MicroRNA expression signature of human sarcomas.

MicroRNAs (miRNAs) are approximately 22 nucleotide-long noncoding RNAs involved in several biological processes including development, differentiation and proliferation. Recent studies suggest that knowledge of miRNA expression patterns in cancer may have substantial value for diagnostic and prognostic determinations as well as for eventual therapeutic intervention. We performed comprehensive analysis of miRNA expression profiles of 27 sarcomas, 5 normal smooth muscle and 2 normal skeletal muscle tissues using microarray technology and/or small RNA cloning approaches. The miRNA expression profiles are distinct among the tumor types as demonstrated by an unsupervised hierarchical clustering, and unique miRNA expression signatures were identified in each tumor class. Remarkably, the miRNA expression patterns suggested that two of the sarcomas had been misdiagnosed and this was confirmed by reevaluation of the tumors using histopathologic and molecular analyses. Using the cloning approach, we also identified 31 novel miRNAs or other small RNA effectors in the sarcomas and normal skeletal muscle tissues examined. Our data show that different histological types of sarcoma have distinct miRNA expression patterns, reflecting the apparent lineage and differentiation status of the tumors. The identification of unique miRNA signatures in each tumor type may indicate their role in tumorigenesis and may aid in diagnosis of soft tissue sarcomas.

Regulation of apoptosis by C. elegans CED-9 in the absence of the C-terminal transmembrane domain.

Bcl-2 proteins regulate apoptosis in organisms as diverse as mammals and nematodes. These proteins are often localized at mitochondria by a C-terminal transmembrane domain. Although the transmembrane domain and mitochondrial localization are centrally involved in specific cases of vertebrate Bcl-2 activity, the significance of this localization is not clear for all species. Studying the Caenorhabditis elegans Bcl-2 homolog CED-9, we found that the transmembrane domain was both necessary and sufficient for localization at mitochondrial outer membranes. Furthermore, we found that in our assays, ced-9 transgenes lacking the transmembrane domain, although somewhat less active than equivalent transgenes derived from wild-type ced-9, rescued embryonic lethality of ced-9(lf) animals and responded properly to upstream signals in controlling the fate of Pn.aap neurons. Both of these apoptotic activities were retained in a construct where CED-9 lacking the transmembrane domain was targeted to the cytosolic surface of the endoplasmic reticulum and derived organelles, suggesting that in wild-type animals, accumulation at mitochondria is not essential for CED-9 to either inhibit or promote apoptosis in C. elegans. Taken together, these data are consistent with a multimodal character of CED-9 action, with an ability to regulate apoptosis through interactions in the cytosol coexisting with additional evolutionarily conserved role(s) at the membrane.

Characterization of tRNA precursor splicing in mammalian extracts.

Transcription of a Xenopus laevis tRNATyr gene and splicing of the transcript have been studied in HeLa cell extracts. This tRNATyr gene has a 13-base intervening sequence and is expressed as mature tRNA when transfected into mammalian cells. The tRNATyr gene is transcribed under conditions of low concentrations of magnesium and ATP, but is processed by splicing only when both of these cofactors are added at higher concentrations. The endonucleolytic activity of the tRNA-splicing system in the HeLa extract produces exons with 3'-phosphate and 5'-hydroxyl groups. The 3'-phosphate is retained during the ligation reaction and forms the phosphodiester bond in the mature tRNA. Retention of the 3'-phosphate during tRNA splicing differs from the more extensively studied process in yeast extracts where a phosphate group from an ATP cofactor is used to form the phosphodiester bond joining the exons. Thus, eucaryotic organisms can splice tRNA precursors by at least two distinguishable mechanisms.