Molecular Analysis of Axonal Transport Dynamics upon Modulation of Microtubule Acetylation.

Axonal transport is used by neurons to distribute mRNAs, proteins, and organelles to their peripheral compartments in order to sustain their structural and functional integrity. Cargoes are transported along the microtubule (MT) network whose post-translational modifications influence transport dynamics. Here, we describe methods to modulate MT acetylation and record its impact on axonal transport in cultured mouse cortical projection neurons as well as in motoneurons of Drosophila melanogaster third-instar larvae. Specifically, we provide a step-by step procedure to reduce the level of MT acetylation and to record and analyze the transport of dye-labeled organelles in projection neuron axons cultured in microfluidic chambers. In addition, we describe the method to record and analyze GFP-tagged mitochondria transport along the motoneuron axons of transgenic Drosophila melanogaster third-instar larvae.

Learning about cell lineage, cellular diversity and evolution of the human brain through stem cell models.

Here, we summarize the current knowledge on cell diversity in the cortex and other brain regions from in vivo mouse models and in vitro models based on pluripotent stem cells. We discuss the mechanisms underlying cell proliferation and temporal progression that leads to the sequential generation of neurons dedicated to different layers of the cortex. We highlight models of corticogenesis from stem cells that recapitulate specific transcriptional and connectivity patterns from different cortical areas. We overview state-of-the art of human brain organoids modeling different brain regions, and we discuss insights into human cortical evolution from stem cells. Finally, we interrogate human brain organoid models for their competence to recapitulate the essence of human brain development.

ATAT1-enriched vesicles promote microtubule acetylation via axonal transport.

Microtubules are polymerized dimers of α- and ß-tubulin that underlie a broad range of cellular activities. Acetylation of α-tubulin by the acetyltransferase ATAT1 modulates microtubule dynamics and functions in neurons. However, it remains unclear how this enzyme acetylates microtubules over long distances in axons. Here, we show that loss of ATAT1 impairs axonal transport in neurons in vivo, and cell-free motility assays confirm a requirement of α-tubulin acetylation for proper bidirectional vesicular transport. Moreover, we demonstrate that the main cellular pool of ATAT1 is transported at the cytosolic side of neuronal vesicles that are moving along axons. Together, our data suggest that axonal transport of ATAT1-enriched vesicles is the predominant driver of α-tubulin acetylation in axons.

p27Kip1 Modulates Axonal Transport by Regulating α-Tubulin Acetyltransferase 1 Stability.

The protein p27Kip1 plays roles that extend beyond cell-cycle regulation during cerebral cortex development, such as the regulation of neuronal migration and neurite branching via signaling pathways that converge on the actin and microtubule cytoskeletons. Microtubule-dependent transport is essential for the maturation of neurons and the establishment of neuronal connectivity though synapse formation and maintenance. Here, we show that p27Kip1 controls the transport of vesicles and organelles along the axon of mice cortical projection neurons in vitro. Moreover, suppression of the p27Kip1 ortholog, dacapo, in Drosophila melanogaster disrupts axonal transport in vivo, leading to the reduction of locomotor activity in third instar larvae and adult flies. At the molecular level, p27Kip1 stabilizes the α-tubulin acetyltransferase 1, thereby promoting the acetylation of microtubules, a post-translational modification required for proper axonal transport.