Although several molecules have been shown to play important roles in subtype specification of neocortical neurons, the entire mechanism involved in the specification, in particular, of upper cortical plate (UCP) neurons still remains unclear. The UCP, which is responsible for intracortical connections in the neocortex, comprises histologically, functionally, and molecularly different layer 2/3 (L2/3) and L4. Here, we report the essential interactions between two types of transcription factors, Rorb (RAR-related orphan receptor beta) and Brn1/2 (Brain-1/Brain-2), for UCP specification. We found that Brn2 expression was detected in all upper layers in the immature UCP, but was subsequently restricted to L2/3, accompanied by up-regulation of Rorb in L4, suggesting demarcation of L2/3 and L4 during cortical maturation. Rorb indeed inhibited Brn2 expression and the expression of other L2/3 characteristics, revealed by ectopic expression and knockdown studies. Moreover, this inhibition occurred through direct binding of Rorb to the Brn2 locus. Conversely, Brn1/2 also inhibited Rorb expression and the expression of several L4 characteristics. Together, these results suggest that a mutually repressive mechanism exists between Brn1/2 and Rorb expression and that the established expression of Brn1/2 and Rorb further specifies those neurons into L2/3 and L4, respectively, during UCP maturation.cerebral cortex | cell fate | transcription factor | layer formation T he mammalian neocortex consists of six anatomically distinct layers, each of which contains one or more subtype of neurons, and is characterized by a specific cell morphology, birth date, molecular identity, and connectivity to other regions of the central nervous system. The cortical plate (CP) can be categorized into two populations: lower and upper cortical plate (LCP and UCP). Neurons in the LCP, which consists of layer 5 (L5) and L6, send axons to subcortical targets such as the thalamus, pons, and spinal cord, whereas the UCP, which is known to be much thicker in primates than in rodents, is characterized by corticocortical (intracortical) connections (1-3). The UCP, in rodents, can be further divided into L2/3 and L4. Many L2/3 neurons show a typical pyramidal morphology and send axons to the contralateral cortex, whereas L4 neurons, showing a round shape and granular morphology, receive inputs from the thalamus and transmit the thalamic inputs to local cortical networks (4). Thus, although UCP neurons share at least some features (e.g., intracortical connections), there are apparent differences (e.g., long vs. local projections and cell morphologies). However, how these differences arise during development is poorly understood.Previous studies have revealed the important roles of subtype-or lineage-specific transcription factors (TFs) in the specification of different neuronal subtypes (5-11). One of the intriguing features of how TFs specify neuronal subtypes is that a crucial TF for a given subtype sometimes suppresses other subtypes (3,12). This mechan...