Abstract
Sensory processing is strongly modulated by different brain and behavioral states, and this is based on the top–down modulation. In the olfactory system, local neural circuits in the olfactory bulb (OB) are innervated by centrifugal afferents in order to regulate the processing of olfactory information in the OB under different behavioral states. The purpose of the present study was to explore the organization of neural networks in olfactory-related cortices and modulatory nuclei that give rise to direct and indirect innervations to the glomerular layer (GL) of the OB at the whole-brain scale. Injection of different recombinant attenuated neurotropic viruses into the GL showed that it received direct inputs from each layer in the OB, centrifugal inputs from the ipsilateralanterior olfactory nucleus (AON), anterior piriform cortex (Pir), and horizontal limb of diagonal band of Broca (HDB), and various indirect inputs from bilateral cortical neurons in the AON, Pir, amygdala, entorhinal cortex, hippocampus, HDB, dorsal raphe, median raphe and locus coeruleus. These results provide a circuitry basis that will help further understand the mechanism by which olfactory information-processing in the OB is regulated.
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Introduction
It is evident that attention, emotion, and experience significantly affect perception, learning and memory. Top–down modulation is considered to play a crucial role in influencing the status of the brain [1]. In the olfactory neural system, the most important task is to precisely represent odor information under different brain and behavioral status, such as when sniffing, anesthetized, awake, behaving, and being rewarded [2]. The principles of neuroanatomical structures provide an important reference for how the sensory world is represented in the pattern of neuronal activity [3]. Previous studies have shown the neurons arising from higher cortical regions, including olfactory cortex, send precise top–down projections to different layers of the olfactory bulb (OB), thereby regulating odor perception and olfactory-related learning and memory under different brain and behavioral states [2,3,4,5,6].
Olfactory perception begins at the olfactory mucosa (or olfactory epithelium) in the nasal cavity. Olfactory sensory neurons (OSNs) convert the odor information into electrical signals through binding between odors and receptors and send it to the OB, where odorant information is continuously processed by complex local neural circuits and projected to different regions of olfactory cortex [7]. The OB is the first processing center of odor information, where the odorant type, concentration, and constituents are encoded as the spatial and temporal response characteristics of various neurons to facilitate decoding in the olfactory cortex [8]. In consequence, the OB plays the most critical role in odor threshold, odor discrimination, and odor-related learning and memory [9]. Apart from transmitting information to the higher cortex, the OB also receives dense innervation from higher brain areas, including feedback and centrifugal inputs [3, 5, 7]. The projections from piriform cortex (Pir) and the anterior olfactory nucleus (AON) are the major source of feedback inputs [3], and the centrifugal inputs include cholinergic, noradrenergic, and serotonergic modulation [5]. Specific manipulation of the circuits by optogenetics has revealed that all these projections dramatically modulate the cellular activity and neural circuits involved in odor information-processing and representation in the OB, and affect olfactory-related behaviors [10]. In the past decade, the influence of centrifugal inputs on the coding and perception of odor information has been the frontier of olfactory research [11,12,13,14,15]. However, one of the defects in our understanding of the structure and function of centrifugal input is the lack of comprehensive and accurate structural network information. The network evidence mainly comes from anterograde labeling of projections at the olfactory cortex or modulatory nuclei, while retrograde labeling from the OB is rare [11, 12, 16, 17]. Furthermore, the traditional study of centrifugal input networks is mainly focused on the granule cell layer (GCL) [7], ignoring other layers, especially the glomerular layer (GL), where the axons of OSNs transmit odorant information to the dendrites of mitral/tufted cells (M/TCs) in the OB [7]. In addition, similar to deep short-axon cells (dSACs) and granule cells (GCs) in the GCL, periglomerular cells (PGCs) and superficial short-axon cells (sSACs) in the GL exhibit stronger odor-evoked excitation in the awake state than in the anesthetized state [18], suggesting that centrifugal inputs to the GL significantly modulate their activity across distinct brain states [19].
However, systematically understanding the mechanism of top–down regulation of the different layers of the OB require dissecting the structural organization of the top–down olfactory circuit at the whole-brain scale, along with fine information on the neuronal circuit architecture [20]. Although previous neuroanatomical research, such as tracing with wheat germ agglutinin and horseradish peroxidase, has identified the basic brain regions that give rise to the centrifugal innervation to the OB [21], the fine architecture of these circuits across the whole brain remains to be elucidated. The recent advance in tracing techniques that use engineered neurotropic viruses for trans-synaptic tracing has driven rapid progress in the dissection of neural circuits [22, 23], because of their reduced virulence and restricted trans-synaptic transport in the anterograde and retrograde directions [24].
Therefore, in the present study, we used monosynaptic and trans-synaptic recombinant neurotropic viral tracers separately to dissect the architecture of the top–down regulatory circuits that directly and indirectly innervate the GL of the OB. In the first set of experiments, two kinds of monosynaptic retrograde rabies virus (RV-ΔG-eGFP and RV-ΔG-dsRed, respectively) were injected into the GL and GCL to quantify and compare the distribution and extent of the topographically organized direct projections in the whole brain. In the second set of experiments, the GL was targeted with injections of RV-ΔG-eGFP or pseudorabies virus (PRV531) to determine the distribution of first- and higher-order projections in the whole brain. The results showed that GCL received more direct centrifugal projections, and GL also received direct centrifugal inputs, but only including AON, anterior piriform cortex (APC) and horizontal limb of diagonal band of Broca (HDB). In addition, the neural circuits in the GL of the lateral OB received varied indirect inputs from bilateral cortical neurons in the AON, Pir, Amygdala (AM), Entorhinal cortex (Ent), hippocampus (Hip) and almost all modulatory nuclei. In all, our results suggested that cortical neurons in these regions have considerable reciprocal connections and innervate the neural circuits in GL of the OB to coordinate and regulate the processing of olfactory information.
Materials and Methods
Animals
Twenty male adult C57 mice (8–10 weeks old, purchased from the Animal Center of Zhongnan Hospital of Wuhan University, Wuhan, China) were housed in a specific pathogen-free facility at a controlled room temperature (22 ± 2 °C) with 60%–80% humidity, under a 12 h:12 h light/dark cycle. Food and water were available ad libitum. During experiments, animals that received viral inoculations were then housed and perfused in Biosafety Level-II animal facilities at the Wuhan Institute of Physics and Mathematics.
Rabies Virus Injection
The recombinant tracers RV-ΔG-eGFP and RV-ΔG-dsRed were prepared by BrainVTA (Wuhan, China). Animals were anesthetized with chloral hydrate (400 mg/kg), and then placed in a stereotaxic apparatus (RWD, Shenzhen, China). During surgery and virus injection, anesthesia was maintained with isoflurane (1%). RV-ΔG-eGFP and RV-ΔG-dsRed (80 nL, 1 × 109 plaque-forming units pfu/mL) were simultaneously injected (50 nL/min) respectively into the ventrolateral GL and ventromedial GCL. The GL coordinates were 4.7 mm anterior to bregma, 1.35 mm from the midline, and 1.75 mm ventral to the dura. The GCL coordinates were 4.7 mm anterior to bregma, 0.7 mm from the midline, and 1.75 mm ventral to the dura. Eight days after virus infection, the animals were transcardially perfused with physiological saline followed by 4% paraformaldehyde (PFA).
PRV531 Injection
The recombinant tracer PRV531 was prepared by BrainVTA. Animals were anesthetized with chloral hydrate (400 mg/kg) and fixed in a stereotaxic instrument (Stoelting, Illinois, USA). The recombinant tracer PRV531 (120 nL, 2 × 109 pfu/mL) was injected (50 nL/min) into the GL. At 48 h and 72 h after virus infection, the animals were transcardially perfused with physiological saline followed by 4% PFA.
Tissue Section Preparation, Imaging, and Data Analysis
The brain was removed, post-fixed in PFA overnight, dehydrated in 30% (w/v) sucrose for 3 days, and then sectioned coronally on a cryostat microtome (NX50, Thermo, Massachusetts, USA). The sequential whole-brain sections, 40 μm thick, were transferred into 24-well plates for storage at − 20 °C. For florescent imaging, they were wet-mounted DAPI, sealed with nail polish, and imaged with TCS SP8 fluorescence laser scanning confocal microscope (Leica, Wetzlar, Germany) or the VS120 virtual microscopy slide-scanning system (Olympus, Tokyo, Japan). The acquired images were adjusted with NIS-Elements Viewer 4.0 (Nikon, Tokyo, Japan), and processed with Adobe Photoshop CS4 and Adobe Illustrator CS6.0 for illustrations. For cell counting, the boundaries of brain regions were delineated manually with Photoshop based on the Allen Brain Atlas and the Mouse Brain Atlas (Fourth Edition). The labeled neurons were counted manually. The data in Rabies Virus cases are presented as the percentage of the total number of labeled neurons in the OB, AON, and HDB, and the numbers of labeled neurons in the anterior piriform cortex (APC) and posterior piriform cortex (PPC) were also counted. For statistical analyses, we examined the distribution of the raw data using the Kolmogorov-Smirnov test in SPSS (version 13.0). Then we used the independent-samples t test to determine if the data were normally distributed, and the statistical significance was set at ***P < 0.001, **P < 0.01, and *P < 0.05. All values are presented as mean ± SEM. Graphs were drawn using Origin 9.0.
Results
Tracing the Local Circuits Within the OB
To systematically dissect the organization of the top–down olfactory circuits, the injection of viral tracer was well localized to the GL and GCL (Fig. 1A, F). In the cases of RV-mediated retrograde labeling from the GL and GCL (Fig. 1A–E), the RV-labeled neurons were mainly distributed on the ipsilateral side and scattered from the GL to the GCL, especially in the mitral cell layer (MCL) (Fig. 1B–D), indicating that local neural circuits communicate information from almost every layer in the OB to the GL and GCL. In the case of RV-ΔG-dsRed-mediated retrograde labeling from the GCL, most of the labeled neurons were in the local GCL specifically (GL: 4.86% ± 2.80%; external plexiform layer or EPL: 16.62% ± 4.35%; MCL: 21.72% ± 4.33%; internal plexiform layer or IPL: 10.34% ± 2.01%; GCL: 46.43% ± 11.15%) (Fig. 1B–E). Quantitative analysis showed that the main population of RV-ΔG-eGFP-mediated retrograde labeling from the GL was in the local GL (GL: 53.20% ± 9.55%; EPL: 16.12% ± 3.98%, MCL: 6.47% ± 2.44%; IPL: 15.25% ± 2.96%; GCL: 4.55% ± 2.20%) (Fig. 1B–E). In addition, neurons in the contralateral OB did not show retrograde labeling by RV, indicating that there was no direct neural projection to the contralateral GL and GCL (Fig. 1D), because only neurons with somata and axon terminals at the injection site can be labeled by glycoprotein-deleted RV [3, 25].
In the PRV-mediated retrograde and trans-synaptic tracing, the injection of virus was limited to the range of 5–10 glomeruli in the GL (Fig. 1F, G); this is the first sub-region for olfactory information processing. At the early stage of infection (after 48 h), the trans-synaptically infected local neural circuits were distributed across the ipsilateral OB, scattering from the GL to the GCL (Fig. 1G, H). The labeled circuits were organized in column-like structures (Fig. 1H), consistent with previous reports [26]. Meanwhile, a few neurons were labeled on the other side of the injected OB, but not in the contralateral OB (Fig. 1G, H). With extension of the infection time to 72 h, the local circuit of the injected OB was densely labeled and exhibited column-like structures (Fig. 1I, J). Neurons in the contralateral OB were also labeled (Fig. 1J), indicating that the bilateral OBs are indirectly connected to each other.
Circuits in the AON Project to the OB
The AON is considered to be responsible for the processing of olfactory information related to direction and concentration through the feedback projections to the bilateral OBs and reciprocal projections between the bilateral AONs [27, 28]. In the case of RV-mediated retrograde tracing, neurons of the AON and anterior olfactory area external part (AOE) were labeled uniformly by both RV-ΔG-eGFP and RV-ΔG-dsRed from the GL and GCL respectively (Fig. 2A, B). In all, the dsRed-positive neurons were distributed in the bilateral AON and AOE, with the majority in the ipsilateral (Ipsi, 70.88% ± 1.15%; Contra, 27.58% ± 0.86%; t = 30.10, P < 0.001, n = 4), whereas the GFP-positive neurons (Ipsi, 1.28% ± 0.40%; Contra, 0.26% ± 0.13%) were much fewer than those with dsRed (Ipsi, t = 56.97, P < 0.001; Contra, t = 31.36, P < 0.001; n = 4) and were mostly in the ipsilateral too (t = 2.41, P = 0.08, n = 4) (Fig. 2A–C, F). These results indicated that neurons in the AON and AOE send direct feedback projections to the bilateral GCL and GL of the OB, but more to the GCL and the ipsilateral.
In the PRV-mediated retrograde and RV tracing from the GL of the OB, the distribution of PRV GFP-positive neurons in the bilateral AON and AOE was more denser than that of RV tracing (Fig. 2C, D, F, G), indicating that it crossed more synapses and more neurons were labeled by PRV 48 h after injection than by RV. In addition, at both 48 h (Fig. 2D, G) and 72 h after infection (Fig. 2E, H), the density of the distribution of GFP-positive neurons was comparable in the bilateral AON and AOE, and all sub-regions of the bilateral AON had similar GFP levels (Fig. 2D, E, G, H). This result showed that there are strong reciprocal projections between the bilateral AON and AOE, consistent with the previous report [27].
Circuits in the Piriform Cortex Project to the OB
The APC is considered to encode information related to the structural or perceptual identity of an odor [29]. In the case of RV-mediated retrograde tracing, the labeled neurons were mainly distributed in layers II and III of the ipsilateral APC (I, 2.44 ± 0.73; II, 147.46 ± 11.08; III, 68.55 ± 15.61) (Fig. 3A–C). The number of dsRed- positive neurons in layer II was double that in layer III (Fig. 3C). In addition, the number of eGFP-positive neurons (I, 0; II, 10.28 ± 7.11; III, 7.43 ± 3.22) was much lower than that of the dsRed-positive neurons in each layer (II, t = 10.42, P < 0.0001; III, t = 3.83, P = 0.02; n = 3) (Fig. 3A, C). These results indicated that the main feedback projections from the APC are in the GCL of the ipsilateral OB. In addition, there were weak feedback projections from APC to the GL, which have not been reported previously.
The PPC encodes the perceptual category of an odor, such as ‘fruity’ [29]. In the case of RV-mediated retrograde tracing, the labeled neurons were mainly distributed in layers II and III of the ipsilateral PPC, similar to the APC (Fig. 4A–C). The dsRed-positive neurons were mainly located in layer II (64.21 ± 14.68), where the number was double that in layer III (29.75 ± 4.81) (P = 0.09, n = 3) (Fig. 4C). Meanwhile, eGFP-positive neurons were not observed in the PPC (Fig. 4B). These results indicated a main feedback projection from the PPC to the GCL of the ipsilateral OB.
In the APC and PPC, the GFP-positive neurons in the PRV-mediated retrograde and trans-synaptic tracing from the GL of the OB were mainly distributed in layers II and III at the earlier stage of infection (48 h after infection) (Figs. 3E and 4G). The distribution density of GFP-positive neurons in the ipsilateral APC/PPC was higher than that in the contralateral APC/PPC (Figs. 3E, H and 4G, J). With the prolongation of infection (72 h after infection), the distribution density of GFP-positive neurons increased significantly, especially in layers II and III of the bilateral APC/PPC (Figs. 3F, I and 4H, K).
Circuits in the Amygdala Project to the OB
The AM has long been known to play critical roles in the processing and retrieval of emotions, such as fear, reward, and happiness [30]. The nuclei of the AM receive direct projections from the OB and AOB [31]. In the case of RV-mediated retrograde tracing, dsRed-positive neurons were mainly located in the ipsilateral basomedial AM (Fig. 4D, E), but no neurons were labeled by RV-dG-eGFP from the GL of the OB in the bilateral AM (Fig. 4D–F, I). In the PRV-mediated retrograde and trans-synaptic tracing, the GFP-positive neurons were mainly distributed in the ipsilateral basomedial AM and basolateral ventral AM at the early stage of infection (48 h after infection) (Fig. 4G). By 72 h after infection, the density of PRV GFP-positive neurons increased across the subregions of the AM, including the basomedial, basolateral ventral, and basolateral amygdala, posterodorsal and posteroventral subnuclei of the medial AM, and the posteromedial and posterolateral cortical AM (PLCo) (Fig. 4H). In addition, no neuron showed retrograde labeling in the contralateral AM at the early stage (48 h) of infection(Fig. 4I, J), and there were fewer GFP-positive neurons scattered in the contralateral subregions and subnuclei of the AM at 72 h than on the ipsilateral side (Fig. 4K).
Circuits in the Entorhinal Cortex (Ent) and Hippocampus (Hip) Project to the OB
Previous studies have reported that the Ent not only receives inputs from the OB, PC, medial AM and Hip, but also sends feedback projections to the OB, PC, and Hip [32, 33]. This special circuit may allow the Ent to regulate olfactory coding based on memory, experience, and preference [33]. In this study, RV-ΔG-dsRed neurons labeled by retrograde tracing were only found in the ipsilateral Ent (94 ± 24.11) and CA1 (29.8 ± 6.16) (Fig. 5A, B), suggesting that the Ent and Hip have direct feedback projections to the GCL of the ipsilateral OB. The number of dsRed-positive neurons in the Ent was 3–4 times higher than that in CA1, although the difference did not reach significance (t = 2.58, P = 0.054, n = 5) (Fig. 5C).
In PRV-mediated retrograde and trans-synaptic tracing from the GL of the OB, GFP-positive neurons were mainly distributed in the bilateral Ent and CA1 at 48 h after infection (Fig. 5D, F), and 72 h after infection, the density of PRV GFP-positive neurons increased significantly in the bilateral Ent, Hip, and peripheral areas, including the CAl/2/3 fields of the Hip, dentate gyrus, amygdalopiriform transition area, PMCo, basolateral posterior AM, perirhinal cortex, ectorhinal cortex, temporal association cortex, and primary auditory cortex (Fig. 5E, G).
Neuromodulatory Circuits Project to the OB
In addition to receiving intensive feedback projections from olfactory-related cortex, the OB also receives neuromodulatory centrifugal projections from neurons that release acetylcholine, serotonin, and norepinephrine; these projections are also necessary for the brain to regulate the processing of olfactory information [5]. In this study, the RV-mediated retrograde tracing showed that the ipsilateral HDB was labeled by both RV-ΔG-dsRed and RV-ΔG-eGFP (Fig. 6A, B, E, H). The percent of dsRed-positive neurons (80.27% ± 0.33%) was five-fold that of eGFP-positive neurons (16.51% ± 0.80%; t = 73.80, P < 0.0001, n = 4) (Fig. 6B). Besides, a small group of neurons expressed both dsRed and eGFP (t = 9.71, P < 0.0001 eGFP-positive versus merged; n = 4) (Fig. 6A, B). These results suggested that axons of cholinergic neurons from the ipsilateral HDB project mainly to the GCL, while project to both the GCL and the GL. In the dorsal raphe (DR) and ipsilateral locus coeruleus (LC), only sparsely distributed dsRed-positive neurons were observed (Fig. 6C, D), suggesting that the axons of both norepinephrinergic and serotoninergic neurons project weakly to the GCL. There was no fluorescence in the median raphe (MR) nucleus (data not shown).
In the PRV-mediated retrograde and trans-synaptic tracing from the GL of the OB, the GFP-positive neurons were mainly distributed in the bilateral HDB and LC at the early stage of infection (48 h), and the distribution of PRV GFP-positive neurons in the ipsilateral HDB and LC was significantly more prominent than that in the contralateral HDB and LC (Fig. 6F, I, M). After infection for 72 h, the density of PRV GFP-positive neurons was significantly higher in the DR and MR, and bilaterally in the HDB and LC (Fig. 6F–G, I–N), and even extended to peripheral nuclei, such as the lateral nucleus of the diagonal band (Fig. 6G, J, L, N).
Discussion
By combining monosynaptic RV-mediated tracing with PRV-mediated trans-synaptic retrograde labeling, we have described the cortical organization of centrifugal afferents to the GL and GCL of the OB (Fig. 7). We first compared the brain regions directly projecting into the GL and GCL, which indicated that the GL only received inputs from each layer in the OB and centrifugal inputs from the ipsilateral AON, APC, and the HDB (Fig. 7A). Retrograde tracing with PRV531 at two time points after viral infection (48 h and 72 h) uncovered various organizational patterns of the neurons that give rise to direct or indirect innervations of the neural circuits in the GL of the lateral OB. At 48 h post-infection, trans-synaptic GFP-labeled neurons were sparsely distributed in the bilateral AON, Pir, AM, Ent, Hip, HDB, LC, DR, and MR (Fig. 7B). At 72 h post-infection, a marked increase in the number of GFP-labeled neurons was found in these olfactory-related cortical regions and neuromodulatory nuclei (Fig. 7C). These results showed that the neural circuits of the GL in the lateral OB receive both direct and indirect feedback and centrifugal inputs, which will help to further understand how olfactory information processing is regulated in the OB.
Local Intra-bulbar Microcircuits
With RV-mediated labeling from the GL, infected neurons were distributed throughout the GL, EPL, MCL, IPL, and GCL. In the GL, especially within each glomerulus, OSN terminals excite the apical dendritic tufts of tens of homotypic M/TCs [34, 35] and various juxtaglomerular cells [glutamatergic external tufted cells (ETCs), GABAergic periglomerular cells (PGCs), and combined GABAergic and dopaminergic superficial short-axon cells (sSACs)] [19, 36, 37]. ETCs provide the principal excitatory drive to MCs and the entire glomerular microcircuit, composed of PGCs and sSACs [35, 38]. GABA release from PGCs mediates glomerulus-wide suppression of homotypic M/TCs through direct gap-junctional coupling between homotypic PGCs [39,40,41]. The majority of sSACs, which mediate robust monosynaptic GABAergic inhibitory signaling in ETCs and M/TCs by gap-junctional coupling somatodendritic contacts with local sSACs [36, 42], may support distinct scales of interglomerular interactions due to multiple axonal branch projections of distant sSACs even up to several tens of glomeruli [37, 43]. Together, these neurons form local microcircuits in the GL. MC and TC somata are arrayed in the MCL and throughout the EPL, respectively, while their apical dendritic tufts receive both excitation from OSN terminals and/or ETCs and inhibition from PGCs and/or sSACs [19]. In addition, calbindin-positive PGCs not only receive input from ETCs in the GL, but also from TCs and MCs [40]. These circuits may establish connections from the EPL/MCL to the GL. Moreover, PGCs, ETCs, and TC apical dendrites in the GL, but not MCs, receive inhibitory GABAergic inputs from the GL-projecting deep SACs (dSACs) whose somata are located in the IPL or GCL and whose axons arborize extensively across the GL [44, 45]. Therefore, GL-projecting dSACs, which may participate in multi-glomerular coordination, establish a novel intra-bulbar projection from deep to superficial layers, from the IPL/GCL to the GL.
With RV-mediated labeling from the GCL, infected neurons were also distributed throughout the GL, EPL, MCL, IPL, and GCL. There are two kinds of interneuron in GCL: GCs and dSACs; the latter are GABAergic and have extensive axonal ramification in various layers of the OB [45, 46] and they strongly inhibit GCs [45, 46]. It has been estimated that each EPL- and/or GCL-dSAC innervates on the order of 103 GCs, with ~75 EPL-and/or GCL-dSACs converging onto each GC [19, 47]. In the EPL, the apical dendrites of superficial GCs and deep GCs form reciprocal dendrodendritic synapses with lateral dendrites of MCs and TCs in the superficial versus deep EPL, respectively [19]. In addition, both GCs and dSACs receive axodendritic excitatory synapses from M/TC axon collaterals in the GCL [45, 48]. These neural circuits potentially establish connections from the MCL and/or EPL to the GCL. The apical dendrites of GCs, which receive excitatory synapses from the axons of ETCs in homologous glomeruli, form inhibitory synapses on the ETCs connected to other homologous ipsilateral glomeruli [49, 50]. Therefore, the excitatory input of ETCs onto the proximal primary axons of GCs establisha potential connection from the GL to the GCL. This may also be the only known pathway linking the dorsal and ventral GL in our PRV-mediated trans-synaptic tracing from the GL, in which some infected neurons were in the dorsal GL and MCL.
Feedback from Olfactory Cortex to the OB
The OB receives dense input from higher brain areas, in which the AON and Pir are the major source of feedback [3]. The AON can be subdivided into the pars externa (AOE) and the pars principalis (AONpP). The latter is further segmented into dorsal, ventral, medial, and lateral regions [51]. The AOE feedback to the bulb has been studied; axons from AOE neurons target mirror-symmetric glomeruli in the contralateral OB, creating a bilateral olfactory map [52]. In contrast, projections from the AONpP are known to target the GCL bilaterally [6]; this is consistent with our RV labeling. Moreover, feedback to the GCL from the ipsilateral AON is uniformly distributed, as we found in this study; but we did not find that projections from the contralateral AON showed a strong ventral bias [3]. This may be because our central injection sites were predominantly in the ventral GCL. In addition, this is the first report that neurons of AONpP and AOE send direct feedback projections to the bilateral GL, indicating that there are more neural circuits from the AON to the OB than originally thought.
Neurons in the AON were more densely infected from the GL with PRV- than RV-mediated trans-synaptic tracing. Which circuit provides the ability to make high strength of the PRV GFP tracing in the bilateral AON? As far as we know, AON send weak feedback projection on the GL of the ipsilateral OB and there was no feedback projection on the contra-lateral GL. The dense feedback projections from the AON to the bilateral GCL [6], and the dense projections from the GCL to the GL within the OB [44, 45], as well as the strong reciprocal projections between the bilateral AONs [53], might explain the high efficiency of PRV GFP-mediated trans-synaptic labeling of the bilateral AON.
Apart from the AON, pyramidal neurons in layers II and III of the APC send robust excitatory centrifugal input to the GCs and dSACs in the GCL [54]. But it had not been reported that centrifugal feedback inputs originating PPC to GCL and GL, whose target neurons and possible functions need to be further identified. In addition, olfactory-related feedback afferents arise from many sources, including the peri-amygdaloid cortex and amygdala [33], but precise neural connections are rarely reported. This is the first report that the basomedial, basolateral, medial, posteromedial cortical, and posterolateral AM could directly and indirectly regulate olfactory information processing in the GL. Because the medial and posteromedial cortical AM received inputs from the AOB, and the posterolateral cortical AM received inputs from the OB [31], these circuits between main olfactory and vomeronasal cortex may be nodes where main and accessory olfactory information converged and are reciprocally regulated.
The OB receives centrifugal projections from the Ent and Hip [55]. The hippocampal formation, which is anatomically and functionally related to olfactory structures especially in rodents, is essential for olfactory identification and the expression of odor memory representations [56]. Anatomically, the Hip receives olfactory information directly through the medial olfactory tract to the hippocampal rudiment and indirectly through the perforant path from the Ent to the dentate gyrus [56]. Retrograde and anterograde tracing experiments have shown that the Hip projections to OB mainly come from ventral CA1 [57, 58], which is consistent with our RV-mediated labeling. Whether these projections from Ent and Hip to the OB process spatial information for olfactory recognition or are involved in olfactory learning and memory remains to be elucidated.
Neuromodulatory Centrifugal Projections to the OB
In addition to the dense centrifugal feedback projections from higher olfactory-related areas, the OB also receives dense neuromodulatory inputs (cholinergic, noradrenergic, and serotonergic) [5, 13, 14]. Cholinergic input to the OB is provided primarily by the axons of neurons whose cell bodies reside in the HDB in the basal forebrain; this has been implicated in odor discrimination and detection, as well as olfactory learning and memory [4, 5]. Both nicotinic and muscarinic receptors are found in the OB and play crucial and complementary roles in regulating the coherence and sparseness of the OB network output and olfactory behaviors [59, 60]. Although each layer in the OB received cholinergic HDB projections, both the GL and IPL are predominant in the distribution of axonal projections in choline acetyltransferase (Chat-Cre) mice [17, 61], which is inconsistent with our RV-mediated retrograde labeling showing that more neurons innervate the GCL than GL. Perhaps this is because the method used in this study through axon terminal RV absorption is different from measuring the density of axon branches. It may also be that cholinergic neurons have more synapses in the GCL than in the GL. In addition to cholinergic inputs, GCs receive centrifugal GABAergic projections from basal forebrain as well as dSACs [62, 63].
The OB receives significant noradrenergic input from the LC and norepinephrine is involved in olfactory associative learning, as well as odor detection and discrimination [64,65,66]. Norepinephrine dramatically changes the activity of ETCs and GCs [67,68,69], which is consistent with the RV labeling from the GCL, but no neurons in the LC were infected in RV-mediated labeling from the GL. It may be that the number of ETCs is much smaller than that of GCs [19]. Besides, the density of axons of dopamine-B-hydroxylase in the GL was much lower than that in the GCL [33].
Serotonergic neurons in the raphe nuclei are involved, via their extensive innervation, in a variety of functions including depression, anxiety, sleep-wake cycles, reward, patience in decision-making, and sexual preference [70,71,72,73,74,75,76]. Serotonergic projections from the DR and MR densely innervate the OB, where they modulate the initial representation and processing of olfactory information [5, 77, 78]. Almost all types of neurons in the OB are dramatically modulated by serotonin [77, 79,80,81,82,83], the DR mainly projecting to the GCL, and the MR to the GL [78]. In our RV-mediated labeling, only neurons in the DR were infected from the GCL, but neurons in the MR were not infected from the GL. This may be because of the difference between the two labeling methods. It is also possible that the two types of projection differ in function.
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Acknowledgements
We thank Dr. Lingling Xu (Wuhan Institute of Physics and Mathematics) for maintaining and managing the optical platform. This work was supported by grants from the National Natural Science Foundation of China (31400946, 31671120, 31771197, 31329001, 31771156, 91632303, and 81661148053/H09), the Strategic Priority Research Program of Chinese Academy of Science (XDB32030200), and the National Basic Research Development Program (973 Program) of China (2015CB755600).
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Wen, P., Rao, X., Xu, L. et al. Cortical Organization of Centrifugal Afferents to the Olfactory Bulb: Mono- and Trans-synaptic Tracing with Recombinant Neurotropic Viral Tracers. Neurosci. Bull. 35, 709–723 (2019). https://doi.org/10.1007/s12264-019-00385-6
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DOI: https://doi.org/10.1007/s12264-019-00385-6