Elevated levels of thymidylate synthase linked to neoplastic transformation of mammalian cells.

Thymidylate synthase (TS), an enzyme that is essential for DNA synthesis and repair has been identified as an important biomarker for colorectal and other human cancers. The elevated steady-state levels of TS found in many common human malignancies have been thought to represent a secondary event in tumor formation. However, it has recently been demonstrated that the deregulated levels of ectopic TS may also have a causal effect on tumorgenesis since overexpression of human TS transforms immortalized mammalian cells to a malignant phenotype. Since the levels of TS are regulated by E2F-1 and thus are linked to the cell cycle pathway, regulating TS activity may be an important factor for the control of cell cycle progression and for the development of therapeutic strategies and cancer prevention.

Thymidylate synthase as an oncogene: a novel role for an essential DNA synthesis enzyme.

Thymidylate synthase (TS) is an E2F1-regulated enzyme that is essential for DNA synthesis and repair. TS protein and mRNA levels are elevated in many human cancers, and high TS levels have been correlated with poor prognosis in patients with colorectal, breast, cervical, bladder, kidney, and non-small cell lung cancers. In this study, we show that ectopic expression of catalytically active TS is sufficient to induce a transformed phenotype in mammalian cells as manifested by foci formation, anchorage independent growth, and tumor formation in nude mice. In contrast, comparable levels of two TS mutants carrying single point mutations within the catalytic domain had no transforming activity. In addition, we show that overexpression of TS results in apoptotic cell death following serum removal. These data demonstrate that TS exhibits oncogene-like activity and suggest a link between TS-regulated DNA synthesis and the induction of a neoplastic phenotype.

Evolutionary conservation of a 2-kb intronic sequence flanking a tissue-specific alternative exon in the PTBP2 gene.

nPTB is a member of the polypyrimidine tract-binding (PTB) protein family, which participates in alternative pre-mRNA processing. Tissue-specific splicing of exon 10 in nPTB (HGMW-approved symbol PTBP2) may play an important role in regulating the functional activity of nPTB in neuronal versus nonneuronal cells. In this study, we found that 297 consecutive intronic nucleotides flanking this alternatively spliced exon 10 were identical between human, green monkey, mouse, rat, and pig, while 207 consecutive intronic nucleotides were identical between human and bird DNA. In addition, a 2-kb sequence spanning this intron region showed 85 and 70% conservation in mammal and bird DNA, respectively. Unexpected intergenic sequence conservation between human and mouse genomes has recently been identified. We have now identified intragenic (intronic) sequence conservation from mammals to birds. The striking conservation of this large segment of flanking intronic sequence suggests an important role in tissue-specific splice site selection and may function in regulating the production of functional nPTB.

Alternative splicing of brain-specific PTB defines a tissue-specific isoform pattern that predicts distinct functional roles.

Splicing of neural-specific exons is differentially regulated in neuronal and non-neuronal cells. The polypyrimidine tract binding protein (PTB) has been implicated as a negative regulator for exon splicing, whereas the brain-specific homolog of PTB, termed nPTB, promotes exon splicing exclusively in neurons. We have now isolated a novel mRNA splice variant of nPTB from non-neuronal cells. In contrast to the neural nPTB transcript, the expression of this novel isoform was absent from brain tissue and was generated in non-neuronal cells by alternative splicing to include five additional amino acid residues encoded by exon 9. In addition, we identified a brain-specific transcript containing a novel, alternatively spliced, internal exon 10. The exclusion of this 34-nucleotide exon 10 in non-neuronal tissues generates a premature termination codon and results in the truncation of the open reading frame. Our findings suggest that alternative splicing of nPTB has an important role in regulation of tissue-specific gene expression and thus in the functional activity of nPTB in neuronal and non-neuronal cells.