Regionalization is a critical, highly conserved step in the development of the vertebrate brain. Discrepancies exist in how regionalization of the anterior vertebrate forebrain is conceived since the “preoptic area” is proposed to be a part of the telencephalon in tetrapods but not in teleost fish. To gain insight into this complex morphogenesis, formation of the anterior forebrain was analyzed in 3D over time in zebrafish embryos, combining visualization of proliferation and differentiation markers, with that of developmental genes. We found that the region containing the preoptic area behaves as a coherent morphogenetic entity, organized around the optic recess and located between telencephalon and hypothalamus. This optic recess region (ORR) makes clear borders with its neighbor areas and expresses a specific set of genes (dlx2a, sim1a and otpb). We thus propose that the anterior forebrain (secondary prosencephalon) in teleosts contains three morphogenetic entities (telencephalon, ORR and hypothalamus), instead of two (telencephalon and hypothalamus). The ORR in teleosts could correspond to “telencephalic stalk area” and “alar hypothalamus” in tetrapods, resolving current inconsistencies in the comparison of basal forebrain among vertebrates.
The ordered development of the vertebrate brain integrates several concomitant events: dynamic morphogenetic processes, controlled proliferation and maturation of neural progenitor cells and positional information specifying cell fate locally or at long range1,2,3,4. The spatial control of neuronal specification depends on the expression of a specific set of genes within discrete territories of the neural tube, which will become the main anatomic divisions of the brain3,5,6. This widely accepted concept of brain regionalization, by which the neural tube is patterned into distinct topological domains, has been refined over the years, notably with the introduction of neuromeric models of brain patterning7,8,9. The neuromeres are defined as transversal divisions of the neural tube. They are morphogenetic entities with a transiently recognizable morphology and they are characterized individually by different molecular identities or “genoarchitectures”10.
Neuromeres are well established in the rhombencephalon (rhombomeres), where segmentation shaped by specific genetic and cellular mechanisms is clearly observed9,11. In contrast, the situation in the prosencephalon, the most anterior of the three vesicles of the developing brain, remains more controversial, largely due to the extensive morphological changes affecting this territory during development. Fate mapping studies have suggested that the prosencephalic region of the neural plate comprises the primordia of the telencephalon, eye field, hypothalamus and diencephalon6,12,13,14,15. A significant anterior-posterior rearrangement occurs in the forebrain during the formation of the neural tube. Studies in zebrafish have shown that the hypothalamic anlage is relocated by forward subduction below the presumptive telencephalon, favoring the lateral positioning of a large part of the eye field15,16.
Despite difficulties presented by the extensive changes in morphology, neuromeres were also proposed in the prosencephalon (prosomeres) based on developmental gene expression and morphological hallmarks7,8,17. In the current prosomeric model, the forebrain is divided into the caudal diencephalon and the rostral secondary prosencephalon18, the latter containing the future telencephalon, hypothalamus and the retina. In the secondary prosencephalon, transversal segmentation has been difficult to recognize due to its complex morphology8. A main longitudinal axis through the neural tube is the boundary between alar and basal plates, which has been proposed to extend up to the most rostral end of the neural tube19. In the secondary prosencephalon, the hypothalamus is considered to be subdivided into alar and basal domains and the telencephalon to be derived from the roof plate of the anterior neural tube8,18.
These general events of regionalization are thought to be conserved among different vertebrate groups, notably at the developmental time point referred to as the “phylotypic period” during which progenitor cells acquire a positional identity. Thus the comparison of gene expression patterns at development stages among species have often been interpreted within the framework of the prosomeric model20,21,22,23. When analyzed in detail however, there exist a number of discrepancies observed among species. Most notably, while the preoptic area has been proposed to be a part of the telencephalon in tetrapods18,23,24, it is identified as a region distinct from the telencephalon and the hypothalamus in teleosts25. Although the preoptic area occupies a large part of the anterior forebrain in adult teleosts, the development of this region has not been well studied.
To verify whether there is a distinct morphogenetic entity giving rise to the preoptic area in the teleost forebrain, we examined the course of neural differentiation of this region in zebrafish embryos based on the location and shape of the brain ventricles, progenitor cell maturation and the expression of developmental genes. The analysis was performed systematically in three dimensions (3D) and at three developmental stages. We started our analysis at 48 hpf, when the initial wave of neurogenesis is achieved. To better understand the dynamics leading to this configuration, we extended our analysis backwards to earlier developmental stages: 30 hpf when brain ventricles are inflated26 and 24 hpf when brain ventricles are just opening and the initial scaffold of axon bundles is forming.
We found that the region containing the zebrafish preoptic area behaves as a morphogenetic entity, distinct from the telencephalon and the hypothalamus. As it is organized around the optic ventricular recess, we named this new morphogenetic entity the “optic recess region” (ORR). We compare our data with the current prosomeric model and discuss possible homology with tetrapods.
Anatomical descriptions are oriented with reference to the body axis and neuraxis, following Herget et al. (2014)27. We use terms “rostral” “caudal” “dorsal” “ventral” to refer the axial system co-linear to body parts. Generally the images shown in figures follow this body axis. We use terms “anterior” and “posterior” to take into account the temporal changes of the orientation of axes resulting from the curvature of the neuraxis. For instance, in 24 hpf embryos, the telencephalon is located rostrally and the hypothalamus is located caudally relative to each other, but they both exhibit an anterior topology in the prosencephalon at the stages we examined.
3D analysis of ventricular morphology in the 48 hpf zebrafish forebrain reveals the shape of the optic recess
In the developing brain, neurogenesis is organized around the ventricle in a centrifugal manner2,28. Thus, to accurately analyze the morphogenesis of brain structures, we first extracted the morphology of the ventricles of the zebrafish secondary prosencephalon. To visualize the ventricular walls and to collect data suitable for reconstructing the 3D shape of the ventricular system, we used immunodetection of ZO-1, a marker of the tight junctions labeling the apical side of neuroepithelial cells lining the ventricles29. In addition, the general organization of cells and their nuclei within the neural parenchyma was analyzed by a nuclear counterstain (DAPI). In a ventral view, the ventricle at 48 hpf takes the shape of a latin cross (Fig. 1A) with the lateral extension of the ventricles originating at the level of the optic stalk. This lateral extension of the ventricle spreads over the whole dorso-ventral thickness of the anterior neural tube (Figs. 1A–C and S1). From a lateral view, it displays an inverted S-shape bent rostrally in its dorsal extension and bent caudally in its large ventral extension, with an inflexion point located roughly half-way through its dorso-ventral expansion. The dorsal ventricular lumen is especially enlarged (asterisk in Fig. 1B), which corresponds to the anterior intraencephalic sulcus (AIS) lying between the telencephalon and the diencephalon30. In contrast, no such enlargement exists ventrally. The narrowing of the lateral ventricle ventrally is clearly highlighted in the frontal view (Fig. 1D: frontal view and Supplementary Material 1). We refer to this ventral part of the lateral ventricular extension as the optic recess.
More caudally, in the hypothalamus, two other recesses extend laterally. The rostral one, the lateral recess, is oriented roughly along the horizontal plane of the forebrain, while the posterior recess is oriented along the dorso-ventral plane (Fig. S1B,C). Thus, we systematically analyzed anatomical data with regard to the complex morphology of the ventricle through three orthogonal views simultaneously, scrolling up and down each view to encompass the whole shape of the brain.
It is worth noting that DAPI staining itself provides relevant information regarding the position of the ventricles, as the ZO-1 staining systematically coincides with a clear gap between cell nuclei (Fig. 1A and B). Moreover, the nuclei of the cells lining the ventricles are elongated and densely packed, while those of the periphery are rounded and more sparsely distributed. These morphological and cytological features can be used in subsequent analyses to deduce the position of the ventricle from cell morphology, even in the absence of ZO-1 staining.
Three distinct cell masses are juxtaposed in the zebrafish ventral secondary prosencephalon
The general distribution of cell nuclei with reference to the ventricular morphology clearly identified three distinct cellular masses, each centered on a ventricular extension (Fig. 1A, bottom panel). The rostral-most cellular mass corresponds to the telencephalic region and develops around the rostral medial ventricle (telencephalic ventricle). The caudal-most cellular mass corresponds to the hypothalamic region and develops around the caudal part of the medial ventricle and the lateral and posterior recesses (Figs. 1B and S1). The region situated between the telencephalic and hypothalamic regions is symmetrically organized around the optic recess, which is oriented perpendicularly to the medial ventricle; thus we have termed it the optic recess region (ORR).
In the developing brain, neuronal fibers form bundles and establish other important and useful anatomical landmarks that can be visualized by the expression of acetylated α-tubulin (Figs. 1C and S1E). These bundles are located at the periphery of the brain, with very few tracts in the medial region. Two of these bundles, the anterior commissure (ac) and the postoptic commissure (poc), are flanking the ORR, further highlighting the three regions described in the previous paragraph (figs. 1C and S1E). Additionally, GFAP-labeled processes of radial glia appear more densely packed at the rostral and caudal limits of the ORR domain, abutting the telencephalon and hypothalamus respectively. This higher density of glia and their processes is easily visible on ventral horizontal sections and corresponds to the location of the two commissures (Fig. S1E). Furthermore, based on the position of these commissures with regard to the brain, it can be deduced that the ORR corresponds to the region identified as the preoptic area in the mature zebrafish brain.
Centrifugal organization of proliferation and differentiation from the ventricle to the periphery in the zebrafish secondary prosencephalon
To study the dynamics of cell maturation, from proliferation to differentiation, in relation with ventricular morphology, we simultaneously analyzed a series of progressive maturation markers: cyclin A2 (ccna2) transcripts, expressed at G1/S and G2/M transitions, were used to label proliferation, elavl3/HuC transcripts to label differentiating neurons and HuC/D immunolabeling to label differentiated neurons. The translation of the HuC/D protein is delayed from the transcription of its corresponding elavl3 mRNA, enabling a convenient spatial visualization of the time course of neuronal maturation.
At 48 hpf, proliferating cells (ccna2-positive) are restricted to a narrow band bordering the ventricular wall (Fig. 1E and F). Exclusively in this ccna2-positive zone, DAPI staining shows nuclei characteristic of dividing cells, with an elongated shape, sometimes forming doublets and with dense/bright staining compared to the uniformly stained, non-dividing nuclei (Fig. S1D). Differentiating cells (elavl3-positive, HuC/D-negative) are located in a domain adjacent and lateral to proliferating cells. Differentiated cells (HuC/D-positive) are detected in the marginal zone of the neural tube, partially overlapping with the outermost elavl3-positive rows of cells. The comparison of the localization territories of these markers fits well with the general centrifugal organization of neurogenesis within the neural tube. Most interestingly, this pattern of organization is consistent in the telencephalic, ORR and hypothalamic regions. Hence, these three regions are generated from and around the telencephalic ventricle, optic recess and hypothalamic ventricle respectively, each forming a distinct morphogenetic entity.
Analysis of ventricular morphology and cell maturation at 30 hpf and 24 hpf confirms that three morphogenetic entities compose the ventral secondary prosencephalon
In order to better understand how these three regions take shape, we looked at earlier stages of development to more precisely define the relationship between cell proliferation/differentiation and morphogenesis of the anterior neural tube over time. To this aim, we used the same approach as at 48 hpf, but respectively at the end (30 hpf) and at the beginning (24 hpf) of the ventricle expansion process.
At 30 hpf, the telencephalon, ORR and hypothalamus are already clear as distinct morphological masses, however, the organization of the ventricle is more simple than at 48 hpf (Fig. 2, for a detailed visualization of ventricular morphology see Fig. S2 and Supplementary Material 1). Specifically, the enlargement of the lumen dorsal to the optic recess is much smaller and the hypothalamic recesses are not yet apparent, but the “latin cross” formed by the intersection of the medial ventricle and the optic recess is present. When compared to 48 hpf, proliferating zones labeled with ccna2 are wider (nonetheless mitotic cells are found only along the ventricular wall, Fig. S2C) and the territories labeled by elavl3 and Hu-protein are smaller (Fig. 2D and E). At the border between the ORR and the hypothalamus/diencephalon, Hu-positive differentiated cells (Fig. 2D, arrow heads) are clearly flanked by elavl3 on both sides.
At 24 hpf the hypothalamus and ORR are easily identifiable but the telencephalon is more difficult to delineate (Fig. 3A). The optic recess is already extended laterally, while the ventricle dorsal to the optic recess is even smaller than at 30 hpf (Fig. 3C frontal). This indicates that, over time, the ventral part of the optic recess tends to narrow, while the dorsal part widens suggesting that the dorsal and ventral optic recess territories undergo different morphogenetic processes.
At 24 hpf most of the cells in the brain are proliferating, as highlighted by the large ccna2-positive domains, nevertheless, dividing nuclei are still located exclusively along the ventricles (Fig. S3). Similar to at 30 hpf, Hu-expressing cells (Fig. 3D, arrow heads) are located at the borders of the three cell masses (Fig. 3D and E).
Interestingly, the first differentiated cells (HuC/D-positive cells, shown in magenta in Fig. 3D and E) appear in the telencephalon earlier than in other secondary prosencephalic domains. A second population of HuC/D-positive cells is detectable later in the ORR and only later in the hypothalamus (except for its most anterior part), implying heterochronic differentiation of progenitors within the secondary prosencephalon.
Differentiated cells define the boundaries of the three morphogenetic entities
Since neural differentiation occurs in a centrifugal manner, from the ventricular wall to the mantle, we reasoned that if the telencephalon, the ORR and the hypothalamus are distinct morphogenetic entities, differentiated cells would be located and apposed at the border of each of the regions.
At 48 hpf, the limit between each one of the three regions, the telencephalon, the ORR and the hypothalamus, is composed of at least two rows of Hu-expressing cells bordered on each side by elavl3-expressing cells (Fig. 4A–D). Thus, the caudal limit of the telencephalic differentiation domain meets the rostral edge of the ORR differentiation domain (they are orthogonally oriented), each of these domains being characterized by the presence of HuC/D-labeled cells. This is also the case at the limit where the caudal ORR differentiation domain abuts the rostral end of the hypothalamus differentiation domain.
The analysis at earlier stages further clarified how these borders are established over time. At 30 hpf, the rostral limit of the ORR with the telencephalon (Fig. 4E), as well as its caudal limit with the hypothalamus (Fig. 4F), is marked by the presence of HuC/D-positive cells sandwiched between two neurogenic domains. This is verified in all three dimensions, as seen on frontal and lateral reconstructed views (Fig. 4E and F, the three right and bottom panels). Similar characteristics were observed at 24 hpf (Fig. 4G and H), although at this stage, HuC/D-positive cells are mostly found as a single row of cells surrounded by rows of differentiating neurons.
The edge of the ORR, marked by the HuC/D-positive cells, is adjacent to the bundles of fibers immunolabeled for acetylated-tubulin, as shown in Fig. 1C. Therefore, the borders of the ORR with the telencephalon and the hypothalamus are marked in a highly congruent fashion by the morphology of the domains surrounding specific portion of the ventricle, the bundles of neuronal fibers, the presence of differentiated neurons, as well as the dense packing of radial glia processes as described in a different context31. Overall, these results confirm that the ventral secondary prosencephalon of the zebrafish brain displays three morphogenetic entities, each organized in a symmetrical and centrifugal manner around a part of the brain ventricles.
Expression patterns of developmental genes in the secondary prosencephalon
We then examined how these three morphogenetic entities correlate with the expression pattern of genes widely used as regional markers in the prosencephalon.
In all vertebrates studied so far, Shh is expressed all along the basal plate in the rhombencephalon and spinal cord. Since Shh expression extends into the forebrain, it has been proposed to also define a basal plate component in the secondary prosencephalon24,32,33. As previously described, shha is expressed within the anterodorsal hypothalamic region [7, 14, 22]. In frontal and ventral views, the expression domain of shha takes the conical shape of the rostral hypothalamus abutting the medio-caudal part of the ORR that surrounds it (Figs. 5A–C, S4A–B). As a consequence, the shape of the shha-positive hypothalamic region varies on sagittal sections according to their medio-lateral position: the shha expression domain reaches the optic recess on mid-sagittal sections (Fig. 5B, arrow head), but not on more lateral sections (Fig. 5C), where a large layer of interposed elavl3-positive and ventricular cells are positioned between the rostral end of the shha hypothalamic region and the optic recess. This expression domain does not change significantly from 24 hpf to 48 hpf (Fig. S4).
Nkx2.1 codes for a transcription factor known to be downstream of Shh signaling and it is expressed in a hypothalamic domain that partially overlaps with that of Shh21,22,34,35. In the rostral domain abutting the ORR, we found the expression of nkx2.1a is very similar to that of shha at all time points analyzed (Figs. 5D,G,H and S4).
Interestingly, the expression domain of shha and nkx2.1a is consistently excluded from that of elavl3, most notably at the border between the ORR and hypothalamus (Fig. 5A,C,D,F). Thus, shha and nkx2.1a label most of the hypothalamic region, but they do not precisely mark the boundary between the ORR and the hypothalamus, since they are not detected in the last row of differentiating cells at the periphery of the hypothalamus when analyzed at a cellular resolution.
We next analyzed the expression of Sim1, Otp and Dlx2 genes as they have been shown to be expressed within subdivisions of the so-called alar hypothalamus in several groups of vertebrates8,22 and Dlx2 is also a marker of the subpallium within the telencephalon. In zebrafish embryos at 30 and 48 hpf, we found that the dlx2a expression domain overlaps with the elavl3-expressing domains at the border of the three morphogenetic entities (Fig. 6B and F). Additionally, at 48 hpf the rostral dlx2a expression domain in the telencephalon is entirely distinct from the dlx2a domain in the ORR (Fig. 6E, arrow head indicating the gap). These data suggest that the dlx2a-positive domains are composed of differentiating cells originating from the ventricular zones of the three distinct morphogenetic entities.
Sim1a and otpb appear to be expressed in the same region around the lateral edge of the optic recess (Fig. 6A and C). Their expression patterns are very dynamic during development (Fig. S5), however, at 30 hpf and 48 hpf, sim1a expression is consistently in apposition to dlx2a expression (Fig. 6A and E). The dynamics of dlx2a expression can be determined by comparing the ventral views of 30 hpf (Fig. 6A and B) and 48 hpf (Fig. 6E and F). In the ORR, sim1a and otpb expression is located within the elavl3-expressing domain (Fig. 6) and largely coincides with the expression of the proneural gene neurogenin1 (neurog1, Fig. 6D) suggesting that they are predominantly expressed in differentiating cells. On the lateral sections presented in fig. 6, the sim1a expression domain is flanked by two dlx2a domains, whereas in the ventral and frontal sections sim1a is located at the lateral edge of the dlx2a domain. Together, the expression pattern of these developmental genes further supports the ORR being a distinct morphogenetic entity.
The 3D reconstruction of the optic recess morphology combined with that of sim1a/otpb gene expressions (Fig. 7A and B) demonstrates that their dorsal limit coincides with the dorsal limit of the optic recess, marked by the inflection point in the curvature of the ventricle (Fig. 7C, arrow head). We also found that the expression of pax6a, a well-known dorsal marker in the forebrain, is abutting the dorsal limit of the ORR (Fig. 7D). Together this data strengthens the regional identity of the ORR and sets its dorsal limit.
Foxg1 is often used as a marker to identify the telencephalon in non-mammalian species including zebrafish36,37. This is due to the prominent expression of Foxg1 in the telencephalic hemispheres in mouse38,39, however, its expression has been observed to extend to the nasal (anterior) part of the optic stalk and of the optic vesicle40,41. In line with these observations, we found that the foxg1a is expressed in the entire region rostrodorsal to the optic recess, containing the telencephalon and the rostral part of the ORR (Fig. 8). Its caudoventral limit does not coincide with that of dlx2a, a subpallial marker in the telencephalon and overlaps with sim1a/otpb, alar hypothalamus markers (Fig. 9).
Overall, these data show that, as opposed to relying on a single marker, analyzing the intersecting and overlapping expression of a combination of genetic markers allows for the most accurate definition of the regional boundaries in the secondary prosencephalon.
To be able to fully account for the highly dynamic changes taking place during regionalization of the zebrafish prosencephalon, we chose to analyze the brain morphology in relation to the ventricular organization, with cell state information and gene expression patterns. The 3D reconstruction and segmentation of the secondary prosencephalon in zebrafish revealed the unexpected complexity of the ventricular morphology, in particular that of the optic recess. The morphogenetic organization of the secondary prosencephalon is thus very difficult to interpret without 3D analysis of the data at cellular resolution. The present study revealed the existence of a morphogenetic entity surrounding the optic recess, the optic recess region (ORR), distinct from the telencephalon and the hypothalamus (Fig. 9A).
A “morphogenetic entity” can be defined as a natural unit, built from a coherent neurogenic process, with the formation of clear borders with neighboring areas. Its spatial organization directly derives from the ventricle-to-mantle orientation of the proliferation and differentiation stages of neural progenitors over time. The borders of such a morphogenetic entity are marked by 1) bundles of fibers, 2) concentration of radial glia processes and 3) apposition of differentiated neurons coming from different “morphogenetic entities”, as it is the case for the telencephalon, ORR and hypothalamus, respectively. Accordingly, such a morphogenetic entity would also express a characteristic set of genes, which underlie the neurogenic, morphogenetic and differentiation processes.
The observations we report here that the zebrafish preoptic area is a morphogenetic entity located between the telencephalon and the hypothalamus fit with classical anatomical descriptions of the adult teleost brain. This region has been identified as the “optic stalk” in zebrafish embryonic brains by Wilson et al.4,42. In agreement with our observation, these authors show that a gap exists between the telencephalon, identified by foxg1a expression (see below) and the hypothalamic boundary depicted by the conical-shape of shha expression. However, this gap domain was originally not considered to be a region in itself. According to these observations, the ORR could derive from the eye field of the neural plate. Studies performed at earlier developmental stages indeed indicate that the optic vesicles originate from the same topological position as the ORR, between the telencephalon and the hypothalamus43,44,45.
We propose that, during brain patterning, differentiated cells arising from different morphogenetic entities abut to contribute to the formation of the regional boundaries between telencephalon, ORR and hypothalamus. In this respect, the formation of these regions does not preclude the possibility that cells could migrate across the boundaries between the telencephalon, ORR and hypothalamus, but such migration occurs at later developmental stages than those we studied here. It should be stressed that the regional boundaries cannot always be delineated just based on gene expressions. We found that foxg1a is expressed in the telencephalon and the rostral ORR. Around 30 hpf, sim1a and otpb are prominently expressed in the ORR, but they are not detected in the differentiating (elavl3-positive) cells at the border of ORR with the telencephalon and with the hypothalamus. Similarly, nkx2.1a is expressed in the hypothalamic region, but not present in the differentiating cells at the border with the ORR.
Interestingly, the differentiating cells at the borders of the telencephalon/ORR and the hypothalamus/ORR both express dlx2a. At these developmental stages, dlx2a expression is found exclusively in the elavl3-positive domains. Based on the spatial orientation of cell maturation, we interpret that dlx2a-expressing cells in the telencephalon, ORR and hypothalamus represent differentiating cell populations that originate from the ventricular zones of the three distinct morphogenetic entities. Although dlx2a is often used as a regional marker, it is likely that it reflects stage of cell differentiation, in addition to positional identity.
Our combined analysis of cell differentiation markers and patterning gene expression, conducted at cellular resolution, leads to a reassessment of the interpretation of the neural genoarchitecture18 to identify homologous forebrain regions among different vertebrate classes. According to the current prosomeric model, the rostral Dlx2 expression domain is identified as the subpallium (containing the striatum and preoptic area), the Sim1/Otp-expressing domain as the supraopto-paraventricular area (SPV) and the caudal Dlx2 domain as the suprachiasmatic area (SC). Although not fully fitting with the limit of Shh expression, the alar/basal boundary is usually drawn in direct continuity from the rhombencephalon all the way to the terminal wall of the neural tube. Within this framework, the SPV and SC together have been considered as the alar hypothalamus and the Shh/Nkx2.1 domains ventral to the SC as the basal hypothalamus.
Previous work suggested that the expression patterns of developmental genes in zebrafish are comparable with those in tetrapods, when lateral views and/or sagittal sections were used8,23,24,46,47. However, our analysis reveals discrepancies in applying the current model of forebrain regionalization to depict regional boundaries in zebrafish. Firstly, the sim1a/otpb-expressing domain, flanked by dlx2a-expressing domains (used to define the SPV) is recognizable only transiently (at 48 hpf) from a lateral view (Fig. 9B). Secondly, the “preoptic area” (PO) defined in zebrafish atlases25,28 is much larger than the PO transposed from the current prosomeric model. Whereas the tetrapod PO is limited to the Dlx2/Foxg1 positive domain and considered to be a part of the telencephalon (Fig. 9C, Current view in the mouse brain), the teleost PO includes the sim1a/otpb domain (Fig. 9C, Current view in the zebrafish brain). A recent publication in zebrafish suggests that otp-expressing neuroendocrine cells in the PO are homologous to those located in the alar hypothalamic SPV in tetrapods27, instead of being telencephalic. Thirdly, there is a discordance in the telencephalic/hypothalamic boundary when it is defined based on gene expressions. The telencephalic limits depicted by dlx2a (Fig. 9B and C, arrow heads) and by foxg1a (Fig. 9B and C, arrows), the two commonly used marker genes, do not coincide. In agreement with our observation, such a difference in the ventral limit of the Dlx2 and Foxg1 expression territories, although small, has already been described in the mouse brain6,41 (Fig. 9C, mouse).
Considering the ORR as a morphogenetic entity distinct from the telencephalon or the hypothalamus would resolve such discrepancies in the definition of regional identities. Our model of anterior forebrain regionalization in comparison with the current model is shown in Fig. 9C. Our hypothesis considering a subset of the tetrapod “alar hypothalamus” as a part of the ORR is consistent with the previous study suggesting that the otp-positive neuroendocrine cells in tetrapods and teleosts are homologous27. The dlx2a-positive/otpb-negative area of the anterior ORR may be homologous to the non-evaginated “telencephalic stalk area” in amniotes48,49. Importantly, this new model of brain regionalization relies on a radially-organized morphogenesis centered by and organized around the ventricles. This radial organization would have been difficult to recognize in tetrapods due to the relative small size of the ORR compared to the enlarged telencephalon.
Careful observations of published data, nonetheless, indicate the presence of the ORR in tetrapods. An area flanked by the anterior commissure and the postoptic commissure (here identified as the ORR) is present in mouse developing brains and it has been called the “optic stalk”33. The rostral half of this region expresses Foxg133,40,41, similarly to the rostral ORR in zebrafish. The presence of the ORR in tetrapods needs to be assessed by carefully probing the morphogenesis occurring around the optic recess and lineage tracing in different groups of species.
Overall, the protocols we designed here for staining and imaging the forebrain in the zebrafish provide an unparalleled refinement in morphological and gene expression analyses at cellular resolution. A systematic application of these procedures will allow building a 3D atlas of the zebrafish forebrain at different time points during development, providing a powerful and comprehensive tool to analyze in detail morphogenesis, neurogenesis and regionalization in the zebrafish brain, in a comparative perspective.
Wild-type zebrafish (AB strain) were raised according to standards procedures50. Embryos were staged as hours post fertilization (hpf) according to specific criteria outlined by Ref. 51. All experiments were carried out in accordance with animal care guidelines provided by the French ethical committee. The experiments were approved by the local Ethical Committee (n° 59) and carried under the supervision of authorized investigators (level 1 for experiments on model animals).
Mouse anti-ZO-1 (clone ZO1-1A12, Invitrogen) was used at a dilution of 1/200 to label the ventricles29. Mouse anti-acetylated Tubulin (clone 6-11B-1, Sigma) was used at a dilution of 1/1000 to label axons52. Mouse anti-HuC/D (clone16A11, Invitrogen) was used at a dilution of 1/500 to label neurons53. Rabbit anti-GFAP (Z0334, Dako) was used at a dilution of 1/1000 to label glial processes.
Whole-mount Fluorescent in situ hybridization and immunofluorescence
Fluorescent in situ hybridization (FISH) was performed as described previously54. Embryos were fixed in fresh 4% paraformaldehyde (PFA) in PBS-tween20 0.1% (PBST) for 24 hours at 4°C, dehydrated and stored at −20°C in methanol for at least 24 hours. Embryos were then rehydrated through a descending series of ethanol solutions, permeabilized by proteinase K (10 μg/ml; P6556, Sigma) treatment followed by incubation with 20 mM glycine in PBST. Embryos were prehybridized in hybridization buffer for 4 hours at 65°C. Hybridization was then performed at 65°C for 18 hours in hybridization buffer containing the mixture of probes. Samples were washed (50% formamide/50% 2xSSC; 2xSSC; 0.2xSSC; PBST), treated for 30 minutes with H2O2 3% to inactivate endogenous peroxidases and washed again in PBST. Probes detection was carried out as follow: 1) incubation with hapten-specific antibodies conjugated to POD, 2) incubation in H2O2 0.001% with the suitable fluorophore-conjugated tyramide and 3) POD inactivation, by H2O2 2%. Fluorescein-labeled probes were recognized by an anti-fluorescein POD antibody (11207733910, Roche Diagnostics) and revealed by a fluorescein-conjugated tyramide (protocol available on Xenbase: http://www.xenbase.org/other/static/methods/FISH.jsp). For digoxigenin- labeled probes, an anti-digoxigenin-POD antibody (11207733910, Roche Diagnostics) and a TAMRA-conjugated tyramide55 were used.
Antisense RNA probes for sim1a56 and otp1b57 were generated from RT-PCR products and cloned into pCR2.1 vectors (Invitrogen). The primer paires used for PCR are the following: 5′-GCA GCG GGT ACC TGA AGA T-3 and 5′-CGG AGA GAG TCT TGT TTT GGT C-3′ for sim1a and 5′-GTA GAG TAG TTT GGG AAG CAG TTG TGA C-3′ and 5′-TTG GTT TTG CTG GCC GCC CGT CTG-′3 for otpb. Other antisense probes have been described in the following publications:ccna258, elavl358, nkx2.1a34, shha59, dlx2a60, neurog161, pax6a62 and foxg1a63.
Immunofluorescence was performed after FISH: embryos were incubated in primary antibody in DMSO 0,5%,Triton 0,1%, goat serum 4%/PBST for 24 hours at 4°C. After washes, embryos were incubated in secondary antibodies for 4 hours at RT.
After extensive washes, embryos were counterstained with dapi (5 μg/ml, Sigma) mounted in Vectashield H-1000 Mounting Medium (Vector, Eurobio/Abcys) and examined using a Zeiss LSM700 laser scanning confocal microscope equipped with a 40 × 1.3 NA oil objective. Multitracking sequential acquisitions were performed to avoid signal crossover. Stacks ranged from 100 μm to 170 μm in Z-dimension with a step of 1 μm. Linear laser or/and PMT correction was used to compensate for signal attenuation in Z. Pinhole settings chosen to 1.0 Airy unit.
Images were first visualized using Fiji64 and then processed through ITK-SNAP 2.4.065 software to perform manual and semi-automatic 3D segmentation of brain and ventricle, respectively. Reconstructed structures were then exported as binary 3D images and further processed with custom developed software to extract surfaces suitable to be embedded in a 3D pdf file. Images of ventricle underwent a median filtering and a morphological closure. All images were subsampled in order to simultaneously smooth and reduce the size of the resulting isosurfaces. Each image has been converted to a 3D pdf format through the 3Dpdf Paraview plugin (http://www.pdf3d.com/) and the final embedding in the 3D pdf file was performed via Adobe Acrobat X Pro utilities. The morphological closure facilitates the visualization of ventricles, but produces structures thicker than the corresponding ones in the raw data. We considered this compromise acceptable for our purpose of 3D interactive visualization.
Edlund, T. & Jessell, T. M. Progression from extrinsic to intrinsic signaling in cell fate specification: a view from the nervous system. Cell 96, 211–224 (1999).
Diez del Corral, R. & Storey, K. G. Markers in vertebrate neurogenesis. Nat Rev Neurosci 2, 835–839 (2001).
Vieira, C. et al. Molecular mechanisms controlling brain development: an overview of neuroepithelial secondary organizers. Int J Dev Biol 54, 7–20 (2010).
Wilson, S. W. & Houart, C. Early steps in the development of the forebrain. Dev Cell 6, 167–181 (2004).
Cavodeassi, F. & Houart, C. Brain regionalization: of signaling centers and boundaries. Dev Neurobiol 72, 218–233 (2012).
Rubenstein, J. L., Shimamura, K., Martinez, S. & Puelles, L. Regionalization of the prosencephalic neural plate. Annu Rev Neurosci 21, 445–477 (1998).
Rubenstein, J. L., Martinez, S., Shimamura, K. & Puelles, L. The embryonic vertebrate forebrain: the prosomeric model. Science 266, 578–580 (1994).
Puelles, L. & Rubenstein, J. L. Forebrain gene expression domains and the evolving prosomeric model. Trends Neurosci 26, 469–476 (2003).
Kiecker, C. & Lumsden, A. Compartments and their boundaries in vertebrate brain development. Nat Rev Neurosci 6, 553–564 (2005).
Puelles, L. & Ferran, J. L. Concept of neural genoarchitecture and its genomic fundament. Front Neuroanat 6, 47 (2012).
Keynes, R. & Lumsden, A. Segmentation and the origin of regional diversity in the vertebrate central nervous system. Neuron 4, 1–9 (1990).
Cobos, I., Shimamura, K., Rubenstein, J. L., Martinez, S. & Puelles, L. Fate map of the avian anterior forebrain at the four-somite stage, based on the analysis of quail-chick chimeras. Dev Biol 239, 46–67 (2001).
Inoue, T., Nakamura, S. & Osumi, N. Fate mapping of the mouse prosencephalic neural plate. Dev Biol 219, 373–383 (2000).
Woo, K. & Fraser, S. E. Order and coherence in the fate map of the zebrafish nervous system. Development 121, 2595–2609 (1995).
England, S. J., Blanchard, G. B., Mahadevan, L. & Adams, R. J. A dynamic fate map of the forebrain shows how vertebrate eyes form and explains two causes of cyclopia. Development 133, 4613–4617 (2006).
Varga, Z. M., Wegner, J. & Westerfield, M. Anterior movement of ventral diencephalic precursors separates the primordial eye field in the neural plate and requires cyclops. Development 126, 5533–5546 (1999).
Figdor, M. C. & Stern, C. D. Segmental organization of embryonic diencephalon. Nature 363, 630–634 (1993).
Puelles, L., Harrison, M., Paxinos, G. & Watson, C. A developmental ontology for the mammalian brain based on the prosomeric model. Trends Neurosci 36, 570–578 (2013).
Puelles, L., Martinez-de-la-Torre, M., Bardet, S. & Rubenstein, J. L. R. Hypothalamus. in The mouse Nervous System (ed. Watson C., Paxinos G. & Puelles L. ) [221–312] (Elsevier Academic Press, Waltham, 2012).
Hauptmann, G., Soll, I. & Gerster, T. The early embryonic zebrafish forebrain is subdivided into molecularly distinct transverse and longitudinal domains. Brain Res Bull 57, 371–375 (2002).
Dominguez, L., Gonzalez, A. & Moreno, N. Characterization of the hypothalamus of Xenopus laevis during development II. The basal regions. The Journal of comparative neurology (2013).
Dominguez, L., Morona, R., Gonzalez, A. & Moreno, N. Characterization of the hypothalamus of Xenopus laevis during development. I. The alar regions. The Journal of comparative neurology 521, 725–759 (2013).
Medina, L. Evolution and embryological development of forebrain. in Encyclopedic Reference of Neuroscience (ed. Binder, M. D. & BinderHirokawa, N. ) 1172–1192 (Springer-Verlag, 2008).
Moreno, N. & Gonzalez, A. The non-evaginated secondary prosencephalon of vertebrates. Front Neuroanat 5, 12 (2011).
Wullimann, M. F., Rupp, B. & Reichert, H. Neuroanatomy of the zebrafish brain: A topological atlas [1–183] (Birkhäuser Verlag, Basel, 1996).
Lowery, L. A. & Sive, H. Totally tubular: the mystery behind function and origin of the brain ventricular system. Bioessays 31, 446–458 (2009).
Herget, U., Wolf, A., Wullimann, M. F. & Ryu, S. Molecular neuroanatomy and chemoarchitecture of the neurosecretory preoptic-hypothalamic area in zebrafish larvae. The Journal of comparative neurology (2013).
Mueller, T. & Wullimann, M. F. Atlas of early zebrafish brain development: a tool for molecular neurogenetics (Elsevier, Amsterdam, 2005).
Zhang, J. et al. Establishment of a neuroepithelial barrier by Claudin5a is essential for zebrafish brain ventricular lumen expansion. Proc Natl Acad Sci U S A 107, 1425–1430 (2010).
Folgueira, M. et al. Morphogenesis underlying the development of the everted teleost telencephalon. Neural Dev 7, 32 (2012).
Barresi, M. J. et al. Essential genes for astroglial development and axon pathfinding during zebrafish embryogenesis. Dev Dyn 239, 2603–2618 (2010).
Vieira, C. & Martinez, S. Sonic hedgehog from the basal plate and the zona limitans intrathalamica exhibits differential activity on diencephalic molecular regionalization and nuclear structure. Neuroscience 143, 129–140 (2006).
Shimamura, K., Hartigan, D. J., Martinez, S., Puelles, L. & Rubenstein, J. L. Longitudinal organization of the anterior neural plate and neural tube. Development 121, 3923–3933 (1995).
Rohr, K. B., Barth, K. A., Varga, Z. M. & Wilson, S. W. The nodal pathway acts upstream of hedgehog signaling to specify ventral telencephalic identity. Neuron 29, 341–351 (2001).
van den Akker, W. M., Brox, A., Puelles, L., Durston, A. J. & Medina, L. Comparative functional analysis provides evidence for a crucial role for the homeobox gene Nkx2.1/Titf-1 in forebrain evolution. J. Comp. Neurol. 506, 211–223 (2008).
Jeong, J. Y. et al. Patterning the zebrafish diencephalon by the conserved zinc-finger protein Fezl. Development 134, 127–136 (2007).
Danesin, C. et al. Integration of telencephalic Wnt and hedgehog signaling center activities by Foxg1. Dev Cell 16, 576–587 (2009).
Tao, W. & Lai, E. Telencephalon-restricted expression of BF-1, a new member of the HNF-3/fork head gene family, in the developing rat brain. Neuron 8, 957–966 (1992).
Xuan, S. et al. Winged helix transcription factor BF-1 is essential for the development of the cerebral hemispheres. Neuron 14, 1141–1152 (1995).
Hatini, V., Tao, W. & Lai, E. Expression of winged helix genes, BF-1 and BF-2, define adjacent domains within the developing forebrain and retina. J Neurobiol 25, 1293–1309 (1994).
Marcus, R. C. et al. Domains of regulatory gene expression and the developing optic chiasm: correspondence with retinal axon paths and candidate signaling cells. J. Comp. Neurol. 403, 346–358 (1999).
Macdonald, R. et al. Regulatory gene expression boundaries demarcate sites of neuronal differentiation in the embryonic zebrafish forebrain. Neuron 13, 1039–1053 (1994).
Ivanovitch, K., Cavodeassi, F. & Wilson, S. W. Precocious acquisition of neuroepithelial character in the eye field underlies the onset of eye morphogenesis. Dev Cell 27, 293–305 (2013).
Picker, A. et al. Dynamic coupling of pattern formation and morphogenesis in the developing vertebrate retina. PLoS Biol 7, e1000214 (2009).
Lamb, T. D., Collin, S. P. & Pugh, E. N., Jr Evolution of the vertebrate eye: opsins, photoreceptors, retina and eye cup. Nature reviews 8, 960–976 (2007).
Bulfone, A. et al. Spatially restricted expression of Dlx-1, Dlx-2 (Tes-1), Gbx-2 and Wnt-3 in the embryonic day 12.5 mouse forebrain defines potential transverse and longitudinal segmental boundaries. J Neurosci 13, 3155–3172 (1993).
Bardet, S. M., Martinez-de-la-Torre, M., Northcutt, R. G., Rubenstein, J. L. & Puelles, L. Conserved pattern of OTP-positive cells in the paraventricular nucleus and other hypothalamic sites of tetrapods. Brain Res Bull 75, 231–235 (2008).
Bardet, S. M., Cobos, I., Puelles, E., Martinez-De-La-Torre, M. & Puelles, L. Chicken lateral septal organ and other circumventricular organs form in a striatal subdomain abutting the molecular striatopallidal border. J. Comp. Neurol. 499, 745–767 (2006).
Flames, N. et al. Delineation of multiple subpallial progenitor domains by the combinatorial expression of transcriptional codes. J Neurosci 27, 9682–9695 (2007).
Westerfield, M. The zebrafish book. A guide for the laboratory use of zebrafish (Danio rerio) (Univ. of Oregon Press, Eugene, 2000).
Kimmel, C. B., Ballard, W. W., Kimmel, S. R., Ullmann, B. & Schilling, T. F. Stages of embryonic development of the zebrafish. Dev Dyn 203, 253–310 (1995).
Wilson, S. W., Ross, L. S., Parrett, T. & Easter, S. S., Jr The development of a simple scaffold of axon tracts in the brain of the embryonic zebrafish, Brachydanio rerio. Development 108, 121–145 (1990).
Henion, P. D. et al. Screen for mutations affecting development of Zebrafish neural crest. Developmental genetics 18, 11–17 (1996).
Fontaine, R. et al. Dopamine inhibits reproduction in female zebrafish (Danio rerio) via three pituitary D2 receptor subtypes. Endocrinology 154, 807–818 (2013).
Lauter, G., Soll, I. & Hauptmann, G. Multicolor fluorescent in situ hybridization to define abutting and overlapping gene expression in the embryonic zebrafish brain. Neural Dev 6, 10 (2011).
Löhr, H., Ryu, S. & Driever, W. Zebrafish diencephalic A11-related dopaminergic neurons share a conserved transcriptional network with neuroendocrine cell lineages. Development 136, 1007–1017 (2009).
Ryu, S. et al. Orthopedia homeodomain protein is essential for diencephalic dopaminergic neuron development. Curr Biol 17, 873–880 (2007).
Coolen, M., Thieffry, D., Drivenes, O., Becker, T. S. & Bally-Cuif, L. miR-9 controls the timing of neurogenesis through the direct inhibition of antagonistic factors. Dev Cell 22, 1052–1064 (2012).
Takamiya, M. & Campos-Ortega, J. A. Hedgehog signalling controls zebrafish neural keel morphogenesis via its level-dependent effects on neurogenesis. Dev Dyn 235, 978–997 (2006).
Akimenko, M. A., Ekker, M., Wegner, J., Lin, W. & Westerfield, M. Combinatorial expression of three zebrafish genes related to distal-less: part of a homeobox gene code for the head. J Neurosci 14, 3475–3486 (1994).
Blader, P. et al. Conserved and acquired features of neurogenin1 regulation. Development 131, 5627–5637 (2004).
Puschel, A. W., Gruss, P. & Westerfield, M. Sequence and expression pattern of pax-6 are highly conserved between zebrafish and mice. Development 114, 643–651 (1992).
Toresson, H., Martinez-Barbera, J. P., Bardsley, A., Caubit, X. & Krauss, S. Conservation of BF-1 expression in amphioxus and zebrafish suggests evolutionary ancestry of anterior cell types that contribute to the vertebrate telencephalon. Dev Genes Evol 208, 431–439 (1998).
Schindelin, J. et al. Fiji: an open-source platform for biological-image analysis. Nat Methods 9, 676–682 (2012).
Yushkevich, P. A. et al. User-guided 3D active contour segmentation of anatomical structures: significantly improved efficiency and reliability. NeuroImage 31, 1116–1128 (2006).
Roy, A. et al. LHX2 is necessary for the maintenance of optic identity and for the progression of optic morphogenesis. J Neurosci 33, 6877–6884 (2013).
This work was supported by grants from CNRS, the University Paris-Sud, Region Ile de France (DIM Cerveau & Pensée), the Paris School of Neurosciences (ENP), the Fondation pour la Recherche Médicale (FRM) and European Community ZF-Health (FP7/2010–2015, grant agreement number 242048). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
We thank Laure Bally-Cuif, Marion Coolen, Maryline Blin and Romain Fontaine for important suggestions and help at early stage of the work, Laure Bally-Cuif, Sylvie Rétaux and Shauna Katz for helpful comments on the manuscript and Sébastien Bedu for support with fish care.
The authors declare no competing financial interests.
About this article
Cite this article
Affaticati, P., Yamamoto, K., Rizzi, B. et al. Identification of the optic recess region as a morphogenetic entity in the zebrafish forebrain. Sci Rep 5, 8738 (2015). https://doi.org/10.1038/srep08738
Cell and Tissue Research (2021)
Animal Cognition (2021)
BMC Biology (2019)
Scientific Reports (2016)