Project
5:
CNTF Promotes Neuronal Survival and
Axonal Sprouting
Investigator: Dr. John Watt
Neurotrophic factors can prevent and reverse neuronal
cell death associated with CNS disorders. Consequently,
neurotrophic factors in general and ciliary neurotrophic
factor (CNTF) in particular continues to be considered
attractive therapeutic targets for the treatment of
a variety of acute and chronic neurodegenerative conditions.
However, despite the potential clinical importance
of CNTF, little is known regarding its expression
in adult brain and the mechanisms of its actions in
vivo. The long term goal of my laboratory
is to gain a greater understanding of the mechanisms
by which neurotrophins and related cytokines promote
neuronal survival and process outgrowth in the damaged
CNS. Our central hypothesis is that CNTF
acts as both a neuronal survival factor and sprouting
factor for magnocellular neurosecretory neurons in
vivo. In support of this hypothesis, we have demonstrated
an endogenous glial source of CNTF in the supraoptic
nucleus of the magnocellular neurosecretory system
(MNS). Results of immunocytochemical and in situ hybridization
analysis demonstrated that axotomy significantly increased
CNTF expression in both the axotomized supraoptic
nucleus and in the contralateral intact supraoptic
nucleus from which axonal sprouting originates. Furthermore,
we have shown activation of Signal Transducer and
Activator of Transcription (STAT) proteins in response
to both axotomy and following direct infusion of rat
recombinant CNTF (rrCNTF) in the supraoptic nucleus
in vivo. We will apply a novel systems biology
approach to investigate the role of CNTF and
specific signal transduction pathways in promoting
post-injury neuro-restorative functions. The innovation
of the proposed studies lies in our ability to induce
an apoptotic response in identified magnocellular
neurons through infundibular nerve crush injury, monitor
the neuronal decline through external physiological
measures, and then reverse that decline through direct
intervention with exogenous rrCNTF. This model will
also allow detailed analysis of the specific signaling
pathways evoked as a result of both the injury and
the CNTF treatment and the subsequent downstream induction
of other growth factors and cytokines which support
neuronal survival and process outgrowth in young v
mature rats. Elucidating the mechanisms by which CNTF
mediates neuronal survival either through direct actions
on neurons or indirectly through glial activation
will provide a significant advancement
in our understanding of the mechanisms by which neurotrophin-mediated
cellular activities are controlled throughout the
CNS. Moreover, our findings will contribute to the
knowledge base necessary for the development of intervention
strategies for those conditions where CNTF or other
growth factors may contribute to neuro-restorative
functions. |
