The faecal flora of the giant panda (Ailuropoda melanoleuca)

The faecal floras of two adult (male and female) and one infant (male) giant panda kept at the Ueno Zoo, Tokyo, Japan were examined and shown to be quite different from those of other animals. The predominant bacteria in the adults were Streptococcus (including Enterococcus) and Enterobacteriaceae, while obligate anaerobes had minor populations. Fastidious anaerobes were not detected. The predominant bacteria in the suckling infant were Lactobacillus and Streptococcus, followed by Bifidobacterium. After the infant began to eat bamboo leaves the number of Lactobacillus decreased and Bifidobacterium became undetectable, whereas Enterobacteriaceae became one of the most predominant flora. The most dominant streptococcus isolated from the female panda was identified as Streptococcus bovis, but those from the male adult and the weaned infant were not identified as any known species.     

The faecal flora of the giant panda (Ailuropoda melanoleuca)

The faecal floras of two adult (male and female) and one infant (male) giant panda kept at the Ueno Zoo, Tokyo, Japan were examined and shown to be quite different from those of other animals. The predominant bacteria in the adults were Streptococcus (including Enterococcus ) and Enterobacteriaceae, while obligate anaerobes had minor populations. Fastidious anaerobes were not detected. The predominant bacteria in the suckling infant were Lactobacillus and Streptococcus , followed by Bifidobacterium. After the infant began to eat bamboo leaves the number of Lactobacillus decreased and Bifidobacterium became undetectable, whereas Enterobacteriaceae became one of the most predominant flora. The most dominant streptococcus isolated from the female panda was identified as Streptococcus bovis , but those from the male adult and the weaned infant were not identified as any known species.     

野化培训大熊猫幼仔的食性转换

本文以2010—2020年15只母兽带仔野化培训的大熊猫幼仔为研究对象,基于红外视频监控系统观察和音频颈圈解译获得的行为资料、GPS颈圈跟踪定位采集的粪样数据,分析了野化培训大熊猫幼仔的行为发育进程和食性转换特征。结果表明：随着野化培训大熊猫幼仔的生长发育,与觅食和警戒相关的行为得到充分发育,且具有较强的时间关联性,包括食乳、爬行、走动、玩耍物品、爬树、咬玩竹子、饮水和采食竹子等。8～10月龄的大熊猫幼仔开始取食竹子,其发育性食性转换过程划分为3个阶段：食乳期(1～7月龄)、食母乳—食竹子转换期(8～28月龄)和食竹期(29～39月龄),其中转换期细分为关键期(8～18月龄)和过渡期(19～28月龄)。从统计检验来看,不同食性阶段间差异显著;过渡期的大熊猫幼仔可离开母兽独立生活,此阶段大熊猫幼仔食物组分比例与食竹期相比无显著差异。野化培训大熊猫幼仔的季节性食性转换规律与带仔母兽和野生大熊猫具有相似的格局,即春季主要取食竹笋,夏、秋季则以嫩竹茎和竹叶为食,冬季采食竹叶与竹茎。     

An improved,chromosome-level genome of the giant panda (Ailuropoda melanoleuca)

BackgroundThe iconic giant panda (Ailuropoda melanoleuca), as both a flagship and umbrella species endemic to China, is a world famous symbol for wildlife conservation. The giant panda has several specific biological traits and holds a relatively small place in evolution. A high-quality genome of the giant panda is key to understanding the biology of this vulnerable species.FindingsWe generated a 2.48-Gb chromosome-level genome (GPv1) of the giant panda named “Jing Jing” with a contig N50 of 28.56 Mb and scaffold N50 of 134.17 Mb, respectively. The total length of chromosomes (n = 21) was 2.39-Gb, accounting for 96.4% of the whole genome. Compared with the previously published four genomes of the giant panda, our genome is characterized by the highest completeness and the correct sequence orientation. A gap-free and 850 kb length of immunoglobulin heavy-chain gene cluster was manually annotated in close proximity to the telomere of chromosome 14. Additionally, we developed an algorithm to predict the centromere position of each chromosome. We also constructed a complete chromatin structure for “Jing Jing”, which includes inter-chromosome interaction pattern, A/B compartment, topologically associated domain (TAD), TAD-clique and promoter-enhancer interaction (PEI).ConclusionsWe presented an improved chromosome-level genome and complete chromatin structure for the giant panda. This is a valuable resource for the future genetic and genomic studies on giant panda.     

Female giant panda (Ailuropoda melanoleuca) chirps advertise the caller's fertile phase

Although female mammal vocal behaviour is known to advertise fertility, to date, no non-human mammal study has shown that the acoustic structure of female calls varies significantly around their fertile period. Here, we used a combination of hormone measurements and acoustic analyses to determine whether female giant panda chirps have the potential to signal the caller''s precise oestrous stage (fertile versus pre-fertile). We then used playback experiments to examine the response of male giant pandas to female chirps produced during fertile versus pre-fertile phases of the caller''s reproductive cycle. Our results show that the acoustic structure of female giant panda chirps differs between fertile and pre-fertile callers and that male giant pandas can perceive differences in female chirps that allow them to determine the exact timing of the female''s fertile phase. These findings indicate that male giant pandas could use vocal cues to preferentially associate and copulate with females at the optimum time for insemination and reveal the likely importance of female vocal signals for coordinating reproductive efforts in this critically endangered species.     

秦岭野生大熊猫牙齿的形态机能

大熊猫(Ailuropoda melanoleuca)是国家一级保护动物,被誉为国宝.牙齿作为大熊猫消化器官之一,相对于其他动物而言,大熊猫牙齿有其自身的构造特点.以往学者和专家对大熊猫牙齿形态的研究侧重于为大熊猫的种群分类寻找根据(Dvadi,1869; Milne-Edwards,1870;王将克,1974),更多关注牙齿在大熊猫进化、演变过程中的意义(王令红等,1982;黄万波,1993).研究的齿位大多局限于臼齿(张鹤宇和刘理,1959),所得结果或数据并不详细和全面.此外,还有一些学者对大熊猫牙齿釉质的超微组织结构进行研究(赵资奎等,1984 ).     

野化培训大熊猫的生境利用和空间格局

了解动物栖息地和空间利用模式是开展野生动物放归自然的重要前提。为明确野化培训大熊猫Ailuropoda melanoleuca)在野外环境中生境利用特征和空间格局,本文以2只野化培训大熊猫为研究对象,基于其野外GPS项圈数据,通过数字高程模型(DEM)、动物移动模块等工具分析其在野外环境中栖息地利用状况。结果表明:随着在野外环境时间的增加,2只大熊猫由低海拔西南坡的阔叶林逐渐向高海拔南坡针阔混交林区域移动,且坡度利用也存在明显的差异,但均偏向在17°～20°的平缓区域活动。在野外环境的最初一个月,2只大熊猫平均日移动距离较大,之后逐渐减小并趋于稳定。2只野化培训大熊猫在野外环境初期,活动区域大小随时间的变化而呈现出无规律的变化趋势,活动区域主要集中在3～4个栖息地斑块,且斑块间面积和距离各异。因此,认为野化培训大熊猫在野外栖息地环境初期属于不稳定的随机选择模式。     

Sixteen novel microsatellite loci developed for the giant panda (Ailuropoda melanoleuca)

Sixteen novel microsatellite DNA loci were developed from the giant panda (Ailuropoda melanoleuca) using a magnetic-bead capture method. A total of 115 alleles were obtained for these markers, ranging from 4 to 12 alleles per locus (average 7.188). These loci exhibited high levels of polymorphic information content and expected heterozygosity, 0.558–0.855 (average 0.729) and 0.628–0.885 (average 0.778), respectively. Therefore, the allelic polymorphism and heterozygosity show that the giant pandas raised in China Research and Conservation Center possess abundant genetic variation. In addition, if the three markers showing null alleles were excluded, the remaining 13 microsatellite loci still presented extremely low non-exclusion probabilities of parentage (0.002), paternity (0.000) and identity (0.000). As a result, this new suit of microsatellite markers would be a very informative tool for the genetic and conservation studies of giant pandas.     

岷山地区大熊猫(Ailuropoda melanoleuca)生境影响因子连通性及主导因子

岷山地区是大熊猫保护的关键地区.运用图论分析法研究了岷山地区大熊猫生境影响因子,及其相互作用关系.结果表明:在岷山地区,12个影响因子66对组合中,47.0%的影响因子间存在直接的联系,其中89.2%的影响具有增大效应,这说明人类活动对大熊猫生境的影响具有协同增大效应,并占主导地位.研究发现,在影响因子关系集中,存在强连通性的子集K={(TD);(RB);(MI);(HPL);(AP);(AD);(SR);(TH);(FC)},这表明近期进行的旅游景点开发,公路建设,采矿,高压电线走廊建设,以及传统的农业开发,畜牧业,薪柴采集等影响因子之间存在着强烈相互作用关系,这些人类活动还会将其他人类活动对大熊猫生境的影响放大,加剧其对大熊猫生境的不利影响,是影响岷山地区大熊猫生境的主导因素.研究还表明如果不能对主导因子进行有效的控制,很难有效地保护岷山地区大熊猫生境.研究表明图论分析法是研究大熊猫生境影响因子的一个有效工具,有助于明确影响熊猫生境的主导和关键因子,为制定有效的大熊猫保护策略提供科学依据.     

Major histocompatibility complex class II variation in the giant panda (Ailuropoda melanoleuca)

Habitat destruction and human activity have greatly impacted the natural history of the giant panda (Ailuropoda melanoleuca). Although the genetic diversity of neutral markers has been examined in this endangered species, no previous work has examined adaptive molecular polymorphisms in the giant panda. Here, the major histocompatibility complex (MHC) class II DRB locus was investigated in the giant panda, using single-strand conformation polymorphism (SSCP) and sequence analysis. Comparisons of DNA samples extracted from faecal and blood samples from the same individual revealed that the two materials yielded similar quantities and qualities of DNA, as well as identical SSCP patterns and allelic sequences, demonstrating the reliability of DNA isolation from panda faeces. Analysis of faecal samples from 60 giant pandas revealed relatively low number of alleles: seven alleles. However, the alleles were quite divergent, varying from each other by a range of 7-47 nucleotide substitutions (4-25 amino acid substitutions). Construction of a neighbour-joining tree and comparisons among DRB alleles from other species revealed that both similar and highly divergent alleles survived in the bottlenecked panda populations. Despite species-specific primers used and excellent faecal DNA isolated, a lower level of heterozygosity than expected was still observed due to inbreeding. There were three types of evidence supporting the presence of balancing selection in the giant panda: (i) an obvious excess of nonsynonymous substitutions over synonymous at the antigen-binding positions; (ii) trans-species evolution of two alleles between the giant panda and other felids; and (iii) a more even distribution of alleles than expected from neutrality.     

A reliable, non-invasive PCR method for giant panda (Ailuropoda melanoleuca) sex identification

We developed an inexpensive, fast and reliable PCR method for sex identification of giant panda (Ailuropoda melanoleuca) by using one pair of primers to co-amplify homologous fragments with size polymorphism that located at amelogenin (AMEL) exon 5. In giant panda, a 63 bp deletion in exon 5 of Y-linked allele provides a significant discrimination between AMELX and AMELY, thus the amplification products can be distinguished simply by agarose gel electrophoresis, exhibiting sex-specific banding patterns (male: 237 bp, 174 bp; female: 237 bp). Both blood and feces samples from known-sex giant pandas were successfully amplified. Cross species test also revealed that this method could be applied to other Ursidae species. These authors contributed equally to this work.     

Successful artificial insemination in the giant panda (Ailuropoda melanoleuca) at ueno zoo

Successful breeding of the giant panda (Ailuropoda melanoleuca) following artificial insemination was achieved at the Ueno Zoo in 2 consecutive years (1985 and 1986). The first cub, born in June 1985, unfortunately died 43 hours after birth from being crushed by the mother panda; the second cub, born in June 1986, has been growing in good health. Electroejaculation and artificial insemination procedures were performed after immobilization with diazepam (0.1 mg/kg) and ketamine HCL (4.0–5.0 mg/kg). Semen of the male panda was collected by electroejaculation using a rectal probe with a diameter of 2.0 cm and with eight rings as electrodes. Stimulation of the male was given with 3 V (30–40 mA) over a 5-sec period with 5-sec intervals. The female panda exhibited estrus between late February and early March in 1985 and also between mid-january and early February 1986. Increased excretion of urinary total estrogen showed coincidentally at maximum behavioral estrus, and a gradual rise of pregnanediol level was followed by artificial insemination. The gestational length for the first pregnancy was 110 days and that of the second 121 days.     

Pregnancy detection and fetal monitoring via ultrasound in a giant panda (Ailuropoda melanoleuca)

Transabdominal ultrasound was used to monitor the reproductive tract of a female giant panda (Ailuropoda melanoleuca) for three consecutive breeding seasons starting in 2001. Parturition did not occur in 2001 or 2002. In 2003, uterine enlargement was noted 109 days after natural mating occurred. A twin pregnancy was detected via transabdominal ultrasound 134 days following natural mating. Four subsequent ultrasound examinations, performed at 137, 138, 140, and 142 days postmating, documented fetal development. The female gave birth to one infant 150 days postmating. Zoo Biol 23:449–461, 2004. © 2004 Wiley‐Liss, Inc.     

Thirty-three microsatellite loci for noninvasive genetic studies of the giant panda (Ailuropoda melanoleuca)

Limited microsatellite markers useable in noninvasive genetic methods have hampered the studies of dispersal patterns and mating systems of giant pandas. Therefore, we describe in this paper the characterization of 15 novel microsatellite loci from genomic DNA-enriched libraries and 18 redesigned microsatellite loci from published papers on the giant panda. The number of alleles per locus in 60 individuals ranged from 2 to 13, the average observed heterozygosity per locus from 0.168 to 0.800, and the average expected heterozygosity per locus from 0.152 to 0.882. All loci followed Hardy-Weinberg expectations. Four pairs of significant linkage association were found among all these loci. Moreover, the 33 microsatellite loci showed high amplification successes rate in noninvasive samples, which indicated that these loci will be of use in studying dispersal patterns and mating systems of giant pandas using noninvasive genetic methods.     

降低圈养大熊猫排粘液频率的措施初探

大熊猫(Ailuropoda melanoleuca)是中国特有的珍稀动物,在其整个消化道内膜上,都分布有丰富的粘液腺。在野外,这些粘液腺的分泌物包裹于大熊猫摄食的竹茎、竹叶和竹笋表面而排出体外;圈养条件下,常常见到这些分泌物积聚到一定数量而成团排出,这即被称为大熊猫的排粘液现象(王平     

Molecular characterization of major histocompatibility complex class I genes from the giant panda (Ailuropoda melanoleuca)

The major histocompatibility complex class I genes play crucial roles in the adaptive immune system of vertebrates against intracellular pathogens. To date, no class I genes from the giant panda (Ailuropoda melanoleuca) has been reported, even none from species of Ursidae. In this study, we successfully identified three class I genes from a giant panda bacterial artificial chromosome library and designated them as Aime-128, 152, and 1906, respectively. Pairwise sequence alignments revealed that (1) the Aime-1906 always possessed the lowest identities (52–86%) in different regions compared with the Aime-128 and 152 and (2) the Aime-128 also varied from the Aime-152 in the regions of 5′ untranslated region (UTR), 3′ UTR, and exon1, whose similarities were 83%, 87%, and 91%, respectively. Comparison of structure characteristics indicated that the Aime-128 possessed all conserved amino acids important to the function of antigen presentation while the Aime-152 and 1906 presented two and five mutated residues. Analysis of phylogenetic trees demonstrated that the Aime-128, 152, and 1906 were clustered into three different branches with 99% or 100% bootstrap values. As a result, these three kinds of evidence supported that the Aime-1906, 152, and 128 should be derived from different loci. Furthermore, in view of a prestop codon in the exon 7 and patterns of amino acid replacement within alleles, the Aime-1906 gene is predicted to be a nonclassical locus, which is most closely related to dog leukocyte antigen 79 in the phylogenetic tree constructed with various mammalian class I loci. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Cloning and sequence analysis of FSH and LH in the giant panda (Ailuropoda melanoleuca)

The giant panda (Ailuropoda melanoleuca) is an endangered species and indigenous to China. It has been proposed that it has a highly specialized reproductive pattern with low fecundity, but little is known about its basic reproductive biology at the molecular level. In this report the genes encoding gonadotropin subunits alpha, follicle-stimulating hormone (FSH) beta and luteinizing hormone (LH) beta of the giant panda were amplified for the first time by RT-PCR from pituitary total RNA, and were cloned, sequenced and analyzed. The results revealed that the open reading region (ORF) of gonadotropin subunits alpha, FSH beta and LH beta are 363, 390 and 426 bp long, respectively. They displayed a reasonably high degree (74-94, 85-93, 75-91%, for alpha, FSH beta and LH beta subunits, respectively) of identity when deduced amino acids were compared with homologous sequences from partial available mammals including human, cattle, sheep, pig, rat, mouse. Three distinct differences were found at the site of 59 aa of the alpha subunit and 55 aa, 68 aa of FSH beta subunit. Our results provide an insight into understanding the mechanism of reproduction regulation and genetic characteristics of giant panda which will make an actual contribution to its conservation. In addition they lay a foundation for a further study towards producing recombinant panda FSH and LH which can be used in artificial breeding aimed to increase its captive reproductive efficiency.     

Genetic diversities of the giant panda (Ailuropoda melanoleuca) in Wanglang and Baoxing Nature Reserves

Genetic variations in the giant panda populations in Wanglang and Baoxing Nature Reserves were evaluated in this study. Panda feces were collected from these two reserves and DNA samples extracted from the feces were genotyped at 13 microsatellite loci. A total of 130 alleles were identified from the 13 microsatellite loci in 63 giant pandas, including 35 private alleles in Wanglang, 53 private alleles in Baoxing, and 42 alleles shared between the two populations. The mean observed heterozygosity, average number of alleles, average number of allelic richness, and average polymorphism information content were 0.488, 6.2, 3.302, and 0.612, respectively for the Wanglang population and 0.553, 7.6, 4.050, and 0.747 for the Baoxing population. A moderate degree of genetic differentiation (F _st = 0.26) and no gene flow were found between these two populations. W. He and L. Lin contributed equally to this work.     

cDNA cloning of growth hormone from giant panda (Ailuropoda melanoleuca) and its expression in Escherichia coli

A cDNA encoding Ailuropoda melanoleuca growth hormone (AmGH) was isolated from pituitary total RNA using RT-PCR and expressed in Escherichia coli. This is the first report of a GH nucleotide and amino acid (aa) sequence from giant panda. The open reading frame of AmGH (651 bp) encodes a precursor of 216 aa comprising a 26 aa signal peptide and a 190 aa mature protein with four cysteine residues similar to the typical primary structure of mammalian GH precursor. AmGH shares a high degree of identity (54-98.9%) with that of mammals, birds and amphibians, but a very low identity with bony fish GH (only 20-30%). The mature AmGH exhibits striking similarity to that of putative ancestral GH with a difference of only two residues, indicating a very slow basal rate of molecular evolution. The DNA fragment encoding mature AmGH was then subcloned into the pGEX-4T-1 expression vector and highly expressed in E. coli host BL21 with IPTG induction. The expressed proteins fused to GST were found to be sequestered into inclusion bodies and therefore the NaOH method was employed to solubilize the inclusion bodies; the proteins were further purified by Glutathione Sepharose 4B affinity chromatography. The production and purification of GST-AmGH reported here provide a basis for further studies on the biological activity of AmGH.