ABSTRACT
Sonic hedgehog (Shh) plays well characterized roles in brain and spinal cord development, but its functions in the hypothalamus have been more difficult to elucidate owing to the complex neuroanatomy of this brain area. Here, we use fate mapping and conditional deletion models in mice to define requirements for dynamic Shh activity at distinct developmental stages in the tuberal hypothalamus, a brain region with important homeostatic functions. At early time points, Shh signaling regulates dorsoventral patterning, neurogenesis and the size of the ventral midline. Fate-mapping experiments demonstrate that Shh-expressing and -responsive progenitors contribute to distinct neuronal subtypes, accounting for some of the cellular heterogeneity in tuberal hypothalamic nuclei. Conditional deletion of the hedgehog transducer smoothened (Smo), after dorsoventral patterning has been established, reveals that Shh signaling is necessary to maintain proliferation and progenitor identity during peak periods of hypothalamic neurogenesis. We also find that mosaic disruption of Smo causes a non-cell autonomous gain in Shh signaling activity in neighboring wild-type cells, suggesting a mechanism for the pathogenesis of hypothalamic hamartomas, benign tumors that form during hypothalamic development.
INTRODUCTION
The hypothalamus is an ancient brain region with important roles in the regulation of several homeostatic processes and animal behaviors. Neural circuits mapping to distinct areas of the hypothalamus control a variety of essential bodily functions, including food intake, energy expenditure, fluid balance, temperature regulation, wakefulness, daily rhythms, as well as social behaviors associated with reproduction, aggression, arousal and stress (Saper and Lowell, 2014; Zha and Xu, 2015; Hashikawa et al., 2017; Tan and Knight, 2018). Organized into small clusters of neurons, termed nuclei, the hypothalamus is unlike other regions of the central nervous system (CNS) that are typically arranged in cell layers (Shimada and Nakamura, 1973; Altman and Bayer, 1986). Further adding to this complex architecture, most hypothalamic nuclei are composed of diverse neuronal cell types with opposing or sometimes unrelated functions. The developmental mechanisms regulating neuronal heterogeneity within hypothalamic nuclei are poorly understood compared with other CNS regions (Bedont et al., 2015; Burbridge et al., 2016; Xie and Dorsky, 2017).
The hypothalamus derives from the ventral diencephalon and can be divided into four principal regions from rostral to caudal: preoptic, anterior, tuberal and mammillary. Within the tuberal hypothalamus, neurons in the arcuate nucleus (ARC), ventromedial hypothalamic nucleus (VMH), dorsomedial hypothalamic nucleus (DMH) and paraventricular nucleus (PVN) integrate sensory information from the environment to elicit autonomic, endocrine and behavioral responses that maintain vital set points in the animal or adapt to various stressors (Saper and Lowell, 2014). In addition to receiving inputs from other brain regions, the positioning of the tuberal hypothalamus offers unique exposure to peripheral cues carried through the bloodstream that are presented to neurons at the median eminence.
Recent advances have been made in our understanding of the neuronal circuitry and function of tuberal hypothalamic nuclei. This is particularly true for the VMH, an elliptical nucleus located above the ARC and below the DMH (Fig. 1L). The VMH is subdivided into ventrolateral (VMHVL), central (VMHC) and dorsomedial (VMHDM) regions, each with distinguishable gene expression profiles (Segal et al., 2005; McClellan et al., 2006; Kurrasch et al., 2007). Genetic, pharmacogenetic and optogenetic approaches have further delineated VMH neurons into functionally distinct categories. ERα-expressing neurons in the VMHVL regulate sexually dimorphic features related to energy expenditure, reproductive behavior and aggression (Lin et al., 2011; Lee et al., 2014; Correa et al., 2015). By contrast, insulin receptor (IR)-expressing neurons in the VMHC and leptin receptor (LEPR) neurons in the VMHDM affect body weight regulation in both males and females (Dhillon et al., 2006; Klöckener et al., 2011). Steroidogenic factor 1 (SF1, officially designated Nr5a1)-positive neurons in the VMHDM also influence behavioral responses to fear and anxiety (Silva et al., 2013; Kunwar et al., 2015).
Despite the progress in assigning functions to VMH neurons, we still know relatively little about how this nucleus forms and the process by which its subdivisions are established. During hypothalamic development, Nr5a1 is selectively expressed by all VMH neurons soon after they exit the cell cycle and undergo neurogenesis (Tran et al., 2003). Nr5a1 is required for the terminal differentiation of VMH neurons, as well as their coalescence into a nucleus with a distinct cytoarchitecture (Ikeda et al., 1995; Davis et al., 2004; Büdefeld et al., 2011). Consequently, mice lacking Nr5a1 in the VMH are obese, anxious and infertile (Majdic et al., 2002; Zhao et al., 2008; Kim et al., 2010). Additional cell type-specific factors acting upstream of Nr5a1 remain to be identified.
One signaling molecule that may help bridge the gap in knowledge concerning the ontogeny of VMH neurons is Sonic Hedgehog (Shh). Shh has been studied in several spatial and temporal contexts related to hypothalamic development. Shh signaling from the prechordal plate, which underlies the ventral forebrain at early stages of its development, is required for the induction of the hypothalamic territory (Chiang et al., 1996; Dale et al., 1997). Conditional deletion of Shh in the ventral diencephalon causes defects in the patterning, regionalization and formation of ventral hypothalamic nuclei (Szabó et al., 2009; Shimogori et al., 2010; Zhao et al., 2012; Carreno et al., 2017). Nevertheless, the pathogenic mechanisms underlying these Shh dependent alterations in hypothalamic development have yet to be fully elucidated. Moreover, since Shh continues to be expressed in VMH progenitors well beyond the initial patterning stage, additional roles for Shh in VMH nucleogenesis and neuronal subtype identity are likely (Alvarez-Bolado et al., 2012).
Here, we use conditional knockout mice to interrogate the functional requirements for Shh signaling at specific periods of hypothalamic development. We show that the pronounced loss of hypothalamic nuclei that manifests from early deletion of Shh at embryonic day 9 (E9.0) is caused by defects in dorsoventral patterning, neurogenesis and the expansion of ventral midline cells, indicating a novel role for Shh in restricting ventral midline development in the tuberal hypothalamus. Fate-mapping experiments reveal that Shh-expressing and Shh-responsive cell lineages are enriched in distinct domains of the VMH, contributing to the neuronal heterogeneity of this nucleus. Deletion of smoothened (Smo), an essential transducer of Shh signaling, at later stages of hypothalamic development (after E10.5), resulted in a cell-autonomous loss of VMH neuronal subtype identity. Remarkably, we also detect a non-cell-autonomous expansion and reprogramming of neighboring wild-type cells, which likely occurred in response to residual Shh ligand that was not taken up by Smo mutant cells. This gain in Shh signaling activity may explain the pathogenesis of hypothalamic hamartomas (HH), benign tumors caused, in some cases, by somatic gene mutations that block Shh responsiveness (Saitsu et al., 2016; Hildebrand et al., 2016).
RESULTS
Shh is required for development of tuberal hypothalamic nuclei
To determine how Shh signaling contributes to the formation of tuberal hypothalamic nuclei, we first evaluated the expression of cell type-specific markers in SBE2-cre; Shhloxp/− (ShhΔhyp) embryos. SBE2-cre is a transgenic mouse line that uses Shh brain enhancer 2 (SBE2) to activate cre transcription in the ventral diencephalon in a similar pattern to the endogenous expression of Shh. We have previously shown that Shh is selectively deleted in the ventral diencephalon of ShhΔhyp embryos by E9.0 (Zhao et al., 2012). Expression of cell type-specific markers of the DMH (Hmx3), VMH (Nr5a1) and ARC (pro-opiomelanocortin, POMC; tyrosine hydoxylase, TH; and somatostatin, Sst) nuclei was either absent or greatly diminished in ShhΔhyp embryos at E14.5 (Fig. 1A-K; POMC-expressing cells: control 140.8±52.9, ShhΔhyp 1.0±1.7, n=5, P=0.0004; TH-expressing cells: control 104.0±13.2, ShhΔhyp 12.3±6.6, n=4, P<0.0001; Sst-expressing cells: control 63.0±3.0, ShhΔhyp 0.3±0.6, n=3, P<0.0001). Ectopic expression of Hmx3 was also detected in the VMH, possibly owing to its derepression in the absence of Shh (Fig. 1A,B). These results are consistent with previous findings demonstrating a requirement for Shh in the development of tuberal hypothalamic nuclei (Fig. 1L-N; Szabó et al., 2009; Shimogori et al., 2010; Carreno et al., 2017).
Alterations in dorsoventral patterning, neurogenesis and ventral midline formation explain the absence of tuberal hypothalamic nuclei in ShhΔhyp embryos
Shh signaling is required to establish distinct neuronal identities at ventral positions along the length of the vertebrate neural tube through activation and repression of homeodomain and basic helix-loop-helix (bHLH) transcription factors (Ericson et al., 1997; Briscoe and Ericson, 1999; Briscoe et al., 2000; Muhr et al., 2001; Balaskas et al., 2012). However, the temporal and spatial dynamics of Shh signaling in the hypothalamus differ from those in more posterior regions of the CNS. Shh is initially broadly expressed in ventral hypothalamic progenitors and then rapidly downregulated in the ventral midline at the level of the tuberal hypothalamus (Manning et al., 2006; Trowe et al., 2013). As a result, Shh is expressed in bilateral stripes adjacent to the ventral midline, unlike in spinal cord and hindbrain regions where Shh is restricted to the floor plate (Fig. 2A; Echelard et al., 1993). Moreover, neural progenitors immediately dorsal to the bilateral stripes of Shh are responsive to Shh signaling, indicated by Gli1 expression, whereas progenitors located in the ventral midline are refractory to Shh signaling (Fig. 2B; Ohyama et al., 2008).
We evaluated key patterning genes in ShhΔhyp mutants at E10.5 to address whether alterations in their expression might explain the loss of tuberal hypothalamic nuclei at later stages. As expected, Shh and Gli1 were absent in ShhΔhyp embryos (Fig. 2A,B,H,I). The number of cells expressing Nkx2.1, a broad determinant of ventral hypothalamic progenitor identity (Kimura et al., 1996; Sussel et al., 1999), was reduced by 48% in ShhΔhyp embryos compared with control littermates (Fig. 2C,J,O; control: 540.8±56.4, n=5; ShhΔhyp: 282.0±22.0, n=6, P<0.0001). In addition, Pax6, a prethalamic marker was expanded ventrally to a position abutting the Nkx2.1 domain (Fig. 2C,J). At E10.5, Nkx2.2 is expressed in a population of Shh-responsive neuronal progenitors that occupy the gap between cells expressing Pax6 and Nkx2.1 (Fig. 2D). The number of progenitor cells expressing Nkx2.2 in the ventricular zone of ShhΔhyp embryos was dramatically reduced (Fig. 2D,K,P; control: 221.0±21.2, n=4; ShhΔhyp: 1.6±2.1, n=5, P<0.0001), which may explain the ventral expansion of Pax6 due to deficient cross-repressive interactions between these transcription factors (Ericson et al., 1997; Briscoe and Ericson, 1999; Muhr et al., 2001). These results suggest that alterations in the dorsoventral patterning of tuberal hypothalamic progenitors are responsible, at least in part, for the loss of their neuronal identities at later stages in ShhΔhyp embryos.
The bHLH transcription factor Ascl1 is required for ARC and VMH neurogenesis (McNay et al., 2006). We observed an 81% reduction in the number of Ascl1-expressing cells in the ventral hypothalamus of ShhΔhyp embryos compared with control littermates (Fig. 2E,L,Q; control: 252.7±11.7, n=3; ShhΔhyp: 47.0±18.5, n=3, P<0.0001). Therefore, the reduction of neuroendocrine neurons in the ARC and VMH nuclei of ShhΔhyp embryos may also be explained by the downregulation of Ascl1.
Another striking feature of ShhΔhyp embryos is the dysmorphic appearance of the ventral midline. Rather than the V-shaped morphology typical of wild-type embryos, the ventral midline of ShhΔhyp embryos is U-shaped with a flattened appearance (Fig. 2F,M). Ventral midline cells in the tuberal hypothalamus undergo cell-cycle arrest and express the T-box protein Tbx3 in response to Bmp signaling (Manning et al., 2006; Trowe et al., 2013). We quantified the zone of non-proliferation by counting the number of DAPI-positive nuclei in the Ki67-negative ventral midline territory and observed a significant increase in ShhΔhyp embryos (Fig. 2F,M,R; 50.5±3.7, n=4) compared with control littermates (14.67±1.5, n=3, P<0.0001). The length of the ventral midline territory marked by Tbx3 was also significantly increased in ShhΔhyp embryos (Fig. 2G,N,S; 239.1±8.2 µm, n=3) compared with control littermates (96.7±11.6 µm, n=3, P=0.0001). These results demonstrate that the loss of Shh in the tuberal hypothalamus expands the fate of non-dividing ventral midline cells at the expense of proliferating Nkx2.1-positive neuronal progenitors. Interestingly, Bmp4 was previously shown to be upregulated in the ventral midline of ShhΔhyp embryos (Zhao et al., 2012). Hence, our findings highlight a unique role for Shh in restricting the size of the ventral midline in the tuberal hypothalamus by opposing Bmp signaling, in stark contrast to the floor plate promoting activity of Shh in more posterior regions of the CNS (Echelard et al., 1993; Roelink et al., 1994; Roelink et al., 1995; Martí et al., 1995; Ericson et al., 1996; Chiang et al., 1996).
Descendants of Shh-expressing progenitors contribute to the VMH
Shh and Gli1 continue to be expressed beyond the stage when tuberal hypothalamic progenitors first acquire their identity and extend into the peak period of DMH, VMH and ARC neurogenesis between E12.5 and E14.5 (Fig. S1). We next sought to determine the relative contributions of Shh-expressing and Shh-responsive progenitors to distinct tuberal hypothalamic nuclei. We used a genetic fate-mapping strategy to indelibly label Shh-expressing (ShhCreER) and Shh-responsive (Gli1CreER) progenitors with an inducible GFP reporter (RosaZsGreen). Pregnant dams carrying either ShhCreER/+; RosaZsGreen/+ or Gli1CreER/+; RosaZsGreen/+ embryos were administered tamoxifen at a single time point: E10.5. The contribution of Shh- and Gli1-expressing cells to tuberal hypothalamic nuclei was evaluated by co-labeling with GFP and cell type-specific markers at E14.5.
The majority of postmitotic neurons in the VMH express Nr5a1 and Nkx2.1 at E14.5 (Fig. 3A,B; Correa et al., 2015). GFP+ cells in ShhCreER/+; RosaZsGreen/+ embryos were detected in the ventricular zone adjacent to the VMH as well as in 46% of Nr5a1-positive neurons in the mantle zone (Fig. 3A,G). This finding suggests that Shh-expressing progenitors in the ventricular zone of the tuberal hypothalamus migrate radially to populate neurons in the VMH, in agreement with a previous study (Alvarez-Bolado et al., 2012). The number of GFP and Nr5a1 double-labeled neurons was enriched in ventral (199.3±11.9, n=3) compared with dorsal (112.3±8.0, n=3, P=0.0005) regions of the VMH in ShhCreER/+; RosaZsGreen/+ embryos (Fig. 3A and Fig. S2). A similar ventral VMH bias was observed for GFP and Nkx2.1 double-labeled neurons (Fig. 3B). Nkx2.2 is expressed in a subset of postmitotic neurons in the dorsal VMH, of which 22% co-label with GFP (Fig. 3C,G). These data reveal that descendants of Shh-expressing progenitors marked with GFP at E10.5 are partitioned along the dorsoventral axis of the VMH into primarily ventral and central positions and are largely excluded from the dorsal-most region (Fig. 3J and Fig. S2).
We also assessed the contribution of Shh-expressing progenitors to other tuberal hypothalamic nuclei. The DMH is composed of GABAergic neurons that express Gad1 and a subset of neurons that express Isl1. No overlap in GFP and Gad1 or Isl1 was observed in the DMH of ShhCreER/+; RosaZsGreen/+ embryos, suggesting that Shh-expressing progenitors do not contribute to this nucleus when labeled at E10.5 (Fig. 3H-J). Some overlap between GFP and Isl1 was observed in ventrolateral neurons in the VMH, as well as a small subset of ARC neurons (Fig. 3I,N). In summary, Shh-expressing neuronal progenitors in the tuberal hypothalamus predominantly contribute to the VMH when labeled at E10.5.
Descendants of Gli1-expressing progenitors contribute to the DMH and VMH
We next examined the fate of Shh-responsive cells in Gli1CreER/+; RosaZsGreen/+ embryos administered tamoxifen at E10.5 and collected at E14.5. Given that Gli1 is expressed dorsal to Shh, we expected that GFP+ cells would be confined to the DMH. Indeed, GFP+ cells were detected in the ventricular zone immediately adjacent to the DMH, as well as in Gad1- and Isl1-expressing neurons that appeared to migrate radially into the DMH (Fig. 3K-N).
Surprisingly, we also identified a small population of Nr5a1 neurons in the VMH of Gli1CreER/+; RosaZsGreen/+ embryos that co-labeled with GFP (Fig. 3D,G; 10.6±1.4%, n=3). These GFP+ cells appeared to stream ventrally from a more-dorsal progenitor domain to occupy a dorsolateral region of the VMH (Fig. 3D-F). The number of GFP and Nr5a1 double-labeled neurons was enriched in dorsal (57.3±13.5, n=3) compared with ventral (5.0±1.7, n=3, P=0.002) regions of the VMH in Gli1CreER/+; RosaZsGreen/+ embryos (Fig. 3D and Fig. S2). GFP co-labeling was also observed in postmitotic neurons expressing Nkx2.1 and Nkx2.2 in primarily dorsal regions of the VMH (Fig. 3E-G). These data suggest that VMH neurons originate from spatially segregated pools of Shh-expressing and Shh-responsive progenitors that may contribute to the cellular heterogeneity of the VMH (Fig. 3J,M).
Shh signaling is required to maintain tuberal hypothalamic progenitors in a proliferative state
The results of our lineage-tracing and gene expression experiments demonstrated that Shh signaling is active in tuberal hypothalamic progenitors after their dorsoventral identity is established. To address whether Shh signaling is also required at later stages of DMH and VMH neurogenesis, we generated mice in which Smo, an essential regulator of Shh signaling, was conditionally deleted in Gli1-expressing cells at E10.5. This approach is expected to block Shh signaling in tuberal hypothalamic progenitors that are Shh responsive at E10.5.
Pregnant dams carrying Gli1CreER/+; Smoloxp/−; RosaZsGreen/+ (cSmo) and Gli1CreER/+; Smoloxp/+; RosaZsGreen/+ (control) embryos were administered tamoxifen at E10.5 and collected at different developmental stages. Strikingly, the number of GFP-positive cells in the tuberal hypothalamus was decreased by 43% in cSmo embryos (453.8±52.27, n=8) compared with control littermates (800.2±155.3, n=9, P=0.0003) when harvested at E14.5 (Fig. 4A-C). The reduction in GFP-positive cells was detected in both mantle and ventricular zones. A significant reduction in the number of GFP-positive cells was also observed 1 day earlier at E13.5 (Fig. 4D-F; cSmo: 418.1±45.5, n=7, versus control: 603±138.9, n=6, P=0.0066), but not at E12.5 (Fig. 4G-I; cSmo: 512.4±96.1, n=5, versus control: 578.6±96.7, n=5, P>0.05).
The failed expansion of Shh-responsive cells in cSmo embryos between E12.5 and E14.5 might be explained by increased cell death or decreased proliferation, or both. Immunostaining for activated caspase 3, an indicator of apoptosis, was minimal in cSmo and control embryos at E12.5 and E14.5, with no significant differences between genotypes (Fig. S3). On the other hand, fewer GFP-positive cells co-labeled with the proliferation marker Ki67 in the ventricular zone of cSmo embryos at E12.5 (Fig. 4J-L; 28.5±6.2%, n=3) compared with control littermates (50.1±8.7%, n=9, P=0.0249). From these results, we conclude that Shh signaling is required to maintain tuberal hypothalamic progenitors in a mitotically active state during the peak period of VMH and DMH neurogenesis.
Cell-autonomous requirement for Smo in promoting tuberal hypothalamic neuron identity
Given the contribution of Shh-responsive cells to distinct neuronal subtypes in the DMH and VMH, we next assessed whether aspects of their identity were compromised in cSmo mutants. We observed a 30% reduction in the number of Isl1-positive neurons in the DMH of cSmo (Fig. 5A-C; 477.6±130.7, n=5) compared with control littermates (678.3±44.6, n=4, P=0.0229). There was also a 30% reduction in the number of postmitotic neurons expressing Nkx2.2 in the dorsal VMH of cSmo (Fig. 5D-F; 315.2±52.1, n=9) compared with control embryos (451.6±28.2, n=9; P<0.0001). These findings suggest that the conditional loss of Shh signaling after E10.5 causes a cell-autonomous reduction in the proliferation of progenitors contributing to distinct DMH and VMH neurons.
Non-cell-autonomous defects in cSmo embryos alter VMH neuron subtype identity
Remarkably, despite the reduction of postmitotic neurons expressing Nkx2.2 in the VMH of cSmo embryos, the total number of VMH neurons expressing Nr5a1 was unchanged (Fig. 5G-I; cSmo: 598.5±100.7, n=8, versus control: 590.8±196.4, n=6, P=0.9253). Moreover, fewer Nr5a1-expressing neurons were found to co-label with Nkx2.1 in cSmo embryos, especially in ventral VMH regions (Fig. 5J-L, Fig. S4). The presence of defects in areas of the tuberal hypothalamus that are not derived from Gli1-expressing progenitors, such as VMHVL, suggests that some phenotypes in cSmo embryos may occur through non-cell-autonomous mechanisms.
To address how non-cell-autonomous defects may be occurring in cSmo embryos, we evaluated the specification of tuberal hypothalamic progenitors. At E14.5, Nkx2.1 continues to be expressed in neuronal progenitors in the ventricular zone of the tuberal hypothalamus, extending from the ventral midline to a dorsal limit that approximates the border between the VMH and DMH (Fig. 6A). The ventral limit of Nkx2.2 expression in the ventricular zone overlaps with Nkx2.1 at the level of the dorsal VMH and extends caudally into the ventricular zone of the prethalamus (Fig. 6A).
We observed a significant reduction in the number of neuronal progenitors expressing Nkx2.1 in the ventricular zone of cSmo embryos (Fig. 6A; cSmo: 131.0±80.4, n=5, versus control: 259.4±58.9, n=5, P=0.0205) and a concomitant gain in the number of neuronal progenitors expressing Nkx2.2 (Fig. 6A; cSmo: 118.2±42.9, n=9, versus control: 58.0±23.2, n=9, P=0.002). The ventral expansion of Nkx2.2-positive progenitors was puzzling given our prior finding that postmitotic VMH neurons expressing Nkx2.2 were reduced in cSmo embryos (Fig. 5D-F). To reconcile these seemingly incongruous results, we reasoned that if a cell-autonomous loss of Shh signaling explains the reduction in Nkx2.2-positive neurons in the dorsal VMH, then perhaps a non-cell autonomous gain in Shh signaling could explain the increase in Nkx2.2-positive neuronal progenitors in more ventral regions of the tuberal hypothalamus.
Given that Nkx2.2 is a direct transcriptional target of Shh signaling (Lei et al., 2006; Vokes et al., 2007), we focused our attention on other direct readouts of the Shh pathway that could be readily quantified. We observed a similar ventral expansion in the number of neuronal progenitors expressing Olig2 (cSmo: 125.8±12.9, n=5, versus control: 73.4±6.5, n=5, P<0.0001) and Ki67 (cSmo: 107.0±13.5, n=8, versus control: 81.8±16.4, n=9, P=0.0037) in cSmo embryos (Fig. 6B,C). The increased proliferation of ventral tuberal progenitors may explain why the ventricle is extended ventrally in cSmo embryos (Fig. 6A-E). Notably, the cells displaying ectopic expression of Nkx2.2, Olig2 and Ki67 were not GFP positive, suggesting that they had not undergone Smo recombination (Fig. S5). No change in the expression of Gli1 was observed between cSmo and control embryos at E14.5 or earlier stages, suggesting that the ectopic response to Shh signaling was transient and/or below the sensitivity of this marker (Fig. 6D). The most parsimonious explanation for these results is that the conditional deletion of Smo prevented the normal uptake of Shh ligand, causing a non-cell autonomous gain in Shh signaling in neighboring wild-type cells (Fig. 6E).
DISCUSSION
Shh directs dorsoventral patterning and neurogenesis in the hypothalamus
Our results confirm that the early source of Shh in the anterior diencephalon is required for the formation of diverse neuronal cell types in the tuberal hypothalamus (Szabó et al., 2009; Shimogori et al., 2010; Zhao et al., 2012). To understand the mechanism underlying the loss of these cell types in ShhΔhyp mutants, we evaluated embryos at E10.5 and observed a failure in the activation of patterning, proliferation and neurogenic programs. This result is consistent with known morphogenetic roles of Shh in establishing ventral neuronal identities through the regulation of homeodomain and bHLH transcription factors with some notable differences described below (Ericson et al., 1997; Briscoe and Ericson, 1999; Briscoe et al., 2000; Muhr et al., 2001; Balaskas et al., 2012).
At spinal cord and hindbrain levels of the CNS, the notochord is the principal source of Shh required to specify ventral neuronal progenitors, whereas the secondary source of Shh in the floor plate is needed for the formation of later-born glial and ependymal cells types (Matise et al., 1998; Yu et al., 2013). In contrast, expression of Shh in the prechordal plate is transient and only present for sufficient time to specify the hypothalamic territory, marked by Nkx2.1, but not the identity of neuronal progenitors (Szabó et al., 2009). Instead, it is the neuronal source of Shh in the hypothalamus that establishes ARC, VMH and DMH progenitor domains. Thus, whereas notochord-derived Shh activates target genes such as Nkx2.2 and Olig2 in the overlying neural tube, a similar function is fulfilled by the hypothalamic source of Shh. Given that hypothalamic neurons develop over a protracted period compared with most spinal cord neurons, it makes sense that they rely on an enduring source of Shh within the hypothalamus for their development (Davis et al., 2004; Altman and Bayer, 1986; Ishii and Bouret, 2012).
Shh restricts ventral midline development in the tuberal hypothalamus
In addition to the dorsoventral patterning and neurogenic defects in ShhΔhyp mutants, our analysis revealed an unexpected expansion of ventral midline territory. The increased number of ventral midline cells in ShhΔhyp embryos is likely a consequence of heightened Bmp signaling, as evidenced by the expanded zone of non-proliferation and Tbx3 expression, two molecular readouts of this pathway (Manning et al., 2006). Indeed, loss of Shh signaling in the anterior hypothalamus of ShhΔhyp embryos was shown to cause a rostral shift in Bmp4 expression as early as E9.5 (Zhao et al., 2012). A similar phenotype was also observed in Lrp2−/− mutant embryos, including downregulation of Shh signaling, a flattened and expanded ventral midline, and a rostral shift in Bmp4 expression (Christ et al., 2012). Lrp2 belongs to the LDL receptor gene family and binds both Shh (as a co-receptor) and Bmp4 (as a scavenger receptor) (McCarthy et al., 2002; Spoelgen et al., 2005; Christ et al., 2012). Therefore, disruption in the balance of Shh and Bmp signaling, loss and gain respectively, is likely responsible for the ventral midline defects in Lrp2−/− and ShhΔhyp mutants.
The additional role that we uncovered for Shh in restricting ventral midline development in the tuberal hypothalamus is intriguing given the opposite function it plays in promoting floor-plate induction in posterior regions of the CNS (Echelard et al., 1993; Roelink et al., 1995; Martí et al., 1995; Ericson et al., 1996; Chiang et al., 1996). Why might Shh have contrasting roles in the development of ventral midline cells at different axial levels of the neural tube? First, ventral midline cells in the tuberal hypothalamus, known as the median eminence, differ from floor-plate cells in the spinal cord in that the former comprises tanycytes, a specialized type of radial glia with neurogenic and gliogenic properties (Rizzoti and Lovell-Badge, 2017). In mammals, floor-plate cells of the spinal cord are considered glial like but do not give rise to neurons or glia. Tanycytes are an integral component of the hypophyseal portal system that connects the hypothalamus to the pituitary gland and they regulate a variety of homeostatic processes owing to their access to blood-borne signals (Rodríguez et al., 2005; Robins et al., 2013; Bolborea and Dale, 2013). Second, the hypothalamic ventral midline is a site of integration for multiple signaling pathways, including Shh, Bmp, Wnt and Fgf, that help to facilitate the unique organization of the hypothalamic-pituitary axis (Manning et al., 2006; Davis and Camper, 2007; Zhu et al., 2007; Potok et al., 2008; Zhao et al., 2012; Carreno et al., 2017; Fu et al., 2017). At the level of the spinal cord, Shh is the primary regulator of ventral neuronal identities, with additional signals serving to modulate Shh responsiveness (Gouti et al., 2015; Kong et al., 2015). Third, Shh-expressing cells in the hypothalamus are different from elsewhere in the neural tube in that they constitute actively dividing neuronal progenitors (Szabó et al., 2009; this study). Within the spinal cord, Shh-expressing floor-plate cells lack neurogenic properties. Given the clear differences in ventral development between the hypothalamus and spinal cord, it is not altogether surprising that Shh exhibits unique and overlapping functions at each of these CNS regions.
Later Shh signaling: delineating fates
We sought to investigate roles and requirements for the enduring source of Shh in the tuberal hypothalamus after patterning is established. Though our lineage-tracing experiments only marked progenitors at a single time point (E10.5), we identified general contributions of these lineages to several hypothalamic nuclei. Our experiments revealed biased contributions of Shh-expressing and Shh-responding lineages to compartments of the VMH and DMH. On the basis of these observations, we wondered whether integration of progenitors may serve as a potential means by which neuronal heterogeneity is achieved within tuberal hypothalamic nuclei.
Shh-expressing and Shh-responsive populations mix to give rise to the large domain of Nr5a1 neurons in the VMH, although their contributions remain spatially segregated. Initially found broadly in the VMH, Nr5a1 expression becomes restricted to the VMHDM by P0 (Cheung et al., 2013; Correa et al., 2015). Transcriptome analysis of the VMH in both neonatal and adult mice revealed enrichment of 200 genes relative to expression in neighboring nuclei (Segal et al., 2005; Kurrasch et al., 2007). Examining the patterns of these markers showed distinct spatial domains and biases, some overlapping with Nr5a1 and some mutually exclusive. Thus, it is clear that VMH neurons are diverse in nature. Molecular characterization of VMH neuronal subclasses has largely been performed in postnatal animals. Specifically, Islet1 and ERα are restricted to the VMHVL (Davis et al., 2004), BDNF to the VMHDM and VMHC (McClellan et al., 2006), and the leptin receptor to the VMHDM (Balthasar et al., 2004; Dhillon et al., 2006). However, little is known about the processes through which these diverse populations are specified. Thus, within the VMH, the ventral bias of cells derived from Shh-expressing progenitors and the dorsal bias of Gli1-expressing descendants may indicate a role for Shh signaling in delineating distinct neuronal fates within a single nucleus.
The migration of a small number of Shh-responsive progenitors into the VMH bears similarity to other hypothalamic cell types that originate from outside of their local progenitor territory. Most neuronal populations in the ARC are generated from multipotent progenitors that migrate radially from the adjacent ventricular zone (Li et al., 1996; McNay et al., 2006; Yee et al., 2009; Pelling et al., 2011; Lu et al., 2013; Lee et al., 2016). However, some cells migrate tangentially from distal locations. For example, GnRH neurons originate in the olfactory bulb and navigate substantial distance to access their final location within the ARC (Wray et al., 1989; Wray, 2002). Moreover, gene expression studies suggest that some Sst neurons migrate to the ARC from an anterior hypothalamic birthplace (Morales-Delgado et al., 2011). We propose that the migration of a Shh-responsive cell population into the VMH, albeit from a nearby location, may further explain how cellular diversity is achieved in this nucleus.
Later Shh signaling: maintaining proliferation of progenitor pools
In assessing the requirements of Shh signaling at later stages of hypothalamic development, we observed a dependency on Smo for maintaining tuberal hypothalamic progenitors in a mitotically active state during peak periods of VMH and DMH neurogenesis. Consequently, the contribution of Shh-responsive progenitors to the VMH and DMH was reduced in cSmo embryos, resulting in a 30% reduction in the number of Nkx2.2- and Isl1-expressing neurons, respectively. These results are consistent with previous findings demonstrating a mitogenic role for Shh in other neurodevelopmental contexts (Rowitch et al., 1999; Wallace, 1999; Wechsler-Reya and Scott, 1999; Fuccillo et al., 2006; Komada et al., 2008).
Non-cell-autonomous phenotypes in cSmo mutants due to ectopic Shh signaling
The cSmo mutants used in our study show a cell-autonomous loss of Shh signaling. In addition to its role as Shh receptor, Ptch1 also functions to sequester Shh in a feedback mechanism that limits the spread of Shh ligand in a field of receptive cells (Jeong and McMahon, 2005). In Smo−/− embryos, there is less Shh uptake and a greater distribution of Shh ligand due to lower amounts of Ptch1 on the cell surface (Chamberlain et al., 2008). In our cSmo mutants, neighboring control cells that have not undergone Smo recombination gain responsiveness to residual Shh ligand and ectopically activate several targets of Shh signaling (Nkx2.2, Olig2 and Ki67) in the ventricular zone of the ventral tuberal hypothalamus. A similar non-cell-autonomous gain in Shh signaling was previously described in response to mosaic deletion of Smo in the ventral telencephalon (Xu et al., 2010).
Our observation of increased Shh signaling in non-recombined cells from cSmo mutant embryos is provocative in light of the association of somatic mutations in regulators of Shh signaling with hypothalamic hamartomas (Craig et al., 2008; Wallace et al., 2008; Hildebrand et al., 2016; Saitsu et al., 2016). Hypothalamic hamartomas are benign tumors that form during fetal brain development and, depending on their size and location, may disrupt endocrine function and cause seizures. Dominant mutations in GLI3 that produce a truncated protein with constitutive repressor activity have been identified in hypothalamic hamartomas (Craig et al., 2008; Wallace et al., 2008; Hildebrand et al., 2016; Saitsu et al., 2016). Mutations in other components of the SHH signaling pathway, OFD1 and PRKACA (which encodes the catalytic subunit α of PKA), have also been described in resected hamartoma tissue (Hildebrand et al., 2016; Saitsu et al., 2016).
The mechanism of hypothalamic hamartoma formation is unknown; however, several key features of their biology may reveal important insight into their development. First, the truncated form of GLI3 acts as a dominant repressor of Shh signaling. Second, most hamartomas are mosaic with varying amounts of mutant and wild-type cells (Saitsu et al., 2016). Third, GLI3 mutant cells cause a cell-autonomous reduction in SHH signaling that possibly manifests in reduced PTCH1 expression and increased dissemination of SHH ligand. Finally, accumulation of extracellular SHH is predicted to induce ectopic signaling in neighboring wild-type cells, resulting in a transient growth advantage.
In cases of Pallister Hall syndrome, germline-truncating mutations in GLI3 cause a reduction, but not complete blockade, of SHH signaling in all cells (Kang et al., 1997; Böse et al., 2002). Hypothalamic hamartomas may form in response to stochastic upregulation of SHH signaling within a single cell or cluster of cells. A higher concentration of SHH may be required for hamartoma formation in cases of Pallister Hall syndrome to overcome the negative influence of the truncating GLI3 mutation on pathway activation.
Hypothalamic hamartomas are also associated with SOX2 haploinsufficiency in humans (Kelberman et al., 2006). Similar hypothalamic protuberances have been described in mouse embryos with hypomorphic Sox2 mutations (Langer et al., 2012). Interestingly, these Sox2hyp mutants show a dramatic decrease in Gli3 expression in the ventral midline of the tuberal hypothalamus, and ectopic Shh transcription. As Gli3 mutant mice do not exhibit hypothalamic hamartomas, it is conceivable that the gain in Shh expression contributes to the phenotype, which is consistent with our model. Although experiments in our study did not extend into postnatal life and may not have targeted enough cells to induce hypothalamic hamartomas, they do nevertheless offer a compelling explanation for how these ectopic growths might form during brain development.
MATERIALS AND METHODS
Mice
All animal work was approved by the Institutional Animal Care and Use Committee (IACUC) at the Perelman School of Medicine, University of Pennsylvania. The SBE2-cre mouse line has been previously described (Zhao et al., 2012). Gli1CreER (Gli1tm3(cre/ERT2)Alj), Gli1lacZ (Gli1tm2Alj), RosaZsGreen (Gt(ROSA)26Sortm6(CAG-ZsGreen1)Hze), Shh+/−, Shhloxp/loxp (Shhtm2Amc), ShhCreER (Shhtm2(cre/ERT2)Cjt), Smo+/− (Smotm1Amc) and Smoloxp/loxp (Smotm2Amc) mouse strains were procured from the Jackson Laboratories. Tamoxifen dissolved in corn oil was orally gavaged at 0.15 mg/g body weight to pregnant dams at appropriate developmental time points.
Tissue dissection
Embryos were collected at the stated developmental age, with noon of plug day designated E0.5. Heads were dissected in ice-cold PBS and fixed in 4% paraformaldehyde (PFA) for 90 min to overnight at 4°C. Heads were then cryoprotected in 30% sucrose and embedded in Tissue-Tek OCT compound. Frozen tissue was cryosectioned at 16 µm (for E12.5 and E13.5 embryos), 18 µm (for E14.5 embryos) or 20 µm (for E10.5 and E18.5 embryos).
Immunohistochemistry and section in situ hybridization
Immunohistochemistry was performed with the following antibodies: mouse anti-Ascl1 (1:100 BD Pharmingen, 556604), rabbit anti-cleaved caspase 3 (1:1000, Cell Signaling, 9661), mouse anti-Gad1 (1:500, EMD Millipore, MAB5406), mouse anti-Isl1 (1:100, DSHB, 39.4D5), rabbit anti-Ki67 (1:1000, Novocastra. NCL-Ki67p), rabbit anti-Nkx2.1 (1:1000, Abcam, AB76013), mouse anti-Nkx2.2 (1:1000, DSHB, 74.5A5), rabbit anti-Olig2 (1:500, Millipore, AB9610), mouse anti-Pax6 (1:1000, DSHB, Pax6), rabbit anti-POMC (1:500, Phoenix Pharmaceuticals, H-029-30), mouse anti-Nr5a1 (1:200, R&D Systems, PP-N1665), rat anti-somatostatin (1:200, Millipore, MAB354) rabbit anti-tyrosine hydroxlase (1:1000, Pel-Freez, P40101-0). Somatostatin, Pax6, Nkx2.2, Nr5a1, Gad1 and Isl1 antibodies required antigen retrieval in 10 mM citric acid buffer (pH 6.0) at 90°C. A Mouse on Mouse detection kit (Vector Laboratories BMK-2202) was used for blocking and primary antibody dilution of Nkx2.2, Gad1 and Isl1 antibodies.
Detection of primary antibodies was achieved using secondary antibodies conjugated to Cy3 anti-rabbit (1:200, 111-165-003, Jackson ImmunoResearch Laboratories), Cy3 anti-mouse (1:200, 115-166-006, Jackson ImmunoResearch Laboratories), Cy3 anti-rat (1:200, 112-166-003, Jackson ImmunoResearch Laboratories) or AlexaFluor 633 anti-rabbit (1:100, Invitrogen, A21070). Section in situ hybridization with digoxygenin-UTP-labeled riboprobes was performed as described previously (Nissim et al., 2007). A minimum of three embryos per genotype was evaluated with each antibody or in situ probe.
β-Galactosidase staining
Heads from Gli1lacZ/+ embryos were dissected in ice-cold PBS and fixed in 4% PFA for 90 min at 4°C. Heads were then cryoprotected in 30% sucrose and embedded in Tissue-Tek OCT compound. Frozen tissue was cryosectioned at 20 µm. Slides were then stained in a solution containing 1 mg/ml X-gal at 37°C overnight. Following staining, slides were post-fixed in 4% PFA and washed in PBS.
Alignment of sections, quantification and statistical analysis
All cell counts were performed using the cell counter function in ImageJ (NIH) on hemi- or full tissue sections from at least three control and mutant embryos. To ensure that all quantifications were performed at similar axial levels, we performed Nr5a1 immunostaining to denote the rostral and caudal limits of the VMH. Fate-mapping and gene expression studies were performed at the midpoint of the VMH territory.
In cases where double labeling was examined for GFP and another cell-specific marker, the tissue was imaged in a single z-plane. Each channel (green for GFP, red for the marker) was first examined independently, assigning a positive count for a given marker to the DAPI-stained nucleus most closely associated with the staining. A cell was only counted as double labeled if a single nucleus marked by DAPI had been assigned to the cell labeled by GFP and the cell-specific marker. Statistical analysis of all cell counts was performed in GraphPad Prism using the Student's t-test.
Acknowledgements
We thank Ishmail Abdus-Saboor, Sarah Millar and Alex Rohacek for critical comments on the manuscript. We appreciate use of antibodies obtained from the Developmental Studies Hybridoma Bank, created by the NICHD of the NIH and maintained at The University of Iowa, Department of Biology, Iowa City, IA 52242.
Footnotes
Author contributions
Conceptualization: D.J.E., T.S.C., S.E.B.; Methodology: D.J.E., T.S.C.; Formal analysis: D.J.E., T.S.C.; Investigation: T.S.C., S.E.B.; Resources: D.J.E.; Writing - original draft: D.J.E., T.S.C.; Writing - review & editing: S.E.B.; Supervision: D.J.E.; Funding acquisition: D.J.E.
Funding
This work was supported by a grant from the National Institutes of Health (R01 NS039421) to D.J.E. Deposited in PMC for release after 12 months.
References
Competing interests
The authors declare no competing or financial interests.