TBR1

T-box, brain, 1 is a transcription factor protein important in vertebrate embryo development. It is encoded by the TBR1 gene. This gene is also known by several other names: T-Brain 1, TBR-1, TES-56, and MGC141978. TBR1 is a member of the TBR1 subfamily of T-box family transcription factors, which share a common DNA-binding domain. Other members of the TBR1 subfamily include EOMES and TBX21. TBR1 is involved in the differentiation and migration of neurons and is required for normal brain development. TBR1 interacts with various genes and proteins in order to regulate cortical development, specifically within layer VI of the developing six-layered human cortex. Studies show that TBR1 may play a role in major neurological diseases such as Alzheimer's Disease (AD) and Parkinson's Disease (PD). TBR1 was identified in 1995 by the Nina Ireland Laboratory of Developmental Neurobiology Center at the University of California, San Francisco. The gene, initially named TES-56, was found to be largely expressed in the telencephalic vesicles of the developing forebrain of mice. The protein product of TES-56 was discovered to be homologous to the Brachyury protein, a T-box transcription factor, which plays a role in establishing symmetry during embryonic development. Thus, due to its relation to T-box genes (such as Tbx-1, Tbx-2, Tbx-3), TES-56 was renamed TBR1. The human TBR1 gene is located on the q arm of the positive strand of chromosome 2. It is 8,954 base pairs in length. TBR1 is one of the three genes that make up the TBR1 subfamily of T-box genes. The two other genes that form the TBR1 subfamily are EOMES (also known as TBR2) and TBX21 (also known as T-BET). TBR1 is also known as T-box Brain Protein, T-Brain 1, and TES-56. The encoded protein consists of 682 amino acid residues and has a predicted molecular weight of 74,053 Da. It is composed of 6 exons. Tbr1 is a protein, called a transcription factor, that binds to DNA and regulates the transcription of genes into mRNA. It is expressed in postmitotic projection neurons and is critical for normal brain development. Tbr1 has been shown to be expressed in the developing olfactory bulb. Tbr1 has also been observed in the developing cerebral cortex. Tbr1 has several functions. These include involvement in the developmental process, brain development, neuronal differentiation, axon guidance, and regulation of neurons in the developing neocortex. Tbr1, along with Pax6 and Tbr2, has a role in glutamatergic projection neuron differentiation. Glutamatergic neurons make and release in an activity-dependent manner the excitatory neurotransmitter glutamate as opposed to the inhibitory neurotransmitter GABA. The transition from radial glial cells to postmitotic projection neurons occurs in three steps, each associated with one of the aforementioned transcription factors. The first starts out with the expression of Pax6 in radial glial cells found primarily at the ventricular surface. In the next step, Pax6 is downregulated and Tbr2 is expressed as the cell differentiates into an intermediate progenitor cell. Likewise, in the final step, Tbr2 is extremely downregulated to undetectable levels as Tbr1 signals the transition into a postmitotic projection neuron. In cultured hippocampal neurons, Tbr1 and calcium/calmodulin-dependent serine kinase (CASK) interact with CASK-interacting nucleosome assembly protein (CINAP) to modulate the expression of N-methyl-D-aspartic acid receptor subunit 2b (NR2b) by acting on its promoter region. Tbr1 is a transcriptional regulator of NR1, an essential subunit of NMDA receptors. Cells that stop dividing (post-mitotic) and differentiate into neurons early in cortical development are important in laying the groundwork on which other developing neurons can be guided to their proper destination. Tbr1 aids in neuronal migration in the early development of the cerebral cortex. It is largely expressed in post-mitotic neurons of the preplate, which forms a foundation upon which neurons are able to grow and move. As a transcription factor, Tbr1 modulates the expression of RELN, which encodes the Reln protein that forms part of the extracellular matrix of cells. Thus, through regulation of Reln expression, Tbr1 regulates the formation of the matrix through which neurons migrate. Without Tbr1, neurons fail to migrate properly.