α-Synuclein Pathology and Reduced Neurogenesis in the Olfactory System Affect Olfaction in a Mouse Model of Parkinson's Disease

Olfactory deficits found in late-stage α-syn-Tg mice

A progressive loss of olfaction is a well-known nonmotor symptom in PD patients (Ansari and Johnson, 1975; Haehner et al., 2011). Here, we evaluated olfactory deficits in a mouse model of PD before and after the appearance of motor abnormalities, i.e., early (six to seven months) and late (12–14 months) stages, respectively (Chandra et al., 2005; Piltonen et al., 2013). Olfactory deficits were analyzed using standardized buried food tests as they are effective methods to evaluate the ability of trained mice to locate scented foods using olfactory cues (Dawson et al., 2005; Yang and Crawley, 2009; Lehmkuhl et al., 2014).

Our results from olfactory tests showed that α-syn-Tg mice displayed olfactory deficits at late stages (12–14 months) compared with WT controls (p = 0.029) but not at early stages (six to seven months; p = 0.8048; Fig. 1A). These data suggested an olfactory impairment caused by α-syn-Tg overexpression in mice at advanced stages of the disease. In both α-syn-Tg and WT groups, data from males and females were merged after we ruled out the influence of sex on the results. To exclude the influence of motor deficits or lack of motivation by food in mice, particularly at late stages, we performed a surface food test in which the latency to find the food was recorded as a measure of mobility. There were no differences between WT and α-syn-Tg at early (p = 0.9709) and late (p = 0.1156) stages (Fig. 1B), indicating that motor agility did not influence olfactory performance, although 12- to 14-month mice had motor deficits on more challenging motor tests (Chandra et al., 2005). In summary, we found that aged α-syn-Tg mice exhibited olfactory behavior deficits.

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Figure 1.

α-Syn-Tg mice show olfactory deficits at 12–14 months. A, Wild-type (WT) and α-syn-Tg (carrying the hA30P mutant α-syn) mice are evaluated for olfactory deficits using standard buried food tests. Mice at early stages of the disease (6–7 months) do not exhibit olfactory dysfunction measured as the latency to find a hidden food. At late stages (12–14 months), α-syn-Tg mice show olfactory deficits indicative of dysregulated olfactory pathway. B, Surface food location test did not show any difference between WT and α-syn-Tg mice, performed to exclude bias because of motor deficits or lack of motivation for food. Data are normalized between 0 as the minimum latency time (0 s), and 1 as the maximum latency time (300 s; *p < 0.05). Statistics: unpaired nonparametric Mann–Whitney U test.

Cytoarchitecture of the olfactory pathway of α-syn-Tg mice

Next, we sought to establish any α-syn pathology within the primary olfactory system to investigate the causes of olfactory deficits observed in 12- to 14-month mice. The olfactory pathway is organized in three fundamental processing stations interconnected by projection neurons (Fig. 2A):

1. Olfactory sensory neurons (OSNs) expressing odor receptors are located in the olfactory epithelium (OE) lining the nasal cavity. When odorants bind, the information is sent to the first olfactory processing center of the brain, the olfactory bulb (OB).

2. The OB has a laminar organization formed by 6 layers which go from the most superficial to the deepest as follows: (1) olfactory nerve layer; (2) glomerular layer (GL); (3) external plexiform layer (EPL); (4) mitral cell layer (MCL); (5) internal plexiform layer (IPL); and (6) granule cell layer (GCL). These layers are formed by a variety of projection neurons (PNs), involved in receiving and processing the olfactory signals received from OSNs, and interneurons (INs) that modulate those signals. PNs include mitral and tufted cells (M/Tc), whose cell bodies locate in the MCL and outer EPL, respectively. PNs extend both primary apical dendrites that arborize in spherical structures called glomeruli (Gl) where they form synapses with axon termini of OSNs, and lateral secondary dendrites that extend laterally within the EPL, where olfactory information is highly modulated. Both type of PNs send their axons to higher brain structures, predominantly the tubular striatum (TuS) and the olfactory cortex (OC), the last the subject of our analysis.

3. The OC is the third station studied in this work and is divided in the anterior olfactory nucleus (AON) and piriform cortex (PC), both responsible for the higher brain processing of an odor and memory formation (Shepherd et al., 2021).

We began by examining disruptions in the OE neuronal cytoarchitecture. OSNs in the OE are continuously renewed during the lifetime of an individual in a process that requires cell division of OE neural stem cells (horizontal and globose cells) and their differentiation to OSNs. The differentiation stages of OSNs were identified using specific markers such as (1) olfactory marker protein (OMP) to label mature OSNs; (2) adenylate cyclase 3 (AC3) to label differentiating OSNs; and (3) growth associated protein 43 (GAP43) to label immature OSNs (Liberia et al., 2019). Our analysis showed no disrupted OE cytoarchitecture between WT controls (Fig. 2B,D) and α-syn-Tg mice at 12–14 months of age (Fig. 2C,E). We tested whether the unaffected morphology was because of the absence of the disease in the OE by detecting two hallmarks of α-syn pathology, specifically: (1) the accumulation of α-syn aggregates (aggregated α-syn); and (2) phosphorylation of serine 129 of α-syn (pSer129-α-syn; Narhi et al., 1999; Fujiwara et al., 2002). The data showed that α-syn pathology was not detected in the OE, and there was no difference between genotypes in aggregated α-syn (Fig. 2F,G) and pSer129-α-syn (Fig. 2H,I) staining. We also assessed for changes along the dorsal-ventral axis by staining with NADPH dehydrogenase [quinone] 1 (NQO1), a selective marker for the dorsal region, and we did not find any difference between the groups (Fig. 2F–I). Our observations were consistent with data found from PD patients (Del Tredici and Braak, 2012).

Next, we explored the anatomy of the OB layers and general activity of OB projection neurons in 12- to 14-month mice. We first studied the GL, formed by the glomeruli and periglomerular neurons (PGNs) by staining against vesicular glutamate transporter 2 (VGLUT2) and OMP, both characteristic markers for OSNs axons. No evidence of anatomic disruptions was found in α-syn-Tg mice compared with WT controls (Fig. 2J,K). In addition, we studied the dopaminergic local circuits established by PGNs expressing the enzyme tyrosine hydroxylase (TH⁺; Kosaka and Kosaka, 2016), by quantifying TH⁺ cells around randomly selected glomeruli. Our results showed similar morphologies (Fig. 2L,M) and no statistical differences (p = 0.1358; t = 1.864, df = 4) in the number of TH⁺ cells in WT (443 ± 43 cells/mm²) versus α-syn-Tg mice (535 ± 74 cells/mm²). These data differ from those previously published showing a decrease in the number of TH⁺ cells, or an increase in the TH innervated area in transgenic mice expressing hA30P mutant α-syn (Lelan et al., 2011; Nuber et al., 2011; Neuner et al., 2014). We do not have a definitive explanation for the different outcomes, but several seem plausible. First, the promotors used in different manuscripts to drive the expression of hA30P α-syn transgene are variable in their effectiveness (Rockenstein et al., 2002). As a consequence, there can be a corresponding variance in the expression of TH, making it challenging to use TH expression as a measure of cell loss. Further, variability in outcomes may be attributed to the species in which the transgene was expressed as well as the use of conditional expression models.

Finally, we searched for changes in the cellular activity in mitral cells as the main projection neurons of the OB, by analyzing the expression levels of phosphorylated S6 ribosomal protein (Ser235/236; pS6). Oscillations in pS6 levels have been correlated with the activation of neurons in response to stimuli, synaptic plasticity or pathologic events such as traumatic injury or seizures (Biever et al., 2015). In the OB, pS6 expression levels are reported to be reduced in OB mitral cells after sensory deprivation (Galliano et al., 2021). Here, we quantified the intensity of pS6 staining along the MCL in both WT and α-syn-Tg mice, showing no statistically significant difference between the groups (Fig. 2N–P). Overall, these results suggested no effect of α-syn pathology on the gross cytoarchitecture and mitral cell activity of the OB in aged α-syn-Tg mice.

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Figure 2.

Organization of mouse olfactory system, and cytoarchitecture of the olfactory epithelium (OE) and bulb (OB) in α-syn-Tg mice at 12–14 months. A, Diagram of the mouse olfactory system summarizing the different station relays used by the olfactory information to travel from the OE to the brain. B, C, Immunohistochemistry against AC3 (red) and OMP (blue) to label intermediate differentiating and mature OSNs, respectively. D, E, Staining for GAP43 (green) and OMP (blue) showing immature and mature OSNs, respectively. No alterations in the OE cytoarchitecture are seen in α-syn-Tg mice. F, G, Low-magnification images of the OE stained for α-syn pathology using aggregated α-syn (green; mouse, EMD Millipore; Table 1) and NQO1 (red), specific for dorsal OE. No evidence of α-syn aggregation is seen in the OE. H, I, Low-magnification images of the OE stained for α-syn pathology using pSer129-α-syn (green; rabbit, Abcam; Table 1) and NQO1 (red). No evidence of α-syn pathologic phosphorylation is seen in the OE. Differences in NQO1 staining correspond to slight variations in the section plane along the rostral-caudal axis between the different mice. All these staining show an unaltered cytoarchitecture in the OE of α-syn-Tg mice with lack of α-syn pathology. J, K, OSNs axons labeled with VGLUT2 (green) and OMP (red) in the OB show no differences in the glomerular structure between WT and α-syn-Tg mice. L, M, Staining of dopaminergic neurons with TH in the OB-GL (green) and signs of apoptosis using Caspase 3 cleavage (red), showing no disruptions in the morphology or cellular processes or increased cell death in α-syn-Tg mice. N, O, Staining for α-syn pathology in the OB-MCL using pSer129 α-syn (green; mouse, BioLegend; Table 1) and cellular activity detected using pS6 (red) in mitral cells. P, Quantification of pS6 expression levels shows no significant differences between WT and α-syn-Tg mice. Nuclei counterstained with Dapi (blue). AC3: adenylyl cyclase type 3; AON: anterior olfactory nucleus; EPL: external plexiform layer; GAP43: growth associated protein-43; GL: glomerular layer; GCL: granule cell layer; LOT: lateral olfactory tract; LP: lamina propia; LV: lateral ventricle; MCL: mitral cell layer; NQO1: NAD(P)H dehydrogenase [quinone] 1; OB: olfactory bulb; OE: olfactory epithelium; OMP: olfactory marker protein; OSNs: olfactory sensory neurons; PC: piriform cortex; pS6: phosphorylated S6 Ribosomal Protein (Ser235/236); RMS: rostral migratory stream; SP: septum; TuS: tubular striatum; TH: tyrosine hydroxylase; VGLUT2: vesicular glutamate transporter 2. Scale bars: 500 µm (F–I), 200 µm (J, K), 100 µm (L, M), 50 µm (B–E, N, O). Statistics: unpaired t test.

Expression of human α-synuclein transgene and pathology in α-syn-Tg mice

The α-syn-Tg mouse model of PD expresses the human A30P mutant α-syn under the Thy1 promoter, which is known to trigger protein expression predominantly in projection neurons (Feng et al., 2000). To validate how this model was affecting the olfactory system, we first investigated where human α-syn (hα-syn) was expressed. We performed triple IHC to detect hα-syn in combination with pSer129-α-syn and aggregated α-syn, as hallmarks of α-syn pathology, in α-syn-Tg mice at both 6–7 and 12–14 months (Fig. 3). We performed the study in two main areas of the olfactory system, the OB and the anterior region of piriform cortex (APC) which is the area that receives the most innervation from the OB (Martin-Lopez et al., 2019).

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Figure 3.

Detection of transgenic human α-synuclein expression and associated α-syn pathology in α-syn-Tg mice. A human specific anti-α-syn antibody (hα-syn) is used to detect the expression of the transgene in the α-syn-Tg mice (green). α-Syn pathology is detected using pSer129-α-syn (red; rabbit, Abcam; Table 1; largely somatic) and aggregated α-syn (magenta; rat, BioLegend; Table 1; largely synaptic). A–a'', B–b'', Staining in the OB and APC of WT control mice at six to seven months. Only a residual expression of pSer129-α-syn is seen in OB mitral cells (A, a', red arrowheads). C–c'', D–d'', Staining in the OB and APC of α-syn-Tg mice at six to seven months. Transgene expression in the OB is seen in neuronal processes of the GL, EPL, IPL, and GCL layers (c) In APC, hα-syn stains neuronal processes of layers 1, 2, and 3, and it appears somatic in some neurons of 2b (d). Most of these processes and neuronal bodies in APC co-expressed α-syn pathology (white arrowheads; hα-syn⁺; red arrowheads in C, c', D, d'; magenta arrowheads in D, d', d''). Strong expression of aggregated α-syn is detected in layers 1b and 2a of APC (d''). E–e'', F', f'', Staining in the OB and APC of WT control mice at 12–14 months. A residual expression of pSer129-α-syn remains in the OB mitral cells at this age (E, e', red arrowheads). G–g'', H–h'', Staining in the OB and APC of α-syn-Tg mice at 12–14 months. Compared with six to seven months, at 12–14 months, there is a stronger accumulation of the transgene (hα-syn⁺, green) along all layers of OB (g), and layers 1b, 2a, and 2b in APC (h). hα-syn staining is somatic in some mitral cells (g). In APC, most neurons expressing hα-syn also show pathology (H–h''). In APC, no hα-syn or α-syn pathology is seen in layer 2a (H–h''). Nuclei counterstained with Dapi (blue). APC: anterior piriform cortex; EPL: external plexiform layer; GCL: granule cell layer; GL: glomerular layer; IPL: internal plexiform layer; LOT: lateral olfactory tract; MCL: mitral cell layer; OB: olfactory bulb. Scale bars: 100 µm.

As expected, hα-syn was not detected in WT animals (Fig. 3A,a,B,b,E,e,F,f), although we observed some residual expression of pSer129-α-syn in the OB-MCL (Fig. 3a',e') that did not occur in APC (Fig. 3b',f'). In transgenic mice, the hα-syn expression pattern was synaptic and appeared distributed predominantly in neuronal fibers in the GCL and IPL of the OB at six to seven months (Fig. 3c, white arrowheads). However, the hα-syn staining pattern became more somatic in the MCL at 12–14 months (Fig. 3g, white arrowheads). In APC, the hα-syn expression pattern was found predominantly in (1) the densely packed cell layers 2a+b and three formed by superficial and deep pyramidal neurons, respectively (Fig. 3d,h), with higher expression at 12–14 months (compare Fig. 3d staining with h). In layers 2 and 3, a more pronounced somatic expression was observed at 12–14 months (Fig. 3d,h, white arrowheads); (2) in layer 1, stronger staining was evident at 12–14 months, suggesting an increase of hα-syn expression with age (Fig. 3D,d,H,h). Sublayer 1a contains the primary synapses from the OB projection neurons onto the apical dendrites of the pyramidal neurons in layers 2 and 3, while sublayer 1b includes the associational synapses with corticocortical axons coming from other OC regions (Martin-Lopez et al., 2019). α-Syn pathology was detected in both OB and APC tissues from mice at 6–7 (Fig. 3C–c'',D–d'') and 12–14 (Fig. 3G–g'',H–h'') months, colocalizing predominantly with cell bodies and processes expressing hα-syn (white arrowheads). The overall increase of total α-syn (both human and mouse endogenous) and aggregated α-syn in α-syn-Tg mice was confirmed by WB in OB homogenates of α-syn-Tg mice when compared with WT at both 6–7 and 12–14 months (Fig. 4A,B). The data were not significant at six to seven months probably because of the insensitivity of the antibody in Western blotting (Fig. 4B).

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Figure 4.

Quantification of human/endogenous and aggregated α-synuclein by Western blotting (WB). A, WB detecting total (endogenous and human) α-syn in WT controls and α-syn-Tg mice at both studied stages (6- to 7- and 12- to 14-month mice). The amount of protein quantified by densitometry showed a significant increase of total α-syn between WT versus α-syn-Tg mice at both 6–7 and 12–14 months in the OB. B, Detection of aggregated α-syn (mouse, EMD Millipore; Table 1) by WB showed an increase in the amount of protein in the OB of α-syn-Tg mice at 12–14 months. Intensity densitometry values are normalized against the β-actin intensity, used as a loading control. *p < 0.05, **p < 0.01. Statistics: unpaired t test.

To further investigate which neuronal types were targeted by the overexpression of hA30P mutant α-syn, we performed a triple IHC analysis along the olfactory pathway of 12- to 14-month mice, to detect hα-syn together with aggregated α-syn as a marker for pathology and either TBR1 (T-Box Brain Protein-1) to identify excitatory/glutamatergic projection neurons (Hevner et al., 2001), or GAD65/67 (Glutamic Acid Decarboxylase isoform 65 and 67) to identify GABA inhibitory neurons (Erlander et al., 1991; Fig. 5). Our results with TBR1 showed that all cells expressing hα-syn colocalized with TBR1 in the OB-MCL, AONl, and APC (Fig. 5B,b',C',c',D',d', white arrowheads) but not in the OB-GL region (Fig. 5A,a'). However, not all TBR1 cells expressed hα-syn (Fig. 5A–D, red arrowheads, and red cells). α-Syn pathology studied with the aggregated α-syn antibody colocalized predominately with TBR1 cells that also expressed hα-syn (Fig. 5a''–d'', white arrowheads). There were instances of GAD65/67 overlapping with hα-syn or aggregated α-syn (Fig. 5E–h'', red arrowheads), but it was not as robust as seen in projection neurons and was less somatic.

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Figure 5.

Detection of the transgenic human α-synuclein expression in excitatory projection and inhibitory neurons at 12–14 months. A–a'' to D–d'', Staining for human specific α-syn (hα-syn; green) with the projection neurons marker TBR1 (red) and aggregated α-syn (magenta; rat, BioLegend; Table 1) in the OB: GL and MCL layers, the lateral AON and APC. No colocalization is seen in TBR1⁺ neurons in the OB-GL with hα-syn or aggregated α-syn (A, a', red arrowheads). In the OB-MCL, AONl, and APC, some neurons express the transgene (hα-syn⁺) which always colocalized with TBR1 and α-syn pathology (B–b'', C–c'', D–d'', white arrowheads). E–e'' to H–h'', Staining for human specific α-syn (hα-syn; green) with the inhibitory neurons marker GAD65/67 (red) and aggregated α-syn (magenta; rat, BioLegend; Table 1) in the same olfactory regions. GAD65/67⁺ neuron colocalizes with hα-syn or aggregated α-syn. The IPL, which is occupied predominantly by OB projection neuron axons is labeled for hα-syn or aggregated α-syn but not for GAD65/67, indicating that the transgene is prominent in projection excitatory neurons. Nuclei counterstained with Dapi (blue). AONl: lateral anterior olfactory nucleus; APC: anterior piriform cortex; EPL: external plexiform layer; GAD65/67: glutamate decarboxylase isoforms 65 and 67; GL - glomerular layer; IPL: internal plexiform layer; MCL: mitral cell layer; OB: olfactory bulb; TBR1: T-Box Brain Transcription Factor-1. Scale bars: 50 µm.

Collectively, we concluded that the α-syn pathology in the α-syn-Tg mouse model was found throughout the olfactory pathway, most prominently in projection/excitatory neurons.

Detection and quantification of α-synuclein pathology in the central olfactory pathway of α-syn-Tg mice

We next investigated the presence of α-syn pathology, measured as the relative intensity of staining for aggregated α-syn and pSer129-α-syn, in the three main stations of the central olfactory pathway: the OB, the AON, and PC of mice at 12–14 months. In the OB, we quantified the expression of both aggregated α-syn and pSer129-α-syn in each of the OB layers and found that α-syn pathology was laminar specific (Fig. 6). There was no difference in GL expression between WT and α-syn-Tg mice in either aggregated α-syn (Fig. 6C; p = 0.7187, t = 0.3866, df = 4) or pSer129-α-syn (Fig. 6J; p = 0.4241; t = 0.8893, df = 6). In the EPL, minimal expression of aggregated α-syn was seen in both WT and α-syn-Tg groups (Fig. 6A–a'',B–b'',D; p = 0.7187; t = 0.3866, df = 4). In WT and α-syn-Tg mice, pSer129-α-syn staining was equivalent in the EPL (Fig. 6H–h'',I–i'',K; p = 0.2336; t = 1.402, df = 4). A subpopulation of OB projection neuron somata expressing TBR1⁺ in the outer EPL (oEPL), tufted cells, were pSer129-α-syn labeled in α-syn-Tg mice (Fig. 6h,h').

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Figure 6.

α-Synuclein pathology in the olfactory bulb (OB) of mice at 12–14 months. A–a'', B–b'', Representative images of OB coronal sections of mice stained against aggregated α-syn (green; mouse, BioLegend; Table 1) and TBR1 (red) as a marker for projection neurons in WT (A–a'') and α-syn-Tg (B–b'') mice. Staining seems to be restricted to cell processes. Quantification of stained area shows a significantly higher accumulation of aggregated α-syn in α-syn-Tg mice in the IPL (F) and GCL (G), with a strong trend in MCL (E). No differences are detected between the groups in GL (C) and EPL (D). H–h'', I–i'', Representative images of OB coronal sections of mice stained against pSer129-α-syn (green; mouse, BioLegend; Table 1) and TBR1 (red) in WT (H–h'') and α-syn-Tg (I–i'') mice. Quantifications show significantly increased pSer129-α-syn in the MCL of α-syn-Tg mice compared with controls (L) with no statistical differences in the other layers (J, K, M, N). Remarkably, a strong accumulation of pSer129-α-syn is seen in tufted cells (i, i', white arrowheads) and in apical and lateral dendrites of mitral cells (i, i', green arrowheads) of α-syn-Tg. There is a characteristic staining of pSer129-α-syn in the GCL forming a pattern intermingled with granule cell islets that likely belong to M/Tc axons (I). Nuclei counterstained with Dapi (blue). EPL: external plexiform layer; GCL: granule cell layer; IPL: internal plexiform layer; M/Tc: mitral and tufted cells; TBR1: T-Box Brain Transcription Factor-1. Scale bars: 500 µm (A, B, H, I), 100 µm (a–a'', b–b'', h–h'', i–i''). *p < 0.05, **p < 0.01. Statistics: unpaired t test.

The lateral dendrites of mitral cells extend horizontally in the inner EPL (iEPL) and synapse with granule cell dendrites, while apical dendrites extend radially in the EPL to innervate glomeruli. Both dendrites were stained with pSer129-α-syn in WT (Fig. 6h,h') and α-syn-Tg mice (Fig. 6i,i', green arrows), but the distribution was different between the experimental groups: the expression was limited to the lateral dendrites in the WT mice while both the lateral and apical dendrites showed expression in the α-syn-Tg mice (Fig. 6h,i). As mentioned above, we attributed its presence in the WT mice with a residual phosphorylation of α-syn previously reported to occur in healthy aged, adult brains representing ∼4% of the total brain phosphorylated α-syn (Fujiwara et al., 2002). In the MCL, there was a strong trend of higher levels of aggregated α-syn in α-syn-Tg mice (Fig. 6E; p = 0.0553; t = 2.679, df = 4), while pSer129-α-syn expression was significantly higher in α-syn-Tg mice compared with WT (Fig. 6L; p < 0.01; t = 5.204, df = 4). Labeling of pSer129-α-syn which was most evident in the cell bodies of mitral cells of both WT (Fig. 6H–h'') and α-syn-Tg (Fig. 6I–i'') mice, colocalized with TBR1. These data together with our previous observations using hα-syn (Fig. 5A–d''), were consistent with the notion that α-syn pathology, detected by phosphorylation of α-syn in Ser129, is a process restricted to projection/non-GABAergic neurons, as previously reported (Taguchi et al., 2019). Deeper in the IPL, aggregated α-syn was significantly higher in α-syn-Tg (Fig. 6b,b') than in WT controls (Fig. 6F; p < 0.01; t = 4.934, df = 4), while pSer129-α-syn expression levels were unchanged between experimental groups (Fig. 6M; p = 0.1465; t = 1.798, df = 4). This is consistent with the observation that pSer129-α-syn staining is mainly concentrated in cell bodies and thicker neurites (Schell et al., 2009). In the GCL aggregated α-syn (Fig. 6A–a'',B–b'') expression was significantly higher in α-syn-Tg than in WT (Fig. 6G; p < 0.01; t = 3.594, df = 4) and appeared preferentially localized to neurites interdigitated with the granule cell islets. The staining for pSer129-α-syn within the GCL (Fig. 6H–h'',I–i'') showed a pattern characteristic of the mitral/tufted cell (M/Tc) axons as they coalesce and subsequently form the lateral olfactory tract (LOT). There was only a trend toward a higher expression of pSer129-α-syn in the GCL (Fig. 6N; p = 0.3740; t = 0.998, df = 4). Together, our results indicated that α-synuclein pathology accumulation was enhanced in the OB projection M/Tc neurons of α-syn-Tg mice.

We next examined the olfactory cortices formed by the anterior olfactory nucleus (AON) and piriform cortex (PC) for evidence of α-syn pathology. The AON is formed by a compact ring of cells, the pars principalis, surrounding the olfactory peduncle. This region is subdivided into two basic zones: an outer plexiform layer (opl), and an inner cell zone (icz) containing pyramidal cells (Brunjes et al., 2005). We found a trend for increased aggregated α-syn in the inner cell zone of α-syn-Tg mice (Fig. 7A–C; p = 0.1033; t = 2.103, df = 4). Interestingly, pSer129-α-syn was significantly increased in projection neurons (TBR1⁺ cells colocalizing with pSer129-α-syn) of the AON inner cell zone in α-syn-Tg mice with respect to controls (Fig. 7J,K; p < 0.01; t = 5.852, df = 4), consistent with the pathology restricted to these cells. These results showed compelling evidence of AON pathology as described in humans (Daniel and Hawkes, 1992; Pearce et al., 1995).

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Figure 7.

α-Synuclein pathology in anterior olfactory nucleus and piriform cortex of mice at 12–14 months. A, B, Representative images of AON coronal sections from WT and α-syn-Tg mice stained against aggregated α-syn (green; mouse, BioLegend; Table 1) and TBR1 (red) as a marker for projection neurons. C, Percentage of stained area in the AON showing higher levels of aggregated α-syn in α-syn-Tg versus WT mice with no statistical differences because of high variability. D, E, G, H, Representative images of aggregated α-syn staining from the APC and PPC showing α-syn aggregation in layer 2 (a + b) of α-syn-Tg mice, with accumulation in some neuronal cell bodies (arrowheads). F, I, Quantification of aggregated α-syn stained area in APC and PPC showing no statistical differences between WT and α-syn-Tg mice, although there is a trend to be higher in α-syn-Tg mice. J, K, Representative images of pSer129-α-syn staining (green; mouse, BioLegend; Table 1) in AON, showing a strong accumulation of α-syn pathology in cell bodies of projection neurons co-labeled with TBR1 (red). L, The comparison of stained area for pSer129-α-syn in AON shows statistically significant higher accumulation in α-syn-Tg mice. M, N, P, Q, Examples of images taken in APC and PPC showing an intense labeling for pSer129-α-syn in neuronal cell bodies of layer 2 (a + b) in APC, and IIb in PPC (dotted line). O, R, Quantification of pSer129-α-syn stained area in APC and PPC showing statistically significant differences between WT and α-syn-Tg mice. Nuclei counterstained with Dapi (blue). AON: anterior olfactory nucleus; APC: anterior piriform cortex; icz: inner cell zone; opl: outer plexiform layer; LOT: lateral olfactory tract; PPC: posterior piriform cortex; TBR1: T-Box Brain Transcription Factor-1. Scale bars: 200 µm (A, B, J, K), 50 µm (D, E, G, H, M, N, P, Q). *p < 0.05, **p < 0.01. Statistics: unpaired t test.

In PC, we studied areas in the anterior piriform cortex (APC) and posterior piriform cortex (PPC) to cover the anatomic and functional differences along the rostral-caudal axis (Martin-Lopez et al., 2019; Shepherd et al., 2021). In the APC, we found an increase in aggregated α-syn in layers 1b, occupied predominantly by the apical dendrites of PC projection neurons (Martin-Lopez et al., 2019; Fig. 7D,E; compare similar staining on Fig. 3d'',h''), and layer 2b, occupied predominantly by pyramidal neuron cell bodies some of which were strongly labeled for aggregated α-syn (Fig. 7E, arrowheads). Quantification of the stained area showed a trend of higher aggregated α-syn in α-syn-Tg mice, although this increase was not statistically significant most likely because of the high variability among individual mice (Fig. 7F; p = 0.1489; t = 1.785, df = 4). Results for aggregated α-syn in PPC were analogous (Fig. 7G–I; p = 0.3128; t = 1.154, df = 4). In contrast, the expression levels of pSer129-α-syn highlighted an intense pathologic profile in α-syn-Tg mice in both APC (Fig. 7M–O; p < 0.01; t = 5.897, df = 4) and PPC (Fig. 7P–R; p < 0.05; t = 3.383, df = 4) compared with WT controls. In these cases, pSer129-α-syn staining was restricted to cell bodies and processes of projection neurons in layers 2a and b, and layer 3 (Fig. 7N,Q) of α-syn-Tg mice. Interestingly, there was a lack of pSer129-α-syn labeling in layer 2a of APC compared with PPC (Fig. 5N,Q). Sublayer 2a is occupied by semilunar cells (SL; Mazo et al., 2017), and the reasons for the differential expression in APC versus PPC requires further analyses.

Collectively, these data showed substantial evidence of α-syn pathology throughout the central olfactory pathway, with a prominent accumulation in projection neuron cell bodies and processes, whose pathology seems likely to be linked to olfactory deficits at late stages of PD.

Ultrastructural analysis revealed unaltered synaptic and mitochondrial numbers in α-syn-Tg mice

We next asked whether synaptic connectivity was impacted in α-syn-Tg mice at 12–14 months. We used EM to quantify number and type of synapses found in the two primary regions in the olfactory pathway where projection neurons make synaptic contacts: (1) the OB glomerular neuropil (Gl), where M/Tc receive excitatory asymmetrical synapses from OSN axons and inhibitory symmetrical synapses with periglomerular interneurons (Kasowski et al., 1999); and (2) layer 1 of the APC, where axons from M/Tc make asymmetrical excitatory synapses with apical dendrites of PC pyramidal cells in layer 1a and local interneurons make symmetrical inhibitory synapses with the PC pyramidal apical dendrites in layer 1b (Sarma et al., 2011; Martin-Lopez et al., 2019). In both regions, we quantified asymmetric (Fig. 8, red arrowheads), symmetric (Fig. 8, green arrowheads), and reciprocal (Fig. 8, yellow arrowheads) synapses. We also quantified the number of mitochondria, whose dysfunction is reported to play a determining role in the progression of PD and can also be used as a proxy for neuronal activity (Trinh et al., 2021).

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Figure 8.

Ultrastructure of synapses and mitochondria in the OB glomeruli and APC layer I. A, B, Representative images of electron microscopy in the glomeruli of OBs from WT and α-syn-Tg mice. Number of mitochondria (Mito) and different types of synapses are quantified and highlighted as: asymmetric (Asym.; red arrowheads), symmetric (Sym.; green arrowheads), and reciprocal (Rec.; yellow arrowheads). C, Quantification of Mito. and synapses in the glomeruli parenchyma show no statistical differences between WT and α-syn-Tg mice. D, Representation of the number of Mito. and total synapses counted per image and arranged from the smallest to the greatest number of objects, showing a strong trend of α-syn-Tg mice to have less Mito., although no statistical differences are found. E, F, Representative images of APC layer 1 parenchyma at EM showing asymmetric (red arrowheads) and symmetric (green arrowheads) synapses. G, Quantification of mitochondria and synapses in APC showing no statistical differences between WT and α-syn-Tg mice. H, Representation of the distribution of mitochondria and synapses on each image arranged from lowest to highest number of objects showing a similar trend to that observed in OB. APC: Anterior Piriform Cortex; EM: Electron Microscopy; OB: Olfactory Bulb. Scale bars: 0.5 µm. Statistics: unpaired t test.

Total numbers of synapses and mitochondria between WT and α-syn-Tg mice in both the Gl (Fig. 8A–C) or APC (Fig. 8E–G) parenchyma showed no statistical differences: number of synapses in OB (p = 0.6819; t = 0.4412, df = 4) and APC (p = 0.4953; t = 0.7494, df = 4), asymmetric synapses in OB (p = 0.5449; t = 0.6609, df = 4) and APC (p = 0.7396; t = 0.3563, df = 4), symmetric synapses in OB (p = 0.2292; t = 1.418, df = 4) and APC (p = 0.7096; t = 0.400, df = 4), reciprocal synapses in OB (p = 0.2301; t = 1.414, df = 4) and APC (p = 0.1929; t = 1.564, df = 4), and mitochondria in OB (p = 0.2605; t = 1.309, df = 4) and APC (p = 0.0685; t = 2.475, df = 4). These data indicated that anomalies in number of mitochondria or synapses were unlikely to account for olfactory dysfunction. Interestingly, when the data are arranged by individual images from lower to highest number of elements (mitochondria or synapses), we found a consistent trend for fewer mitochondria and synapses in α-syn-Tg mice compared with WT controls (Fig. 8D,H). Collectively, our data did not show evidence of morphologic and ultrastructural changes that could explain the olfactory deficits observed in α-syn-Tg mice at late stages (12–14 months).

Adult subventricular zone proliferation and olfactory bulb neurogenesis in α-syn-Tg mice

Previous studies suggested that overexpression of human WT or hA30P mutant α-syn in animal models of PD results in altered neurogenesis in different layers of the OB (Winner et al., 2004; Marxreiter et al., 2009; Neuner et al., 2014; Schreglmann et al., 2015). Neurogenesis of OB interneurons occurs throughout the lifetime of an individual and is crucial to the control and modulation of olfaction (Whitman and Greer, 2009; Lazarini and Lledo, 2011). Newly generated interneurons proliferate from neural stem cells located in the subventricular zone (SVZ) of the lateral ventricles (LV), after which they migrate toward the OB in a migratory chain called the rostral migratory stream (RMS; Lim and Alvarez-Buylla, 2016). New neuroblasts in this pathway take an average of 12–14 d to reach the OB in adult mice (Mobley et al., 2013) and approximately another week to integrate in the OB circuits (Whitman and Greer, 2007). Here, we sought to evaluate the effect of α-syn pathology on the neurogenesis of interneurons targeted to the OB at early (six to seven months) and late (12–14 months) stages of the disease, that is, before and after the onset of hyposmia. Newly formed neurons were identified by injecting BrdU, and tissues analyzed at 25 d postinjection (DPI). We quantified BrdU⁺ cells in three layers of the OB receiving interneurons from this route, namely, the GL, GCL, and bulbar part of the RMS.

In the GL, we found no difference in the number of BrdU⁺ periglomerular neurons (PGNs) at six to seven months by genotype (Fig. 9E; p = 0.7213; t = 0.3695, df = 8) but showed a significant decrease at 12–14 months (Fig. 9E; p = 0.0491; t = 2.460, df = 6), indicating that the hA30P mutant α-syn affected the neurogenesis at late stages of the disease progression (Fig. 9A–D,a'–d',E). Since our quantification of PGNs that were TH+ showed no differences between WT and α-syn-Tg mice (see above) and considering that no BrdU⁺-PGNs expressed TH (Fig. 10E,F), we concluded that the PGN population affected by the expression of hA30P mutant α-syn at 12–14 months did not include dopaminergic PGNs. In the GCL, we detected a significant decrease in the number of BrdU⁺ cells only at early (six to seven months) stages (Fig. 9F; six to seven months: p = 0.0136; t = 3.152, df = 8; vs 12–14 months: p = 0.095; t = 1.976, df = 6), highlighting that hA30P mutant α-syn overexpression was affecting OB neurogenesis in the GCL before the onset of olfactory deficits (Fig. 9A–D,a–d,F). This is consistent with results from similar animal models expressing the hA30P α-syn mutation under the CaMK-tet regulated promoter (Marxreiter et al., 2009). The differences observed between both ages and layers may plausibly be because of the global decrease in neurogenesis of cells targeting the OB during aging (Mobley et al., 2013, 2014). Further, differences in the addition of new neuroblasts in the GCL and GL layers occur with aging with declines in the GCL but increases in the GL (Ninkovic et al., 2007). Both effects may have masked the effect of hA30P mutant α-syn in the granule cells at 12–14 months and the periglomerular neurons at six to seven months. Finally, there was no evidence of a change in the number of BrdU⁺ cells in the OB-RMS at either six to seven months (Fig. 9G; p = 0.6048; t = 0.5386, df = 8) or 12–14 months (Fig. 9G; p = 0.1076; t = 1.890, df = 6; Fig. 9A–D,a–d). Since BrdU injections at adult stages could only label OB interneurons generated in the SVZ and considering that α-syn pathology was only expressed in projection neurons of the olfactory pathway (Figs. 3, 5–7), the effects observed in OB neurogenesis are presumably indirect, for instance via an alteration in the dopamine release into the SVZ (Höglinger et al., 2004; Taylor et al., 2014). To test whether hA30P mutant α-syn had an effect on the SVZ proliferation, we injected WT and α-syn-Tg mice with BrdU and analyzed the proliferation rate 24 h postinjection, before the labeled cells migrating into the RMS. We did not find a statistically significant decrease in the number of labeled cells in the transgenic mice versus WT (WT= 237 ± 28 BrdU cells/0.1 mm² vs α-syn-Tg= 197 ± 53 BrdU cells/0.1 mm²; p = 0.2351). Thus, proliferation in the SVZ does not appear to fully account for differences in BrdU labeling in the GCL and GL (see below for further discussion).

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Figure 9.

Effect in adult neurogenesis in the olfactory bulb glomerular and granule cell layers of α-syn-Tg mice. Neurogenesis is studied by counting newly generated cells 25 d after they incorporated the thymidine analog BrdU during cell division at the moment of injection. BrdU staining is shown in green, while immature neurons (neuroblasts) are identified with doublecortin (DCX) marker (red). A–d', Representative images of OB coronal sections in WT and α-syn-Tg mice at six to seven months (A, a', B, b') and 12–14 months (C, c', D, d') stages. Insets are high-magnification images of BrdU-labeled and DCX-labeled cells located in the RMS + GCL (a–d) or the GL (a'–d'). E, Quantification of BrdU cells in the GL shows a statistically significant decrease of cells in α-syn-Tg mice at late stages 12–14 months, and an overall increase in the total number of BrdU⁺ cells in this layer between 6- to 7- and 12- to 14-month mice. F, Analysis of BrdU cells in the GCL shows a statistically significant decrease of labeled cells in α-syn-Tg mice exclusively at early stages of the disease (6–7 months). G, Quantification of BrdU⁺ cells in the RMS showing no statistical differences between WT and α-syn-Tg mice. Nuclei counterstained with Dapi (blue). EPL: external plexiform layer; GL: glomerular layer; Gl: individual glomeruli; GCL: granule cell layer; MCL: mitral cell layer; RMS: bulbar portion of the rostral migratory stream. Scale bars: 500 µm (A–D), 100 µm (a–d), 50 µm (a'–d'). *p < 0.05. Statistics: unpaired t test.

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Figure 10.

Characterization of cellular phenotypes of BrdU-expressing cells in the olfactory bulb and subventricular zone after 25 d of injection. BrdU staining (green) is shown with different markers typical of neuronal and glial cells (red). A–J, Phenotypic characterization in the OB. A, B, No BrdU⁺ cell expresses the neuroblast marker DCX in either the GCL or RMS. C, D, Identification of mature neurons with NeuN in the GCL, which accounts for roughly 43% and 30% of the BrdU⁺ cells in WT controls and α-syn-Tg mice, respectively. E, F, Detection of dopaminergic neurons in the GL using the TH markers. No colocalization is seen with BrdU⁺ cells. G, H, GFAP marker is used to identify astrocytes shows no colocalization with BrdU⁺ cells. I, J, Microglial cells expressing IBA1 do not colocalize with BrdU⁺ cells either. K–S, Phenotypic characterization in the SVZ of WT control and α-syn-Tg mice. K, L, DCX marker is used to label neuroblast or “A” cells which do not colocalizes with BrdU⁺ cells. M, N, GFAP is used to label radial glia neural stem cells or “B” cells do not colocalizes with BrdU⁺ cells. O, P, TBR2 used to identify SVZ-dorsal TACs do not colocalizes with BrdU⁺ cells. Q, R, Dlx2 is used to label TACs or “C” cells which colocalizes with adult resident BrdU⁺ cells at the time of study (25 d post-BrdU injection). S, Greyscale image of the analyzed region showing the anatomic location of the SVZ next to the ventricular zone (VZ) and the lateral ventricle (LV). Nuclei counterstained with Dapi (blue). DCX: doublecortin; Dlx2: Distal-Less Homeobox 2; GCL: granule cell layer; GFAP: glial fibrillary acidic protein; IBA1: ionized calcium-binding adapter molecule-1; NeuN: neuronal nuclei marker; OB: olfactory bulb; RMS: rostral migratory stream; SVZ: subventricular zone; TACs: transient amplifying cells; TBR2: T-Box brain transcription factor-2; TH: tyrosine hydroxylase. Scale bars: 400 µm (S), 50 µm (A–J), 25 µm (K–R).

Collectively, our data showed that hA30P mutant α-syn affected OB neurogenesis in the GCL at early stage before the onset of olfactory deficits, whereas neurogenesis in the GL was affected in the later stages when olfactory deficit was apparent in α-syn-Tg mice, both effects being independent of cells proliferation in the SVZ.

To ensure that all BrdU⁺ cells belonged to neuronal lineages and to exclude cell division by local glial cells, we characterized BrdU⁺ cell phenotypes with IHC using specific markers to detect neuroblasts, mature neurons and glial cells in the two regions we found BrdU-labeled cells: the OB and the SVZ. First, we looked for neuroblasts by using doublecortin (DCX), a microtubule-associated protein required for the migration of cells. BrdU⁺ cells that were located in the OB did not colocalize with the DCX marker (Fig. 10A,B), suggesting that most BrdU⁺ cells have completed migration and begun to differentiate into neurons at the time of the study. This is consistent with our prior studies showing that OB neuroblasts require three weeks to migrate and differentiate into neurons after generation in the SVZ (Whitman and Greer, 2007; Mobley et al., 2013). Mature neurons in the OB were identified using the neuronal nuclei marker NeuN. Unexpectedly, only a fraction of the total number of BrdU⁺ cells (representing ∼40% of the total) colocalized this marker in the OB (Fig. 10C,D), suggesting that the remaining ∼60% of BrdU⁺ cells could be neurons in intermediate stages of differentiation with a DCX^–/NeuN^– phenotype. We also looked for an effect in the TH subpopulation within the GL, a group of mature PGNs reported to be affected in PD patients (Mundiñano et al., 2011) and in similar animal models (Lelan et al., 2011; Neuner et al., 2014). Our data demonstrated that none of the BrdU⁺-cells in the GL colocalized with the TH marker (Fig. 10E,F). To ensure that the DCX^–/NeuN^– phenotypes did not belong to dividing glial cells, we searched for astrocytes and microglial cells using glial fibrillary acid protein (GFAP) and ionized calcium-binding adapter molecule 1 (IBA1), respectively. Neither GFAP (Fig. 10G,H) nor IBA1 (Fig. 10I,J) colocalized with BrdU⁺ cells, indicating they were not dividing glial cells. In the SVZ, these markers identify characteristic subpopulations of cells that represent the three differentiation stages of OB interneurons: “A” cells or neuroblasts (DCX⁺); “B” cells or neural stem cells, which share a phenotype with radial glial cells (GFAP⁺); and “C” cells or intermediate transient amplifying cells (TACs; Dlx2⁺ and Tbr2⁺ for dorsal TACs; Lim and Alvarez-Buylla, 2016). Our results showed that BrdU⁺ cells found in the SVZ were negative for DCX (Fig. 10K,L), GFAP (Fig. 10M,N), and Tbr2 (T-Box Brain Protein-2; Fig. 10O,P), indicating they were no “A,” “B,” or dorsal “C” cells. However, they expressed Distal-Less Homeobox 2 factor (Dlx2), characteristic of all “C” cells (Lim and Alvarez-Buylla, 2016), indicating that some “C” (TAC) cells remained in the SVZ 25 d after the BrdU injection. These cellular classifications were uniform for both WT and α-syn-Tg mice.

Collectively, we found that the hA30P mutant α-syn expression significantly reduced OB neurogenesis in the GCL at early stages (six to seven months) and in the GL at later stages (12–14 months), respectively. Among the BrdU ⁺ cells found in the OB, ∼40% of them were differentiated to neurons (DCX^–/NeuN⁺), while the remaining ∼60% (DCX^–/NeuN^–) remained at intermediate stages of neuronal differentiation. In addition, the scarce number of BrdU⁺ cells found in the SVZ were transient amplifying cells or “C” cells.

Age-related changes in synaptic endocytic proteins in α-syn-Tg mice

To further understand development of olfactory system pathology in an unbiased manner, we performed proteomic analysis on OB and APC from six- to seven-month and 12- to 14-month WT and α-syn-Tg mice (n = 3/genotype with technical triplicates) by label-free quantification mass spectrometry (LFQ-MS). Our proteomic analysis of the OBs from six- to seven-month mice identified a total of 3328 proteins, 14 of which were significantly differentially expressed in α-syn-Tg mice (Fig. 11A,B; Table 2). Consistent with transgenic overexpression and immunohistochemical results, we observed a significant increase in α-syn expression in the OB of α-syn-Tg mice (SYUA; Fig. 11A,B). This was confirmed via Western blotting (Fig. 4A). Protein kinase c-Src was the most significantly upregulated protein in the OB of α-syn-Tg mice (SRC, Fig. 11A,B, fold change of 2.88). Among other functions, protein kinase c-Src phosphorylates components of endocytic trafficking (Reinecke and Caplan, 2014) and notably, α-syn (Ellis et al., 2001). GO enrichment analysis performed on the proteins that showed significant changes (p > 0.05) identified pathways involving vesicle-mediated transport, specifically endocytosis, which were significantly enriched (Fig. 11C). The vast majority of proteins from our dataset that were implicated in these pathways were downregulated in α-syn-Tg samples (Fig. 11A,B), suggesting a deficit in vesicle-mediated transport in the OB. Overall, proteomic analysis of the OB at early stages revealed dysfunction in endocytosis and vesicular transport.

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Figure 11.

Proteomics of OB and APC revealed defects in synaptic endocytosis and exocytosis pathways in the OB, but minimum alterations in APC of α-syn-Tg mice. A, Volcano plot of fold change in the OB proteome of six- to seven-month α-syn-Tg compared with control wild-type (WT) mice (n = 3 mice/genotype). Proteins that changed 1.25-fold (vertical dotted lines) with a p-value of <0.05 (horizontal dotted line) are considered to be significantly differentially expressed. Among the 14 significant proteins, eight are upregulated (red) and six are downregulated (blue). B, Heat map of significantly differentially expressed proteins in OB of α-syn-Tg compared with WT mice at early stage (6–7 months) for each technical replicate (3 technical replicates/mouse). Red indicates increased expression (+2), and blue indicates decreased expression (−2). C, Biological pathways that are significantly (FDR < 0.05) affected in the OB of six- to seven-month α-syn-Tg mice, determined by GO enrichment analysis. D, Volcano plot of fold change in the OB proteome of 12- to 14-month α-syn-Tg compared with WT mice (n = 3 mice/genotype). Among the 15 significantly differentially expressed proteins (1.25-fold, p < 0.05), seven are upregulated (red) and eight are downregulated (blue). E, Heat map of significantly differentially expressed proteins in OB of late stage (12–14 months) α-syn-Tg mice compared with their WT counterparts for each technical replicate (3 technical replicates/mouse). F, Biological pathways that are significantly (FDR < 0.05) affected in the OB of 12- to 14-month α-syn-Tg mice, determined by GO enrichment analysis. G, Volcano plot of fold change in the APC proteome. α-syn-Tg compared with WT mice (n = 3 mice/genotype) at six to seven months. All the 11 significantly differentially expressed proteins (1.25-fold, p < 0.05) are upregulated in α-syn-Tg mice. H, Heat map of significantly differentially expressed proteins in APC of α-syn-Tg compared with WT mice at six to seven months for each technical replicate (3 technical replicates/mouse). I, Biological pathways that are significantly (FDR < 0.05) affected in the APC of six- to seven-month α-syn-Tg mice, determined by GO enrichment analysis. J, Volcano plot of fold change in the APC proteome of α-syn-Tg compared with WT mice (n = 3 mice/genotype) at 12–14 months. Among the 16 significantly differentially expressed proteins (1.25-fold, p < 0.05), 12 are upregulated (red) and four are downregulated (blue). K, Heat map of significantly differentially expressed proteins in APC of α-syn-Tg mice compared with WT controls for each technical replicate (3 technical replicates/mouse) at 12–14 months. L, Biological pathways that are significantly (FDR < 0.05) affected in the APC of 12- to 14-month α-syn-Tg mice, determined by GO enrichment analysis. APC: anterior piriform cortex; FDR: False Discovery Rate; GO: Gene Ontology analysis; OB: olfactory bulb.

In the OB of 12- to 14-month mice, proteomic analysis detected a total of 2712 proteins, 15 of which were significantly differentially expressed in α-syn-Tg samples (Fig. 11D,E; Table 3). There was a trend in overexpression of α-syn (SYUA), which was confirmed via Western blotting (Fig. 4A). Similar to what we found in six- to seven-month mice, GO analysis identified pathways involving vesicle-mediated transport, specifically at the presynapses, as significantly enriched (Fig. 8F). These pathways were driven by a majority of proteins that were downregulated in α-syn-Tg samples, including the vesicular trafficking proteins PICALM, UNC13A, SNAP29, and VPS45 (Fig. 11D,E). Thus, proteomic analysis at late stages (12–14 months) reaffirms the endocytic and vesicular transport defects seen at six to seven months in the OB (Fig. 11A–C), and provided additional evidence that, with age, these deficits became prominent in synaptic terminals of α-syn-Tg mice.

In the APC of six- to seven-month mice, proteomic analysis identified a total of 2955 proteins, 11 of which were significantly differentially expressed in α-syn-Tg samples (Fig. 11G,H; Table 4). As anticipated, we observed a significant increase in α-syn expression (SYUA; Fig. 11D,E). Interestingly, GO analysis largely revealed broader dysfunction in cellular metabolism (Fig. 11F) without enrichment of any vesicle mediated-transport pathways seen in the OB (Fig. 11C). In the APC of 12- to 14-month mice, proteomic analysis identified a total of 2596 proteins, 16 of which were significantly differentially expressed in α-syn-Tg samples (Fig. 11J,K; Table 5). Similarly, GO analysis revealed only a subtle dysregulation in receptor clustering in α-syn-Tg samples, without any dysregulation of synaptic endocytosis and exocytosis as seen in the OB of these mice. Collectively, our proteomic analysis suggested that the OB is more vulnerable to α-syn pathology induced by the hA30P α-syn mutation expression than the APC, and that olfactory deficits seen at late stages might arise because of early age-related endocytic changes in the synaptic terminals of the OB circuitry.