Identification of an early subset of cerebellar nuclei neurons in mice

Maryam Rahimi-Balaei; Shayan Amiri; Thomas Lamonerie; Sih-Rong Wu; Huda Y Zoghbi; G Giacomo Consalez; Daniel Goldowitz; Hassan Marzban

doi:10.7554/eLife.93778.3

eLife Assessment

The authors are interested in the developmental origin of the neurons of the cerebellar nuclei. In this study, they identify a population of neurons with a specific complement of markers that originate in a distinct location from where cerebellar nuclear precursor cells have been thought to originate that show distinct developmental properties. The discovery of a new germinal zone giving rise to a new population of neurons is an exciting finding, and it enriches our understanding of cerebellar development. The important claims, better explained in the current version, are well supported by solid evidence with the authors using a wide range of technical approaches, including transgenic mice that allow them to disentangle the influence of distinct developmental organizers

https://doi.org/10.7554/eLife.93778.3.sa3

Significance of findings

important: Findings that have theoretical or practical implications beyond a single subfield

landmark
fundamental
important
valuable
useful

Strength of evidence

solid: Methods, data and analyses broadly support the claims with only minor weaknesses

exceptional
compelling
convincing
solid
incomplete
inadequate

During the peer-review process the editor and reviewers write an eLife assessment that summarises the significance of the findings reported in the article (on a scale ranging from landmark to useful) and the strength of the evidence (on a scale ranging from exceptional to inadequate). Learn more about eLife assessments

Abstract

Cerebellar nuclei (CN) neurons serve as the primary output of the cerebellum and originate from the cerebellar primordium at early stages of cerebellar development. These neurons are diverse, integrating information from the cerebellar cortex and relaying it to various brain regions. Employing various methodologies, we have characterized a specific subset of CN neurons that do not originate from the rhombic lip or ventricular zone of the cerebellar primordium. Embryos were collected at early stages of development and processed for immunohistochemistry (IHC), Western blotting, in situ hybridization (ISH), embryonic culture, DiI labeling, and flow cytometry analysis (FCM). Our findings indicate that a subset of CN neurons expressing α-synuclein (SNCA), OTX2, MEIS2, and p75NTR (NGFR) are located in the rostroventral region of the nuclear transitory zone (NTZ). While CN neurons derived from the rhombic lip are positioned in the caudodorsal area of the NTZ in the cerebellar primordium. Utilizing Otx2-GFP and Atoh1^−/− mice, we have determined that these cells do not originate from the germinal zone of the cerebellar primordium. These results suggest the existence of a novel extrinsic germinal zone for the cerebellar primordium, possibly the mesencephalon, from which early CN neurons originate.

Significance statement

The cerebellum contains a variety of distinct neuronal populations, each playing a significant role in its function within the brain. This research demonstrates that a particular subset of cerebellar nuclei neurons originates from a previously unrecognized germinal zone specific to the cerebellar primordium, independently of Atoh1’s influence.

Introduction

The cerebellum, a key player in both motor and non-motor functions, is a complex structure composed of the cerebellar nuclei (CN) and cerebellar cortex. The CN, the main cerebellar output to the rest of brain, are comprised of at least three distinct neuronal types: glutamatergic, GABAergic, and glycinergic neuron (Koziol et al., 2014, Manto et al., 2012, Marzban et al., 2015). In the mouse, the cerebellar primordium, an early structure in cerebellar development, emerges at approximately embryonic day (E) 7–E8 from the alar plate of the rhombomere-1(Kebschull et al., 2023, Goldowitz and Hamre, 1998, Sotelo, 2004, Wang and Zoghbi, 2001a, Marzban et al., 2015). The cerebellar primordium is rostrally limited by the isthmus, a boundary between the mesencephalon (midbrain)-rhombencephalon (hindbrain). Two key genes, orthodenticle homeobox 2 (Otx2) and gastrulation brain homeobox 2 (Gbx2), are among the earliest genes expressed in the neuroectoderm, dividing it into anterior and posterior domains with a border that marks the isthmus. Otx2 is crucial for the development of the forebrain and midbrain, while Gbx2 is essential for the anterior hindbrain (Millet et al., 1999). The isthmus, where Otx2 and Gbx2 expression meets, is a multi-signaling center that regulates other genes essential for the early development of both the midbrain and cerebellar primordium (Joyner et al., 2000, Wurst and Bally-Cuif, 2001).

The cerebellar primordium contains two distinct germinal zones, which are responsible for cerebellar neurogenesis and gliogenesis; the ventrally-located ventricular zone (VZ) and dorsally-located rhombic lip (RL) (Fink et al., 2006). Early studies on the development of CN indicated that both glutamatergic and GABAergic CN neurons originate from the cerebellar VZ (Voogd and Glickstein, 1998). Further studies highlighted the involvement of the RL as an origin for glutamatergic CN neurons (between E9-E12) (Fink et al., 2006, Wang and Zoghbi, 2001a, Green and Wingate, 2014, Machold and Fishell, 2005, Kebschull et al., 2023). LIM homeobox transcription factor 1 alpha (LMX1A) regulates the development of the glutamatergic CN neurons originating from the RL. It is also expressed in the nuclear transitory zone (NTZ) and is considered to be a marker for the majority of rhombic lip-derived CN neurons in addition to a subset of LMX1A positive cells that do not originate from the RL migratory stream (Chizhikov et al., 2006, Chizhikov et al., 2010).

Extensive developmental studies have shown that all cerebellar cells are produced sequentially from the VZ and the upper RL (Marzban et al., 2015). In this report, we provide evidence that a subset of CN neurons expressing OTX2, α-Synuclein (SNCA), MEIS2, and p75 neurotrophin receptor (p75NTR)/Nerve Growth Factor Receptor (NGFR) originate from the rostral end of the cerebellar primordium and are positioned in the rostroventral region of the NTZ during early cerebellar development. Our data suggest that the mesencephalon represents a third germinal zone and is the origin of previously unrecognized neurons that contribute to CN formation and development.

Results

In mouse embryos, the earliest neuronal populations, which are located at the rostral end of the cerebellar primordium, are immunopositive for neurofilament-associated antigens (NAA; detected by 3A10 antibody), a marker typically expressed in neuronal somata and axons (Marzban et al., 2008, Marzban et al., 2019) (Fig. 1). To further explore these cells in the rostral end of the cerebellar primordium at E9, we used an antibody to detect SNCA, which is expressed in CN neurons during embryogenesis (Zhong et al., 2010). We identified SNCA⁺ neurons at the rostral end of the NTZ in the cerebellar primordium (Fig. 1E-F and Fig. Suppl. 4). At E12, we aimed to determine the location of the SNCA⁺ cells in the cerebellar primordium and compare their position with that of the rhombic lip-derived LMX1A⁺ CN neurons (E10-12) in the NTZ. To perform this, double immunofluorescence labeling of SNCA and LMX1A (Fig. 2 A-D, medial section and Fig. E-H, lateral section) showed that an LMX1A⁺ population of CN neurons, originating from the RL, either flanks SNCA⁺ neurons in the medial section (Fig. 2A-D) or is located dorsally in the lateral section (Fig. 2E-H) in the NTZ. This indicates that SCNA⁺ cells are a distinct cell population different from rhombic lip-derived LMX1A+ cells. To further explore the characteristics of SNCA⁺ cells, we wanted to determine whether these cells originate from the mesencephalon. OTX2 which is highly expressed in the mesencephalon, has its caudal limit at the boundary of the rhombencephalon (i.e., the isthmus)(Kurokawa et al., 2004), thus makes it an appropriate marker for identifying mesencephalon-derived cells. Interestingly, results from double immunofluorescence experiments in sagittal sections of E12 cerebella showed that OTX2 was highly expressed in the mesencephalon (Fig. 3A, B), and was co-expressed with SNCA⁺ cells in the rostral region of the cerebellar primordium (Fig. 3 A-E). This result suggests that SNCA⁺ cells originate from the mesencephalon. Next, we used quantitative flow cytometry analysis to determine whether OTX2⁺ cells co-express SNCA and/or LMX1A (Fig. 3F, G). An increase in the number of OTX2 and SNCA positive cells (but not LMX1A) was observed at E14 in comparison to E12 (*p<0.05). Interestingly, the majority of neural cells were not SNCA⁺/LMX1A⁺, consistent with our IHC findings, or SNCA⁺/OTX2⁺, with the exception of a few cells that did show co-labeling. Of note, more SNCA⁺/OTX2⁺ than SNCA⁺/LMX1A⁺ cells were detected at E12 compared to E14, indicating the co-expression of these markers at different time point during cerebellar development. An increase in the OTX2 expression at the rostral end of the cerebellar primordium was also confirmed by the IHC at E12-E15 (Fig. 4 A-F). The total number of OTX2⁺ cells in the cerebellar primordium sections were counted from E12 to E15 (Fig. 4G) and comparison between these embryonic stages indicated a slight increase in the number of OTX2+ cells between E12 and E15. Significant differences were observed between E12 and E14 (**p<0.01), E12 and E15 (***p<0.001), as well as E13 and E15 (#p<0.05).

The presence of neurons in the cerebellar primordium at E9 and spatial expression of SNCA. The cerebellar primordium immunostained with NAA and SNCA, shows that a distinct subset of neurons located at the rostral end of the developing cerebellum.
A: Dorsal view of the schematic illustration of the cerebellar primordium, mesencephalon, isthmus, and 4th ventricle. The red line indicates the sagittal plane about which the sections shown in **B-D** were taken.
**B-D:** Sagittal section through the cerebellar primordium at early E9 immunoperoxidase-labeled with NAA 3A10 shows the presence of neurons in the cerebellar primordium that cross the isthmus (i) and continue to the mesencephalon. C. A higher magnification of **B. D**. Differentiated neurons at E9.5 are visible; a higher magnification is shown in the inset, d.
E: Sagittal section through the cerebellar primordium at late E9. Immunofluorescence labeling of SNCA shows SNCA⁺ (green) expressing CN neurons in the mesencephalon, at the isthmus (i) and in the rostral part of the cerebellar primordium (cb). F. A higher magnification of E.
Abbreviations: 4thv, 4th ventricle; cb, cerebellum; c, caudal; d, dorsal; i, isthmus; m, mesencephalon; r, rostral; v, ventral
Scale bar = 100 µm in B; 50 µm in C and E; 20 µm in D

SNCA expression relative to Lmx1a in the early developing mouse cerebellum. The sagittal section through the cerebellar primordium at E12.5 reveals double immunofluorescence labeling with SNCA and LMX1A antibodies in both medial (panels A-D) and lateral (panels E-H) sections.
**A–G:** SNCA (green, A and E) and LMX1A (red, B and F) immunopositive cells are located at the NTZ. SNCA⁺ cells continue to the mesencephalon, and LMX1A⁺ cells toward the rhombic lip. Merged images show that the SNCA⁺ cells form a population of CN neurons distinct from the rhombic lip-derived cells (LMX1A⁺) in the NTZ (C and G). D and H show a higher magnification of C and G, respectively.
Abbreviations: 4thV, 4th ventricle; cb, cerebellum; c, caudal; d, dorsal; i, isthmus; m, mesencephalon; rl, rhombic lip; NTZ, nuclear transitory zone; r, rostral; v, ventral.
Scale bar = 100 µm.

Expression of SNCA and OTX2 in the developing cerebellar primordium. Double immunofluorescence labeling with SNCA and OTX2 antibodies in sagittal sections of the cerebellar primordium at E12.5.
**A–E:** Double immunolabeling of SNCA (green) and OTX2 (red) of a sagittal section of the cerebellar primordium at E12.5 A. High OTX2 immunoreactivity was detected in the mesencephalon. SNCA⁺ cells in the mesencephalon accompany OTX2⁺ cells across the isthmus (i) and in the NTZ. B. higher magnification of A. **C-E**. Immunolabeling with SNCA (green, C) and OTX2 (red, D) and merged (E) shows co-expression in the NTZ.
**F-G:** Cerebellar cells at E12 and E14 were dissociated and immunolabeled for SNCA + OTX2, SNCA + LMX1A, or each antibody individually (F). Quantitative analysis was performed by flow cytometry to detect SNCA⁺, OTX2⁺, LMX1A⁺, SNCA⁺/ LMX1A⁺ and SNCA⁺/ OTX2⁺ cells (G). No significant differences were observed for the number of LMX1A⁺ cells between E12 and E14. An increase in SNCA and OTX2 positive cells was shown at E14 in comparison to E12 (*P<0.05). The number of cells positive for SNCA/LMX1A or SNCA/OTX2 was very low at E12 and E14.
Abbreviations: 4thv, 4th ventricle; cb, cerebellum; c, caudal; d, dorsal; i, isthmus; m, mesencephalon; rl, rhombic lip; NTZ, nuclear transitory zone; r, rostral; v, ventral.
Scale bar = 200 µm in A; 50 µm in B; 20 µm in C, D, and E.

The spatial and temporal expression of OTX2 in the developing cerebellum of mice. Sagittal sections through the cerebellar primordia at E12, 13, 14, and 15 were analyzed for peroxidase immunoreactivity of OTX2.
**A–F:** Sagittal section through cerebellar primordium at E12 (A; higher magnification shown in B), E13 (C; higher magnification shown in D), E14 (E), and E15 (F). High OTX2 immunoreactivity at the mesencephalon is evident, and a few OTX2+ cells cross the isthmus and position at the rostral part of the cerebellar primordium at the NTZ. Examples of Otx2 expressing cells are indicated by arrowheads in panels B, D, E, and F. In panels E and F, the isthmus and adjacent cerebellar area are showed in the same orientation as panels A-D (I; isthmus). The orientation label (r-c and d-v; rostral caudal and dorsal ventral) in panel A applies to all panels.
G: Comparison of the number of OTX2 positive cells in the cerebellar primordium from E12 to E15. Results indicate a slight increase in the number of OTX2 positive cells over time. Significant differences were observed between E12 and E14 (**P<0.01), E12 and E15 (***P<0.001), as well as E13 and E15 (#P<0.05). Data were analyzed by One-Way ANOVA followed by a Tukey’s multiple comparison test. Abbreviations: 4thv, 4th ventricle; cb, cerebellum; c, caudal; d, dorsal; i, isthmus; m, mesencephalon; rl, rhombic lip; r, rostral; v, ventral.
Scale bar = 200 µm in A and C; 50 µm in F (applies to B, D, E, and F).

To further confirm the presence of OTX2⁺ cells in the rostral end of the cerebellar primordium, we used Otx2-GFP transgenic mice and performed double immunofluorescence labeling with OTX2 and GFP on E13 sections (Fig. 5). Results showed that an extension of OTX2-GFP positive cells, highly prevalent in the mesencephalon, crossed the isthmus and terminated in the rostral end of the cerebellar primordium in the NTZ (Fig. 5B, C, and D). To further validate our observations, we employed RNAscope fluorescence in situ hybridization (FISH) at E12 to detect the presence of Otx2 mRNA in the cerebellar primordium (Fig. 5 E-J). Otx2 mRNA was highly expressed in the mesencephalon and caudally extended to the rostral cerebellar primordium in the NTZ (Fig. 5 E-J and Suppl. Fig. 4).

Otx2 expression in developing cerebella of Otx2-GFP transgenic and control mice. Sagittal sections through the cerebellar primordium of Otx2-GFP transgenic mice at E13 are shown in panels A-D, and RNAscope fluorescence in situ hybridization (FISH) of Otx2 at E12 in wild-type mice in panels E-J.
**A-D:** DAPI labels the outline of the cerebellar primordium and mesencephalon (A, blue). GFP expression, which is enhanced by immunofluorescence labeling with anti-GFP (B, green), and immunofluorescence labeling for OTX2 (C, red), reveal co-labeled cells (D, merged) in the mesencephalon and NTZ at the rostral end of the cerebellar primordium. Arrows indicate the isthmus.
**E-G:** Merged channels of the *in situ* hybridization of *Otx2* mRNA probe counterstained with DAPI at low (E) and high (F and G) magnification captured by confocal microscopy.
**H-J:** The Otx2 mRNA signal was strong in the mesencephalon and extended as a tail through the isthmus to the rostral cerebellar primordium in the NTZ. The isthmus is indicated by arrows in (**E, F, H, I**) and a line in (J).
Abbreviations: cb, cerebellum; c, caudal; d, dorsal; m, mesencephalon; rl, rhombic lip; ntz, nuclear transitory zone; r, rostral; v, ventral.
Scale bar = 200 µm in D (applies to A-D); 100 µm in H (applies to E and H); 20 µm in J (applies to F - J).

To evaluate whether OTX2⁺ cells are present in the absence of Snca gene expression, we used Pap^−/−; Snca^−/−mice. OTX2 immunoperoxidase staining showed that even in the absence of Snca expression, OTX2⁺ cells still terminated in the rostral cerebellar primordium (Suppl. Fig. 1). This indicates that the expression of Otx2 in these cells is independent of SNCA. We previously reported that nerve growth factor receptor (p75NTR; Ngfr), a neuronal proliferation and differentiation marker, was expressed in the rostral end of the cerebellar primordium in Pap^−/−; Snca^−/− mice (Jiang et al., 2008, Bernabeu and Longo, 2010, Dechant and Barde, 2002, Rahimi-Balaei et al., 2019b). To determine whether SNCA⁺ neurons are p75NTR immunopositive, double immunolabeling with SNCA and p75NTR revealed that SNCA⁺ cells in the NTZ exhibited cell membrane expression of p75NTR (Fig. 6A–D). This data was further confirmed by Western blot analysis of SNCA and p75NTR protein expression in embryonic cerebellar lysates (E11, 13 and 15; Fig. 6d). In addition, to conclusively determine that p75NTR is expressed in the membranes of SNCA⁺ cells, we utilized primary dissociated cultures of cerebellum at E10, DIV 4 (Fig. 6E-H). IHC demonstrated that p75NTR was indeed expressed in the membranes of SNCA⁺ cells (with punctate appearance, Fig. 6E–H (Dechant and Barde, 2002)).

SNCA immunopositive cells express p75NTR (NGFR) in developing cerebellum in vivo and in vitro.
**A–D:** Double immunofluorescence labeling with SNCA (A, green) and p75NTR (B, red) antibodies reveals co-labeled cells (C, merged) in the NTZ; a higher magnification of the NTZ is shown in D.
d. Western blot analysis of SNCA and p75NTR expression during cerebellar development. Immunoblots of total cerebellar lysates from embryos at E11, E13 and E15 indicate an increase in expression of SNCA and p75NTR from E11 to E15. Equal protein loading was confirmed by β-actin expression.
**E–H:** Primary dissociated cultures of cerebellum obtained from an E10 mouse embryo (DIV 4), double immunofluorescence stained for SNCA (E: green) and p75NTR (F: red) (merged image shown in G). H is a higher magnification of G; punctuate cellular p75NTR immunoreactivity is marked by arrow heads. Abbreviations: cb, cerebellum; c, caudal; d, dorsal; NTZ, nuclear transitory zone; r, rostral; v, ventral.
Scale bar = 50 µm in A–C and D–F; 20 µm in H; 10 µm in G.

Atonal BHLH Transcription Factor 1 (ATOH1) plays a crucial role in regulating the development of glutamatergic CN neurons derived from the RL at E12, prior to the formation of other rhombic lip-derived cells (granule cells and unipolar brush cells) (Ben-Arie et al., 1997, Wang et al., 2005). To determine whether OTX2 and SNCA immunopositive cells exist in the absence of rhombic lip-derived CN neurons, we used Atoh1^−/− mice (Fig. 7 A-C). Immunostaining revealed the presence of SNCA⁺ and OTX2⁺ cells at the rostral end of the cerebellar primordium at E12, which reveals this cell population has no RL origin. To validate our findings, we evaluated MEIS2, a transcription factor typically expressed in the NTZ and glutamatergic CN neurons (Willett et al., 2019), in Atoh1^+/+ and Atoh1^−/− cerebellar sections at E12. Notably, our results showed the presence of two distinct sets of MEIS2⁺ cells in the NTZ of Atoh1^+/+ embryos: 1) rhombic lip-derived CN neurons located in the caudodorsal region, which do not express SNCA (MEIS2⁺/SNCA^-), and 2) a subset of MEIS2⁺/SNCA⁺ CN neurons situated in the rostroventral region of the NTZ (Fig. 7D-I). In Atoh1^−/− sections, MEIS2⁺/SNCA⁺ cells were still present in the rostroventral region of the NTZ, whereas the subpopulation of MEIS2⁺/SNCA^- rhombic lip-derived CN neurons was absent in the caudodorsal region of the NTZ (Fig. 7 J-O).

SNCA, OTX2, and MEIS2 expression in the developing cerebella of Atoh1 null and control mice. Sagittal sections through the cerebellar primordia of Atoh1^+/+ and Atoh1^−/− embryos at E12.5; double immunofluorescence labeling with SNCA + OTX2 and SNCA + MEIS2 antibodies is demonstrated.
**A–C:** SNCA (green, A) and OTX2 (red, B) immunopositive cells are present in the mesencephalon and NTZ of Atoh1 KO mouse (merged channels, C).
**D-F:** In E12.5 Atoh1^+/+ sagittal sections, SNCA⁺ (green, D) cells are observed in the mesencephalon and NTZ. MEIS2⁺ (red, E) cells are present in the mesencephalon and NTZ in addition to another population of MEIS2⁺ cells in the dorsal region of the NTZ which extends to the rhombic lip. Merged image (F) confirms the presence of two distinct sets of MEIS2⁺ cells in the NTZ: rhombic lip-derived CN neurons located in the caudodorsal (cd) region, which do not express SNCA (MEIS2⁺/SNCA^-), and a subset of MEIS2⁺/SNCA⁺ CN neurons situated in the rostroventral (rv) region of the NTZ.
**G-I:** Higher magnification of D-F.
**J-L:** In E12.5 Atoh1^−/− sagittal sections, the expression of SNCA (green, J) shows no change as compared to Atoh1^+/+, whereas Meis2 abundance (red, K) exhibited a different pattern. Thus, MEIS2⁺/SNCA⁺ cells were still present in the rostroventral region of the NTZ. However, the subpopulation of MEIS2⁺/SNCA^- rhombic lip-derived CN neurons were absent in the caudodorsal region of the NTZ.
**M-O:** Higher magnification of **J-I**.
Abbreviations: 4thV, 4th ventricle; cb, cerebellum; cd, caudodorsal; i, isthmus; m, mesencephalon; rl, rhombic lip; NTZ, nuclear transitory zone; rv, rostroventral.
Scale bar = 100 µm

To explore if the rostroventral subset of CN neurons derived from an external cerebellar germinal zone, possibly the mesencephalon, we utilized FAST DiI as a neuronal tracer to mark cells within a potential source region. FAST DiI was applied to the dorsum of the caudal mesencephalon at E9, where it was maintained for 4 days (Fig. 8 A, a). At DIV 4, cells stained with DiI in the dorsum of the mesencephalon were present in both rostral (Fig. 8B) and caudal (Fig. 8C) directions. Sections from the cerebellar primordium revealed the presence of DiI-labeled cells within the cultured embryo (Fig. Suppl. 2). To investigate the earliest DiI-positive cell population in the mesencephalon and avoid unwanted cell staining due to long DiI exposure, we focused on early cerebellar development at E9; it has been reported that one of the premier neuronal populations in the CNS is present at this time in the mesencephalon and projects caudally (Stainier and Gilbert, 1990, Easter et al., 1993). To determine if an early generation of mesencephalic DiI-labeled cells is present within the cerebellar primordium, we limited cellular DiI exposure to only 24 hours (Fig. 8 D, d), after which it was removed (Fig. Suppl. 3). Intriguingly, almost all DiI⁺ cells migrated caudally and presented in the cerebellar primordium (Fig. 8E, e and Fig. Suppl. 3). DiI staining was clear and strong in cells as shown in Fig. 8 E, e and Fig. Suppl. 3 (arrowhead); it should be noted, however, that some DiI staining was evident in other cells in the rostral end of the cerebellar primordium, although the signal appeared relatively weak (Suppl. Fig. 3).

Labeling of mesencephalic cells during early development in mice using embryonic culture. Fast DiI was applied to an embryo at E9 and kept for 4 days (DIV 4, panels A-C) or removed after 24 hours (DIV 1, panels D-E).
**A, a:** Fast DiI was inserted in the mesencephalon at E9 (DIV 0), arrowhead shows insertion location of DiI crystal in the mesencephalon. The arrow indicates the isthmus. Inset “a” shows the whole embryo and indicates the site of DiI insertion.
**B-C:** 4 days post DiI insertion, DiI positive cells directed both rostrally to the mesencephalon (B) and caudally to the rostral cerebellar primordium (C).
**D, d:** Fast DiI was inserted in the mesencephalon at E9 (DIV 0) (indicated by arrowhead) and removed at DIV1, arrow shows the isthmus. Inset “d” shows the whole embryo and indicates the site of DiI insertion. **E, e:** DiI positive cells present in cerebellar primordium at DIV 6 after removal of Fast DiI at DIV1.
Abbreviations: cb, cerebellum; c, caudal; d, dorsal; m, mesencephalon; r, rostral; v, ventral. Scale bar = 500 µm in a, d; 200 µm in A, D; 100 µm in B-C, E.

A schematic illustration of the developing cerebellum at ~E12, created using BioRender.com. The expression patterns of SNCA, MEIS2, and OTX2 within the cerebellar primordium indicate a subset of CN neurons with origins distinct from the rhombic lip (rl).
Abbreviations: c, caudal; d, dorsal; m, mesencephalon; ntz, nuclear transitory zone; r, rostral; rl, rhombic lip; v, ventral.

Discussion

Previously, it was commonly held that all CN neurons had a singular origin in the VZ (Pierce, 1975, Miale and Sidman, 1961). However, recent discoveries have challenged this notion, revealing a dual origin for CN neurons. Some originate from the VZ, while others arise from the RL (Wang and Zoghbi, 2001b, Wang et al., 2005, Ben-Arie et al., 1997). Genetic fate mapping further suggested that glutamatergic CN projection neurons may arise from the RL (Ben-Arie et al., 1997, Machold and Fishell, 2005, Fink et al., 2006). Transcription factor expression patterns indicate that CN neurons migrate from the RL to the NTZ through a subpial stream pathway, while sequentially expressing the genes Lmx1a, Pax6, Tbr2, and Tbr1 (Fink et al., 2006).

In this study, we characterized a subset of CN neurons that do not originate from the cerebellar primordium germinal zones (RL and VZ) during early cerebellar development. We demonstrated a newly identified subset of CN neurons, which are SNCA⁺/ OTX2⁺/ MEIS2⁺/ p75NTR⁺/ LMX1A^-, in the rostroventral region of the NTZ of the cerebellar primordium. This suggests the existence of a new germinal zone during cerebellar neurogenesis.

The exact origin of the SNCA⁺/ OTX2⁺/ MEIS2⁺/ p75NTR⁺/ LMX1A^- CN neurons is currently unclear; however, they do not originate from the RL or VZ. Rhombic lip-derived TBR1⁺/LMX1A⁺ CN neurons are born at E9, but do not reach the NTZ until ~E11 (Kebschull et al., 2023, Machold and Fishell, 2005, Wang et al., 2005, Manto et al., 2012, Fink et al., 2006, Rahimi-Balaei et al., 2018). Our results revealed that SNCA⁺ cells are a group of differentiating neurons (NAA 3A10⁺) present in the NTZ at E9, before the arrival of any neurons that originate from the RL. The majority of SNCA⁺ CN neurons are not LMX1A⁺; however, a small proportion of cells seems to exhibit co-expression. This suggests that in the early stages of CN neurogenesis, the pattern of protein expression in SNCA⁺ neurons may be changing, possibly with respective down- and upregulation of Snca and Lmx1a. Conversely, this may not occur at all, and ‘co-labeling’ could have been observed due to overlapping cells. A similar display of SNCA expression has recently been demonstrated in oligodendrocyte development and maturation (Djelloul et al., 2015). Our findings indicated that CN neuron somata are highly positive for SNCA until E14, after which SNCA expression is refined to Purkinje cells at P0 (Zhong et al., 2010) and axonal projections, suggesting that SNCA⁺ cells at the rostral end of the cerebellar primordium are associated with CN establishment in the NTZ. Our results from studies using Pap^−/−; Snca^−/− mice showed that lack of SNCA during cerebellar development did not affect the formation of rostroventral subset of CN neurons (Rahimi-Balaei et al., 2019a), which still expressed OTX2 and terminated in the NTZ. While our comprehensive fate-mapping study of SNCA-expressing CN neurons is still in progress, previous research has documented SNCA expression in the medial CN neurons of adult mice. (Fujita et al., 2020). Excitatory CN neurons were previously classified into two main types. However, recent research has further subdivided these neurons into spatially distinct subpopulations within each cerebellar nucleus. (Kebschull et al., 2023, Krishnamurthy et al., 2024). Specifically, excitatory neurons in the medial CN have been divided into four subpopulations based on the expression of three marker proteins, including SNCA (Fujita et al., 2020). Notably, SNCA⁺ neurons are predominantly located ventrally in the caudal medial CN. Further studies using mice with mutations in En1 and En2, which are crucial for regulating the function of the isthmic organizer, have demonstrated a loss of a subpopulation of excitatory neurons in the medial CN (Krishnamurthy et al., 2024). This finding suggests that the early SNCA⁺ subpopulation may consist of excitatory neurons that did not originate from the RL.

Furthermore, our observations reveal the expression of MEIS2 in the NTZ (Fig. 7 and (Morales and Hatten, 2006)). The expression of MEIS2 in NTZ along with several other NTZ markers such as POU3F1, BRN2, IRX3, and MEIS1 as documented in (Kebschull et al., 2023, Wu et al., 2022), c-Ret and Tlx3 (Fig. Suppl. 4), indicating the existence of discrete subpopulations of precursors within the CN. MEIS2 (homeobox transcription regulator) is expressed in the mesencephalic alar plate of both mice (Cecconi et al., 1997) and chicks (Agoston and Schulte, 2009, Bobak et al., 2009). MEIS2 plays a crucial role in the development of cranial nerves and craniofacial structures (Machon et al., 2015). It has been suggested that mesencephalon development is regulated by Meis2 cross-talk with Otx2 (Agoston and Schulte, 2009). Notably, the expression of MEIS2 in CN neurons is remarkably distinct, allowing for a clear demarcation of the caudodorsal (SNCA^-/MEIS2⁺) and rostroventral (SNCA⁺/MEIS2⁺) regions of the NTZ, whether originating from the RL or not (Fig. 7D-I). CN neurons derived from the RL require ATOH1 expression, as they are absent in an Atoh1-null mutant (Wang et al., 2005, Machold and Fishell, 2005, Zordan et al., 2008, Florio et al., 2012, Ben-Arie et al., 1997). In the Atoh1-null cerebellar primordium, the caudodorsal (SNCA^-/MEIS2⁺) subset of CN is absent in the NTZ, while the rostroventral (SNCA⁺/MEIS2⁺) population is still present, indicating that the Meis2⁺ rostroventral subset of the CN in the NTZ develops independently from Atoh1.

What are the potential origins of SNCA⁺/ OTX2⁺/ MEIS2⁺/ p75NTR⁺/ LMX1A^- cells in the NTZ during the early stages of cerebellar development? Our study suggests that the origin of these cells may be guided by a continuous flow of rostroventral cells toward the rostral end (mesencephalon), and caudodorsal cells toward the caudal end (RL) of the cerebellar primordium. It is well established that Otx2 is required for the development of the fore- and midbrain, while Gbx2 is necessary for anterior hindbrain development (Simeone et al., 1992, Alvarado-Mallart, 2005, Li and Joyner, 2001, Joyner et al., 2000). The expression of OTX2 in the rostral and GBX2 in the caudal neural tube, is considered limited to the isthmus (Alvarado-Mallart, 2005). However, a study by Martinez et al. on chick/quail chimeras determined that the rostral portion of the cerebellar primordium is located more rostrally in the so-called ‘mesencephalic’ alar plate (Martinez and Alvarado-Mallart, 1989). Recently, Isl1 positive cells in the anterior cerebellum were shown to exhibit residual OTX2 protein activity (Wizeman et al., 2019). Several other studies have shown that rostral cerebellar development is associated with factors expressed in the caudal mesencephalon, such as engrailed family En1 and −2 (Joyner et al., 1991, Hanks et al., 1995, Millen et al., 1995), and Acp2 (Bailey et al., 2013, Bailey et al., 2014), which are regulated by the multi-signaling center known as the isthmic organizer (Martinez et al., 2013). Furthermore, by employing embryonic cultures in conjunction with DiI labeling, we determined that the source of the rostroventral subset of CN neurons appears to be an external cerebellar germinal zone, possibly originating from the mesencephalon, which is in line with other studies (Nichols and Bruce, 2006, Wizeman et al., 2019). While our current study hints at the possibility of the caudal mesencephalon serving as a novel extrinsic germinal zone for the cerebellar primordium, further investigation is required. Genetic inducible fate mapping and long-term follow-up studies are essential to gain a comprehensive understanding of the origin, fate, and connectivity of, as well as the role played by the SNCA⁺/ OTX2⁺/ MEIS2⁺/ p75NTR⁺/ LMX1A^- rostroventral subset of CN neurons in the development of the cerebellum.

In conclusion, our study indicates that the SNCA⁺/ OTX2⁺/ MEIS2⁺/ p75NTR⁺/ LMX1A^- rostroventral subset of CN neurons do not originate from the well-known distinct germinative zones of the cerebellar primordium. Instead, our findings suggest the existence of a previously unidentified extrinsic germinal zone, potentially the mesencephalon.

Material and methods

Animal maintenance

All animal procedures were performed in accordance with institutional regulations and the Guide to the Care and Use of Experimental Animals from the Canadian Council for Animal Care. For this study, we used embryos from 47 CD1 timed-pregnant mice at embryonic day (E) 9 to E18 (total number of embryos was 409). Our approach to sample size was to include enough samples to reach a sufficient level, which was determined empirically (in most of the experiments, sample size was equal to 9 embryos).Timed-pregnant, prostatic acid phosphatase (PAP) mutant (Pap^−/−) (Zylka et al., 2008, Hokin and Hokin, 1959) mice were used at E12, because they do not express Snca (Pap^−/−;Snca^−/−) and are a valuable experimental tool to assess whether SNCA is required in the development of the CN neurons (Rahimi-Balaei et al., 2019b). In addition, we studied GFP-tagged Otx2 mouse embryos (from Thomas Lamonerie lab at Université Côte d’Azur), a reporter mouse line in which the Otx2 protein is fused to the fluorescence protein GFP (Otx2^Otx2-GFP/+; (Fossat et al., 2007)). The animal procedures related to GFP-tagged Otx2 mouse embryos were in accordance with Université Côte d’Azur Institutional Animal Care and Use Committee guidelines. Atoh1 knockout embryos were provided by Dr. Huda Zoghbi at the Baylor College of Medicine. The mice were bred, phenotyped, and genotyped (by the Zoghbi lab) according to the previously described protocol (Wang et al., 2005). Animal procedures involving Atoh1 knockout mice were in accordance with The Baylor college of Medicine Institutional Animal Care and Use Committee guidelines.

All timed-pregnant CD1 mice were obtained from the Central Animal Care Service, University of Manitoba. Animals were housed at room temperature and relative humidity (18–20°C, 50–60%) on a light:dark cycle (12:12 h) with free access to food and water. The embryonic age was determined by referencing the morning after the detection of a vaginal plug following overnight mating, considered to be E 0.5. CD1 timed-pregnant mice were anesthetized at E9, 10, 11, 12, 13, 14, 15, or 18 (+ 0.5) (n=47) using 40% isoflurane (USP, Baxter Co. Mississauga, Ontario, Canada), after which embryos were removed and prepared for Western blotting, embryonic culture, or flow cytometry analysis (FCM) or fixed in 4% paraformaldehyde (PFA) for immunohistochemistry (IHC) or neutral buffered formalin for in situ hybridization (ISH).

Section immunohistochemistry

Cryostat sections (20 μm) of 4% paraformaldehyde (PFA) fixed samples were utilized for IHC as described in our previous studies (Bailey et al., 2014, Bailey et al., 2013). Antibody dilutions were used as follows: α-synuclein 1:500 (sc-69977, Santa Cruz), p75NTR 1:1000 (8238, Cell Signaling), LMX1A 1:500 (AB10533, EMD Millipore Corporation), OTX2 1:1000 (ab114138, Abcam), NAA 1:500 (3A10, Developmental Studies Hybridoma Bank), Meis2 1:500 (ab244267, Abcam), and GFP 1:1000 (1020, Aves Labs). Fluorescent detection was performed using antibodies as follows: Streptavidin Alexa Fluor® 488 conjugate, Alexa Fluor® 568 Goat Anti-Rabbit IgG (H+L), Alexa Fluor® 488 Chicken Anti-Mouse IgG (H+L), Alexa Fluor® 488 Chicken Anti-Rabbit IgG (H + L), and Alexa Fluor® 568 Goat Anti-Mouse IgG (H+L) (S-11223, A-11036, A21200, A21441, A11004, respectively, from Life Technologies), AlexaFluro® 568 Donkey anti-goat (A-11057, invitrogen), and AlexaFluro® 647 Donkey anti-mouse (A-31571, Invitrogen), all at 1:1000. Detection of peroxidase IHC was performed as described previously (Rahimi Balaei et al., 2016, Bailey et al., 2014, Bailey et al., 2013) using Horseradish peroxidase (HRP) conjugated goat anti-rabbit IgG and goat anti-mouse IgG (H+L) antibodies (EMD Millipore Corporation, 12-348 and AP308P, respectively), both at 1:500, and developed with 3,3’-diaminobenzidine solution (DAB, Sigma, St. Louis MO, USA).

Primary dissociated cerebellar cell culture

Primary cerebellar cultures were prepared from E10 CD1 mice, and maintained for varying ‘days in vitro’ (DIV; 1, 2, 3, 5, and 8), according to published methods (Shabanipour et al., 2019). Briefly, the entire cerebellum was removed from each embryo and immediately placed into ice cold Ca²⁺/Mg²⁺-free Hank’s balanced salt solution (HBSS) containing gentamicin (10 μg/ml) and glucose (6 mM). Next, cerebella were incubated at 34°C for 12 min in HBSS containing 0.1% trypsin. After washing, the cerebella were gently triturated with a Pasteur transfer pipette in HBSS containing DNase I (5 U/ml) and 12 mM MgSO₄ until the cell mass was no longer visible. Cells were collected by centrifugation (1,200 rpm, 4°C for 5 min) and re-suspended in seeding medium (Dulbecco’s modified Eagle’s medium and F12, 1:1) supplemented with putrescine (100 μM), sodium selenite (30 nM), L-glutamine (1.4 mM), gentamicin (5 μg/ml), and 10% heat-inactivated fetal bovine serum. Cells were seeded on poly-L-ornithine coated glass coverslips (12 mm) at a density of 5×10⁶ cells/ml, and each coverslip was placed into an individual well of a 24-well plate. After 6–8 h incubation in a CO₂ incubator (95% humidity, 37°C, 5% CO₂) to accomplish cell adherence, 500 μl of culture medium supplemented with transferrin (200 μg/ml), insulin (20 μg/ml), progesterone (40 nM), and triiodothyronine (0.5 ng/ml) was added to each culture well. After 7 days, half of the medium in each dish was replaced with fresh medium that was additionally supplemented with cytosine arabinoside (4 μM) and bovine serum albumin (100 μg/ml) (Bailey et al., 2013, Marzban and Hawkes, 2007, Marzban et al., 2003).

Embryonic cultures and DiI labeling of cells within the mesencephalon

Embryonic cultures were prepared from E9 and E10 CD1 timed-pregnant mice, and maintained for various DIV (4 and 6). Each embryo was removed from the amniotic sac and immediately placed into ice cold Ca²⁺/Mg²⁺-free HBSS containing gentamicin (10 μg/ml) and glucose (6 mM). Embryos were placed into 24-well plates in culture medium plus 10% fetal bovine serum and incubated in a CO₂ incubator (95% humidity, 37°C, 5% CO₂) (Marzban and Hawkes, 2007). During incubation, embryos were monitored every 6 h to evaluate the heartbeat (as an indicator of survival). On DIV 4 or 6, each well was fixed with 4% PFA and prepared for whole mount IHC.

For neuronal tracing and labeling, we used FAST DiI crystal (FAST DiI™ solid; DiIΔ9,12-C18(3), CBS (1,1’-Dilinoleyl-3,3,3’,3’-Tetramethylindocarbocyanine, 4-Chlorobenzenesulfonate, D7756, Fisher Scientific). Briefly, FAST DiI was inserted into the mesencephalon at E9 using a sharp-ended needle (30g). After insertion of FAST DiI, images were captured by a stereomicroscope to assess the location of DiI at DIV 0. After placing the embryos into 24-well plates in culture medium, they were monitored every 6 hours and fixed with 4% PFA on the desired day. Next, whole mount IHC with neurofilament-associated antigen (NAA 3A10) was performed to visualize neural fiber growth, followed by sectioning and imaging of the DiI positive cells in the mesencephalon and cerebellar primordium.

Fluorescent in situ hybridization (FISH)-RNAscope

All of the ISH experiments were carried out using E12 CD1 mice, in which the cerebellar primordium is well established, using RNAscope ACD HybEZ™ II Hybridization System and RNAscope^® Multiplex Fluorescent Reagent Kit v2 (Advanced Cell Diagnostics, Hayward, CA, USA). Briefly, embryos were fixed in 10% (vol/vol) neutral buffered formalin at room temperature for 24 h, dehydrated, and embedded in paraffin. Tissue sections cut at 10 μm thickness were processed for RNA in situ detection according to the manufacturer’s user manual. The sequence of the probe used in this study was Mm-Otx2-C3 (444381, ACD); and cyanine 3 (NEL744E001KT; TSA^® Plus, Perkin Elmers, Waltham, MA, USA) was used as the fluorophore.

Western blot analyses

Equal amounts of total protein were separated by SDS/PAGE in 10–15% precast gels (Bio-Rad, Hercules, CA, USA) and transferred onto PVDF-membranes. For Western blot analysis, membranes were blocked in 5% nonfat dry milk (NFDM) in TBS containing 0.02% Tween 20 (TBST) for 1hour at RT and subsequently incubated overnight at 4°C with primary antibodies [α-synuclein (sc-69977, Santa Cruz, 1:2000) or p75NTR (8238, Cell Signaling, 1:1000), all dilutions in blocking buffer]. After washing with TBST, membranes were exposed to secondary antibodies [HRP conjugated goat anti-mouse IgG (AP308P, Millipore, 1:6000) or HRP conjugated goat anti-rabbit IgG (12-348, Millipore, 1:6000)]. Bands were visualized using the enhanced chemiluminescence (ECL) protocol on scientific imaging film. All bands were normalized to β-actin expression.

Counting of OTX2 positive cells

To assess the number of OTX2-positive cells, we conducted immunohistochemistry (IHC) labeling on slides containing serial sections from embryonic days 12, 13, 14, and 15 (3 embryos were used at each time point). Under the microscope, we systematically counted OTX2-positive cells within the cerebellar primordium. This analysis encompassed a minimum of 10 sections, spread across at least 3 slides, ensuring comprehensive coverage of OTX2 expression along the mediolateral axis of the cerebellar primordium. For each slide, the counts of OTX2⁺ cells from all sections were cumulatively calculated to determine the total number of positive cells per slide. Subsequently, statistical analysis was employed to compare the results obtained at different developmental time points.

Flow cytometry analysis

After dissociation (see primary dissociated cerebellar cell culture section), cells were fixed in 4% PFA. Each group consisted of 350,000 cells and all procedures before sorting were performed at room temperature. Primary antibodies used: α-synuclein 1:500 (sc-69977, Santa Cruz), LMX1A 1:1000 (AB10533, EMD Millipore Corporation), and OTX2 1:500 (ab114138, Abcam). Fluorescent detection was performed using antibodies as follows: Alexa Fluor 488 Chicken Anti-Rabbit IgG (H / L) and Alexa Fluor 568 Goat Anti-Mouse IgG (H+L) (A21441 and A11004, respectively, from Life Technologies), both at 1:750. Cells were pelleted by centrifugation, washed, and resuspended in 200 µL staining buffer (1X PBS contains 1% FBS and 1mM EDTA). Data were acquired on a CytoFlex-LX flow cytometer (Beckman Coulter) equipped with 355, 375, 405, 488, 561, 638 and 808 Laser lines using CytExpert software, and analyzed with Flow Jo (version 10, Treestar, San Carlos, CA) at the University of Manitoba flow cytometry core facility. Cellular debris was excluded using forward light scatter/side scatter plot.

Imaging and figure preparation

For bright field microscopy, images were captured using a Zeiss Axio Imager M2 microscope and subsequently analyzed with Zeiss Microscope Software (Zen Image Analyses software; Zeiss, Toronto, ON, Canada). For fluorescence microscopy of entire cerebellar sections, a Zeiss Lumar V12 Fluorescence stereomicroscope (Zeiss, Toronto, ON, Canada) equipped with a camera was used; captured images were analyzed using Zen software. For high magnification fluorescence microscopy, a Zeiss Z1 and Z2 Imager and a Zeiss LSM 700 confocal microscope (Zeiss, Toronto, ON, Canada) equipped with camera and Zen software were used to capture and analyze images. Images were cropped, corrected for brightness and contrast, and assembled into montages using Adobe Photoshop CS5 Version 12.

Statistical analysis

Data on OTX2 positive cell counts are presented as the mean ± standard error of mean (SEM) from n separate experiments. Statistical significance of differences was evaluated by one-way ANOVA followed by post hoc Tukey’s multiple comparison test. Differences were considered statistically significant when p<0.05. All statistical analyses were performed using GraphPad Prism 10 software for Windows.

Acknowledgements

The authors would like to acknowledge Dr. Christine Zhang and Mr. Gerald Stelmack for their technical assistance, and Science Impact (Winnipeg, Canada) for (post-)editing the manuscript.

Competing interest

The authors have no conflicts of interest.

Funding

This study was supported by grants from the Natural Sciences and Engineering Research Council (HM: NSERC Discovery Grant # RGPIN-2018-06040), The Children’s Hospital Research Institute of Manitoba (HM: CHRIM Grant # 320035), Research Manitoba Tri-Council Bridge Funding Program (HM: Grant # 47955), and University Collaborative Research Program (UCRP).

Supplementary figures

OTX2 expression persists in Snca null mice. OTX2 immunoperoxidase staining in the cerebellar primordium of Pap^−/−; Snca^−/− mice at E12. Results show OTX2⁺ cells are present in the ntz and terminate in the rostral cerebellar primordium.
Abbreviations: cb, cerebellum; I, isthmus; ntz, nuclear transitory zone Scale bar = 50 µm

Fast DiI was applied to an embryo at E9 and kept for 4 days in vitro (DIV 4), revealing labeled cells within the cerebellar primordium.
**A-C:** Low and high magnifications show only a few positive cells in the rostral cerebellar primordium in the NTZ at the level of the medial cerebellar section.
**D-F:** Low and high magnifications indicate the presence of just a few positive cells in the rostral cerebellar primordium in the NTZ at the level of the lateral cerebellar section.
Abbreviations: cb, cerebellum; c, caudal; d, dorsal; m, mesencephalon; NTZ, nuclear transitory zone; r, rostral; v, ventral.
Scale bar = 100 µm in A applies to D; 50 µm in B applies to E; 20 µm in C applies to I as well.

Fast DiI was applied to the embryo at E9 and removed after 24 hours, resulting in the visualization of labeled cells within the cerebellar primordium (higher magnification in Fig. 8 E,e). A: DiI positive cells present in cerebellar primordium at DIV 6 after removal of Fast DiI at DIV1 (indicated by arrowhead), arrow points to the isthmus.
B: A higher magnification from the caudal to mesencephalon and rostral rhombencephalon shows DiI positive cells in the cerebellar primordium, arrow points to the isthmus.
Abbreviations: cb, cerebellum; c, caudal; d, dorsal; m, mesencephalon; r, rostral; v, ventral. Scale bar = 500 µm in B; 100 µm in C.

*In situ* hybridization demonstrates expression pattern of Otx2, Snca, C-Ret, and Tlx3. These images show distribution of Otx2, Snca, C-Ret and Tlx3 in the cerebellar primordium at E11.5, E13.5 and E15.5; all markers are present in the rostroventral region of the NTZ. All images show cerebellar primordia. Image credit: Allen Institute. © 2008 Allen Institute for Brain Science. Allen Developing Mouse Brain Atlas. Available online at: https://developingmouse.brain-map.org/.

References

1. Agoston Z.
2. Schulte D.
2009Meis2 competes with the Groucho co-repressor Tle4 for binding to Otx2 and specifies tectal fate without induction of a secondary midbrain-hindbrain boundary organizerDevelopment 136:3311–22
1. Alvarado-Mallart R. M.
2005The chick/quail transplantation model: discovery of the isthmic organizer centerBrain Res Brain Res Rev 49:109–13
1. Bailey K.
2. Rahimi Balaei M.
3. Mannan A.
4. Del Bigio M. R.
5. Marzban H.
2014Purkinje cell compartmentation in the cerebellum of the lysosomal Acid phosphatase 2 mutant mouse (nax - naked-ataxia mutant mouse)PLoS One 9
1. Bailey K.
2. Rahimi Balaei M.
3. Mehdizadeh M.
4. Marzban H.
2013Spatial and temporal expression of lysosomal acid phosphatase 2 (ACP2) reveals dynamic patterning of the mouse cerebellar cortexCerebellum 12:870–81
1. Ben-Arie N.
2. Bellen H. J.
3. Armstrong D. L.
4. Mccall A. E.
5. Gordadze P. R.
6. Guo Q.
7. Matzuk M. M.
8. Zoghbi H. Y.
1997Math1 is essential for genesis of cerebellar granule neuronsNature 390:169–72
1. Bernabeu R. O.
2. Longo F. M.
2010The p75 neurotrophin receptor is expressed by adult mouse dentate progenitor cells and regulates neuronal and non-neuronal cell genesisBMC neuroscience 11
1. Bobak N.
2. Agoston Z.
3. Schulte D.
2009Evidence against involvement of Bmp receptor 1b signaling in fate specification of the chick mesencephalic alar plate at HH16Neurosci Lett 461:223–8
1. Cecconi F.
2. Proetzel G.
3. Alvarez-Bolado G.
4. Jay D.
5. Gruss P.
1997Expression of Meis2, a Knotted-related murine homeobox gene, indicates a role in the differentiation of the forebrain and the somitic mesodermDev Dyn 210:184–90
1. Chizhikov V.
2. Steshina E.
3. Roberts R.
4. Ilkin Y.
5. Washburn L.
6. Millen K. J.
2006Molecular definition of an allelic series of mutations disrupting the mouse Lmx1a (dreher) geneMammalian genome 17:1025–1032
1. Chizhikov V. V.
2. Lindgren A. G.
3. Mishima Y.
4. Roberts R. W.
5. Aldinger K. A.
6. Miesegaes G. R.
7. Currle D. S.
8. Monuki E. S.
9. Millen K. J.
2010Lmx1a regulates fates and location of cells originating from the cerebellar rhombic lip and telencephalic cortical hemProceedings of the National Academy of Sciences 107:10725–10730
1. Dechant G.
2. Barde Y.-A.
2002The neurotrophin receptor p75NTR: novel functions and implications for diseases of the nervous systemNature neuroscience 5:1131–1136
1. Djelloul M.
2. Holmqvist S.
3. Boza-Serrano A.
4. Azevedo C.
5. Yeung M. S.
6. Goldwurm S.
7. Frisén J.
8. Deierborg T.
9. Roybon L.
2015Alpha-synuclein expression in the oligodendrocyte lineage: an in vitro and in vivo study using rodent and human modelsStem cell reports 5:174–184
1. Easter S. S.
2. Ross L. S.
3. Frankfurter A.
1993Initial tract formation in the mouse brainJ Neurosci 13:285–99
1. Fink A. J.
2. Englund C.
3. Daza R. A.
4. Pham D.
5. Lau C.
6. Nivison M.
7. Kowalczyk T.
8. Hevner R. F.
2006Development of the deep cerebellar nuclei: transcription factors and cell migration from the rhombic lipThe Journal of neuroscience 26:3066–3076
1. Florio M.
2. Leto K.
3. Muzio L.
4. Tinterri A.
5. Badaloni A.
6. Croci L.
7. Zordan P.
8. Barili V.
9. Albieri I.
10. Guillemot F.
11. Rossi F.
12. Consalez G. G.
2012Neurogenin 2 regulates progenitor cell-cycle progression and Purkinje cell dendritogenesis in cerebellar developmentDevelopment 139:2308–20
1. Fossat N.
2. Le Greneur C.
3. Beby F.
4. Vincent S.
5. Godement P.
6. Chatelain G.
7. Lamonerie T.
2007A new GFP-tagged line reveals unexpected Otx2 protein localization in retinal photoreceptorsBMC Dev Biol 7
1. Fujita H.
2. Kodama T.
3. Du Lac S.
2020Modular output circuits of the fastigial nucleus for diverse motor and nonmotor functions of the cerebellar vermisElife 9
1. Goldowitz D.
2. Hamre K.
1998The cells and molecules that make a cerebellumTrends in neurosciences 21:375–382
1. Green M. J.
2. Wingate R. J.
2014Developmental origins of diversity in cerebellar output nucleiNeural Dev 9
1. Hanks M.
2. Wurst W.
3. Anson-Cartwright L.
4. Auerbach A. B.
5. Joyner A. L.
1995Rescue of the En-1 mutant phenotype by replacement of En-1 with En-2Science 269:679–82
1. Hokin M. R.
2. Hokin L. E.
1959The synthesis of phosphatidic acid from diglyceride and adenosine triphosphate in extracts of brain microsomesJournal of Biological Chemistry 234:1381–1386
1. Jiang X.
2. Gwye Y.
3. Mckeown S. J.
4. Bronner-Fraser M.
5. Lutzko C.
6. Lawlor E. R.
2008Isolation and characterization of neural crest stem cells derived from in vitro– differentiated human embryonic stem cellsStem cells and development 18:1059–1071
1. Joyner A. L.
2. Herrup K.
3. Auerbach B. A.
4. Davis C. A.
5. Rossant J.
1991Subtle cerebellar phenotype in mice homozygous for a targeted deletion of the En-2 homeoboxScience 251:1239–43
1. Joyner A. L.
2. Liu A.
3. Millet S.
2000Otx2, Gbx2 and Fgf8 interact to position and maintain a mid–hindbrain organizerCurrent opinion in cell biology 12:736–741
1. Kebschull J. M.
2. Casoni F.
3. Consalez G. G.
4. Goldowitz D.
5. Hawkes R.
6. Ruigrok T. J. H.
7. Schilling K.
8. Wingate R.
9. Wu J.
10. Yeung J.
11. Uusisaari M. Y.
2023Cerebellum Lecture: the Cerebellar Nuclei-Core of the CerebellumCerebellum
1. Koziol L. F.
2. Budding D.
3. Andreasen N.
4. D’arrigo S.
5. Bulgheroni S.
6. Imamizu H.
7. Ito M.
8. Manto M.
9. Marvel C.
10. Parker K.
11. Pezzulo G.
12. Ramnani N.
13. Riva D.
14. Schmahmann J.
15. Vandervert L.
16. Yamazaki T.
2014Consensus paper: the cerebellum’s role in movement and cognitionCerebellum 13:151–77
1. Krishnamurthy A.
2. Lee A. S.
3. Bayin N. S.
4. Stephen D. N.
5. Nasef O.
6. Lao Z.
7. Joyner A. L.
2024Engrailed transcription factors direct excitatory cerebellar neuron diversity and survivalDevelopment 151
1. Kurokawa D.
2. Kiyonari H.
3. Nakayama R.
4. Kimura-Yoshida C.
5. Matsuo I.
6. Aizawa S.
2004Regulation of Otx2 expression and its functions in mouse forebrain and midbrainDevelopment 131:3319–3331
1. Li J. Y.
2. Joyner A. L.
2001Otx2 and Gbx2 are required for refinement and not induction of mid-hindbrain gene expressionDevelopment 128:4979–4991
1. Machold R.
2. Fishell G.
2005Math1 is expressed in temporally discrete pools of cerebellar rhombic-lip neural progenitorsNeuron 48:17–24
1. Machon O.
2. Masek J.
3. Machonova O.
4. Krauss S.
5. Kozmik Z.
2015Meis2 is essential for cranial and cardiac neural crest developmentBMC Dev Biol 15
1. Manto M.
2. Gruol D. L.
3. Schmahmann J. D.
4. Koibuchi N.
5. Rossi F.
2012Handbook of the cerebellum and cerebellar disordersNew York: Springer
1. Martinez S.
2. Alvarado-Mallart R. M.
1989Rostral cerebellum originates from the caudal portion of the so-called ‘mesencephalic’vesicle: a study using chick/quail chimerasEuropean Journal of Neuroscience 1:549–560
1. Martinez S.
2. Andreu A.
3. Mecklenburg N.
4. Echevarria D.
2013Cellular and molecular basis of cerebellar developmentFront Neuroanat 7
1. Marzban H.
2. Del Bigio M. R.
3. Alizadeh J.
4. Ghavami S.
5. Zachariah R. M.
6. Rastegar M.
2015Cellular commitment in the developing cerebellumFrontiers in cellular neuroscience 8
1. Marzban H.
2. Hawkes R.
2007Fibroblast growth factor promotes the development of deep cerebellar nuclear neurons in dissociated mouse cerebellar culturesBrain research 1141:25–36
1. Marzban H.
2. Khanzada U.
3. Shabir S.
4. Hawkes R.
5. Langnaese K.
6. Smalla K. H.
7. Bockers T. M.
8. Gundelfinger E. D.
9. Gordon-Weeks P. R.
10. Beesley P. W.
2003Expression of the immunoglobulin superfamily neuroplastin adhesion molecules in adult and developing mouse cerebellum and their localisation to parasagittal stripesJournal of Comparative Neurology 462:286–301
1. Marzban H.
2. Kim C.-T.
3. Doorn D.
4. Chung S.-H.
5. Hawkes R.
2008A novel transverse expression domain in the mouse cerebellum revealed by a neurofilament-associated antigenNeuroscience 153:1190–1201
1. Marzban H.
2. Rahimi-Balaei M.
3. Hawkes R.
2019Early trigeminal ganglion afferents enter the cerebellum before the Purkinje cells are born and target the nuclear transitory zoneBrain Struct Funct 224:2421–2436
1. Miale I. L.
2. Sidman R. L.
1961An autoradiographic analysis of histogenesis in the mouse cerebellumExp Neurol 4:277–96
1. Millen K. J.
2. Hui C. C.
3. Joyner A. L.
1995A role for En-2 and other murine homologues of Drosophila segment polarity genes in regulating positional information in the developing cerebellumDevelopment 121:3935–45
1. Millet S.
2. Campbell K.
3. Epstein D. J.
4. Losos K.
5. Harris E.
6. Joyner A. L.
1999A role for Gbx2 in repression of Otx2 and positioning the mid/hindbrain organizerNature 401:161–4
1. Morales D.
2. Hatten M. E.
2006Molecular markers of neuronal progenitors in the embryonic cerebellar anlageJ Neurosci 26:12226–36
1. Nichols D. H.
2. Bruce L. L.
2006Migratory routes and fates of cells transcribing the Wnt-1 gene in the murine hindbrainDevelopmental dynamics 235:285–300
1. Pierce E. T.
1975Histogenesis of the deep cerebellar nuclei in the mouse: an autoradiographic studyBrain Res 95:503–18
1. Rahimi-Balaei M.
2. Bergen H.
3. Kong J.
4. Marzban H.
2018Neuronal Migration During Development of the CerebellumFront Cell Neurosci 12
1. Rahimi-Balaei M.
2. Buchok M.
3. Vihko P.
4. Parkinson F. E.
5. Marzban H.
2019Loss of prostatic acid phosphatase and alpha-synuclein cause motor circuit degeneration without altering cerebellar patterningPLoS One 14
1. Rahimi-Balaei M.
2. Buchok M.
3. Vihko P.
4. Parkinson F. E.
5. Marzban H.
2019Loss of prostatic acid phosphatase and α-synuclein cause motor circuit degeneration without altering cerebellar patterningPloS one 14
1. Rahimi Balaei M.
2. Jiao X.
3. Ashtari N.
4. Afsharinezhad P.
5. Ghavami S.
6. Marzban H.
2016Cerebellar expression of the neurotrophin receptor p75 in naked-ataxia mutant mouseInternational journal of molecular sciences 17
1. Shabanipour S.
2. Dalvand A.
3. Jiao X.
4. Rahimi Balaei M.
5. Chung S. H.
6. Kong J.
7. del Bigio M. R.
8. Marzban H.
2019Primary Culture of Neurons Isolated from Embryonic Mouse CerebellumJ Vis Exp
1. Simeone A.
2. Acampora D.
3. Gulisano M.
4. Stornaiuolo A.
5. Boncinelli E.
1992Nested expression domains of four homeobox genes in developing rostral brainNature 358:687–90
1. Sotelo C.
2004Cellular and genetic regulation of the development of the cerebellar systemProgress in neurobiology 72:295–339
1. Stainier D.
2. Gilbert W.
1990Pioneer neurons in the mouse trigeminal sensory systemProceedings of the National Academy of Sciences 87:923–927
1. Voogd J.
2. Glickstein M.
1998The anatomy of the cerebellumTrends in cognitive sciences 2:307–313
1. Wang V. Y.
2. Rose M. F.
3. Zoghbi H. Y.
2005Math1 expression redefines the rhombic lip derivatives and reveals novel lineages within the brainstem and cerebellumNeuron 48:31–43
1. Wang V. Y.
2. Zoghbi H. Y.
2001Genetic regulation of cerebellar developmentNature Reviews Neuroscience 2
1. Wang V. Y.
2. Zoghbi H. Y.
2001Genetic regulation of cerebellar developmentNat Rev Neurosci 2:484–91
1. Willett R. T.
2. Bayin N. S.
3. Lee A. S.
4. Krishnamurthy A.
5. Wojcinski A.
6. Lao Z.
7. Stephen D.
8. Rosello-Diez A.
9. Dauber-Decker K. L.
10. Orvis G. D.
11. Wu Z.
12. Tessier-Lavigne M.
13. Joyner A. L.
2019Cerebellar nuclei excitatory neurons regulate developmental scaling of presynaptic Purkinje cell number and organ growthElife 8
1. Wizeman J. W.
2. Guo Q.
3. Wilion E. M.
4. Li J. Y.
2019Specification of diverse cell types during early neurogenesis of the mouse cerebellumeLife 8
1. Wu J. P. H.
2. Yeung J.
3. Rahimi-Balaei M.
4. Wu S. R.
5. Zoghbi H.
6. Goldowitz D.
2022The Transcription Factor Pou3f1 Sheds Light on the Development and Molecular Diversity of Glutamatergic Cerebellar Nuclear Neurons in the MouseFront Mol Neurosci 15
1. Wurst W.
2. Bally-Cuif L.
2001Neural plate patterning: upstream and downstream of the isthmic organizerNat Rev Neurosci 2:99–108
1. Zhong S.-C.
2. Luo X.
3. Chen X.-S.
4. Cai Q.-Y.
5. Liu J.
6. Chen X.-H.
7. Yao Z.-X.
2010Expression and subcellular location of alpha-synuclein during mouse-embryonic developmentCellular and molecular neurobiology 30:469–482
1. Zordan P.
2. Croci L.
3. Hawkes R.
4. Consalez G. G.
2008Comparative analysis of proneural gene expression in the embryonic cerebellumDev Dyn 237:1726–35
1. Zylka M. J.
2. Sowa N. A.
3. Taylor-Blake B.
4. Twomey M. A.
5. Herrala A.
6. Voikar V.
7. Vihko P.
2008Prostatic acid phosphatase is an ectonucleotidase and suppresses pain by generating adenosineNeuron 60:111–122

Article and author information

Author information

Maryam Rahimi-Balaei
Department of Human Anatomy and Cell Science, The Children’s Hospital Research Institute of Manitoba (CHRIM), Max Rady College of Medicine, Rady Faculty of Health Sciences, University of Manitoba, Winnipeg, MB, Canada, Department of Medical Genetics, Centre for Molecular Medicine and Therapeutics, BC Children’s Hospital Research Institute, University of British Columbia, Vancouver, BC, Canada
Shayan Amiri
Department of Human Anatomy and Cell Science, The Children’s Hospital Research Institute of Manitoba (CHRIM), Max Rady College of Medicine, Rady Faculty of Health Sciences, University of Manitoba, Winnipeg, MB, Canada, Department of Pharmacology and Therapeutics, Division of Neurodegenerative Disorders, St Boniface Hospital Albrechtsen Research Centre, University of Manitoba, Winnipeg, MB, Canada
Thomas Lamonerie
Université Côte d’Azur, CNRS, Inserm, iBV, France
Sih-Rong Wu
University of California San Francisco (UCSF), San Francisco, California, USA, Department of Neuroscience, Baylor College of Medicine, Houston, TX, 77030, USA, Jan and Dan Duncan Neurological Research Institute at Texas Children’s Hospital, Houston, TX, 77030, USA
Huda Y Zoghbi
Department of Neuroscience, Baylor College of Medicine, Houston, TX, 77030, USA, Jan and Dan Duncan Neurological Research Institute at Texas Children’s Hospital, Houston, TX, 77030, USA, Howard Hughes Medical Institute, Baylor College of Medicine, Houston, TX, 77030, USA
G Giacomo Consalez
Division of Neuroscience, IRCCS Ospedale san Raffaele, Italy, Università Vita-Salute San Raffaele, 20132 Milan, Italy
Daniel Goldowitz
Department of Medical Genetics, Centre for Molecular Medicine and Therapeutics, BC Children’s Hospital Research Institute, University of British Columbia, Vancouver, BC, Canada
Hassan Marzban
Department of Human Anatomy and Cell Science, The Children’s Hospital Research Institute of Manitoba (CHRIM), Max Rady College of Medicine, Rady Faculty of Health Sciences, University of Manitoba, Winnipeg, MB, Canada
ORCID iD: 0000-0001-6885-2590
- For correspondence: hassan.marzban@umanitoba.ca

Version history

Sent for peer review: December 9, 2023
Preprint posted: January 25, 2024
Reviewed Preprint version 1: April 8, 2024
Reviewed Preprint version 2: August 27, 2024
Reviewed Preprint version 3: November 12, 2024

Copyright

This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.

Metrics

views: 501
downloads: 10
citations: 0

Views, downloads and citations are aggregated across all versions of this paper published by eLife.