Downregulation of the transcription factor scleraxis in brain of patients with Down syndrome.

Performing gene hunting in fetal Down Syndrome (DS) brain, we found a downregulated sequence with 100% homology to the basic-helix-loop-helix transcription factor (TF) scleraxis (Scl). It was the aim of the study to evaluate Scl-mRNA steady state levels in adult DS brain with Alzheimer's disease (AD) neuropathological changes, brain of patients with AD, and controls in order to find out whether Scl-downregulation is linked to DS per se or simply to neurodegeneration, common to both disorders. Determination of Scl-mRNA steady state levels was carried out by a blotting method in frontal, parietal, temporal, occipital lobe and cerebellum. We found significantly decreased Scl-transcripts in brain of DS and AD, both, when normalized versus the house-keeping gene beta actin or total RNA. We demonstrate the significant decrease of Scl-mRNA steady state levels in the pathogenesis of DS and AD suggesting a tentative role for this transcription factor in the development of the neurodegenerative processes known to occur in both disorders. More specifically, the biological meaning of the downregulation of Scl may be the involvement in the pathogenesis of impaired neuronal plasticity and wiring observed in DS and AD, phenomena regulated by the concerted action of the many transcription factors expressed in human brain.

Deficient brain snRNP70K in patients with Down syndrome.

The small nuclear ribonucleoprotein 70K (snRNP 70K; U1-70 kDa) is an integral part of the spliceosome, a large RNA-protein complex catalyzing the removal of introns from nuclear pre-mRNA. snRNP is one of the best-studied essential subunits of snRNPs, is highly conserved and its inactivation was shown to result in complete inhibition of splicing. Applying subtractive hybridization, we found a sequence with 100% identity to snRNP absent in fetal Down syndrome (DS) brain. This observation made us determine snRNP-mRNA steady-state levels and protein levels in brains of adult patients with DS. snRNP-mRNA and protein levels of five individual brain regions of DS and controls each, were determined by blotting techniques. snRNP-mRNA steady state levels were significantly decreased in DS brain. Performing Western blots with monoclonal and human antibodies, snRNP protein levels were decreased in several regions of DS brain, although one monoclonal antibody did not reveal different snRNP-immunoreactivity. Although decreased snRNP-protein could be explained by decreased mRNA-steady state levels, another underlying mechanism might be suggested: snRNP is one of the death substrates rapidly cleaved during apoptosis by interleukin-1-beta-converting enzyme-like (ICE) proteases, which was well-documented by several groups. As apoptosis is unrequivocally taking place in DS brain leading to permanent cell loses, decreased snRNP-protein levels may therefore reflect decreased synthesis and increased apoptosis-related proteolytic cleavage.