The EPAC (exchange protein directly activated by cAMP) proteins are GEFs (guanine nucleotide-exchange factors) that activate Rap GTPases upon binding to cAMP. The involvement of these proteins in a number of diseases, neurodegenerative, inflammatory and metabolic, has started to show how they may prove to be important targets for therapeutic intervention. We first became interested in EPAC when we discovered that the expression levels of both EPAC1 and EPAC2 were altered in those regions of the brain associated with Alzheimer's disease [McPhee, Breslin, Kewney, MacKenzie, Cooreman, Gibson and Hammond (2004) International Patent number WO 2004/096199 A2]. It was known that compounds could be designed to be selective for EPAC over PKA (protein kinase A); however, these compounds were all based around the core structure of cAMP. We decided to screen a small compound library (10 000 compounds) to investigate the possibility of developing a compound series outside of the cAMP structure. We subsequently developed a novel, high-throughput screen based on the displacement of [ 3 H]cAMP from the EPAC cAMP-binding site and identified small molecule hits from the Scottish Biomedical Lead Generation Library. These compounds selectively bind to the cAMP-binding sites of EPAC1 and EPAC2 and are structurally dissimilar to cAMP. They have similar affinities for both EPAC1 and EPAC2 and have a high degree of specificity for EPAC over PKA. We believe that these compounds provide a valuable starting point for a drug optimization programme.
The thalamic pulvinar and the lateral intraparietal area (LIP) share reciprocal anatomical connections and are part of an extensive cortical and subcortical network involved in spatial attention and oculomotor processing. The goal of this study was to compare the effective connectivity of dorsal pulvinar (dPul) and LIP and to probe the dependency of microstimulation effects on task demands and spatial tuning properties of a given brain region. To this end, we applied unilateral electrical microstimulation in the dPul and LIP in combination with event-related BOLD fMRI in monkeys performing fixation and memory-guided saccade tasks. Microstimulation in both dPul and LIP enhanced task-related activity in monosynaptically-connected prefrontal cortex and along the superior temporal sulcus (STS) as well as in extrastriate cortex. Both dPul and LIP stimulation also elicited activity in several cortical areas in the opposite hemisphere, implying polysynaptic propagation of excitation. LIP microstimulation elicited strong activity in the opposite homotopic LIP while no homotopic activation was found during dPul stimulation. Despite extensive activation along the intraparietal sulcus evoked by LIP stimulation, there was a difference in frontal and occipital connectivity elicited by posterior and anterior LIP stimulation sites. Comparison of dPul stimulation with the adjacent but functionally distinct ventral pulvinar also showed distinct connectivity. On the level of single trial timecourses within a region, most microstimulation regions did not show task-dependence of stimulation-elicited response modulation. Across regions, however, there was an interaction between the task and the stimulation, and task-specific correlations between the initial spatial selectivity and the magnitude of stimulation effect were observed. Consequently, stimulation-elicited modulation of task-related activity was best fitted by an additive model scaled down by the initial response amplitude. In summary, we identified overlapping and distinct patterns of thalamocortical and corticocortical connectivity of the two key visuospatial areas, highlighting the dorsal bank and fundus of STS as a prominent node of shared circuitry. Spatial task-specific and partly polysynaptic modulations of cue and saccade planning delay period activity in both hemispheres exerted by unilateral pulvinar and parietal stimulation provide insight into the distributed interhemispheric processing underlying spatial behavior.HighlightsElectrical stimulation of pulvinar and LIP was used to study fMRI effective connectivityBoth regions activated prefrontal cortex and the dorsal bank of superior temporal sulcusActivations within and across hemispheres suggest polysynaptic propagationStimulation effects show interactions between task- and spatial selectivityStimulation effects are best fitted by an additive model scaled by the initial response
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