Exploring the Relationships between South Texas Northern Bobwhite Populations and Cecal Worms via System Dynamics

National Quail Symposium Proceedings Pub Date : 1900-01-01 DOI:10.7290/nqsp0910tz

N. Traub, B. Turner, L. Brennan, A. Fedynich

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Abstract

Community ecology historically focused on plants and free-living organisms; however, problems such as defining habitat boundaries and obtaining adequate sample sizes arise when evaluating such communities. The unique nature of host-helminth systems allows parasite community ecologists to avoid these problems when testing ecological hypotheses. Unlike free-living communities that have artificially constructed boundaries, parasite communities have well-defined unambiguous boundaries within host individuals. Due to the inherently complex and dynamic nature of ecological systems, traditional experimental methods often require expensive, long-term trials beyond investigators’ time and resource budgets. Conversely, a system dynamics approach facilitates learning about such systems via simulation of ecosystem processes integrated with historical data (both quantitative and qualitative). Relatively few studies focus on parasites in South Texas, USA, although research on avian host-parasite systems has shown that parasites can potentially regulate host populations. The northern bobwhite (Colinus virginianus; hereafter, bobwhite) is a game species of ecological, economic, cultural, and recreational importance in Texas that has been experiencing a long-term, widespread decline. To holistically examine the bobwhite-helminth system in South Texas, we created a system dynamics model capturing the feedback relationships between a South Texas bobwhite population, a grasshopper (family Acrididae) population, and the corresponding cecal worm (Aulonocephalus pennula) populations on a hypothetical 1,000-acre ranch in South Texas. The model structure, constructed in Vensim® PLE 7.2 software (Ventana Systems, Inc.), integrates the hypothesized biotic and abiotic drivers (precipitation, parasite load, insect abundance, and quail density) unique to the host-helminth system over 7 years (2012–2019). Our specific objectives were to 1) develop a working baseline model to replicate the synergistic population dynamics among bobwhite, grasshopper, and cecal worm populations and then 2) test hypotheses about each population’s boom-and-bust cycles resulting from environmental stressors (e.g., drought). Applications of the model can provide landowners and natural resource managers with a better understanding of the complex dynamics occurring among bobwhite, grasshopper, and cecal worm populations in South Texas. Citation: Traub, N. J., B. L. Turner, L. A. Brennan, and A. M. Fedynich. 2022. Exploring the relationships between South Texas northern bobwhite populations and cecal worms via system dynamics. National Quail Symposium Proceedings 9:193. https:// doi.org/10.7290/nqsp0910TZ

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通过系统动力学探索南德克萨斯北部山齿鹑种群与盲肠蠕虫之间的关系

群落生态学历来关注植物和自由生物;然而，在评价这些群落时，出现了诸如确定生境边界和获得足够的样本量等问题。寄主-蠕虫系统的独特性质允许寄生虫群落生态学家在测试生态学假设时避免这些问题。与人为构建边界的自由生活群落不同，寄生虫群落在宿主个体内部有明确明确的边界。由于生态系统固有的复杂性和动态性，传统的实验方法往往需要昂贵的、长期的试验，超出了研究人员的时间和资源预算。相反，系统动力学方法通过与历史数据(定量和定性)相结合的生态系统过程模拟，促进了对这些系统的学习。尽管对鸟类宿主-寄生虫系统的研究表明，寄生虫可以潜在地调节宿主种群，但对美国南德克萨斯州寄生虫的研究相对较少。北山齿鹑(Colinus virginianus;(以下简称山齿鹑)是一种具有生态、经济、文化和娱乐重要性的狩猎物种，在德克萨斯州经历了长期的、广泛的衰退。为了全面考察南德克萨斯州的山齿鹑-蠕虫系统，我们创建了一个系统动力学模型，捕捉了南德克萨斯州山齿鹑种群、蚱蜢(family Acrididae)种群和相应的盲肠蠕虫(Aulonocephalus pennula)种群之间的反馈关系。该模型结构在Vensim®PLE 7.2软件(Ventana Systems, Inc.)中构建，集成了7年来(2012-2019)宿主-蠕虫系统特有的假设生物和非生物驱动因素(降水、寄生虫负荷、昆虫丰度和鹌鹑密度)。我们的具体目标是:1)建立一个工作基线模型，以复制山齿鹑、蚱蜢和盲肠虫种群之间的协同种群动态;2)测试由环境压力因素(如干旱)导致的每种种群的繁荣与萧条周期的假设。该模型的应用可以让土地所有者和自然资源管理者更好地了解南德克萨斯州山齿鹑、蚱蜢和盲肠蠕虫种群之间的复杂动态。出处:Traub, n.j.， B. L. Turner, L. A. Brennan和A. M. Fedynich, 2022。通过系统动力学探索南德克萨斯北部山齿鹑种群与盲肠蠕虫之间的关系。全国鹌鹑研讨会论文集9:193。https:// doi.org/10.7290/nqsp0910TZ

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