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Plant pathogens, insect pests and weeds in a changing global climate: a review of approaches, challenges, research gaps, key studies and concepts

JUROSZEK, P. ; von TIEDEMANN, A.

Cambridge University Press (CUP) ; 2013

In: The Journal of Agricultural Science Vol. 151, No. 2 ( 2013-04), p. 163-188

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In: The Journal of Agricultural Science, Cambridge University Press (CUP), Vol. 151, No. 2 ( 2013-04), p. 163-188

Abstract: Climate change biology is witnessing a significant quantity of new publications each year, which compromises efforts to keep up-to-date on the rapidly growing body of climate change biology literature. The present paper provides an overview on research approaches and challenges in climate change biology with respect to plant pathogens, insect pests and weeds (collectively termed ‘pests’ here). It also summarizes the suggestions of researchers about how to conceptualize and prioritize future research strategies. Recently published key studies demonstrate that climate change research is qualitatively advancing and that the interactions among environmental and biotic factors which have been found are complex. This complexity hinders attempts to generalize responses of pests to changes in climate. The challenge remains to identify the most significant causal relationships and to separate them from other factors such as crop management practices, which may also influence the observed changes in pest distribution and prevalence in managed ecosystems. In addition, the present overview shows that there are still gaps in many research areas, while other fields have been intensively investigated. For example, the identification of potential benefits in plant protection that may emerge from future climate change has not been explored as extensively as the potential threats. However, encouraging developments can be observed in recent climate change research, for instance the increased number of studies performed under subtropical and tropical climatic conditions, the increased availability of results from multi-factorial field experiments and modelling studies do consider increasingly pest–crop–climate interactions. Further progress can be expected, provided that researchers, sponsors and other stakeholders maintain their interest in climate change biology research.

Type of Medium: Online Resource

ISSN: 0021-8596 , 1469-5146

URL: Article

DOI: 10.1017/S0021859612000500

Language: English

Publisher: Cambridge University Press (CUP)

Publication Date: 2013

detail.hit.zdb_id: 1498349-7

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Effects of elevated CO 2 and temperature on seed quality

HAMPTON, J. G. ; BOELT, B. ; ROLSTON, M. P. ; [et al.]

Cambridge University Press (CUP) ; 2013

In: The Journal of Agricultural Science Vol. 151, No. 2 ( 2013-04), p. 154-162

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In: The Journal of Agricultural Science, Cambridge University Press (CUP), Vol. 151, No. 2 ( 2013-04), p. 154-162

Abstract: Successful crop production depends initially on the availability of high-quality seed. By 2050 global climate change will have influenced crop yields, but will these changes affect seed quality? The present review examines the effects of elevated carbon dioxide (CO 2 ) and temperature during seed production on three seed quality components: seed mass, germination and seed vigour. In response to elevated CO 2 , seed mass has been reported to both increase and decrease in C 3 plants, but not change in C 4 plants. Increases are greater in legumes than non-legumes, and there is considerable variation among species. Seed mass increases may result in a decrease of seed nitrogen (N) concentration in non-legumes. Increasing temperature may decrease seed mass because of an accelerated growth rate and reduced seed filling duration, but lower seed mass does not necessarily reduce seed germination or vigour. Like seed mass, reported seed germination responses to elevated CO 2 have been variable. The reported changes in seed C/N ratio can decrease seed protein content which may eventually lead to reduced viability. Conversely, increased ethylene production may stimulate germination in some species. High-temperature stress before developing seeds reach physiological maturity (PM) can reduce germination by inhibiting the ability of the plant to supply the assimilates necessary to synthesize the storage compounds required for germination. Nothing is known concerning the effects of elevated CO 2 on seed vigour. However, seed vigour can be reduced by high-temperature stress both before and after PM. High temperatures induce or increase the physiological deterioration of seeds. Limited evidence suggests that only short periods of high-temperature stress at critical seed development stages are required to reduce seed vigour, but further research is required. The predicted environmental changes will lead to losses of seed quality, particularly for seed vigour and possibly germination. The seed industry will need to consider management changes to minimize the risk of this occurring.

Type of Medium: Online Resource

ISSN: 0021-8596 , 1469-5146

URL: Article

DOI: 10.1017/S0021859612000263

Language: English

Publisher: Cambridge University Press (CUP)

Publication Date: 2013

detail.hit.zdb_id: 1498349-7

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