Comparative neuroanatomy of vasotocin and vasopressin in amphibians and other vertebrates

Historical perspective: Hormonal regulation of behaviors in amphibians

This review focuses on research into the hormonal control of behaviors in amphibians that was conducted prior to the 21st century. Most advances in this field come from studies of a limited number of species and investigations into the hormonal mechanisms that regulate reproductive behaviors in male frogs and salamanders. From this earlier research, we highlight five main generalizations or conclusions. (1) Based on studies of vocalization behaviors in anurans, testicular androgens induce developmental changes in cartilage and muscles fibers in the larynx and thereby masculinize peripheral structures that influence the properties of advertisement calls by males. (2) Gonadal steroid hormones act to enhance reproductive behaviors in adult amphibians, but causal relationships are not as well established in amphibians as in birds and mammals. Research into the relationships between testicular androgens and male behaviors, mainly using castration/steroid treatment studies, generally supports the conclusion that androgens are necessary but not sufficient to enhance male behaviors. (3) Prolactin acts synergistically with androgens and induces reproductive development, sexual behaviors, and pheromone production. This interaction between prolactin and gonadal steroids helps to explain why androgens alone sometimes fail to stimulate amphibian behaviors. (4) Vasotocin also plays an important role and enhances specific types of behaviors in amphibians (frog calling, receptivity in female frogs, amplectic clasping in newts, and non-clasping courtship behaviors). Gonadal steroids typically act to maintain behavioral responses to vasotocin. Vasotocin modulates behavioral responses, at least in part, by acting within the brain on sensory pathways that detect sexual stimuli and on motor pathways that control behavioral responses. (5) Corticosterone acts as a potent and rapid suppressor of reproductive behaviors during periods of acute stress. These rapid stress-induced changes in behaviors use non-genomic mechanisms and membrane-associated corticosterone receptors.

The vertebrate social behavior network: evolutionary themes and variations

Based on a wide variety of data, it is now clear that birds and teleost (bony) fish possess a core "social behavior network" within the basal forebrain and midbrain that is homologous to the social behavior network of mammals. The nodes of this network are reciprocally connected, contain receptors for sex steroid hormones, and are involved in multiple forms of social behavior. Other hodological features and neuropeptide distributions are likewise very similar across taxa. This evolutionary conservation represents a boon for experiments on phenotypic behavioral variation, as the extraordinary social diversity of teleost fish and songbirds can now be used to generate broadly relevant insights into issues of brain function that are not particularly tractable in other vertebrate groups. Two such lines of research are presented here, each of which addresses functional variation within the network as it relates to divergent patterns of social behavior. In the first set of experiments, we have used a sexually polymorphic fish to demonstrate that natural selection can operate independently on hypothalamic neuroendocrine functions that are relevant for (1) gonadal regulation and (2) sex-typical behavioral modulation. In the second set of experiments, we have exploited the diversity of avian social organizations and ecologies to isolate species-typical group size as a quasi-independent variable. These experiments have shown that specific areas and peptidergic components of the social behavior network possess functional properties that evolve in parallel with divergence and convergence in sociality.

Neural responses to territorial challenge and nonsocial stress in male song sparrows: segregation, integration, and modulation by a vasopressin V1 antagonist

The present experiments were conducted to determine (1) which basal forebrain regions and/or their peptidergic components are responsive to social challenge and nonsocial stress, and (2) the influence of an arginine vasopressin V(1) antagonist (AVPa) on these responses. Experiments were conducted in wild-caught male song sparrows (Melospiza melodia) that were housed on seminatural territories (field-based flight cages). Subjects were each fitted with a chronic guide cannula directed at the lateral ventricle and exposed to one of five conditions before sacrifice and histochemistry: saline + simulated territorial intrusion (STI; consisting of song playback and presentation of a caged conspecific male), AVPa + STI, saline + empty cage, AVPa + empty cage, unhandled. Two tissue series were prepared and immunofluorescently double-labeled for ZENK (egr-1) protein and either arginine vasotocin (AVT; avian homologue of AVP) or corticotropin releasing factor (CRF). The results indicate that the neuronal populations that are sensitive to nonsocial stress (capture, handling and infusion) and STI are at least partially segregated. Increases in ZENK-immunoreactive (-ir) nuclei following handling and infusion were observed in a large number of areas, whereas neural responses that were specific to STI were more limited. However, multiple areas showed responses to both handling and STI. AVPa infusions significantly reduced or eliminated most experimental increases in ZENK-ir, suggesting a broad role for endogenous AVT in the modulation of baseline activity and/or stress responsivity, and a much more limited role in the specific response to social challenge. Particular attention is given to the numerous zones of the lateral septum (LS), which are differentially responsive to handling, STI, and V(1)-like receptor blockade. These data suggest that septal AVT modulates neural responses to general stressors, not social stimuli specifically. Thus, species differences in septal AVT function (as previously described in songbirds) likely reflect differences in the relationship of stress or anxiety to species-specific behaviors, or to behavior in species-typical contexts.

Functional organization of preoptic vasotocin and isotocin neurons in the brain of rainbow trout: central and neurohypophysial projections of single neurons

Preoptic magnocellular neurosecretory cells (NSCs) in the brain of rainbow trout show synchronization of periodic Ca(2+) pulses, patterns of which differ between vasotocin (VT) and isotocin (IT) neurons. To provide neuroanatomical bases of the synchronized periodic Ca(2+) pulses and their biological implications, we examined the organization of preoptic VT and IT neurons in the brain of rainbow trout. The cytoarchitecture of the preoptic neurosecretory system was characterized by a confocal double-color immunofluorescence. Two to five VT neurons, and also IT neurons, aggregate to form cell-type specific clusters. VT clusters tend to localize medially, while IT clusters laterally. VT neurons are closely apposed at the proximal neuronal processes. A Golgi-like immunohistochemistry demonstrated that VT and IT fibers distribute widely in the brain, such as ventral telencephalon, diencephalon, and various mesencephalic structures, in addition to the neurohypophysial projections. Projections from single VT and IT neurons were examined by an intracellular staining with biocytin injection in a sagittally hemisected brain preparation, which contains the entire forebrain region. Single VT and IT neurons project toward the pituitary and the extrahypothalamic regions. Some IT neurons, but not VT neurons, were dye-coupled. These results support the idea that the same types of NSCs are connected to form cell-type-specific networks responsible for the synchronization of periodic Ca(2+) pulses. The organization of the preoptic neurosecretory system shown in the present study is suitable for the simultaneous control of neurohypophysial and extrahypothalamic outputs through the synchronization of electrical activity.

Putative isotocin distributions in sonic fish: relation to vasotocin and vocal-acoustic circuitry

Recent neurophysiological evidence in the plainfin midshipman fish (Porichthys notatus) demonstrated that isotocin (IT) and arginine vasotocin (AVT) modulate fictive vocalizations divergently between three reproductive morphs. To provide an anatomical framework for the modulation of vocalization by IT and to foster comparisons with the distributions of the IT homologues mesotocin (MT) and oxytocin (OT) in other vertebrate groups, we describe putative IT distributions in the midshipman and the closely related gulf toadfish, Opsanus beta. Double-label fluorescent histochemistry was used for IT and AVT (by using antibodies for MT, OT, and the mammalian AVT homologue, arginine vasopressin [AVP]). MT/OT-like immunoreactive (MT/OT-lir) cell groups were found in the anterior parvocellular, posterior parvocellular, and magnocellular preoptic nuclei. MT/OT-lir fibers and putative terminals densely innervated the ventral telencephalon and numerous areas in the hypothalamus and brainstem. These distributions included all sites of vocal-acoustic integration recently identified for the forebrain and midbrain and diencephalic components of the ascending auditory pathway. Results were qualitatively comparable across morphs, species, and seasons. In contrast to the widespread distribution of MT/OT-lir, AVP-lir somata, fibers, and putative terminals were almost completely restricted to vocal-acoustic regions. These data parallel previous descriptions of AVT immunoreactivity in these species, although the present methods showed a previously undescribed, seasonally variable AVP-lir cell group in the anterior tuberal hypothalamus, a vocally active site and a component of the ascending auditory pathway. These findings provided anatomic support for the role of IT and AVT in the modulation of vocal behavior at multiple levels of the central vocal-acoustic circuitry.

Neurochemical correlates of male polymorphism and alternative reproductive tactics in the Azorean rock-pool blenny, Parablennius parvicornis

In the common Azorean rock-pool blenny, Parablennius parvicornis, males exhibit alternative reproductive morphologies: (1) larger males defend nest sites, provide parental care, have anal glands (involved in pheromone release), testicular glands, and low gonad:body weight ratio (GSI) and (2) smaller, younger, males do not defend nests, have reduced glands and high GSI. These smaller non-nesting males behave as satellites (associated with nests) or sneakers (moving among nests), attempting to achieve parasitic fertilizations via sperm competition. In non-mammals, arginine vasotocin (AVT) is a key hypothalamic peptide involved in the control of reproductive behavior and physiology, and several fish species that exhibit alternative male reproductive morphs show polymorphism in AVT brain chemistry. We conducted an immunocytochemical study to generate comparative data on this intertidal blenny. Our analysis showed no difference in AVT-immunoreactive cell number or size between the male morphs, which is consistent with studies on other fish, including blennies. The number of AVT cells was positively correlated to fish body mass, while cell size showed no such relation. If corrected for body mass, the smaller non-nesting males have significantly more cells than the large nesting males. Our data suggest that the size and number of forebrain AVT cells develops initially to allow for reproduction in the young non-nesting males and this pattern does not appear to change when males take on the nesting morphotype later in life. This result appears to be consistent in many fishes with alternative male morphotypes.

Gender-related changes in the avian vasotocin system during ontogeny

The arginine vasotocin (AVT) system of the avian brain includes a sexually dimorphic part that extends from the caudal part of preoptic region through the medial part of the bed nucleus of stria terminalis (BSTm) to the lateral septum. It is composed of the parvocellular neurons located in the BSTm and the dense innervation of the medial preoptic region and lateral septum. In this part of the brain, AVT expression is stronger in males than in females in a few bird species investigated to date. This review focuses on the ontogeny of sexual differences in the vasotocinergic system of two gallinaceous species, domestic chicken and Japanese quail, and on the role of gonadal hormones in organizing during development and maintaining in adulthood these differences. Parvocellular AVT neurons become discernible in the BSTm of males and females during the second half of embryonic development. These cells undergo a profound and irreversible sexual differentiation during ontogenetic development. Recent findings demonstrate a dual role of estrogens in the organization and activation of sex differences in the AVT system. During the embryonic period of ontogeny, estrogens differentiate the AVT system in a sexually dimorphic manner in parallel with the differentiation of sexual behavior, while in adulthood estrogens, locally produced from testosterone in the male brain, activate AVT synthesis in the BSTm. The sexually dimorphic part of the AVT system is sensitive to a number of abiotic factors such as light, temperature, and water availability. It is suggested that sex dimorphic vasotocinergic systems could be implicated in processes of social recognition in various behavioral contexts.

Arginine Vasotocin Modulates a Sexually Dimorphic Communication Behavior in the Weakly Electric fish APTERONOTUS LEPTORHYNCHUS

South American weakly electric fish produce a variety of electric organ discharge (EOD) amplitude and frequency modulations including chirps or rapid increases in EOD frequency that function as agonistic and courtship and mating displays. In Apteronotus leptorhynchus, chirps are readily evoked by the presence of the EOD of a conspecific or a sinusoidal signal designed to mimic another EOD, and we found that the frequency difference between the discharge of a given animal and that of an EOD mimic is important in determining which of two categories of chirp an animal will produce. Type-I chirps (EOD frequency increases averaging 650Hz and lasting approximately 25ms) are preferentially produced by males in response to EOD mimics with a frequency of 50–200Hz higher or lower than that of their own. The EOD frequency of Apteronotus leptorhynchus is sexually dimorphic: female EODs range from 600 to 800Hz and male EODs range from 800 to 1000Hz. Hence, EOD frequency differences effective in evoking type-I chirps are most likely to occur during male/female interactions. This result supports previous observations that type-I chirps are emitted most often during courtship and mating. Type-II chirps, which consist of shorter-duration frequency increases of approximately 100Hz, occur preferentially in response to EOD mimics that differ from the EOD of the animal by 10–15Hz. Hence these are preferentially evoked when animals of the same sex interact and, as previously suggested, probably represent agonistic displays. Females typically produced only type-II chirps. We also investigated the effects of arginine vasotocin on chirping. This peptide is known to modulate communication and other types of behavior in many species, and we found that arginine vasotocin decreased the production of type-II chirps by males and also increased the production of type-I chirps in a subset of males. The chirping of most females was not significantly affected by arginine vasotocin.

Mechanisms for quick and variable responses

Dominant and subordinate males produce neuroendocrine stress responses during aggressive social interaction. In addition, stress responsiveness has both acute and chronic temporal components. A neurochemical marker that distinguishes social status and aggression by temporal and regional differentiation is the activity of serotonergic nuclei and terminals. A unique model for distinguishing the relationships among the neuroendocrine machinery of stress, social status and behavior is the lizard Anolis carolinensis. Dominant males exhibit more aggression and have temporally advanced serotonergic responses. Chronic serotonergic activity is associated with subordinate social status and reduced aggression. Acute and chronic serotonergic responses occur in both dominant and subordinate males, and are distinguished temporally. This provides a fundamental question that may elucidate basic differences in behavior: What causes temporally advanced serotonergic activity in response to stress in dominant males? Secondarily, what is the neural basis for the acute and chronic responses? The neural mechanisms for transduction of the relevant behavioral signals are very plastic. Behavioral experience and visual stimuli can produce very rapid responses. Faster and greater responsiveness may be stimulated by restraint stress, social stress and the absence of social sign stimuli (e.g. eyespots of the lizard Anolis carolinensis). Stress response machinery provides regulatory factors necessary to modify social behavior, and to adapt it for specific contexts. Serotonergic activity is rapidly modified by glucocorticoids and GABA, and also by CRF under conditions of previous stress or in combination with AVP. Advancing acute elevation of serotonergic activity may be a distinguishing characteristic of dominant males. Social events add contextual conditioning to brain transmitter activity, with social information processed in a distributed fashion. Medial amygdala manifests delayed serotonergic response compared to hippocampus and nucleus accumbens, and is therefore a good candidate to mediate chronic stress responsiveness. Limiting or delaying acute effects, in addition to chronic serotonergic activity, may be the distinguishing characteristics of subordinate males. Monoamines, glucocorticoids, testosterone, CRF, AVP, AVT, play neuromodulatory roles producing context appropriate behavior.