Helen B. Treloar

Glomerular formation in the developing rat olfactory bulb

Using the confocal microscope together with markers for the cellular components of glomeruli, we examined the spatiotemporal cellular interactions that occur between the axons of olfactory receptor cells, their dendritic targets, and glial cells during the critical period of glomerular formation. We have employed markers of immature and mature olfactory receptor cell axons, mitral/tufted cell dendrites, and glial cells as well as a synapse‐associated protein for double‐ and triple‐label immunocytochemistry. Axons of olfactory receptor cells grew into a dense dendritic zone of the olfactory bulb (comprising the dendrites of both mitral and tufted cells) between E17 and E18. At E19, these axons coalesced into protoglomeruli, which continued to develop until birth, when the basic anatomical structure of adult glomeruli emerged. Neither mitral/tufted cell dendrites nor olfactory bulb astrocytes became specifically associated with these protoglomeruli until E21. Ensheathing cells remained restricted to the outer nerve fiber layer and did not appear to contribute to glomerular formation. Finally, the synaptophysin staining has shown that synaptic constituents are expressed as early as E17, prior to the appearance of mature olfactory receptor cell axons. Based on these data, we have established a time line detailing the temporal and spatial interactions that occur between cell types during late embryonic rat olfactory bulb development. We conclude that the initial event in the formation of glomeruli is the penetration of the mitral/tufted cell dendritic zone by olfactory receptor cell axons. The coalescence of dendritic and glial processes into glomerular structures appears secondary to the arrival of the olfactory receptor cell axons. J. Comp. Neurol. 413:289–304, 1999.

Sublaminar organization of the mouse olfactory bulb nerve layer

Olfactory sensory neuron (OSN) axons coalesce to form the olfactory nerve (ON) and then grow from the olfactory epithelium to the olfactory bulb (OB), enter the olfactory nerve layer (ONL), reorganize extensively, and innervate specific glomeruli. Within the ON and ONL a population of glial cells, the olfactory ensheathing cells (OECs), surround OSN axon fascicles. To better understand the relationship between OECs and axon fascicles in the ONL of the adult mouse, we used confocal microscopy and antibodies to the low affinity nerve growth factor receptor p75 (p75), glial fibrillary acidic protein (GFAP), neuropeptide Y (NPY), and S‐100 to identify glia. Antibodies to olfactory marker protein (OMP) and neuronal cell adhesion molecule (NCAM) were used to identify OSN axons. Electron microscopy characterized the ONL ultrastructure. We found that glial processes were not uniformly distributed in the ONL of the mouse. The p75+ OEC processes were restricted to the ON and the outer ONL sublamina, and oriented parallel to the plane of the OB layers. In the inner ONL NPY+ OEC‐like processes were seen. GFAP+ processes were restricted to the inner ONL sublamina, the ONL/GL boundary, and the GL, where they delineated loosely aggregated axon fascicles that entered the glomeruli obliquely. S‐100+ processes and somata were distributed throughout the ONL; the outer and inner ONL were equivalent in their S‐100 staining. Ultrastructural studies showed that, although OECs could be identified in both the outer and inner ONL, in the latter, their relationship to bundles of OEC axons appeared less orderly than seen in the outer ONL. Our data demonstrate a differential organization of the ONL that could subserve distinct functions; axon extension may occur predominately in the outermost ONL, whereas glomerular targeting occurs in the inner sublamina of the ONL. J. Comp. Neurol. 446:68–80, 2002.

Composition of the migratory mass during development of the olfactory nerve.

The embryonic development of the olfactory nerve includes the differentiation of cells within the olfactory placode, migration of cells into the mesenchyme from the placode, and extension of axons by the olfactory sensory neurons (OSNs). The coalition of both placode‐derived migratory cells and OSN axons within the mesenchyme is collectively termed the “migratory mass.” Here we address the sequence and coordination of the events that give rise to the migratory mass. Using neuronal and developmental markers, we show subpopulations of neurons emerging from the placode by embryonic day (E)10, a time at which the migratory mass is largely cellular and only a few isolated OSN axons are seen, prior to the first appearance of OSN axon fascicles at E11. These neurons also precede the emergence of the gonadotropin‐releasing hormone neurons and ensheathing glia which are also resident in the mesenchyme as part of the migratory mass beginning at about E11. The data reported here begin to establish a spatiotemporal framework for the migration of molecularly heterogeneous placode‐derived cells in the mesenchyme. The precocious emigration of the early arriving neurons in the mesenchyme suggests they may serve as “guidepost cells” that contribute to the establishment of a scaffold for the extension and coalescence of the OSN axons. J. Comp. Neurol. 518:4825–4841, 2010.

Disrupted compartmental organization of axons and dendrites within olfactory glomeruli of mice deficient in the olfactory cell adhesion molecule, OCAM

There is an overall topographic connectivity in the axonal projections of olfactory sensory neurons from the olfactory epithelium (OE) to the olfactory bulb (OB). The molecular determinants of this overall topographic OE-OB connectivity are not known. For 20 years, the intriguing expression pattern of the olfactory cell adhesion molecule (OCAM) has made it the leading candidate as determinant of overall topographic OE-OB connectivity. Here, we have generated a strain of OCAM knockout mice by gene targeting. There were no obvious alterations in the distribution of olfactory sensory neurons within the OE or in the coalescence of axons into specific glomeruli. However, the compartmental organization of dendrites and axons within the glomeruli was disrupted. Surprisingly, the mutant mice exhibited an increase in olfactory acuity; they appeared to have a better sense of smell. Thus, despite its striking expression pattern, OCAM is not essential for overall topographic OE-OB connectivity. Instead, OCAM is required for establishing or maintaining the compartmental organization and the segregation of axodendritic and dendrodendritic synapses within glomeruli.

Nestin promoter/enhancer directs transgene expression to precursors of adult generated periglomerular neurons

The subventricular zone (SVZ) is a major neurogenic region in the adult brain. Cells from the SVZ give rise to two populations of olfactory bulb interneurons: the granule cells and periglomerular (PG) cells. Currently, little is known about the signaling pathways that direct these newly generated neurons to become either granule or PG neurons. In the present study, we used the nestin promoter and enhancer to direct expression of the tetracycline transactivator (tTA). We generated two independent strains of nestin‐tTA transgenic animals and crossed founder mice from both lines to mice containing a tetracycline‐regulated transgene (mCREB) whose expression served as a marker for the activity of the nestin‐tTA transgene. mCREB expression occurred in a subset of proliferating cells in the SVZ and rostral migratory stream in both lines. Surprisingly, in both lines of nestin‐tTA mice transgene expression in the olfactory bulb was limited to PG neurons and was absent from granule cells, suggesting that this nestin promoter construct differentiates between the two interneuronal populations. Transgene expression occurred in several subtypes of PG neurons, including those expressing calretinin, calbindin, GAD67, and tyrosine hydroxylase. These results suggest that a unique subset of SVZ precursor cells gives rise to PG, and not granule cells. The ability to express different transgenes within this subpopulation of neuronal precursors provides a powerful system to define the signals regulating the differentiation and survival of adult‐generated neurons in the olfactory bulb. J. Comp. Neurol. 475:128–141, 2004.

Cell surface carbohydrates and glomerular targeting of olfactory sensory neuron axons in the mouse

Cell surface carbohydrates have been implicated in axon guidance and targeting throughout the nervous system. We have begun to test the hypothesis that, in the olfactory system, a differential distribution of cell surface carbohydrates may influence olfactory sensory neuron (OSN) axon targeting. Specifically, we have examined the spatial distribution of two different plant lectins, Ulex europaeus agglutinin (UEA) and Dolichos biflorus agglutinin (DBA), to determine whether they exhibit differential and reproducible projections onto the main olfactory bulb. Each lectin exhibited a unique spatial domain of glomerular labeling that was consistent across animals. UEA labeling was strongest in the ventral aspect of the olfactory bulb; DBA labeling was strongest in the dorsal aspect of the olfactory bulb. Some evidence for colocalization was present where these two borders intersected. Large areas of the glomerular layer were not labeled by either lectin. To determine whether patterns of lectin labeling were reproducible at the level of individual glomeruli, UEA labeling was assessed relative to M72‐IRES‐taulacZ‐ and P2‐IRES‐taulacZ‐labeled axons. Although glomeruli neighboring these two identified glomeruli were consistently labeled with UEA, none of the lacZ positive axons was lectin labeled. Labeling of vomeronasal sensory neuron axons in the accessory olfactory bulb was more uniform for the two lectins. These data are the first to show a differential distribution of UEA vs. DBA labeling in the main olfactory bulb and are consistent with the hypothesis that a differential distribution of cell surface carbohydrates, a glycocode, may contribute to the targeting of OSN axons. J. Comp. Neurol. 467:22–31, 2003.

Chromosomal Location-Dependent Nonstochastic Onset of Odor Receptor Expression

As odorant receptors (ORs) are thought to be critical determinants of olfactory sensory neuron (OSN) axon targeting and organization, we examined the spatiotemporal onset of mice ORs expression from the differentiation of OSNs in the olfactory placode to an aging olfactory epithelium. ORs were first detected in the placode at embryonic day 9 (E9), at the onset of OSN differentiation but before axon extension. By E13, 22 of 23 ORs were expressed. Onset of individual OR expression was diverse; levels and patterns of expression were unique for each OR. Regional distribution of ORs within zones of the olfactory epithelium appeared stable across development; adult-like patterns were observed by E13. Finally, analysis of OR expression and chromosomal location suggests that ORs are not stochastically expressed; they show evidence of coordinated expression. Collectively, these studies demonstrate that ORs are not equally represented in the “olfactome” across an animals lifespan.

Tenascin-C Is an Inhibitory Boundary Molecule in the Developing Olfactory Bulb

We recently described the boundary-like expression pattern of the extracellular matrix molecule tenascin-C (Tnc) in the developing mouse olfactory bulb (OB) (Shay et al., 2008). In the present study, we test the hypothesis that Tnc inhibits olfactory sensory neuron (OSN) axon growth in the developing OB before glomerulogenesis. The period of time before glomerular formation begins, when axons remain restricted to the developing olfactory nerve layer (ONL), is crucial for axon sorting. Here, we show with in vitro analyses that OSN neurite outgrowth is inhibited by Tnc in a dose-dependent manner and that, in stripe assays, axons preferentially avoid Tnc. Using Tnc-null mice, we also show that that glomerular development is delayed in the absence of Tnc. In wild-type mice, OSN axons coalesce into immature or protoglomeruli, which further differentiate and segregate into glomeruli. Glomeruli are first identifiable as discrete structures at birth. In null mice, glomeruli appear immature at birth, remain fused to the ONL, and have a significantly larger diameter compared with wild-type controls. By postnatal day 4, null glomeruli are indistinguishable from controls. Thus, OSN axons appear delayed in their coalescence into glomerular structures. These data correlate with behavioral reports of Tnc-null mice, which are delayed by 24 h in their acquisition of an olfactory behavior (de Chevigny et al., 2006). Collectively, these data demonstrate that Tnc is an inhibitory boundary molecule in the developing OB during a key period of development.

Inverse expression of olfactory cell adhesion molecule in a subset of olfactory axons and a subset of mitral/tufted cells in the developing rat main olfactory bulb

The projection of olfactory sensory neuron (OSN) axons from the olfactory epithelium (OE) to the olfactory bulb (OB) is highly organized but topographically complex. Evidence suggests that odorant receptor expression zones in the OE map to the OB about orthogonal axes. One candidate molecule for the formation of zone‐specific targeting of OSN axon synapses onto the OB is the olfactory cell adhesion molecule (OCAM). OCAM+ OSNs are restricted to three of the four zones in the OE and project their axons to the ventral OB where they form synapses with mitral/tufted (M/T) cells. To determine when this zonal connection is established, we have examined OCAM expression in rat olfactory system, during seminal periods of glomerular formation. OCAM+ axons sort out in the ventral olfactory nerve layer of the OB before glomerular formation. Surprisingly, OCAM was also expressed transiently by subsets of M/T cell dendrites located in the dorsal OB. The expression of OCAM by OSN axons and M/T dendrites was asymmetrical; in the dorsal OB, OCAM− OSN axons synapsed on OCAM+ M/T dendrites, whereas in the ventral OB, OCAM+ OSN axons synapsed on OCAM− M/T dendrites. The restricted spatial map of OCAM+ M/T cells appeared earlier in development than the zonal segregation of OCAM+ OSN axons. Thus, OCAM on M/T cell dendrites may act in a spatiotemporal window to specify regions of the developing rat OB, thereby establishing a foundation for mapping of the OE zonal organization onto the OB. J. Comp. Neurol. 458:389–403, 2003.

Cell surface carbohydrates reveal heterogeneity in olfactory receptor cell axons in the mouse

Abstract. Cell surface carbohydrates, both in the olfactory system and elsewhere, have been proposed to play critical roles in axon guidance and targeting. Recent studies have used plant lectins to study the heterogeneous distribution of carbohydrates in the olfactory system. One lectin, Dolichos biflorus agglutinin (DBA), heterogeneously labels subsets of glomeruli. In the olfactory epithelium DBA labeled a subset of olfactory sensory neurons (OSNs) including their cilia, dendrites, and somata. OSN axons were also labeled and readily observed in the olfactory nerve and bulb. The patterns of glomerular innervation by DBA labeled (DBA+) axons were diverse; some glomeruli contained many labeled axons, while others contained few or no labeled axons. To characterize the heterogeneous innervation of glomeruli, we double labeled olfactory bulbs with DBA and an antibody to olfactory marker protein (OMP). OMP colocalized in most, but not all, DBA+ axons. To determine if those axons that did not express OMP were immature, we double labeled olfactory bulbs with DBA and anti-GAP-43. GAP-43 rarely colocalized with DBA, suggesting that DBA+ axons are not, as a population, immature. Triple labeling with all three markers revealed a small subset of DBA+ axons which did not express either OMP or GAP-43. Electron microscopy established that DBA labels axons in the olfactory nerve and DBA-labeled axons form typical glomerular axodendritic synapses.