Large-scale analysis of Macaca fascicularis transcripts and inference of genetic divergence between M. fascicularis and M. mulatta.

Background: Cynomolgus macaques (Macaca fascicularis) are widely used as experimental animals in biomedical research and are closely related to other laboratory macaques, such as rhesus macaques (M. mulatta). We isolated 85,721 clones and determined 9407 full-insert sequences from cynomolgus monkey brain, testis, and liver.

Mapping of chimpanzee full-length cDNAs onto the human genome unveils large potential divergence of the transcriptome.

The genetic basis of the phenotypic difference between human and chimpanzee is one of the most actively pursued issues in current genomics. Although the genomic divergence between the two species has been described, the transcriptomic divergence has not been well documented. Thus, we newly sequenced and analyzed chimpanzee full-length cDNAs (FLcDNAs) representing 87 protein-coding genes.

Substitution rate and structural divergence of 5'UTR evolution: comparative analysis between human and cynomolgus monkey cDNAs.

The substitution rate and structural divergence in the 5'-untranslated region (UTR) were investigated by using human and cynomolgus monkey cDNA sequences. Due to the weaker functional constraint in the UTR than in the coding sequence, the divergence between humans and macaques would provide a good estimate of the nucleotide substitution rate and structural divergence in the 5'UTR. We found that the substitution rate in the 5'UTR (K5UTR) averaged approximately 10%-20% lower than the synonymous substitution rate (Ks).

Analysis of 5'-end sequences of chimpanzee cDNAs.

We constructed full-length enriched cDNA libraries from chimpanzee brain, skin, and liver tissues by the oligo-capping method to establish a database of sequences of chimpanzee genes. Randomly selected clones from the libraries were subjected to one-pass sequencing from their 5'-ends. As a result, we collected 6813 chimpanzee cDNA sequences longer than 400 bp.

Cynomolgus monkey testicular cDNAs for discovery of novel human genes in the human genome sequence.

Background: In order to contribute to the establishment of a complete map of transcribed regions of the human genome, we constructed a testicular cDNA library for the cynomolgus monkey, and attempted to find novel transcripts for identification of their human homologues.

Result: The full-insert sequences of 512 cDNA clones were determined. Ultimately we found 302 non-redundant cDNAs carrying open reading frames of 300 bp-length or longer.

Molecular cloning, mRNA expression and chromosomal localization of mouse angiotensin-converting enzyme-related carboxypeptidase (mACE2).

We isolated two mouse cDNA clones which show significant similarities with human angiotensin-converting enzyme-related carboxypeptidase (ACE2). The cDNAs were 2746 and 1995 bp in length and seemed to arise from the same gene by alternative splicing. The longer cDNA encoded a 798-amino acid protein containing the sequence motif conserved among zinc metallopeptidases.

Search for genes positively selected during primate evolution by 5'-end-sequence screening of cynomolgus monkey cDNAs.

It is possible to assess positive selection by using the ratio of K(a) (nonsynonymous substitutions per plausible nonsynonymous sites) to K(s) (synonymous substitutions per plausible synonymous sites). We have searched candidate genes positively selected during primate evolution by using 5'-end sequences of 21,302 clones derived from cynomolgus monkey (Macaca fascicularis) brain cDNA libraries. Among these candidates, 10 genes that had not been shown by previous studies to undergo positive selection exhibited a K(a)/K(s) ratio > 1.

Prediction of unidentified human genes on the basis of sequence similarity to novel cDNAs from cynomolgus monkey brain.

Background: The complete assignment of the protein-coding regions of the human genome is a major challenge for genome biology today. We have already isolated many hitherto unknown full-length cDNAs as orthologs of unidentified human genes from cDNA libraries of the cynomolgus monkey (Macaca fascicularis) brain (parietal lobe and cerebellum). In this study, we used cDNA libraries of three other parts of the brain (frontal lobe, temporal lobe and medulla oblongata) to isolate novel full-length cDNAs.