Tupaia belangeri as an experimental animal model for viral infection.

Tupaias, or tree shrews, are small mammals that are similar in appearance to squirrels. The morphological and behavioral characteristics of the group have been extensively characterized, and despite previously being classified as primates, recent studies have placed the group in its own family, the Tupaiidae. Genomic analysis has revealed that the genus Tupaia is closer to humans than it is to rodents. In addition, tupaias are susceptible to hepatitis B virus and hepatitis C virus. The only other experimental animal that has been demonstrated to be sensitive to both of these viruses is the chimpanzee, but restrictions on animal testing have meant that experiments using chimpanzees have become almost impossible. Consequently, the development of the tupaia for use as an animal infection model could become a powerful tool for hepatitis virus research and in preclinical studies on drug development.

Proteomic characteristics of the liver and skeletal muscle in the Chinese tree shrew (Tupaia belangeri chinensis).

Valid animal models are useful for studying the pathophysiology of specific disorders, such as neural disease, diabetes and cancer. Previous molecular phylogeny studies indicate that the tree shrew is in the same order as (or a close sister to) primates, and thus may be an ideal model in which to study human disease. In this study, the proteome of liver and muscle tissue in tree the shrew was identified by combining peptide fractionation and LC-MS/MS identification. In total, 2146 proteins were detected, including 1759 proteins in liver samples and 885 proteins in skeletal muscle samples from the tree shrew. Further sub-source analysis revealed that nearly half of the identified proteins (846 proteins and 418 proteins) were derived from human database. In this study, we are the first to describe the characteristics of the proteome from the liver and skeletal muscle of the tree shrew. Phylogenetic tree analysis based on these proteomic data showed that the tree shrew is closer to primates (human) than to glires (the mouse and rat).

Evaluating the phylogenetic position of Chinese tree shrew (Tupaia belangeri chinensis) based on complete mitochondrial genome: implication for using tree shrew as an alternative experimental animal to primates in biomedical research.

Tree shrew (Tupaia belangeri) is currently placed in Order Scandentia and has a wide distribution in Southeast Asia and Southwest China. Due to its unique characteristics, such as small body size, high brain-to-body mass ratio, short reproductive cycle and life span, and low-cost of maintenance, tree shrew has been proposed to be an alternative experimental animal to primates in biomedical research. However, there are some debates regarding the exact phylogenetic affinity of tree shrew to primates. In this study, we determined the mtDNA entire genomes of three Chinese tree shrews (T. belangeri chinensis) and one Malayan flying lemur (Galeopterus variegatus). Combined with the published data for species in Euarchonta, we intended to discern the phylogenetic relationship among representative species of Dermoptera, Scandentia and Primates. The mtDNA genomes of Chinese tree shrews and Malayan flying lemur shared similar gene organization and structure with those of other mammals. Phylogenetic analysis based on 12 concatenated mitochondrial protein-encoding genes revealed a closer relationship between species of Scandentia and Glires, whereas species of Dermoptera were clustered with Primates. This pattern was consistent with previously reported phylogeny based on mtDNA data, but differed from the one reconstructed on the basis of nuclear genes. Our result suggested that the matrilineal affinity of tree shrew to primates may not be as close as we had thought. The ongoing project for sequencing the entire genome of Chinese tree shrew will provide more information to clarify this important issue.

[Cloning of full-length coding sequence of tree shrew CD4 and prediction of its molecular characteristics].

The tree shrews, as an ideal animal model receiving extensive attentions to human disease research, demands essential research tools, in particular cellular markers and monoclonal antibodies for immunological studies. In this paper, a 1 365 bp of the full-length CD4 cDNA encoding sequence was cloned from total RNA in peripheral blood of tree shrews, the sequence completes two unknown fragment gaps of tree shrews predicted CD4 cDNA in the GenBank database, and its molecular characteristics were analyzed compared with other mammals by using biology software such as Clustal W2.0 and so forth. The results showed that the extracellular and intracellular domains of tree shrews CD4 amino acid sequence are conserved. The tree shrews CD4 amino acid sequence showed a close genetic relationship with Homo sapiens and Macaca mulatta. Most regions of the tree shrews CD4 molecule surface showed positive charges as humans. However, compared with CD4 extracellular domain D1 of human, CD4 D1 surface of tree shrews showed more negative charges, and more two N-glycosylation sites, which may affect antibody binding. This study provides a theoretical basis for the preparation and functional studies of CD4 monoclonal antibody.

[Molecular cloning of Tupaia belangeri chinensis neuropeptide Y and homology comparison with other analogues from primates].

Much attention has been payed to tree shrews for their close phylogenetic relationship with primates, small size, and short reproductive cycle. Especially, they are considered as excellent experiential animals for medicine or/and disease research. A nucleotide sequence encoding neuropeptide Y(NPY) precursor has been cloned from the cDNA library of Tupaia belangeri chinensis. Sequence alignment revealed that the sequence homology with primate NPY was up to 96.9%. The phylogenetic analysis based on NPY precursor sequence revealed that the tree shrew has a close relationship with primates.

[Studies of hereditary conditionality index on some morphological characters of Tupaia belangeri chinensis].

Tree shrew is a kind of excellent experimental animal resource in medical science and biology. In this paper, 35 Tupaia blangeri chinensises (TBCs) captured from Kunming,Yunnan province were investigated. We analyzed hereditary conditionality index about some morphological characters. According to Rife-Buranamanas law, we analyzed the appearance characteristics with hereditary conditionality including color of fur, orbit etc. The results showed the following: wild fur with seasonal red spot, white fur of abdomen, non-white orbit, flesh-color palm, non-cocked ear, round tip tail, and the line between the breasts of both sides in a vertical position with axis line.

Comparative cytogenetic studies in tree shrews (Tupaia).

Through use of BrdU replication, RBA-banded karyotypes of Tupaia belangeri, T. chinensis, and T. glis were obtained. A chromosome number of 2n = 62 for T. belangeri is described here for the first time and is confirmed for T. chinensis. All chromosomes between these two phenotypically different species appear to have identical RBA banding patterns; in addition, there is no difference between T. belangeri and T. chinensis in the number and position of nucleolus organizer regions (NORs). The reduced chromosome number of 2n = 60 in T. glis can be explained by a Robertsonian translocation between two acrocentric chromosome pairs, Nos. 10 and 13, of T. belangeri and/or T. chinensis, resulting in the metacentric chromosome pair 1 of T. glis. Furthermore, two chromosome pairs each of T. glis and T. belangeri and/or T. chinensis are not homoeologous, as judged by their RBA patterns. Differences were also found in the number and position of NORs; whereas T. glis displays eight positively stained NORs after AgNO3 staining, there are only four silver-stained NORs in both T. belangeri and T. chinensis. The possibility of geographical isolation as an explanation for the lack of chromosomal differentiation between T. belangeri and T. chinensis is discussed.