种间竞争对同域分布田鼠种群动态的影响

我们对美国伊利诺斯州中东部的蓝草和高草牧场共生的橙腹田鼠(Microtus ochrogaster)和草原田鼠(Microtus pennsylvanicus)开放种群进行了去除实验,以测定潜在的种间竞争。在蓝草草原,橙腹田鼠和草原田鼠的种群密度不因另一种的存在而受抑制;同时,另一种存在的情况下,相互间对月存活率、青年鼠位置的持久性生殖或迁入鼠数量没有负面影响,尽管在高草草原,草原田鼠似乎对橙腹田鼠的种群密度有强烈影响,并限制了迁入鼠的数量,但是雌橙腹田鼠的存活率、青年鼠的持久性和生殖活动的比例不因草原田鼠的存在而受影响。总之,在此研究地点,种间竞争没有对橙腹田鼠和草原田鼠共存种群的动态起到驱动作用。     

田鼠种群波动的原因和时间

本文总结了橙腹田鼠（Microtus ochrogaster）和草原田鼠（M．permsylvanicus）25年的种群统计学研究结果和结论。探讨了田鼠种群波动周期性、诱发种群波动以及导致波动期间峰值变异的因素。并对种群存活值和繁殖活动的作用进行了分析和评价。根据两种田鼠种群波动周期性、波动峰值出现的时间以及特定年份峰值的高度等特征,证明两物种波动均具有不稳定性。两种田鼠存活值的变化是由特定年份是否发生波动以及波动峰值出现的时间决定。增加初始阶段的种群密度及时间长度是造成两种动物种群波动峰值不同的主要原因。橙腹田鼠种群停止增长的原因是存活值降低,而草原田鼠则是繁殖活动减少。据推测,与种群波动初始密度相关的种群死亡率的差异是由捕食者的净效应（Net effect）决定的,调控两种群密度的因素均为非密度的其它生态学因子。由于特定年份田鼠种群捕食压力的不确定性,导致了橙腹田鼠和草原田鼠种群波动的不稳定性。     

鼠类种群动态:食物资源影响力的实验评估

本研究在美国伊利诺斯州中东部测定了中等食物质量(莓系属的牧草)和低食物质量(高杆草牧场)栖息地内橙腹田鼠(Microtusochrogaster)和草原田鼠(M.pennsylvanicus)种群对附加食物的响应。在中等食物质量栖息地内投放附加食物,橙腹田鼠种群的波动幅度高于对照样地,但同类型食物质量栖息地内,种群平均密度和波动模式无显著的差异。仅在低等食物质量的高杆草栖息地内,投放附加食物可导致草原田鼠的种群密度高于对照样地。附加食物不直接影响两种栖息地内橙腹田鼠的成活率或成熟率,在中等食物质量栖息地中投放附加食物,繁殖活跃的成熟雌性个体比例及雄性成体的体重高于对照。附加食物不影响莓系属牧草内草原田鼠,也不能影响该动物在高杆草环境中的存活率。然而,投放附加食物,可缩短低等食物质量栖息地内草原田鼠的成熟期,提高繁殖活跃雌性的比例和迁入个体比例,增加并引起雄性个体体重增加。据此,本研究证明食物资源在橙腹田鼠和草原田鼠种群动态中只起极小的作用。     

局部环境增温对根田鼠冬季种群的影响

通过建立开顶式增温小室模拟全球变暖的实验, 对海北高寒草甸地区实验增温样地及其对照样地内根田鼠的冬季种群进行调查, 旨在研究局部增温对根田鼠冬季种群的可能影响。结果表明, 在冬季, 实验增温草甸样地和灌丛样地内根田鼠的种群密度均显著高于其对照( P < 0.05) ; 实验增温灌丛样地与对照间性比的差异不显著( P > 0.05) ; 增温样地和对照之间、不同植被类型的增温样地之间、对照样地之间, 根田鼠留存率、平均体重及年龄结构的差异均不显著( P > 0.05) ; 有从对照样地向增温样地单方向迁移的记录。总之, 局部环境增温导致实验样地内根田鼠的冬季种群密度明显上升, 而其性比、存活率、种群平均体重以及年龄结构无明显变化; 在冬季, 根田鼠有从对照样地向增温样地扩散或迁移的趋势。     

球虫感染与捕食对根田鼠繁殖性能的影响

在自然界,捕食者和寄生物是两种主要的种群外部调节因子,二者的交互作用会对猎物和宿主种群波动产生深远影响。较低的球虫感染强度与捕食对根田鼠（Alexandromys oeconomus）繁殖无显著的交互作用。自然界球虫感染存在季节性变化,秋季感染强度最高。为了探究较高感染强度下,球虫与捕食对根田鼠繁殖的主效应及交互作用,本研究采用2×2析因实验设计,在野外围栏中测定了根田鼠种群肠道内寄生物的感染率和感染强度、雄性睾丸指数、睾酮水平、精子密度、精子活力以及雌性卵巢指数。结果表明,较高的感染强度下,球虫能显著抑制根田鼠的繁殖性能,但球虫感染与捕食对根田鼠的繁殖无显著的交互作用,这可能与球虫感染和捕食效应在时间上的错配有关。本研究认为,球虫感染对繁殖期小哺乳动物种群的调节作用虽有限,但其可通过与捕食者的耦合来降低宿主越冬时的存活率,进而影响宿主种群波动。     

野外围栏条件下根田鼠肠道寄生物的感染率

寄生物是调节小哺乳动物种群波动的因子之一。许多生物和非生物因子可影响寄生物的感染。本研究以根田鼠为对象,在野外围栏条件下测定了根田鼠肠道寄生物种类及其感染率,并分析了根田鼠建群者数量、性别、年龄及时间对寄生物感染率的影响。结果表明,根田鼠肠道寄生物有球虫、线虫和绦虫,球虫是主要寄生物, Eimeria wenrichi 为球虫中的优势种;其感染率随根田鼠建群者数量增加而增加,且随时间而显著变化。在根田鼠幼体中,高密度处理组E. wenrichi 的感染率显著高于低密度处理组,而根田鼠幼体的E. ochrogasteri 感染率显著高于成体。本研究未发现根田鼠性别间的球虫感染率差异。上述结果说明,在根田鼠种群中,球虫感染率有时间变化,且受宿主密度的制约,高密度种群引起的生前应激与当前密度制约性感染可能对球虫感染率具有耦合效应。     

大型野外围栏实验揭示增食对布氏田鼠种群动态的复杂效应

尽管大多数实验都证明增加食物能提高动物的种群密度,但有关增食对动物的繁殖、存活和迁移的影响机制仍然存在争议.建立有效排除种群扩散和天敌捕食引起的复杂效应的野外大型围栏实验是目前解决这一争议必不可少的前提条件.2010~2014年,本课题组调查了增食处理对8个大型野外围栏(每个0.48 ha)内布氏田鼠(Lasiopodomys brandtii)种群动态和植物群落的影响.结果表明,增食通过增加幼体补充数量对种群密度产生正效应.然而,增食对布氏田鼠的存活产生复杂的效应:即在非繁殖季节产生正效应,在繁殖季节产生负效应.另外,增食提高了布氏田鼠植物食物的质量(蛋白质含量增加),但降低了围栏内植物群落中不喜食植物的数量.因此,增食通过增加食物的供给直接对小型啮齿类动物产生正效应.同时,食物引起的种群密度增加又通过密度制约效应间接对动物种群产生负效应,并且通过改变植物群落的结构和数量分布对啮齿动物产生长期的影响.     

小型啮齿动物种群系统调节复合因子理论的野外实验研究：食物可利用性和捕食对根田鼠种群空间行为的作用模式及其对种群调节的探讨

本项研究在野外围栏条件下,采用析因实验设计,测定食物可利用性和捕食对根田鼠（Ｍｉｃｒｏｔｕｓｏｅｃｏｎｏｍｕｓ）种群空间行为的作用模式。检验的特定假设为,高质量食物较大的可利用性能降低田鼠的攻击行为和活动;捕食能减少田鼠的活动。研究结果表明,食物可利用性能间接地和直接地影响根田鼠的空间行为。附加食物种群具有较高的密度和较小的巢区,且在诱捕期间具有较少的长距离活动和较低的攻击水平。捕食者的存在不直接影响攻击行为,但能影响诱捕期间的长距离活动,此为根田鼠对捕食者存在作出的直接反应。在阐明田鼠种群动态时,应仔细考虑上述因子相互作用的效应。     

小型啮齿动物种群系统调节复合因子理论的野外实验研究：食物可利用性和捕食对根田鼠种群动态作用的分析

本研究在野外围栏条件下采用析因实验设计,测定营养、捕食及空间行为对根田鼠（Ｍｉ－ｃｒｏｔｕｓｏｅｃｏｎｏｍｕｓ）种群统计特征的影响。本文旨在检验下述特定假设：高质量食物可利用性和捕食对限制小型啮齿动物种群密度具有独立的和累加的效应。３年期间,４种野外实验处理６个重复的研究结果表明,附加食物并预防捕食者处理的种群具有最高密度;未附加食物及不预防捕食者处理（对照）的种群密度最低;而单一处理的种群,其密度居中。不同处理条件下,新生个体在种群的补充模式以及种群瞬时增长率的变化均与种群密度的变动相应一致。双因素ＡＮＯＶＡ的结果证明,附加高质量食物能明显地提高根田鼠的种群密度,而对种群补充量的作用则较弱,仅接近显著水平;预防捕食者不仅能显著地作用于种群密度,更能强烈地影响种群补充量。高质量食物和捕食者的作用具有累加的性质,两者的交互作用对种群密度和补充量均无显著影响。     

雪后海北高寒草甸地区根田鼠种群特征的变化

根田鼠 (Ｍｉｃｒｏｔｕｓｏｅｃｏｎｏｍｕｓ)是一种分布广泛的小型哺乳动物[1 ] ,在海北高寒草甸地区 ,根田鼠是优势小型啮齿动物之一 ,主要分布于植被较好的草甸和灌丛中 ,有关其自然以及实验状态下种群数量动态的研究相对较多[2～6] ,但是对该地区冬季恶劣自然条件下 ,其种群动态的研究尚未见报道。研究冬季根田鼠种群特征的变化有助于对其整个生活史过程的全面理解 ,也便于了解冬季恶劣气候条件对其越冬留存率的影响进而又是如何影响翌年的种群数量。为此 ,作者于 2 0 0 0年 1 0月和 1 2月在海北高寒草甸生态系统定位站地区对根田鼠种…     

Changes in population structure and reproduction during a 3-yr population cycle of voles

Cyclic changes in population growth rate are caused by changes in survival and/or reproductive rate. To find out whether cyclic changes in reproduction are an important part of the mechanism causing cyclic fluctuations in small mammal populations, we studied changes in the population structure and reproduction of field voles ( Microtus agrestis ), sibling voles ( M. rossiaemeridionalis ), bank voles ( Clethrionomys glareolus ), and common shrews ( Sorex araneus ) in western Finland during 1984–1992, in an area with 3-yr vole cycles. We also modelled the population growth of voles using parameter values from this study. The animals studied were collected by snap trapping in April, May, June, August, September, and, during 1986–1990, also in October. We found several phase-related differences in the population structure (age structure, sex ratio, proportion of mature individuals) and reproduction (litter size, length of the breeding season) of voles. In non-cyclic common shrews, the only significant phase-related difference was a lower proportion of overwintered individuals in the increase phase. According to the analyses and the vole model, phase-related changes in litter size had only a minor impact on population growth rate. The same was true for winter breeding in the increase phase. The length and intensity of the summer breeding season had an effect on yearly population growth but this impact was relatively weak compared to the effect of cyclic changes in survival. The population increase rates of Microtus were delayed dependent on density (8–12-month time lag). Our results indicate that cyclic changes in reproduction are not an important part of the mechanism driving cyclic fluctuations in vole populations. Low survival of young individuals appeared to play an important role in the shift from the peak to the decline phase in late summer and early autumn.     

Do delayed effects of overgrazing explain population cycles in voles?

Theoretical models predict that delayed density-dependent processes with a time-lag of approximately nine months are sufficient to generate regular 3–5 year fluctuations in densities of northern small rodents. To examine whether this time-lag could be generated by plant-herbivore interactions, we studied delayed effects of overgrazed food plants on voles. We introduced field voles ( Microtus agrestis ) in four large predator-proof enclosures that had suffered heavy grazing during the preceding autumn and winter, and compared them with voles introduced to previously ungrazed control areas. We found no detrimental effects of previous grazing on population growth, reproduction or body condition of voles. Chemical analyses did not show consistent effects of grazing on nutritional components of common food plants (grasses). These results suggest that short-term population cycles of Microtus voles in grassland habitats are not primarily driven by delayed effects of plant-herbivore interactions.     

Five-year population dynamics of plateau pikas (<Emphasis Type="Italic">Ochotona curzoniae</Emphasis>) on the east of Tibetan Plateau

Small mammals mediate trajectories of vegetation change where both their density and the growing season are moderated by temperature and precipitation. On the Tibetan Plateau, the cold and arid climate particularly restricts the plant growing season, but the role of mammals’ density and climate in moderating small mammal populations remains unknown. We conducted a 5-year mark-recapture study of plateau pikas (Ochotona curzoniae) to test the relative importance of density-dependent and climatic factors on survival and reproduction. Plateau pikas had seasonal fluctuations in density and survival. During the warm summer season (May–August), monthly survival was density-independent, ranging from 74.7 to 90.4%, but varied with sex and age, increased with precipitation and NDVI, and decreased with temperature. During the cold season (September–April), monthly survival was around 98%. Density and precipitation had negative effects on reproductive success for the first and second litters of the year, and temperature showed consistently positive effects on reproductive success for both litters of the year. Pika density and climate regulated together the population dynamics of plateau pikas. These data on the relationships between density and climatic factors on survival and reproduction are critical for the management and conservation of plateau pikas on the Tibetan Plateau.     

Simulating density-dependent relationships in south Texas northern bobwhite populations

Density dependence influences northern bobwhite (Colinus virginianus) reproduction and overwinter mortality. However, the functional forms of these density-dependent relationships or the factors that influence them during the annual life cycle events of this bird are not clear. We used a systems analysis approach with a compartment model based on difference equations (Δt = 3 months) for bobwhites in South Texas to simulate population behavior using 16 different functional forms of density-dependent production and overwinter mortality. During the reproductive season, a weak linear density-dependent relationship resulted in the longest population persistence (up to 100.0 yr), whereas a reverse-sigmoid density-dependent relationship had the worst population persistence (2.5–3.5 yr). Regarding overwinter mortality, a sigmoid or weak linear density-dependent relationship and a weak linear or no density-dependent reproduction relationship had the longest population persistence (87.5–100.0 yr). Weak linear density-dependent reproduction with either sigmoid or weak linear overwinter mortality produced stable fall population trends. Our results indicated that density dependence may have a greater influence on overwinter survival of bobwhites than previously thought. Inclusion of density-dependent functional relationships that represent both density-dependent reproduction and overwinter mortality, were critical for our simulation model to function properly. Therefore, integrating density-dependent relationships for both reproductive and overwinter periods of the annual cycle of bobwhite life history events is essential for conducting realistic bobwhite population simulation analyses that can be used to test different management scenarios in an integrated and interdisciplinary manner. © 2012 The Wildlife Society.     

Large manipulative experiments reveal complex effects of food supplementation on population dynamics of Brandt's voles

Although food supplementation is well known to increase population density,there is still debate on the causative effects of food supplementation on reproduction,survival,and immigration.Large manipulative experiments,which exclude any confounding effects of dispersal and predation,are essential for clarifying the debate.In this study,we investigated the effects of food supplementation on Brandt's vole population dynamics and plant community in eight large enclosures(0.48 ha each) from2010 to 2014.Food supplementation showed significant positive effects on population density due to increases in recruitment;however,it showed a complex effect on survival of voles:positive in non-breeding seasons,but negative in breeding seasons.In addition,food supplementation increased the quality of plants(as reflected by increased crude protein content),but decreased the quantity of less preferred plants in experimental enclosures.Thus,food seems to have direct positive effects on small rodents through improvement of food supply and indirect negative effects through food-induced density-dependent effects,and may have long-term effects on rodents through altering plant community composition and abundance.     

Cyclic voles and shrews and non-cyclic mice in a marginal grassland within European temperate forest

Cyclic population dynamics of small mammals are not restricted to the boreal and arctic zones of Eurasia and North America, but long-term data series from lower latitudes are still less common. We demonstrated here the presence of periodic oscillations in small mammal populations in eastern Poland using 22-year (1986–2007) trapping data from marginal meadow and river valley grasslands located in the extensive temperate woodland of Białowieża Primeval Forest. The two most common species inhabiting meadows and river valleys, root vole Microtus oeconomus and common shrew Sorex araneus, exhibited synchronous periodic changes, characterised by a 3-year time lag as indicated by an autocorrelation function. Moreover, the cycles of these two species were synchronous within both habitats. Population dynamics of the striped field mouse Apodemus agrarius was not cyclic. However, this species regularly reached maximum density 1 year before the synchronized peak of root voles and common shrews, which may suggest the existence of interspecific competition. Dynamics of all three species was dominated by direct density-dependent process, whereas delayed density dependent feedback was significant only in the root vole and common shrew. Climatic factors acting in winter and spring (affecting mainly survival and initial reproduction rates) were more important than those acting in summer and autumn and affected significantly only the common shrew. High temperatures in winter and spring had positive effects on autumn-to-autumn changes in abundance of this species, whereas deep snow in combination with high rainfall in spring negatively affected population increase rates in common shrew.     

Influence of Density and Climate on Population Dynamics of a Large Herbivore Under Harsh Environmental Conditions

ABSTRACT Dynamics of herbivore populations can be influenced both by density-dependent processes and climate. We used age-at-harvest data for adult female white-tailed deer (Odocoileus virginianus) collected over 23 years to estimate survival and reproduction by age class and to identify effects of environmental factors. The study population was located on Anticosti Island (QC, Canada), at the northern limit of the species' range; the population was at high density, and the landscape had scarce forage and abundant snow during winter. Despite severe environmental conditions, population growth apparently increased during the study; adult survival was similar to other populations, although reproduction appeared lower. Winter severity was not related to survival, but density affected adult female survival. Density at estrus was the main factor influencing reproduction of 2- and 3–4-year-olds and also affected reproduction of prime-aged females (5–9-yr-olds), but not of older females. Reproductive rate of younger females was influenced by environmental conditions in autumn, such as high density or snow conditions that limited forage availability. Reproductive success of 5–9- and ≥10-year-old females appeared dependent on spring conditions favoring high-quality forage, probably through effects on neonatal survival. Relative to other studies on northern ungulates, demographic processes in our study appeared to be more affected by autumn and spring climate, in addition to population density, than by winter climate. We thus propose that population density, as well as autumn and spring climate, should be considered in management strategies. Harvest data offered a unique opportunity to study forest ungulates, for which individual monitoring is rarely possible.     

Population fluctuations and regulation in great snipe: a time-series analysis

1. During the last centuries, the breeding range of the great snipe Gallinago media has declined dramatically in the western part of its distribution. To examine present population dynamics in the Scandinavian mountains, we collected and analysed a 19-year time series of counts of great snipe males at leks in central Norway, 1987-2005. 2. The population showed large annual fluctuations in the number of males displaying at lek sites (range 45-90 males at the peak of the mating season), but no overall trend. 3. We detected presence of direct density-dependent mechanisms regulating this population. Inclusion of the density-dependent term in a Ricker-type model significantly improved the fit with observed data (evaluated with Parametric Bootstrap Likelihood Ratio tests and Akaike's Information Criterion for small sample size). 4. An analysis of (a number of a priori likely) environmental covariates suggests that the population dynamics were affected by conditions influencing reproduction and survival of offspring during the summer, but not by conditions influencing survival at the wintering grounds in Africa. This is in contrast to many altricial birds breeding in the northern hemisphere, and supports the idea that population dynamics of migratory nidifugous birds are more influenced by conditions during reproduction. 5. Inclusion of these external factors into our model improved the detectability of density dependence. This illustrates that allowing for external effects may increase statistical power of density dependence tests and thus be of particular importance in relatively short time series. 6. In our best model of the population dynamics, two likely density-independent offspring survival covariates explained 47.3% of the variance in great snipe numbers (predation pressure estimated by willow grouse reproductive success and food availability estimated by the amount of precipitation in June), whereas density dependence explained 35.5%. Demographic stochasticity and unidentified environmental stochasticity may account for the remaining 17.2%.