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In this study, the authors describe the subset of activity-regulated enhancers that modulate transcription in cultured neurons and that participate in the regulation of synaptic maturation. In addition, they demonstrate Fos binding to these enhancers is essential for this activity-dependent regulation of transcription. Experience-dependent gene transcription is required for nervous system development and function. However, the DNA regulatory elements that control this program of gene expression are not well defined. Here we characterize the enhancers that function across the genome to mediate activity-dependent transcription in mouse cortical neurons. We find that the subset of enhancers enriched for monomethylation of histone H3 Lys4 (H3K4me1) and binding of the transcriptional coactivator CREBBP (also called CBP) that shows increased acetylation of histone H3 Lys27 (H3K27ac) after membrane depolarization of cortical neurons functions to regulate activity-dependent transcription. A subset of these enhancers appears to require binding of FOS, which was previously thought to bind primarily to promoters. These findings suggest that FOS functions at enhancers to control activity-dependent gene programs that are critical for nervous system function and provide a resource of functional cis -regulatory elements that may give insight into the genetic variants that contribute to brain development and disease.

Sensory stimuli drive the maturation and function of the mammalian nervous system in part through the activation of gene expression networks that regulate synapse development and plasticity. These networks have primarily been studied in mice, and it is not known whether there are species- or clade-specific activity-regulated genes that control features of brain development and function. Here we use transcriptional profiling of human fetal brain cultures to identify an activity-dependent secreted factor, Osteocrin (OSTN), that is induced by membrane depolarization of human but not mouse neurons. We find that OSTN has been repurposed in primates through the evolutionary acquisition of DNA regulatory elements that bind the activity-regulated transcription factor MEF2. In addition, we demonstrate that OSTN is expressed in primate neocortex and restricts activity-dependent dendritic growth in human neurons. These findings suggest that, in response to sensory input, OSTN regulates features of neuronal structure and function that are unique to primates. Osteocrin is a non-neuronal secreted protein in mice that has been evolutionarily repurposed to act as a neuronal development factor in primates. Osteocrin—a factor in primate brain development Much of the research on the gene expression networks that drive brain development has been performed in mice. Relatively little is known about how expression networks in other animal groups—particularly primates, in which the cerebral cortex is expanded—might differ from the mouse model. Here, Michael Greenberg and colleagues identify a non-neuronal secreted factor in mice, Osteocrin, that may have been re-purposed evolutionarily as a neuronal development gene in primates. Osteocrin is specifically expressed in the neocortex of the humans and macaques. In mice it is enriched in bone and muscle tissues, but not in the brain.

The EphB family of receptor tyrosine kinases can signal bidirectionally and functions in a kinase-dependent and kinase-independent manner. To determine the importance of the kinase activity of EphBs for axonal guidance and synaptogenesis, the authors used a chemical genetic method and generated knock-in mice that allow the kinase activity of EphBs to be inhibited without altering kinase-independent functions of EphBs. They find that specific inhibition of EphB kinase activity had no effect on synaptogenesis, but impaired axonal guidance, thereby implicating the kinase function of EphB in one neuronal process, but not other processes that are nevertheless dependent on EphBs. EphB receptor tyrosine kinases control multiple steps in nervous system development. However, it remains unclear whether EphBs regulate these different developmental processes directly or indirectly. In addition, given that EphBs signal through multiple mechanisms, it has been challenging to define which signaling functions of EphBs regulate particular developmental events. To address these issues, we engineered triple knock-in mice in which the kinase activity of three neuronally expressed EphBs can be rapidly, reversibly and specifically blocked. We found that the tyrosine kinase activity of EphBs was required for axon guidance in vivo . In contrast, EphB-mediated synaptogenesis occurred normally when the kinase activity of EphBs was inhibited, suggesting that EphBs mediate synapse development by an EphB tyrosine kinase–independent mechanism. Taken together, our data indicate that EphBs control axon guidance and synaptogenesis by distinct mechanisms and provide a new mouse model for dissecting EphB function in development and disease.

Sensory stimuli drive the maturation and function of the mammalian nervous system in part through the activation of gene expression networks that regulate synapse development and plasticity. These networks have primarily been studied in mice, and it is not known whether there are species- or clade-specific activity-regulated genes that control features of brain development and function. Here we use transcriptional profiling of human fetal brain cultures to identify an activitydependent secreted factor, Osteocrin (OSTN), that is induced by membrane depolarization of human but not mouse neurons. We find that OSTN has been repurposed in primates through the evolutionary acquisition of DNA regulatory elements that bind the activity-regulated transcription factor MEF2. In addition, we demonstrate that OSTN is expressed in primate neocortex and restricts activity-dependent dendritic growth in human neurons. These findings suggest that, in response to sensory input, OSTN regulates features of neuronal structure and function that are unique to primates.