Abstract
To address the hypothesis that retinoids produced by synthesizing enzymes present in the primary olfactory system influence the mouse olfactory sensory map, we expressed a dominant-negative retinoic acid receptor selectively in olfactory sensory neurons. We show that neurons deficient in nuclear retinoid signaling are responsive to odors and form correct odorant receptor-specific axonal projections to target neurons in the olfactory bulb of the brain. Subsequent to the formation of the map, the neurons die prematurely by retrograde-driven caspase-3 activation, which resembles the previously described mechanism of neural death after olfactory bulb ablation. This neurodegenerative event is initiated the second postnatal week and occurs in the adult animal without a compensatory increase of progenitor cell proliferation. In addition, we find that nuclear retinoid signaling is required for the expression of a retinoic acid-degrading enzyme, Cyp26B1, in a small fraction of mature neurons. Collectively, the results provide evidence for a role of locally regulated retinoid metabolism in neuroprotection and in determining population size of neurons at a late stage of neural circuit formation.
Introduction
Localized synthesis and degradation of bioactive vitamin A derivatives (retinoids) mediated by retinal dehydrogenases (RALDHs) and specific cytochrome P450 enzymes (Cyp26s) provide a mechanism for temporal and spatial regulation of retinoid signaling in the nervous system (McCaffery et al., 1999; Thompson Haskell et al., 2002; Reijntjes et al., 2005). Retinoids influence early developmental events such as patterning, neurogenesis, neuronal specification, and axonal outgrowth by binding to nuclear retinoid receptors [retinoic acid receptors (RARs) and retinoid X receptors (RXRs)] that regulate gene transcription (Chambon, 1996; Maden, 2001). Retinoids continue to play a critical role in the mature nervous system, effecting adult neurogenesis, plasticity, and cognitive decline associated with aging (Chiang et al., 1998; Etchamendy et al., 2001; Misner et al., 2001; Thompson Haskell et al., 2002; Crandall et al., 2004; Wang et al., 2005). In addition, defective retinoid signaling has been implicated in neurodegenerative diseases such as Alzheimer’s disease and amyotrophic lateral sclerosis (Corcoran et al., 2002, 2004; Goodman and Pardee, 2003).
Olfactory sensory neurons (OSNs) in the olfactory epithelium and their synaptic target structures, the glomeruli of the olfactory bulb, provide a useful system to determine the role of retinoid signaling during formation, refinement, maintenance, and/or regeneration of an axonal projection map in mammals. In mice, the olfactory projection map is formed by ∼1000 scattered subpopulations of OSNs, each expressing a specific odorant receptor gene, that project with their axons to topographically defined glomeruli (Ressler et al., 1994; Vassar et al., 1994). Dividing neural progenitor cells, located in the basal cell layer of the olfactory epithelium, replenish the OSNs that degenerate continuously in the adult animal (Graziadei and Graziadei, 1979; Schwob, 2002). Evidence that OSNs respond to retinoids has come from expression studies of RARs, RXRs, and cellular retinoic acid binding protein type I (CRABP-I), as well as from analyses of retinoic acid response element (RARE)-driven β-galactosidase (βgal) expression in transgenic mice (Whitesides et al., 1998; Gustafson et al., 1999; Krezel et al., 1999; Zetterstrom et al., 1999; Zhang, 1999; Asson-Batres et al., 2003a). The relevance of retinoid signaling not only during the initial morphogenesis of the olfactory epithelium (LaMantia et al., 2000) but also postdevelopmentally is indicated by the presence of RALDH-positive cells in the vicinity of OSN cell bodies and their axons in the olfactory nerve and olfactory bulb (Norlin et al., 2001; Niederreither et al., 2002; Wagner et al., 2002). A study of vitamin A-deficient adult rats has provided a link between retinoid signaling and regulation of cell dynamics in the olfactory epithelium of adult animals (Asson-Batres et al., 2003b). However, the pleiotropic effects of vitamin A derivatives have made it difficult to determine whether retinoid signals act directly or indirectly on OSNs and/or their progenitors.
We used the promoter of the olfactory marker protein (OMP) gene (Danciger et al., 1989) to generate transgenic mice with OSNs that express a mutated RAR variant (RARα403) that inhibits the function of endogenous RARs. This way, the direct responses of OSNs to retinoids during late stages of olfactory map formation and maintenance may be selectively examined. We provide evidence that RARE-dependent transcription and local homeostatic control of retinoids is required for the maintenance of a population of functional neurons with established projections and that inhibition of retinoid signaling results in postnatal and adult neurodegeneration.
Materials and Methods
Generation of transgenic mice.
The coding sequence of dominant-negative RAR (dnRAR) (hRARα403) (Damm et al., 1993) was ligated 3′ to a 6 kb fragment of the mouse OMP promoter and 5′ to a simian virus 40 (SV40) polyadenylation site (Alenius and Bohm, 2003). A DNA fragment corresponding to the OMP-dnRAR-SV40poly(A+) transgene was gel purified and microinjected into pronuclei of C57BL/6/CBA one-cell embryos. Four independent founder lines that expressed the dominant-negative RAR construct selectively in OSNs were generated. Transgenic founder mice were backcrossed to C57BL/6J mice (Taconic M & B, Ry, Denmark), for more than four generations. The progeny from all transgenic founder lines that expressed dnRAR displayed the same morphological phenotype in the olfactory epithelium (data not shown). All animal experiments were approved by the ethical committee at Umeå University.
In situ hybridization.
Tissue with olfactory mucosa were dissected from cervical dislocated mice and fixed overnight at 4°C in 4% paraformaldehyde in PBS. Tissues were cryoprotected in 30% sucrose at 4°C for 24 h, frozen in Tissue-Tek O.C.T. (Sakura Finetek, Torrance, CA), and cryosectioned at 12 μm and pretreated, hybridized, and washed (Alenius and Bohm, 2003). Sections were hybridized at 52°C overnight with 35S-labeled cRNA probes specific to the following: hRARα403 (1–2914 bp; GenBank accession number X06614), mRARα [expressed sequence tag (EST) clone; GenBank accession number BF120655], mRARβ2 (EST clone; GenBank accession number AA673166), and mRARγ (EST clone; GenBank accession number BI904383). Probes specific to different odorant receptors (M40, K20, and M50) were as described previously (Sullivan et al., 1995). Slides were dehydrated and processed for autoradiography using NTB-emulsion (Eastman Kodak, Rochester, NY) and exposed for 5–14 d at 4°C. In situ hybridization using digoxygenin-labeled Cyp26B1 (EST clone; GenBank accession number BQ770766) probe was performed as described previously (Schaeren-Wiemers and Gerfin-Moser, 1993). Hoechst 33258 was used as histological stain, and analysis was performed using both fluorescent and dark-field optics on a Zeiss (Oberkochen, Germany) Axioskop microscope with a Hamamatsu (Shizouka, Japan) digital CCD camera. Images were processed using Adobe Photoshop version 7.0.1 (Adobe Systems, San Jose, CA). Brightness and contrast adjustments of images were done linearly.
Immunohistochemistry and 5-bromo-2′-deoxyuridine labeling.
Olfactory mucosa and olfactory bulb tissue were dissected from cervical dislocated mice and fixed in 4% paraformaldehyde in PBS for 30–90 min at room temperature or overnight for phosphorylated-cAMP response element-binding protein (phospho-CREB) immunohistochemical analyses, cryoprotected in 30% sucrose at 4°C for 24 h, frozen in Tissue-Tek O.C.T., and cryosectioned (12–20 μm). Tissue of 4 weeks and older mice was decalcified for 10–20 min in RDO Rapid Decalcifier (Apex Engineering Products, Aurora, IL). c-Fos antigen retrieval was done by heat treatment in 10 mm citrate buffer, pH 6.0, for 10 min. Nonspecific background was blocked by incubation for 1 h in 2% bovine serum albumin in Tris-buffered saline (TBS) with 0.3% Triton X-100, followed by overnight incubation at 4°C in TBS, 0.3% Triton X-100 containing anti-phospho-histone 3 (H3) (1:500; Upstate Biotechnology, Lake Placid, NY), anti-activated caspase-3 (1:500; BD Biosciences, Mountain View, CA), anti-OMP (1:1000), anti-stathmin/SCG10 (1:1000), anti-tyrosine hydroxylase (TH) (1:500; Pel-Freez Biologicals, Rogers, AR), anti-phosphorylated CREB (1:200; Upstate Biotechnology), anti-c-Fos (1:4000; Oncogene Sciences, Uniondale, NY), and anti-OR256–17 [1:1000 (Strotmann et al., 2004)]. Sections were washed with TBS and 0.3% Triton X-100 and incubated for 1 h with fluorescently labeled secondary antibodies [cyanine 3-conjugated goat anti-rabbit IgG (Jackson ImmunoResearch, West Grove, PA) or Alexa Fluor 488-conjugated donkey anti-goat IgG (Invitrogen, Carlsbad, CA)]. Sections were counterstained with Hoechst 33258 (Sigma, St. Louis, MO). Double caspase-3/OMP images were produced using a Leica (Nussloch, Germany) DM IRB confocal microscope with argon and helium/neon lasers. Caspase-3-positive and OMP-positive cells were detected with a 40× oil-immersion lens using Alexa Fluor 488-conjugated donkey anti-rabbit IgG and Alexa Fluor 546-conjugated donkey anti-goat IgG (Invitrogen), respectively. A total of 60 and 80 caspase-3-positive cells in the neural cell layer of the olfactory epithelium of control and dnRAR transgenic mice, respectively, were identified by optical sectioning, and 1.5 μm Z images of positive cells were analyzed sequentially for OMP immunoreactivity. Intraperitoneal injections of 50 μg/g 5-bromo-2′-deoxyuridine (BrdU) (BD Biosciences PharMingen, San Diego, CA) were done three times with an interval of 3 h, and tissues were taken for analysis 24 h after the last injection. For the BrdU immunohistochemical analysis, an anti-BrdU antibody (1:10; BD Biosciences PharMingen) was used.
Odor exposure.
Odor exposure was done according to Norlin et al. (2005). Two-week-old mice were placed in an odor-free 4 dm3 plastic box with a tight seal for 20 min, after which an odor was presented by introducing a sealed, perforated container that contained 25 μl/dm3 pyridine. After exposure for 10 min, the odor was removed, mice were killed 60 min after the end of odor exposure, and tissues were processed for immunohistochemistry.
βgal-histochemical analyses of RARE, P2, and MOL2.3 reporter mice.
Transgenic mice were crossed to P2-IRES-tauLacZ mice (Mombaerts et al., 1996), MOL2.3-IRES-tauLacZ-IRES-GFP (Conzelmann et al., 2000), or RARE-Hsp-LacZ mice. Tissues from the F1 generation of these crosses were processed and sectioned at 20 μm as described above. Slides were rinsed three times for 20 min in 0.1 m phosphate buffer, 2 mm MgCl2, 5 mm EGTA, 0.02% Nonidet P-40, and 0.001% sodium deoxycholate. The staining reaction was performed at 37°C overnight in the same buffer, supplemented with 1 mg/ml 5-bromo-4-chloro-3-indolyl-β-d-galactopyranoside, 5 mm K3Fe(CN)6, and 5 mm K4Fe(CN)6. Sections were subsequently rinsed three times in PBS and counterstained with Hoechst 33258.
Quantification of βgal, phospho-H3, and activated caspase-3-positive OSNs.
The numbers of caspase-3-positive cells and βgal-positive cells in P2-IRES-tauLacZ, MOL2.3-IRES-tauLacZ, or RARE-LacZ mice were counted for every sixth (7-month-old mice), every fifth (4- and 6-week-old mice), or every fourth (2-week-old mice), every third (1-week-old mice), and every second (newborn mice) coronal section, throughout the rostrocaudal extent of the nasal cavity, and the numbers obtained were multiplied by six, five, four, three, or two, respectively, to estimate the total number per nasal cavity. The numbers of phospho-H3-positive cells were estimated in the same way, except that the region analyzed was limited to the olfactory epithelium that lined the septum. Numbers of phospho-CREB and c-Fos-positive cells were from a 330-μm-long epithelial section lining the septum. The thickness of the epithelium was quantified for each image, and the numbers of positive cells per square micrometer were calculated. The numbers of c-Fos-positive periglomerular cells were counted for a region of the periglomerular layer that spanned 10 glomeruli and that was located in the medial part of the olfactory bulb. Student’s t test (two-tailed) was used to determine statistical significance of all datasets.
Results
Reduced number of mature OSNs in postnatal OMP-dnRAR mice
To determine the role of RAR-dependent gene expression in OSNs, we generated transgenic mouse lines that expressed dnRAR under the transcriptional control of a 6 kb gene regulatory region of the mouse OMP gene that drives OSN-specific transgene expression in both immature and mature OSNs (Fig. 1A) (Alenius and Bohm, 2003). OMP and odorant receptor transcripts are expressed before olfactory axons form synapses with olfactory bulb neurons, and contact with the olfactory bulb is not necessary for their expression (Sullivan et al., 1995). The dnRAR used (hRARα403) inhibits the function of all RAR isoforms (RARα, RARβ, and RARγ), conceivably by forming transcriptionally inactive RARα403-RXR heterodimers (Damm et al., 1993). The dnRAR lacks the AF2 ligand-dependent transactivation domain and therefore does not mediate induced transcription in response to retinoic acid. However, RXR agonist-dependent activation of RARα403-RXR heterodimers cannot be excluded (Damm et al., 1993; Johnson et al., 1999). In situ hybridization analyses of transgenic animals, with a dnRAR-specific probe, showed that OMP promoter-driven dnRAR transcripts were, as expected, specifically expressed in the cell layers containing immature and mature OSNs throughout the olfactory epithelium lining the nasal cavity (Fig. 1B). Dividing neural progenitor cells, located in the basal cell layer of the olfactory epithelium, replenish the OSNs that degenerate continuously in the adult animal (Graziadei and Graziadei, 1979; Schwob, 2002). Newly generated immature OSNs migrate upward in the epithelium while accumulating the OMP protein to high steady-state levels. OMP immunohistochemical analyses showed that the olfactory epithelium of OMP-dnRAR and littermate control mice were indistinguishable with regard to cell organization, thickness, and OMP immunoreactivity at postnatal day 1 (PD1) (Fig. 1C). Interestingly, at 1 month of age (PD28), both the epithelial thickness and OMP immunoreactivity were reduced in transgenic mice compared with littermate controls (Fig. 1C). This, together with the fact that dietary vitamin A deficiency has been shown to reduce the number of mature OSNs in adult animals in a similar way (Asson-Batres et al., 2003b), provided strong evidence that retinoid signaling was inhibited because of dnRAR expression. However, in vitamin A-deficient animals, the thickness of the olfactory epithelium is unaltered because of a compensatory increase in the number of immature neurons (Asson-Batres et al., 2003b). Stathmin/SCG10 (SCG10) is a described marker for immature OSNs (Pellier-Monnin et al., 2001). Double-immunohistochemistry analysis showed that the OMP-positive cell layer was reduced, whereas the stathmin/SCG10-positive cell layer appeared unaltered in transgenic mice compared with control mice at PD28 (Fig. 1D). These results suggested that the thinner epithelium in the dnRAR-expressing transgenic mice was a consequence of a diminished population of mature OSNs. Interestingly, this postnatal loss of mature neurons was not associated with a corresponding expansion of immature OSNs, which is the case in an olfactory epithelium that regenerates after, e.g., axotomy (Schwob, 2002). To quantify the reduction of OSNs over time, we used the P2-IRES-tauLacZ reporter mouse line. This mouse line is modified to express a bicistronic transcript encoding both the P2 odorant receptor and βgal, which allows for quantification of the number of neurons specified to express one particular odorant receptor (Fig. 2A). Histochemical analyses of epithelial sections of control P2-IRES-tauLacZ mice showed that the number of P2-positive OSNs was increased during the first 2 weeks of postnatal life and declined thereafter (Fig. 2B). These time kinetics correlated with the known expansion of the olfactory epithelium during the first weeks of postnatal life and the following age-dependent diminution of total number of neurons in a given area in normal adult mice and rat (Fung et al., 1997; Weiler and Farbman, 1997). Interestingly, examination of P2-IRES-tauLacZ-expressing dnRAR revealed that the number of P2-positive neurons in the epithelium started to deviate significantly from control mice during the second postnatal week (Fig. 2B). The number of P2-positive neurons in mice that expressed the dnRAR transgene was found to be reduced by 40–60% compared with control mice from the second week to 6.5 months of life. Thus, the decrease in number of P2 neurons in the aging olfactory epithelium occurred substantially earlier in the transgenic mice. This decrease did not appear to be attributable to differences in the mechanism leading to postnatal expansion of the system because the kinetics did not differ during the first week of life (Fig. 2B). These results indicated that OMP-dnRAR transgenic mice were compromised in their ability to recover from an initial wave of postnatal loss of mature OSNs.
The P2 odorant receptor belongs to class II odorant receptors and is expressed in a medial zone of the epithelium, whereas MOL2.3 is a class I odorant receptor that is expressed in a dorsal zone of the epithelium (Mombaerts et al., 1996; Conzelmann et al., 2000). To verify that also class I receptor-expressing OSNs were reduced in number, we analyzed newborn and 1-month-old (PD28) progeny from OMP-dnRAR × MOL2.3-IRES-tauLacZ crosses. The results revealed that the number of MOL2.3-positive OSNs, similar to the P2-positive OSNs, was reduced in 1-month-old OMP-dnRAR mice but was not significantly altered in newborn mice compared with littermates controls (Fig. 2C). This analysis, together with in situ hybridization analyses using probes specific for additional odorant receptors, showed that the zonal pattern of odorant receptor expression was unaltered in OMP-dnRAR transgenic mice (supplemental Fig. S1A, available at www.jneurosci.org as supplemental material).
Expression of dnRAR inhibits RARE-mediated transcription in vivo
In situ hybridization analyses revealed that endogenous RARα and RARγ transcripts were highly expressed in cell layers of the epithelium containing mature OSN (Fig. 2D), whereas RARβ transcripts were sparsely distributed in cells of the olfactory epithelium as well as in cells of the lamina propria, underneath the epithelium (Fig. 2D). These results indicated that dnRAR in theory could inhibit the function of endogenous RARs in OSNs. RAR-RXR heterodimers control gene transcription through RAREs. The unaltered number of OSNs in the olfactory epithelium of newborn OMP-dnRAR mice allowed us to address whether dnRAR actually inhibited RARE-mediated gene transcription in OSNs in vivo. To address this issue, we used a transgenic reporter mouse line (RARE-Hsp-LacZ) (Rossant et al., 1991), in which RARE-driven transcription results in the accumulation of βgal activity. Histochemical analyses of RARE-Hsp-LacZ mice revealed a scattered distribution of a limited number of βgal-positive OSNs in the olfactory epithelium (Fig. 2E). The distribution of βgal-positive OSNs was similar to that reported by Whitesides et al. (1998) who used another RARE reporter mouse line to show that OSNs are responsive to endogenous retinoids. Importantly, histochemical analyses of the olfactory epithelium from newborn (PD1) control and dnRAR transgenic mice obtained from OMP-dnRAR × RARE-Hsp-LacZ crosses showed that the expression of dnRAR corresponded to a 60% reduction in the number of βgal-positive OSNs (Fig. 2C). The observation that RARE-driven βgal expression was reduced in newborn transgenic mice before the observed decline in OSN numbers suggested that dnRAR directly inhibited RARE-mediated transcription.
Repression exerted by unliganded retinoid receptors has been shown to be essential for certain developmental processes (Weston et al., 2003). Our result did not discriminate between the possibilities that dnRAR increased repression or decreased ligand-dependent activation of RARE-dependent transcription. However, because repression and ligand-dependent activation are mechanistically linked, these result indicated that dnRAR inhibited nuclear retinoid signaling.
Caspase-3 activation and absence of compensatory progenitor cell proliferation
To address whether the reduction of OSNs coincided with increased apoptosis, we performed immunohistochemical analyses for activated (cleaved) caspase-3. Quantification of activated caspase-3-positive OSNs in newborn mice showed that the numbers were similar in OMP-dnRAR and littermate control mice (Fig. 3A). In agreement with the observed loss of OSNs in OMP-dnRAR during the second postnatal week, we found that transgenic mice at this age (PD10) had a significantly increased number of caspase-3-positive OSNs compared with controls (Fig. 3A,C). At 1 month of age, this difference was even more pronounced (Fig. 3A). To analyze whether proliferation of progenitors was altered by dnRAR, we used the mitosis marker phospho-H3. Quantification of phospho-H3-positive cells in the olfactory epithelium revealed no significant difference in the number of mitotic cells in transgenic versus control mice at either PD10 or PD28 (Fig. 3B). To further examine the effects of dnRAR on cell proliferation, we quantified BrdU-positive nuclei in the basal and neural cell layers of the olfactory epithelium. The numbers of BrdU-positive nuclei per millimeter epithelium in control mice at PD7, PD14, and PD35 were 302 ± 24.9, 256 ± 31.8 and 106 ± 13.6, respectively. The corresponding numbers for dnRAR transgenic mice were similar: 316 ± 45.5, 274 ± 24.2, and 107 ± 16, respectively. Collectively, these results indicated that the decreased number of OSNs in adult dnRAR transgenic mice was attributable to increased cell death, which was not compensated for by increased progenitor cell proliferation.
Activation of caspase-3 in OSN axon terminals of newborn transgenic mice
Recent studies have shown that OSNs undergo caspase-mediated retrograde apoptosis after nerve transection or target cell ablation, during which an initial caspase-3 activation in axons is followed by apoptosis of OSN cell bodies (Fung et al., 1997; Cowan et al., 2001). To investigate whether the dnRAR-induced cell death that we observed occurred by a similar mechanism, we analyzed OSN axons at the level of the olfactory bulb for the presence of activated caspase-3. In newborn transgenic mice, but not littermate controls, we found activated caspase-3 immunoreactivity in the axon terminals in the forming glomeruli (Fig. 3D). At PD10, the caspase-3 immunoreactivity in transgenic mice was even more pronounced and was detected in the glomerular layer of the olfactory bulb and in the nerve layer (Fig. 3E, right). A faint signal was also present in the nerve layer of the olfactory bulb in control mice (Fig. 3E, left). The presence of activated caspase-3 in axon terminals several days before the accumulation of activated caspase-3 in the cell bodies (Fig. 3A) indicated that the mechanism of OSN death caused by decreased RARE-dependent transcription resembled the retrograde-driven type of death that has been reported to occur after nerve transection, olfactory bulbectomy, and target cell deprivation (Fung et al., 1997; Cowan et al., 2001). Results of double-immunohistochemical analyses by confocal microscopy (Fig. 3F) revealed that 55 and 73% of caspase-3-positive cells in the olfactory epithelium at PD14 were immunopositive also for OMP in control and dnRAR transgenic mice, respectively. The increased ratio of caspase-3/OMP-double positive cells together with the initial appearance of activated caspase-3 in axon terminals suggested that inhibition of RARE-dependent transcription influenced survival of mature OSNs that had reached target neurons in the olfactory bulb.
OSNs in OMP-dnRAR mice show unaltered axonal targeting
We next addressed whether the increased death of mature OSNs in OMP-dnRAR mice coincided with incorrect axonal targeting. OMP (Fig. 3G,H) and synaptophysin (data not shown) immunohistochemical analyses of mice at PD1 and PD14 showed that the overall organization of the nerve layer and the glomerular layer of the olfactory bulb were similar in transgenics and controls. However, in accordance with the increased death of mature OSNs, the nerve layer was relatively thinner in adult transgenic mice than in littermate controls (Fig. 3H). Axons with the same odorant recept or specificity are organized into the same few glomeruli. To visualize the topography of odorant receptor-specific projections, we analyzed whole-mount preparations from the progeny of OMP-dnRAR × P2-IRES-tauLacZ crosses. These analyses revealed a similar pattern of axonal convergence of the P2 OSN subpopulation to laterally and medially located glomeruli in the olfactory bulb of OMP-dnRAR transgenic and control mice at PD48 (Fig. 4A). Analyses of progeny from OMP-dnRAR × MOL2.3-IRES-tauLacZ crosses gave the same result (data not shown). Analyses with antibodies that recognize one specific odorant receptor [mOR256–17 (Strotmann et al., 2004)] confirmed that OSN axons expressing the same receptor converged to topographically defined glomeruli in both newborn (PD1) and 1-month-old (PD28) OMP-dnRAR transgenic mice (Fig. 4B). We interpreted these results to indicate that inhibition of RARE-dependent transcription did not cause receptor-specific OSN subpopulations to innervate an excessive number of glomeruli and, hence, that incorrect axonal targeting was unlikely to underlie the increased death rate of mature OSNs.
Expression of neural activity markers is not changed in OMP-dnRAR mice
To examine for the possibility that the increased death of OSNs in postnatal OMP-dnRAR mice was associated with a general decrease in odor-stimulated signaling, immunohistochemical analyses for proteins known to show an altered expression in response to neural activity was performed. The expression of TH in postsynaptic periglomerular cells in the olfactory bulb is downregulated several weeks after naris occlusion as well as in mice lacking an olfactory cyclic nucleotide-gated channel subunit gene required for odor-stimulated activity in the majority of OSNs (Baker et al., 1999). However, TH immunoreactivity in periglomerular cells was not significantly reduced in OMP-dnRAR at PD28 compared with littermate controls at PD28 (Fig. 4C). This suggested that mature OSNs in dnRAR transgenic were able to activate postsynaptic target cells. Another event associated with odorant receptor activation as well as neural survival is CREB phosphorylation (Watt et al., 2004). Our examination of the OSN epithelial layer at PD10 showed that OMP-dnRAR and control mice displayed a similar pattern and frequency of phospho-CREB-immunoreactive cells (Fig. 5A,D). This result indicated that expression of dnRAR did not inhibit a signaling pathway that has been implicated in OSN survival and odorant receptor activity. We have shown previously that exposing mice to an odor elicits increased c-Fos expression in different populations of mature OMP-positive OSNs depending on odor used, suggesting that c-Fos reflects cellular events regulated by odorant receptor stimulation (Norlin et al., 2005). Exposure of 2-week-old (PD14) mice for 10 min to pyridine resulted in a robust induction of c-Fos in both transgenic and control mice (Fig. 5B,D). The unaltered induction of c-Fos in response to an odor indicated that dnRAR did not inhibit odor-induced intracellular signaling. A marked induction of c-Fos was also evident in fractions of target cells in the periglomerular cells layers of olfactory bulb in both OMP-dnRAR and control mice (Fig. 5C,D). The 27 ± 4% decrease in c-Fos-positive periglomerular cells observed in exposed transgenic mice, compared with control mice, most likely reflected the reduced axonal input in transgenic mice attributable to the increased death of OSNs at PD14. Importantly, the fold induction of c-Fos-positive periglomerular cells (odor exposure/air exposure) (Fig. 5D) was similar in control and transgenic mice, which indicated that OSNs expressing dnRAR were able to activate postsynaptic target cells in response to odor.
A fraction of mature OSNs express the retinoid-degrading enzyme Cyp26B1 in an RAR-dependent manner
Conceivably, RALDH-expressing cells in the primary olfactory system produce retinoids that OSN receive via their cell bodies and/or axons (Norlin et al., 2001; Niederreither et al., 2002; Wagner et al., 2002). Localized retinoid degradation mediated by the Cyp26 subfamily of cytochrome P450 enzymes provides one mechanism to regulate retinoid homeostasis spatially within a tissue (McCaffery et al., 1999; Reijntjes et al., 2005). Because our results indicated that OSNs required nuclear retinoid signaling for their prolonged survival, an interesting possibility was that retinoid homeostasis normally influences the lifespan of mature OSNs. Interestingly, in situ hybridization analyses of control mice at PD28 revealed that OSNs, located in the apical neuronal cell layer of the epithelium, expressed high levels of Cyp26B1 mRNA (Fig. 6A). Moreover, Cyp26B1-positive OSNs were absent in OMP-dnRAR mice (Fig. 6A). In situ hybridization of newborn (PD1) mice with a digoxygenin-labeled Cyp26B1 probe showed that control mice had a limited number of OSNs (39 ± 7.9 per section), located close to the sustentacular cell layer, that expressed high levels of Cyp26B1 mRNA, whereas no expression was detected in dnRAR transgenic mice (Fig. 6B). Because newborn transgenic and control mice were found to have an equal number of OSNs, the result suggested that Cyp26B1 expression in the transgenic mice was abolished because of dnRAR-mediated inhibition of Cyp26B1 transcription.
Discussion
We show here that inhibition of retinoid signaling selectively in OSNs in vivo results in death of mature OSNs subsequent to the development of the olfactory sensory map. One important implication of this result is that it is possible to experimentally separate a retinoid-regulated survival mechanism that operates at a late stage of neural circuit formation, or during maintenance of established connections, from retinoid-regulated mechanisms that influence survival of neurons during early stages, e.g., during neurogenesis, establishment of neuronal identity, and formation of precise axonal projection patterns (Sockanathan et al., 2003; Wang et al., 2005). This finding is particularly relevant in light of studies that have demonstrated a fundamental role of retinoid signaling for the maintenance of mature brain function (Chiang et al., 1998; Etchamendy et al., 2001; Misner et al., 2001; Goodman and Pardee, 2003). It is also noteworthy that studies have shown that the amyloid precursor protein, which is involved in the pathogenesis of Alzheimer’s disease, normally promotes postdevelopmental neurite arborization (Leyssen et al., 2005) and that a γ-secretase generated fragment of the amyloid precursor protein has been shown to inhibit RARE-mediated transcription in vitro (Gao and Pimplikar, 2001).
The fact that dnRAR expression reduces the number of OMP-positive OSNs supports the conclusion that mature OSNs are specifically targeted for death in retinoid-depleted tissue (Asson-Batres et al., 2003b). However, in retinoid-depleted animals, a compensatory increase in OSN progenitor proliferation is observed (Asson-Batres et al., 2003b). Importantly, dying OSNs in OMP-dnRAR mice do not induce such an increase in cell division. Moreover, the total number of OSNs (immature plus mature) is unaltered in vitamin A-deficient rats, whereas it is reduced in adult OMP-dnRAR mice. Absence of a compensatory increase in progenitor cell proliferation in OMP-dnRAR mice indicates that OSN death rate per se does not determine the rate of progenitor cell proliferation. A similar conclusion has arisen from a study of transgenic mice with OSNs that express the antiapoptotic gene BclII under the control of the OMP promoter (Hayward et al., 2004). In these mice, OSNs show an increased half-life after olfactory bulb ablation, without causing a relative decrease in progenitor cell proliferation. The increase of progenitor cell proliferation in vitamin A-deficient animals and the absence of a compensatory increase in progenitor cell proliferation in OMP-dnRAR mice also open up the interesting possibility that a distinct retinoid-dependent mechanism regulates progenitor cell proliferation. Evidence that OMP-negative cells in the olfactory epithelium indeed are responsive to retinoids is supported by the scattered expression of RARβ together with the presence of βgal-positive cells in the sustentacular and basal cell layer of the olfactory epithelium, as well as in the in lamina propria of RARE-Hsp-LacZ mice. Moreover, CRABP-II has been shown to be selectively expressed in a subset of basal cells and in the sustentacular cells (Asson-Batres et al., 2003a). An alternative, but not mutually exclusive, hypothesis is that vitamin A deficiency influences neurogenesis in an RXR-dependent manner. RXRs regulate transcription as homodimers or by forming heterodimers with other nuclear receptors, and a neuroprotective function of endogenous RXR ligands that is mediated by Nurr1-RXR heterodimers occurs in the embryonic nervous system (Wallen-Mackenzie et al., 2003). However, it remains to be determined whether neurogenesis in the olfactory epithelium is regulated by RXR-specific agonists. In any case, our results suggest that an important function of retinoids in the primary olfactory system is to prolong survival of mature OSNs to maintain the differentiated (adult) population of connected OSNs.
Neural activity is central to OSN survival and several aspects of olfactory map refinement and maintenance (Zhao and Reed, 2001; Nakatani et al., 2003; Watt et al., 2004; Yu et al., 2004; Zou et al., 2004). We find that OSNs expressing dnRAR are normal with regard to cellular events that are associated with odorant receptor signaling, i.e., postsynaptic TH expression (Baker et al., 1999), CREB phosphorylation, and odor-induced presynaptic and postsynaptic expression of c-Fos (Watt et al., 2004; Norlin et al., 2005). Moreover, the phenotype of OMP-dnRAR mice is not similar to mice that are deficient in a cyclic nucleotide-gated channel subunit that is essential for odor-evoked activity (Baker et al., 1999), neither is the phenotype similar to that of mice genetically altered to express genes that diminish OSN excitability or synaptic release (Yu et al., 2004). Collectively, these findings indicate that the effect of retinoids on OSNs is mechanistically separate from positive effects of neural activity on cell survival.
There is evidence that OSN death induced after axonal damage or target deprivation is driven by retrograde propagation of activated caspase-3 from axon terminals to the cell bodies (Cowan et al., 2001; Cowan and Roskams, 2004). Interestingly, activated caspase-3 is present in axon terminals several days before its appearance in the OSN cell bodies of OMP-dnRAR mice. This result points to a connection between death caused by dnRAR expression and death caused by disruption of synaptic contacts. Caspase-3 activation by cell intrinsic or extrinsic pathways, associated with acute as well as chronic neurodegenerative disorders, is typically viewed as the final event of the cell death cascade. However, evidence now suggests that transient and localized nonapoptotic caspase-3 activation is required for normal cell function, e.g., during growth cone regeneration, synaptic remodeling, and circuit refinement (McLaughlin, 2004; Verma et al., 2005). It is thus possible that reduced retinoid signaling results in premature and/or enhanced levels of activated caspase-3 that normally is required transiently and in limited amounts during a plastic phase of neural circuit formation. Aberrant axonal OSN projections, formed during embryonic development, disappear during the first 2–3 weeks of postnatal life (Nakatani et al., 2003; Zou et al., 2004). This postnatal phase of refinement thus coincides with a massive increase of activated caspase-3 in axons and death of OSNs in OMP-dnRAR transgenic mice. Interestingly, maintenance of aberrant OSN projections correlates with prolonged OSN survival (Zou et al., 2004).
Conceivably, inhibition of retinoid signaling changes the activity of a protein(s), which regulates the extent, duration, and/or retrograde transport of activated caspase-3 in the axons. The recent identification of dynactin-mediated retrograde transport of activated initiator caspase-8 and the finding that p75, the low-affinity NGF receptor, may function as an upstream death receptor in the mechanism leading to retrograde apoptosis of OSNs provides an interesting starting point for the identification of such protein(s). Additional candidate proteins are Trk and glial cell line-derived neurotrophic factor receptors that influence the survival of cultured embryonic sympathetic neurons in a retinoid-dependent manner (Plum et al., 2001; Doxakis and Davies, 2005).
Conceivably, retinoids are produced by RALDH-positive cells in nerve sheaths, meninges, and periglomerular cells of the olfactory bulb (Norlin et al., 2001; Niederreither et al., 2002; Wagner et al., 2002), and it has been suggested that CRABP-I in OSN axons capture and transport retinoic acid to the OSN nucleus (Gustafson et al., 1999; Asson-Batres et al., 2003a). The possibility that cells in the proximity of OSN axons may be a source of retinoids essential for OSN survival is interesting considering the special attention paid to the capacity of cells in the olfactory nerve to stimulate repair after transplantation into areas of spinal cord injury (Mackay-Sim, 2005). Moreover, studies of OSN turnover after olfactory bulb ablation have established that OSNs are trophically dependent on the olfactory bulb for their prolonged survival. The neuroprotective factor(s) mediating this effect has not been identified. Because RALDH-positive cells are also depleted after olfactory bulb ablation, it is interesting to speculate that retinoids may be such a trophic factor required. However, these hypotheses do not exclude the possibility that retinoid production by RALDH-positive cells in the vicinity of mature OSN cell bodies in the epithelium contributes to OSN survival. A study of chicken OSNs has shown that embryonic OSNs are more resistant than postnatal neurons to apoptosis caused by axotomy (Mathonnet et al., 2002). This result was interpreted to be attributable to a greater plasticity of embryonic neurons and that embryonic and postnatal OSNs may depend differently on local and target-derived factors. Such an interpretation may also account for the differential sensitivity of embryonic and postnatal OSNs to dnRAR expression. In this respect, it is particularly interesting that embryonic and postnatal olfactory epithelium have been shown to differ with regard to both the level and the distribution of RALDH expression (Niederreither et al., 2002). Whereas RALDHs produce retinoic acid, it is currently thought that catabolic Cyp26 enzymes mediate negative feedback control of retinoic acid signaling. We find that Cyp26B1 is expressed in a subpopulation of OSNs, located just underneath the sustentacular cell layer, and that the expression of this enzyme decreases before the effect of dnRAR expression on cell survival. This result is in accordance with studies that have shown RARα-dependent induction of Cyp26B1 expression (Reijntjes et al., 2005). Because the activity of Cyp26B1, like dnRAR, inhibits retinoic acid function, it possible that the Cyp26B1-positive OSNs in postnatal and adult normal mice are more vulnerable to die in response to events that lead to caspase-3 activation in axons. The death induced by dnRAR may therefore pertain to the way by which the number of mature OSNs is controlled normally.
In summary, our results provide the first in vivo evidence for a direct role of retinoid signaling in the survival of mature neurons in the postnatal and adult animal. The results also indicate that homeostatic control of retinoids can directly influence the population size of functional neurons with established axonal projections. Thus, our results are consistent with a role for defective retinoid signaling in neurodegenerative disease.
Footnotes
-
This work was supported by Swedish Natural Science Research Council Grant B5101-1250/2001 and Deutsche Forschungsgemeinschaft Sonderforschungsbereich 495. M.H. was supported by a National Network in Neuroscience graduate student fellowship (a Stiftelsen för Strategisk Forskning). We thank Dr. Peter Mombaerts for kindly providing P2-IRES-tauLacZ mice, Dr. Janet Rossant for the RARE-HspLacZ mice, Dr. Frank Margolis for the OMP antibody, and Dr. Martin Gullberg for the Stathmin/SCG10 antibody.
- Correspondence should be addressed to Staffan Bohm, Department of Molecular Biology, Umeå University, Umeå, SE901 87 Sweden. Email: staffan.bohm{at}molbiol.umu.se