TBR1 Research Articles

Protection of Hippocampal Neurogenesis from Toll-Like Receptor 4-Dependent Innate Immune Activation by Ablation of Prostaglandin E 2 Receptor Subtype EP1 or EP2

Prostaglandin E2 is one of several eicosanoid products of the cyclooxygenase isozymes and is a key regulator of innate immune responses; it also possesses paracrine effects on mature neurons. The prostaglandin E2 receptor family consists of four subtypes of which EP1 and EP2 are known to be expressed by microglia. Lipopolysaccharide (LPS)-induced innate immune activation leads to the degeneration of intermediate progenitor cells (IPCs) that are destined for neuronal maturation in the hippocampal subgranular zone (SGZ); these cells can be identified by the expression of the transcription factor T-box brain gene 2 (Tbr2). Importantly, depletion of LPS-induced IPCs from the SGZ is suppressed by cyclooxygenase inhibitors. We therefore tested the hypothesis that either EP1 or EP2 is critical to LPS-induced depletion of Tbr2+ IPCs from the SGZ. Expression of either EP1 or EP2 was necessary for Toll-like receptor 4-dependent innate immune-mediated depletion of these Tbr2+ IPCs in mice. Moreover, EP1 activation was directly toxic to murine adult hippocampal progenitor cells; EP2 was not expressed by these cells. Finally, EP1 modulated the response of murine primary microglia cultures to LPS but in a manner distinct from EP2. These results indicate that prostaglandin E2 signaling via either EP1 or EP2 is largely to completely necessary for Toll-like receptor 4-dependent depletion of IPCs from the SGZ and suggest further pharmacological strategies to protect this important neurogenic niche.

Intermediate Progenitors in Adult Hippocampal Neurogenesis: Tbr2 Expression and Coordinate Regulation of Neuronal Output

Neurogenesis in the adult hippocampus is a highly regulated process that originates from multipotent progenitors in the subgranular zone (SGZ). Currently, little is known about molecular mechanisms that regulate proliferation and differentiation in the SGZ. To study the role of transcription factors (TFs), we focused on Tbr2 (T-box brain gene 2), which has been implicated previously in developmental glutamatergic neurogenesis. In adult mouse hippocampus, Tbr2 protein and Tbr2-GFP (green fluorescent protein) transgene expression were specifically localized to intermediate-stage progenitor cells (IPCs), a type of transit amplifying cells. The Tbr2+ IPCs were highly responsive to neurogenic stimuli, more than doubling after voluntary wheel running. Notably, the Tbr2+ IPCs formed cellular clusters, the average size of which (Tbr2+ cells per cluster) likewise more than doubled in runners. Conversely, Tbr2+ IPCs were selectively depleted by antimitotic drugs, known to suppress neurogenesis. After cessation of antimitotic treatment, recovery of neurogenesis was paralleled by recovery of Tbr2+ IPCs, including a transient rebound above baseline numbers. Finally, Tbr2 was examined in the context of additional TFs that, together, define a TF cascade in embryonic neocortical neurogenesis (Pax6 --> Ngn2 --> Tbr2 --> NeuroD --> Tbr1). Remarkably, the same TF cascade was found to be linked to stages of neuronal lineage progression in adult SGZ. These results suggest that Tbr2+ IPCs play a major role in the regulation of adult hippocampal neurogenesis, and that a similar transcriptional program controls neurogenesis in adult SGZ as in embryonic cerebral cortex.

MRNA expression patterns and distribution of white matter neurons in dorsolateral prefrontal cortex of depressed patients differ from those in schizophrenia patients

Background Schizophrenia, bipolar illness, and major depressive disorder have distinct presentations, but share some common symptoms. Hence, some common cellular and molecular abnormalities may be identifiable in these disorders. Methods We examined cell-specific markers in the dorsolateral prefrontal cortex of brains from 18 patients with bipolar or major depressive disorder, and 18 matched controls, using in situ hybridization histochemistry and staining for nicotinamide-dinucleotide phophate-diaphorase (NADPH). The distribution of NADPH-positive interstitial cells of the white matter and the expression of the mRNA for the 67 KD form of glutamic acid decarboxylase (GAD 67) had previously been shown to be altered in prefrontal cortex of schizophrenics. Other markers identifying glutamatergic neuronal populations were α-type II calcium/calmodulin dependent protein kinase (CAMKII-α), brain derived neurotrophic factor, (BDNF) and the putative transcription factor, T-brain–1 (TBR1). Results Expression of GAD 67 and the distribution of NADPH-positive cells in the white matter were not significantly altered in the dorsolateral prefrontal cortex of depressed subjects. Expression of CAMKII-α and TBR1 mRNAs was significantly increased in bipolar patients but not in major depressed patients, and there was a trend toward reduced BDNF expression in both groups. Abnormal patterns of gene expression and neuronal distribution in schizophrenics are markedly different from those in depressed patients. Conclusions The findings that TBR1 and CAMKII-α expression is increased only in bipolar patients suggests abnormalities of specific genes related to a major cortical cell type and its connectivity.

Genomic organization, sequence and chromosomal localization of the mouse Tbr2 gene and a comparative study with Tbr1

Members of the T-box family are known to play critical roles in the embryonic development of most animal species. Recently, we have isolated its new mammalian member, Tbr2, from mouse embryonic brain. We have also shown that the expression patterns of Tbr2 and the closely related Tbr1 appear to be reciprocal in the developing brain; Tbr2 is expressed in mesencephalon and rhombencephalon, but expression of Tbr1 is restricted to telencephalon. To investigate possible structural and functional relationships of Tbr2 and other T-box containing genes, we analyzed genomic organization of the murine Tbr2 gene. The Tbr2 gene is composed of six exons (1353, 155, 122, 159, 62 and 1035 bp), and five introns (920, 643, 602, 85 and 2036 bp). This exon/intron organization is very similar to that of Tbr1. We also analyzed the 3.9 kb sequence of the 5′ promoter region flanking the Tbr2 gene and the corresponding region of the Tbr1 gene. The sites for Brn-2 and Tst-1 were found in the promoter of Tbr2 but not Tbr1. On the contrary, there were eight HNF-3β binding sites in the Tbr1 gene promoter but only three in the Tbr2 promoter. The differential presence of putative binding sites for these brain-specific transcription factors may explain the reciprocal expression of Tbr1 and Tbr2. Furthermore, a single chromosomal locus for mouse Tbr2 was assigned to 9F3 by fluorescence in-situ hybridization 1.