Abstract
The developing cerebral cortex uses a complex developmental plan involving angiogenesis, neurogenesis and neuronal migration. Our recent studies have highlighted the importance of endothelial cell secreted GABA signaling in the embryonic forebrain and established novel autonomous links between blood vessels and the origin of neuropsychiatric diseases. A GABA pathway operates in both endothelial cells and GABAergic neurons of the embryonic telencephalon; however, while the neuronal GABA pathway has been extensively studied, little is known about the endothelial GABA pathway. Our recently generated Vgat endothelial cell knockout mouse model that blocks GABA release from endothelial cells, serves as a new tool to study how endothelial GABA signaling shapes angiogenesis and neurovascular interactions during prenatal development. Quantitative gene expression profiling reveals that the endothelial GABA signaling pathway influences genes connected to specific processes like endothelial cell proliferation, differentiation, migration, tight junction formation, vascular sprouting and integrity. It also shows how components of the neuronal GABA pathway, for instance receptor mediated signaling, cell cycle related components and transcription factors are affected in the absence of endothelial GABA release. Taken together, our findings delineate the close relationship between vascular and nervous systems that begin early in embryogenesis establishing their future interactions and interdependence.
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Introduction
GABA is well established as the first excitatory transmitter to become functional in the embryonic brain and exerts diverse region-specific roles at different developmental stages. It is a deeply interesting and versatile molecule. Multi-modal actions of GABA-GABAA receptor signaling have been elucidated in individual cortical layers during embryonic brain development1. It plays an important role in building the cortical network by controlling processes like neural progenitor proliferation, neuronal migration, dendritic maturation and synaptogenesis2,3,4. Abnormalities in neurons, altered GABAA receptor distribution and dysregulated tonic inhibition have been implicated in neuropsychiatric diseases such as epilepsy, autism, schizophrenia and depression1,5,6,7,8,9,10,11. However, traditional views of neocortical development have depicted this source of GABA to be exclusively neuronal. We believe that GABA’s versatility is due to its different sources in the embryonic forebrain - neuronal versus endothelial with select roles performed depending on the cell type that secretes it. Our discovery of a novel GABA and its receptors’ signaling pathway within forebrain endothelial cells independent of the traditional GABA neuronal pathway has produced a new way to think about the origin and mechanisms of psychiatric illnesses12. The vesicular GABA transporter (Vgat) loads GABA from the endothelial cytoplasm into vesicles. By deleting Vgat specifically from endothelial cells, we were able to successfully turn off endothelial GABA secretion during embryonic brain development, illustrating that Vgat is the primary mechanism for GABA release from endothelial cells at early embryonic stages12. No GABA transporters (GATs) were present at this stage in telencephalic endothelial cells. Thus, we were able to evaluate the full significance of Vgat in endothelial GABA release for angiogenesis as well as other key cellular events during forebrain development - neurogenesis, radial migration of projection neurons and tangential migration of GABAergic interneurons, all of which were affected to some degree. With respect to angiogenesis, the cellular events that were significantly affected were endothelial cell proliferation, migration, tube formation and loss of tight junction formation with increased vascular permeability12. These results indicated that endothelial GABA signaling is connected to other key angiogenesis pathways. With respect to fostering neuro-vascular interactions, endothelial cell secreted GABA played a critical role for long distance GABAergic neuronal migration in the embryonic forebrain12. Neuronal GABA was unable to compensate for this unique role of endothelial GABA, since GABAergic neuronal tangential migration was significantly affected in the absence of endothelial GABA. The Vgat endothelial cell conditional knockout (VgatECKO) mouse model developed severe seizures during the early postnatal period and did not survive beyond 2 months of age12. Thus, this endothelial Vgat-GABA signaling pathway is a key mediator of vascular development and neuro-vascular interactions in the prenatal period, important for cortical circuit formation and indispensable for proper behavioral function.
As we now understand the significance of this vascular GABA pathway, it is essential to gain mechanistic insights by segregating this pathway specifically in endothelial cells and to see how neuronal gene expression is affected in the absence of endothelial GABA signaling. Global gene expression profiling of whole brain is not sufficient to address this issue and cell-type specific isolation of endothelial cells versus neuronal cells is important to achieve this goal. For instance, what molecular changes occur in telencephalic endothelial cells in the absence of endothelial Vgat and subsequent GABA release? How does loss of vascular GABA release affect genes that are critical for neuronal development? The VgatECKO mouse model is ideal to address such questions. It is significant for identifying not only the mechanistic basis by which endothelial cell secreted GABA achieves its autocrine actions on angiogenesis and paracrine actions on neurons, but also, it serves as new resource, to isolate hitherto unknown or novel molecular mechanisms that regulate vascular development in the embryonic forebrain.
By using microarray technology, we were able to profile periventricular endothelial cells and neuronal cells from control (Vgatfl/fl) and VgatECKO embryonic telencephalon at high resolution. Our results show that extensive molecular changes occurred within the telencephalic endothelium and within neuronal cells due to loss of endothelial GABA release. It provides valuable insights into altered expression of transcription factors, Wnt signaling and tight junction molecules as well as new GABA signaling components in VgatECKO endothelial cells. Additionally, it shows how gene expression programs that regulate neuronal proliferation, differentiation and migration are altered. Furthermore, our study explains how changes in cell-type specific gene expression are a key determinant of behavioral outcome.
Results
Isolation of endothelial and neuronal populations from Vgat ECKO telencephalon and gene expression profiling
To understand in detail how endothelial GABA modulates the neuronal GABA signaling pathway, we isolated and cultured periventricular endothelial cell and neuronal cell populations from Vgatfl/fl and VgatECKO telencephalon at embryonic stage 15 (E15), an age midway through mouse cortical neurogenesis and migration, using well established methods13,14,15,16. In the VgatECKO model, endothelial GABA signaling is affected from early embryonic stages. Therefore, VgatECKO neurons isolated at E15 have already undergone significant molecular changes in the absence of endothelial cell secreted GABA in vivo. Since key cellular events were affected in both cortical and sub-cortical telencephalon by this stage12, we did not restrict the neuronal isolation spatially. The neuronal population was characterized by immunocytochemistry, morphology, and sub-type specific marker expression and was found to be predominantly GABAergic, with a small proportion of glutamatergic neurons and an absence of microglia (Supplementary Figures 1 and 2). RNA was isolated from cell type specific samples and subsequent microarray hybridization and analysis was performed (Fig. 1a). Principal component analysis (PCA) showed differences in molecular signatures between endothelial cells and neurons from VgatECKO and Vgatfl/fl telencephalon based on cell segregation, that were further supported by strict clustering of independent triplicates (Fig. 1b). Endothelial or neuronal cells were also well distinguished by their genotypes (Vgatfl/fl or VgatECKO) by PCA 2 and 3 in the 3D PCA table (Fig. 1b). Differential gene expression analysis provided a robust identification of changes in several distinct gene ontology (GO) terms/pathways in VgatECKO endothelial and neuronal cells (Fig. 1c,d), including ‘tight junction’ and ‘Wnt receptor signaling’ categories in endothelial cells versus ‘neurogenesis’, ‘cell fate commitment’ and ‘cell migration’ categories in neuronal cells. Analysis of differentially expressed genes depicted global up-and downregulation in both endothelial cells and neuronal cells from VgatECKO telencephalon (Fig. 1e,g). These variations in gene expression were graphed using a scatter plot and a pie chart to distinguish between up (orange) and down (blue) regulated genes in VgatECKO endothelial and neuronal cells (Fig. 1e,g). We found 367 (2.04%) or 572 (3.18%) significantly up- or down-regulated genes in VgatECKO endothelial cells (Fig. 1e) and 544 (3.03%) or 849 (4.72%) up- or down-regulated genes in VgatECKO neuronal cells with comparison to controls (Fig. 1g). GO analysis with up- or down-regulated gene set of VgatECKO periventricular endothelial cells revealed that terms such as ‘developmental process’, ‘Wnt receptor signaling’, ‘blood vessel development’, ‘blood vessel morphogenesis’, and ‘angiogenesis’ were strongly downregulated in VgatECKO endothelial cells, in contrast to enrichment of GO term, ‘regulation of cellular process’, in the up-regulated gene set (Fig. 1f). This observation is consistent with the reduction in blood vessel densities and low angiogenic score observed in the VgatECKO forebrain12. In neuronal sets, however, significant up-and down-regulation was observed in ‘developmental/cellular processes and ‘cell proliferation/cell cycle’ categories (Fig. 1h). This is also interesting since the VgatECKO telencephalon showed an increase in mitotic cells in the SVZ while no differences were observed in the VZ, indicative of significant differential expression in cell cycle related genes12. VgatECKO neurons also showed an increase in neuronal differentiation, hypoxia related and cell death categories (Fig. 1h) and a down-regulation in cell maturation, motility and migration categories (Fig. 1h). This is coordinate with the observation of stalled neuronal migration in the VgatECKO telencephalon12.
Comparison of gene expression profile of Vgatfl/fl and VgatECKO endothelial and neuronal cells. (a) Schematic depicting brain dissection, removal of pial membrane, isolation and culture of periventricular endothelial cells and neuronal cells from E15 Vgatfl/fl and VgatECKO mouse embryos and subsequent microarray hybridization. (b) PCA analysis of gene expression profile from endothelial cells and neuronal cells, n = 3 biological samples. (c,d) Gene ontology analysis of differentially expressed genes in VgatECKO endothelial cells (c) and neuronal cells (d). (e) Scattered plot and pie chart (inset) expression for up- and down-regulated genes in E15 VgatECKO endothelial cells compared to Vgatfl/fl endothelial cells. (f) GO biological process analysis of up- and down-regulated genes in VgatECKO endothelial cells. (g) Scattered plot along with pie chart expression for up- and down-regulated genes in VgatECKO neuronal cells when compared to controls. (h) GO biological process analysis of up- and down-regulated genes in VgatECKO neuronal cells. ECs: endothelial cells; NCs: neuronal cells.
Extensive changes in gene expression profiles in Vgat ECKO endothelial cells
To obtain detailed biologically relevant information of gene expression dynamics in VgatECKO endothelial cells, we performed step-by-step characterization of the data using multi-faceted approaches. GO enrichment analysis of VgatECKO periventricular endothelial cells revealed 119 differentially expressed genes that were involved in 5 categories related to: angiogenesis, tight junction, Wnt signaling, transcription factor activity and GABA signaling (Fig. 2a). Analysis of the overlap in similarities and differences between gene sets showed that 11 angiogenesis related genes were shared with transcription related genes. Among the 11 genes, 6 genes overlapped with Wnt signaling genes. We next performed a leading-edge analysis with gene sets from the 5 biological categories and found that the enrichment score of most genes from 4 categories including angiogenesis, Wnt signaling, tight junction, and transcription, were significantly low, while some GABA signaling related genes of periventricular endothelial cells showed a higher enrichment score (Fig. 2b). These results implied that angiogenesis and its related biological processes such as Wnt signaling, tight junctions, and transcription, were closely associated, and moreover down-regulated together following the loss of Vgat function in endothelial cells. Genes that showed high enrichment score in GABA signaling category (Gabbr1, Gabra2, Gabrb2, Gabrg3) may indicate compensational mechanisms in response to the lack or low extracellular GABA signals. To further investigate these gene sets, we performed computational marker selection analysis and identified the top 27 marker genes (Fig. 2c). Genes of Wnt signaling and tight junction categories mostly emerged from the analysis. All selected genes were hierarchically clustered (Fig. 2c) and were displayed in a heatmap matrix for their expression pattern similarity analysis (Fig. 2d). Distinct patterns of gene expression emerged, and high co-relations were found for several gene sets. For instance, expression pattern similarity analysis showed significant upregulation of Gabrb2, Pard6b, and Shroom2, and significant down-regulation of Gabrp, Nps, Itgb3, and Wnt10a in VgatECKO periventricular endothelial cells. Additionally, detailed expression of 10 marker genes in 5 categories: angiogenesis, Wnt signaling, tight junction, transcription factor and GABA signaling in Vgatfl/fl versus VgatECKO endothelial cells were represented as violin plots (Fig. 2e). An increase in genes necessary for morphogenesis, survival, vascular responses and inflammation (F2rl1, Stc1, Nrp1, Shroom2) and a reduction in genes specific for endothelial cell proliferation (Pdgfrb, Vegfa), differentiation (Hoxa9), migration (Itgb3, Sema4a, Vegfa), vascular sprouting and integrity (Fgf9, Vegfa) was observed in VgatECKO endothelial cells. Gain or loss of function of Wnt pathway signaling components can result in abnormal vascular development and angiogenesis and this was re-capitulated by differential gene expression in VgatECKO endothelial cells. Wnts play multiple roles in governing cell fate, proliferation, migration, polarity, and death, during development17. Several genes involved in Wnt signaling/Wnt signaling pathway (Ptpru, Dkk4, Invs, Rspo3, Wnt10a, Wnt10b, Wnt16) were downregulated and negative regulation of Wnt signaling pathway genes (Wif1, Sost, Nkd1) were upregulated in VgatECKO endothelial cells when compared to controls (Fig. 2e). Disruption of tight junctions disturbs endothelial barrier functions. In the mouse brain, a functional blood-brain barrier (BBB) is formed by embryonic day 15 and endothelial cell-cell junctions provide stable connections to prevent leakage18. Differential expression of several claudins, occludin and tight junction associated signaling molecules was observed in VgatECKO endothelial cells (Fig. 2e). Claudin genes (Cldn2, Cldn4, Cldn9, Cldn20) related to tight junction formation were significantly altered in VgatECKO periventricular endothelial cells. And Akt2, important for maintenance of BBB integrity was downregulated19, while shroom2 that interacts with ZO-1 at tight junctions was up-regulated20. Transcriptional regulatory networks were also significantly altered in VgatECKO endothelial cells that can contribute to abnormal blood vessel development. For instance, Dlx5, Smad9, Myb and Gsc were upregulated, while Pbx2, Hoxa9, Gata1 and Bhlhe41 were downregulated. Hoxa9 transcriptionally regulates the EphB4 receptor to modulate endothelial cell migration and tube formation21 while Gata1 regulates angiogenic factor Aggf1 and endothelial cell function22. In the GABA signaling category, GABAA receptor subunits expression was altered (Gabrb2, Gabbr1, Gabrbp) in VgatECKO endothelial cells. The homeobox gene, Dlx1 and glutamic acid decarboxylase isoform, Gad2, were concurrently upregulated, but not Gad1. GABA is synthesized from glutamate by Gad isoforms. Specific promoter regulatory elements of Gad2 are direct transcriptional targets of Dlx1. This indicates that intracellular GABA levels are ramped up in VgatECKO endothelial cells. Taken together, these results implicate Vgat as a critical modulator of multiple angiogenesis pathways in the embryonic forebrain.
Major gene expression changes in VgatECKO endothelial cells. (a) Venn diagram of gene sets overlapping in 5 ‘biological process’ categories of VgatECKO endothelial cells. (b) Leading edge analysis of 5 ‘biological process’ gene sets of VgatECKO endothelial cells compared to controls (up-regulation (red color), down-regulation (blue color)). (c) Selection and hierarchical clustering of top differentially expressed genes in Vgatfl/fl and VgatECKO endothelial cells. (d) Expression similarity analysis of selected genes by using Pearson correlation method. (e) Violin plot comparison of differentially regulated genes (10 genes) in 5 ‘biological process’ categories between Vgatfl/fl endothelial cells (blue) and VgatECKO endothelial cells (orange).
Extensive changes in gene expression profiles in neuronal cells from Vgat ECKO telencephalon
We next turned our attention to understand the gene expression changes in VgatECKO neuronal cells in the absence of endothelial GABA release. Grouping of genes into Venn diagrams illustrated 146 genes in neuronal development, cell cycle, cell proliferation, cell fate commitment and transcription related categories (Fig. 3a). In leading edge analysis, we found that the enrichment score of genes associated with the cell cycle and cell proliferation categories were mostly low, and cell fate commitment were moderately low, while the score of genes related to neuronal development and transcription were moderately high (Fig. 3b). These results denote that altered GABA signaling from VgatECKO periventricular endothelial cells can directly affect several aspects of neuronal development including cell cycle, proliferation, fate commitment and transcription factor activity. We then isolated 30 marker genes for these 5-biological processes in VgatECKO neuronal populations (Fig. 3c). These genes were also clustered hierarchically, and we analyzed expression pattern similarity as a heatmap matrix (Fig. 3d). The analyses revealed prominent changes in genes specifically associated with GABAergic neuronal development, cell cycle, proliferation, fate commitment, and transcription related categories. Genes that displayed co-relation in expression pattern within the upregulated genes set were Adora2a, Ss18l1, Gata3, Gbx2, Nr4a2 and Ret, while in the downregulated genes sets were Cyp1a1, Itgb3bp and Ppara. Based on the GSEA results, a violin plot was used to represent the differential expression of top 10 genes in the above categories (Fig. 3e). Surface expression of several GABAA receptor subunits (Gabrb1, Gabrg2 {Fig. 3b,e}; Gabra3, Gabrq {Fig. 3b}), distinct from the ones on VgatECKO endothelial cells and several genes associated with GABAergic neuronal specification, differentiation and survival (Nkx2.1, Lhx1, Lhx6) were upregulated in VgatECKO neurons. No changes were observed in Gad isoforms (Gad1, Gad2) or GABA release and uptake mechanisms in neuronal cells (Gat1-4 and Vgat). Cell cycle and cell proliferation related genes showed differential expression. While cell cycle genes (Cdc6, Nde1, Brca1, Spry1, Cdkn3, Spc24, Fgfr1) were downregulated, positive regulation of cell cycle genes (Cast, Rara, Arid3a) were upregulated in VgatECKO neuronal cells. Similarly, while some genes related to cell proliferation (Etv5, Ptges, Appl2, Ncapg2, Tgfbr3 and Nde1) were down regulated; some others were upregulated (Fgf5, Gbx2, Met and Lhx1). Genes involved in neuronal fate commitment (Nkx2.2, Hes5, Nodal, Fgfr1, Spry1) and synapse organization (Erbb2), were downregulated in VgatECKO neuronal cells. Neuronal migration associated genes were significantly affected in VgatECKO neuronal populations. Positive regulators of cell motility/migration related genes were significantly downregulated (Fgfr1, Nde1, Ntn1 and Twist1), while negative regulators of cell migration (Drd2, Adra2c) were upregulated. For instance, an upregulation of Drd2 that can slow down neuronal migration was observed. Drd2 activation has been reported to decrease tangential GABAergic neuronal migration from the ganglionic eminences to the cerebral cortex23. These results provide more in-depth mechanistic understanding of the cell proliferation changes and stalled long distance GABAergic neuronal migration in VgatECKO telencephalon12. Thus, based on the extensive changes in gene expression patterns, GABAergic neuronal cell gene expression is significantly affected by alteration of endothelial GABA release.
Major gene expression changes in VgatECKO neuronal cells. (a) Venn diagram of gene sets overlapping in 5 ‘biological process’ categories of VgatECKO neuronal cells. (b) Leading edge analysis of 5 ‘biological process’ gene sets of VgatECKO neuronal cells compared to controls (up-regulation (red color), down-regulation (blue color)). (c) Selection and hierarchical clustering of top differentially expressed genes of Vgatfl/fl and VgatECKO neuronal cells. (d) Expression similarity analysis of selected genes by using Pearson correlation method. (e) Violin plot comparison of differentially regulated genes (10 genes) in 5 ‘biological process’ categories between Vgatfl/fl neuronal cells (green) and VgatECKO neuronal cells (purple).
Validation of gene expression by quantitative real-time PCR analysis
We further confirmed some of the notable changes in gene expression in Vgatfl/fl and VgatECKO endothelial cells and neuronal cells by performing quantitative real-time polymerase chain reaction (qRT-PCR). In VgatECKO endothelial cells, angiogenesis genes, Itgb3, and Vegfa were down-regulated while Nrp1 was upregulated (Fig. 4a–c). Vegfa binding to Nrp1 is a trigger for several of the biological functions of Vegfa24; therefore, the inverse co-relation in Vegfa-Nrp1 expression in VgatECKO endothelial cells is particularly interesting. Tight junction related gene (Cldn2) and Wnt signaling genes (Wnt10a, Wnt10b) were significantly downregulated (Fig. 4d–f). The signaling pathways triggered by Wnt10a and Wnt10b in embryonic brain endothelial cells are yet uncharacterized. Cldn2 has been reported as an essential component of tight junctions at the blood retinal barrier and blood-CSF barrier and is believed to contribute to key functions at this interface25, and may have new roles in periventricular angiogenesis at this embryonic stage. Another novel aspect is the change in GABA related gene expression in VgatECKO endothelial cells. The absence of a GABA release mechanism triggered an elevated expression of transcription factors Dlx1 and Dlx5, and GABA synthesizing enzyme Gad2 in VgatECKO endothelial cells (Fig. 4g–i). Gad genes are direct Dlx transcriptional targets that may explain the concurrent up-regulations. Thus, validation of gene expression changes in VgatECKO endothelial cells provided new mechanistic insights that account for the vascular deficits observed in the VgatECKO telencephalon (Fig. 4j,k).
Validation of altered gene expression in VgatECKO endothelial and neuronal cells. (a–i) RT-qPCR validation of microarray gene expression profiles in Vgatfl/fl and VgatECKO endothelial cells. Data represents mean ± S.D, (n = 3, *P < 0.05, Student’s t test). (j,k) Schema depicting altered vascular profiles in VgatECKO telencephalon. Vgatfl/fl embryonic telencephalon has normal periventricular vascular network (red lattice pattern) and normal endothelial GABA signaling pathway (reddish orange hue) (j) while in VgatECKO telencephalon there is complete loss of endothelial GABA secretion (light yellowish hue) that affects periventricular angiogenesis (dotted red pattern) and vascular pattern formation (k). (l–t) RT-qPCR validation of microarray gene expression profiles in Vgatfl/fl and VgatECKO neuronal cells. Data represents mean ± S.D, (n = 3, *P < 0.05, Student’s t test). (u,v) Schema depicting GABAergic neuronal tangential migration (green) in Vgatfl/fl and VgatECKO telencephalon. Complete loss of endothelial GABA secretion (light yellowish hue) has significant consequences for GABAergic neuronal migration resulting in neuronal reductions and abnormal cortical distribution in VgatECKO telencephalon (v). LV: lateral ventricle.
In the VgatECKO neuronal cell population, we found an increase in the mRNA level of Lhx1, Lhx6, Nkx2.1 and Mef2c, multi-functional determinants of GABAergic neuronal development (Fig. 4l–o), including differentiation, migration, interneuron fate specification and survival. For instance, Lhx6 and Nkx2.1 were coordinately upregulated in VgatECKO neuronal cells. Lhx6 functions directly downstream of Nkx2.1 in the specification of parvalbumin and somatostatin interneuron fate26. Nkx2.1 expression needs to be normally turned off during interneuron migration to the cortex and increases in Nkx2.1 expression can lead to an accumulation of MGE-derived interneurons in the striatum27 as observed in the VgatECKO telencephalon12. The increase in surface expression of several neuronal GABAA receptors units in the absence of endothelial GABA release was also confirmed (Fig. 4p–r). Transcription factor Nkx2.2 expression that partially overlaps with the expression domains of Nkx2.1 and Dlx28 was down-regulated (Fig. 4s), so too was Etv5 that is important for dendrite development and plasticity29 (Fig. 4t). These results provide new mechanistic understanding of the stalled GABAergic neuronal migration and accumulation in the VgatECKO ventral telencephalon (Fig. 4u,v) and abnormal distribution and cortical layer-specific reductions in interneuron populations12. Taken together, our data illustrate validated down-stream gene expression changes in endothelial and neuronal cells due to the loss of autocrine and paracrine GABA signaling from endothelial cells.
Cell type specific gene expression and its significance for neuropsychiatric disease
We next questioned whether the gene expression profile in endothelial cells versus neuronal cells could be used to isolate which cell type contributes to the postnatal phenotype of the VgatECKO mice. Interestingly, when genes were classified according to disease categories by using the CDT database, endothelial cells showed more significant enrichment in autism spectrum disorder and epilepsy categories versus neuronal cells (Fig. 5a), that co-related with the VgatECKO postnatal phenotype. VgatECKO mice show seizure-like activity from P7 onward, with periods of quiescence, tremors and decreased voluntary movement and serves as model for childhood epilepsy or autism12. Neuronal cells on the other hand showed similar or greater enrichment in disease categories: intellectual disability, basal ganglia diseases, dyskinesia, movement disorders and schizophrenia (Fig. 5a). We also performed a network analysis to reveal the relationship between diseases and their corresponding genes in VgatECKO endothelial cells and neurons. In gene-disease network relationships, we observed that the genes were distinct with respect to cell types and disease categories (Fig. 5b,c). For instance, autism spectrum disorder related genes were different in endothelial cells versus neuronal cells. Several genes from endothelial cells (Cp, Apoe, Grin2A, Slc1a1, Ntrk1, Ntrk2, Igf2, Hcn1, and Kcna2) and neuronal cells (Drd2, Adora2a, Cnr1, Prl, Sod1, Cp, Cntnap2, Kcna2, Grin2a, Met, Polg, Mef2c, Reln and Htr2a) however showed cross-connectivity and relationship with 3 or more disease categories. Taken together, our results signify the importance of making correct identification of cell-type specific contributions to a specific disease phenotype. Delineation of cell-type specific effects, neuronal versus endothelial, during the developmental window, is important before treatment strategies can be designed in a disease model.
The significance of cell-type specific gene expression for neuropsychiatric disorders. (a) Comparison of disease enrichment score between VgatECKO endothelial cells (E) and neurons (N) in similar brain disease categories. (b) Network of differentially expressed genes and corresponding brain disorders of VgatECKO endothelial cells based on CTD analysis. (c) Network of differentially expressed genes and corresponding brain disorders of VgatECKO GABAergic neurons based on CTD analysis. (d) Summary schema highlighting the extensive gene expression changes in endothelial cells and neuronal cells in the absence of Vgat and an endothelial GABA release mechanism at embryonic stages.
Discussion
This study provides new insights into the mechanistic contributions of endothelial Vgat to forebrain development. Although neuronal GABA signaling has been extensively studied in the embryonic telencephalon, the molecular mechanisms regulating vascular GABA signaling are unknown. Deletion of Vgat from endothelial cells disturbed the normal dynamics of endothelial specific gene expression and strongly affected Wnt signaling and tight junction formation markers, supporting novel functions for Vgat in vascular integrity and early blood-brain barrier development. Among the novel genes that were significantly down-regulated by Vgat in endothelial cells were Wnt10a, Wnt10b, Wnt16, Cld2, Cld4 and Ocln. Additionally, genes involved in endothelial cell proliferation, migration, sprouting and vascular pattern formation (Pdgfrb, Vegfa, Hoxa9, Itgb3, Sema4a and Fgf9) were significantly affected. Our data also illustrates many new components of GABA signaling in endothelial cells (Dlx1, Gad2, several GABAA receptor subunits, Nps, Cnr2) that are affected in the absence of Vgat. Vgat is thus a crucial mediator for maintenance of telencephalic angiogenesis. GABA release from endothelial cells is critical for activating endothelial GABAA receptors and maintaining a positive feedback cycle. When endothelial GABA vesicular storage and release is absent, extracellular GABA levels are concurrently affected. Absence of this endothelial GABA release mechanism increased surface expression of GABAA receptor subunits in endothelial cells and triggered internal changes in angiogenesis pathway genes (Fig. 5d). Absence of endothelial GABA release also affected extracellular GABAA receptor subunit expression on neuronal cells and directly influenced cell cycle and transcription related genes that determine the intrinsic properties of neuronal differentiation, migration, fate and survival (Fig. 5d). Thus, endothelial GABA release and signaling has profound effects in shaping neuronal development.
The spatiotemporal patterns of neuronal GABAA receptor expression are believed to be important in the orchestration of the normal GABA-related regulation of proliferation and migration of neural progenitors in the embryonic brain30. There are several lines of evidence of changes in expression or modification of specific subunits and the altered function of certain GABAA receptors during pregnancy and post-partum period that result in altered synaptic transmission31. This is particularly interesting, since deletion of endothelial Vgat, altered surface expression of several GABAA receptor subunits on both endothelial and neuronal cells, that can also account for the enhanced neuronal network excitability and changes in plasticity observed in the postnatal period12. For instance, VgatECKO neuronal cells showed an elevated GABAA receptor beta 1 subunit expression, while very low expression of the mRNA transcript for the GABAA receptor beta 1 subunit has been reported in the normal embryonic forebrain with expected peaks only at postnatal stages P6–P121. Specific sub-unit composition of GABAA receptors are critical for neuronal migration and may constitute a homeostatic mechanism to maintain a steady balance in establishing GABA’s role as excitatory in the embryonic brain versus inhibitory in the postnatal brain.
Our results also implicate genes enriched in VgatECKO periventricular endothelial cells as being specifically contributory to the disease phenotype of the VgatECKO mouse model versus neuronal cells. Alterations of cell-type specific gene expression provide a template for putative disease subtypes that can be associated with clinical symptoms and phenotypes. These findings implicate the importance of understanding cell-type specific contributions in neuropsychiatric disease origin and calls for a change in perspectives that primarily implicates neuronal dysfunctions to these disorders. Thus, endothelial GABA signaling modulates core aspects of vascular and neuronal development, forming a foundation for more complex neuro-vascular interactions. Consumption of GABA-acting drugs may have profound effects on blood vessels and the blood-brain barrier. In this context, it would be interesting to examine the specific effects of vascular GABA-GABAA receptor signaling in the postnatal and adult brain in future studies.
Materials and Methods
Animals
Timed pregnant CD1 mice were purchased from Charles River laboratories, MA. Colonies of GAD65-GFP and Tie2-GFP mice were maintained in our institutional animal facility. Tie2-cre mice and Vgat floxed (Vgatfl/fl) mice were obtained from Jackson Labs. The Tie2-cre transgene is known for uniform expression of cre-recombinase in endothelial cells during embryogenesis and adulthood12,32,33,34. To selectively delete Vgat in endothelial cells, Tie2-cre transgenic mice (males) were crossed to Vgatfl/fl mice (females) to generate Tie2-cre; Vgatfl/+ mice (males). These were further crossed with Vgatfl/fl mice (females) to obtain the Vgat conditional knock-outs (Tie2-cre; Vgatfl/fl mice). The day of plug discovery was designated embryonic day 0 (E0). Animal experiments were in full compliance with the NIH Guide for Care and Use of Laboratory Animals and were approved by the McLean Institutional Animal Care Committee.
Isolation and primary culture of endothelial cells
Embryonic brains were dissected under a stereo-microscope and the telencephalon was removed. Pial membranes were peeled out and discarded. The remaining telencephalon without pial membranes was pooled (periventricular endothelial cells). Purity of endothelial cell cultures was established with endothelial cell markers and determined to be one hundred percent13,14,35. Isolation and culture of endothelial cells was performed according to published methodology14.
Isolation and primary culture of neuronal cells
Primary culture of E15 embryonic neurons was performed using modifications of established methods15,16. Briefly, embryonic brains were extracted under a stereo microscope and placed in cold PBS. After removal of pial membrane, telencephalon was dissected from each embryonic brain. Telencephalon was minced into 1–2 mm slice in cold PBS. Minced telencephalon was treated with 0.1x trypsin/EDTA at 37 °C for 5 min. Trypsin treatment was stopped by adding FBS-DMEM media followed by DNase I/ FBS-DMEM. Dissociated cells were filtered with a 40 um cell strainer and finally filtered cells were cultured in poly-D-lysine and laminin coated cover slips (Corning) in 24 well culture dishes (50,000 cells per well) in Neurobasal media (Life technologies) with 1x B-27 (Life technologies) and 1x Glutamax (Life technologies) in the presence of BDNF (100 ng/ml) and GDNF (50 ng/ml) for 4 days at 37 °C at 5% CO2.
Gene expression profile analysis
RNA samples were prepared from Vgatfl/fl and VgatECKO endothelial and neuronal cell cultures from three different brain pools. Total RNA from each cell type was extracted by using the PicoPure RNA Isolation kit (Arcturus) followed by supplier’s protocol. Mouse Gene 2.0 ST Array (Affymetrix) and data normalization for producing gene level expression values, were performed at the Boston University Microarray & Sequencing Resource, Boston, MA by using the implementation of the Robust Multiarray Average (RMA)36 in the affy package (version 1.36.1)37 included in the Bioconductor software suite (version 2.11)38. Normalization of microarray were performed together using the Robust Multiarray Average (RMA) algorithm and a CDF (Chip Definition File) that maps the probes on the array to unique Entrez Gene identifiers. The result is a matrix in which each row corresponds to an Entrez Gene ID and each column corresponds to a sample. The expression values are log2-transformed by default. PCA was analyzed and visualized using Transcriptome Analysis Console 4.0 (Affymetrix). Heatmap visualization, hierarchical clustering, and similarity heatmap analysis were performed using Morpheus (Broad Institute, Boston, MA, USA; https://software.broadinstitute.org/GENE-E/), and ranked by t-test statistics (p < 0.05). Violin plot visualization was generated with Z-score using GraphPad Prism v8.0 (GraphPad Software, La Jolla California USA). Gene ontology was performed by using the Database for Annotation, Visualization and Integrated Discovery (DAVID; https://david.ncifcrf.gov/) v6.8 with modified Fisher’s exact test (p < 0.05)39 and was visualized using GraphPad Prism software. GSEA and leading-edge analysis was performed using GSEA3.0 (Broad Institute, Boston, MA, USA; http://software.broadinstitute.org/gsea)40. Altanalyzer was used for collection of marker genes from expression profiles of VgatECKO endothelial cells and neurons41. Comparative Toxicogenomics Database (CTD; http://ctdbase.org/tools/) analysis (p < 0.01) was performed to categorize genes into corresponding diseases42. Cytoscape software (v. 3.7.1) was used to network the gene-disease relationship43.
Quantitative real-time PCR
RT was performed by using iScript Reverse Transcription Supermix kit (Bio-Rad). PCR reactions were run on a CFX96 Touch Real Time PCR (Bio-Rad) with SsoAdvanced™ Universal SYBR® Green Supermix (Bio-Rad). Primers for qPCR (Cldn2, Dlx1, Dlx5, Etv5, Gabrb1, Gabrg2, Gabra3, Gad2, Gapdh, Itgb3, Lhx1, Lhx6, Mef2c, Nkx2.1, Nkx2.2, Nrp1, VegfA, Wnt10a, Wnt10b) were obtained from Thermo Fisher Scientific. The housekeeping gene Gapdh was used as a reference. The relative gene expression among different samples and subsequent fold increase in Vgatfl/fl versus VgatECKO endothelial cells or GABAergic neurons was determined according to published methodology44.
Statistical analysis
Statistical significance of differences between groups was analyzed by two-tailed Student’s t test (Prism; GraphPad software) and has been noted in individual figure legends. Significance was reported at p < 0.05.
Data availability
The authors will make the VgatECKO mouse model, data and associated protocols available upon request.
References
Egawa, K. & Fukuda, A. Pathophysiological power of improper tonic GABA(A) conductances in mature and immature models. Front Neural Circuits 7, 170 (2013).
Wang, D. D. & Kriegstein, A. R. Defining the role of GABA in cortical development. J Physiol 587, 1873–1879 (2009).
Varju, P., Katarova, Z., Madarasz, E. & Szabo, G. GABA signalling during development: new data and old questions. Cell Tissue Res 305, 239–246 (2001).
Represa, A. & Ben-Ari, Y. Trophic actions of GABA on neuronal development. Trends Neurosci 28, 278–283 (2005).
Treiman, D. M. GABAergic mechanisms in epilepsy. Epilepsia 42(Suppl 3), 8–12 (2001).
Marin, O. Interneuron dysfunction in psychiatric disorders. Nat Rev Neurosci 13, 107–120 (2012).
Levitt, P., Eagleson, K. L. & Powell, E. M. Regulation of neocortical interneuron development and the implications for neurodevelopmental disorders. Trends Neurosci 27, 400–406 (2004).
Lewis, D. A., Hashimoto, T. & Volk, D. W. Cortical inhibitory neurons and schizophrenia. Nat Rev Neurosci 6, 312–324 (2005).
Lewis, D. A. & Levitt, P. Schizophrenia as a disorder of neurodevelopment. Annu Rev Neurosci 25, 409–432 (2002).
Holmes, G. L. & Ben-Ari, Y. The neurobiology and consequences of epilepsy in the developing brain. Pediatr Res 49, 320–325 (2001).
Sanacora, G., Mason, G. F. & Krystal, J. H. Impairment of GABAergic transmission in depression: new insights from neuroimaging studies. Crit Rev Neurobiol 14, 23–45 (2000).
Li, S. et al. Endothelial cell-derived GABA signaling modulates neuronal migration and postnatal behavior. Cell Res 28, 221–248 (2018).
Won, C. et al. Autonomous vascular networks synchronize GABA neuron migration in the embryonic forebrain. Nat Commun 4, 2149 (2013).
Kumar, T.P. & Vasudevan, A. Isolation and culture of endothelial cells from the embryonic forebrain. J Vis Exp, e51021 (2014).
Franchi, S. A. et al. A Method to Culture GABAergic Interneurons Derived from the Medial Ganglionic Eminence. Front Cell Neurosci 11, 423 (2017).
Pozas, E. & Ibanez, C. F. GDNF and GFRalpha1 promote differentiation and tangential migration of cortical GABAergic neurons. Neuron 45, 701–713 (2005).
Miller, J. R. The Wnts. Genome Biol 3, REVIEWS3001 (2002).
Ben-Zvi, A. et al. Mfsd2a is critical for the formation and function of the blood-brain barrier. Nature 509, 507–511 (2014).
Turner, J. R., Buschmann, M. M., Romero-Calvo, I., Sailer, A. & Shen, L. The role of molecular remodeling in differential regulation of tight junction permeability. Semin Cell Dev Biol 36, 204–212 (2014).
Farber, M. J., Rizaldy, R. & Hildebrand, J. D. Shroom2 regulates contractility to control endothelial morphogenesis. Mol Biol Cell 22, 795–805 (2011).
Bruhl, T. et al. Homeobox A9 transcriptionally regulates the EphB4 receptor to modulate endothelial cell migration and tube formation. Circ Res 94, 743–751 (2004).
Fan, C. et al. Novel roles of GATA1 in regulation of angiogenic factor AGGF1 and endothelial cell function. J Biol Chem 284, 23331–23343 (2009).
Crandall, J. E. et al. Dopamine receptor activation modulates GABA neuron migration from the basal forebrain to the cerebral cortex. J Neurosci 27, 3813–3822 (2007).
Herzog, B., Pellet-Many, C., Britton, G., Hartzoulakis, B. & Zachary, I. C. VEGF binding to NRP1 is essential for VEGF stimulation of endothelial cell migration, complex formation between NRP1 and VEGFR2, and signaling via FAK Tyr407 phosphorylation. Mol Biol Cell 22, 2766–2776 (2011).
Goncalves, A., Ambrosio, A. F. & Fernandes, R. Regulation of claudins in blood-tissue barriers under physiological and pathological states. Tissue Barriers 1, e24782 (2013).
Du, T., Xu, Q., Ocbina, P. J. & Anderson, S. A. NKX2.1 specifies cortical interneuron fate by activating Lhx6. Development 135, 1559–1567 (2008).
Nord, A. S., Pattabiraman, K., Visel, A. & Rubenstein, J. L. R. Genomic perspectives of transcriptional regulation in forebrain development. Neuron 85, 27–47 (2015).
Price, M. et al. Regional expression of the homeobox gene Nkx-2.2 in the developing mammalian forebrain. Neuron 8, 241–255 (1992).
Fontanet, P. A., Rios, A. S., Alsina, F. C., Paratcha, G. & Ledda, F. Pea3 Transcription Factors, Etv4 and Etv5, Are Required for Proper Hippocampal Dendrite Development and Plasticity. Cereb Cortex 28, 236–249 (2018).
Haydar, T. F., Wang, F., Schwartz, M. L. & Rakic, P. Differential modulation of proliferation in the neocortical ventricular and subventricular zones. J Neurosci 20, 5764–5774 (2000).
Licheri, V. et al. Plasticity of GABAA Receptors during Pregnancy and Postpartum Period: From Gene to Function. Neural plasticity 2015, 170435 (2015).
Schlaeger, T. M. et al. Uniform vascular-endothelial-cell-specific gene expression in both embryonic and adult transgenic mice. Proceedings of the National Academy of Sciences of the United States of America 94, 3058–3063 (1997).
Koni, P. A. et al. Conditional vascular cell adhesion molecule 1 deletion in mice: impaired lymphocyte migration to bone marrow. The Journal of experimental medicine 193, 741–754 (2001).
Li, S., Haigh, K., Haigh, J. J. & Vasudevan, A. Endothelial VEGF sculpts cortical cytoarchitecture. J Neurosci 33, 14809–14815 (2013).
Vasudevan, A., Long, J. E., Crandall, J. E., Rubenstein, J. L. & Bhide, P. G. Compartment-specific transcription factors orchestrate angiogenesis gradients in the embryonic brain. Nat Neurosci 11, 429–439 (2008).
Ritchie, M. E. et al. limma powers differential expression analyses for RNA-sequencing and microarray studies. Nucleic Acids Res 43, e47 (2015).
Gautier, L., Cope, L., Bolstad, B. M. & Irizarry, R. A. affy–analysis of Affymetrix GeneChip data at the probe level. Bioinformatics 20, 307–315 (2004).
Gentleman, R. C. et al. Bioconductor: open software development for computational biology and bioinformatics. Genome Biol 5, R80 (2004).
Jiao, X. et al. DAVID-WS: a stateful web service to facilitate gene/protein list analysis. Bioinformatics 28, 1805–1806 (2012).
Subramanian, A. et al. Gene set enrichment analysis: a knowledge-based approach for interpreting genome-wide expression profiles. Proc Natl Acad Sci USA 102, 15545–15550 (2005).
Emig, D. et al. AltAnalyze and DomainGraph: analyzing and visualizing exon expression data. Nucleic Acids Res 38, W755–762 (2010).
Davis, A. P. et al. The Comparative Toxicogenomics Database’s 10th year anniversary: update 2015. Nucleic Acids Res 43, D914–920 (2015).
Shannon, P. et al. Cytoscape: a software environment for integrated models of biomolecular interaction networks. Genome Res 13, 2498–2504 (2003).
Livak, K. J. & Schmittgen, T. D. Analysis of relative gene expression data using real-time quantitative PCR and the 2(−Delta Delta C(T)) Method. Methods 25, 402–408 (2001).
Acknowledgements
This work was supported by awards from the National Institute of Mental Health (R01MH110438) and National Institute of Neurological Disorders and Stroke (R01NS100808) to AV.
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A.V. conceived the study; Y.K.C. and A.V. designed experiments; Y.K.C. performed dissections, culture experiments, gene expression profifile analysis and quantitative real-time P.C.R.; Y.K.C. and A.V. analyzed data, prepared figures and wrote the manuscript.
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Choi, Y.K., Vasudevan, A. Mechanistic insights into autocrine and paracrine roles of endothelial GABA signaling in the embryonic forebrain. Sci Rep 9, 16256 (2019). https://doi.org/10.1038/s41598-019-52729-x
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DOI: https://doi.org/10.1038/s41598-019-52729-x
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