Itaru Imayoshi

Roles of continuous neurogenesis in the structural and functional integrity of the adult forebrain

Neurogenesis occurs continuously in the forebrain of adult mammals, but the functional importance of adult neurogenesis is still unclear. Here, using a genetic labeling method in adult mice, we found that continuous neurogenesis results in the replacement of the majority of granule neurons in the olfactory bulb and a substantial addition of granule neurons to the hippocampal dentate gyrus. Genetic ablation of newly formed neurons in adult mice led to a gradual decrease in the number of granule cells in the olfactory bulb, inhibition of increases in the granule cell number in the dentate gyrus and impairment of behaviors in contextual and spatial memory, which are known to depend on hippocampus. These results suggest that continuous neurogenesis is required for the maintenance and reorganization of the whole interneuron system in the olfactory bulb, the modulation and refinement of the existing neuronal circuits in the dentate gyrus and the normal behaviors involved in hippocampal-dependent memory.

Essential Roles of Notch Signaling in Maintenance of Neural Stem Cells in Developing and Adult Brains

Activation of Notch signaling induces the expression of transcriptional repressor genes such as Hes1, leading to repression of proneural gene expression and maintenance of neural stem/progenitor cells. However, a requirement for Notch signaling in the telencephalon was not clear, because in Hes1;Hes3;Hes5 triple-mutant mice, neural stem/progenitor cells are depleted in most regions of the developing CNS, but not in the telencephalon. Here, we investigated a role for Notch signaling in the telencephalon by generating tamoxifen-inducible conditional knock-out mice that lack Rbpj, an intracellular signal mediator of all Notch receptors. When Rbpj was deleted in the embryonic brain, almost all telencephalic neural stem/progenitor cells prematurely differentiated into neurons and were depleted. When Rbpj was deleted in the adult brain, all neural stem cells differentiated into transit-amplifying cells and neurons. As a result, neurogenesis increased transiently, but 3 months later all neural stem cells were depleted and neurogenesis was totally lost. These results indicated an absolute requirement of Notch signaling for the maintenance of neural stem cells and a proper control of neurogenesis in both embryonic and adult brains.

Dynamic Notch signaling in neural progenitor cells and a revised view of lateral inhibition

In the developing mammalian nervous system, neural progenitor cells first express the Notch effector Hes1 at variable levels and then proneural genes and Notch ligands in salt-and-pepper patterns. Recent real-time imaging analysis indicates that Hes1 expression in these cells oscillates with a period of about 2–3 h. Furthermore, the proneural gene Neurogenin-2 (Ngn2) and the Notch ligand gene Deltalike-1 (Dll1) are expressed cyclically in neural progenitor cells under the control of Hes1 oscillation but are expressed continuously in postmitotic neurons, which lose Hes1 expression. Hes1-driven Ngn2 and Dll1 oscillations seem to be advantageous for maintenance of a group of cells in an undifferentiated state by mutual activation of Notch signaling. This dynamic mode of gene expression would require a revision of the traditional view of how Notch-mediated lateral inhibition operates in the developing mammalian nervous system.

Oscillatory Control of Factors Determining Multipotency and Fate in Mouse Neural Progenitors

Oscillation Stabilizes the Progenitor State Transcription factors regulate fate choice between different neural lineages, but the same transcription factors are also expressed in neural progenitor cells. Imayoshi et al. (p. 1203, published online 31 October) analyzed the details of expression of several transcription factors in mouse neural cells. In neural progenitor cells, several different transcription factors were expressed in an oscillatory manner, whereas differentiated neurons stably expressed a single lineage-specific factor. During neural development, the differentiated state correlates with sustained expression of a single fate-determination factor. The basic helix-loop-helix transcription factors Ascl1/Mash1, Hes1, and Olig2 regulate fate choice of neurons, astrocytes, and oligodendrocytes, respectively. These same factors are coexpressed by neural progenitor cells. Here, we found by time-lapse imaging that these factors are expressed in an oscillatory manner by mouse neural progenitor cells. In each differentiation lineage, one of the factors becomes dominant. We used optogenetics to control expression of Ascl1 and found that, although sustained Ascl1 expression promotes neuronal fate determination, oscillatory Ascl1 expression maintains proliferating neural progenitor cells. Thus, the multipotent state correlates with oscillatory expression of several fate-determination factors, whereas the differentiated state correlates with sustained expression of a single factor.

The cyclic gene Hes1 contributes to diverse differentiation responses of embryonic stem cells

Stem cells do not all respond the same way, but the mechanisms underlying this heterogeneity are not well understood. Here, we found that expression of Hes1 and its downstream genes oscillate in mouse embryonic stem (ES) cells. Those expressing low and high levels of Hes1 tended to differentiate into neural and mesodermal cells, respectively. Furthermore, inactivation of Hes1 facilitated neural differentiation more uniformly at earlier time. Thus, Hes1-null ES cells display less heterogeneity in both the differentiation timing and fate choice, suggesting that the cyclic gene Hes1 contributes to heterogeneous responses of ES cells even under the same environmental conditions.

Hes genes and neurogenin regulate non-neural versus neural fate specification in the dorsal telencephalic midline

The choroid plexus in the brain is unique because it is a non-neural secretory tissue. It secretes the cerebrospinal fluid and functions as a blood-brain barrier, but the precise mechanism of specification of this non-neural tissue has not yet been determined. Using mouse embryos and lineage-tracing analysis, we found that the prospective choroid plexus region initially gives rise to Cajal-Retzius cells, specialized neurons that guide neuronal migration. Inactivation of the bHLH repressor genes Hes1, Hes3 and Hes5 upregulated expression of the proneural gene neurogenin 2 (Ngn2) and prematurely depleted Bmp-expressing progenitor cells, leading to enhanced formation of Cajal-Retzius cells and complete loss of choroid plexus epithelial cells. Overexpression of Ngn2 had similar effects. These data indicate that Hes genes promote specification of the fate of choroid plexus epithelial cells rather than the fate of Cajal-Retzius cells by antagonizing Ngn2 in the dorsal telencephalic midline region, and thus this study has identified a novel role for bHLH genes in the process of deciding which cells will have a non-neural versus a neural fate.

Continuous neurogenesis in the adult forebrain is required for innate olfactory responses

Although the functional significance of adult neurogenesis in hippocampal-dependent learning and memory has been well documented, the role of such neurogenesis in olfactory activity is rather obscure. To understand the significance of adult neurogenesis in olfactory functions, we genetically ablated newly born neurons by using tamoxifen-treated Nestin-CreERT2;neuron-specific enolase-diphtheria toxin fragment A (NSE-DTA) mice. In these mice, tamoxifen-inducible Cre recombinase allows the NSE (Eno2) gene to drive DTA expression in differentiating neurons, leading to the efficient ablation of newly born neurons in the forebrain. These mutant mice were capable of discriminating odors as competently as control mice. Strikingly, although control and mutant mice frequently showed freezing behaviors to a fox scent, a predator odor, mutant mice approached this odor when they were conditioned to associate the odor with a reward, whereas control mice did not approach the odor. Furthermore, although mutant males and females showed normal social recognition behaviors to other mice of a different sex, mutant males displayed deficits in male–male aggression and male sexual behaviors toward females, whereas mutant females displayed deficits in fertility and nurturing, indicating that sex-specific activities, which are known to depend on olfaction, are impaired. These results suggest that continuous neurogenesis is required for predator avoidance and sex-specific responses that are olfaction dependent and innately programmed.

bHLH Factors in Self-Renewal, Multipotency, and Fate Choice of Neural Progenitor Cells

Multipotent neural progenitor cells (NPCs) undergo self-renewal while producing neurons, astrocytes, and oligodendrocytes. These processes are controlled by multiple basic helix-loop-helix (bHLH) fate determination factors, which exhibit different functions by posttranslational modifications. Furthermore, depending on the expression dynamics, each bHLH factor seems to have two contradictory functions, promoting NPC proliferation and cell-cycle exit for differentiation. The oscillatory expression of multiple bHLH factors correlates with the multipotent and proliferative state, whereas sustained expression of a selected single bHLH factor regulates the fate determination. bHLH factors also regulate direct reprogramming of adult somatic cells into neurons and oligodendrocytes. Thus, bHLH factors play key roles in development and regeneration of the nervous system. Here, we review versatile functions of bHLH factors, focusing on telencephalic development.

High Levels of Cre Expression in Neuronal Progenitors Cause Defects in Brain Development Leading to Microencephaly and Hydrocephaly

Hydrocephalus is a common and variegated pathology often emerging in newborn children after genotoxic insults during pregnancy (Hicks and D’Amato, 1980). Cre recombinase is known to have possible toxic effects that can compromise normal cell cycle and survival. Here we show, by using three independent nestin Cre transgenic lines, that high levels of Cre recombinase expression into the nucleus of neuronal progenitors can compromise normal brain development. The transgenics analyzed are the nestin Cre Balancer (Bal1) line, expressing the Cre recombinase with a nuclear localization signal, and two nestin CreERT2 (Cre recombinase fused with a truncated estrogen receptor) mice lines with different levels of expression of a hybrid CreERT2 recombinase that translocates into the nucleus after tamoxifen treatment. All homozygous Bal1 nestin Cre embryos displayed reduced neuronal proliferation, increased aneuploidy and cell death, as well as defects in ependymal lining and lamination of the cortex, leading to microencephaly and to a form of communicating hydrocephalus. An essentially overlapping phenotype was observed in the two nestin CreERT2 transgenic lines after tamoxifen mediated-CreERT2 translocation into the nucleus. Neither tamoxifen-treated wild-type nor nestin CreERT2 oil-treated control mice displayed these defects. These results indicate that some forms of hydrocephalus may derive from a defect in neuronal precursors proliferation. Furthermore, they underscore the potential risks for developmental studies of high levels of nuclear Cre in neurogenic cells.

Dynamic regulation of Notch signaling in neural progenitor cells

In the developing nervous system, differentiating neurons express Delta and activate Notch signaling in their neighboring cells. As a result of Notch activation, neuronal differentiation is inhibited in neighboring cells and they remain neural progenitor cells. Thus, differentiation of neurons and maintenance of neural progenitor cells are well balanced owing to Notch signaling. Recent studies revealed that Notch signaling is under the control of more complex and dynamic regulation than previously thought, such as cell cycle dependent activation and oscillating gene expression. We discuss here recent advances in understanding how Notch signaling is regulated in the developing nervous system and what outcome each type of regulation of Notch signaling leads to. We highlight the role of Notch signaling in proliferation and differentiation of neural progenitor cells.