On the ecology of Diaeretiella rapae (M'Intosh)

McKenzie, Caroline Anne

January 1977

vii, 137 leaves : photos, (Part col.), graphs, tables ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Entomology, 1979

Diaeretiella rapae.

Brevicoryne brassicae.

Ecological patterns in plant defence chemistry and herbivore responses in natural populations of Brassica oleracea

Goodey, Nicole Ann

January 2015

Relationships between two taxonomic kingdoms; plants and herbivorous insects, are hypothesized to be a major zone of interaction for generating current day biodiversity; and coevolutionary processes between these intricately linked organisms are hypothesized to maintain diversity in plant secondary chemistry. These metabolites play a key role in plant defence against herbivory and a high degree of intraspecific variation is observed at multiple ecological scales. However, the nature of selection maintaining variation in plant defence profiles is still a major question in evolutionary biology and ecology, and progress towards a deeper understanding is hampered by a lack of studies that take into account ecological context and the multivariate nature of plant defence phenotypes. In this thesis, I employ sophisticated chemical analysis techniques to identify a suite of glucosinolate secondary chemicals, representing different biosynthetic pathways, in the wild cabbage, Brassica oleracea, in natural populations in the UK. I used model-based cluster analysis to explore patterns of association between individual glucosinolates, predicting that as simultaneous resource allocation to multiple defences is likely to be constrained; negative associations between defensive traits should be observed. However, results revealed positive associations between glucosinolates. Therefore co-expression of multiple defences may not be costly for this species. Using this information in conjunction with herbivore surveys and experiments, I show that this mixture has the potential to shape patterns of herbivore abundance and host plant utilization: species-specific responses to variation in glucosinolate phenotypes are discovered at various ecological scales. Thus there is the potential for differential selection on plant chemotypes though species-specific attractions and aversions. By conducting fine scale experiments with herbivore species, I also found that glucosinolate variation has an impact on the counter-adaptations that some brassica specialists have evolved: in order to optimally defend against their own natural enemies, Brevicoryne brassicae aphids sequestering glucosinolates from their host plants must do so selectively, and must choose plants whose chemical profile best matches this behaviour. These findings show that glucosinolate profiles may be under natural selection by herbivores in wild populations, and that reciprocal evolution between these plants and their specialists may continue to promote diversity in secondary metabolites. Together these results highlight the complexity inherent in plant-insect interactions, the importance of field studies and generate a wealth of testable hypotheses for future work.

635

Black mustard and the butterfly effect : metabolomics of plant-insect interactions under multiple stress conditions

Papazian, Stefano

January 2017

One main goal of ecological research is to understand nature´s complexity, in order to predict the potential impact of environmental perturbations. In this thesis, I investigate the ecological interactions between some of the most ancient organisms living on our planet: plants and insects. Focus of my research is the interaction between the wild brassicaceous plant black mustard (Brassica nigra L.) and its specialist insect herbivore, the large white cabbage butterfly (Pieris brassicae L). Both organisms are well characterized model species used in chemical ecology research. Using different analytical techniques, such as liquid and gas chromatography coupled to mass-spectrometry (LC- and GC-MS) and headspace collection of volatile organic compounds (VOCs), I apply the approach of metabolomics and systems biology to the field of ecology to explore the metabolic changes occurring inside the plants exposed to biotic and abiotic stresses. Particularly, I study the plant metabolic responses against P. brassicae chewing caterpillars during sequential treatment exposure to: abiotic stress by the oxidative air pollutant ozone (O3); dual herbivory with specialist Brevicoryne brassicae piercing-sucking aphids; and chemical induction of plant defences with the oxylipin phytohormone methyl-jasmonate (MeJA). Results show how during herbivore-induced responses, changes in defence- and growth-metabolic processes are tightly connected to stress protection mechanisms, indicating that plants actively reprogram their inner metabolic networks in order to adapt to consecutive changes in the environment. This thesis illustrates how evaluating the plant metabolome in its entirety rather than single metabolites, can help us understanding plant responses towards abiotic and biotic stresses, and improve our ability to predict how constant shifts in the environment affect plant physiology and ecology. / Ett huvudsyfte för ekologisk forskning är att förstå naturens komplexitet för att kunna förutse effekter av störningar i miljön. I min avhandling har jag fokuserat på ekologiska interaktioner mellan växter och insekter, två av de äldsta terrestra organismgrupperna på jorden. I mina studier har jag undersökt interaktioner mellan den korsblommiga växten svartsenap (Brassica nigra L.) och den specifika herbivoren kålfjäril (Pieris brassicae L.). Båda är väl karaktäriserade modellarter i kemisk-ekologisk forskning. De metaboliska förändringar som sker när växten utsätts för biotisk och abiotisk stress har analyserats hjälp av metabolomik, det vill säga analyser av metabolomet i sin helhet med hjälp av tekniker som vätske- och gaskromatografi kopplad till masspektrometri (LC- och GC-MS), och så kallad headspace-uppsamling av flyktiga organiska föreningar (VOCs). Jag har särskilt undersökt de metaboliska förändringar som sker när växten betas av kålfjärilslarver vid samtidig exponering för: abiotisk stress i form av ozon (O3), en oxidativ luftförorening; ytterligare betning i form av stickande och sugande bladlus (Brevicoryne brassicae); tillsats av oxylipinfytohormon metyl-jasmonat (MeJA), ett ämne som inducerar växtens försvar. Resultaten visar att de metaboliska förändringar som sker i växten vid herbivori med konsekvenser för dess försvar och tillväxt är nära kopplade till de metaboliska förändringar som sker vid stress, vilket visar att växten kan fortlöpande och aktivt omprogrammera sina metaboliska nätverk för att anpassa sig till förändringar i miljön. Avhandlingen visar att genom att utvärdera växtmetabolomet i sin helhet, snarare än att studera enskilda metaboliter, vi kan få bättre förståelse för hur växter reagerar på olika former av stress och därmed också bidra till att vi kan göra förutsägelser för hur förändringar i miljön kan påverka växters fysiologi och ekologi.

plant physiology

metabolomics

glucosinolates

multiple stress

ozone

Brassica nigra

Pieris brassicae

Brevicoryne brassicae

Ecology

Ekologi

Influence of plant architecture on tritrophic interactions between winter canola (Brassicae napus), Aphids (Hemiptera: Aphididae) and Hippodamia convergens (Coleoptera: Coccinellidae)

Cibils-Stewart, Ximena

January 1900

Master of Science / Department of Entomology / Brian P. McCornack / Winter canola production in the south-central US is commonly threatened by a complex of aphid species that can cause up to 70% in yield loss. Aphid species vary in their life-history traits, performance (sequestration/excretion of secondary compounds; glucosinolates), vertical distribution within the plant, and temporal dynamics across the growing season. Colonizing behavior of these aphids may be affected by intrinsic characteristics of the host plant (bottom-up effects), such as nutritional value, secondary compounds, or plant architecture. Understanding bottom-up effects may enable the evaluation of plant-level interactions that are influencing predator-prey dynamics. The goal of my research project is to understand aphid population dynamics in different canola plant structures, assess whether aphid quality (sequestration/ excretion of glucosinolates) is influenced by feeding location on the canola plant, and if so, assess the impact on the existing predator communities, specifically the development and fitness of immature and adult Hippodamia convergens. A combination of filed and greenhouse experiments provided novel contributions that will help shape our understanding of key factors regulating aphid population growth in canola fields, which will lead to more judicious use of insecticides and better sampling strategies.

Lady beetles

Aphids

Canola

Demography

Aphididae

Coccinellidae

Hippodamia convergens

Brevicoryne brassicae

Myzus persicae

LTRE

Biology (0306)

Ecology (0329)

Entomology (0353)

Climate-induced changes to multi-trophic interactions in an agroecosystem

Romo, Cecilia Marie

January 2012

Our earth is currently undergoing unprecedented human induced climate change, which is expected to drive widespread changes in species distributions and abundances that will affect natural pest suppression. Recent studies have suggested that climate change may cause changes to predator and herbivore assemblages in ways that alter multi-trophic food webs and affect the stability of ecosystems. Moreover, higher temperatures and increased climatic variability are expected to induce differential responses from predators and their prey that will undoubtedly disrupt species interactions. This thesis aims to test how climate change will impact the ability of natural enemies to continue to control pests in agroecosystems, and how they will continue to survive and function. In a field experiment using 13 farm sites across a natural temperature gradient, I found that temperature had direct positive effects on the abundances of the dominant parasitoid (an aphid specialist) and hyperparasitoid species, highlighting the importance of specific species responses in shaping larger communities. I also found that overall community composition was affected by temperature, with composition in warmer sites changing more throughout the season than cooler sites. In a future of inevitable climatic changes this result tells us we can expect arthropod community structure to change, which will have questionable impacts on overall population dynamics. To build on the field experiments, I used laboratory experiments to test differential responses of species to both drought and temperature and found that natural enemies responded to drought and temperature in a non-additive way, suggesting that the interaction between various climate change drivers is more important than their singular effect. Also, different species of natural enemies responded differently to abiotic factors, highlighting the importance of conserving natural enemies that can maintain important functional attributes in the face of climate change. Although biodiversity can be important for ensuring ecosystem functioning, response diversity, rather than species richness, may better promote ecosystem resilience, especially in the face of changing climate. The mechanisms underlying biodiversity effects are often difficult to disentangle, however, by manipulating the diversity of climate responses exhibited by ecosystem service providers, I tested how the rates and stability of prey suppression by predators are affected by climate warming and drought. I found that predator combinations with different individual responses to climate change maintained greater and less variable (i.e. more stable) prey suppression, compared with single predator species or combinations of predators with similar climate responses. This response complementarity became strongest through time and under drought or high temperature treatments. I suggest that response complementarity provides ‘insurance’ effects, which may be more important than previously envisaged for maintaining ecosystem functions such as biological control under global environmental change. Overall, the non-additive effects of different climate drivers, combined with differing responses across trophic levels, suggests that predicting future pest outbreaks will be more challenging than previously imagined.

aphids

biodiversity

Brevicoryne brassicae

climate change

complementarity

drought

herbivore

hyperparasitoids

insurance

interactive drivers

natural enemies

parasitoid

predator-prey interactions

temperature

Circadian rhythms and effects of different diets on the development and reproduction of Nabis Kinbergii (Hemipteria : Nabidae).

Nguyen, Quang Huu

January 2008

Nabis kinbergii is a native polyphagous predator in Australia. It has been found in all states and territories of Australia. N. kinbergii has been regarded as an efficient predator of many insect pests in lucerne, cotton and particularly brassica crops. The circadian rhythms, the effects of different prey on development and reproduction, and prey preferences of N. kinbergii have not been studied in South Australia. These are the subjects of this thesis. N. kinbergii is more active at night than in the day. They seemed to be still more frequently at dawn and more active at dusk under natural environmental conditions. Yet, their behaviour was possibly different when they were held in a controlled environment with artificial light. Under both natural and artificial lighting conditions, they would spend more time moving on plants at night. They spent less time moving than other activities. Furthermore, they were more active during the second day of the observations, probably because of the hunger. A mixed diet including Plutella xylostella, Myzus persicae and Brevicoryne brassicae brought the most significant positive influences to the development, survival and longevity of N. kinbergii. It had a shorter preoviposition period and greater egg production when fed on P. xylostella than when fed on M. persicae. Among the three prey, B. brassica was the poorest food because the survival rate between egg hatch and adult eclosion was only 7.5 %, compared to 85 %, 92.5 % and 97.5 % when N. kinbergii fed on M. persicae, P. xylostella and a mixed diet, respectively. Evidence of prey preference was exhibited by N. kinbergii. B. brassica seemed to be the least preferred food. N. kinbergii possibly attacked less mobile prey and delayed eating prey with poor nutrition or that were toxic. In wind tunnel experiments, N. kinbergii may have been attracted by plant volatiles rather than prey odour. These findings may help to refine the timing of experiments and improve the understanding of the role of this predator in integrated pest management. / Thesis (M.Sc.) -- University of Adelaide, School of Agriculture, Food and Wine, 2008

Agricultural pests -- Australia.

Agricultural pests -- Ecology.

The effectiveness of Solanum panduriforme (Mey) based extracts on the cabbage aphid, Brevicoryne brassicae (Linnacus) on brassicas

Mhazo, Mary Louis

18 May 2018

PhD (Agric) (Plant Production) / Department of Plant Production / Brassicas are important vegetable crops grown for home consumption and market gardening in eastern and southern Africa. However, productivity is affected by aphids, through both direct feeding and disease transmission. Botanical insecticides have potential to control the aphids, but so far few plants have been evaluated for use on brassicas. This study was conducted to evaluate the effectiveness of Solanum panduriforme to control aphids on brassicas. Botanical extracts from three parts of S. panduriforme were assessed for their insecticidal effects on the cabbage aphid, Brevicoryne brassicae. The extracts from leaf powder (LP), ripe berry powder (BP), fresh ripe berries (RB) and fresh unripe berries (UB) were extracted with four solvents; water, ethanol, hexane and diethyl ether, using homogenisation, maceration and solvent-assisted / sequential extraction methods. The effectiveness of the extracts was determined by laboratory bioassays as well as by plant assays in the screen house and under field conditions. The experiments were replicated three or four times depending on the assays and the design used was completely randomized design (CRD). The immature (LP and UB) plant parts were generally more effective than the mature (BP and RB) plant parts, with mortalities ranging from 100 % down to 40 % respectively depending on assays. Ethanol extracts were more effective than aqueous extracts (LP 96% and 63%; BP 96% and 64%; RB 100% and 64%; UB 100% and 90%). The dried crude extracts from hexane were more effective than di-ethyl ether extracts. The group chemical analysis indicated presence of alkaloids in the berries (BP, RB and UB), which were absent in the leaves (LP). Phenolic compounds and flavonoids were present in all the extracts (LP, BP, RB, and UB). Saponins were present in the fresh parts (RB and UB). The results show how the locally available S. panduriforme plants can be used as an aphicide to control aphids on brassicas. Farmers can directly prepare an easy and cheap botanical / NRF

Aphicide

Biossays

Brassica

Brevicoryne brassicae

Effectiveness

Extracts

Mortality

Solan panduriforme

635.340968

Brassica -- South Africa -- Limpopo

Cabbage -- South Africa

Cabbage aphid -- South Africa

Preference-performance relationships in herbivorous insects feeding on oilseed rape inoculated with soil-borne fungi

Li, Hong

03 July 2008

No description available.

630 Landwirtschaft

Veterinärmedizin

Agricultural Sciences

Acremonium alternatum

Verticillium longisporum

Delia radicum

Brevicoryne brassicae

Plutella xylostella

preference-performance of insect

volatile profile

phytosterols profile.

42.75

YF 000: Haustiere

Insektenzucht

Tierzucht und Tierhaltung