Misako Satoh

Abnormal telomere dynamics of B-lymphoblastoid cell strains from Werner's syndrome patients transformed by Epstein – Barr virus

The characteristics of B-lymphoblastoid cell strains transformed by Epstein – Barr virus (EBV) from normal individuals and Werners syndrome (WRN) patients were compared. We continuously passaged cell strains from 28 WRN patients and 20 normal individuals for about 2 years corresponding to over 160 population doubling levels (PDLs). First, the WRN mutation significantly suppressed the immortalization: all the 28 cell strains from WRN patients, as well as 15 out of 20 cell strains from normal individuals, died out before 160 PDLs mostly without developing a significant telomerase activity. The remaining five cell strains from normal individuals became moderately/strongly telomerase-positive and, three of them were apparently immortalized with an infinitively proliferating activity. Second, the monitoring of the telomere length of both normal and WRN cell strains during the culture period suggests that the WRN gene mutation causes abnormal dynamics of the telomere: (1) a significant proportion of WRN cell strains showed drastic shortening or lengthening of telomere lengths during cell passages compared with normal cell strains, and (2) WRN cell strains terminated their life-span at a wide range of telomere length (between 3.5 and 18.5 Kbp), whereas normal cell strains terminated within a narrow telomere length range (between 5.5 and 9 Kbp). The chromosomal aberration characteristic of WRN cells, including translocation was confirmed in our experiment. We discussed the correlation between the chromosomal instability, abnormal telomere dynamics and inability of immortalization of the WRN B-lymphobloastoid cell strains.

Mutation and haplotype analyses of the Werner's syndrome gene based on its genomic structure : genetic epidemiology in the Japanese population

Abstract The correlation between mutations in the Werner’s syndrome (WRN) gene and the haplotypes of surrounding markers was studied in Japanese patients. We have elucidated the genomic structure of WRN helicase, and found five additional mutations, designated mutations 6–10. Mutations 4 and 6 were found to be the two major mutations in this population; these mutations comprised 50.8% and 17.5%, respectively, of the total in a sample of 126 apparently unrelated chromosomes. Almost all the patients homozygous for mutation 4 shared a haplotype around the WRN gene, consistent with the view that they are derived from a single ancestor. This important advantage demonstrated in the identification of the WRN gene suggests that the Japanese present a unique population for the cloning of other disease genes. The conserved haplotype was observed across 19 loci, extending a distance estimated to be more than 1.4 Mbp around the WRN gene. This haplotype is rare among random Japanese individuals. Unexpectedly, all the nine patients homozygous for mutation 6 shared a haplotype that was identical to this haplotype at 18 of these 19 markers. These results suggest that mutations 4 and 6 arose independently in almost identical rare haplotypes. The remaining mutations (1, 5, 7, 8, 9, and 10) occurred rarely, and were each associated with different haplotypes.

Prevalence of Werner's syndrome heterozygotes in Japan

1Worldwide, 1200 patients have been reported from 1904 to 1996; 845 from Japan. Patients are distributed all over Japan. 2 But how widely distributed is the mutated WRN gene in the general population? We previously analysed the mutation in 63 patients with Werner’s syndrome, and found that among 126 chromosomes, 65 (51·6%) chromosomes had mutation 4 and 22 (17·5%) had mutation 6, 3 and the rest had other mutations. We focused on mutations 4 and 6. DNA extracted from the blood of 1000 apparently healthy, unlinked anonymous volunteers in Kanagawa prefecture of Japan were analysed for mutations 4 and 6 by a method developed by us. 4

Cloning of boar SPMI gene which is expressed specifically in seminal vesicle and codes for a sperm motility inhibitor protein

Boar semen contains a seminal plasma motility inhibitor (SPMI) that blocks the motility of demembranated‐reactivated spermatozoa as well as of intact spermatozoa. In this paper, we describe the primary structure of SPMI, the coding of boar SPMI cDNA gene and its expression in various porcine tissues. Nucleotide sequence analysis of the 645‐bp SPMI cDNA predicts a coded polypeptide of 137 amino acid residues which includes a 21‐residue signal peptide and a 116‐residue secreted protein. The amino acid sequence of SPMI was found to be highly homologous to AQN‐3, a member of spermadhesin family proteins of boar that bind to spermatozoa. Expression of the boar SPMI gene detected by Northern blot analysis revealed that its expression is very abundant in seminal vesicles and specific to this tissue.

A comparative analysis of the proteins between the fibroblasts from Werner's syndrome patients and age-matched normal individuals using two-dimensional gel electrophoresis

Werners syndrome (WS) is an autosomal recessive disorder causing symptoms of premature aging. The fibroblasts of WS patients have a shorter life-span than normal fibroblasts. We analyzed the fibroblast proteins from three WS patients and from three age-matched normal individuals using two-dimensional gel electrophoresis and image processing. The expressions of 12 proteins were shown to be augmented or suppressed in WS fibroblasts compared with normal fibroblasts: 11 of 12 spots on the electrophoresis gel of WS fibroblasts were denser than the corresponding spots of normal individual fibroblasts, while the remaining one spot was fainter in WS fibroblasts than in normal fibroblasts. The abundance of these proteins were compared to those of the corresponding proteins from normal fibroblasts at various cell passages in vitro reported in the TMIG-2DPAGE database. The result shows that the change in the protein patterns in in vitro aging did not necessarily correspond to the change in WS fibroblasts, except for three proteins abundant in WS fibroblasts, which increased their abundance during in vitro aging. These results suggest that the premature aging process of WS fibroblasts shares only part of the in vitro aging process of normal fibroblasts.

In Vitro Establishment of Tumorigenic Human B-Lymphoblastoid Cell Lines Transformed by Epstein-Barr Virus

We studied tumorigenic and phenotypic characteristics of pre- and postimmortal human B-lymphoblastoid cell lines (LCLs) transformed by Epstein-Barr virus (EBV): preimmortal LCLs showed low telomerase activity and a normal diploid karyotype while postimmortal LCLs showed much higher telomerase activity and maintained a clonal aneuploidic state. Among five postimmortal LCLs tested, LCLs N0005 and N6803 formed colonies in agar medium and showed marked aneuploidy, and N6803 was transplantable into nude mice indicating that it had a complete malignant phenotype, but all preimmortal LCLs and the remaining three postimmortal LCLs lacked these characteristics. The products of tumor suppresser genes, p16(INK4A) and pRb, were downregulated in these two LCLs, and the p53 gene was mutated in N0005 LCL. We believe these results showed for the first time that some postimmortal EBV-transformed LCLs can become tumorigenic, contrary to previous reports, and that these LCLs provide an in vitro model of tumorigenesis induced by EBV.

CLONING AND CHARACTERIZATION OF A NOVEL GENE, WS-3, IN HUMAN CHROMOSOME 8P11-P12

A novel human gene referred to as the WS-3 gene, in the short arm of human chromosome 8, was cloned by a combination of exon trapping, thermal asymmetric interlaced-PCR (TAIL-PCR) and the Marathon-Ready cDNA amplification method. The gene consists of 7 exons separated by 6 introns, and is at the telomere side of the STS marker, D8S1055. The full-length WS-3 gene contains 1052 nucleotides and codes for a protein of 190 amino acids with a calculated mol. wt. of 20,747. Southern blot experiments showed that the WS-3 gene exists as a single copy in the human genome. A protein encoded by the WS-3 gene has an R-G-D (Arg-Gly-Asp) motif in the N-terminal region, which seems to confer adhesive properties to macromolecular proteins like fibronectin. Although WS-3 is a small gene with unknown biological function, its ubiquitous expression in various tissues and organs suggests that the encoded protein is one of the essential components of all organs and tissues.

Overexpression of mRNAs of TGFβ-1 and related genes in fibroblasts of Werner syndrome patients

We analyzed mRNAs that were up- or down-regulated in fibroblasts from Werner syndrome (WS) patients compared with those from normal individuals. The mRNAs from normal and WS cells were first screened by differential display, and those mRNAs that were apparently up- or down-regulated were selected except for mRNAs related to extra-cellular matrix (ECM) proteins that are already known to be up-regulated in WS fibroblasts. Then, the expression levels of these mRNAs were semiquantified by northern blot analysis, and six up-regulated and two down-regulated mRNAs were identified in WS cell lines. Among the six up-regulated mRNAs were three mRNAs that coded TGFbeta-1 and two proteins, their expressions of which were increased by TGFbeta-1. These results together with the fact that TGFbeta-1 up-regulates the expression of ECM proteins strongly suggest that TGFbeta-1 has a key role in accelerated cellular senescence of fibroblasts of WS patients.

Estimation of the physical distance between major genomic markers in the Werner syndrome locus (8p 11.2-12) by dual-color fish analysis

SummaryThe gene responsible for Werner syndrome (WS) is considered to be located between D8S131 and D8S87 in the 8p11.2-12 region that includes the closest marker D8S339 (Goto et al. (1992) Nature 355: 735–738). In this experiment, the order of major markers in this region was determined and the physical distances between them were estimated by dual-color fluorescence in situ hybridization (FISH) using P1, PAC and cosmid clone DNAs as probes. The fine overall order of telomere-D8S131-D8S339-GSR-PP2Aβ-D8S283-D8S87-centromere was determined for the first time. The distance from D8S131 to D8S87 was estimated to be 1,634 kb. To our surprise, the distance between D8S131 and D8S87 is much shorter than previously estimated by recombination analysis, 8.3 cM equivalent to 8.3 Mb in physical distance. These information provide the basis for the positional cloning of WS gene and the identification of its mutation.