小熊猫繁殖周期血清雌二醇和孕酮含量变化

为研究小熊猫繁殖周期血清雌二醇、孕酮含量变化规律,采用化学发光免疫分析法连续16 次测定了2只成体雌性小熊猫血清雌二醇和孕酮含量变化,历经发情间期、发情期和两次妊娠期;连续9次测定了7只小熊猫妊娠期的孕酮含量变化。结果:(1)发情间期,小熊猫血清雌二醇的水平一直维持在低水平(基础水平),进入发情前期,血清雌二醇水平明显升高,在发情期一直维持高水平,配种后迅速降至基础水平; (2)小熊猫血清孕酮含量在发情间期和发情期均维持在较低水平,直至发情期过后才出现升高,在妊娠期一直维持高水平,峰值出现在5 月;(3)发情的小熊猫不论妊娠与否,在妊娠期内血清孕酮含量均维持在高水平。研究表明:小熊猫血清雌二醇、孕酮含量变化能直接反映其繁殖规律,雌二醇对启动雌性小熊猫季节性繁殖起重要作用;在妊娠期内小熊猫血清孕酮含量升高不能作为判断小熊猫妊娠的标准;雌性小熊猫在妊娠期有假孕现象。     

动物园里小熊猫的饲养与繁殖

小熊猫(Ailurus fulgens)是我国的珍贵动物之一。动物园倒养中不易繁殖。我园1973年引进小熊猫一对(下面分别用♀、♂表示)。1974年7月开始繁殖。五年来繁殖9胎,成活8只,其中第二代繁殖获得成功。经饲养与观     

成体雌性小熊猫卵巢组织学观察

2000 年至2009 年,12 只固定于10% 福尔马林中非生殖系统疾病死亡的小熊猫卵巢组织,按常规组织学技术制作组织切片,HE 染色,光学显微镜观察。结果:(1)不同发情时期卵巢均有原始卵泡、初级卵泡和次级卵泡分布。发情期的卵巢未观察到典型的成熟卵泡和卵母细胞; (2)原始卵泡数量较少,初级卵泡数量较多,多数初级卵泡和大多数的次级卵泡都处在闭锁状态;(3)卵泡腔出现之前,卵母细胞的直径和卵泡直径同时增长;卵泡腔出现之后,卵母细胞直径增长较慢,卵泡直径增长较快; (4)不同发情时期的小熊猫卵巢均存在大量的间质腺细胞;(5)妊娠小熊猫和发情间期无妊娠小熊猫的卵巢均有发育正常的黄体;(6)卵泡细胞发育呈低柱状至柱状时出现透明带。结论:(1) 卵泡闭锁主要发生在初级卵泡阶段,仅少数卵泡能发育至次级卵泡;(2)卵母细胞和卵泡生长呈双相生长的趋势; (3) 不同发情时期的小熊猫卵巢间质腺都发达; (4)发情排卵后,非妊娠黄体与妊娠黄体维持的时间相似,证实了小熊猫存在假孕现象。     

雌性小熊猫粪样中雌二醇与孕酮水平的变化与繁殖启动的关系

于1999年12月-2000年4月在成都动物园和成都大熊猫繁育研究基地,用放射免疫分析法测定了4只雌性小熊猫（Ailurus fulgens)粪样中雌二醇(E2)和孕酮(P)水平的变化,同时对其交配行为进行了观察。研究结果表明：雌性小熊猫进入发情期后,粪样中E2迅速升高,并多次出现峰值,表明小熊猫可能是季节性多发情动物。交配行为发生前E2出现峰值,P水平上升,说明E2和P是启动雌性小熊猫交配行为的重要因素;未伴随有P水平相对上升的E2峰值不能引起雌性小熊猫发生交配行为,该现象为暗发情。交配行为发生后P水平持续升高,据此推断小熊猫的排卵方式可能是诱导排卵,诱导因子是交配刺激。     

小熊猫的饲养管理

小熊猫 (Ａｉｌｕｒｒｕｓｆｕｌｇｅｎｓ)在动物园的饲养最早是 1 869在年英国伦敦动物园开始的。到 2 0世纪 70年代 ,世界上已有 50 0多家动物园饲养繁殖过小熊猫。国内也有 50多家动物园饲养展出过。虽然有关小熊猫饲养繁殖的文章发表了很多 (丁耀华 1 964 ,汤佛胜 1 978,熊荫芝 1 979,1 980 ,刘荣启 1 979,顾文仪 1 982 ,吕美娟 1 982 ,Ａｎｏｎ .1 960 ,ＲｏｂｅｒｔｓＭ .Ｓ .1 975,1 979,ＧｒｅｙＢ .Ｊ.1 970 ) ,但是系统阐述小熊猫饲养管理的文章在国内还未见报道。笔者从1 993年到 1 998年 ,通过对卧龙自然保护区小熊猫饲养场 2 0…     

人工饲养下大熊猫繁殖生态的一些观察

我园人工饲养大熊猫已有27年历史,但从事人工饲养下的繁殖研究起步较晚,现就我园几年来人工饲养下大熊猫繁殖生态的一些观察叙述如下:大熊猫的年龄结构与性表现年龄:重庆动物园现饲养大熊猫8只,年龄分别为1至27周岁,雄性2只,雌性6只。年龄在4.5至15岁间的雌性熊猫3只,具有繁殖潜力。(其中2只已有生育,1只于1986年初开始发情,另3只年龄为1岁、2岁和27岁)。性表现的年龄与徐启明报道基本一致,但本园所繁殖3胎的生育年龄分别始于9岁和12岁,看来有性表现不等于具备繁殖能力,故可不必急于实施人工授精。人工饲养下的发情(持续)时间:雌性大熊猫在…     

北京地区恒河猴试验性繁殖及部分生物学特性观察

本实验于1992年底开始,通过选种、选配,建立了一个11只雄猴,77只雌猴的恒河猴生产繁殖种群并对其繁殖性能进行了观察与研究。三年间,利用大笼群养的“后宫式”繁殖方法,母猴怀孕107例,流产11例,生产仔猴96只,离乳94只。平均妊娠率、产仔率、离乳率分别为51．44％、46．15％、97．92％。在“后宫式”群养方式繁殖成功后,我们又尝试了单笼饲养、定期交配的新的繁殖方法,当年投种9只母猴,怀孕7只,生产7只。怀孕率、生产率均为77．78％。在进行实验性繁殖的同时,对人工条件下饲养的恒河猴的部分生物学特性如妊娠期、月经周期、血液生理生化指标、生长特性等进行了观察、记录和统计。结果表明人工条件下饲养的恒河猴在每年11月至次年4月间交配,4月至9月分娩。恒河猴具有间情期,每年秋冬季发情,平均月经周期为28．31±2．82d（n＝70）。平均怀孕期为163．46±11.87d（n＝13）。本实验为人工繁殖恒河猴进而实现实验动物化积累了基础数据,为将来提供高等级的、遗传背景清楚的、高质量的实验猕猴奠定了工作基础。     

圈养马麝(Moschus sifanicus)发情交配节律的比较研究

在1997～2000年间,甘肃兴隆山麝场的圈养马麝发情交配的时间节律保持相对年间恒定,1996年麝场进行了大规模的圈群间动物调整,导致该年的马麝圈群进入发情较迟,发情持续时间也较其他年份长。总体上,圈养马麝的发情持续时间达3个月,而66％的的发情交配发生于1个月内（从11月21日～12月21日）,发情季节（75％的发情完成累计时间）长36天。雌性圈养马麝发情的时间格局受圈养环境的季节性因子影响。饲养人员的饲养风格及各个饲养区内雌性马麝的社会行为的调节效应,各饲养区动物的发情时间格局有显著差异。年龄可影响马麝的发情交配,5．5岁龄以上的马麝发情定时更早。上一年度的繁殖成功与否和当年动物发情迟早无显著相关。野捕圈养麝群和其F1代圈群间的发情时间格局无显著差异。有较多发情周期的个体并不比发情周期仅1～2次的个体更早进入发情。     

圈舍环境对圈养大熊猫发情率的影响

发情率低是圈养大熊猫Ailuropoda melanoleuca饲养的难题之一,也是制约圈养大熊猫繁育的重要因素。近年来,随着大熊猫圈养技术的不断进步,圈养大熊猫的发情率有了大幅提高,但并未达到特别高的水平。对中国保护大熊猫研究中心2006—2012年参与繁殖计划的圈养成年雌性大熊猫种群的发情率进行统计发现,2009—2012年每年雌性大熊猫的发情率高达90%以上,较2006—2008年的发情率有显著提高。2006—2012年,该大熊猫种群的饲养和管理模式、食物结构都未变化,但从2009年起圈舍环境有明显变化。经分析,该种群发情率的变化与圈舍面积、圈舍地形、圈舍植被覆盖率和植物种类等因素变化有关。本研究为提高圈养大熊猫的发情率从改善大熊猫圈舍条件的角度提供了有效的参考。     

应用微卫星分型进行小熊猫亲子鉴定

小熊猫栖息于喜马拉雅与横断山脉,是亚洲濒危物种。中国的小熊猫谱系已登记圈养小熊猫个体９６８ 只,现有存活个体３５５ 只（２０１３ 年）,然而,现有谱系中存在部分信息不明确的问题。为此,我们选择１９ 对小熊猫特异性引物对４１ 只圈养小熊猫进行微卫星扩增,并分析其亲缘关系。将获取的亲子鉴定结果,结合种群原始记录信息,利用Pedigraph 软件构建福州圈养小熊猫的种群遗传谱系图。结果表明：在母子关系确实的情况下,１９个基因座位的联合父权排除概率为０. ９９９９９９６８;利用６ 个已知双亲的后代检验１９ 个基因座位的可信度,后代与双亲的基因型完全符合孟德尔遗传定律,表明１９个基因座位能有效确认小熊猫的亲权关系。应用１９ 个微卫星标记成功地为１５ 个后代找到了生物学父亲。尽管一些雌性个体在繁殖期有多重交配的行为,亲子鉴定的结果显示同一窝小熊猫均来自单一父权。基因型比对结果表明７ 对双胞胎均属于异卵双生子。福州种群的后代中除＃９２０和＃９２１ 外,其余均源于＃４８７ 或＃８９８ 两只雄性,表明不同个体参与繁殖的机会不均等。因此,利用现代繁殖技术,加强濒危野动物种群管理,科学制定繁殖计划具有积极的现实意义。     

哺乳期圈养雌性大熊猫圈舍转移及其育幼行为变化

<正>大熊猫(Ailuropoda melanoleuca)为我国特有珍稀濒危物种之一,被誉为"国宝"。经过科研人员多年努力,圈养大熊猫"配种难、受孕难、幼仔存活难"等问题已基本被成功解决,圈养大熊猫种群数量正在快速增加(张和民等,2013)。目前我国已经建立了四川卧龙、成都和陕西楼观台3个较大的圈养大熊猫种群繁育基地。截至2013年底,圈养大熊猫种群数量已经达到375只(谢钟,2013)。快速增加的圈养种群,导致现存可供使用     

Daily activity of captive giant pandas (Ailuropoda melanoleuca) at the wolong reserve

Daytime activity patterns of captive giant pandas (Ailuropoda melanoleuca) (n = 21) were observed for 2 week periods during October 1991 and January, April, and July 1992. A daytime bimodal activity pattern was seen with increased activity coinciding with feeding times at 1000 and 1600 h. The animals spent an average of 40 ± 10% of their time sleeping, 21 ± 10% resting, 25 ± 11% eating, 13 ± 9% walking, and 1 ± 3% interacting with other giant pandas. Adult females were less active than males or juveniles. During July, giant pandas were less active during the daytime than during other seasons of the year. There was no difference in activity patterns between pregnant and non-pregnant females. Two infants had similar activity patterns to the adults by the time they were 6 months old. Comparison with wild giant pandas (n = 5) at the Wolong Nature Reserve revealed similar bimodal activity cycles, although the time of peak activity differed and foraging/feeding time was greater for wild pandas than for captive animals. © 1994 Wiley-Liss, Inc.     

The giant panda is closer to a bear,judged by α- and β-hemoglobin sequences

Summary Using - and -hemoglobin sequences, we made a maximum likelihood inference as to the phylogenetic relationship among carnivores, including the two pandas, giant and lesser. Molecular phylogenetic studies up to 1985 had consistently indicated that the giant panda is more closely related to the bear than to the lesser panda. In 1986, however, a contradictory tree was constructed, using hemoglobins and so on, in which the two pandas link together (Tagle et al. 1986). In contrast to that tree, our conclusion supports the close relationship between bear and giant panda. The surface impression of a close relationship between the two pandas drawn from pairwise amino acid differences is explained by a rapid rate of hemoglobin evolution in the bear compared to that in the two pandas.Offprint requests to: T. Hashimoto     

Gut microbiota in reintroduction of giant panda

Reintroduction is a key approach in the conservation of endangered species. In recent decades, many reintroduction projects have been conducted for conservation purposes, but the rate of success has been low. Given the important role of gut microbiota in health and diseases, we questioned whether gut microbiota would play a crucial role in giant panda's wild‐training process. The wild procedure is when captive‐born babies live with their mothers in a wilderness enclosure and learn wilderness survival skills from their mothers. During the wild‐training process, the baby pandas undergo wilderness survival tests and regular physical examinations. Based on their performance through these tests, the top subjects (age 2–3 years old) are released into the wild while the others are translocated to captivity. After release, we tracked one released panda (Zhangxiang) and collected its fecal samples for 5 months (January 16, 2013 to March 29 2014). Here, we analyzed the Illumina HiSeq sequencing data (V4 region of 16S rRNA gene) from captive pandas (n = 24), wild‐training baby pandas (n = 8) of which 6 were released and 2 were unreleased, wild‐training mother pandas (n = 8), one released panda (Zhangxiang), and wild giant pandas (n = 18). Our results showed that the gut microbiota of wild‐training pandas is significantly different from that of wild pandas but similar to that of captive ones. The gut microbiota of the released panda Zhangxiang gradually changed to become similar to those of wild pandas after release. In addition, we identified several bacteria that were enriched in the released baby pandas before release, compared with the unreleased baby pandas. These bacteria include several known gut‐health related beneficial taxa such as Roseburia, Coprococcus, Sutterella, Dorea, and Ruminococcus. Therefore, our results suggest that certain members of the gut microbiota may be important in panda reintroduction.     

圈养小熊猫的昼夜活动节律

Daily activity rhytlms of three radio-collared captive red pandas were monitored individually at 15 minute intervals for 3 euntinuous days each month at Yele Nature Reserve, Xiangling Mountains, June- October 1995. Our data indicated that mean rate of activity [0.51 ) of captive red pandas was lower than that of wild red pandas. Three captive red pandas showed similar daily activity patterns, being least active during night and more active during daytime. Mean rate of activity during daylight (0.58)was higher than during nighttime (0.41). Daily mean durations of activity and rest were 12.21 hours and 11.79 hours, respectively. Active times of captive red pandas accounted for 50.6% of each 24 hours, of which 66.5% were recorded during daylight and 33.5% during night. Two active peaks appeared at07: 30-09: 15 and 17: 30- 19: 00. We recorded a mean of 2.17, 2.13 and 0.88 long, mid-length, and short resting bouts daily, which had mean durations of 3.47, 1.65 and 0.87 hour, respectively.Among these long rests, 46.1% occurred during daytime and 53.8% during nighttime.     

Hemoglobins of pandas

We tried to elucidate the genetical relationship of giant and lesser panda and especially that of Ursidae and Procyonidae by sequence analysis. We sequenced hemoglobins of four Ursidae and also those of giant and lesser panda. The surprising result is that the hemoglobin of both pandas only differs in six amino-acid exchanges whereas to other Carnivores, especially to Ursidae and Procyonidae, there exist much more ones. The interpretation of these and other amino-acid sequences with the maximum parsimony method gave a phylogenetic tree with the Felidae and Canidae representing their expected position and classifying the pandas a family or their own between Ursidae and Procyonidae. Because many sequences are available, with the help of molecular biology one can obtain very detailed information on special biological problems.     

大熊猫与同域动物在海拔分布上的生态位分化

大熊猫（Ailuropoda melanoleuca）是中国的特有物种,其成功放归可能受放归地气候、栖息地、同域动物等多种因素的影响。本研究在野外调查的基础上,基于生态位理论等方法,探讨了栗子坪国家级自然保护区大熊猫与其大中型同域动物的空间关系。调查结果表明,该保护区内大熊猫同域动物共20种,分别属于2纲5目,其中东洋型分布物种占优势（30%）。大熊猫同域动物分布海拔显著低于大熊猫的分布海拔（P＜0.05）,大熊猫分别与灵长目等5个目的动物在海拔分布上均存在显著的生态位分化（P＜0.001）。灵长目动物在空间分布上与大熊猫分布相异,而其他目的动物与大熊猫空间分布类似。偶蹄目动物痕迹数量占比最高（54.14 %）,而食肉目的小熊猫与大熊猫样线共同遇见率达到了43.75%。本研究结果表明,该地大熊猫同域动物较为丰富,在海拔分布上与大熊猫存在生态位分化。该研究可为圈养大熊猫的放归提供参考依据。     

Pregnancy detection from fecal progestin concentrations in the red panda (Ailures fulgens fulgens)

The reproductive physiology of red pandas (Ailures fulgens fulgens) has not been well documented. This critically endangered species is not self‐sustaining in captivity despite several breeding populations, with low reproductive success and high infant mortality being leading causes of the decline. Hormone profiles were monitored in three groups of females (mated with birth, mated no birth, and not paired) to document pregnancy and parturition. Fecal samples were analyzed for progestins using a radio‐immuno assay. Females that gave birth had significantly higher progestins during the study period compared to females that mated and did not give birth and females that were not paired with a male. Two critical time frames were detected, Weeks 7–11 and Weeks 13–20, in which pregnant females could be differentiated from the others with a 95% confidence interval (CI). Detecting pregnancy in captive red pandas may assist animal care staff in management of the females and increase the survival rate of offspring. Zoo Biol 0:1–11, 2005. © 2005 Wiley‐Liss, Inc.     

野生大熊猫与放牧家畜的活动格局比较

活动格局是动物内在机制和环境作用所表现出来的昼夜活动节律及其活动水平的行为生态特征,影响着动物的能量代谢能力、觅食行为策略和进化适应。通过内置活动传感器的GPS颈圈,于2010—2012年在四川卧龙国家级自然保护区的"核桃坪"及其毗邻区域,采集了野生大熊猫和放牧家畜的大量活动数据。分别选择3只成年大熊猫和3个马群的代表性个体作为样本,引入活动强度、活动时间百分率、活动时间片段率和活动片段时长等指标进行了两者之间的比较,以揭示大熊猫和放牧家畜在时间利用方面的内在特征。结果表明:野生大熊猫和放牧家畜在活动强度、活动时间百分率和活动时间片段率等方面都具有极显著性差异(P0.0001),仅两者之间的活动片段时长无明显的统计学意义(P=0.4107)。野生大熊猫表现为活动水平低、活动时间少、活动片段率高和活动片段时长短等特征的活动格局,且不同月份(季度)之间变化较大(P0.0001);放牧家畜则呈现出相异的时间利用规律,即活动水平高、活动时间多、活动时间片段率稍低和活动片段时长略长等特性。不同的时间利用规律和不同的空间利用模式,造成动物之间对栖息地、食物资源和伴生动物的利用方式、影响强度和空间分布的截然不同。因而,合理规划和管控放牧家畜的散养区域与数量,是自然保护管理与社区经济发展相协调的有效途径之一。     

大熊猫血液生理指标的测定

大熊猫(Aluropoda melanoleuca)是举世瞩目的珍稀濒危动物,被誉为中国的国宝,越来越受到国内外各界人士的喜爱和重视。关于大熊猫的血液生理生化指标资料已有较多报道。Chen(1987)对6只大熊猫,王强等(1998)对18只大熊猫,