Abstract
We showed previously that the orphan nuclear receptor Tlx is required for the correct establishment of the pallio-subpallial boundary. Loss of Tlx results in a dorsal expansion of ventral markers (e.g., the homeodomain protein GSH2) into the ventralmost pallial region, i.e., the ventral pallium. We also observed a disproportionate reduction in the size of the Tlx mutant lateral ganglionic eminence (LGE) from embryonic day 14.5 onward. Here we show that this reduction is caused, at least in large part, by a proliferation defect. Interestingly, in Tlx mutants, the LGE derivatives are differentially affected. Although the development of the Tlx mutant striatum is compromised, an apparently normal number of olfactory bulb interneurons are observed. Consistent with this observation, we found that Tlx is required for the normal establishment of the ventral LGE that gives rise to striatal projection neurons. This domain is reduced by the dorsal and ventral expansion of molecular markers normally confined to progenitor domains flanking the ventral LGE. Finally, we investigated possible genetic interactions between Gsh2 and Tlx in lateral telencephalic development. Our results show that, although Gsh2 and Tlx have additive effects on striatal development, they differentially regulate the establishment of ventral pallial identity.
- GSH2
- Neurogenin2
- NR2E1
- striatum
- subpallium
- tailless
- ventral pallium
- ventral LGE
- dorsal LGE
- Dbx1
- SFRP2
- NKX6.2
- Er81
- ISL1
Introduction
The telencephalon is patterned along the dorsoventral and rostrocaudal axes by the action of secreted signaling molecules produced by local signaling centers (Rubenstein et al., 1998; Rallu et al., 2002). This leads to the establishment of discrete progenitor domains marked by the expression of individual, or combinations of, developmental control genes that seem to generate distinct neuronal subtypes (Marin and Rubenstein, 2002; Schuurmans and Guillemot, 2002). For example, the lateral (or intermediate) telencephalon can be subdivided into four progenitor domains: the lateral pallium, ventral pallium, dorsal lateral ganglionic eminence (LGE), and ventral LGE.
The LGE is known from transplantation experiments and genetic studies to generate striatal projection neurons and olfactory bulb interneurons (Deacon et al., 1994; Olsson et al., 1995, 1997, 1998; Wichterle et al., 1999, 2001). Yun et al. (2001) subdivided the LGE ventricular zone (VZ) into separate dorsal and ventral domains on the basis of the expression of the ETS transcription factor Er81 mRNA and high levels of the homeodomain-containing gene Gsh2 in the dorsal LGE. We then subdivided the LGE subventricular zone (SVZ) on the basis of the expression of Er81 in the dorsal LGE and the LIM homeodomain-containing protein Islet1 (ISL1) in the ventral LGE (Stenman et al., 2003a). In addition, we proposed and provided evidence in support of the idea that the ventral LGE generates striatal projection neurons, whereas the dorsal LGE contributes interneurons to the olfactory bulb (Stenman et al., 2003a). The ventral pallium is believed to generate the basolateral nucleus of the amygdala and other structures in the rhinencephalon (Fernandez et al., 1998; Puelles et al., 1999, 2000; Stenman et al., 2003b).
Relatively little is known about the genetic mechanisms that control the establishment and maintenance of these progenitor domains. The establishment of the pallio-subpallial boundary depends on the mutual genetic repression of Gsh2 and the paired homeodomain-containing gene Pax6 (Corbin et al., 2000; Toresson et al., 2000; Yun et al., 2001). In addition, we showed recently that the orphan nuclear receptor Tlx (also known as Tailless, NR2E1), which is broadly expressed in the telencephalon (Monaghan et al., 1995; Stenman et al., 2003b), interacts genetically with Pax6 in the establishment of this boundary (Stenman et al., 2003b). In Tlx mutants, ectopic expression of GSH2 and other ventral genes seem to be restricted to the ventral pallium and could be responsible for the suppression of the ventral pallium markers Dbx1 (Yun et al., 2001) and SFRP2 (secreted frizzled-related protein 2) (Kim et al., 2001) in this region.
To gain additional insights into the development of lateral telencephalic progenitor domains, we analyzed expression of markers of these domains in Tlx, Gsh2, and Gsh2/Tlx double mutants. We show that Tlx and Gsh2, which are known to be involved in striatal development, have additive effects on ventral LGE development. However, although the development of dorsal LGE derivatives appear unaffected in Tlx mutants, high-level Gsh2 expression is crucial for the establishment of this domain. In addition, analysis of Gsh2/Tlx double mutant reveals that Gsh2 and Tlx differentially regulate ventral pallial development.
Materials and Methods
Animals and genotyping
Tlx mice and embryos (Yu et al., 2000) were genotyped as described by Stenman et al. (2003b). Gsh2 mice and embryos (Szucsik et al., 1997) were typed by PCR using the following primers: 5Gsh2common, ATGGATGTGTTGGGTTAGACTGGGTTCTGG; 3Gsh2wt, TGCTTCACGCGACGGTTCTGAAACCATATT; and 3Gsh2neo, CAGGACATAGCGTTGGCTACCCGTGATATT. The wild-type allele results in a 317 bp band, whereas the targeted allele gives a 750 bp band. For staging of embryos, the morning of vaginal plug was designated as embryonic day 0.5 (E0.5).
Histological analysis
Embryos were fixed and sectioned on a cryostat as described previously (Toresson et al., 2000). Immunohistochemistry was performed on slidemounted sections as described by Stenman et al. (2003b). At least three embryos (8-15 sections per embryo) were analyzed with respect to all markers used in this study. Analysis of a total of >20 embryos at different embryonic stages showed no significant variation between embryos. Primary antibodies were used at the following concentrations: rabbit anti-DARPP-32 (dopamine and cAMP-regulated phosphoprotein) (1:1000; Chemicon, Temecula, CA), rabbit anti-Er81 (1:5000; provided by S. Morton and T. Jessell, Columbia University, New York, NY), rabbit anti-GSH2 (1:5000) (Toresson et al., 2000), rabbit anti-ISL1/2 (1:500; provided by T. Edlund, Umeå University, Umeå, Sweden), guinea pig anti-NKX6.2 (1:1000; provided by J. Ericson, Karolinska Institute, Stockholm, Sweden) (Vallstedt et al., 2001), rabbit anti-PAX6 (1:200; Covance, Princeton, NJ), and goat anti-PAX6 (1:250; Santa Cruz Biotechnology, Santa Cruz, CA). The secondary antibodies used were biotinylated swine anti-rabbit antibodies (Dako, Carpinteria, CA), biotinylated goat anti-guinea pig antibodies (Vector Laboratories, Burlingame, CA), and biotinylated goat anti-rat antibodies (Vector Laboratories). The ABC kit (Vector Laboratories) was used to visualize the reaction product for the biotinylated antibodies with diaminobenzidine (Sigma, St. Louis, MO) as the final chromogen.
Nonradioactive in situ hybridization was performed as described by Toresson et al. (1999) using the following probes: Dbx1 (I.M.A.G.E. clone 426959), Lhx2 (I.M.A.G.E. clone 2101448), Ngn2 (Sommer et al., 1996), SFRP2 (Kim et al., 2001), and Tbr1 (I.M.A.G.E. clone 303483). Terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling. Terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling (TUNEL) analysis was performed by first treating the sections with 0.3% H2O2 in PBS and subsequently with 0.2% Triton X-100 for 20 min. The sections were then incubated in the reaction mixture [0.2 m sodium cacaoylate, 25 mm Tris-HCl, pH 6.6, 0.25 mg/ml BSA, 1.5 mm CoCl2, 0.4 μm digoxigenin (DIG)-11-UTP, and 12.5 U of terminal deoxynucleotidyl transferase] for 1 hr at 37°C and thereafter incubated with a primary sheep anti-DIG antibody (Roche Diagnostics, Mannheim, Germany) overnight. The secondary antibody used was a biotinylated rabbit antisheep antibody (Vector Laboratories). The ABC kit (Vector Laboratories) was used to visualize the reaction product for the biotinylated antibodies with diaminobenzidine (Sigma) as the final chromogen.
Bromodeoxyuridine labeling. We injected pregnant mice intraperitoneally with bromodeoxyuridine (BrdU) (50-100 mg/kg; Sigma) and subsequently killed the animals 30 min (E12.5 injection) or 2 hr (E14.5 injection) later. Embryos were processed as described above. Frozen sections were pretreated with 4N HCl for 30 min at 65°C and incubated in normal goat serum for 30 min, after which immunohistochemistry was performed using a rat anti-BrdU antibody (diluted 1:50; Serotec, Oxford, UK).
BrdU-positive cells were counted in four square-shaped bins of equal area that were placed adjacent to each other along the ventriculo-pial axis of the ventral LGE (see Fig. 1E). The first bin stretched from the ventricular lumen to the end of the VZ in a wild-type embryo. We counted a minimum of six sections per embryo from three wild-type and three mutant embryos. We calculated the average number of BrdU-positive cells in each bin for wild-type and Tlx mutant embryos, respectively. We then performed an unpaired t test to determine whether the differences observed were statistically significant (p ≤ 0.01).
Results
Reduced size of the Tlx mutant LGE
We noted previously that the E14.5 LGE in Tlx mutants exhibits a disproportionate reduction in size compared with other developing telencephalic structures (Stenman et al., 2003b) (Fig. 1C,D). However, the E12.5 Tlx mutant LGE appears to be relatively normal in size (Fig. 1A,B). This shows that the dramatic increase in size of the LGE that normally occurs between these stages is compromised. Possible explanations for the observed phenotype are an increase in cell death, a proliferation defect, or a combination of both.
Because no increase in cell death, as detected by TUNEL analysis, is evident at E11.5, E12.5, E13.5, or E14.5 in the Tlx mutant telencephalon (data not shown; Roy et al., 2002), we wanted to determine whether a proliferation defect might be responsible for its reduced size. At E12.5, there appears to be no difference in the expression of Ki67 (Fig. 1A,B), which marks cells in all stages of the cell cycle (Schlüter et al., 1993), between wild-type and Tlx mutant LGEs. By E14.5, a reduction in the number of proliferating cells in the Tlx mutant LGE is evident (Fig. 1C,D). Similarly, whereas at E12.5 no obvious difference in the number of BrdU-positive cells was observed after a short pulse (data not shown), at E14.5 the number of cells in S-phase was, as determined by statistical analysis (see Materials and Methods), significantly decreased in the LGE (Fig. 1E,G), particularly in the SVZ (Fig. 1G). Together, these observations indicate that a proliferation defect is primarily responsible for the reduced size of the Tlx mutant LGE. In line with this, expression of GSH2 (Fig. 2A-D) and MASH1 (mammalian achaete-scute homolog 1) (data not shown) in precursor cells of the Tlx mutant VZ/SVZ shows that the mutant germinal zone appears thinner than in wild types.
The reduction in size of the Tlx mutant LGE at E14.5 suggests that the development of LGE derivatives is compromised in these mutants. A number of studies have shown that the LGE contributes GABAergic interneurons to the olfactory bulb and striatal projection neurons to the developing striatum (Olsson et al., 1997, 1998; Wichterle et al., 2001). We therefore examined the development of these neuronal subtypes in Tlx mutants.
Indeed, at E18.5, the striatum, as marked by DARPP-32 (Fig. 3A,B), which marks the patch compartment at perinatal stages (Foster et al., 1987), and calbindin (Fig. 3C,D), which marks the matrix compartment in the mature striatum (Gerfen et al., 1985), is considerably reduced in size. It should be noted that, at E18.5, Tlx mutant brains are in general smaller than wild-type brains (Monaghan et al., 1997); however, the reduction in size of the Tlx mutant striatum is clearly disproportiate compared with that of other structures, such as the septum and the cerebral cortex (Fig. 3; and data not shown).
In contrast, there appears to be no significant reduction in the number of olfactory bulb interneurons (as marked by Er81) in the Tlx mutants (Fig. 3G,H). Thus, a general reduction in size of the LGE and its progenitor domains does not constitute a satisfactory explanation of the defects observed in Tlx mutant brains. We and others have proposed recently that the LGE is subdivided into a dorsal and a ventral LGE (Yun et al., 2001; Stenman et al., 2003a). We thus wanted to determine whether these progenitor domains are differentially affected in Tlx mutants.
Molecular identity of the dorsal LGE
Consistent with the preservation of olfactory bulb neurogenesis in Tlx mutants, markers that define the dorsal LGE are still expressed in the LGE (as well as being expanded into the ventral pallium) (Stenman et al., 2003b). Indeed, these even appear to be expanded ventrally. For example, GSH2, which normally is expressed in a gradient (high dorsal, low ventral) within the LGE (Fig. 2A,C), appears to be expressed at high levels throughout much of the Tlx mutant LGE (Fig. 2B,D). Moreover, Er81 expression in the LGE SVZ is expanded ventrally (Fig. 4B) and appears to overlap with the ISL1 expression domain (Fig. 4E), unlike the case in wild-types (Fig. 4A,E). Thus, the expansion of dorsal LGE characteristics in Tlx mutants (Stenman et al., 2003b; data shown here) might be expected to give rise to more olfactory bulb interneurons, which is not the case (Fig. 3H; and data not shown). It should be stressed here, however, that the expansion of dorsal LGE markers does not necessarily imply a respecification of flanking domains (and hence an enlargement of the dorsal LGE domain) but rather most likely represents a misspecification of the progenitor domains. It is also possible that autoregulatory mechanisms exist that control the number of olfactory bulb interneurons that can be generated.
We showed previously that the Er81-positive dorsal LGE is essentially missing in the Gsh2 mutant at E18.5 (Stenman et al., 2003a). This is opposite to that observed in the Tlx mutant (Stenman et al., 2003a) (Fig. 4). Here we show that the dorsal LGE, as marked by Er81 expression in the LGE SVZ, is missing in Gsh2 mutants at E14.5 (Fig. 4C). Together with the expanded domain of high GSH2 expression in Tlx mutants, these data indicate that high levels of GSH2 may be required for the formation of a dorsal LGE. To test the requirement for Gsh2 in dorsal LGE formation, we analyzed Gsh2/Tlx double mutants. Similar to the Gsh2 mutants, these lack Er81 expression in the LGE SVZ (Fig. 4D). Er81 expression in the telencephalon of Gsh2 mutants and Gsh2/Tlx double mutants is confined to the VZ (Fig. 4C,D), which is typical of pallial Er81 expression. These findings indicate that Gsh2 is absolutely required for the correct molecular identity of the dorsal LGE.
Molecular identity of the ventral LGE
The ventral LGE has been defined by low-level expression of GSH2 in the VZ and by ISL1 expression in the SVZ/mantle zone (MZ) (Yun et al., 2001; Stenman et al., 2003a). In Tlx mutants, the expression domain of the ventral LGE marker ISL1 is drastically reduced in size by E14.5 (Fig. 4F). ISL1 is normally downregulated shortly after birth in the striatal projection neurons but maintains expression in the cholinergic interneurons into adulthood (Wang and Liu, 2001). However, in the Tlx mutants, ISL1 expression is already significantly downregulated at E18.5, unlike that in wild types (data not shown).
The ventral expansion of dorsal LGE characteristics is likely not enough to explain the truncation of the ISL1 expression domain described above. We identified a novel expression domain for the homeobox transcription factor NKX6.2 [also known as GTX (Komuro et al., 1993); antibody described by Vallstedt et al., 2001] in the embryonic telencephalon. NKX6.2 is expressed weakly in the telecephalon as early as E11 (data not shown), but, by E12.5, the expression is strong and confined to the sulcus between the LGE and medial ganglionic eminence (MGE) (Fig. 5A). It remains expressed in this region at all prenatal stages (Fig. 5C, shown at E14.5; and data not shown). This telencephalic expression pattern has been confirmed by analysis of heterozygote embryos in which the Nkx6.2 coding region has been replaced with the tau-lacZ gene [J. Ericson (Karolinska Institute, Stockholm, Sweden), personal communication; mice described by Vallstedt et al., 2001]. In E12.5 Tlx mutants, ectopic NKX6.2 expression is observed within the VZ of the ventral LGE (Fig. 5B). At E14.5, strong NKX6.2 expression marks only a small domain (Fig. 5D); however, as mentioned above, the size of the entire mutant LGE is considerably smaller at this stage than in wild-type embryos (Fig. 5C). In addition, scattered NKX6.2-expressing cells can be detected throughout most of the mutant LGE VZ (Fig. 5D, inset). No obvious change in the expression of the MGE markers NKX2.1, Lhx6, Lhx6.1, or Lhx7 is observed in the Tlx mutant telencephalon (data not shown). However, the expression of NKX6.2 is expanded into the MGE of the Tlx mutants (Fig. 5B). This shows that the NKX6.2-positive/NKX2.1-negative domain is distinct from the NKX2.1-expressing MGE in its regulation by Tlx and that MGE development is relatively unperturbed in Tlx mutants. Together, the dorsal expansion of the NKX6.2 expression domain and the ventral expansion of the Er81 expression domain show that the ventral LGE of Tlx mutants is misspecified by the ectopic expression of genes normally flanking its borders.
In addition to having a partially mispatterned LGE VZ, E12.5 Gsh2 mutants lack, or at least have a severely compromised, LGE SVZ, and, hence, generation of early-born striatal projection neurons is compromised (Corbin et al., 2000; Toresson et al., 2000; Toresson and Campbell, 2001; Yun et al., 2001). Later on, a recovery, mediated by the expansion of Gsh1, occurs and later aspects of striatal neurogenesis appear to be carried out (Corbin et al., 2000; Toresson et al., 2000; Toresson and Campbell, 2001; Yun et al., 2001). Tlx mutants, on the other hand, do not exhibit such a recovery, nor do they show ectopic Gsh1 expression in the LGE at E14.5 (data not shown). Hence, a reasonable assumption is that Gsh2/Tlx double mutants would exhibit additive defects on striatal development. Consistent with this prediction, the E18.5 Gsh2/Tlx double-mutant striatum is greatly reduced in size (Fig. 3C,F) compared with that of a wild type (Fig. 3A,D); in addition, it is also smaller than that of a Tlx mutant and Gsh2 mutant (Fig. 3B,E; and data not shown). Like in the Gsh2 (Toresson and Campbell, 2001) and Tlx mutants (Fig. 3E), calbindin appears to be expressed at higher levels in the double mutants (Fig. 3F). Although the double-mutant striatum is smaller, significant DARPP-32 expression is observed in the developing striatum (Fig. 3C). This result is opposite to that observed for DARPP-32 expression in Gsh2 mutants. Interestingly, as in Tlx mutants, the level of ISL1 expression in Gsh2/Tlx double mutants is lower (data not shown).
The worsening of the striatal phenotype in the Gsh2/Tlx double mutants suggests that the development of the ventral LGE would be even more severely affected than in either single mutant. Previous work has shown that the ventral LGE, as marked by ISL1 expression, is truncated in the Gsh2 mutant (Fig. 4G) (Toresson et al., 2000; Toresson and Campbell, 2001). This truncation has been seen primarily as a result of ectopic PAX6 expression in the dorsalmost LGE. Surprisingly however, the Gsh2 mutant LGE also exhibits ectopic expression of NKX6.2 in scattered cells located throughout most of the LGE VZ (Fig. 6H, inset). As demonstrated above, the ventral LGE is also truncated in Tlx mutants. In fact, at E14.5, the ISL1 expression domain in both Tlx (Fig. 4F) and Gsh2/Tlx mutants (Fig. 4H) is even smaller than that in Gsh2 mutants (Fig. 4G). Interestingly, the patterning defects observed in the E12.5 Gsh2/Tlx double-mutant LGE appears to reflect both the Gsh2 and Tlx phenotypes. NKX6.2 expression is ectopic in the ventral part of the LGE (Fig. 6C), as is the case in the Tlx mutants (Fig. 5B), and PAX6 is expanded into the dorsal half of the LGE (Fig. 6F), similar to that in Gsh2 mutants (Fig. 6E). Interestingly, the PAX6-positive cells that emanate from the pallio-subpallial boundary appear to be similar in number between both Gsh2/Tlx double mutants (Fig. 6F) and wild types (Fig. 6D). This is despite the fact that these cells are severely depleted in Gsh2 mutants (Fig. 6E) (Toresson et al., 2000).
At E14.5, the Gsh1-dependent recovery has begun in Gsh2 mutants (Corbin et al., 2000; Toresson et al., 2000; Toresson and Campbell, 2001; Yun et al., 2001) (Fig. 6, compare J, K). As in Gsh2 mutants (Fig. 6K), PAX6 expression in Gsh2/Tlx double mutants has retracted to the LGE-pallium angle (Fig. 6L), similar to that in wild types (Fig. 6J). In addition, Gsh1 is, as in Gsh2 mutants, ectopically expressed throughout the LGE (data not shown). In contrast to single Tlx or Gsh2 mutants, NKX6.2 expression is significantly upregulated throughout the E14.5 double-mutant LGE (Fig. 6I). The expression domain of NKX6.2 now nearly abuts that of PAX6, suggesting that most of the LGE VZ is misspecified in the double mutants. This expansion of the NKX6.2 expression domains occurs, as in Tlx mutants, without an enlargement of the NKX2.1 expression domain (data not shown).
Molecular identity of the ventral pallium
We showed previously that GSH2 is ectopically expressed in the most ventral part of the Tlx mutant pallium and that this region lacks expression of the ventral pallium markers Dbx1 and SFRP2 (Stenman et al., 2003b). Because Gsh2 is required to repress Dbx1 expression in the subpallium (Yun et al., 2001), it may be that its dorsal expansion in the Tlx mutant telencephalon is responsible for the loss of ventral pallial identity (Stenman et al., 2003b). In E12.5 Gsh2 mutants, Dbx1 is ectopically expressed throughout the LGE (Fig. 7B) (Yun et al., 2001). Dbx1 is also expressed throughout the LGE in E12.5 Gsh2/Tlx double mutants (Fig. 7C); however, fewer expressing cells are observed than in Gsh2 mutants. Thus, Tlx seems to be required for the robust expression of Dbx1 in the lateral telencephalon, whereas Gsh2 functions to restrict its expression to the ventral pallium. The expression domain of SFRP2, on the other hand, appears to require Tlx for its expression in the lateral telencephalon (Fig. 7F). The expression of this gene is not dependent on Gsh2; however, its expression shifts ventrally into the LGE (Fig. 7E), corresponding to the ventral limit of PAX6 expression (Fig. 6E). By E14.5, when the recovery has occurred in the Gsh2 mutant LGE, SFRP2 expression is found at the LGE-pallium angle, similar to that in wild types (data not shown). In addition, Ngn2, which is missing from the ventralmost part of the pallium in Tlx mutants (Stenman et al., 2003b), is expanded ventrally into the dorsal half of the LGE in the Gsh2/Tlx double mutants, similar to that in Gsh2 mutants (data not shown; Corbin et al., 2000; Toresson et al., 2000; Yun et al., 2001), suggesting that Gsh2 negatively regulates Ngn2 expression. Despite these molecular alterations, the expression of Tbr1, a pallial marker, and Lhx2, a marker of the ventral pallial MZ, can still be detected in the lateral telencephalon (Fig. 8A-D). Therefore, although our data show that Tlx and Gsh2 differentially regulate the molecular identity of the ventral pallium, aspects of ventral pallial identity can develop in the absence of these gene products.
Discussion
Telencephalic progenitor domains
In the ventral spinal cord, progenitor domains for distinct neuronal subtypes have been well characterized on the basis of restricted expression of developmental control genes (for review, see Jessell, 2000; Briscoe and Ericson, 2001). Cross-repressive actions between these developmental control genes have been shown to be required for the refinement of progenitor domains along the dorsoventral axis (Muhr et al., 2001; Novitch et al., 2001; Vallstedt et al., 2001). It is now clear that the telencephalic neuroepithelium also can be divided into a number of molecularly distinct progenitor domains, including those studied here: the ventral pallium, dorsal LGE, and ventral LGE (for review, see Marin and Rubenstein, 2002).
In this study, we reported a novel expression domain for the homeobox transcription factor NKX6.2. Cells expressing this protein are found in the sulcus between the LGE and MGE. This interganglionic expression of NKX6.2 may mark a new progenitor domain in the telencephalon. We currently do not know what cell types derive from this domain. In the spinal cord, NKX6.2 plays an important role in establishing the boundary between the most dorsal progenitor domains in the ventral spinal cord, p0 and p1; the establishment of these progenitor domains depends crucially on cross-repression with Dbx1 (Vallstedt et al., 2001). It is interesting to note that the telencephalic expression of NKX6.2 and GSH2 appears to be complementary (data not shown). It is therefore possible that NKX6.2 acts as a repressor also in the telencephalon and regulates the establishment of the ventral expression border of the ventral LGE progenitor domain.
Information remains scarce as to how the gene expression boundaries between the defined progenitor domains are established in the developing telencephalon. Moreover, it is quite likely that a number of domains have yet to be identified. In addition, a detailed analysis of what neuronal subtypes are generated by each progenitor domain is still lacking. In this study, we contributed to the understanding of how the gene expression boundaries marking distinct progenitor domains both within and flanking the LGE are established.
Control of ventral LGE development
In a recent study examining the Tlx mutant cortex, Roy et al. (2002) provided evidence suggesting that mutant cortical cells undergo precocious differentiation and, as a result, deplete the progenitor pool midway through cortical neurogenesis. Moreover, their results from BrdU-incorporation studies indicate that, between E9 and E14, the cell cycle of cortical progenitors is shortened in Tlx mutants compared with wild types. Together, these defects were proposed to account for the observed thinning of the Tlx mutant cortex. Although the entire telencephalon of Tlx mutants is reduced compared with wild types (Monaghan et al., 1997), the LGE and, importantly, only one of its derivatives, the striatum, are proportionately more affected than other telencephalic regions. Therefore, the proliferation defect we reported here, and which was described previously for the cortex (Roy et al., 2002), is unlikely to account for all of the defects observed in the ventral telencephalon but is probably only an element of a more complex phenotype.
Previous studies have shown that ISL1 marks differentiating striatal projection neurons but is rapidly downregulated after birth (Toresson et al., 2000; Toresson and Campbell, 2001; Wang and Liu, 2001). Our present findings demonstrate that ISL1 is already downregulated by E18.5 in Tlx mutants. This finding would support the precocious differentiation hypothesis of Roy et al. (2002); however, the ISL1-expressing ventral LGE is already reduced in size by E14.5, indicating that even early striatal projection neuron generation is compromised. This reduction in size of the ventral LGE is observed simultaneously with that of a ventral expansion of dorsal LGE markers and a dorsal expansion of the interganglionic marker NKX6.2. This indicates that both the proliferation and the patterning defects are early events that occur at the earliest steps of LGE development. It is possible that either the proliferation defect causes the patterning defect or the other way around. In any case, the disproportionate reduction in the ventral LGE and subsequently the striatum is likely to result from the additive effects of both the proliferation and patterning defects.
In Gsh2 mutants, the dorsal LGE is most severely reduced; however, a significant truncation of the ventral LGE also occurs (Yun et al., 2001; Stenman et al., 2003a). The Tlx phenotype, on the other hand, is most severe in the ventral LGE. Thus, when removing both Tlx and Gsh2, the effect on ventral LGE, and therefore on the striatum, is even more severe than in either of the single mutants. Whereas, at early stages (i.e., E12.5) in Gsh2/Tlx double mutants, PAX6 is ectopically expressed in the dorsal half of the LGE, NKX6.2 is ectopically expressed in the ventral half; this leaves only a small domain, which is, at least apparently, correctly patterned. However, by E14.5, the expression domain of NKX6.2 and PAX6 nearly abut in the LGE-cortex angle of the double mutants. This suggests that very few striatal projection neurons would be generated during late stages of striatal development. Moreover, because Gsh2 mutants lack the early formation of the LGE SVZ, it is likely that both early and late striatal neurogenesis is affected in the Gsh2/Tlx mutants (Toresson et al., 2000; Yun et al., 2001).
Control of dorsal LGE identity
As mentioned above, Gsh2 gene function is crucial for the expression of dorsal LGE characteristics. It is interesting to note that high-level GSH2 expression is observed in more ventral regions of the Tlx mutant LGE, suggesting that Tlx is required to confine high-level GSH2 expression to the dorsal LGE. This concept is hard to reconcile with the observation that GSH2 and Tlx are both expressed at high levels in the dorsal LGE. However, it is clear that, together with Pax6, Tlx regulates a genetic program that represses Gsh2 from the ventral pallium (Stenman et al., 2003b). Thus, there might be a specific genetic partner for Tlx in the ventral LGE. It may also be that Tlx represents a weak repressor of Gsh2 and that there is a patterning center in the lateral telencephalon that induces high levels of Gsh2 by virtue of it close proximity.
Er81 gene expression is found in both the VZ and SVZ of the dorsal LGE (Yun et al., 2001); however, expression of the protein is confined of the SVZ of the dorsal LGE (Stenman et al., 2003a). It is interesting to note that the expression of Er81 in the SVZ correlates well with high levels of GSH2 in the overlying VZ. Indeed, the restriction of Er81 to the SVZ of the dorsal LGE is dependent on Gsh2 gene function. In both Gsh2 mutants and Gsh2/Tlx double mutants, Er81 is expressed in the LGE VZ and not in the SVZ.
Control of ventral pallial identity
We suggested previously that Tlx might be required for driving expression of Ngn2 in the ventral pallium (Stenman et al., 2003b). However, at E12.5, in the Gsh2/Tlx double mutants, both PAX6 and Ngn2 are, as in Gsh2 mutants, ectopically expressed in the dorsal half of the LGE, and, at E14.5, after the Gsh1-mediated recovery (Toresson and Campbell, 2001), PAX6 and Ngn2 are expressed in their normal expression domain. This indicates that the ectopic expression of GSH2 in the ventral pallium of Tlx mutants is responsible for the repression of Ngn2. This does not preclude the possibility that Tlx may also promote Ngn2 expression in the ventral pallium; however, this effect would clearly be less significant than the repressive effect of Gsh2. Dbx1 regulation in the lateral telencephalon is more complicated. Analysis of Gsh2 mutants has shown that Gsh2 genetically represses Dbx1 expression (Yun et al., 2001; this study). However, in Gsh2/Tlx double mutants, Dbx1 is expressed at lower levels than in Gsh2 mutants, showing that Tlx expression is required for high levels of Dbx1 expression in the telencephalon. SFRP2 appears to be regulated in a more simple manner. No evidence exists in support of Gsh2 being a repressor of SFRP2. In fact, SFRP2 is expressed at both E12.5 and E14.5 in Gsh2 mutants; the expression domain is shifted at E12.5 to the most ventral part of the PAX6 expression domain, whereas at E14.5 SFRP2 expression is indistinguishable from that in wild types. SFRP2, however, is missing in Sey mutants (Kim et al., 2001) as well as in Tlx mutants (Stenman et al., 2003b) and Gsh2/Tlx mutants. Thus, Pax6 and Tlx could be direct regulators of SFRP2. At least one allele of both Pax6 and Tlx is absolutely required for the lateral telencephalic expression of SFRP2 (Stenman et al., 2003b). In summary, whereas Gsh2 appears to be a negative regulator of ventral pallial identity by virtue of it repressive actions on Pax6, Ngn2, and Dbx1 expression, Tlx is required to confine Gsh2 expression to the dorsal LGE as well as to promote the expression of Dbx1 and SFRP2. As we showed previously (Stenman et al., 2003b), Tlx performs these functions in concert with the pallial-enriched Pax6 gene.
Footnotes
This work was supported by National Institutes of Health Grant NS044080 and Human Frontiers Science Program Grant RG160-2000B (K.C.). We thank R. T. Yu and R. M. Evans for providing the Tlx mice. We gratefully acknowledge the kind gifts of probes and antibodies from D. Anderson, T. Edlund, P. Emson, J. Ericson, M. Götz, T. Jessell, and S. Morton.
Correspondence should be addressed to Kenneth Campbell at the above address. E-mail: kenneth.campbell{at}chmcc.org.
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