Autosomal recessive spinal muscular atrophy (SMA) is linked to mutations in the survival motor neuron (SMN) gene. The SMN protein has been implicated at several levels of mRNA biogenesis and is expressed ubiquitously. Studies in various model organisms have shown that the loss of function of the SMN gene leads to embryonic lethality. The human contains two genes encoding for SMN protein and in patients one of these is disrupted. It is thought the remaining low levels of protein produced by the second SMN gene do not suffice and result in the observed specific loss of lower motor neurons and muscle wasting. The early lethality in the animal mutants has made it difficult to understand why primarily these tissues are affected. We have isolated a Drosophila smn mutant. The fly alleles contain point mutations in smn similar to those found in SMA patients. We find that zygotic smn mutant animals show abnormal motor behavior and that smn gene activity is required in both neurons and muscle to alleviate this phenotype. Physiological experiments on the fly smn mutants show that excitatory post-synaptic currents are reduced while synaptic motor neuron boutons are disorganized, indicating defects at the neuromuscular junction. Clustering of a neurotransmitter receptor subunit in the muscle at the neuromuscular junction is severely reduced. This new Drosophila model for SMA thus proposes a functional role for SMN at the neuromuscular junction in the generation of neuromuscular defects.
The actual frequency of constitutively activating thyrotropin receptor or Gsalpha mutations in toxic thyroid nodules (TTNs) remains controversial as considerable variation in the prevalence of these mutations has been reported. We studied a series of 75 consecutive TTNs and performed mutation screening by the more sensitive method of denaturing gradient gel electrophoresis (DGGE) in addition to direct sequencing. Furthermore, the likelihood of somatic mutations occurring in genes other than that for the thyroid-stimulating hormone receptor (TSHR) and exons 7-9 of the Gsalpha protein gene was determined by clonality analysis of TTNs, which did not harbor mutations in the investigated genes. In 43 of 75 TTNs (57%) constitutively active TSHR mutations were identified. Six TSHR mutations were detected only by DGGE, underlining the importance of a sensitive screening method. Novel, constitutively activating mutations were identified at positions 425 (Ser-->Leu) and 512 (Leu-->Glu/Arg). Furthermore, a new base substitution was detected at position Pro639Ala (CCA-->GCA). Ten of 20 TSHR or Gsalpha mutation negative cases (50%) showed nonrandom X-chromosome inactivation, indicating clonal origin. In conclusion, somatic, constitutively activating TSHR mutations appear to be a major cause of TTNs (57%), while mutations in Gsalpha play a minor role (3%). The mutation negative but clonal cases indicate a probable involvement of somatic mutations other than in the TSH receptor or Gsalpha genes as the molecular cause of these hot nodules.
(Neuron, in press) as previously described (6). Cultures used for recording had been maintained in vitro for 12 to Ther. 7, 6 (1984)]. Nystatin patch electrodes [R. Horn and A. Marty, J. Gen. Physiol. 92, 145 (1988)
In our efforts to investigate the biologic role of Ha-ras oncogenes in human melanoma by Ha-ras phosphorothioate antisense oligonucleotides, we observed that antisense, sense, and scrambled control oligonucleotides at a concentration of 10 microM all similarly and strongly inhibited growth of our human melanoma target cell line SK-2 in vitro but without specific decrease of the target protein. Cell numbers with respect to the untreated control were reduced by 84% +/- 4.2% (ISD), 82.9% +/- 3.6%, and 84% +/- 3%, respectively. In vivo studies in a SCID-hu mouse model confirmed these findings. Both antisense and sense control oligonucleotides administered through osmotic pumps significantly (p < 0.006) reduced the mean tumor weight (1.5 g +/- 0.4 g and 1.8 g +/- 0.8 g, respectively) in comparison with saline-treated (5.7 g +/- 0.7 g) or untreated control animals (5.8 g +/- 1.0 g). The vascularity of oligonucleotide-treated tumors was greatly reduced. Clinical signs of oligonucleotide-related toxicity were not observed, and there was no evidence of histopathologic alterations in a variety of mouse tissues. We could demonstrate that the antimelanoma effects can be abrogated in vitro by adding basic fibroblast growth factor (bFGF). In the context of the importance of bFGF in melanocyte biology and angiogenesis, we argue in favor of an interaction between polyanionic phosphorothioate oligonucleotides and bFGF in our melanoma system. These findings stress the notion that phosphorothioate oligonucleotides may be promising antineoplastic lead compounds capable of employing antitumor effects by mechanisms other than specific inhibition of gene expression.
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