Targeted activation of the hippocampal CA2 area strongly enhances social memory.

Social cognition enables individuals to understand others' intentions. Social memory is a necessary component of this process, for without it, subsequent encounters are devoid of any historical information. The CA2 area of the hippocampus, particularly the vasopressin 1b receptor (Avpr1b) expressed there, is necessary for memory formation. We used optogenetics to excite vasopressin terminals, originating from the hypothalamic paraventricular nucleus, in the CA2 of mice. This markedly enhanced their social memory if the stimulation occurred during memory acquisition, but not retrieval. This effect was blocked by an Avpr1b antagonist. Finally, this enhanced memory is resistant to the social distraction of an introduced second mouse, important for socially navigating populations of individuals. Our results indicate the CA2 can increase the salience of social signals. Targeted pharmacotherapy with Avpr1b agonists or deep brain stimulation of the CA2 are potential avenues of treatment for those with declining social memory as in various dementias.

Role of the vasopressin 1b receptor in rodent aggressive behavior and synaptic plasticity in hippocampal area CA2.

The vasopressin 1b receptor (Avpr1b) is critical for social memory and social aggression in rodents, yet little is known about its specific roles in these behaviors. Some clues to Avpr1b function can be gained from its profile of expression in the brain, which is largely limited to the pyramidal neurons of the CA2 region of the hippocampus, and from experiments showing that inactivation of the gene or antagonism of the receptor leads to a reduction in social aggression. Here we show that partial replacement of the Avpr1b through lentiviral delivery into the dorsal CA2 region restored the probability of socially motivated attack behavior in total Avpr1b knockout mice, without altering anxiety-like behaviors. To further explore the role of the Avpr1b in this hippocampal region, we examined the effects of Avpr1b agonists on pyramidal neurons in mouse and rat hippocampal slices. We found that selective Avpr1b agonists induced significant potentiation of excitatory synaptic responses in CA2, but not in CA1 or in slices from Avpr1b knockout mice. In a way that is mechanistically very similar to synaptic potentiation induced by oxytocin, Avpr1b agonist-induced potentiation of CA2 synapses relies on NMDA (N-methyl-D-aspartic acid) receptor activation, calcium and calcium/calmodulin-dependent protein kinase II activity, but not on cAMP-dependent protein kinase activity or presynaptic mechanisms. Our data indicate that the hippocampal CA2 is important for attacking in response to a male intruder and that the Avpr1b, likely through its role in regulating CA2 synaptic plasticity, is a necessary mediator.

Oxytocin as a natural antipsychotic: a study using oxytocin knockout mice.

It has been previously suggested that oxytocin (Oxt) may act as a natural antipsychotic. To test this hypothesis, we investigated whether disruption of the oxytocin gene (Oxt-/-) made mice more susceptible to the psychosis-related effects of amphetamine (Amp), apomorphine (Apo) and phencyclidine (PCP). We examined drug-induced changes in the prepulse inhibition (PPI) of the startle reflex, a measure of sensorimotor gating deficits characteristic of several psychiatric and neurological disorders, including schizophrenia. We found that treatment with Amp, Apo and PCP all had effects on PPI. However, in Oxt-/- mice, but not Oxt+/+ mice, PCP treatment resulted in large PPI deficits. As PCP is a noncompetitive N-methyl-D-aspartic acid receptor antagonist, these findings suggest that the absence of Oxt alters the glutamatergic component of the PPI.

Intrinsic quantal variability due to stochastic properties of receptor-transmitter interactions.

Synaptic events at the neuromuscular junction are integer multiples of a quantum, the postsynaptic response to transmitter released from one presynaptic vesicle. At central synapses where quanta are small, it has been suggested they are invariant due to occupation of all postsynaptic receptors, a concept neglecting inherent fluctuations in channel behavior. If this did occur, the quantal release model would not apply there and could not be used to localize sites of synaptic modification. Monte Carlo simulations of quanta include transmitter diffusion and interactions with postsynaptic receptors that are treated probabilistically. These models suggest that when there are few postsynaptic channels available at a synapse, their stochastic behavior produces significant intrinsic variance in response amplitude and kinetics, and saturation does not occur. These results were confirmed by analysis of inhibitory quanta in embryonic and adult Mauthner cells involving a small and large number of channels, respectively. The findings apply to excitatory synapses as well.

Opioid receptors undergo axonal flow.

Previous studies have indicated the presence of opiate receptors on axons of the rat vagus nerve and on other small diameter fibers. In examinations of the effect of ligation on the distribution of receptors in the vagus nerve by in vitro labeling light microscopic autoradiography, a large buildup of receptors was found proximal to the ligature. This result indicates an axonal flow of receptors.

A deletion truncating the gonadotropin-releasing hormone gene is responsible for hypogonadism in the hpg mouse.

Hereditary hypogonadism in the hypogonadal (hpg) mouse is caused by a deletional mutation of at least 33.5 kilobases encompassing the distal half of the gene for the common biosynthetic precursor of gonadotropin-releasing hormone (GnRH) and GnRH-associated peptide (GAP). The partially deleted gene is transcriptionally active as revealed by in situ hybridization histochemistry of hpg hypothalamic tissue sections, but immunocytochemical analysis failed to show the presence of antigen corresponding to any part of the precursor protein.

Huntington's disease gene (IT15) is widely expressed in human and rat tissues.

Huntington's Disease (HD) is notable for selective neuronal vulnerability in the basal ganglia and cerebral cortex. We have investigated in human and rodent tissues the expression of the gene (IT15) whose mutation causes HD. IT15 is widely expressed, with highest levels of expression in brain, but also in lung, testis, ovary, and other tissues. Within the brain, expression is widespread with a neuronal pattern and is not enriched in the basal ganglia. Expression of IT15 is not reduced in the brain of HD patients when corrected for actin (though it is slightly decreased in the striatum when uncorrected, consistent with neuronal loss). Thus, the widespread distribution of IT15 expression does not correspond with the restricted distribution of neuropathologic changes in HD. We suggest that pathophysiology may relate to abnormal cell type-specific protein interactions of the HD protein.

Reduced ultrasonic vocalizations in vasopressin 1b knockout mice.

The neuropeptides oxytocin and vasopressin have been implicated in rodent social and affiliative behaviors, including social bonding, parental care, social recognition, social memory, vocalizations, territoriality, and aggression, as well as components of human social behaviors and the etiology of autism. Previous investigations of mice with various manipulations of the oxytocin and vasopressin systems reported unusual levels of ultrasonic vocalizations in social settings. We employed a vasopressin 1b receptor (Avpr1b) knockout mouse to evaluate the role of the vasopressin 1b receptor subtype in the emission of ultrasonic vocalizations in adult and infant mice. Avpr1b null mutant female mice emitted fewer ultrasonic vocalizations, and their vocalizations were generally at lower frequencies, during a resident-intruder test. Avpr1b null mutant pups emitted ultrasonic vocalizations similar to heterozygote and wildtype littermates when separated from the nest on postnatal days 3, 6, 9, and 12. However, maternal potentiation of ultrasonic vocalizations in Avpr1b null and heterozygote mutants was absent, when tested at postnatal day 9. These results indicate that Avpr1b null mutant mice are impaired in the modulation of ultrasonic vocalizations within different social contexts at infant and adult ages.

Disruption of the vasopressin 1b receptor gene impairs the attack component of aggressive behavior in mice.

Vasopressin affects behavior via its two brain receptors, the vasopressin 1a and vasopressin 1b receptors (Avpr1b). Recent work from our laboratory has shown that disruption of the Avpr1b gene reduces intermale aggression and reduces social motivation. Here, we further characterized the aggressive phenotype in Avpr1b -/- (knockout) mice. We tested maternal aggression and predatory behavior. We also analyzed the extent to which food deprivation and competition over food increases intermale aggression. We quantified defensive behavior in Avpr1b -/- mice and later tested offensive aggression in these same mice. Our results show that attack behavior toward a conspecific is consistently reduced in Avpr1b -/- mice. Predatory behavior is normal, suggesting that the deficit is not because of a global inability to detect and attack stimuli. Food deprivation, competition for food and previous experience increase aggression in both Avpr1b +/+ and -/- mice. However, in these circumstances, the level of aggression seen in knockout mice is still less than that observed in wild-type mice. Defensive avoidance behaviors, such as boxing and fleeing, are largely intact in knockout mice. Avpr1b -/- mice do not display as many 'retaliatory' attacks as the Avpr1b +/+ mice. Interestingly, when territorial aggression was measured following the defensive behavior testing, Avpr1b -/- mice typically show less initial aggressive behavior than wild-type mice, but do show a significant increase in aggression with repeated testing. These studies confirm that deficits in aggression in Avpr1b -/- mice are limited to aggressive behavior involving the attack of a conspecific. We hypothesize that Avpr1b plays an important role in the central processing that couples the detection and perception of social cues (which appears normal) with the appropriate behavioral response.

Vasopressin 1a receptor knockout mice have a subtle olfactory deficit but normal aggression.

Two receptors for vasopressin (Avp) are expressed in the brain, the Avp 1a receptor (Avpr1a) and the Avp 1b receptor (Avpr1b). To investigate the role of Avpr1a in behaviors in mice more extensively, we generated a line of mice lacking a functional Avpr1a (knockout, Avpr1a(-/-)). We first performed a baseline phenotypic screen of the Avpr1a knockouts followed by a more detailed analysis of their circadian rhythms and olfactory function. When free-running in constant darkness, the Avpr1a(-/-) mice have a longer circadian tau than the wild types. There are also subtle olfactory deficits in Avpr1a(-/-) mice as measured in an olfactory habituation/dishabituation test and in the discrimination of female urine from male urine using an operant testing paradigm. An extensive body of research has shown that manipulation of the Avpr1a alters behavior, including aggression and social recognition. Therefore, we expected profound behavioral deficits in mice lacking the Avpr1a gene. Contrary to our expectations, social aggression, anxiety-like behavior and social recognition are unaffected in this line of Avpr1a knockout mice. These data suggest either that the Avpr1a is not as critical as we thought for social behavior in mice or, more likely, that the neural circuitry underlying aggression and other social behaviors compensates for the life-long loss of the Avpr1a. However, the olfactory deficits observed in the Avpr1a(-/-) mice suggest that Avp and Avpr1a drugs may affect behavior, in part, by modulation of chemosensory systems.

Attenuated stress response to acute lipopolysaccharide challenge and ethanol administration in vasopressin V1b receptor knockout mice.

The arginine vasopressin (Avp) 1b receptor (Avpr1b) present on anterior pituitary corticotrophs is involved in the stimulation of adrenocorticotrophic hormone (ACTH) secretion, especially during times of stress. Corticotrophin-releasing hormone (CRH) is considered the major ACTH secretagogue during acute stress whereas Avp appears to be the more dominant mediator of the hypothalamic-pituitary-adrenal (HPA) axis response during chronic stress situations. To investigate the role of the Avpr1b in the HPA axis response to acute stress, we measured ACTH and corticosterone (CORT) plasma levels in Avpr1b knockout (KO) mice and wild-type controls in response to bacterial lipopolysaccharide (LPS) challenge and ethanol (EtOH) administration. Mice deficient in Avpr1b had markedly compromised plasma ACTH and CORT responses to acute (30 min) LPS, but normal ACTH and CORT response to more extended exposure (4 h) to the immune system activator. The plasma ACTH and CORT levels stimulated by intoxicating, sedative doses of EtOH (3.2 and 4 g/kg) were significantly decreased in the Avpr1b KO mice compared to wild-type littermates. Significantly higher EtOH-induced plasma ACTH and CORT secretion was measured in female than in male Avpr1b wild-type mice. There were no differences in the blood alcohol levels following acute EtOH administration in Avpr1b KO or wild-type mice of either gender. Our results clearly suggest that Avpr1b plays a significant role in the HPA axis response to acute immune stress and EtOH intoxication.

The vasopressin 1b receptor is prominent in the hippocampal area CA2 where it is unaffected by restraint stress or adrenalectomy.

The vasopressin 1b receptor (Avpr1b) is one of two principal receptors mediating the behavioral effects of vasopressin (Avp) in the brain. Avpr1b has recently been shown to strongly influence social forms of aggression in mice and hamsters. This receptor appears to play a role in social recognition and motivation as well as in regulating the hypothalamic-pituitary-adrenal axis. Most of these studies have been performed in knockout mice, a species in which the localization of the Avpr1b has not been described, thus precluding correlations with the behaviors. We performed in situ hybridization histochemistry (ISHH) with specific probes and found especially prominent expression within the CA2 pyramidal neurons of the hippocampus, with much lower expression in the hypothalamic paraventricular nucleus and amygdala. Reverse transcriptase-polymerase chain reaction (RT-PCR) confirmed expression in those as well other areas in which the ISHH was not sensitive enough to detect labeled cells (e.g. piriform cortex, septum, caudate-putamen and lower brainstem areas). Mouse Avpr1b transcript levels were not altered in the CA2 field by restraint stress or adrenalectomy. Finally, ISHH and RT-PCR showed expression of the Avpr1b gene in the rat and human hippocampi as well. We suggest that the CA2 field may form or retrieve associations (memories) between olfactory cues and social encounters.

A microscopic view of helix propagation: N and C-terminal helix growth in alanine helices.

Molecular dynamics simulations with umbrella sampling are used to perform free energy simulations of C-terminal and N-terminal helix propagation in small helices of Ace-(Ala)n-NMe, with n= (4,5,10,15), in water. From the resulting free energy surfaces, computed as a function of the terminal psi dihedral angle, the roles of length and end effects in helix propagation are explored. An energetic analysis of the helices, both formed and partially formed, is used to develop a molecular rationalization for the observed trends in helix stability. We find that the microscopic helix propagation parameters vary significantly depending on the end and length of the helix in which the terminal hydrogen bond is forming. A model which considers propagation of the helices from either end as statistically independent yields Zimm-Bragg s parameters in the range of 0.5 to 1.5, depending on helical length. Analysis of the mechanism of helix propagation suggests that 3(10)-helix plays a role in helix formation but its population should be low in the helical state of these model peptides.

The effect of thyroid hormone on the chromatin structure and expression of the malic enzyme gene in hepatocytes.

Malic enzyme catalyzes the NADP-dependent oxidative decarboxylation of malate to pyruvate and carbon dioxide and is involved in lipogenesis. We have investigated the effect of thyroid hormone on the chromatin structure of the malic enzyme gene in rat liver. Hypersensitivity to DNase I in the immediate 5'-flanking region was altered by T3. T3 stimulation induced hypersensitive sites at -310 base pairs (bp) and -50 bp whereas a hypersensitive site at -170 bp was thyroid hormone independent. Hypersensitive sites identified in the 3'-flanking region showed no change with T3 stimulation. We further characterized expression of the malic enzyme gene as a function of thyroidal state by localizing malic enzyme mRNA in hepatocytes using in situ hybridization histochemistry. In hypothyroid and euthyroid states, two populations of hepatocytes were seen, some with malic enzyme message and others with no detectable message. These differences in malic enzyme gene expression were most evident between groups or regions of hepatocytes. After 10 days of thyroid hormone treatment all hepatocytes demonstrated malic enzyme message. The hypersensitivity results confirm that thyroid hormone stimulation of malic enzyme synthesis occurs in part at the level of transcription, and localization of malic enzyme gene expression suggests this stimulation is accompanied by recruitment of hepatocytes. Hepatocytes may be heterogeneous in their ability to respond to thyroid hormone.

Plasma hyperosmolality increases G protein and 3',5'-cyclic adenosine monophosphate synthesis in the paraventricular and supraoptic nuclei.

Hyperosmotic stimuli produce profound changes in cellular morphology and biosynthetic activities within the hypothalamic paraventricular and supraoptic nuclei (SON) of the rat. The mechanisms by which osmoreceptive signals are transduced within these nuclei are poorly understood. We examined several components of the cAMP-associated second messenger system after giving rats 2% saline to drink for one week, a strong hyperosmotic stimulus. We found that mRNA levels for both the stimulatory and inhibitory guanine-nucleotide binding protein alpha-subunits were increased in the paraventricular nucleus and SON. In the SON, these changes were accompanied by increased basal cAMP levels, cholera toxin-stimulated adenylate cyclase, and Gs alpha. Our results suggest that Gs alpha levels are not saturated with respect to adenylate cyclase coupling and that osmoreception activates the cAMP second messenger system.

High level, cell-specific expression of ornithine decarboxylase transcripts in rat genitourinary tissues.

We evaluated transcript levels for the rate-limiting enzyme in polyamine biosynthesis, ornithine decarboxylase (ODC), in rat tissues by Northern blotting and in situ hybridization histochemistry, using a rat cDNA probe. ODC transcripts were expressed at a high level, relative to levels in other tissues, in the kidney and testis of the adult rat; maximal levels of transcripts in these tissues occurred after sexual maturation had taken place, i.e. between 20 and 150 days of age. In situ hybridization histochemistry revealed high level expression in the kidney, testis, prostate, and seminal vesicles of the male rat; this high level expression was limited to certain cell types: kidney, S3 cells of the proximal convoluted tubule; prostate and seminal vesicles, glandular or luminal epithelial cells; and testis, early spermatogenic cells. High level expression of ODC mRNA disappeared from the prostate and seminal vesicle epithelial cells after castration and reappeared with testosterone treatment; in contrast, levels of kidney ODC mRNA were essentially unchanged by castration and were similar in male and female adult rats. We conclude that high level ODC mRNA expression occurs in specific cell types in the adult rat, where it appears to be regulated by both androgen-dependent and independent mechanisms.

Raphe serotonin neuron-specific oxytocin receptor knockout reduces aggression without affecting anxiety-like behavior in male mice only.

Serotonin and oxytocin influence aggressive and anxiety-like behaviors, though it is unclear how the two may interact. That the oxytocin receptor is expressed in the serotonergic raphe nuclei suggests a mechanism by which the two neurotransmitters may cooperatively influence behavior. We hypothesized that oxytocin acts on raphe neurons to influence serotonergically mediated anxiety-like, aggressive and parental care behaviors. We eliminated expression of the oxytocin receptor in raphe neurons by crossing mice expressing Cre recombinase under control of the serotonin transporter promoter (Slc6a4) with our conditional oxytocin receptor knockout line. The knockout mice generated by this cross are normal across a range of behavioral measures: there are no effects for either sex on locomotion in an open-field, olfactory habituation/dishabituation or, surprisingly, anxiety-like behaviors in the elevated O and plus mazes. There was a profound deficit in male aggression: only one of 11 raphe oxytocin receptor knockouts showed any aggressive behavior, compared to 8 of 11 wildtypes. In contrast, female knockouts displayed no deficits in maternal behavior or aggression. Our results show that oxytocin, via its effects on raphe neurons, is a key regulator of resident-intruder aggression in males but not maternal aggression. Furthermore, this reduction in male aggression is quite different from the effects reported previously after forebrain or total elimination of oxytocin receptors. Finally, we conclude that when constitutively eliminated, oxytocin receptors expressed by serotonin cells do not contribute to baseline anxiety-like behaviors or maternal care.

Changes in cellular levels of messenger ribonucleic acid encoding gonadotropin-releasing hormone in the anterior hypothalamus of female rats during the estrous cycle.

Cellular levels of messenger RNA encoding GnRH were measured using quantitative in situ hybridization in coronal sections through the area of the organum vasculosum of the lamina terminalis of female rats examined at various times of the 4-day estrous cycle. GnRH mRNA levels were high on the morning of diestrus day 1, but declined throughout the day of diestrus day 2 to a nadir on the morning of proestrus. Although GnRH message levels were lowest on the morning of proestrus, they rose nearly two-fold by 1900h that evening and remained high during the day of estrus. These data support the hypothesis that GnRH synthesis is coupled to GnRH release, and indicate that GnRH biosynthesis is not stimulated on the morning of proestrus in preparation for the ovulatory surge release of GnRH and LH in the afternoon.

Localization of binding sites in the central nervous system for leptin (OB protein) in normal, obese (ob/ob), and diabetic (db/db) C57BL/6J mice.

Leptin (OB protein) fused to the FLAG epitope and a kinase recognition site was expressed in bacteria, immunopurified, and phosphorylated using [gamma-(33)P] ATP. The resulting probe was used to characterize the distribution of leptin binding sites within brain sections of normal, ob/ob, and db/db C57BL/6J male mice. Leptin binding sites were found in leptomeninges and choroid plexus. Leptin binding within the choroid plexus is slightly elevated in ob/ob mice when compared to normal males (p<0.05). Binding of leptin by the choroid plexus of db/db male mice is lower than in normal males (p<0.05), but normally distributed. Based on the association and dissociation rates of leptin binding on tissue sections, we estimate the K(D) of the choroid plexus site at 0.25X10(-9) M. From our results, we hypothesize that the binding of leptin to its site may cause the release or transport of uncharacterized factor(s) into the cerebral spinal fluid (CSF) to affect neuronal populations controlling feeding and metabolism.

Hypertrophy and increased gene expression of neurons containing neurokinin-B and substance-P messenger ribonucleic acids in the hypothalami of postmenopausal women.

We have previously described hypertrophy of neurons containing estrogen receptor mRNA in the infundibular nucleus of postmenopausal women. In the present investigation we identified peptide mRNAs in the hypertrophied neurons and determined whether postmenopausal neuronal hypertrophy was accompanied by changes in gene expression. In the first study in situ hybridization was performed on sections from hypothalami of postmenopausal women (n = 3) using synthetic 35S-labeled cDNA probes complementary to mRNAs encoding estrogen receptor, substance-P (SP), neurokinin-B (NKB), POMC, cholecystokinin, dynorphin, CRF, enkephalin, galanin, neuropeptide-Y, GH-releasing hormone, and tyrosine hydroxylase. Neuronal cross-sectional areas and cell densities were measured with the aid of a computer microscope system. Neurons labeled with the NKB and SP probes were comparable in size, morphology, and distribution to the hypertrophied neurons containing estrogen receptor mRNA. In contrast, neurons labeled with other cDNA probes were sparsely distributed (CRF and dynorphin), smaller in size (neuropeptide-Y, galanin, GH-releasing hormone, enkephalin, cholecystokinin, and POMC), or located anterior to the hypertrophied population (tyrosine hydroxylase). In the second study sections from hypothalami of premenopausal (n = 3) and postmenopausal (n = 3) women were incubated with cDNA probes complementary to SP or NKB mRNAs. The mean cross-sectional areas of postmenopausal infundibular neurons containing NKB and SP mRNAs increased to 194% and 176% of premenopausal values, respectively. The autoradiographic grain densities of infundibular neurons labeled with either probe were also significantly increased in the postmenopausal group. Finally, the numbers of labeled neurons/tissue increased 6-fold (SP) and 15-fold (NKB) in the postmenopausal infundibular nucleus. These data demonstrate that human menopause is associated with marked increases in hypothalamic NKB and SP gene expression. We propose that neurons containing estrogen receptor, SP, and NKB mRNAs participate in the hypothalamic circuitry regulating estrogen negative feedback in the human.