Invoking posthumanist vistas: A diffractive gaze on curriculum practices and potential

Humanist discourse has assumed such an ideological normalcy to the extent that any attempts at its disruption are likely to be met with severe resistance. As such, higher education curriculum design and curriculum content continue to be largely anthropocentric, buoyed by human-centred neoliberal principles that have gradually encroached the academe. To explore ways out of the dilemma, we draw on wild pedagogy theory (Jickling 2015; Mcphie and Clarke 2015; Springgay and Zaliwska 2017; Jickling et al. 2018b) as a means to challenge the straitjacket constraints of neoliberal higher education. Over time, the wild has been banished from classrooms: the call for wild pedagogies might mean that we have reached the limits of the “tamed” ‒ and we have tamed a lot in order to offer a “one size fits all” approach to (higher) education (Jickling et al. 2018a). The tendency for higher education to teach more and more people in less and less time, has implied an understanding of teaching that is characterised by efficiency and processing, at the cost of the process of learning as a relational becoming with the world in the posthuman condition we live in (Braidotti 2019). In this article, vignettes are used to offer an account of our critical posthumanist incursions as university lecturers into curriculum practices. We use a diffractive gaze to present the generative potential of non-anthropocentric approaches as well as the struggles that these present as we strive to de-center our humanistic tendencies towards curriculum knowledge and teaching within the neoliberal space, we find ourselves

Plant structural changes due to herbivory: Do changes in Aceria-infested coconut fruits allow predatory mites to move under the perianth?

Being minute in size, eriophyoid mites can reach places that are small enough to be inaccessible to their predators. The coconut mite, Aceria guerreronis, is a typical example; it finds partial refuge under the perianth of the coconut fruit. However, some predators can move under the perianth of the coconut fruits and attack the coconut mite. In Sri Lanka, the phytoseiid mite Neoseiulus baraki, is the most common predatory mite found in association with the coconut mite. The cross-diameter of this predatory mite is c. 3 times larger than that of the coconut mite. Nevertheless, taking this predator’s flat body and elongated idiosoma into account, it is—relative to many other phytoseiid mites—better able to reach the narrow space under the perianth of infested coconut fruits. On uninfested coconut fruits, however, they are hardly ever observed under the perianth. Prompted by earlier work on the accessibility of tulip bulbs to another eriophyoid mite and its predators, we hypothesized that the structure of the coconut fruit perianth is changed in response to damage by eriophyoid mites and as a result predatory mites are better able to enter under the perianth of infested coconut fruits. This was tested in an experiment where we measured the gap between the rim of the perianth and the coconut fruit surface in three cultivars (‘Sri Lanka Tall’, ‘Sri Lanka Dwarf Green’ and ‘Sri Lanka Dwarf Green × Sri Lanka Tall’ hybrid) that are cultivated extensively in Sri Lanka. It was found that the perianth-fruit gap in uninfested coconut fruits was significantly different between cultivars: the cultivar ‘Sri Lanka Dwarf Green’ with its smaller and more elongated coconut fruits had a larger perianth-fruit gap. In the uninfested coconut fruits this gap was large enough for the coconut mite to creep under the perianth, yet too small for its predator N. baraki. However, when the coconut fruits were infested by coconut mites, the perianth-rim-fruit gap was not different among cultivars and had increased to such an extent that the space under the perianth became accessible to the predatory mites

Size of predatory mites and refuge entrance determine success of biological control of the coconut mite

Published online: 06 July 2016Predators face the challenge of accessing prey that live in sheltered habitats. The coconut mite Aceriaguerreronis Keifer (Acari: Eriophyidae) lives hidden beneath the perianth, which is appressed to the coconut fruit surface, where they feed on the meristematic tissue. Its natural enemy, the predatory mite Neoseiuluspaspalivorus De Leon (Acari: Phytoseiidae), is larger than this pest and is believed to gain access to the refuge only after its opening has increased with coconut fruit age. In the field, experimentally enlarging the perianth-rim-fruit distance beyond the size of the predators resulted in earlier predator occurrence beneath the perianth and lower numbers of coconut mites. On non-manipulated coconut fruits, the predators gained access to the prey weeks later than on manipulated ones, resulting in higher pest densities of coconut mites. Successful biological control thus critically hinges on the size of the predator relative to the opening of the prey refuge

Duurzame bestrijding tulpengalmijt : onderzoek naar de effectiviteit van de roofmijt Neoseiulus paspalivorus tegen tulpengalmijt Aceria tulipae en onderzoek naar alternatieve voedselbronnen voor N. paspalivorus

Tulpengalmijt vormt de grootste plaag in de bewaring van tulpen, is een risico voor verspreiding van TVX en kost de sector jaarlijks miljoenen euro’s. Huidige bestrijdingsmethodes werken in praktijk niet voldoende. Eerder onderzoek heeft aangetoond dat de roofmijt Neoseiulus paspalivorus tulpengalmijt in de bewaring goed in toom kan houden (project 14745). In een vervolgproef werd weer aangetoond dat de kleine roofmijt een goede bestrijder is van tulpengalmijt. Verder is er een stap gezet naar massakweek van de roofmijt door het vinden van alternatieve voedselbronnen. Met producenten van biologische bestrijders zijn contacten gelegd om de mogelijkheden voor commerciële massakweek te verkennen

Neoseiulus paspalivorus, een nieuwe bestrijder van tulpengalmijt?!

Tulpengalmijt vormt de grootste plaag in de bewaring van tulpen, is een risico voor verspreiding van TVX en kost de sector jaarlijks miljoenen euro’s. Huidige bestrijdingsmethodes werken in praktijk niet bevredigend en de toekomst van chemische middelen is onduidelijk. Reden voor PPO en de Universiteit van Amsterdam om samen onderzoek te doen naar alternatieve bestrijdingsmethode met roofmijten. De eerste proeven tonen aan dat de Braziliaanse rover Neoseiulus paspalivorus tulpengalmijt in de bewaring in toom kan houden en zichzelf goed kan handhaven. Hij presteert daarbij vele malen beter dan de eerder onderzochte Neoseiulus cucumeris. Vertegenwoordigers uit de praktijk zien kansen voor deze nieuwe roofmijt maar hebben nog veel vragen

Ambulatory dispersal in Tetranychus urticae: an artificial selection experiment on propensity to disperse yields no response

Dispersal to new hosts is an important process for an invasive herbivore, such as the two-spotted spider mite. A recent study, using artificial selection experiments, has suggested that genetic variation and genetic trade-offs are present for propensity to disperse in this species. However, due to the experimental setup alternative explanations for the response to selection could not be ruled out. Using an altered setup, we investigated whether the propensity for ambulatory dispersal differs genetically between individuals and whether genetic correlations with life-history traits exist. Upward and downward selection on propensity to leave the colony was performed for seven generations in four replicate artificial selection experiments and the results were compared to control lines. No consistent responses to selection were found and no significant effect on life-history traits (oviposition rate, juvenile survival, development rate and number of adult offspring) or sex ratio was present across the replicates. The data suggest that our base population of spider mites harbours at best a low amount of additive genetic variation for this behaviour

Herbivore benefits from vectoring plant virus through reduction of period of vulnerability to predation

Herbivores can profit from vectoring plant pathogens because the induced defence of plants against pathogens sometimes interferes with the induced defence of plants against herbivores. Plants can also defend themselves indirectly by the action of the natural enemies of the herbivores. It is unknown whether the defence against pathogens induced in the plant also interferes with the indirect defence against herbivores mediated via the third trophic level. We previously showed that infection of plants with Tomato spotted wilt virus (TSWV) increased the developmental rate of and juvenile survival of its vector, the thrips Frankliniella occidentalis. Here, we present the results of a study on the effects of TSWV infections of plants on the effectiveness of three species of natural enemies of F. occidentalis: the predatory mites Neoseiulus cucumeris and Iphiseius degenerans, and the predatory bug Orius laevigatus. The growth rate of thrips larvae was positively affected by the presence of virus in the host plant. Because large larvae are invulnerable to predation by the two species of predatory mites, this resulted in a shorter period of vulnerability to predation for thrips that developed on plants with virus than thrips developing on uninfected plants (4.4 vs. 7.9 days, respectively). Because large thrips larvae are not invulnerable to predation by the predatory bug Orius laevigatus, infection of the plant did not affect the predation risk of thrips larvae from this predator. This is the first demonstration of a negative effect of a plant pathogen on the predation risk of its vector