MRI Determination of Axonal Transport Rates in Mouse CNS
Pautler, Robia G.   
Baylor College of Medicine, Houston, TX, United States

It is possible to tract trace neuronal pathways in vivo in the central nervous system (CMS) utilizing a technique that we developed, Manganese Enhanced Magnetic Resonance Imaging (MEMRI) tract tracing. Manganese ion, Mn2+, is a calcium analogue and can enter neurons through calcium (Ca2+) channels. Furthermore, Mn2+ is transported along microtubules via fast axonal transport and is also paramagnetic, rendering it MRI detectable in spin-lattice (H)-weighted MRI images. It is therefore possible to utilize MRI to repeatedly measure dynamic changes in signal intensity, relfective of fast axonal transport of Mn2+ ion, within the same animal before and during disease progression. Axonal transport deficits have been observed in flies and cultured rodent neurons exposed to excess amyloid precursor protein (APR) or amyloid-beta, but neither the molecular basis of the transport deficit nor the temporal relationship of the transport deficit and the acquisition of Alzheimer's Disease (AD) are known. We hypothesize that: 1) Normal aging mice will exhibit declines in axonal transport rates throughout the brain as aging ensues 2) The presence of excess APR causes a reduction in axonal transport prior to the formation of neuritic plaques and 3) Impairment in the sequestering of Mn2+ into the endoplasmic reticulum results in the observed early decline in axonal transport rates. We plan to test our hypotheses through the following Specific Aims:
Aim 1 : We will determine longitudinally the in vivo axonal transport rates of Mn2+ ion in the CMS in control mice and an APR overexpressing mouse model of AD (TG 2576) as the animals age;
Aim 2 : We will resolve the mechanism of this axonal transport deficit by determining which steps in Mn2+ uptake and transport are affected in normal and TG 2576 mice as aging ensues.