Would future climate warming cause zoonotic diseases to spread over long distances?

is a major rodent found in arid environments and desert areas. They feed on plant seeds, young branches and some small insects, and have hibernating habits. Peak numbers impact the construction of the plant community in the environment, but also have a human impact as these rodents carry a variety o...

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Published in:PeerJ (San Francisco, CA) CA), 2024-02, Vol.12, p.e16811-e16811, Article e16811
Main Authors: Bu, Fan, Yue, Xiuxian, Sun, Shanshan, Jin, Yongling, Li, Linlin, Li, Xin, Zhang, Rong, Shang, Zhenghaoni, Yan, Haiwen, Zhang, Haoting, Yuan, Shuai, Wu, Xiaodong, Fu, Heping
Format: Article
Language:English
Subjects:
Animals
Arid environments
Biodiversity
Climate Change
Climatic changes
Deserts
Dipus sagitta
Disease transmission
Ecosystem
Feed industry
Fleas
Geographical distribution
Habitats
Hazard dispersal
Holocene
Human impact
Humans
International economic relations
Plant communities
Population control
Population distribution
Potential distribution area
Predation
Rodentia
Rodents
Seeds
Software
Temperature
Trends
Zoonoses
Zoonoses - epidemiology
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Summary:is a major rodent found in arid environments and desert areas. They feed on plant seeds, young branches and some small insects, and have hibernating habits. Peak numbers impact the construction of the plant community in the environment, but also have a human impact as these rodents carry a variety of parasitic fleas capable of spreading serious diseases to humans. Based on 216 present distribution records of and seven environmental variables, this article simulates the potential distribution of during the Last Glacial Maximum, the mid-Holocene, the present and the future (2070s, RCP4.5, RCP8.5). This study also analyzes the geographic changes of the population distribution and evaluates the importance of climate factors by integrating contribution rate, replacement importance value and the jackknife test using the MaxEnt model. In this study, we opted to assess the predictive capabilities of our model using the receiver operating characteristic (ROC) and partial receiver operating characteristic (pROC) metrics. The findings indicate that the AUC value exceeds 0.9 and the AUC ratio is greater than 1, indicating superior predictive performance by the model. The results showed that the main climatic factors affecting the distribution of the three-toed jerboa were precipitation in the coldest quarter, temperature seasonality (standard deviation), and mean annual temperature. Under the two warming scenarios of the mid-Holocene and the future, there were differences in the changes in the distribution area of the three-toed jerboa. During the mid-Holocene, the suitable distribution area of the three-toed jerboa expanded, with a 93.91% increase in the rate of change compared to the Last Glacial Maximum. The size of the three-toed jerboa's habitat decreases under both future climate scenarios. Compared to the current period, under the RCP4.5 emission scenario, the change rate is -2.96%, and under the RCP8.5 emission scenario, the change rate is -7.41%. This indicates a trend of contraction in the south and expansion in the north. It is important to assess changes in the geographic population of due to climate change to formulate population control strategies of these harmful rodents and to prevent and control the long-distance transmission of zoonotic diseases.
ISSN:2167-8359
2167-8359
DOI:10.7717/peerj.16811