Participation of catecholamines and NO in regulation of apoptosis of nonapeptidergic neurons of neonatal rat pups

Abstract

Effects of catecholamines (CA) and the character of interaction of CA and NO in regulation of apoptosis were studied in vasopressinergic (VP-ergic) neurons of supraoptic (SON) and paraventricular (PVN) nuclei of rat pups in early postnatal ontogenesis. To study role of CA in regulation of programmed cell death in SON and PVN in the course of embryonal development, pregnant female rats were intraperitoneally injected daily from the 13th to the 20th day with αMPT—a blocker of CA synthesis. The second group of pregnant rats was injected from the 13th to the 20th day with the same volume of saline. The third group was composed of intact animals. The born rat pups were sacrificed at the 3rd and 15th days of life. Caspase 9, Bcl-2, tyrosine hydroxylase, and neuronal NO-synthase (nNOS) in SON and PVN neurons were revealed immunohistochemically, and the amount of immunoreactive substance in neuronal bodies was estimated using the computerized digital analyzer of TV image and Video Test software. Caspase-9 was shown to play an important role in postnatal formation of cellular composition of hypothalamic nonapeptidergic centers by leading to initiation of apoptosis and rejection of “useless” postmitotic SON and PVN neurons. Survival of “useless” nonapeptidergic neurons in early postnatal ontogenesis seems to be connected with antiapoptotic action of Bcl-2. Death of postmitotic neurons, and therefore formation of cellular composition begins earlier and, accordingly, is completed earlier in SON, in which neurons were noted to have a considerable decrease of the caspase-9 expression and, therefore, also a decrease of intensity of neuronal death via caspase-9-dependent pathway. In PVN, neurons continue to die also at the 15th day of rat life, i.e., almost two weeks later than in SON. The observed high correlation between the content of nNOS, caspase-9, and Bcl-2 in the SON and PVN neurons of intact rats of both age groups allows suggesting participation of NO in realization of apoptosis in the course of early postnatal development. The increase of nNOS expression in hypothalamic neurons as a result of disturbances in CA-ergic innervation in embryogenesis might be a possible cause of the long preserved enhancement of expression of apoptosis signal proteins. It can be suggested that CA participate in morphogenesis of hypothalamic neurons by increasing expression of nNOS in neurons and thereby affecting expression of apoptotic proteins.