Social amnesia in mice lacking the oxytocin gene.

The development of social familiarity in rodents depends predominantly on olfactory cues and can critically influence reproductive success. Researchers have operationally defined this memory by a reliable decrease in olfactory investigation in repeated or prolonged encounters with a conspecific. Brain oxytocin (OT) and vasopressin (AVP) seem to modulate a range of social behaviour from parental care to mate guarding. Pharmacological studies indicate that AVP administration may enhance social memory, whereas OT administration may either inhibit or facilitate social memory depending on dose, route or paradigm. We found that male mice mutant for the oxytocin gene (Oxt-/-) failed to develop social memory, whereas wild-type (Oxt+/+) mice showed intact social memory. Measurement of both olfactory foraging and olfactory habituation tasks indicated that olfactory detection of non-social stimuli is intact in Oxt-/- mice. Spatial memory and behavioural inhibition measured in a Morris water-maze, Y-maze, or habituation of an acoustic startle also seemed intact. Treatment with OT but not AVP rescued social memory in Oxt-/- mice, and treatment with an OT antagonist produced a social amnesia-like effect in Oxt+/+ mice. Our data indicate that OT is necessary for the normal development of social memory in mice and support the hypothesis that social memory has a neural basis distinct from other forms of memory.

Infant vocalization, adult aggression, and fear behavior of an oxytocin null mutant mouse.

Previous studies have shown that oxytocin (OT)-deficient female mice produced by homologous recombination fail to lactate but exhibit normal parturition and reproductive behaviors. We examined the ultrasonic vocalizations of infant mice and the subsequent aggressive and fear behavior of adult male OT knockout (OT-KO) mice. Infant OT-KO mice were less vocal than wild-type (WT) control mice during separations from the mother and peers. Adult OT-KO males were generally more aggressive in isolation-induced and resident-intruder tests of aggression and less fearful in the plus maze and acoustic startle reflex tests than WT controls. Although the increase in tests of aggression was robust for OT-KO males from obligate litters (progeny of homozygous x homozygous crossings), the increase in aggression was reduced during tests for OT-KO males derived from nonobligate mating (progeny of heterozygous x heterozygous crossings), suggesting that the OT-KO genotype was not, by itself, responsible for the changes in adult behavior. We conclude that the absence of exposure to OT during development was associated with abnormalities in the development of emotional behavior.

Differential rearing affects corpus callosum size and cognitive function of rhesus monkeys.

This study investigated the effects of different rearing conditions on neural and cognitive development of male rhesus monkeys (Macaca mulatta). Infants raised individually in a nursery from 2 to 12 months of age (NURSERY, n=9) were compared to age-matched infants raised in a semi-naturalistic, social environment (CONTROL, n=11). Various brain regions were measured by MRI. Although overall brain volumes did not differ between NURSERY and CONTROL animals, corpus callosum (CC) size, measured in mid-sagittal sections, was significantly decreased in the NURSERY group. Group differences were most evident in the posterior aspects of the corpus callosum and appeared to result from changes in the number of cross-hemispheric projections rather than from a decrease in cortical gray matter volume. The decrease in corpus callosum size in the NURSERY animals persisted after 6 months of social housing in a peer-group. Rearing group differences were not found in other structures analyzed, including the hippocampus, cerebellum and anterior commissure. In cognitive testing, NURSERY animals had more difficulty acquiring the delayed non-matching to sample (DNMS) task, but showed no deficits in subsequent memory performance when a 2 or 10 min delay was imposed. The NURSERY infant monkeys were also impaired in object, but not in spatial, reversal learning, although there were no differences in a simple object discrimination task. The cognitive deficits exhibited by the NURSERY animals were significantly correlated with the alterations found in the CC. In summary, rearing environment was associated with sustained differences in cross-hemispheric projections, white matter volume and cognitive performance.

NMDA-dependent modulation of CA1 local circuit inhibition.

Whole-cell and extracellular recording techniques were used to examine local circuit inhibition in the CA1 region of the rat hippocampus in vitro. Activation, primarily of the recurrent inhibitory circuit by alvear stimulation, elicited an IPSP in pyramidal neurons that was dependent, in part, on NMDA receptor activation. Application of a tetanizing stimulus to the alveus evoked long-term potentiation (LTP) of the intracellularly recorded recurrent IPSPs. This LTP also was NMDA-dependent and was more sensitive to blockade by the NMDA antagonists 2-amino-5-phosphonovalerate (APV) and N-acetyl-aspartyl-glutamate, than the excitatory LTP produced by Schaffer collateral stimulation. With regard to APV, the sensitivity of inhibitory LTP was an order of magnitude greater. A biophysical simulation of hippocampal CA1 circuitry was used in a model of learned pattern recognition that included LTP in both excitatory and inhibitory recurrent circuits. In this model, selective blockade of inhibitory LTP produced aberrant spread of lateral excitation, resulting in confusion of normally distinguishable patterns of neuronal activity. Consideration is given to the possibility that selective disruption of NMDA-dependent modulation of local circuit inhibition may serve as a model for some aspects of dysfunction associated with NMDA-antagonist exposure and schizophrenia.