Neuropeptide Y in cortex and striatum. Ultrastructural distribution and coexistence with classical neurotransmitters and neuropeptides.
Review
Overview
abstract
NPY-neurons in the striatum and cortex have many morphological and chemical features in common. They are intrinsic, medium sized, aspiny and exhibit ultrastructural characteristics typical of neurons undergoing active synthesis and release of peptides. Most of the NPY-neurons in the two regions coexist with somatostatin, exhibit high levels of NADPH-diaphorase and are resistant to degeneration associated with Huntington's disease. Ultrastructural analysis suggests that the ensheathment by glia and sparsity of asymmetric (putatively excitatory) inputs may render NPY neurons resistant to excitotoxicity. Although NPY-neurons receive few inputs, they make numerous contacts with dendrites within a small region of the neuropil. Among their targets are GABAergic neurons. These NPY-receptive GABA neurons differ from other GABAergic neurons in the vicinity in that they receive few other inputs along their somata and proximal dendrites. This suggests that NPY may exert more influence on a specific class of GABAergic neurons. Many more of the NPY-terminals are found at sites that would be strategic for the simultaneous modulation of the release of transmitters and postsynaptic responses. The differences among NPY-neurons in the striatum versus cerebral cortex are mainly chemical. Most notably, the NPY-neurons are GABAergic in the cortex and not GABAergic in the striatum. In addition, some of the NPY-axons in the ventral portions of striatum and cerebral cortex may be catecholaminergic, and thus originate in brainstem areas recognized to contain NPY and epinephrine or norepinephrine. NPY- and catecholaminergic fibers converge onto same dendrites. Thus, the two transmitters may interact through intercellular biochemical pathways postsynaptically. Finally, the sites where the two fibers directly contact each other may be where NPY stimulates the turnover of dopamine.