The rodent accessory olfactory system

The accessory olfactory system contributes to the perception of chemical stimuli in the environment. This review summarizes the structure of the accessory olfactory system, the stimuli that activate it, and the responses elicited in the receptor cells and in the brain. The accessory olfactory system consists of a sensory organ, the vomeronasal organ, and its central projection areas: the accessory olfactory bulb, which is connected to the amygdala and hypothalamus, and also to the cortex. In the vomeronasal organ, several receptors—in contrast to the main olfactory receptors—are sensitive to volatile or nonvolatile molecules. In a similar manner to the main olfactory epithelium, the vomeronasal organ is sensitive to common odorants and pheromones. Each accessory olfactory bulb receives input from the ipsilateral vomeronasal organ, but its activity is modulated by centrifugal projections arising from other brain areas. The processing of vomeronasal stimuli in the amygdala involves contributions from the main olfactory system, and results in long-lasting responses that may be related to the activation of the hypothalamic–hypophyseal axis over a prolonged timeframe. Different brain areas receive inputs from both the main and the accessory olfactory systems, possibly merging the stimulation of the two sensory organs to originate a more complex and integrated chemosensory perception.     

Functional Architecture of the Vomeronasal Organ of the Frog (Genus Rana)

Abstract The vomeronasal organ in the frog, genus Rana, is composed of three interconnected cavities; superior, middle and inferior, which are separated from and anterior to the principal olfactory cavity. The superior cavity is found just underneath the external naris and forms a vestibule both for the principal olfactory organ and the vomeronasal organ. The vomeronasal sensory epithelium is located in the medial region of the inferior cavity and contains ciliated cells and microvillous receptor cells. Inspection of microscopic sections of frogs that had been swimming in fluorescent colorants revealed fluorescence on the surface of the vomeronasal organ, but not on that of the olfactory organ. Observations in vivo show that water enters via the external naris by two fissures, one on each side of the movable nasal lid, passes the middle cavity to flow via the sensory epithelium of the inferior cavity. The design of the frog nose makes it possible for this amphibious animal to sample the chemical composition of its environment; above water the frog can inhale air and expose its olfactory organ to volatile substances; in water the vomeronasal organ samples water-borne substances. These new findings are discussed in relation to the air/water interface and the position of the amphibians in the evolution of terrestrial vertebrates.     

Sensory coding of pheromone signals in mammals

The vomeronasal organ (VNO) of mammals plays an essential role in the detection of pheromones, chemical cues secreted by animals that elicit genetically programmed sexual and aggressive behaviors among conspecifics. The recent characterization of genes encoding molecular components of the VNO sensory response suggests that VNO neurons express a unique set of molecules to recognize and translate pheromone signals into neuronal electrical activity. Identification of these genes, which include putative pheromone receptor genes, has offered a new opportunity to uncover basic principles of pheromone sensory processing and important aspects of vomeronasal development.     

Parallel thalamic pathways for whisking and touch signals in the rat

In active sensation, sensory information is acquired via movements of sensory organs; rats move their whiskers repetitively to scan the environment, thus detecting, localizing, and identifying objects. Sensory information, in turn, affects future motor movements. How this motor-sensory-motor functional loop is implemented across anatomical loops of the whisker system is not yet known. While inducing artificial whisking in anesthetized rats, we recorded the activity of individual neurons from three thalamic nuclei of the whisker system, each belonging to a different major afferent pathway: paralemniscal, extralemniscal (a recently discovered pathway), or lemniscal. We found that different sensory signals related to active touch are conveyed separately via the thalamus by these three parallel afferent pathways. The paralemniscal pathway conveys sensor motion (whisking) signals, the extralemniscal conveys contact (touch) signals, and the lemniscal pathway conveys combined whisking–touch signals. This functional segregation of anatomical pathways raises the possibility that different sensory-motor processes, such as those related to motion control, object localization, and object identification, are implemented along different motor-sensory-motor loops.     

Something in the air? New insights into mammalian pheromones

Olfaction is the dominant sensory modality for most animals and chemosensory communication is particularly well developed in many mammals. Our understanding of this form of communication has grown rapidly over the last ten years since the identification of the first olfactory receptor genes. The subsequent cloning of genes for rodent vomeronasal receptors, which are important in pheromone detection, has revealed an unexpected diversity of around 250 receptors belonging to two structurally different classes. This review will focus on the chemical nature of mammalian pheromones and the complementary roles of the main olfactory system and vomeronasal system in mediating pheromonal responses. Recent studies using genetically modified mice and electrophysiological recordings have highlighted the complexities of chemosensory communication via the vomeronasal system and the role of this system in handling information about sex and genetic identity. Although the vomeronasal organ is often regarded as only a pheromone detector, evidence is emerging that suggests it might respond to a much broader variety of chemosignals.     

Discrimination of chemical stimuli in conspecific fecal pellets by a visually adept iguanid lizard,Crotaphytus collaris

Iguanid lizards are known for visual acuity and a diminished vomeronasal organ, which has led to mixed conclusions on whether iguanids use chemical cues. The collared lizard, Crotaphytus collaris, is a territorial iguanid that lives in open rocky habitats. Fecal pellets placed prominently on open rocky perches may provide an ideal mechanism for intraspecific chemical signaling. In order to determine whether collared lizards can discriminate between chemical stimuli found in conspecific fecal pellets, we collected 24 males and 25 females to analyze sex-specific behavioral responses via tongue-flicks and a newly observed behavior for the species, gular pumps, to cotton swabs containing water, cologne, chemical stimuli from conspecific male and female fecal pellets, and the lizard’s own fecal pellet. Both sexes were able to discriminate chemical stimuli from water via at least one behavior. Male collared lizards exhibited greater rates of response (tongue-flick and gular pumps) toward male fecal pellets when compared to the negative water control. Our results also suggest individuals may be able to discriminate between fecal pellets, as indicated by generally greater (but non-significant) counts of male tongue-flick responses to male fecal pellets when compared to their own. Collared lizard chemical discrimination appears to utilize tongue-flick and gular pump behaviors, possibly associated with distinct chemosensory modes (vomerolfaction and olfaction). Based on this study, we suggest that chemical signals may play a greater role in intraspecific communication than previously thought in this highly visual lizard.     

Suprasternal gland secretion of male short-tailed opossum induces IP3 generation in the vomeronasal organ

Chemical communication is an important component of mammalian social behaviors. Gray short-tailed opossums (Monodelphis domestica) communicate by scent marking. The male opossum possesses a prominent suprasternal scent gland, extracts of which strongly attract female opossums. This attractivity remains unaltered following repeated lyophilization. The suprasternal gland secretion functions in a sexually dimorphic manner, i.e., it elicits elevated levels of IP(3) in the vomeronasal (VN) sensory epithelium of female opossums, but suppressed the levels of IP(3) in the VN sensory epithelium of male opossums. The elevated levels of IP(3) induced by suprasternal gland secretion in female vomeronasal sensory epithelium is inhibited by the G(i/o) specific inhibitor, NF023, but not its inactive analogue, NF007. It is also suppressed by specific antibodies to the alpha subunits of G(i) and G(o) proteins, by the phospholipase C inhibitor, U73122, as well as by GDPbetaS. Surprisingly, GDPbetaS itself enhances basal levels of IP(3) in female VN sensory epithelium. This GDPbetaS-induced increase in levels of IP(3) is reduced by the PLC inhibitor, U73122, but not by the G(i/o) inhibitor, NF023. In addition, GDP also enhances basal levels of IP(3). GDPbetaS, a known inhibitor of G-protein activation, thus appears to have dual functions: as both stimulator and inhibitor of IP(3) production in the VN sensory epithelium of opossums. In contrast, this nucleotide analogue functions as an inhibitor in the VN sensory epithelium of mice. The mechanism of signal transduction underlying the suprasternal gland secretion-elicited signals in the VN sensory epithelium of opossums appears to involve signals that are generated through activation of G-protein-coupled receptors and transduced via activation of G(i/o)-proteins and the effector, phospholipase C, resulting in an increased production of the second messenger, IP(3). The extracellular signals are thus amplified.     

A divergent pattern of sensory axonal projections is rendered convergent by second-order neurons in the accessory olfactory bulb

The mammalian vomeronasal system is specialized in pheromone detection. The neural circuitry of the accessory olfactory bulb (AOB) provides an anatomical substrate for the coding of pheromone information. Here, we describe the axonal projection pattern of vomeronasal sensory neurons to the AOB and the dendritic connectivity pattern of second-order neurons. Genetically traced sensory neurons expressing a given gene of the V2R class of vomeronasal receptors project their axons to six to ten glomeruli distributed in globally conserved areas of the AOB, a theme similar to V1R-expressing neurons. Surprisingly, second-order neurons tend to project their dendrites to glomeruli innervated by axons of sensory neurons expressing the same V1R or the same V2R gene. Convergence of receptor type information in the olfactory bulb may represent a common design in olfactory systems.     

A map of pheromone receptor activation in the mammalian brain

In mammals, the detection of pheromones is mediated by the vomeronasal system. We have employed gene targeting to visualize the pattern of projections of axons from vomeronasal sensory neurons in the accessory olfactory bulb. Neurons expressing a specific receptor project to multiple glomeruli that reside within spatially restricted domains. The formation of this sensory map in the accessory olfactory bulb and the survival of vomeronasal organ sensory neurons require the expression of pheromone receptors. In addition, we observe individual glomeruli in the accessory olfactory bulb that receive input from more than one type of sensory neuron. These observations indicate that the organization of the vomeronasal sensory afferents is dramatically different from that of the main olfactory system, and these differences have important implications for the logic of olfactory coding in the vomeronasal organ.     

Sensation in the gastrointestinal tract

There are similarities between sensation in the gastrointestinal tract (GI tract) and somatic sensation. This review concentrates on parasympathetic (vagal) components of GI sensation rather than the sympathetic (splanchnic) elements. A wide range of enteroceptors have been described over the whole length of the gut which subserve several different sensory modalities. Fibres from these enteroceptors project to the medulla, primarily to the nucleus of the solitary tract. In the medulla there is considerable integration of afferent information from different parts of the GI tract. Regulatory peptides are present both in the brain and in the GI tract. It is likely that these peptides may play a role in the modulation of sensory information in the medulla. Parallels may be drawn at a receptor level between somatic sensation and sensation in the GI tract. More centrally, sensory mechanisms relating to the gut seem less highly organized than in somatic sensation. This reduced influence of the central nervous system in GI tract sensation may be explained by the presence in the gut of a highly sophisticated intrinsic nervous system, the enteric nervous system, which pre-programmes many of the functions of the GI tract.     

Differential histochemical localization patterns of reduced nicotinamide adenine dinucleotide phosphate-diaphorase and neuronal nitric oxide synthase during postnatal development of the rat vomeronasal organ

The present study was undertaken to examine the localization patterns of nicotinamide adenine dinucleotide phosphate-diaphorase (NADPH-d) by enzyme histochemistry and neuronal nitric oxide synthase (NOS) by immunohistochemistry in the vomeronasal organ of rat from postnatal day 0 for 8 weeks (adult). Nicotinamide adenine dinucleotide phosphate-diaphorase activity was not observed in the sensory epithelium of the vomeronasal organ at postnatal day 0 (the day of birth) and at day 1. At postnatal day 2, NADPH-d activity was observed in several vomeronasal neurons and on the surface of the sensory epithelium. From 25 days through adulthood, the number of vomeronasal neurons having NADPH-d activity increased gradually. On the other hand, neuronal NOS immunoreactivity was not observed in the sensory epithelium of the vomeronasal organ in newborns or in the adult rat. In this study, it is suggested that the nitric oxide pathway in the sensory epithelium of the vomeronasal organ comes into play beyond postnatal day 3. Moreover, it was found that NADPH-d and neuronal NOS are not colocalized in the sensory epithelium of the developing rat vomeronasal organ.     

Encoding olfactory signals via multiple chemosensory systems

Most animals have evolved multiple olfactory systems to detect general odors as well as social cues. The sophistication and interaction of these systems permit precise detection of food, danger, and mates, all crucial elements for survival. In most mammals, the nose contains two well described chemosensory apparatuses (the main olfactory epithelium and the vomeronasal organ), each of which comprises several subtypes of sensory neurons expressing distinct receptors and signal transduction machineries. In many species (e.g., rodents), the nasal cavity also includes two spatially segregated clusters of neurons forming the septal organ of Masera and the Grueneberg ganglion. Results of recent studies suggest that these chemosensory systems perceive diverse but overlapping olfactory cues and that some neurons may even detect the pressure changes carried by the airflow. This review provides an update on how chemosensory neurons transduce chemical (and possibly mechanical) stimuli into electrical signals, and what information each system brings into the brain. Future investigation will focus on the specific ligands that each system detects with a behavioral context and the processing networks that each system involves in the brain. Such studies will lead to a better understanding of how the multiple olfactory systems, acting in concert, offer a complete representation of the chemical world.     

Encoding Olfactory Signals via Multiple Chemosensory Systems

ABSTRACT

Most animals have evolved multiple olfactory systems to detect general odors as well as social cues. The sophistication and interaction of these systems permit precise detection of food, danger, and mates, all crucial elements for survival. In most mammals, the nose contains two well described chemosensory apparatuses (the main olfactory epithelium and the vomeronasal organ), each of which comprises several subtypes of sensory neurons expressing distinct receptors and signal transduction machineries. In many species (e.g., rodents), the nasal cavity also includes two spatially segregated clusters of neurons forming the septal organ of Masera and the Grueneberg ganglion. Results of recent studies suggest that these chemosensory systems perceive diverse but overlapping olfactory cues and that some neurons may even detect the pressure changes carried by the airflow. This review provides an update on how chemosensory neurons transduce chemical (and possibly mechanical) stimuli into electrical signals, and what information each system brings into the brain. Future investigation will focus on the specific ligands that each system detects with a behavioral context and the processing networks that each system involves in the brain. Such studies will lead to a better understanding of how the multiple olfactory systems, acting in concert, offer a complete representation of the chemical world.     

Mathematical requirements of visual–vestibular integration

This article addresses the intersection between perceptual estimates of head motion based on purely vestibular and purely visual sensation, by considering how nonvisual (e.g. vestibular and proprioceptive) sensory signals for head and eye motion can be combined with visual signals available from a single landmark to generate a complete perception of self-motion. In order to do this, mathematical dimensions of sensory signals and perceptual parameterizations of self-motion are evaluated, and equations for the sensory-to-perceptual transition are derived. With constant velocity translation and vision of a single point, it is shown that visual sensation allows only for the externalization, to the frame of reference given by the landmark, of an inertial self-motion estimate from nonvisual signals. However, it is also shown that, with nonzero translational acceleration, use of simple visual signals provides a biologically plausible strategy for integration of inertial acceleration sensation, to recover translational velocity. A dimension argument proves similar results for horizontal flow of any number of discrete visible points. The results provide insight into the convergence of visual and vestibular sensory signals for self-motion and indicate perceptual algorithms by which primitive visual and vestibular signals may be integrated for self-motion perception.     

Heterogeneity in the accessory olfactory system

The mammalian accessory olfactory bulb (AOB) is chemoarchitecturally heterogeneous in that it stains differentially with a number of markers; the receptor cells that project to the AOB are similarly heterogeneous. What is the significance of this heterogeneity? We have found that the AOB of the gray, short-tailed opossum, Monodelphis domestica, stains differentially with a number of 'markers': antibodies to olfactory marker protein (OMP) and the alpha subunit of the G protein Gi2, the lectin of Vicia villosa and NADPH-diaphorase. These markers stain the rostral AOB more strongly than the caudal AOB whereas, the G protein subunit G(o) alpha is located predominantly in the posterior subdivision of the AOB. This heterogeneity in the chemoarchitecture of the AOB may reflect a fundamental organizational dichotomy within the vomeronasal system that corresponds to a functional dichotomy. The vomeronasal sensory epithelium also exhibits a chemoarchitectural heterogeneity: receptor cells in the basal third are G(o) alpha-immunoreactive whereas the cells in the middle third are Gi2 alpha-immunoreactive. Tracing studies using WGA-HRP demonstrate that the neurons in the middle third of the vomeronasal sensory epithelium project their axons to the anterior AOB whereas those in the basal third appear to project to the posterior AOB.      

Organization of the vomeronasal organ in a plethodontid salamander

Salamanders in the family Plethodontidae show a unique behavior (nose-tapping) and have unique structures (nasolabial grooves) that may be used specifically to convey chemicals to the vomeronasal organ. The nasal structure of Plethodon cinereus was studied to determine if there is enhanced development of the vomeronasal organ compared with other salamander families that would correlate with use of these unique features. The vomeronasal organ in salamanders is found in a ventrolateral diverticulum of each main olfactory organ. P. cinereus has a more anteriorly placed vomeronasal organ within the diverticulum, and the posterior limit of each nasolabial groove is adjacent to the anterior limit of the vomeronasal organs. This suggests that the grooves deliver chemicals preferentially to the vomeronasal organs instead of to the main olfactory organs. In addition, the vomeronasal sensory epithelium is thickest anteriorly and is at its thinnest at about the level corresponding to the location of the vomeronasal organ in other salamander families. These adaptations suggest a specific mechanism of odorant delivery to the vomeronasal organ in plethodontid salamanders not found in other salamander families.     

Olfactory receptors and signalling elements in the Grueneberg ganglion

The Grueneberg ganglion (GG) is a cluster of neurones present in the vestibule of the anterior nasal cavity. Although its function is still elusive, recent studies have shown that cells of the GG transcribe the gene encoding the olfactory marker protein (OMP) and project their axons to glomeruli of the olfactory bulb, suggesting that they may have a chemosensory function. Chemosensory responsiveness of olfactory neurones in the main olfactory epithelium (MOE) and the vomeronasal organ (VNO) is based on the expression of either odorant receptors or vomeronasal putative pheromone receptors. To scrutinize its presumptive olfactory nature, the GG was assessed for receptor expression by extensive RT-PCR analyses, leading to the identification of a distinct vomeronasal receptor which was expressed in the majority of OMP-positive GG neurones. Along with this receptor, these cells expressed the G proteins Go and Gi, both of which are also present in sensory neurones of the vomeronasal organ. Odorant receptors were expressed by very few cells during prenatal and perinatal stages; a similar number of cells expressed adenylyl cyclase type III and G(olf/s), characteristic signalling elements of the main olfactory system. The findings of the study support the notion that the GG is in fact a subunit of the complex olfactory system, comprising cells with either a VNO-like or a MOE-like phenotype. Moreover, expression of a vomeronasal receptor indicates that the GG might serve to detect pheromones.     

Suprasternal gland secretion of male short-tailed opossum induces IP3 generation in the vomeronasal organ

Chemical communication is an important component of mammalian social behaviors. Gray short-tailed opossums (Monodelphis domestica) communicate by scent marking. The male opossum possesses a prominent suprasternal scent gland, extracts of which strongly attract female opossums. This attractivity remains unaltered following repeated lyophilization. The suprasternal gland secretion functions in a sexually dimorphic manner, i.e., it elicits elevated levels of IP₃ in the vomeronasal (VN) sensory epithelium of female opossums, but suppressed the levels of IP₃ in the VN sensory epithelium of male opossums. The elevated levels of IP₃ induced by suprasternal gland secretion in female vomeronasal sensory epithelium is inhibited by the G_i/o specific inhibitor, NF023, but not its inactive analogue, NF007. It is also suppressed by specific antibodies to the alpha subunits of G_i and G_o proteins, by the phospholipase C inhibitor, U73122, as well as by GDPβS. Surprisingly, GDPβS itself enhances basal levels of IP₃ in female VN sensory epithelium. This GDPβS-induced increase in levels of IP₃ is reduced by the PLC inhibitor, U73122, but not by the G_i/o inhibitor, NF023. In addition, GDP also enhances basal levels of IP₃. GDPβS, a known inhibitor of G-protein activation, thus appears to have dual functions: as both stimulator and inhibitor of IP₃ production in the VN sensory epithelium of opossums. In contrast, this nucleotide analogue functions as an inhibitor in the VN sensory epithelium of mice. The mechanism of signal transduction underlying the suprasternal gland secretion-elicited signals in the VN sensory epithelium of opossums appears to involve signals that are generated through activation of G-protein-coupled receptors and transduced via activation of G_i/o-proteins and the effector, phospholipase C, resulting in an increased production of the second messenger, IP₃. The extracellular signals are thus amplified.     

Taxonomic and sensory biases in the mate-choice literature: there are far too few studies of chemical and multimodal communication

The sexual selection literature has grown rapidly in recent years. In an effort to elucidate biases in the focus of current mate-choice research here, I review 297 studies among 230 species. Among taxa, studies of birds were most common (40% of all studies), with insects, fishes, and anurans less well represented (20%, 18%, 14%, respectively). All other taxa were poorly represented in the literature (<3%). Across sensory modalities, studies of visual and acoustic signals were most common (46%, 30%, respectively), with relatively few studies investigating chemical, tactile, and electrical signals in mate choice (3%, 3%, <1%, respectively). Most mate-choice studies of birds and fishes investigated visual signals, while the majority of insect and anuran studies investigated acoustic signals. While these associations may reflect biological realities—birds and anurans tend not to emphasize chemical cues in mate choice; electric communication may indeed be quite uncommon—they may also be grossly misleading: chemical cues are likely critical for mate choice in millions of insect species. Moreover, I suggest that the particularly high vulnerability of chemical communication networks to anthropogenic fouling should provide immediate motivation for many more studies of chemical signals in mate choice. Finally, I find that despite widespread acceptance that male displays are often comprised of multiple elements produced across sensory modalities, studies simultaneously investigating the use of multiple cues in mate choice are rare. While not exhaustive, this review identifies biases in the focus of mate-choice studies, and should serve to identify fruitful directions for future mate-choice research.