posted on 2016-02-22, 07:13authored byMd. Mahiuddin Ahmed, Xiaolu Sturgeon, Misoo Ellison, Muriel
T. Davisson, Katheleen J. Gardiner
The Ts65Dn mouse model of Down syndrome (DS) is trisomic
for orthologs
of 88 of 161 classical protein coding genes present on human chromosome
21 (HSA21). Ts65Dn mice display learning and memory impairments and
neuroanatomical, electrophysiological, and cellular abnormalities
that are relevant to phenotypic features seen in DS; however, little
is known about the molecular perturbations underlying the abnormalities.
Here we have used reverse phase protein arrays to profile 64 proteins
in the cortex, hippocampus, and cerebellum of Ts65Dn mice and littermate
controls. Proteins were chosen to sample a variety of pathways and
processes and include orthologs of HSA21 proteins and phosphorylation-dependent
and -independent forms of non-HSA21 proteins. Protein profiles overall
show remarkable stability to the effects of trisomy, with fewer than
30% of proteins altered in any brain region. However, phospho-proteins
are less resistant to trisomy than their phospho-independent forms,
and Ts65Dn display abnormalities in some key proteins. Importantly,
we demonstrate that Ts65Dn mice have lost correlations seen in control
mice among levels of functionally related proteins, including components
of the MAP kinase pathway and subunits of the NMDA receptor. Loss
of normal patterns of correlations may compromise molecular responses
to stimulation and underlie deficits in learning and memory.