Génomique de l'adaptation de Globodera pallida aux résistances de la pomme de terre et conséquences sur les traits d'histoire de vie du nématode / Genomics of Globodera pallida adaptation to potato resistances and consequences on the nematode life-history traits

Eoche-Bosy, Delphine

23 November 2016

L’étude des modifications phénotypiques et génomiques associées à l’adaptation des pathogènes aux résistances est une étape fondamentale pour mieux comprendre et anticiper le phénomène de contournement des résistances. Le nématode à kyste Globodera pallida est un important pathogène de la pomme de terre, vis-à-vis duquel un QTL majeur de résistance, GpaVvrn, a été identifié chez Solanum vernei. Cependant, la capacité des populations de G. pallida à s’adapter à cette résistance en quelques générations seulement a été mise en évidence par évolution expérimentale. Dans ce contexte, ce travail de thèse avait pour objectifs (1) d’étudier les traits d’histoire de vie du nématode impactés par l’adaptation, afin de tester l’existence éventuelle d’un coût de virulence, et (2) d’identifier les régions génomiques impliquées dans l’adaptation, par une approche originale combinant évolution expérimentale et scans génomiques sur des lignées virulentes et avirulentes. Contre toute attente, nous avons montré que l’adaptation à la résistance issue de S. vernei entraînait une augmentation de la fitness des individus virulents sur hôte sensible. Nous avons également pu identifier des régions génomiques candidates à l’adaptation à la résistance de la plante hôte, contenant des gènes codant pour des effecteurs, et notamment des SPRYSECs, connus chez les nématodes à kyste pour être impliqués dans la suppression des défenses des plantes mais aussi dans la virulence du nématode. À terme, ces résultats s’avéreront utiles pour la conception de stratégies durables de déploiement de variétés de pommes de terre résistantes. / Studying phenotypic and genomic modifications associated with pathogen adaptation to resistance is a crucial step to better understand and anticipate resistance breakdown. The cyst nematode Globodera pallida is an important pest of potato crops, for which a major resistance QTL, GpaVvrn, has been identified in Solanum vernei. However, the capability of G. pallida populations to adapt to this resistance in only few generations has been highlighted through experimental evolution. In this context, the purposes of this work were (1) to study the nematode life-history traits impacted by adaptation, in order to test for potential existence of a virulence cost, and (2) to identify genomic regions involved in adaptation, through an original approach combining experimental evolution and genome scans on virulent and avirulent lineages. Unexpectedly, we highlighted that adaptation to resistance from S. vernei leads to an increase of virulent individual’s fitness on susceptible host. We were also able to pinpoint candidate genomic regions to adaptation to host plant resistance, containing genes encoding effectors, and especially SPRYSECs, known in cyst nematodes to be involved in suppression of host defense but also in nematode virulence. These results will ultimately be useful in order to conceive sustainable strategies of use of potato resistant cultivars

DURABILITE DES RESISTANCES

NEMATODE A KYSTE

EVOLUTION EXPERIMENTALE

POOL-SEQ

SCAN GENOMIQUE

CYST NEMATODE

EXPERIMENTAL EVOLUTION

GENOME SCAN

RESISTANCE DURABILITY

VIRULENCE COST

A functional genomic investigation of an alternative life history strategy : The Alba polymorphism in Colias croceus

Woronik, Alyssa

January 2017

Life history traits affect the timing and pattern of maturation, reproduction, and survival during an organism’s lifecycle and are the major components influencing Darwinian fitness. Co-evolved patterns of these traits are known as life history strategies (LHS) and variation occurs between individuals, populations, and species. The polymorphisms underlying LHS are important targets of natural selection, yet the underlying genes and physiological mechanisms remain largely unknown. Mapping the genetic basis of a LHS and subsequently unraveling the associated physiological mechanisms is a challenging task, as complex phenotypes are often polygenic. However, in several systems discrete LHS are maintained within the population and are inherited as a single locus with pleiotropic effects. These systems provide a promising starting point for investigation into LHS mechanisms and this thesis focuses on one such strategy - the Alba polymorphism in Colias butterflies. Alba is inherited as a single autosomal locus, expressed only in females, and simultaneously affects development rate, reproductive potential, and wing color. Alba females are white, while the alternative morph is yellow/orange. About 28 of 90 species exhibit polymorphic females, though whether the Alba mechanism and associated tradeoffs are conserved across the genus remains to be determined. In this thesis I primarily focus on the species Colias croceus and integrate results from lipidomics, transcriptomics, microscopy, and genomics to gain insights to the proximate mechanisms underlying Alba and Alba’s evolution within the genus. Lipidomics confirm that, consistent with findings in New World species, C. croceus Alba females have larger abdominal lipid stores than orange, an advantage which is temperature dependent and arises primarily due to mobilized lipids. Gene expression data suggests differences in resource allocation, with Alba females investing in reproduction rather than wing color, consistent with previous findings in other Colias species. Additionally, I identify a morphological basis for Alba’s white wing color. Alba females from C. croceus, an Old World species, and Colias eurytheme, a New World species both exhibit a significant reduction in pigment granules, the structures within the wing scale that contain pigment. This is a trait that seems to be unique to Colias as other white Pierid butterflies have an abundance of pigment granules, similar to orange females. I also map the genetic basis of Alba to a single genomic region containing an Alba specific, Jockey-like transposable element insertion. Interestingly this transposable element​ is located downstream of BarH-1, a gene known to affect pigment granule formation in Drosophila. Finally, I construct a phylogeny using a global distribution of 20 Colias species to facilitate investigations of Alba’s evolution within the genus. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Manuscript. Paper 3: Manuscript. Paper 4: Manuscript.</p>

alternative life history strategy

butterfly wing color

Alba

Colias

color polymorphism

dimorphism

life history traits

physiology

lipidomics

genomics

pooled sequencing

phylogenomics

RNA-Seq

Pool-Seq

Zoology

Zoologi