根据蛋壳上的捕食者 DNA 确定鼠尾草巢的捕食者特异性死亡率

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Nolan A. Helmstetter, Courtney J. Conway, Shane Roberts, Jennifer R. Adams, Paul D. Makela, Lisette P. Waits
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引用次数: 0

摘要

大松鸡(以下简称大松鸡;Centrocercus urophasianus)种群数量在其分布范围内出现下降。人类活动造成的土地使用导致巢捕食的增加是导致种群数量下降的原因之一。然而,鼠尾草面临着多种多样的巢捕食者,它们的功能特征(如搜索策略或狩猎模式)和数量各不相同。因此,归纳影响巢命运的因素具有挑战性。因此,确定对巢穴捕食事件负有责任的捕食者物种对于了解土地利用与松鸡巢穴成功模式之间的因果机制至关重要。人们通常认为放牧会降低草的高度(进而降低草的覆盖度),从而有利于捕食者发现巢穴,从而对松鸡的繁殖产生不利影响。然而,最近的证据发现,在牧场范围内,放牧对筑巢命运的假定影响几乎没有得到支持。相反,在不同放牧强度的牧场上,筑巢成功率似乎相似。没有观察到影响的一个可能解释是一个或多个巢的捕食者的局部反应。牛群的存在可能会导致牧场内捕食者密度和/或使用量的暂时降低(牛群回避假说)。根据避牛假说的预测,在筑巢季节,有牲畜的牧场与没有牲畜的牧场相比,至少有一种鼠兔巢捕食者捕食鼠兔巢的概率会降低。为了验证避牛假说,我们从被捕食巢的蛋壳中收集了捕食者的 DNA,并使用遗传方法确定了造成捕食事件的鼠尾草巢捕食者。我们评估了栖息地和放牧对捕食者捕食巢的影响。我们通过在人工巢中安装跟踪摄像机来评估遗传方法的有效性,并将遗传方法的结果与跟踪摄像机捕捉到的物种进行比较。我们的分子方法在35个人工巢中的33个(94%)发现了至少一种通过踪迹照相机捕食人工巢的捕食者。通过分子分析,我们在 114 个被捕食的沙鸡巢中的 76 个(67%)发现了捕食者。在沙鸡巢发现的主要捕食者是郊狼(Canis latrans)和乌鸦(Corvidea)。放牧并不影响郊狼或鸦科鸟类捕食巢的概率。沙棘树冠覆盖率与郊狼捕食巢的概率呈负相关,与水的距离与鸦科鸟类捕食巢的概率呈正相关,平均最低气温与郊狼或鸦科鸟类捕食巢的概率呈负相关。我们的研究为实施一种有效的、非侵入性的方法来识别鼠兔巢中的捕食者提供了一个框架,这种方法可用于更好地了解地方和区域范围内的管理行动会如何影响鼠兔繁殖的一个重要组成部分。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Predator-specific mortality of sage-grouse nests based on predator DNA on eggshells

Predator-specific mortality of sage-grouse nests based on predator DNA on eggshells

Greater sage-grouse (hereafter sage-grouse; Centrocercus urophasianus) populations have declined across their range. Increased nest predation as a result of anthropogenic land use is one mechanism proposed to explain these declines. However, sage-grouse contend with a diverse suite of nest predators that vary in functional traits (e.g., search tactics or hunting mode) and abundance. Consequently, generalizing about factors influencing nest fate is challenging. Identifying the explicit predator species responsible for nest predation events is, therefore, critical to understanding causal mechanisms linking land use to patterns of sage-grouse nest success. Cattle grazing is often assumed to adversely affect sage-grouse recruitment by reducing grass height (and hence cover), thereby facilitating nest detection by predators. However, recent evidence found little support for the hypothesized effect of grazing on nest fate at the pasture scale. Rather, nest success appears to be similar on pastures grazed at varying intensities. One possible explanation for the lack of observed effect involves a localized response by one or more nest predators. The presence of cattle may cause a temporary reduction in predator density and/or use within a pasture (the cattle avoidance hypothesis). The cattle avoidance hypothesis predicts a decreased probability of at least one sage-grouse nest predator predating sage-grouse nests in pastures with livestock relative to pastures without livestock present during the nesting season. To test the cattle avoidance hypothesis, we collected predator DNA from eggshells from predated nests and used genetic methods to identify the sage-grouse nest predator(s) responsible for the predation event. We evaluated the influence of habitat and grazing on predator-specific nest predation. We evaluated the efficacy of our genetic method by deploying artificial nests with trail cameras and compared the results of our genetic method to the species captured via trail camera. Our molecular methods identified at least one nest predator captured predating artificial nests via trail camera for 33 of 35 (94%) artificial nests. We detected nest predators via our molecular analysis at 76 of 114 (67%) predated sage-grouse nests. The primary predators detected at sage-grouse nests were coyotes (Canis latrans) and corvids (Corvidea). Grazing did not influence the probability of nest predation by either coyotes or corvids. Sagebrush canopy cover was negatively associated with the probability a coyote predated a nest, distance to water was positively associated with the probability a corvid predated a nest, and average minimum temperature was negatively associated with the probability that either a coyote or a corvid predated a nest. Our study provides a framework for implementing an effective, non-invasive method for identifying sage-grouse nest predators that can be used to better understand how management actions at local and regional scales may impact an important component of sage-grouse recruitment.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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