Shedding light on ADAM metalloproteinases.

ADAM metalloproteinase disintegrins have emerged as the major proteinase family that mediates ectodomain shedding, the proteolytic release of extracellular domains from their membrane-bound precursors. Recent gene-manipulation studies have established the role of ADAM-mediated shedding in mammalian physiology and, in addition, raised the issue of functional redundancy among ADAM sheddases. ADAM sheddases activate, for example, growth factors and cytokines, thus regulating signalling pathways that are important in development and pathological processes such as cancer. The recent studies have also begun to elucidate the substrate specificity and the mechanisms that control ADAM-mediated shedding events that regulate, for example, growth-factor and Notch signalling, and the processing of the amyloid precursor protein.

Aberrant alternative exon use and increased copy number of human metalloprotease-disintegrin ADAM15 gene in breast cancer cells.

ADAM genes have been associated with cancer, with ADAM expression, genomic rearrangements, and, by implication of ADAM proteins in the altered behavior found in tumor cells. In the present study, increased copy number of the ADAM15 gene in human breast cancer cell lines was demonstrated by fluorescence in situ hybridization. This was not reflected in mRNA levels, however. Instead, the use of alternative ADAM15 exons appeared erratic, leading to aberrant combinations of ADAM15 mRNA isoforms in the cancer cells. Clustering analysis indicated that these isoform patterns were nonrandom, suggesting a failure in the regulation mechanism or mechanisms of the alternative exon usage. Altered regulation of alternative exon usage may provide a useful target for cancer diagnostics development. ADAM15 would be particularly appropriate for breast cancer diagnostics because the various combinations of its three alternatively used exons can be readily examined with a simple, straightforward PCR protocol.

Cloning and expression of short interspersed elements B1 and B2 in ischemic brain.

Global ischemia causes an extensive cell death 3 days after the ischemia in the CA1 region of the hippocampus, which is preceded by induction of a spectrum of genes with both neuroprotective and detrimental properties. This delayed cell death has been suggested to be mainly caused by programmed cell death. Here we applied differential display to characterize transcripts induced by global ischemia after 1 day in Mongolian gerbils, when the cells in the CA1 region are still viable, but initiating the cell death pathway. One of the cloned transcripts turned out to be a repeat sequence termed SINE B2. We also cloned the other member of the SINE family, SINE B1, and found it also to be slightly induced by ischemia in the CA1 region. The SINE repeat regions are not translated and their role in ischemia may be related the neurons' attempt to cope with decreased translational levels and/or genomic reorganization. Together with the previous data demonstrating the inducibility of the SINE transcripts using in vitro stress models, the present study shows that SINE transcripts are stress-inducible factors in the central nervous system.