Spelling suggestions: "subject:"invasion dynamics"" "subject:"dinvasion dynamics""
1 |
Modeling future range expansion and management strategies for an invasive squirrel speciesGoldstein, Emily A., Butler, Fidelma, Lawton, Colin 18 February 2016 (has links)
Successful management of an invasive
species requires in depth knowledge of the invader, the
invaded ecosystem, and their interactions. The complexity
of the species-system interactions can be
reduced and represented in ecological models for
better comprehension. In this study, a spatially explicit
population model was created using the RAMAS
software package to simulate the past and future
invasion dynamics of the eastern grey squirrel (Sciurus
carolinensis) in the fragmented habitat in case study
areas in Ireland. This invasive squirrel species causes
economic damage by bark stripping forest crops and is
associated with the decline of its native congener (S.
vulgaris). Three combinations of demographic and
dispersal parameters, which best matched the distribution
of the species shortly after introduction, were
used to simulate invasion dynamics. Future population
expansion was modeled under scenarios of no control
and two different management strategies: fatal culls
and immunocontraceptive vaccination programmes.
In the absence of control, the grey squirrel range is
predicted to expand to the south and southwest of
Ireland endangering internationally important habitats,
vulnerable forest crops, and the native red
squirrel. The model revealed that region-wide intensive
and coordinated culls would have the greatest
impact on grey squirrel populations. Control strategies
consisting solely of immunocontraceptive vaccines,
often preferred by public interest groups, are predicted
to be less effective. Complete eradication of the grey
squirrel from Ireland is not economically feasible and
strategic evidence-based management is required to
limit further range expansion. Ecological models can
be used to choose between informed management
strategies based on predicted outcomes.
|
2 |
Mathematical foundation of invasion exponents associated with adaptive dynamics / 適応ダイナミックスにおける侵入指数の数学的な基礎付けに関する研究Oba, Takuji 25 March 2019 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(情報学) / 甲第21914号 / 情博第697号 / 新制||情||120(附属図書館) / 京都大学大学院情報学研究科先端数理科学専攻 / (主査)教授 木上 淳, 教授 磯 祐介, 准教授 藤原 宏志 / 学位規則第4条第1項該当 / Doctor of Informatics / Kyoto University / DFAM
|
3 |
Dynamique évolutive des bactéries endocellulaires Wolbachia et des incompatibilités cytoplasmiques chez le moustique Culex pipiens / Evolutionary dynamics of endocellular bacteria Wolbachia and cytoplasmic incompatibilities in the mosquito Culex pipiensAtyame Nten, Célestine Michelle 27 June 2011 (has links)
Les Wolbachia sont des α-Protéobactéries endocellulaires transmises maternellement et qui manipulent la reproduction des Arthropodes pour augmenter leur transmission. Chez le moustique Culex pipiens, Wolbachia induit l'incompatibilité cytoplasmique (IC) qui se traduit par une forte mortalité embryonnaire lors de croisements entre individus infectés par des souches incompatibles de Wolbachia. Ce moustique se caractérise par une forte diversité génétique de ses Wolbachia (nommées wPip) et par des patrons d'IC complexes. Nous avons examiné les mécanismes qui façonnent la dynamique de cette association symbiotique aux niveaux génomique, phénotypique et populationnel. Nous avons montré que les souches wPip ont une origine génétique commune récente et qu'elles s'organisent en groupes génétiques présentant une structuration géographique. Nous avons mis en évidence des évènements de recombinaison entre souches wPip qui pourraient jouer un rôle majeur dans la diversité génétique des Wolbachia et dans l'évolution rapide des patrons d'IC. En croisant des lignées de moustiques d'origines géographiques diverses et infectées par des souches de différents groupes génétiques, nous avons montré que les IC (i) évoluent très rapidement chez Cx. pipiens; (ii) sont contrôlées par plusieurs déterminants génétiques, et (iii) qu'il y a une relation entre les patrons d'IC et les groupes génétiques des Wolbachia. Dans les populations naturelles, il apparaît que les IC sont contre sélectionnées au sein d'une population mais qu'une zone de contact entre populations infectées par des souches incompatibles peut se maintenir de façon stable. / Wolbachia are maternally inherited endocellular α-Proteobacteria that manipulate the reproduction of Arthropods to promote their own transmission. In the mosquito Culex pipiens, Wolbachia induce cytoplasmic incompatibility (CI) which results in high embryonic mortality in crosses between mosquitoes infected with incompatible Wolbachia strains. This mosquito is characterized by high genetic diversity of its Wolbachia (referred as wPip strains) and by complex CI patterns. We examined mechanisms that shape the dynamics of this symbiotic association at genomic, phenotypic and field population levels to understand how it evolves. We showed that wPip strains have a unique and recent evolutionary origin and that their diversity clusters into distinct genetic groups with a geographic structure. We revealed the existence of extensive recombinations among wPip strains, which could influence their adaptive dynamics by creating new wPip strains and thus allow the rapid emergence of new CI patterns. The analysis of crossing relationships between mosquito lines from different geographic origins and infected with wPip strains belonging to different genetic groups showed that CIs (i) evolve rapidly in Cx. pipiens; (ii) are controlled by several genetic factors, and (iii) there is a significant relationship between CI patterns and genetic divergence of wPip strains. In field populations, it appears that CIs are selected against within a population but a contact zone between populations infected by incompatible Wolbachia strains can be stably maintained.
|
Page generated in 0.0847 seconds