#RadialGlia have long basal fibers that end in basal endfeet. @LiWang_neuro & @Kriegsteinlabr explore a
#PLOSBiology study showing that non-muscle
#myosins control endfoot integrity to regulate interneuron organization. Primer
https://plos.io/3J0mRZ5 Paper
https://plos.io/3Yb599J 
Non-muscle myosins control the integrity of cortical radial glial endfeet
Radial glial cells, the stem cells of the cerebral cortex, extend a long basal fiber that ends in basal endfeet. This Primer explores the implications of a new PLOS Biology study revealing that non-muscle myosins control basal endfoot integrity to regulate interneuron organization.
#RadialGlia have long basal fibers that end in basal endfeet. @LiWang_neuro & @Kriegsteinlabr explore a
#PLOSBiology study showing that non-muscle
#myosins control endfoot integrity to regulate interneuron organization. Primer
https://plos.io/3J0mRZ5 Paper
https://plos.io/3Yb599J Non-muscle myosins control the integrity of cortical radial glial endfeet
Radial glial cells, the stem cells of the cerebral cortex, extend a long basal fiber that ends in basal endfeet. This Primer explores the implications of a new PLOS Biology study revealing that non-muscle myosins control basal endfoot integrity to regulate interneuron organization.
#RadialGlia have long basal fibers that end in basal endfeet. @LiWang_neuro & @Kriegsteinlabr explore a
#PLOSBiology study showing that non-muscle
#myosins control endfoot integrity to regulate interneuron organization. Primer
https://plos.io/3J0mRZ5 Paper
https://plos.io/3Yb599J Non-muscle myosins control the integrity of cortical radial glial endfeet
Radial glial cells, the stem cells of the cerebral cortex, extend a long basal fiber that ends in basal endfeet. This Primer explores the implications of a new PLOS Biology study revealing that non-muscle myosins control basal endfoot integrity to regulate interneuron organization.
The proteome of
#RadialGlia basal
#endfeet reveals new functions for this structure in interneuron organization, highlighting complementary requirements for non-muscle
#myosin heavy chain isoforms in radial glial integrity @TheSilverLab
#PLOSBiology https://plos.io/3Yb599J
Non-muscle myosins control radial glial basal endfeet to mediate interneuron organization
A study of the proteome of radial glial basal endfeet reveals new functions for this subcellular structure in interneuron organization, highlighting the complementary requirements for non-muscle myosin heavy chain isoforms in radial glial integrity.
The proteome of
#RadialGlia basal
#endfeet reveals new functions for this structure in interneuron organization, highlighting complementary requirements for non-muscle
#myosin heavy chain isoforms in radial glial integrity @TheSilverLab
#PLOSBiology https://plos.io/3Yb599JNon-muscle myosins control radial glial basal endfeet to mediate interneuron organization
A study of the proteome of radial glial basal endfeet reveals new functions for this subcellular structure in interneuron organization, highlighting the complementary requirements for non-muscle myosin heavy chain isoforms in radial glial integrity.
The proteome of
#RadialGlia basal
#endfeet reveals new functions for this structure in interneuron organization, highlighting complementary requirements for non-muscle
#myosin heavy chain isoforms in radial glial integrity @TheSilverLab
#PLOSBiology https://plos.io/3Yb599JNon-muscle myosins control radial glial basal endfeet to mediate interneuron organization
A study of the proteome of radial glial basal endfeet reveals new functions for this subcellular structure in interneuron organization, highlighting the complementary requirements for non-muscle myosin heavy chain isoforms in radial glial integrity.
PLOS Biology
