
Results Introduction Material & Methods Discussion & Conclusions Where can population variability be attributed? Massive collections of seeds Weight Shape Size Seed coat Genetic material Physiological age Dormancy
Results Introduction Material & Methods Discussion & Conclusions Spatial heterogeneity Climate Landscape Topography Soil
