Sequence and expression of rat ICAM-1.

We have isolated cDNA clones-coding for rat intercellular adhesion molecule-1 (RICAM-1) from a cDNA library constructed from rat Ax cells stimulated with IL-1 beta using the mouse ICAM-1 cDNA as a hybridization probe. The RICAM-1 sequence shows 79.1% homology with mouse ICAM-1 and 55.6% homology with human ICAM-1 at the nucleic acid level. In order to examine the expression of RICAM-1 on Chinese hamster ovary (CHO) cells, we constructed the vector, pSV-RICAM1-neo, containing the SV40 promoter. Flowcytometric analysis showed that CHO-K1 cells transfected with pSV-RICAM1-neo expressed high amounts of RICAM-1 on their surfaces.     

Development and characterization of a Chinese hamster ovary cell-specific oligonucleotide microarray

The Chinese hamster ovary (CHO) cell line is one of the most widely used mammalian cell lines for biopharmaceutical production. We have developed and characterized a gene expression microarray (WyeHamster2a) specific for CHO cells that has enabled the study of ~3,500 sequences. Analysis of multiple sets of replicate scans showed that data derived from the WyeHamster2a array is highly reproducible confirming it as a robust tool for profiling. Twelve gene sequences were selected for follow-up RT-qPCR to confirm the accuracy and precision of the microarray results. In all but the most subtle gene expression differences, the microarray proved to be a reliable measure of differential gene expression. Finally, we were able to quantify the difference between using a bona fide CHO-specific microarray for profiling CHO cells versus an alternate, commercially available, rodent microarray such as a mouse or rat-specific format.     

Adenosine deaminase gene amplification in deoxycoformycin-resistant mammalian cells

Deoxycoformycin (dCF)-resistant mutants of rat hepatoma, mouse LMTK-, and Chinese hamster ovary (CHO) cells have been isolated and shown to overproduce adenosine deaminase (ADA). The overproduction of ADA was found to be due to ADA-gene amplification in rat and mouse cells but not in CHO cells. Deoxycoformycin-resistant rat hepatoma cells have large HSRs (homogeneously staining regions), mouse cells carry DMs (Double minutes), and CHO cells do not appear to have any gross chromosomal anomalies. When dCF-resistant rat hepatoma and mouse cells are selected by increasing the concentration of the inhibitor in small increments, there is a good correlation between the increase in ADA gene copy number and the increase in the level of expression of ADA, suggesting that all of the amplified genes are equally active in the expression of ADA.     

Genome sequence comparison between Chinese hamster ovary (CHO) DG44 cells and mouse using end sequences of CHO BAC clones based on BAC-FISH results

Chinese hamster ovary (CHO) cells have frequently been used in biotechnology as a mammalian host cell platform for expressing genes of interest. Previously, we constructed a detailed physical chromosomal map of the CHO DG44 cell line by fluorescence in situ hybridization (FISH) imaging using 303 bacterial artificial chromosome (BAC) clones as hybridization probes (BAC-FISH). BAC-FISH results revealed that the two longest chromosomes were completely paired. However, other chromosomes featured partial deletions or rearrangements. In this study, we determined the end sequences of 303 BAC clones (BAC end sequences), which were used for BAC-FISH probes. Among 606 BAC-end sequences (BESs) (forward and reverse ends), 558 could be determined. We performed a comparison between all determined BESs and mouse genome sequences using NCBI BLAST. Among these 558 BESs, 465 showed high homology to mouse chromosomal sequences. We analyzed the locations of these BACs in chromosomes of the CHO DG44 cell line using a physical chromosomal map. From the obtained results, we investigated the regional similarities among CHO chromosomes (A–T) and mouse chromosomes (1–19 and sex) about 217 BESs (46.7% of 465 high homologous BESs). Twenty-three specific narrow regions in 13 chromosomes of the CHO DG44 cell line showed high homology to mouse chromosomes, but most of other regions did not show significant correlations with the mouse genome. These results contribute to accurate alignments of chromosomes of Chinese hamster and its genome sequence, analysis of chromosomal instability in CHO cells, and the development of target locations for gene and/or genome editing techniques.     

Isolation, characterization and chromosomal mapping of the mouse tyrosine aminotransferase gene

The tyrosine aminotransferase (TAT) gene is expressed in a tissue and developmental-specific manner. In addition, this gene is regulated by glucocorticoid and polypeptide hormones and its expression is affected when a regulatory region near the albino locus of the mouse is deleted. In order to allow studies of the molecular effects of these deletion mutations we have isolated and characterized the mouse TAT gene. The gene is 9.2 x 10(3) bases in length and consists of 12 exons which give rise to a 2.3 x 10(3) base long messenger RNA. The DNA sequence at the 5' end of the gene was determined and compared with the corresponding sequence of the rat tyrosine aminotransferase gene. The sequence comparison showed extensive homology over the entire region sequenced. In addition, DNA: DNA heteroduplex studies between the mouse and rat tyrosine aminotransferase genes revealed that this homology extends over the entire gene and its flanking sequences. The mouse tyrosine aminotransferase gene has been mapped distal to the serum esterase-1 locus on mouse chromosome 8, using a restriction fragment length polymorphism between two mouse species. Since the albino deletions are located on mouse chromosome 7, the assignment of the TAT gene to chromosome 8 suggests that a regulatory factor(s) affecting TAT gene expression acts in trans.     

红细胞生成素基因在大鼠体内的表达及表达产物的生物学效应

红细胞生成素（ｅｒｙｔｈｒｏｐｏｉｅｔｉｎ,ＥＰＯ）是一种由胎儿肝脏和成人肾脏产生的多肽类生长因子,在体内的表达具有严格的组织特异性,因此,慢性肾病所引起的贫血常常难以得到有效的治疗．随着基因治疗技术的不断成熟与完善,尤其是近年一些实验室先后发现质粒...     

Interspecies mitochondrial fusion between mouse and human mitochondria is rapid and efficient

A detailed molecular understanding of mitochondrial fusion and fission in mammalian cells is rapidly emerging. In this report, we demonstrate for the first time cross-species mitochondrial fusion between distantly related species using green and red fluorescent proteins targeted to the mitochondrial matrix. We found that mouse mitochondria were able to efficiently fuse to unmodified mitochondria of human cells and that the contents of the mitochondrial matrix were completely mixed in less than 4h. We also observed that mitochondria from the mtDNA-less (rho(0)) mouse cells can homogeneously fuse to the mitochondria of human cells. We were, however, unable to maintain human mitochondrial DNA in the mouse cells. These results indicate that mitochondrial fusion proteins in mouse and human cells have enough functional homology to mediate efficient cross-species mitochondrial fusion, but mouse nuclear and human mitochondrial genomes have not retained functional compatibility with one another.     

Cross-species hybridisation of pig RNA to human nylon microarrays

Background

The objective of this research was to investigate the reproducibility of cross-species microarray hybridisation. Comparisons between same- and cross-species hybridisations were also made. Nine hybridisations between a single pig skeletal muscle RNA sample and three human cDNA nylon microarrays were completed. Three replicate hybridisations of two different amounts of pig RNA, and of human skeletal muscle RNA were completed on three additional microarrays.

Results

Reproducibility of microarray hybridisations of pig cDNA to human microarrays was high, as determined by Spearman and Pearson correlation coefficients and a Kappa statistic. Variability among replicate hybridisations was similar for human and pig data, indicating the reproducibility of results were not compromised in cross-species hybridisations. The concordance between data generated from hybridisations using pig and human skeletal muscle RNA was high, further supporting the use of human microarrays for the analysis of gene expression in the pig. No systematic effect of stripping and re-using nylon microarrays was found, and variability across microarrays was minimal.

Conclusion

The majority of genes generated highly reproducible data in cross-species microarray hybridisations, although approximately 6% were identified as highly variable. Experimental designs that include at least three replicate hybridisations for each experimental treatment will enable the variability of individual genes to be considered appropriately. The use of cross-species microarray analysis looks promising. However, additional validation is needed to determine the specifiCity of cross-species hybridisations, and the validity of results.     

Effect of serial passage on gene expression in MC3T3-E1 preosteoblastic cells: a microarray study

The osteoblastic function of mouse preosteoblastic MC3T3-E1 cells, as measured by alkaline phosphatase activity and osteocalcin secretion, decreases after serial passage. To uncover genes responsible for decreased osteoblastic function in high-passage cells, we have studied passage-dependent change of gene expression in MC3T3-E1 cells. Changes in the expression pattern of 2000 selected genes were examined simultaneously by comparing mRNA levels between MC3T3-E1 cells at passage 20 and passage 60 using the cDNA microarray analysis. Significant changes in the steady-state abundance of 27 mRNAs were observed in response to different passage numbers, including 17 known genes, 4 ESTs with homology to known genes, and 6 genes with no previously described function or homology. Northern blot analysis was used to verify and quantify the expression of selected genes, and revealed a significant higher level of up- and down-regulation compared to microarray data. These results indicate the existence of a significant change in gene expression in osteoblastic cells undergoing serial passages. Such changes might be responsible for a reduction in bone regeneration in older osteoblasts. Potential roles of selected genes in bone aging are discussed.     

Cloning of a rat gene encoding the histo-blood group A enzyme. Tissue expression of the gene and of the A and B antigens.

The complete coding sequence of a BDIX rat gene homologous to the human ABO gene was determined. Identification of the exon-intron boundaries, obtained by comparison of the coding sequence with rat genomic sequences from data banks, revealed that the rat gene structure is identical to that of the human ABO gene. It localizes to rat chromosome 3 (q11-q12), a region homologous to human 9q34. Phylogenetic analysis of a set of sequences available for the various members of the same gene family confirmed that the rat sequence belongs to the ABO gene cluster. The cDNA was transfected in CHO cells already stably transfected with an alpha1,2fucosyltransferase in order to express H oligosaccharide acceptors. Analysis of the transfectants by flow cytometry indicated that A but not B epitopes were synthesized. Direct assay of the enzyme activity using 2' fucosyllactose as acceptor confirmed the strong UDP-GalNAc:Fucalpha1,2GalalphaGalNAc transferase (Atransferase) activity of the enzyme product and allowed detection of a small UDP-Gal:Fucalpha1,2GalalphaGal transferase (B transferase) activity. The presence of the mRNA and of the A and B antigens was searched in various BDIX rat tissues. There was a general good concordance between the presence of the mRNA and that of the A antigen. Tissue distributions of the A and B antigens in the homozygous BDIX rat strain were largely different, indicating that these antigens cannot be synthesized by alleles of the same gene in this rat inbred strain.     

Rat–Mouse and Rat–Human Comparative Maps Based on Gene Homology and High-Resolution Zoo-FISH

The laboratory rat, Rattus norvegicus, and the laboratory mouse, Mus musculus, are key animal models in biomedical research. A deeper understanding of the genetic interrelationsships between Homo sapiens and these two rodent species is desirable for extending the usefulness of the animal models. We present comprehensive rat-human and rat-mouse comparative maps, based on 1090 gene homology assignments available for rat genes. Radiation hybrid, FISH, and zoo-FISH mapping data have been integrated to produce comparative maps that are estimated to comprise 83-100% of the conserved regions between rat and mouse and 66-82% of the conserved regions between rat and human. The rat-mouse zoo-FISH analysis, supported by data for individual genes, revealed nine previously undetected conserved regions compared to earlier reports. Since there is almost complete genome coverage in the rat-mouse comparative map, we conclude that it is feasible to make accurate predictions of gene positions in the rat based on gene locations in the mouse.     

Hamster estrogen receptor cDNA: cloning and mRNA expression

Estrogen-induced hamster kidney tumor model serves as a useful model to study the biochemical and molecular mechanisms of hormonal carcinogenesis. In this model, we have demonstrated an increased expression of estrogen receptor mRNA and protein in estrogen-treated kidneys and in estrogen-induced tumors. The sequence information for hamster estrogen receptor gene is not known and has been investigated in this study. A hamster uterus cDNA library was constructed and the 5'-region of the hamster estrogen receptor cDNA cloned from this library using polymerase chain reaction (PCR) methodology. Additionally, hamster kidney polyadenylated RNA was reverse transcribed and PCR amplified using primers that were designed based on maximum homology between mouse, rat and human estrogen receptor cDNAs. These PCR amplified fragments were cloned into plasmid vectors and clones with the expected size of the insert subjected to Southern blot analysis using human estrogen receptor cDNA as a probe. The positive clones on Southern blot analysis and the PCR amplified products from these clones were subjected to DNA sequence analysis. Using this strategy, a full length, 1978 bp hamster estrogen receptor cDNA has been cloned which shows 87% homology with human, 90% with rat and 91% with mouse estrogen receptor cDNA. The deduced amino acid shares 88% homology with human, and 93% with rat and mouse estrogen receptors. Hamster estrogen receptor domain C (DNA binding domain) shows a 100% homology with a similar domain from mouse, rat, human, pig, sheep, horse and chicken estrogen receptor (Genebank reference ID: AF 181077).