Behavioral characteristics of vasopressin-deficient rats (Brattleboro strain)

Electroencephalographic and early communicative abnormalities in Brattleboro rats

Reductions in the levels of the neuropeptide vasopressin (VP) and its receptors have been associated with schizophrenia. VP is also critical for appropriate social behaviors in humans as well as rodents. One of the prominent symptoms of schizophrenia is asociality and these symptoms may develop prodromally. A reduction in event-related potential (ERP) peak amplitudes is an endophenotype of schizophrenia. In this study, we use the Brattleboro (BRAT) rat to assess the role of VP deficiency in vocal communication during early development and on auditory ERPs during adulthood. BRAT rats had similar vocal communication to wild-type littermate controls during postnatal days 2 and 5 but the time between vocalizations was increased and the power of the vocalizations was reduced beginning at postnatal day 9. During adulthood, BRAT rats had deficits in auditory ERPs including reduced N40 amplitude and reduced low and high gamma intertrial coherence. These results suggest that the role of VP on vocal communication is an age-dependent process. Additionally, the deficits in ERPs indicate an impairment of auditory information processing related to the reduction in VP. Therefore, manipulation of the VP system could provide a novel mechanism for treatment for negative symptoms of schizophrenia.

The neuroendocrine basis of social recognition

All social relationships are dependent on an organism's ability to remember conspecifics. Social memory may be a unique form of memory, critical for reproduction, territorial defense, and the establishment of dominance hierarchies in a natural context. In the laboratory, social memory can be assessed reliably by measuring the reduction in investigation of a familiar partner relative to novel conspecifics. The neurohypophyseal neuropeptides oxytocin and vasopressin have been shown to influence a number of forms of social behavior, including affiliation, aggression, and reproduction. This article reviews vasopressin and oxytocin effects on social cognition, particularly the acquisition and retention of social recognition in rats and mice. Studies in rats have demonstrated that vasopressin in specific neural pathways, such as the lateral septum, is necessary for social recognition. As vasopressin facilitates recall when given after an initial encounter, the peptide appears important for the consolidation not the acquisition of a social memory. Although oxytocin has complex effects on social memory in rats, mice with a null mutation of the oxytocin gene are completely socially amnestic without other cognitive deficits evident. As oxytocin given centrally before but not after the initial encounter restores social recognition in these mutant mice, the neuropeptide appears critical for the acquisition rather than the consolidation phase of memory. Oxytocin's effects on social memory are mediated via a discrete cell population in the medial amygdala. These findings support the hypothesis that vasopressin and oxytocin are essential for social memory, although they appear to influence different cognitive processes and may modulate different neural systems. (c) Elsevier Science.

The molecular neurobiology of stress--evidence from genetic and epigenetic models

Knowledge of the genetic and molecular events underlying the neuroendocrine and behavioural sequelae of the response to stress has advanced rapidly over recent years. The response of an individual to a stressful experience is a polygenic trait, but also involves non-genetic sources of variance. Using a combination of top-down (quantitative trait locus [QTL] and microarray analysis) and bottom-up (gene targeting, transgenesis, antisense technology and random mutagenesis) strategies, we are beginning to dissect the molecular players in the mediation of the stress response. Given the wealth of the data obtained from mouse mutants, this review will primarily focus on the contributions made by transgenesis and knockout studies, but the relative contribution of QTL studies and microarray studies will also be briefly addressed. From these studies it is evident that several neuroendocrine and behavioural alterations induced by stress can be modelled in mouse mutants with alterations in hypothalamic-pituitary-adrenal axis activity or other, extrahypothalamic, neurotransmitter systems known to be involved in the stress response. The relative contribution of these models to understanding the stress response and their limitations will be discussed.

The vasopressin deficient Brattleboro rats: a natural knockout model used in the search for CNS effects of vasopressin

Behavioral neuroscience is using more and more gene knockout techniques to produce animals with a specific deletion. These studies have their precedent in nature. A mutation may result in a limited genetic defect, as seen in the vasopressin (VP) deficiency in the Brattleboro rat. The mutation is in a single pair of autosomal loci, and the sequences of VP gene from wild-type and homozygous Brattleboro rats are identical except for a single nucleotide deletion in the second exon. The deletion results in the synthesis of an altered VP precursor that is unable to enter the secretory pathway. The genetic disturbance results in a central diabetes insipidus comparable to that found in humans. Starting with our work during the early 1970s we found that the genetic defect in the availability of VP causes deficits in central nervous system (CNS) functions. Behavioral processes from cognition to drug tolerance appeared to be disturbed by the absence of VP, but not all behaviors are affected. The specificity of the absence of VP in causing behavioral deficits is shown in many cases. However, certain deficits are due to genetic factors other than the deletion of the VP gene. The picture is further complicated by differences in testing conditions, the absence of proper controls, i.e. heterozygous and wild-type Brattleboro rats, sex, compensation phenomena, and the absence of neuropeptides co-localized with VP. Interestingly, an age dependent spontaneous shunt to a heterozygous phenotype in vasopressinergic neurons might also compensate for the disturbance. Accordingly, findings in knockout animals should be interpreted with caution. One should realize that brain functions are modulated by multiple neuropeptides and that neuropeptides possess multiple CNS effects.

Altered alertness of vasopressin-secreting transgenic mice

We evaluated behavior and cognitive performance in a line of transgenic mice that overexpress the rat gene for vasopressin. Open field testing revealed greatest habituation in homozygous mice. Passive avoidance performance indicated equal learning and memory ability of transgenic compared to normal mice. Drinking behavior following exposure to 10% sucrose solution suggested diminished neophobia in homozygous mice. These observations are consistent with enhanced attention and alertness in the transgenic animals and support prior observations on the effects of vasopressin on behavior and cognitive function.

Microdialysis administration of vasopressin into the septum improves social recognition in Brattleboro rats

The role of septal arginine vasopressin (AVP) in a social recognition test was investigated in both homozygous Brattleboro (HO-DI) and normal Long-Evans rats. To do this, the duration of investigation of conspecific juveniles by untreated adult males of both rat strains was measured before and after inter exposure intervals of 30 and 120 min. Additionally, a microdialysis administration technique was used to administer synthetic AVP (0.2 or 2.0 ng) or its V1 receptor antagonist d(CH2)5Tyr(Me)AVP (5.0 ng) into the mediolateral septum concomitantly with the behavioral test. Untreated HO-DI rats showed an impaired social recognition compared with untreated Long-Evans rats. A similarly impaired performance was observed after V1 receptor antagonist treatment of Long-Evans rats. Microdialysis administration of synthetic AVP, on the other hand, significantly improved social recognition in both rat strains. The data suggest that endogenous AVP in the septal brain area is critically involved in the acquisition, storage, and/or recall of olfactory cues in rats.

Vasopressin deficiency and blood glucose interactions on passive avoidance behavior

The performance of a passive avoidance task (measured for two trials based upon number of complete step-downs and latency to respond) and blood glucose levels were examined in five groups of animals. The groups included vasopressin-deficient (DI) and vasopressin-containing (LE) rats under ad lib (AL) and food-restricted (FR) conditions, as well as DI-FR animals provided with access to an 8% sucrose solution (SUC). In the AL condition, no significant differences were found between DI and LE animals in either step-down occurrences or blood glucose levels. However, the DI animals were significantly slower in latency to respond in trial 1. With FR, the LE animals resembled the LE-AL animals in both passive avoidance behavior and blood glucose levels. The DI-FR animals that were not provided with SUC showed an impairment in passive avoidance behavior and low blood glucose levels, whereas DI-FR animals provided with SUC showed an amelioration of passive avoidance deficiencies and had blood glucose levels comparable to AL animals and LE-FR animals. On trial 2, a significant negative correlation was found between number of step-down occurrences and blood glucose levels, and a significant positive correlation was found between latency to respond and blood glucose levels.(ABSTRACT TRUNCATED AT 250 WORDS)

Decreased performance in a delayed alternation task by rats genetically deficient in vasopressin

Acquisition and retention of a delayed alternation task by rats genetically deficient in vasopressin (AVP) due to the homozygous occurrence of the Brattleboro diabetes insipidus (DI) gene (M520/DI) were compared to the response of rats that were heterozygous (M520/HZ) or normal (M520/N) with respect to the DI gene. No significant difference in the adaptation to the apparatus was observed between the groups. However, the rate at which the M520/DI rats acquired the alternation task was significantly slower than the acquisition rates of M520/HZ and M520/N rats. In addition, the maximum intertrial interval reached by the M520/DI rats was significantly shorter than the intertrial intervals reached by the M520/HZ and M520/N rats, indicating the ability to retain information was impaired in the M520/DI rats. These results are consistent with the hypothesis that AVP modulates the acquisition and retention of information for normal memory processes.

The behavior of the homozygous and heterozygous sub-types of rats which are genetically-selected for diabetes insipidus: a comparison with Long Evans and Wistar stocks

Several aspects of spontaneous and conditioned behavior (food and water intake, locomotion and emotionality, passive and active avoidance acquisition and retention) of standard (albino and pigmented) rats, and rats heterozygous (HEDI) and homozygous (HODI) for diabetes insipidus, are reviewed. As would be expected, HODI rats have been repeatedly found to consume far more fluid than either HEDI or control rats. Pigmented rats appear to be more active than albinos. HODI rats exhibit less marked emotional responses than do control rats, among which the pigmented ones exhibit the highest emotionality. Light aversion is more evident in albino than in pigmented rats. No differences are found among HEDI, HODI and normal Long Evans rats. It is quite difficult to provide a clear-cut statement concerning inter-strain differences in passive avoidance behavior, possibly because of the variety of techniques employed. In any case, HODI rats do not perform worse than normal controls do. In one-way active avoidance paradigms, pigmented rats perform better than albinos, and the performance of HODI rats does not differ from that of controls. In two-way avoidance paradigms, albinos appear to outperform pigmented rats. Once again, there are no obvious differences between HODI and control animals. In addition to indicating that HODI rats may actually be less emotional than the other groups of rats reviewed here, the studies described once again fail to confirm the previously alleged functions of vasopressin in memory consolidation.

Septohippocampal system and the prelimbic sector of frontal cortex: a neuropsychological battery analysis in the rat

Rats with lesions in the posterodorsal septal area (aimed at transecting the precommissural fornix) and rats with lesions in the prelimbic sector of the medial frontal cortex were tested postoperatively on a neuropsychological test battery comprised of the following tasks: time-spent-eating in two adaptation boxes, time-to-emerge and ambulation in an open field, general activity, contingently-reinforced (continuous) and schedule-specific (delayed non-matching-to-sample) T-maze alternation, visual and olfactory discrimination in a T-maze, temporal alternation (response patterning) and tactile Go/No-Go discrimination in a runway, approach-avoidance conflict in the runway, step-through inhibitory avoidance, one-way active avoidance, two-way active avoidance, and conditioned taste aversion. It was found that: (1) rats with septal (SEP) lesions spent more time eating than control (CON) rats and rats with lesions in prelimbic cortex (PRE). PRE rats did not differ from CON rats; (2) PRE rats emerged into an open field faster, and spent less time in home cage than CON and SEP rats. SEP rats stayed in home cage less than CON rats. PRE and SEP rats crossed more squares in the open field than CON rats; (3) SEP and PRE rats were more active than CON rats; (4) SEP rats performed the contigently-reinforced and schedule-specific T-maze alternation tasks worse than PRE rats, and PRE rats performed these tasks worse than CON rats. PRE, but not SEP, rats showed improvement with continued practice at brief intertrial and interrun intervals.(ABSTRACT TRUNCATED AT 400 WORDS)

Vasopressin injections impair working memory in a delayed matching to sample task in rats

Effects of vasopressin were measured in a nonspatial working memory task: food-reinforced, delayed matching to sample. Subcutaneous injections of 0.2 microgram of lysine vasopressin (LVP) or saline were alternately administered to Sprague-Dawley rats after the presentation of the sample and compared to the effect of the same treatments given to a yoked control group of rats. Different durations of sample presentation (5 and 30 min) and various retention intervals (10 min, 3 h, 24 h) were selected. The results showed that LVP never facilitated retention performance: there was no improvement under conditions of weak memory (short presentation of the sample and long retention interval); moreover LVP abolished the facilitation normally obtained when either the length of the sample presentation was longer or the duration of the retention interval was shorter. The performance after the injection of the peptide was differentially impaired, according to brightness of the sample which had been presented: after the presentation of the white box, LVP injections lead to more errors and after that of the black one the treatment induced an increase in latencies of response. All these data may suggest that the physiological consequences of hormonal modifications triggered by the LVP injection are processed along with the stimuli of the learning episode and interfere with the learned positive value of the sample.

The effect of AVP and DGAVP on the exploratory activity of rats

The effects of [8-L-arginine] vasopressin (AVP) and desglycinamide [8-L-arginine] vasopressin (DGAVP) were tested on the exploratory activity of adult male rats in a novel environment. The inherited individual differences in the non-specific excitability level of the animals were ascertained prior to the drug administration and the rats were then distributed evenly into the experimental groups. One half of each groups contained the less excitable and the other the more excitable animals. The peptides or saline were injected every other day--altogether 4 times--in a dose of 5 micrograms/kg/ml subcutaneously, 40 min before starting the experiments. The exploratory activity in the novel environment was observed for 15 min. AVP and DGAVP, which differ in their peripheral endocrine activities, had opposite effects on the behavior in a novel environment: AVP, with its wide spectrum of peripheral effects, decreased the exploratory activity, whereas DGAVP, with minimal peripheral effects, increased the exploratory activity slightly. This basic response to the administration of peptides was influenced by the type of inherent non-specific excitability level. The depressive action of AVP was more pronounced in the more excitable rats, whereas DGAVP significantly stimulated the less excitable animals. It is concluded that the inhibitory effect of AVP is mainly due to its peripheral endocrine, especially hemodynamic, effects, whereas DGAVP is supposed to increase arousal, which is responsible for differences in the animals' performance with regard to their inherited non-specific excitability levels.

Conditioned taste aversion in vasopressin-deficient rats (Brattleboro strain)

Brattleboro rats are homozygous for diabetes insipidus (DI), lacking the ability to synthesize vasopressin. Previous studies reported learning deficits in DI rats on passive avoidance tasks using footshock. Other studies, however, could not replicate these results. In two experiments, we studied the learning of DI and control Long Evans (LE) rats in a different avoidance paradigm: conditioned taste aversion (CTA). In the first experiment a mild CTA to saccharin was established gradually using low levels of an illness-inducing agent (lithium chloride). In the second experiment a strong CTA was established in one acquisition trial and the extinction of the conditioned aversion was followed for 12 trials. The two experiments found no differences between the DI and LE rats in either the magnitude or the rate of acquisition and extinction of the CTA. These results suggest that vasopressin is not involved in the acquisition and retention of CTA, and support previous studies indicating that vasopressin may not be involved in avoidance learning.

Behavioral characteristics of Roman high avoidance rats homozygous for diabetes insipidus (RHA: di/di)

These experiments studied the behavior of an inbred strain of vasopressin-deficient rat, the Roman high avoidance rat homozygous for diabetes insipidus (RHA: di/di). The RHA: di/di rat has been bred to be congenic with the parent normal Roman high avoidance (RHA: +/+) strain, differing from it only by the gene(s) coding for diabetes insipidus. Therefore, the RHA: +/+ strain represents an improved model system with which to study the behavioral effects of vasopressin-deficiency, given recent findings suggesting that considerable behavioral variation exists within the Long-Evans derived Brattleboro strain of vasopressin-deficient rat. We examined the behavior of RHA: di/di and RHA: +/+ rats in the open field and on tests of approach-avoidance, spatial memory and passive avoidance. RHA: di/di rats showed retarded habituation of ambulation and elevated incidence of rearing, defecation, and ambulation in the central area of the open field, relative to RHA: +/+ rats. The RHA: di/di and RHA: +/+ rat did not differ on measures of adaptation to a novel straight runway and both groups increased latencies to enter the goal box of the runway following shock, indicating memory. RHA: di/di rats did exhibit substantial recovery of goal-approach following shock, whereas RHA: +/+ rats did not. Both groups were able to solve a delayed non-match to sample task to receive reward. RHA: di/di rats showed a slower acquisition of the contingency and significantly faster run times of choice trials of the paired run procedure. No differences were evident between groups in memory of passive avoidance. The results of these experiments suggest that hereditary deficiency of vasopressin may influence physiological processes which determine arousal or attentiveness. The effects of vasopressin deficiency on performance of memory-indicating tasks appears to be secondary to modulations in arousal.

Behavioral variability within the Brattleboro and Long-Evans rat strains

Samples of genetically diabetes insipidus (DI) and normal (NO) rats were obtained from American suppliers (Rochester (RO)/DI and NO) and from the colony maintained at Charing Cross Hospital in London (Charing Cross (CC)/DI and NO) to test the hypothesis that the behavior of vasopressin-deficient Brattleboro (DI) and possibly normal Long-Evans rats may vary significantly between different colonies. DI rats of both colonies exhibit longer latencies to emerge into an open field than do NO rats. RO/DI and CC/DI rats acquire goal-approach behavior in a straight runway at similar rates. Following shock in the runway goal box, however, RO/DI rats exhibit marked recovery of running behavior relative to CC/DI rats over the ten post-shock sessions. All DI animals show reductions in goal-approach speed on the first post-shock trial, indicating that the aversive experience is remembered. CC/NO rats acquire goal-approach behavior more slowly than RO/NO rats, but neither NO group shows substantial recovery of goal approach behavior following shock. CC/DI rats showed impaired acquisition of a delayed non-match to sample task relative to RO/DI rats. All groups demonstrated the ability to utilize representational memory to solve the delayed non-match to sample problem once the contingency was learned. The results indicate that DI and normal Long-Evans rats from different colonies show marked differences in behavior. Since differences between DI and normal rats on tests indicating memory are not consistent across colonies, it is unlikely that vasopressin deficit is solely responsible for memory deficiencies. However, vasopressin deficiency may result in changes in temperament.

A mnemonic role for vasopressin: the evidence for and against

This review critically evaluates the animal and human research concerning vasopressin's putative mnemonic role. Weaknesses in the interpretations of the early animal experiments as well as the implications of the later inconsistent findings are discussed. It is concluded that both the initial enthusiasm and the subsequent skepticism concerning this hypothesized role were premature. This conclusion applies equally to the human research. A review of these studies reveals that almost all of the negative reports involved cognitively-impaired individuals. The relatively few studies that have been conducted concerning vasopressin's effects in unimpaired human subjects are consistent with the hypothesis that vasopressin does affect cognition, though both the mechanism of action and the specific cognitive processes which are altered have yet to be elucidated.

Hypothalamic neuropeptides and memory

Vasopressin and oxytocin exert pronounced effects on behavior by a direct action on the brain. A single injection of vasopressin results in a long-term inhibition of extinction of a conditioned avoidance response suggesting that vasopressin triggers a long-term effect on the maintenance of a learned response, probably by facilitation of memory processes. In addition vasopressin improves passive avoidance behavior, facilitates retention of sexually motivated T-maze choice behavior in male rats, delays extinction of an appetitive discrimination task, affects approach behavior to an imprinting stimulus in ducklings, delays the postcastration decline in copulatory behavior in male rats, prevents or reverses amnesia induced by electroconvulsive shock, CO2 inhalation, pentylenetetrazol or puromycin. The majority of these effects may be explained by stimulatory influences of vasopressin on memory processes. Generally oxytocin exerts effects which are opposite to those of vasopressin and it has been suggested that oxytocin may be an amnesic neuropeptide. Evidence has been obtained that endogenous vasopressin and oxytocin play a physiological role in brain processes related to memory. Various limbic system structures seem to act as the anatomical substrate for the behavioral effects of vasopressin and different neurotransmitter systems seem to be involved. It is postulated that in case vasopressin affects retrieval processes the site of action is located in the amygdala and the dentate gyrus of the hippocampal complex with dopamine and serotonin as the respective neurotransmitter systems involved.(ABSTRACT TRUNCATED AT 250 WORDS)

Vasopressin and brain development: studies using the Brattleboro rat

Anomalies in hormonal and neurotransmitter status during early stages of brain development, can lead to lifespan alterations in the functioning of central systems. The neuropeptide vasopressin is nowadays recognized as a putative neurotransmitter, after years of study on its neurosecretory hormonal aspect in water metabolism. Since vasopressin is moreover present early in the brain, and has various mitogenic, metabolic and physiological actions, one might expect vasopressin to be of importance for normal brain development as well. Indeed, the absence of brain vasopressin in the Brattleboro mutant rat coincides with impaired brain development, and some physiological and behavioral defects of these rats are not adjusted by treatment with vasopressin. Regionally the cerebellum seems to be the most affected brain area, both morphologically and biochemically. Only when vasopressin supplementation was done prenatally, this disturbed growth could be restored, which suggests an early role for vasopressin in neurogenesis. Enhanced levels of vasopressin during the perinatal period on the other hand, have been shown to affect permanently the 'setting' of peripheral vasopressin functions in cardiovascular and renal regulatory systems. It is not excluded as yet that after such treatments central organization of vasopressin systems is not impaired as well.

Altered emotionality of the vasopressin-deficient Brattleboro rat

Observation of open field behavior of vasopressin-deficient (DI) and normal Long-Evans rats indicated elevated levels of open field activity for the DI rats. Exposure to an acoustic stressor resulted in decreased activity in both groups of animals but with a lesser effect on the DI rat. Handling prior to experimentation diminished the differences between DI and normal rats. Although both groups displayed an equivalent rise in plasma corticosterone in response to the open field, the addition of the acoustic stressor resulted in greater elevation of corticosterone in the normal animals. The behavioral and hormonal data suggest that the DI rat exhibits decreased emotional reactivity. Measurement of brain neurotransmitter levels revealed higher concentrations of serotonin, norepinephrine and dopamine in the limbic regions of the DI rat. These alterations may underlie the behavior reflecting decreased emotionality of the DI rat. In turn, the altered emotional state may be the basis for alteration in performance on learning/memory tasks of these animals. Thus, vasopressin effects on the retrieval and/or consolidation of information may not be direct but rather through its ability to influence the emotional state of the animal.

Neuropeptide effects on brain development to be expected from behavioral teratology

A wealth of literature has become available about lasting functional consequences of perinatal psychotropic drug exposure, having affected brain development in a subtle rather than gross structural way (behavioral teratology or functional neuroteratology). The underlying mechanism is thought to result from changing levels of neurotransmitters during neurogenesis induced by these neuroactive drugs, which as a consequence appears to lead to impaired cell acquisition and receptor setting i.e., to irreversible changes in particular neuronal circuitries. Neuropeptides are true candidates for a neurotransmission function as well, and are also present early in brain development. As for the classical neurotransmitters, a role for neuropeptides in the growth and functional organization of the nervous system, might therefore be expected. Anomalies in neuropeptide levels also would lead to functional neuroteratology. Although not overwhelming, several studies support this view, and the current state is summarized in this paper: a trophic role for some neuropeptides as well as neuroteratological effects upon perinatal manipulation for others were revealed. However, more detailed studies are necessary, certainly also because of the crying need for exposing possible adverse effects at a time when clinical applications of neuropeptides and their analogues are becoming a mode.

Operant behavior and drinking suppression in vasopressin-deficient rats (Brattleboro strain)

A group of Brattleboro rats homozygous for diabetes insipidus (DI) and a group of normal Long-Evans (LE) rats were deprived of water and tested on two tasks thought to measure reinforcement strength: a progressive-ratio schedule in an operant chamber and a quinine-induced drinking-suppression task. Since water-deprived DI rats are in more severe negative water balance than LE rats, it was hypothesized that they would sustain higher ratios than LE rats on the progressive-ratio schedule and would suppress drinking at higher quinine concentrations than LE rats. It was found that DI rats responded less than LE rats on the progressive-ratio schedule and that DI rats suppressed drinking as much as LE rats at each concentration of quinine used on the drinking-suppression test. It is suggested that the reinforcement strength of water for DI rats is not higher than that for LE rats.

A procedure for small-volume brain grafting; vasopressin cells in neonatal and adult Brattleboro rats

A simple and reliable technique is described for the transplantation of fetal vasopressin (VP) neurons in the third ventricle of the brain of homozygous Brattleboro neonates. Small-volume grafting is introduced by microdissection of paraventricular and supraoptic areas and by pelleting the minced tissue for insertion into the transplantation cannula. Morphological and immunocytochemical evaluation yielded results in both neonatal and adult host brain that were similar to those described for anterior hypothalamic grafts in adult Brattleboro brain. The present protocol circumvents some of the general problems encountered when the use of small grafts is imperative, and is also applicable to the implantation of pelleted cell suspensions.

A critique of the vasopressin-memory hypothesis

During the past 20 years, evidence has accumulated to suggest that the neuropeptide vasopressin (VP) enhances memory by acting on central mechanisms, and that oxytocin (OT) has amnestic effects. In this review, the evidence for the memory hypothesis with respect to VP is considered and alternative interpretations evaluated. A critical approach has been adopted; negative findings, design considerations and problems with the various hypotheses are given prominence. It is concluded that the memory hypothesis fails to provide an adequate account, and some alternative theories and suggestions are discussed. It is speculated that the peptide may affect behaviour by two distinct mechanisms: peripheral action may involve reinforcement mechanisms, but its central role may be to modulate arousal level, especially in stressful situations.

Behavioral effects of peripheral administration of arginine vasopressin: a review of our search for a mode of action and a hypothesis

In this review we present data summarizing our studies concerning the mechanism of action for the behavioral effects of peripheral arginine vasopressin (AVP) administration. We have demonstrated a clear performance improvement in a one trial appetitive task designed to measure the memory-learning process. This behavioral effect is blocked by peptide analogs which block the pressor response to AVP. From these data, and from other data obtained in aversively motivated tasks, we hypothesize that peripheral AVP injections induce effects of physiological-endocrinological origin and that these peripheral signals (e.g. vasopressor actions) alert and arouse the animal, thus helping to improve its association of environmental events. This hypothesis is similar to that proposed by others regarding peripheral hormones and memory and still leaves open the possibility that vasopressin in the brain acts independently of the above proposed action for peripherally derived vasopressin.

Dose-related influence of arginine-vasopressin on a passive avoidance behavior: effect of rearing conditions

The present experiment was conducted in order to determine what effects administration of arginine-vasopressine (AVP) would have on post weaned male rats, reared for 44 days either in relative social isolation or in group and tested in a cross-through passive avoidance task. AVP (0.0; 0.1 and 1.0 micrograms/rat) was injected subcutaneously immediately after the application of the electric footshock (0.3 mA for 2 sec). The individual post-weaning housing significantly impaired the passive avoidance performance in rats treated with saline (0.0 micrograms) and in rats treated with 1.0 micrograms AVP. No difference, however, was observed between isolated and group-reared rats injected with 0.1 micrograms AVP. It was concluded that AVP acts upon the passive avoidance performance by changing the animal's state of arousal in a non-monotonic dose-dependent manner.

The effects of vasopressin on positively rewarded responding and on locomotor activity in rats

It has been suggested that arginine-vasopressin (AVP) enhances cognitive, and especially mnemonic, ability. Most studies have employed shock avoidance paradigms; we report the results of a study in which saline or vasopressin (0, 0.5 or 1 microgram, mcg, per rat, subcutaneous) pre-treated rats learned to press a lever for food reward. AVP was found to have a disruptive effect on aquisition, particularly when the tendency for these rats to produce extreme learning scores was taken into account. Locomotor activity, with and without vasopressin pre-treatment (0, 0.5, 1 or 2 mcg/rat), was also studied. Only the highest dose significantly reduced activity; therefore, the effects of AVP on acquisition are unlikely to have been caused by motor disruption. The results are discussed in terms of an hypothesis which suggests that AVP enhances arousal, hence influencing performance.

Behavioral differences between vasopressin-deficient (Brattleboro) and normal Long-Evans rats

Behavioral comparisons were made between rats of the Brattleboro strain with hereditary hypothalamic diabetes insipidus (DI) and normal Long-Evans rats. Measurements were made of activity behavior in a lighted open field and in a darkened activity chamber. Subtle measurement specific differences in the activity behavior of DI rats were found which suggested altered emotion, motivation and/or attention in the DI rats. In terms of learned behavior, DI and normal rats displayed a similar degree of habituation to all within-session activity measures in both the open field and darkened activity chamber. In a passive avoidance test, DI rats exhibited a degree of avoidance behavior equivalent to that of normal animals. Thus, these studies provide evidence that the vasopressin-deficient rat is not defective in learning and memory processes. The data can be interpreted as suggesting that vasopressin may influence memory tasks by extrinsic modulation of related states of emotionality, motivation and/or attention rather than by direct involvement in the retrieval and consolidation of information.

Effect of vasopressin on open field and activity behavior of the vasopressin-deficient (Brattleboro) rat

The effect of 1 and 5 micrograms AVP injections on open field and photoactivity chamber behavior of D.I. and normal Long-Evans animals was studied. Administration of 5 micrograms AVP (SC) resulted in a statistically significant depression of both open field and photochamber activity in the D.I. rat, but had a less pronounced effect on normal animals. However, 1 microgram AVP resulted in only minor alterations of activity in both D.I. and normal animals. In terms of learned behavior, D.I. and normal animals displayed similar within-session habituation when comparisons were made following the same treatment conditions. Thus, this study supports the hypothesis that vasopressin may influence memory tasks by modulation of related states of emotionality, motivation, and/or attention rather than by direct involvement in the retrieval and/or consolidation of information.

Hyperreflexive behavior in Brattleboro rats

In two experiments we compared the size of the startle response elicited by shock and acoustic stimuli in animals having a congenital absence of vasopressin (Brattleboro rats) with closely related controls, which do synthesize vasopressin. The rats lacking vasopressin were hyperresponsive to both shock and acoustic stimuli. Inhibition of the acoustic startle by shock prestimuli also was greater in these animals. These results are consistent with reports which indicate that vasopressin attenuates responses to noxious stimuli.

Centrally mediated effects of neurohypophyseal hormones

The neurohypophyseal hormones oxytocin and vasopressin cause a variety of biological effects in animals which are mediated by central nervous system mechanisms. Among the best studied of these effects is the modulation of both memory processes and the development of drug tolerance and dependence. Neurohypophyseal hormones have also been shown to alter various physiological parameters such as heart rate and body temperature following central administration. In addition, these peptides can profoundly alter spontaneous, unlearned behavior in several rodent species. Many of the centrally mediated effects of neurohypophyseal hormones have been shown to be elicited at sites within the brain stem and the limbic system where vasopressin and oxytocin occur in cell bodies, axons and nerve terminals, suggesting a physiological role for these peptide effects. The various central effects of neurohypophyseal hormones involve different mechanisms which can be distinguished from one another on the basis of required dose, time-course of action, and structure-activity relationships. Thus, alterations of spontaneous behavior are mediated by putative receptors closely related to vasopressin receptors in blood vessels responsible for the peripheral pressor response while the effects on memory processes are mediated by a mechanism which is not closely related to those involved in the peripheral hormonal effects of the peptides. The influence of neurohypophyseal hormones on memory and attention may be useful clinically. A potential role for these peptides in mental disorders is discussed.

The behavior of vasopressin-deficient rats (Brattleboro strain)

Seven Brattleboro rats homozygous for diabetes insipidus (DI) and seven normal Long-Evans (LE) rats were tested on a neuropsychological test battery comprised of the following tasks: time-spent-eating in two adaptation boxes, time-to-emerge into an open field, adaptation to a T-maze, contingently reinforced T-maze alternation, olfactory and visual discrimination, runway learning, approach-avoidance conflict, step-through passive avoidance, prod burying, and stress-induced interference. It was found that DI rats adapted more slowly than LE rats to novel environments (e.g., adaptation box, T-maze, and runway), and DI rats were slower to emerge into an open field. However, DI rats performed as well as LE rats on all other tasks. These results suggest that DI rats have altered temperamental dispositions (timidity or cautiousness), normal working and reference memory, and similar susceptibility (compared to LE rats) to the interfering effects of inescapable stress.

Memory and the septo-hippocampal cholinergic system in the rat

This study examined the effects of intrahippocampal injections of scopolamine (a muscarinic antagonist drug) on performance of a working-memory task (contingently reinforced T-maze alternation) and a reference-memory task (visual discrimination) by the same rats in the same maze. Rats in the first shipment were trained in delayed alternation, received bilateral implantation of cannulae aimed at the CA 3 field of the dorsal hippocampus, and were tested for retention with 1 microliter microinjections of scopolamine (35 micrograms) and saline on alternate days. These rats were then trained on visual discrimination and tested alternately under scopolamine or saline as described above. It was found that scopolamine impaired performance of delayed alternation to a greater extent than performance of visual discrimination. Data from rats in the second shipment replicated this finding, with the order of the tasks reversed, and, additionally, showed that delayed alternation, but not visual discrimination, was impaired at a dose of 12 micrograms/microliter. A dose of 4 micrograms/microliter had no effect on either task. It is concluded that performance of a working-memory task is significantly more sensitive to disruption of cholinergic mechanisms in the hippocampus than performance of a reference-memory task.

Neurohypophysial hormones and brain function: the neurophysiological effects of oxytocin and vasopressin

An increasing body of evidence suggests that the neurohypophysial hormones, in addition to their classical actions, may also act as neurotransmitters. They have a widespread but discontinuous distribution in the CNS; apart from their presence in the magnocellular nuclei they may be found in the hippocampus, amygdala, septum, substantia nigra, brainstem and spinal cord. They exert profound effects on behavior, particularly on memory, a function frequently ascribed to the hippocampus, amygdala and septum; on memory consolidation, internal reward and self stimulation functions frequently ascribed to brainstem and diencephalic aminergic systems including the substantia nigra and on sensory and autonomic responses which involve the medulla and spinal cord. When applied to the CNS they alter multiple unit activity in certain regions, particularly the hippocampus and cells which contain neural lobe hormones appear to be able to drive other cells synaptically. Finally application of the hormones can profoundly affect the activity of single nerve cells in just those parts of the CNS where, on the basis of their behavioral actions, they might be expected to act.

Effects of DDAVP, a vasopressin analog, on delayed matching behavior in the pigeon

Five pigeons were tested in a delayed matching-to-sample task after receiving an acute injection of DDAVP (1-desamino-8-D-arginine), scopolamine or d-amphetamine. A feeding test also was used to document non-specific drug effects. Scopolamine produced a marked dose-related decrement in accuracy of matching, regardless of delay, indicating that scopolamine impairs both discrimination and short-term memory. Neither DDAVP nor d-amphetamine produced consistent changes in delayed matching. Thus, an experimental model of short-term memory with pigeons did not confirm the findings of others of a positive effect of DDAVP upon cognitive performance in humans.