Plague and climate: scales matter - PubMed (original) (raw)

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Plague and climate: scales matter

Tamara Ben-Ari et al. PLoS Pathog. 2011 Sep.

Erratum in

• PLoS Pathog. 2012 May;8(5): doi/10.1371/annotation/84f83f75-2e53-48cf-9f43-7e5eaed74437. Ben Ari, Tamara [corrected to Ben-Ari, Tamara]

Abstract

Plague is enzootic in wildlife populations of small mammals in central and eastern Asia, Africa, South and North America, and has been recognized recently as a reemerging threat to humans. Its causative agent Yersinia pestis relies on wild rodent hosts and flea vectors for its maintenance in nature. Climate influences all three components (i.e., bacteria, vectors, and hosts) of the plague system and is a likely factor to explain some of plague's variability from small and regional to large scales. Here, we review effects of climate variables on plague hosts and vectors from individual or population scales to studies on the whole plague system at a large scale. Upscaled versions of small-scale processes are often invoked to explain plague variability in time and space at larger scales, presumably because similar scale-independent mechanisms underlie these relationships. This linearity assumption is discussed in the light of recent research that suggests some of its limitations.

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Conflict of interest statement

The authors have declared that no competing interests exist.

Figures

Figure 1. Schematic of the plague cycle with small mammals as hosts and fleas as vectors.

Arrows represent connections affected by climate with a color-coding depending on the most influential climate variable on this link (i.e., precipitation, temperatures, and other variables indirectly depending on them such as soil characteristics and soil moisture). Grey rectangles somewhat arbitrarily delimit epizootic, enzootic, and zoonotic cycles. Note that despite their location at the far end of the cycle, humans often provide the only available information on plague dynamics.

Figure 2. Illustration of the abiotic environment impact on the plague cycle as a function of spatial scale.

Arrows represent connections affected by climate (see Figure 1 for the meaning of color coding). Most climate variables act over a wide range of scales and only the effects we deemed most important are represented. At the level of individuals, populations and communities hosts and vectors are influenced by climate variability at the relevant scale (local or regional). At the smaller scale, the burrow acts as a filter on climate variables. Note that secondary hosts are placed at the kilometer and larger scale on the basis of the type of information generally available regarding their infection.

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