The common features of autism spectrum disorder, a highly heritable representative pervasive developmental disorder with significant heterogeneity and multiple-genetic factors, are severe dysfunction in social reciprocity, abnormalities in social brain regions, and disproportionately low probability in the female gender. Concomitantly, certain domains of mental function, such as emotional memory and social reciprocity, show a significant sex difference. In addition, recent neuroimaging studies have shown significant sexual dimorphisms in neuroanatomical correlates of social cognition. Recently, some sexually dimorphic factors, including oxytocin, vasopressin, and genes linked with the x-chromosome, have received attention because of their possible contribution to mental development especially in the social cognitive domain. Taking this evidence together, it is hypothesized that a sexually dimorphic factor associated with social reciprocity could affect characteristics of autism spectrum disorder including dysfunction in social reciprocity, abnormalities in social brain regions, and disproportionately low probability in female gender. This review article overviews sexual dimorphisms in clinical features of autism spectrum disorder, in normal social cognition, and in social brain function and structure. The association of oxytocin with sexual dimorphisms, social reciprocity, neural correlates of social cognition, and the pathogenesis of autism spectrum disorder were further summarized. Recent studies have suggested that oxytocin plays a role in social attachment in experimental animals, in enhancing social interactive ability in human adults, and in the pathogenesis of autism spectrum disorder. Thus, the ongoing accumulated evidence suggests that oxytocin deserves to be examined as a candidate that causes the sexually dimorphic aspect of human social reciprocity, social brain development and the pathogenesis of autism spectrum disorder.

Oxytocin (OT) is implicated in stress reduction as well as in social behavior. It inhibits the stress-induced activity of the hypothalamic-pituitary adrenal axis responsiveness. OT is involved in social affiliation, sexual and maternal-infant binding, anxiety, mood, feeding control and memory. Several lines of evidence suggest a role of OT in psychiatric disorders. Various psychiatric disorders are strongly influenced by social variables, such as panic attacks, depression and early childhood autism, and seem to exhibit a particularly close connection with the brain dynamics that underlie social emotions. This paper proposes an overview of OT in psychiatric disorders through the links with the stress response and prosocial behavior.

Proximate neural mechanisms that influence preferences for groups of a given size are almost wholly unknown. In the highly gregarious zebra finch (Estrildidae: Taeniopygia guttata), blockade of nonapeptide receptors by an oxytocin (OT) antagonist significantly reduced time spent with large groups and familiar social partners independent of time spent in social contact. Opposing effects were produced by central infusions of mesotocin (MT, avian homolog of OT). Most drug effects appeared to be female-specific. Across five estrildid finch species, species-typical group size correlates with nonapeptide receptor distributions in the lateral septum, and sociality in female zebra finches was reduced by OT antagonist infusions into the septum but not a control area. We propose that titration of sociality by MT represents a phylogenetically deep framework for the evolution of OT's female-specific roles in pair bonding and maternal functions.

There is substantial evidence from animal research indicating a key role of the neuropeptides oxytocin (OT) and arginine vasopressin (AVP) in the regulation of complex social cognition and behavior. As social interaction permeates the whole of human society, and the fundamental ability to form attachment is indispensable for social relationships, studies are beginning to dissect the roles of OT and AVP in human social behavior. New experimental paradigms and technologies in human research allow a more nuanced investigation of the molecular basis of social behavior. In addition, a better understanding of the neurobiology and neurogenetics of human social cognition and behavior has important implications for the current development of novel clinical approaches for mental disorders that are associated with social deficits (e.g., autism spectrum disorder, social anxiety disorder, borderline personality disorder). This review focuses on our recent knowledge of the behavioral, endocrine, genetic, and neural effects of OT and AVP in humans and provides a synthesis of recent advances made in the effort to implicate the oxytocinergic system in the treatment of psychopathological states.

G-protein coupled receptors (GPCR) tend to desensitize/internalize when exposed to excess agonist.Previously, we have supported the argument that in the case of the oxytocin receptor (OTR), excess agonist (oxytocin, OT) at birth could be implicated with behavioural disorders of the autistic spectrum. In this review, more recent evidence for this hypothesis is summarized, and it is juxtaposed against reports where exogenous OT was found beneficial in alleviating certain undesired behaviours. Facing this dichotomy, we suggest possible in silico drug discovery approaches to mitigate undesired side effect of OT administration/OTR desensitization, especially in the light of potentially emerging agonist therapies. For this, the most important structural features of OTR are reviewed, and we highlight here the need for higher level of theory studies at the easier approachable extracellular receptor side, where loop 3(e3) and the N-terminated strain of OTR appear to offer targets of particular interest for the development of an agent that conditions the action of excess OT. Another approach, based on the development of new agonists with an improved receptor activation to receptor phosphorylation ratio, is also discussed. Finally, the issue of OTR desensitization is put into the broader context of GPCR desensitization and possible implications for behavioural disorders, and the case is made for the usefulness of computational studies in this area.

Oxytocin (OT) is a neuropeptide that is produced primarily in the hypothalamus and is best known for its role in mammalian birth and lactation. Recent evidence also implicates OT in social behaviors, including parental behavior, the formation of social bonds, and the management of stressful experiences. OT is reactive to stressors, and plays a role in the regulation of both the central and autonomic nervous system, including effects on immune and cardiovascular function. Knowledge of patterns of OT release would be of value in many fields of science and medicine. However, measurements of OT concentration in blood are infrequently performed, and previous attempts to measure OT in saliva have been unsuccessful. Using a sensitive enzyme immunoassay (EIA) and concentrated samples we were able to detect reproducible changes in salivary OT as a function of lactation and massage. These results indicate that measurements of biologically relevant changes in salivary OT are possible. These results confirm the biological relevance of changes in salivary OT with stressors and support saliva as a noninvasive source to monitor central neuroendocrine function.

Social recognition constitutes the basis of social life. In male mice and rats, social recognition is known to be governed by the neuropeptide oxytocin (OT) through its action on OT receptors (OTRs) in the medial amygdala. In female rats and mice, which have sociosexual behaviors controlling substantial investment in reproduction, an important role for OT in sociosexual behaviors has also been shown. However, the site in the female brain for OT action on social recognition is still unknown. Here we used a customized, controlled release system of biodegradable polymeric microparticles to deliver, in the medial amygdala of female mice,"locked nucleic acid" antisense (AS) oligonucleotides with sequences specific for the mRNA of the OTR gene. We found that single bilateral intraamygdala injections of OTR AS locked nucleic acid oligonucleotides several days before behavioral testing reduced social recognition. Thus, we showed that gene expression for OTR specifically in the amygdala is required for normal social recognition in female mice. Importantly, during the same experiment, we performed a detailed ethological analysis of mouse behavior revealing that OTR AS-treated mice underwent an initial increase in ambivalent risk-assessment behavior. Other behaviors were not affected, thus revealing specific roles for amygdala OTR in female social recognition potentially mediated by anxiety in a social context. Understanding the functional genomics of OT and OTR in social recognition should help elucidate the neurobiological bases of human disorders of social behavior (e.g., autism).

Autism spectrum disorders (ASD) are male-biased and characterized by deficits in social behavior and social communication, excessive anxiety or hyperreactivity to stressful experiences, and a tendency toward repetitiveness. The purpose of this review is to consider evidence for a role for two sexually dimorphic neuropeptides, oxytocin (OT) and arginine vasopressin (VP), in these features of ASD. Both VP and OT play a role in normal development. VP is androgen-dependent and of particular importance to male behavior. Excess VP or disruptions in the VP system could contribute to the male vulnerability to ASD. Alternatively, protective processes mediated via OT or the OT receptor might help to explain the relatively rare occurrence of ASD in females. Disruptions in either OT or VP or their receptors could result from genetic variation or epigenetic modifications of gene expression, especially during early development. Deficits in other developmental growth factors, such as reelin, which may in turn regulate or be regulated by OT or VP, are additional candidates for a role in ASD.

Social relationships are essential for maintaining human mental health, yet little is known about the brain mechanisms involved in the development and maintenance of social bonds. Animal models are powerful tools for investigating the neurobiological mechanisms regulating the cognitive processes leading to the development of social relationships and for potentially extending our understanding of the human condition. In this review, we discuss the roles of the neuropeptides oxytocin and vasopressin in the regulation of social bonding as well as related social behaviors which culminate in the formation of social relationships in animal models. The formation of social bonds is a hierarchical process involving social motivation and approach, the processing of social stimuli and formation of social memories, and the social attachment itself. Oxytocin and vasopressin have been implicated in each of these processes. Specifically, these peptides facilitate social affiliation and parental nurturing behavior, are essential for social recognition in rodents, and are involved in the formation of selective mother-infant bonds in sheep and pair bonds in monogamous voles. The convergence of evidence from these animal studies makes oxytocin and vasopressin attractive candidates for the neural modulation of human social relationships as well as potential therapeutic targets for the treatment of psychiatric disorders associated with disruptions in social behavior, including autism.

Evidence suggests that neurogenesis occurs in the adult hypothalamus, including centers containing oxytocin and vasopressin producing neurons. The present study was undertaken to look at one of these centers, the paraventricular nucleus (PVN), to describe its morphology, confirm the presence of neurogenesis and examine the effect of reproductive status on the incidence of neurogenesis. Serial sections of the paraffin-embedded hypothalamus were made from five puberty gilts, four adult gilts and four lactating sows. Specific sections were Nissl-stained for PVN morphology, while others were stained with an oxytocin (OT) primary antibody, which binds to the cytoplasm of oxytocin-containing neurons, and proliferating cell nuclear antigen (PCNA) primary antibody, which binds to PCNA, a protein expressed in the nucleus during cell division. Cells labeled with both OT and PCNA were considered to be oxytocin-containing neurons that had recently divided, signifying the recent synthesis of a mature neuron. The general morphology of the PVN was similar in all pigs, and three subnuclei were identified and named based on cytoarchitecture. Neurogenesis was consistently observed in OT-containing neurons of all pigs studied. However, a significantly greater number of double-labeled (OT + PCNA) cells occurred in the PVN of lactating sows and adult gilts, when compared to puberty gilts. These observations confirm the process of neurogenesis in the hypothalamus of the adult female pig and suggest that the up-regulation of OT-containing neurons is correlated to age and possibly driven by sexual maturation, but not necessarily lactation.