Climate change and its effects on terrestrial insects and herbivory patterns

Cornelissen, Tatiana

doi:10.1590/s1519-566x2011000200001

Cited by 193 publications

(128 citation statements)

References 51 publications

(91 reference statements)

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“…An unambiguous indicator that elevated CO 2 reduces insect growth rates by altering the chemical and physical properties of foliage is that insects consume more high-CO 2 foliage, an average of 14% more, to maintain lower growth rates. Increased consumption of low-quality food to meet critical nutrient limitations is referred to as "compensatory feeding" and may portend greater herbivore damage to both managed and natural ecosystems as CO 2 continues to increase (Cornelissen, 2011).…”

Section: Plants As Food: Co 2 and Temperature Effects On Leaf Chemistrymentioning

confidence: 99%

Climate Change: Resetting Plant-Insect Interactions

et al. 2012

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Elevated CO 2 and temperature are altering the interactions between plants and insects with important implications for food security and natural ecosystems. Ecologically, the acceleration of plant phenology by warming is generating mismatches between plants and insect pollinators. Similarly, shifting the rate of plant development relative to insect development can amplify or minimize the consequences of herbivory. Warming also enables some insects to increase the number of generations per year, thus increasing damage to plant communities. The suitability of plant tissues as food for insects also is modulated by global change. Elevated CO 2 typically increases the concentration of leaf carbohydrates and in combination with elevated temperature decreases nitrogen (N) content. Together, these changes lower nutritional value, causing certain herbivores to consume more foliage to meet their nutritional needs. Whereas the responses of primary metabolites in plants to global change are reasonably well understood, how elevated CO 2 and temperature affect plant defensive compounds (allelochemicals) is considerably less predictable. Recent studies indicate that exposure to elevated CO 2 suppresses the plant defense hormone jasmonic acid (JA) while stimulating production of salicylic acid (SA). By differentially affecting defense compounds, these changes in plant hormones potentially increase susceptibility to chewing insects and enhance resistance to pathogens. Exposure to elevated temperature, in contrast, stimulates JA, ethylene (ET), and SA, enhancing defenses. A deeper understanding of how elevated CO 2 and temperature, singly and in combination, modulate plant hormones promises to increase our understanding of how these elements of global change will affect the positive and negative interactions between plants and insects.Chemoautotrophs notwithstanding, plants provide energy in the form of carbohydrates for all nonphotosynthetic organisms, including insects. Not long after the colonization of land by plants 510 million years ago, plants and insects have engaged in an evolutionary arms race that continues today-plants evolve mechanisms to minimize consumption by insects, and insects evolve mechanisms to circumvent these defenses. Rapid changes in Earth's atmosphere initiated by the human use of fossil fuels is resetting this complex coevolutionary relationship, not only between plants and herbivores but also between plants and their mutualistic partners, including pollinators. Insects have the potential to cause enormous reductions in crop yields and the productivity of natural ecosystems, as well as to provide irreplaceable pollination services that underpin much of the world's agriculture.The combustion of fossil fuels during the Industrial Revolution initiated a rapid rise in atmospheric CO 2 concentration that is accelerating today; preindustrial levels were approximately 280 mL L 21 and below 300 mL L 21 for the previous 20 million years (Pearson and Palmer, 2000). Today's atmosphere is approximately 397 mL L 21...

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Section: Plants As Food: Co 2 and Temperature Effects On Leaf Chemistrymentioning

confidence: 99%

Climate Change: Resetting Plant-Insect Interactions

et al. 2012

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“…Insect herbivore which consumed plant lowered nutritional quality as food will cause a reduction in their performance, including by reducing their growth rates and prolonging their development time (Goverde and Erhardt, 2003). Indirectly, the mortality imposed by natural enemies increase (Stiling et al, 2003), finally reducing the abundance, diversity, and richness of herbivore if compared to ambient CO 2 environments (Cornelissen, 2011).…”

Section: Introductionmentioning

confidence: 99%

Co2 Effects on Larval Development and Genetics of Mealworm Beetle, Tenebrio Molitor L. (Coleoptera: Tenebrionidae) in Two Different Co2 Systems

Hasyimah

Atikah

Halim

et al. 2018

Appl. Ecol. Env. Res.

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Abstract. Tenebrio molitor has never been used as a model species for studying global warming effects. The objectives of this study were to measure the larval development and genetics of T. molitor under a free air CO 2 enrichment (FACE) system, open roof ventilation greenhouse system (ORVS) and a rearing room system (RR). The correlation coefficient analysis showed that the head width: body length was the best character to measure the development (0.465, 0.940 and 0.893) in all systems. Our results show that there were no significant changes in the larvae samples under RR condition, however, slight and moderate changes were observed under FACE and ORVS. Neighbour-joining analysis using cytochrome c oxidase subunit I sequence revealed the genetic data parallel with the results of the correlation coefficient. The FACE F1 progeny showed the slowest development (0.080±0.018 mm) during 0-14 days of larval development, while the most rapid before pupation occurred in the ORVS F1 (0.1205±0.0028 mm). No significant differences were noted between the systems for 0-14 days and before pupation, except for RR F1 vs ORVS F1 and ORVS F1 vs FACE F1 (p = 0.000, p = 0.002). These data can be used to clarify the changes in T. molitor due to global warming effects, as CO 2 could be one of the factors affecting the larval development.

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“…Species are affected directly, by physiological changes, and indirectly, by effects on interacting species [17]. Distribution ranges and synchrony of interacting partners can become mismatched so that the overlapping area and period are reduced, respectively [18,19].…”

Section: Introductionmentioning

confidence: 99%

“…Models predict increasing mismatches, spatially and temporally [20], which can result in the extinction of interacting species [21]. Insect species with narrow substrate preferences for egg laying are especially vulnerable [17]. Hence, knowledge of the preferred oviposition substrate is a crucial factor when predicting a species’ future under changed environmental conditions such as under climate warming.…”

Section: Introductionmentioning

confidence: 99%

Oviposition Substrate of the Mountain Fly Drosophila nigrosparsa (Diptera: Drosophilidae)

et al. 2016

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The survival of insect larvae often depends on the mother’s choice of oviposition substrate, and thus, this choice is an essential part of an insect species’ ecology. Especially species with narrow substrate preferences may suffer from changes in substrate availability triggered by, for example, climate change. Recent climate warming is affecting species directly (e.g., physiology) but also indirectly (e.g., biological interactions) leading to mismatching phenologies and distributions. However, the preferred oviposition substrate is still unknown for many drosophilid species, especially for those at higher elevations. In this study, we investigated the oviposition-substrate preference of the montane-alpine fly Drosophila nigrosparsa in rearing and multiple-choice experiments using natural substrates in the laboratory. Insect emergence from field-collected substrates was tested. More than 650 insects were reared from natural substrates, among them 152 drosophilids but no individual of D. nigrosparsa. In the multiple-choice experiments, D. nigrosparsa preferred ovipositing on mushrooms (> 93% of eggs); additionally, a few eggs were laid on berries but none on other substrates such as cow faeces, rotten plant material, and soil. The flies laid 24 times more eggs per day when mushrooms were included in the substrates than when they were excluded. We infer that D. nigrosparsa is a mushroom breeder with some variation in oviposition choice. The flies favoured some mushrooms over others, but they were not specialised on a single fungal taxon. Although it is unclear if and how climate change will affect D. nigrosparsa, our results indicate that this species will not be threatened by oviposition-substrate limitations in the near future because of the broad altitudinal distribution of the mushrooms considered here, even if the flies will have to shift upwards to withstand increasing temperatures.

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Climate change and its effects on terrestrial insects and herbivory patterns

Cited by 193 publications

References 51 publications

Climate Change: Resetting Plant-Insect Interactions

Climate Change: Resetting Plant-Insect Interactions

Co2 Effects on Larval Development and Genetics of Mealworm Beetle, Tenebrio Molitor L. (Coleoptera: Tenebrionidae) in Two Different Co2 Systems

Oviposition Substrate of the Mountain Fly Drosophila nigrosparsa (Diptera: Drosophilidae)

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