The potassium-chloride transporter KCC2 : a new target for the treatment of neurological diseases – KCC2-SCI

A decrease in synaptic inhibition –disinhibition- appears to be an important substrate in several neuronal disorders, such as spinal cord injury (SCI), neuropathic pain... Glycine and GABA are the major inhibitory transmitters in the spinal cord. An important emerging mechanism by which the strength of inhibitory synaptic transmission can be controlled is via modification of the intracellular concentration of chloride ions ([Cl-]i) to which receptors to GABA/glycine are permeable. Briefly, a low [Cl-]i is a pre-requisite for inhibition to occur and is maintained in healthy neurons by cation-chloride co-transporters (KCC2) in the plasma membrane, which extrude Cl-. We showed recently (Nature Medicine, accepted for publication) that these transporters are down-regulated after SCI, thereby switching the action of GABA and glycine from inhibition to excitation; this can account for both SCI-induced spasticity and chronic pain. KCC2 transporters therefore appear as a new target to restore inhibition within neuronal networks in pathological conditions. The present project aims at reducing spasticity and chronic pain after SCI by up-regulating KCC2.
An important part will consist in identifying new compounds that increase the cell surface expression and/or the functionality of KCC2. Two strategies are considered. 1) Serotonin and BDNF will be tested on the basis of preliminary experiments and/or previous reports in other areas of the central nervous system indicating that these two compounds may affect the expression of KCC2. 2)Testing a large amount of compounds available in a library (“blind test”) to sort out KCC2-modulating molecules. This task can only be done in vitro on an assay that enables to easily visualize and quantify cell surface expression of KCC2, in response to these molecules (HEK293 cells). The few compounds isolated at the end of this task will then be tested on cultures of motoneurons (both mouse motoneurons and human motoneurons derived from induced pluripotent cells) and characterized further (potential toxicity, ability to cross the Brain Blood Barrier and effect on internalization and endocytosis of KCC2).
The selected candidate compounds will enter into the in vivo validation phase aimed at increasing the expression of KCC2 following spinal cord injury (SCI; both contusion and complete spinal cord transection). The selected hits will be applied by intrathecal injections in SCI rats and their effects on KCC2 expression in the plasma membrane of motoneurons will be tested by means of western blots and immunohistochemistry. Their efficacy in increasing the cell-surface expression of KCC2 will also be tested electrophysiologically in vitro (i.e. their ability to hyperpolarize ECl). Functionally, their efficacy in reducing both SCI-induced spasticity and chronic pain will be assessed.
Genetic tools will be used to increase the expression of KCC2 in some spinal neurons. This task will be done in collaboration with teams in the USA. Lentiviral vectors aimed at increasing KCC2 in the host cells, after parenchymal injection, have been developed in San Diego. A transgenic mouse model with a conditional tamoxifen-induced overexpression of KCC2 has been developed in Pittsburgh. The rationale for this part of the project is to use these genetic tools in the chronic phase of SCI to reduce spasticity and chronic pain.
The last part of the project will focus on more fundamental issues regarding the relationship between the SCI-induced downregulation of KCC2 and the development of spasticity and chronic pain.
The significance of the expected results goes far beyond the scope of SCI, since altered chloride homeostasis resulting from mutation or dysfunction of cation-chloride cotransporters has been implicated in various neurological disorders such as, for instance, ischemic seizures neonatal seizures and temporal lobe epilepsy.