Beatrice Quantin scite author profile

Stromelysin is a collagenase-related connective-tissue-degrading metalloproteinase. We have detected RNAs capable of hybridizing to a rat stromelysin cDNA in 11 of 69 human tumours tested. Molecular cloning of cDNAs to these RNAs has identified them as a mixture of stromelysin RNA and a transcript of a hitherto-undescribed related human gene, the stromelysin-2 gene. We have also isolated cDNAs corresponding to a more distantly related new human gene, the pump-1 gene. A comparison of the cDNA-derived amino acid sequences of stromelysin-2 and pump-1 with the known sequences of stromelysin and collagenase reveals significant similarities, with conservation of sequence motifs believed to have functional importance in metalloproteinase action. We conclude that the collagenase gene family in humans consists of at least four members, and speculate that expression of these genes plays a role in cancer.

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Plasmid DNA Is Superior to Viral Vectors for Direct Gene Transfer into Adult Mouse Skeletal Muscle

Davis

Demeneix²,

Quantin³

et al. 1993

Human Gene Therapy

275

125

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Direct gene transfer into skeletal muscle offers several therapeutic possibilities. We assessed direct intramuscular injection of recombinant plasmids, adenovirus, or retrovirus in normal or regenerating muscles of mice. The incorporation and expression of reporter genes introduced by any of these three vectors is greater in regenerating than in mature muscle. In regenerating muscle, pure DNA and adenovirus result in equivalent numbers of fibers expressing reporter gene (> 10%), but adenovirus also induces considerable cellular infiltration. In mature muscle, recombinant DNA is better than adenovirus. Retrovirus failed to infect mature muscle fibers and was less effective than plasmid DNA or adenovirus in regenerating muscle. The surprisingly high relative efficiency of pure plasmid DNA suggests that this method will provide a simple, safe and viable alternative for gene therapy involving muscle tissue.

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Epidermal growth factor stimulates transcription of the c-jun proto-oncogene in rat fibroblasts

Quantin

Breathnach

1988

Nature

273

111

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Some growth factor-induced genes, such as the c-fos gene, are activated rapidly and transiently without intervening protein synthesis. Others, like the rat transin gene, are activated more slowly but more durably and their activation requires prior protein synthesis. It is tempting to speculate that certain rapidly-activated genes code for transcription factors which interact directly with promoter regions of genes like the transin gene to trigger their expression. Unfortunately, little is known about the majority of primary response genes to support this hypothesis. The proto-oncogene c-jun codes for the transcription factor AP-1 or a closely related protein. We show that epidermal growth factor stimulates transcription of the c-jun gene in fibroblasts as a primary response. This supports the notion that increased expression of genes encoding transcription factors is an important element of the signal transduction mechanism, assuring the long-term transcriptional response of cells to growth factors.

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