Dominant expansion of a cryptic subclone with an abnormal karyotype in B lymphoblastoid cell lines during culture.

Although B lymphoblastoid cell lines (B-LCLs) are thought to maintain their original genomic structures during long-term culture, there has been considerable disagreement on the actual genomic stability of these cells. This study was initiated to determine whether B-LCLs develop cell populations with abnormal genomes during culture and to search for factors important to the maintenance of the original genome. We established continuous cultures of B-LCLs for more than 6 months and analyzed the cells using array-based comparative genome hybridization (CGH) analysis, conventional karyotyping and analysis of V(D)J recombination in the immunoglobulin (Ig) gene. We found that one B-LCL acquired an extra chromosome 4 without any other genomic rearrangements at passage 16 of continuous culture. At the Ig light- and heavy-chain loci, analysis of the major cell population showed a difference between cultures at early and later passages. Another aneuploid line was detected among B-LCLs established elsewhere and deposited previously into the RIKEN Cell Bank. Our findings indicate that some of the genomic rearrangements in B-LCLs are not caused by gradual accumulation of mutations and rearrangements during the B-LCL establishment processes, but rather as a result of a change in the cell population from clones with a normal genome to clones with de novo rearrangements. It is therefore feasible to maintain B-LCLs with a normal genomic structure by cell cloning or similar treatment.

Cross talk between hedgehog and epithelial-mesenchymal transition pathways in gastric pit cells and in diffuse-type gastric cancers.

We previously reported hedgehog (Hh) signal activation in the mucus-secreting pit cell of the stomach and in diffuse-type gastric cancer (GC). Epithelial-mesenchymal transition (EMT) is known to be involved in tumour malignancy. However, little is known about whether and how both signallings cooperatively act in diffuse-type GC. By microarray and reverse transcription-PCR, we investigated the expression of those Hh and EMT signalling molecules in pit cells and in diffuse-type GCs. How both signallings act cooperatively in those cells was also investigated by the treatment of an Hh-signal inhibitor and siRNAs of Hh and EMT transcriptional key regulator genes on a mouse primary culture and on human GC cell lines. Pit cells and diffuse-type GCs co-expressed many Hh and EMT signalling genes. Mesenchymal-related genes (WNT5A, CDH2, PDGFRB, EDNRA, ROBO1, ROR2, and MEF2C) were found to be activated by an EMT regulator, SIP1/ZFHX1B/ZEB2, which was a target of a primary transcriptional regulator GLI1 in Hh signal. Furthermore, we identified two cancer-specific Hh targets, ELK1 and MSX2, which have an essential role in GC cell growth. These findings suggest that the gastric pit cell exhibits mesenchymal-like gene expression, and that diffuse-type GC maintains expression through the Hh-EMT pathway. Our proposed extensive Hh-EMT signal pathway has the potential to an understanding of diffuse-type GC and to the development of new drugs.

Ras-mediated signaling pathway regulates the expression of a low-molecular-weight heat-shock protein in fission yeast.

In fission yeast, Schizosaccharomyces pombe, deficiency of ras1 gene causes an abnormal cell shape and abolishes mating ability. However, target genes of this signaling pathway are largely unknown because of the lack of an appropriate analysis system. To overcome this problem, we have started a novel project to categorize entire genes based on their expression levels under different growth conditions. Using this strategy, we screened genes whose expression levels were affected in the presence or absence of the ras1 gene product. For this purpose, we utilized high-density arrays of clones covering the entire genome of the fission yeast, and probed with labelled cDNA derived from various strains and growth conditions. Here, we demonstrate the detection of a low-molecular-weight heat-shock protein gene, hsp16, whose expression is very likely to be regulated by a ras-mediated signaling pathway, but not by the heat-shock response.

Identification and characterization of a novel trans-membrane protein gene, pdh1, from Schizosaccharomyces pombe.

We have cloned a new gene, pdh1, from genomic DNA of fission yeast Schizosaccharomyces pombe. pdh1 is actively transcribed as 1400-nucleotide mRNA in vegetatively growing cells and can code for a 226 amino acid polypeptide (pdh1p). Computational structural prediction has revealed that the pdh1p is a highly hydrophobic protein with seven transmembrane domains. The prediction has also detected a possible C-kinase phosphorylation site within the longest hydrophilic loop.

Enzymic characterization of fission yeast farnesyl transferase: recognition of the -CAAL motif at the C-terminus.

The enzyme farnesyl transferase (FTase) catalyzes the posttranslational modification of Ras and other Ras family proteins with a C15 farnesyl group. The target proteins have a consensus -CAAX motif (X, any amino acid except leucine) at the C-terminus. Since proteins that have leucine as the C-terminal amino acid X are modified with a C20 geranylgeranyl group, it is thought that the C-terminal leucine is the signal (-CAAL motif) for selection of isoprenoid molecules. Here, we report the presence of multiple FTase activities in the fission yeast Schizosaccharomyces pombe, each seeming to correspond to a particular protein known to be modified by the farnesyl group in vivo. Using enzymic activities specific to S. pombe Ras1, we found similar affinities for FTases in the wild-type (EVSTKCCVIC) and mutant Ras1 peptide, in which the C-terminal amino acid is replaced by leucine (EVSTKCCVIL). These results suggest that recognition and selection of the correct isoprenoid group by the FTases require other amino acid sequences of the target protein in addition to the C-terminal -CAAX motif.

Biochemical similarity of Schizosaccharomyces pombe ras1 protein with RAS2 protein of Saccharomyces cervisiae.

Schizosaccharomyces pombe contains single ras oncogene homologue, ras1, that functions in the signal transduction pathway conducting the cell's mating processes. To understand the biochemical basis of yeast ras proteins, we have purified the ras1 protein and compared the major biochemical constants with those of RAS2 protein from Saccharomyces cerevisiae and mammalian ras proteins. The purified ras1 protein showed a remarkably high Kd value for GDP binding (178 nM) and for binding with ATP. In contrast, the Kd value for GTP binding and the rate of GTPase activity were 64 nM and 77 x 10(-6) s-1 at 37 degrees C, respectively; both were higher than normal p21ras protein, but at the same level as the RAS2 protein. We directly measured rate of GTP binding and GDP binding which were 3.9 x 10(-3) s-1 and 1.8 x 10(-3) s-1 at 30 degrees C, respectively. On the other hand, exchange rates between bound and free nucleotides remained almost constant throughout the tested combination of GTP and GDP, and were several-fold lower than the binding rate. These results suggest that the release of the guanine nucleotide is the rate-limiting step in the ras-GTP/GDP cycle. As a whole, the biochemical properties of the ras1 protein are close to those of the RAS2 protein, although these two proteins function differently in the signal transduction pathway in the cells.