Daniel E. Lysko scite author profile

Cell migration is required for normal embryonic development, yet how cells navigate complex paths while integrating multiple guidance cues remains poorly understood. During brain development, interneurons migrate from the ventral ganglionic eminence to the cerebral cortex within several migratory streams. They must exit these streams to invade the cortical plate. While SDF1 (stromal cell-derived factor-1) signaling is necessary for normal interneuron stream migration, how they switch from tangential stream migration to invade the cortical plate is unknown. Here, we demonstrate that SDF1 signaling reduces interneuron branching frequency by reducing cAMP levels via a G i signaling pathway using an in vitro mouse explant system, resulting in the maintenance of stream migration. Blocking SDF1 signaling or increasing branching frequency results in stream exit and cortical plate invasion in mouse brain slices. These data support a novel model to understand how migrating interneurons switch from tangential migration to invade the cortical plate in which reducing SDF signaling increases leading process branching and slows the migration rate, permitting migrating interneurons to sense cortically directed guidance cues.

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SDF1 Reduces Interneuron Leading Process Branching through Dual Regulation of Actin and Microtubules

Lysko

Putt

Golden

2014

J. Neurosci.

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Normal cerebral cortical function requires a highly ordered balance between projection neurons and interneurons. During development these two neuronal populations migrate from distinct progenitor zones to form the cerebral cortex, with interneurons originating in the more distant ganglionic eminences. Moreover, deficits in interneurons have been linked to a variety of neurodevelopmental disorders underscoring the importance of understanding interneuron development and function. We, and others, have identified SDF1 signaling as one important modulator of interneuron migration speed and leading process branching behavior in mice, although how SDF1 signaling impacts these behaviors remains unknown. We previously found SDF1 inhibited leading process branching while increasing the rate of migration. We have now mechanistically linked SDF1 modulation of leading process branching behavior to a dual regulation of both actin and microtubule organization. We find SDF1 consolidates actin at the leading process tip by de-repressing calpain protease and increasing proteolysis of branched-actin-supporting cortactin. Additionally, SDF1 stabilizes the microtubule array in the leading process through activation of the microtubule-associated protein doublecortin (DCX). DCX stabilizes the microtubule array by bundling microtubules within the leading process, reducing branching. These data provide mechanistic insight into the regulation of interneuron leading process dynamics during neuronal migration in mice and provides insight into how cortactin and DCX, a known human neuronal migration disorder gene, participate in this process.

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Unmyelinated sensory neurons use Neuregulin signals to promote myelination of interneurons in the CNS

Lysko

Talbot²

2022

Cell Reports

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Partial loss‐of‐function variant in neuregulin 1 identified in family with heritable peripheral neuropathy

et al. 2022

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Neuregulin 1 signals are essential for the development and function of Schwann cells, which form the myelin sheath on peripheral axons. Disruption of myelin in the peripheral nervous system can lead to peripheral neuropathy, which is characterized by reduced axonal conduction velocity and sensorimotor deficits. Charcot‐Marie‐Tooth disease is a group of heritable peripheral neuropathies that may be caused by variants in nearly 100 genes. Despite the evidence that Neuregulin 1 is essential for many aspects of Schwann cell development, previous studies have not reported variants in the neuregulin 1 gene (NRG1) in patients with peripheral neuropathy. We have identified a rare missense variant in NRG1 that is homozygous in a patient with sensory and motor deficits consistent with mixed axonal and de‐myelinating peripheral neuropathy. Our in vivo functional studies in zebrafish indicate that the patient variant partially reduces NRG1 function. This study tentatively suggests that variants at the NRG1 locus may cause peripheral neuropathy and that NRG1 should be investigated in families with peripheral neuropathy of unknown cause.

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Unmyelinated neurons use Neuregulin signals to promote myelination of neighboring neurons in the CNS

Lysko

Talbot

2022

Preprint

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The signaling mechanisms neurons use to modulate myelination of circuits in the central nervous system (CNS) are only partly understood. Through analysis of isoform-specific neuregulin1 (nrg1) mutants, we identify nrg1 type II as an important regulator of myelination in the zebrafish CNS, required for normal myelination of two classes of spinal cord neurons. Surprisingly, nrg1 type II reporter expression is prominent in unmyelinated Rohon-Beard (RB) sensory neurons, while myelination of interneurons controlling the escape response circuit is reduced in nrg1 type II mutants. Cell type-specific loss-of-function studies indicate that nrg1 type II is required in RB neurons to signal to other neurons, not oligodendrocytes, to modulate spinal cord myelination. Together, our data support a model in which unmyelinated neurons express Nrg1 type II proteins to regulate myelination of circuit partners, a mode of action that may coordinate function of circuits in the CNS involving both unmyelinated and myelinated neurons.

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Daniel E. Lysko

SDF1 Regulates Leading Process Branching and Speed of Migrating Interneurons

SDF1 Reduces Interneuron Leading Process Branching through Dual Regulation of Actin and Microtubules

Unmyelinated sensory neurons use Neuregulin signals to promote myelination of interneurons in the CNS

Partial loss‐of‐function variant in neuregulin 1 identified in family with heritable peripheral neuropathy

Unmyelinated neurons use Neuregulin signals to promote myelination of neighboring neurons in the CNS

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