限制食粪对东方田鼠食物消化和体重生长的影响

食粪行为是植食性小型哺乳动物为满足其营养需求所采取的一种适应对策。实验室条件下,限制1月龄和12月龄东方田鼠摄食粪便,测定了限制食粪对食物消化率和体重生长的影响,旨在进一步揭示食粪行为在植食性小型哺乳动物的营养及消化对策中的作用。结果表明,限制食粪使1月龄和12月龄东方田鼠的干物质消化率分别下降27.64 %和7.89 %,粗蛋白消化率分别下降21.39 %和12.68 %;限制食粪可显著抑制东方田鼠的体重增长,且限制食粪对幼体体重的影响较成体明显。因此,研究结果充分验证了限制食粪可降低东方田鼠的食物消化率及抑制其体重生长的假设。     

三种圈养草食性野生动物粪便对 粪食性金龟的引诱效果

圈养草食性野生动物产生的大量粪便堆积容易造成环境污染,且处理耗时耗力。如果能筛选、利用粪食性金龟对草食性野生动物粪便进行处理,无疑具有一定的应用价值。本研究于2019年8和9月,以南京红山森林动物园3种圈养草食性野生动物,亚洲象（Elephas maximus）、黇鹿（Dama dama）和长颈鹿（Giraffa camelopardalis）的新鲜粪便为诱饵,在南京紫金山研究了粪便对粪食性金龟的引诱效果。本实验分为2个阶段,第1阶段采用更换陷阱法,第2阶段采用放置陷阱法,采用单因素方差分析（One-way ANOVA）对粪食性金龟诱捕数量进行检验。第1阶段更换陷阱法共引诱采集粪食性金龟4 597头,隶属于1科5属7种,优势种为中华嗡蜣螂（Onthophagus sinicus）和短亮凯蜣螂（Caccobius brevis）,占总捕获量的比例分别为48.79%和30.95%。第2阶段放置陷阱法共引诱采集粪食性金龟3 512头,同样隶属于1科5属7种,物种与阶段1实验结果相同。粪食性金龟对3种野生动物粪便显示多食性特征,在3种粪便中取食活动的有效时间段主要集中在1 ~ 2 d内,活动时间较短,粪便放置第7天,基本不存在粪食性金龟的活动。粪食性金龟群落的Shannon-Wiener多样性指数和Pielou均匀度指数在亚洲象粪便中相对较高。本研究表明,动物园3种圈养草食性野生动物粪便对粪食性金龟具有较好的引诱效果,未来需进一步研究粪食性金龟对粪便的处理效果。     

动物分散贮食行为对植物种群更新的影响

分散贮食是许多动物取食行为策略的重要组成部分。对以植物种子为主要贮食对象的动物来说,种子内营养物质含量、种子大小以及种子内次生化合物的含量等因素都直接影响动物的贮食行为。动物偏爱贮藏个体较大的种子,大种子多被搬运并分散贮藏在远离种源的地方,而小种子则多被就地取食,以补充动物贮食过程中的能量消耗。贮食动物主要通过空间记忆、特殊路线以及贮藏点周围的直接线索等途径重新获取贮藏点内食物。在重取过程中,一些贮藏点被遗忘,其中的种子成为植物种群更新的潜在种子库。因此,分散贮食动物不仅是种子捕食者,还是种子传播者,它们对植物种子的捕食、搬运和贮藏,影响了植物种子的存活和幼苗的建成,从而在一定程度上影响植物种群的更新、分布。植物种群为了促进种子的传播,在进化过程中逐渐形成了形式多样的适应性策略,降低种子的直接被捕食率,提高种子的被贮藏率。研究动物分散贮食行为对植物种群更新的影响,将有助于理解贮食动物与植物之间的互惠关系,从而认识贮食动物种群在生态系统中的作用,为生物多样性的保护提供科学依据。     

贮食动物的盗食与反盗食行为策略

食物贮藏是许多动物应对食物短缺、保障其生存和繁衍的一种适应性行为。保护好贮藏食物以供食物短缺期利用,是食物贮藏成功的标志和进化动力。同种或异种动物盗食是贮藏食物损失的重要原因。嗅觉、视觉与空间记忆、随机搜寻等是动物搜寻和盗取食物的重要手段;避免盗食、阻止盗食和容忍盗食是动物反盗食的重要策略。动物通常采用多种行为策略进行盗食和反盗食,分配食物资源,形成相对稳定的种内、种间关系。盗食与反盗食互作及其对贮食行为进化的意义已成为行为生态学的研究热点和前沿之一,针对鸟类和哺乳类动物的研究尤为丰富。本文总结了贮食动物常见的盗食和反盗食行为策略及其相互作用的研究进展,主要内容涉及贮食动物利用嗅觉、视觉与空间记忆、随机搜寻等盗取其他个体食物的盗食策略,以及通过隐藏、转移、保卫、容忍等方式减少被盗食,保护贮藏食物的行为策略。针对现有研究状况,从种间盗食与反盗食及其与物种共存的关系,种间非对称盗食关系及其适应意义,盗食与反盗食最适行为策略及其与贮食动物适合度的关系等方面对今后研究提出了建议。     

啮齿动物的分散贮食行为

食物贮藏是许多动物重要的适应性行为,分散贮藏的食物以植物种子为主。每个贮藏点贮藏数量不等的食物项目。啮齿动物分散贮藏食物之后,可降低食物被其他个体获取的机率,提高对食物资源的控制能力,最终有利于自身的生存和繁殖成功。植物种子被贮藏之后,可减少非贮食鼠类对种子的取食。同时,合适的微生境和埋藏有利于种子萌发、幼苗建成和植物的更新;使植物的分布区得以扩展。探讨啮齿动物的分散贮食行为,能够更好地理解食物贮藏在啮齿动物生活史中的作用,进一步认识鼠类和植物的相互关系以及不同啮齿动物在群落形成中的潜在作用。本综述了啮齿动物分散贮食的研究进展,并提出今后工作中的几点建议。     

黄山短尾猴食土行为

从行为生态学角度,依据黄山短尾猴食土行为在年龄、性别、社会等级序位、食土量、食土频率、食土持续时间中的分布和变化规律,结合土壤基本理化性质测定和分析,探讨了黄山短尾猴食土行为。黄山短尾猴对土壤的摄取是寻找和有目的的选择,有些场所是其"喜好"或"常去之处",食土场所通常是以多个体多次取食挖掘而形成的洞穴形式存在。取食土壤颜色黄色或黄棕色,酸性土壤,富含铁、钙、镁等矿物元素,粘土比例较高。社群各年龄段及性别个体均参与食土行为。平均食土行为持续时间在年龄和性别之间无显著差异;平均食土频率和食土量在成年雌性或雄性个体的社会等级序位之间无显著性差异;而成年雌性的平均食土频率和食土量,显著高于其它年龄或性别组,与雌性正值怀孕末期及产仔哺乳期,需要补充大量铁等矿物元素,以维持生理所需和体力消耗有关。典型的植食性动物黄山短尾猴有规律地取食粘土的行为,支持了食土行为具有"食物解毒作用"假说。人工投喂和食土行为的相关性表现为提高了食土频率,可能与粘土能够缓解高热量、低纤维人工食物造成的胃肠不适有关。     

粪化石在古生态研究中的应用综述

粪化石(coprolite)是石化的动物粪便,而广义上粪化石(bromalite)是石化的动物消化物、排泄物和排出物的总称。作为一类重要遗迹化石,粪化石蕴含了大量实体化石难以提供的生物学信息,为古生态学研究提供以下依据:1)粪化石作为媒介帮助理解远古动物的行为习性、消化系统的结构和功能、食谱特征以及古生态系统食物链/食物网;2)粪化石中保存的古寄生虫线索能有效地解读古生物寄生关系和某些常见肠道寄生虫的起源问题;3)新生代以来古人类粪化石证据可以直接解开早期古人类的食谱、疾病特征及其迁移路径;4)中、新生代以来的粪化石中保存的植物残留信息(孢粉化石和植硅体)是重建古植被面貌、恢复古气候和探索早期动植物关系的重要依据。本文回顾了粪化石研究历史,并针对粪化石在上述古生态各研究方向的最新进展进行了系统总结和综述,认为粪化石可有效解读古生态。文章最后对粪化石的最新研究技术方法(如CT扫描技术)及未来发展方向进行了展望。     

南蝠对鸟的捕食及其对昆虫的选择

2005年11月和2006年5、7、9月在贵州兴义研究了南蝠(Iaio)的食性。通过对南蝠粪便分析,发现7、9和11月份,鸟的残留羽毛在粪便中占很大比例,尤其是在11月份,鸟的羽毛占了食物组成的82%(体积百分比,下同),结果证实南蝠是一种食鸟蝙蝠。但在5月份的粪便中未发现鸟毛,而鞘翅目所占比例很大(85%);7和9月份,鸟的羽毛和鞘翅目残遗物所占的比例相当(7月份分别为44.6%和48.7%;9月份分别为51.1%和43.4%)。5、7、9、11月份南蝠取食鸟类的比例逐渐增加,而对鞘翅目的取食则逐渐减少。除取食鞘翅目外,南蝠还捕食鳞翅目、半翅目、直翅目和膜翅目等昆虫。对比捕食区内潜在的食物,发现南蝠对部分昆虫表现出明显的选择性,说明南蝠为选择性捕食者。     

南蝠对鸟的捕食及其对昆虫的选择

2005年11月和2006年5、7、9月在贵州兴义研究了南蝠(Ia io)的食性。通过对南蝠粪便分析，发现7、9和11月份，鸟的残留羽毛在粪便中占很大比例，尤其是在11月份，鸟的羽毛占了食物组成的82%（体积百分比，下同），结果证实南蝠是一种食鸟蝙蝠。但在5月份的粪便中未发现鸟毛，而鞘翅目所占比例很大（85%）；7和9月份，鸟的羽毛和鞘翅目残遗物所占的比例相当（7月份分别为44.6%和48.7%；9月份分别为51.1%和43.4%）。5、7、9、11月份南蝠取食鸟类的比例逐渐增加，而对鞘翅目的取食则逐渐减少。除取食鞘翅目外，南蝠还捕食鳞翅目、半翅目、直翅目和膜翅目等昆虫。对比捕食区内潜在的食物，发现南蝠对部分昆虫表现出明显的选择性，说明南蝠为选择性捕食者。     

家养食草动物粪便中的花粉及菌孢子类型及其对人类活动的指示意义

考古遗址中动物粪化石中的微体植物遗存是重建过去生态环境以及人类活动的重要材料,然而对于能够指示人类活动的粪化石孢粉组合类型及其特征仍然缺乏清楚的认识。本文研究了山羊(Capra aegagrus)、绵羊(Ovis aries)、牛(Bos taurus)、骆驼(Camelus)、牦牛(Bos grunniens)和马(Equus caballus)等几种中国常见的家养食草类动物粪便中的主要孢粉和真菌孢子类型。通过分析这些动物粪便的花粉组合特征,探讨了花粉和菌孢子等微体植物遗存对生态环境及人类活动的指示意义。花粉种类丰度低、一些特征种属花粉(如禾本科、藜科)含量高是家养食草类动物粪便花粉组合的主要特征,可以用于指示人类的饲养行为。家养食草动物粪便中的粪生真菌孢子类型主要有Sporormiella,Sodaria,Pleospora,Coniochaeta,Thecaphora and Dictyosporium。研究表明真菌孢子的分布主要受到动物活动范围的影响,这使得利用粪生菌孢子(如Sporormiella)并结合其他记录来反映人类的饲养或游牧活动成为可能。     

Coprophagy in female mice during pregnancy and lactation

Coprophagy in female mice was observed predominantly in the reproductive stage. Female mice exhibited coprophagy more frequently during pregnancy and ingested larger amounts of feces during pregnancy and lactation than when they were not pregnant. Feces were found to be rich in vitamin B12 and folic acid. However, there were no marked fluctuations in the levels of either vitamin in the feces during pregnancy or lactation as compared with levels when animals were not pregnant. Acceleration of coprophagy during pregnancy and lactation seemed to correlate with the increased nutritional requirements of females during the reproductive stage.     

Cannibalism and Coprophagy Are Modes of Transmission of Blastocrithidia triatomae (Trypanosomatidae) between Triatomines

Transovarial transmission was not detectable among Blastocrithidia triatomae- infected Triatoma infestans . Rather, B. triatomae was transmitted directiy between triatomines by cannibalism and coprophagy. Cannibalism conditions that excluded coprophagy always resulted in an infection of Dipetalogaster maxima . The efficiency of transmission was not influenced by the blood source—mice or chickens—fed to the infected donor bugs although chicken blood lyses the epimastigotes of the stomach population. Triatoma infestans was infected by coprophagy only if fed, not if unfed. Blastocrithidia triatomae in dry feces was taken up only if the feces were redissolved in fresh feces. Infections also appeared in groups of bugs fed on chickens previously used for feeding infected bugs.     

The relationship between forage material and levels of coprophagy in captive chimpanzees (Pan troglodytes)

Although coprophagy is practiced in the wild by chimpanzees (Pan troglodytes), it occurs more frequently and under more varied circumstances in captivity. This study was designed to determine if different forage materials and amount of residual undigested grain particles found in the feces might cause an increase in coprophagous behavior in those animals which already exhibited the behavior. A possible effect of availability of seed pits and fibrous leaves for “wadge” making, a typical chimpanzee behavior, on levels of coprophagy was also considered. Observations for coprophagous behavior were conducted on 65 juvenile, adolescent, and adult chimpanzees. Coprophagy levels were significantly lower with popcorn than either chicken scratch or sweet feed. A significant increase in coprophagy was noted for all weeks of forage types when tested against the wadge weeks. Residual grain content analysis showed no significant difference in coprophagous behavior between any of the testing conditions. Decreasing levels of coprophagous behaviors may be assisted by the provision of wadge materials. © 1992 Wiley-Liss, Inc.     

Coprophagy in the germfree mouse

Coprophagy was observed in germfree (GF) ICR mice of both sexes, and the results were compared with those of conventional mice. Frequency of coprophagy per animal per day in GF mice was 5.1 in males and 5.8 in females. In conventional (CV) mice, the frequencies were 6.2 in males and 5.3 in females (data from Zoological Science 2:249-255, 1985), with no significant differences compared with GF mice. Coprophagy in CV mice was frequently observed during 6-8 hr after lighting, whereas such close time relationships tended to weaken in GF animals. In a comparison of levels of constituents per unit weight between feces and diet, fecal crude protein and crude fat exhibited lower values than those in the diet. Levels of fecal crude ash and crude fiber were higher than those in the diet, and nitrogen-free extract was almost equal to that in the diet. No essential difference in these tendencies was found compared with CV mice. Levels of fecal vitamin B1, B2, B12 and folic acid were lower than those in the diet. In CV mice, except for vitamin B1, these vitamins exhibited either almost equal or much higher levels compared with those in the diet (data from Experimental Animals 35: 381-386, 1986). From the fact that coprophagy was observed in GF mice, it is suggested that the behavior is inherent in the mouse.     

On the possible adaptive value of coprophagy in free-ranging chimpanzees

Coprophagy occurred during major periods of feeding on fruits of Dialium spp. (Caesalpiniaceae) in a group of orphaned chimpanzees released in Conkouati Douli National Park, Republic of Congo. Since stress, boredom or food scarcity could not explain coprophagy according to our daily behavioral and veterinary control observations, we suggest that Dialium seeds were the item of interest in the feces. Two types of Dialium seeds were commonly found in the feces after chimpanzees swallowed the mesocarp and whole seeds together. These seeds were either whole and hard or whole/broken and soft imbibed. A mechanical and/or chemical effect of the gut passage may enable the chimpanzees to chew and ingest the seeds, thus providing nutritional intake.     

Effects of coprophagy on serum urea and the weight of the gastrointestinal tract of fed or fasted rats

Coprophagy can be minimized by fitting rat cages with metal grids which allow faecal pellets to pass through to the floor of the cage. When bedding was omitted overnight, the extent of coprophagy could be estimated from the weight of the droppings on the cage floor or the weight of the gastrointestinal (GI) tract removed from rats housed with or without grids. The effect of coprophagy was also demonstrated by the elevation of serum urea nitrogen in rats that consumed faeces. Therefore, precautions against coprophagy, or their absence, should be specified in all experimental protocols and reports.     

Reingestion of feces in rodents and its daily rhythmicity

Summary The ingestion of feces is widespread among rodent species and is an extensively employed component of the repertoire of feeding behaviors in some species. Coprophagy is thus a significant consideration in the nutrition and dietary ecology of many rodents. As certain fecal pellets pass from the anus, they are taken up directly into the mouth, chewed, and swallowed. The nocturnally active herbivorous kangaroo rat Dipodomys microps ingests about 1/4 of the feces it produces daily and the daily pattern of reingestion shows a consistent rhythm. For about 8 h of the daytime, during the non-foraging, resting phase of the day, D. microps reingests all fecal pellets produced; during the remainder of the day it leaves all feces produced. The reingested feces contain more nitrogen and water, and less inorganic ions than the non-reingested feces. The extent of reingestion varies among rodent species in relation to diet, and coprophagy is more important in the more herbivorous species. The granivorous kangaroo rat D. merriami ingests feces rarely. The herbivorous vole Microtus californicus ingests about 1/4 of its feces, as does D. microps. However, in contrast to D. microps, M. californicus shows a series of rhythmic, short-term (one to several hour duration) alternations between reingestion and non-reingestion during the course of the day and night. This pattern correlates with the pattern of foraging in M. californicus, which extends over both night and day.     

Cannibalism and coprophagy are modes of transmission of Blastocrithidia triatomae (Trypanosomatidae) between triatomines

Transovarial transmission was not detectable among Blastocrithidia triatomae-infected Triatoma infestans. Rather, B. triatomae was transmitted directly between triatomines by cannibalism and coprophagy. Cannibalism conditions that excluded coprophagy always resulted in an infection of Dipetalogaster maxima. The efficiency of transmission was not influenced by the blood source--mice or chickens--fed to the infected donor bugs although chicken blood lyses the epimastigotes of the stomach population. Triatoma infestans was infected by coprophagy only if fed, not if unfed. Blastocrithidia triatomae in dry feces was taken up only if the feces were redissolved in fresh feces. Infections also appeared in groups of bugs fed on chickens previously used for feeding infected bugs.     

Behaviors and nutritional importance of coprophagy in captive adult and young nutrias (Myocastor coypus)

To estimate the contribution of coprophagy to protein intake, we observed the behavior, particularly that associated with coprophagy, in adult and young captive nutrias (experiment 1), and analyzed chemical composition and amino acid composition, including diaminopimeric acid (DAP), an indication of bacterial-deprived protein, of soft feces, entire hard feces, and the black part and green part of hard feces (experiment 2). Nutrias practiced coprophagy 48 times per 24 h in adults, and 28 times in young animals, which not only had a 24-h rhythm but also had 1-h or 2-h short-term rhythms. Nutrias ingested food and drank water vigorously after sunset, following which they practiced coprophagy from midnight to morning, before lying down for much of the day. When coprophagy was prevented we sampled soft feces, produced from midnight to noon, which had high (P < 0.05) concentration of crude protein (CP), DAP on a dry matter (DM) basis and 13 amino acids on a 16 g N basis than hard feces, and had a low (P < 0.05) content of acid detergent fiber (ADF). CP was greater in the black part than the green part of hard feces (P < 0.05) although ADF was less (P < 0.05). The chemical composition of the black part of hard feces was not significantly different from that of soft feces. The dry weight of soft feces excreted in experiment 1 was 34.5 g and 9.7 g DM per 24 h in adult and young animals, respectively. Using this value, the contribution of soft feces to CP intake in adult nutrias was estimated as 16%, superior to that obtained in rabbits for a diet with similar ADF concentration. To Met and Lys intake the contribution of soft feces was 26% and 19%, respectively in adult animals. These results suggest that coprophagy is quite an effective manner for nutrias to ingest extra protein. Accepted: 10 January 1991     

Analyses of constituents of feces and the effect of a vitamin B12 fortified diet on coprophagy in the mouse

In order to investigate coprophagy from the viewpoint of nutrition, fecal constituents were analyzed in freeze-dried samples. Feces were collected from 7:00 to 11:00 and from 19:00 to 23:00. Inorganic elements and crude fibers per unit weight were 3-4 times more concentrated in feces than in basal diet, whereas, crude proteins, crude fats and nitrogen-free extract showed various degrees of reduction. There were no differences in these tendencies with sampling time. As for some B vitamins, feces collected from 7:00 to 11:00 contained 22-92% more vitamins than feces collected from 19:00 to 23:00. In comparison with the dietary concentration, vitamin B12 was increased by 124-197 times (520-730 micrograms/100 g) in feces collected between 7:00 and 11:00. Folic acid in feces collected between 7:00 and 11:00 was 10 times greater than that in the diet. On the basis of the findings on vitamins, the effect of a vitamin B12 fortified diet (1,350 micrograms/100 g) on coprophagy was examined. Mean frequency of coprophagy per animal per day was 9.6 when animals were fed on the basal diet, whereas the frequency was immediately and significantly (p less than 0.05 approximately p less than 0.01) reduced to 4.7 after the diet had been replaced by the fortified one. However, coprophagy was not completely inhibited by vitamin B12 fortification. This indicates that some nutrient(s) in feces other than vitamin B12 might be of use to the host, and that otherwise, coprophagy might be a basically habitual form of behavior. Furthermore, under the fortified diet, the frequency of coprophagy increased gradually.(ABSTRACT TRUNCATED AT 250 WORDS)