Kamon Sanada

Serine 732 Phosphorylation of FAK by Cdk5 Is Important for Microtubule Organization, Nuclear Movement, and Neuronal Migration

The serine/threonine kinase Cdk5 plays an essential role in neuronal positioning during corticogenesis, but the underlying mechanisms are unknown. In nonneuronal cells, the tyrosine kinase FAK is a major regulator of cell motility through focal adhesions. It is unclear whether FAK plays a role in brain development. Here, we show that FAK phosphorylation by Cdk5 at S732 is important for microtubule organization, nuclear movement, and neuronal migration. In cultured neurons, S732-phosphorylated FAK is enriched along a centrosome-associated microtubule fork that abuts the nucleus. Overexpression of the nonphosphorylatable mutant FAK S732A results in disorganization of the microtubule fork and impairment of nuclear movement in vitro, and neuronal positioning defects in vivo. These observations are reminiscent of what is seen in the Cdk5-deficient mice. Taken together, these results suggest that Cdk5 phosphorylation of FAK is critical for neuronal migration through regulation of a microtubule fork important for nuclear translocation.

G Protein βγ Subunits and AGS3 Control Spindle Orientation and Asymmetric Cell Fate of Cerebral Cortical Progenitors

Neurons in the developing mammalian brain are generated from progenitor cells in the proliferative ventricular zone, and control of progenitor division is essential to produce the correct number of neurons during neurogenesis. Here we establish that Gbetagamma subunits of heterotrimeric G proteins are required for proper mitotic-spindle orientation of neural progenitors in the developing neocortex. Interfering with Gbetagamma function in progenitors causes a shift in spindle orientation from apical-basal divisions to planar divisions. This results in hyperdifferentiation of progenitors into neurons as a consequence of both daughter cells adopting a neural fate instead of the normal asymmetric cell fates. Silencing AGS3, a nonreceptor activator of Gbetagamma, results in defects similar to the impairment of Gbetagamma, providing evidence that AGS3-Gbetagamma signaling in progenitors regulates apical-basal division and asymmetric cell-fate decisions. Furthermore, our observations indicate that the cell-fate decision of daughter cells is coupled to mitotic-spindle orientation in progenitors.

Disabled-1-Regulated Adhesion of Migrating Neurons to Radial Glial Fiber Contributes to Neuronal Positioning during Early Corticogenesis

Disabled-1 regulates laminar organization in the developing mammalian brain. Although mutation of the disabled-1 gene in scrambler mice results in abnormalities in neuronal positioning, migratory behavior linked to Disabled-1 signaling is not completely understood. Here we show that newborn neurons in the scrambler cortex remain attached to the process of their parental radial glia during the entire course of radial migration, whereas wild-type neurons detach from the glial fiber in the later stage of migration. This abnormal neuronal-glial adhesion is highly linked to the positional abnormality of scrambler neurons and depends intrinsically on Disabled-1 Tyr220 and Tyr232, potential phosphorylation sites during corticogenesis. Importantly, phosphorylation at those sites regulates alpha3 integrin levels, which is critical for the timely detachment of migrating neurons from radial glia. Altogether, these results outline the molecular mechanism by which Disabled-1 signaling controls the adhesive property of neurons to radial glia, thereby maintaining proper neuronal positioning during corticogenesis.

Cep120 and TACCs Control Interkinetic Nuclear Migration and the Neural Progenitor Pool

Centrosome- and microtubule-associated proteins have been shown to be important for maintaining the neural progenitor pool during neocortical development by regulating the mitotic spindle. It remains unclear whether these proteins may control neurogenesis by regulating other microtubule-dependent processes such as nuclear migration. Here, we identify Cep120, a centrosomal protein preferentially expressed in neural progenitors during neocortical development. We demonstrate that silencing Cep120 in the developing neocortex impairs both interkinetic nuclear migration (INM), a characteristic pattern of nuclear movement in neural progenitors, and neural progenitor self-renewal. Furthermore, we show that Cep120 interacts with transforming acidic coiled-coil proteins (TACCs) and that silencing TACCs also causes defects in INM and neural progenitor self-renewal. Our data suggest a critical role for Cep120 and TACCs in both INM and neurogenesis. We propose that sustaining INM may be a mechanism by which microtubule-regulating proteins maintain the neural progenitor pool during neocortical development.

Doublecortin-like Kinase Controls Neurogenesis by Regulating Mitotic Spindles and M Phase Progression

The mechanisms controlling neurogenesis during brain development remain relatively unknown. Through a differential protein screen with developmental versus mature neural tissues, we identified a group of developmentally enriched microtubule-associated proteins (MAPs) including doublecortin-like kinase (DCLK), a protein that shares high homology with doublecortin (DCX). DCLK, but not DCX, is highly expressed in regions of active neurogenesis in the neocortex and cerebellum. Through a dynein-dependent mechanism, DCLK regulates the formation of bipolar mitotic spindles and the proper transition from prometaphase to metaphase during mitosis. In cultured cortical neural progenitors, DCLK RNAi Lentivirus disrupts the structure of mitotic spindles and the progression of M phase, causing an increase of cell-cycle exit index and an ectopic commitment to a neuronal fate. Furthermore, both DCLK gain and loss of function in vivo specifically promote a neuronal identity in neural progenitors. These data provide evidence that DCLK controls mitotic division by regulating spindle formation and also determines the fate of neural progenitors during cortical neurogenesis.

Layering defect in p35 deficiency is linked to improper neuronal-glial interaction in radial migration

Several genes essential for neocortical layering have been identified in recent years, but their precise roles in this process remain to be elucidated. Mice deficient in p35—an activator of cyclin-dependent kinase 5 (Cdk5)—are characterized by a neocortex that has inverted layering. To decipher the physiological mechanisms that underlie this defect, we compared time-lapse recordings between p35−/− and wild-type cortical slices. In the p35−/− neocortex, the classic modes of radial migration—somal translocation and locomotion—were largely replaced by a distinct mode of migration: branched migration. Branched migration is cell-autonomous, associated with impaired neuronal-glial interaction and rare in neurons of scrambler mice, which are deficient in Dab1. Hence, our findings suggest that inside-out layering requires distinct functions of Reelin and p35/Cdk5 signaling, with the latter being important for proper glia-guided migration.

A NUDEL-dependent mechanism of neurofilament assembly regulates the integrity of CNS neurons

The cytoskeleton controls the architecture and survival of central nervous system (CNS) neurons by maintaining the stability of axons and dendrites. Although neurofilaments (NFs) constitute the main cytoskeletal network in these structures, the mechanism that underlies subunit incorporation into filaments remains a mystery. Here we report that NUDEL, a mammalian homologue of the Aspergillus nidulans nuclear distribution molecule NudE, is important for NF assembly, transport and neuronal integrity. NUDEL facilitates the polymerization of NFs through a direct interaction with the NF light subunit (NF-L). Knockdown of NUDEL by RNA interference (RNAi) in a neuroblastoma cell line, primary cortical neurons or post-natal mouse brain destabilizes NF-L and alters the homeostasis of NFs. This results in NF abnormalities and morphological changes reminiscent of neurodegeneration. Furthermore, variations in levels of NUDEL correlate with disease progression and NF defects in a mouse model of neurodegeneration. Thus, NUDEL contributes to the integrity of CNS neurons by regulating NF assembly.

LKB1 Regulates Neuronal Migration and Neuronal Differentiation in the Developing Neocortex through Centrosomal Positioning

The cerebral cortex is formed through the coordination of highly organized cellular processes such as neuronal migration and neuronal maturation. Polarity establishment of neurons and polarized regulation of the neuronal cytoskeleton are essential for these events. Here we find that LKB1, the closest homolog of the Caenorhabditis elegans polarity protein Par4, is expressed in the developing neocortex. Knock-down of LKB1 in migrating immature neurons impairs neuronal migration, with alteration of the centrosomal positioning and with uncoupling between the centrosome and nucleus. Furthermore, impairment of LKB1 in differentiating neurons within the cortical plate induces malpositioning of the centrosome at the basal side of the nucleus, instead of the normal apical positioning. This is accompanied with the disruption of axonal and dendritic polarity, resulting in reversed orientation of differentiating neurons. Moreover, LKB1 specifies axon and dendrites identity in vitro. Together, these observations indicate that LKB1 plays a critical role in neuronal migration and neuronal differentiation. Furthermore, we propose that proper neuronal migration and differentiation are intimately coupled to the precise control of the centrosomal positioning/movement directed by LKB1.

DYRK1A and Glycogen Synthase Kinase 3β, a Dual-Kinase Mechanism Directing Proteasomal Degradation of CRY2 for Circadian Timekeeping

ABSTRACT Circadian molecular oscillation is generated by a transcription/translation-based feedback loop in which CRY proteins play critical roles as potent inhibitors for E-box-dependent clock gene expression. Although CRY2 undergoes rhythmic phosphorylation in its C-terminal tail, structurally distinct from the CRY1 tail, little is understood about how protein kinase(s) controls the CRY2-specific phosphorylation and contributes to the molecular clockwork. Here we found that Ser557 in the C-terminal tail of CRY2 is phosphorylated by DYRK1A as a priming kinase for subsequent GSK-3β (glycogen synthase kinase 3β)-mediated phosphorylation of Ser553, which leads to proteasomal degradation of CRY2. In the mouse liver, DYRK1A kinase activity toward Ser557 of CRY2 showed circadian variation, with its peak in the accumulating phase of CRY2 protein. Knockdown of Dyrk1a caused abnormal accumulation of cytosolic CRY2, advancing the timing of a nuclear increase of CRY2, and shortened the period length of the cellular circadian rhythm. Expression of an S557A/S553A mutant of CRY2 phenocopied the effect of Dyrk1a knockdown in terms of the circadian period length of the cellular clock. DYRK1A is a novel clock component cooperating with GSK-3β and governs the Ser557 phosphorylation-triggered degradation of CRY2.

Serine phosphorylation of mCRY1 and mCRY2 by mitogen‐activated protein kinase

The circadian oscillator is composed of a transcription/translation‐based autoregulatory feedback loop in which Cryptochromes and Periods function as negative regulators for their own gene expression. Although post‐translational modifications such as phosphorylation of these regulators appear crucial for circadian time‐keeping mechanism, less is known about responsible protein kinases and their contribution to the function of the regulators. We found that mitogen‐activated protein kinase (MAPK) associates with and phosphorylates mouse Cryptochromes (mCRY1 and mCRY2). Mass spectrometry analysis identified Ser265 and Ser557 of mCRY2 to be in vitro phospho‐acceptor residues. Mutations of both the Ser residues to Ala completely abolished MAPK‐mediated mCRY2 phosphorylation, suggesting that the two residues are the principal phosphorylation sites in mCRY2. Similarly, MAPK phosphorylates mCRY1 at Ser247, a site corresponding to Ser265 of mCRY2. An effect of the Ser phosphorylation was investigated by mutating Ser247 of mCRY1 and Ser265 of mCRY2 to Asp, which resulted in attenuation of each mCRYs’ ability to inhibit BMAL1: CLOCK‐mediated transcription, whereas a similar mutation at Ser557 of mCRY2 induced no measurable change in its activity. These results illustrate a model of MAPK‐mediated negative regulation of mCRY function by phosphorylation at the specific Ser residue.