基于最大熵模型的新疆银盾革蜱和边缘革蜱生境适应性评价

doi:10.12140/j.issn.1000-7423.2022.01.010

摘要/Abstract

摘要：

目的对银盾革蜱和边缘革蜱的生境适应性进行评价,为银盾革蜱、边缘革蜱及其传播疾病的防控提供参考。方法从中国蜱的分布和多样性数据集中收集1980—2017年新疆维吾尔自治区（简称新疆）银盾革蜱和边缘革蜱的分布点,通过中国知网、百度学术、PubMed等数据库收集2017—2021年的分布点;在世界气象数据库中收集环境因子变量。以75%的数据作为训练子集,其余的25%作为模型评估测试集建立最大熵（MaxEnt）模型,通过MaxEnt模型的刀切法试验和R软件筛选主要的环境变量因子;利用MaxEnt物种预测分布模型和ArcGIS空间分析方法预测银盾革蜱和边缘革蜱的孳生环境分布情况;通过ArcMap 10.1绘制模型输出结果,根据MaxEnt模型绘制的生物气候变量响应曲线预测两种蜱的生态环境特性。结果分别筛选出银盾革蜱、边缘革蜱分布点数据46、64个;银盾革蜱、边缘革蜱模型评估测试集的受试者工作特性曲线下面积（AUC）值分别为 0.847、0.815;从19个环境变量因子中筛选出8个对银盾革蜱和边缘革蜱生存有影响的环境因子。适生区预测结果显示,银盾革蜱在新疆的适生区主要为准噶尔盆地、吐鲁番盆地以及塔里木盆地等,边缘革蜱主要为准噶尔山脉、天山山脉和昆仑山脉;银盾革蜱的非适生区、低度适生区、中度适生区和高度适生区的面积分别占新疆总面积的35.80%、29.18%、10.32%和24.70%,边缘革蜱分别占33.62%、17.01%、17.08%和32.28%。刀切法筛出最干月降水量（Bio14）、温度季节性变化（Bio4）、最湿季度平均温度（Bio8）为银盾革蜱分布的主要环境变量因子,最干季度降水量（Bio17）、年降水量（Bio12）、最湿季度降水量（Bio16）为边缘革蜱分布的主要环境变量因子。主要环境变量响应曲线显示,银盾革蜱在Bio14为21 mm、Bio4的变异系数为1 510、Bio8的为20 ℃时存在概率最大;边缘革蜱在Bio17为71 mm、Bio12为230 mm和Bio16在极值269 mm时存在概率最大。结论所构建的MaxEnt模型具有较高的预测精度和准确性,银盾革蜱在低海拔地区更适生,边缘革蜱在高海拔地区更适生;最干月份降水量是影响两种蜱的主要环境因子,温度为影响银盾革蜱的主要变量,降水量为影响边缘革蜱的主要变量。

关键词: 边缘革蜱, 银盾革蜱, 最大熵模型, 地理信息系统, 环境变量因子

Abstract:

Objective To evaluate the habitat adaptability of Dermacentor niveus and D. marginatus, and to provide reference for the prevention and control of the two tick species and their disease transmission. Methods The distribution sites of D. niveus and D. marginatus in Xinjiang from 1980 to 2017 were collected from the distribution and diversity data set of tick species in China, and the distribution sites of the two tick species in Xinjiang from 2017 to 2021 were collected through China National Knowledge Infrastructure (CNKI), Baidu Academic, PubMed and other databases. Environmental variables were downloaded from the World Meteorological Database. The maximum entropy (MaxEnt) model was established with 75% data records as training subset and the remaining 25% as model evaluation subset. The main environmental variables were screened using the “Jackknife” method of MaxEnt model and the R software. MaxEnt species distribution prediction model and ArcGIS spatial analysis method were used to predict the breeding environment distribution of D. niveus and D. marginatus. The model output was presented using ArcMap 10.1, and the characteristics of ecological environment of the two tick species were predicted according to the response curves of bioclimatic variables plotted by MaxEnt model. Results A total of 46 and 64 distribution sites of D. niveus and D. marginatus were found from the screening, respectively, the area under the receiver operating characteristic curve (AUC) values of the model assessment test subsets of D. niveus and D. marginatus were 0.847 and 0.815, respectively. From the 19 environmental variables, 8 environmental factors were screened out, which affect the survival of D. niveus and D. marginatus. The natural habitat prediction showed that the suitable habitats for D. niveus in Xinjiang were in the Junggar Basin, the Turpan Basin and the Tarim Basin; the suitable habitats for D. marginatus were in the Junggar Mountains, the Tianshan Mountains and the Kunlun Mountains. The areas of non-suitable habitat, low suitable habitat, moderate suitable habitat and high suitable habitat for D. niveus accounted for 35.80%, 29.18%, 10.32% and 24.70% of the total area of Xinjiang; while those for D. marginatus accounted for 33.62%, 17.01%, 17.08% and 32.28%, respectively. By the Jackknife method, the data screening found that precipitation of the driest month (Bio14), seasonal temperature change (Bio4), and mean temperature of the wettest quarter (Bio8) were the main environmental variable factor of D. niveus distribution, while the precipitation of the driest quarter (Bio17), annual precipitation (Bio12) and precipitation of wettest quarter (Bio16) were the main environmental variable factor of the distribution of D. marginatus. The response curve of main environmental variables showed that when the Bio14 was 21 mm, the coefficient of variation of Bio4 was 1 510, and Bio8 was 20 ℃, the existence probability of D. niveus was the highest; when Bio17 was 71 mm, Bio12 was 230 mm and Bio16 was 269 mm, the existence probability of D. marginatus was the highest. Conclusion MaxEnt model established exhibits high prediction precision and accuracy. It was demonstrated that low altitude area was the preferable habitat for D. niveus, whereas the high altitude area was the preferable habitat for D. marginatus. The precipitation in the driest month was the main environmental factor affecting the two tick species; the temperature was the primary environmental variable affecting D. niveus distribution, and precipitation was the primary environmental variable affecting D. marginatus distribution.

Key words: Dermacentor niveus, Dermacentor marginatus, Maximum entropy model, Geographic information system, Environmental factor variable

中图分类号:

R384.41

何文文, 伍军, 呼尔查, 阿力木江, 史倩云, 诺明达来, 甘露, 郝蕴伟, 巴音查汗. 基于最大熵模型的新疆银盾革蜱和边缘革蜱生境适应性评价[J]. 中国寄生虫学与寄生虫病杂志, 2022, 40(1): 68-75.

HE Wen-wen, WU Jun, HU Er-cha, A Li-mujiang, SHI Qian-yun, NUO Ming-dalai, GAN Lu, HAO Yun-wei, BAYIN Cha-han. Evaluation of habitat adaptability of Dermacentor niveus and Dermacentor marginatus in Xinjiang based on maximum entropy model[J]. Chinese Journal of Parasitology and Parasitic Diseases, 2022, 40(1): 68-75.

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环境因子变量 Variables	含义 Definition
Bio1	年均温 Annual mean temperature
Bio2	昼夜温差月均值 Mean diurnal range
Bio3	等温性 Isothermality
Bio4	温度季节性变化 Seasonal temperature change
Bio5	最暖月最高温度 Max temperature of the warmest month
Bio6	最冷月最低温度 Min temperature of the coldest month
Bio7	温度全年波动范围 Temperature annual range
Bio8	最湿季度平均温度 Mean temperature of the wettest quarter
Bio9	最干季度平均温度 Mean temperature of the driest quarter
Bio10	最暖季度平均温度 Mean temperature of the warmest quarter
Bio11	最冷季度平均温度 Mean temperature of the coldest quarter
Bio12	年降水量 Annual precipitation
Bio13	最湿月降水量 Precipitation of the wettest month
Bio14	最干月降水量 Precipitation of the driest month
Bio15	降水量变异系数 Variable coefficient of precipitation
Bio16	最湿季度降水量 Precipitation of the wettest quarter
Bio17	最干季度降水量 Precipitation of the driest quarter
Bio18	最暖季度降水量 Precipitation of the warmest quarter
Bio19	最冷季度降水量 Precipitation of the coldest quarter